Dengue, caused by dengue virus (DENV), is now endemic in nearly 100 countries and infection incidence is reported in another 30 countries. Yearly an estimated 400 million cases and 2200 deaths are reported. Effective vaccines against DENV are limited and there has been significant focus on the development of effective antiviral against the disease. The World Health Organization has initiated research programs to prioritize the development and optimization of antiviral agents against several viruses including Flaviviridae. A significant effort has been taken by the researchers to develop effective antivirals against DENV. Several potential small-molecule inhibitors like efavirenz, tipranavir and dasabuvir have been tested against envelope and non-structural proteins of DENV, and are in clinical trials around the world. We recently developed one small molecule, namely 7D, targeting the host PF4-CXCR3 axis. 7D inhibited all 4 serotypes of DENV in vitro and specifically DENV2 infection in two different mice models. Although the development of dengue vaccines remains a high priority, antibody cross reactivity among the serotypes and resulting antibody-dependent enhancement (ADE) of infection are major concerns that have limited the development of effective vaccine against DENV. Therefore, there has been a significant emphasis on the development of antiviral drugs against dengue. This review article describes the rescue effects of some of the small molecule inhibitors to viral/host factors associated with DENV pathogenesis.

One of the rapidly emerging viral diseases dengue is now endemic to more than 100 countries across tropical and subtropical regions of the globe including India [1]. Each year an estimated 400 million cases and 2200 deaths are reported [2]. Throughout the period from 2000 up to 2019, the World Health Organization (WHO) reported a 10-fold rise in cases globally, from 500,000 to 5.2 million. The year 2019 was an unprecedented peak with reported incidents covering 129 countries. While the COVID-19 pandemic and reduced reporting rates caused a slight drop in cases between 2020 and 2022, there has been an increase in dengue infections worldwide since 2023 marked by notable multiplication of outbreaks in both numbers and magnitude concurrently occurring beyond dengue-free areas before.

Dengue is caused by dengue virus (DENV), a single positive-stranded RNA virus of the Flaviviridae family, mainly transmitted by Aedes aegypti trailed by other mosquitoes belonging to genus Aedes [3]. DENV genome encodes three structural proteins (Capsid protein C, Membrane protein M and Envelope Protein E) and seven non-structural proteins (NS1, NS2a, NS2b, NS3, NS4a, NS4b, and NS5) [1]. The RNA genome is divided into three parts: 5′ UTR region (untranslated region), ORF (open reading frame), and 3′ UTR region [4]. DENV is composed of 10,723 nucleotides (approximately 11 kb), which are used to encode larger polyprotein precursors containing ∼3391 amino acid residues [5]. The DENV life cycle is divided into various stages, including viral entry, fusion and disassembly, viral genome replication, viral protein translation and processing, assembly, maturation, budding, and release. The process begins when the virus binds to receptors on a susceptible host cell, causing receptor-dependent endocytosis [6]. The DENV E protein binds to the host cell via interacting with a number of cellular factors present on the target cells, including dendritic cell (DC)-specific intercellular adhesion molecule-3-grabbing non-integrin (DC-SIGN), the mannose receptor, heparan sulfate, FC receptor, and others. DENV uses clathrin-mediated endocytosis to enter the intended cell, enabling the endosome membrane to fuse with DENV, releasing the RNA genome [7]. Viral proteins are produced by the cleavage of a polyprotein resulting from the translation of positive-sense viral RNA by both host and viral proteases. In parallel, an intermediate negative RNA template is created using the positive-sense viral RNA and is utilized as a template for additional genomic replication. During the maturation phase, the replicated genomes and generated viral proteins are put together into virions inside the endoplasmic reticulum (ER). The host enzyme furin cleaves the prM protein into membrane (M) protein as the virions enter the Golgi vesicles, promoting viral maturation. Ultimately, the mature virions are released from the cell via exocytosis [6]. When the virus replicates both the structural and non-structural proteins are transcribed and translated to be available for intracellular antigen processing pathways. These various roles are performed by these NS proteins. Interacting with NS4A/B facilitates replication of the virus by promoting viral replication through binding with NS1 while helicase/protease functions as a protease/helicase on its own [8]. Dengue shock syndrome (DSS) and dengue haemorrhagic fever (DHF) represent critical manifestations. The DENV comprises four distinct serotypes DENV1, DENV2, DENV3, and DENV4. Despite similarities in their amino acid sequences, ranging from 70% to 80%, each serotype poses unique challenges. Notably, individuals previously exposed to one serotype face an elevated risk of severe dengue if infected by another serotype, highlighting the importance of cross-immunity [9]. This is because the sub-neutralizing cross-reactive antibodies opsonize virus particles, facilitating infection of mononuclear phagocytes via Fc-receptor (FcR), a phenomenon called antibody-dependent enhancement (ADE) of infection [10–12]. In 2009, the WHO issued a guideline dividing symptomatic cases into two subgroups: non-severe and severe dengue, further dividing non-severe into symptomatic and symptomatic. The clinical symptoms of febrile illness include low platelet counts, tiredness, irritability, bleeding from body openings, clinical fluid accumulation in the body or legs, tummy pain or tenderness as well as large liver. The severe dengue is characterized by significant organ damage, substantial plasma leakage and haemorrhage, resulting in thrombocytopenia, coagulation abnormalities, vasculopathy, or disseminated intravascular coagulation [13].

This review article elucidates the therapeutic impact of specific small molecule inhibitors on viral and host factors implicated in DENV pathogenesis. Small molecules, defined as low molecular weight organic compounds typically less than 900 Daltons, can regulate biological processes and are widely used in medicinal chemistry to modulate protein functions and pathways due to their ability to easily diffuse across cell membranes. In the context of DENV, these small molecules are being explored as potential antiviral agents. Researchers are investigating these compounds for their ability to inhibit various stages of the DENV life cycle, including entry into host cells, replication, and assembly. By targeting specific viral proteins or host factors essential for viral replication, small molecules could potentially serve as effective treatments to reduce the severity and spread of dengue infections [146]. Antibody cross reactivity among the serotypes and resulting ADE of infection are major concerns that have limited the development of effective vaccines against DENV and there has been, therefore, a significant emphasis on the development of antiviral drugs against dengue. Current research focuses on the development of effective antivirals that can be prescribed early in the course of infection that would prevent transmission of the viruses. The WHO has initiated research programs to prioritize the development and optimization of antiviral agents against several viruses including Flaviviridae. Unfortunately, at the current scenario, there are no approved antivirals against dengue [14]. Many antiviral compounds that inhibit DENV replication have been identified in vivo and in vitro by several groups of researchers [15]. Specific inhibitors targeting the viral envelope [16], NS4B [17], methyl transferase [18], protease [19], and host enzymes such as ER glucosidase [20] have been identified and demonstrated antiviral activity. There is presently no licensed antiviral therapy for DENV infection in humans, despite their apparent efficacy in preventing DENV replication [21]. This review article highlights the urgent need for effective interventions and treatment options for dengue fever (Figure 1).

Dengue pathogenesis in primary and heterologous secondary infection

Figure 1
Dengue pathogenesis in primary and heterologous secondary infection

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Figure 1
Dengue pathogenesis in primary and heterologous secondary infection

Created with Biorender.com.

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During mosquito feeding on humans, DENV is apparently injected into the bloodstream, with spill over in the epidermis and dermis, leading in infection of young Langerhans cells (epiderma DCs) and keratinocytes Following infection, cells that have been infected migrate from the initial site of infection to the lymph nodes. Monocytes and macrophages are attracted to the lymph nodes and hence become susceptible to infection. This increases the infection and spreads the virus throughout the lymphatic system. The term first ‘viremia’ refers to the initial phase of viral infection, during which the virus enters the bloodstream and begins disseminating. This stage involves the infection of numerous mononuclear cells, including monocytes from the bloodstream, myeloid DCs, and macrophages in the spleen and liver. During the initial viral infection in dengue, the virus spreads quickly across the host’s circulatory system, resulting in systemic dissemination. This phase is crucial for infection establishment because the virus gains access to many tissues and organs, allowing for more replication and amplification. Infected mononuclear cells, especially DCs and macrophages, play an important role in delivering the virus to lymphoid organs, where it can evade the host’s immune response and spread. The intensity and duration of initial viremia are major predictors of illness severity and can have an impact on clinical outcomes in dengue patients. This stage must be managed effectively in order to control the infection’s spread and progression [22,23].

Even in secondary infections, severe dengue is infrequent, occurring in just 0.5% to 1% of cases, resulting in severe syndromes. In which antibodies produced during the initial DENV infection bind to but do not neutralize the different DENV serotype. It has been proposed that binding an antibody to a virus of a different serotype allows the immune cells like macrophages and monocytes, potentially up taking more viruses, leading to increased virus production, viremia, and pathogenesis [24]. These antibodies let the virus enter cells with FcγR receptors, which increases viral levels and worsens the sickness [25]. Furthermore, FcγR-mediated DENV infection effectively suppresses the host’s antiviral innate immune response, leading to increased intracellular replication [26]. Some of these mechanisms include antibody-dependent enhancement, cell-mediated pathogenesis, the cytokine storm phenomenon, an individual’s genetic background, virus strain differences, virus levels circulating in individuals during the acute phase, and the infected individual’s nutritional status [27].“Summarized in (Figure 1)”.

Researchers have developed some potential small-molecule inhibitors like efavirenz, tipranavir and dasabuvir against Flaviviruses [28]. The efavirenz was developed to target a non-nucleoside reverse transcriptase inhibitor (NNRTI) of HIV infection. Recent research suggests that efavirenz may also have antiviral effect by blocking the DENV NS5 protein [29]. Tipranavir is a protease inhibitor authorized for the treatment of HIV. Interestingly, tipranavir exhibits antiviral by targeting NS2B-NS3 protease of DENV [30]. The small molecule AZD0530 and Dasatinib have been indicated to reduce DENV2 RNA replication, resulting in decreased steady-state viral RNA accumulation within cells. In addition, research has shown that depleting Fyn kinase using RNA interference (RNAi) resulted in significant suppression of DENV2. Fyn kinase activates SYK protein, which in turn enhances PLC gamma activity. This activity results in the production of DAG and IP3. IP3 increases calcium levels, while DAG activates PKC, leading to the production of NF-κB. The activation of NF-κB subsequently releases cytokines and chemokines, reducing viral infection [31]. Research on JNJ-1802, an effective DENV inhibitor, successfully targets the DENV non-structural protein NS4B and disrupts its interaction with NS3. NS4B is crucial for evading the host's antiviral response by inhibiting the activation of STAT1 and interferon-stimulated genes (ISGs), i.e. IRF1, IRF2, IRF 7, IRF9, ISG15, ISG20, RIG-1, etc., decreasing the host cell's antiviral defence mechanisms [32]. Another study related to small molecule inhibitor of dengue has shown that DHBTs dihydrobenzo thiepines (tricyclic small-molecule) significantly restrict DENV2 infection by altering the ERK signalling pathway via DRD4 regulation, resulting in a reduction in viral replication. Antagonism of DRD4 and subsequent downstream phosphorylation of epidermal growth factor receptor (EGFR)-related kinase (ERK) were discovered to have a negative impact on DENV infection, and blocking signalling through this network was confirmed as the mechanism of anti-DENV activity for this class of compounds [10]. Our laboratory research shows that PF4 promotes p38 MAPK phosphorylation and prevents STAT-2 and IRF-9, in turn decreases IFN-α synthesis in monocytes following DENV2 infection. Importantly, this route was reversed by either anti-PF4 antibody or the PF4 receptor CXCR3 antagonist AMG487, which allowed IFN-α secretion in infected monocytes [33]. This review article describes the rescue effects of small molecules antagonist to several factors associated with DENV pathogenesis.

The recent COVID-19 pandemic has again highlighted the importance of developing antiviral to combat such diseases. Effective antiviral can be prescribed early in the course of infection to prevent transmission of the viruses. The World Health Organization has initiated research programs to prioritize the development and optimization of antiviral agents against several viruses including Flaviviridae. Small molecules which target the specific viral protein and exerts its antiviral properties are called as direct acting antivirals [34]. They will have promising antiviral activity and low toxicity in comparison to host directed small molecules. Development of resistance is the major drawback in developing these direct acting antivirals [35]. Development of such small molecules need the approach of structurally understanding the different proteins encoded by the DENV genome. In DENV, Envelope (structural protein), NS1, NS3 and NS5 (Non-structural proteins) are well studied as target proteins due to their functional activity [36] (Summarized in Figure 2).

Dengue virus replication cycle in host immune cell

Figure 2
Dengue virus replication cycle in host immune cell

It begins with (1) Attachment of virus to host receptor via; (2) clathrin mediated endocytosis further; (3) Disassembly of clathrin coated virus containing vesicles; (4) Forming early endosomes; (5) Maturing into late endosomes and fusion leading to disassembly of virus and release of viral RNA due to low pH; (6) Early endosomes fuse with autophagosomes to facilitate successful replication of DENV further; (7) Fuse with lysosomes for degradation; (8) Viral RNA in cytoplasm replicates in the replication complexes; (9) Translates into virus polypeptide in endoplasmic reticulum (ER); (10,11) Virus assembly and maturation takes place in the golgi apparatus; and further (12) egress from the cells. Created with Biorender.com.

Figure 2
Dengue virus replication cycle in host immune cell

It begins with (1) Attachment of virus to host receptor via; (2) clathrin mediated endocytosis further; (3) Disassembly of clathrin coated virus containing vesicles; (4) Forming early endosomes; (5) Maturing into late endosomes and fusion leading to disassembly of virus and release of viral RNA due to low pH; (6) Early endosomes fuse with autophagosomes to facilitate successful replication of DENV further; (7) Fuse with lysosomes for degradation; (8) Viral RNA in cytoplasm replicates in the replication complexes; (9) Translates into virus polypeptide in endoplasmic reticulum (ER); (10,11) Virus assembly and maturation takes place in the golgi apparatus; and further (12) egress from the cells. Created with Biorender.com.

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NS1

Antiviral small molecules towards NS1 are not that common but studies have shown that peptides which selectively bound DENV NS1 and inhibited all DENV serotypes except DENV3 effectively in human cell lines. However, the higher concentrations of these peptides were found to be cytotoxic [37]. Another study has found that miRNA let-7a inhibited all the serotypes of DENV by targeting a highly conserved sequence of NS1. Studies also found that extracts from honeysuckle plants increase the expression of miRNA let-7a both in vitro and in vivo. Mice treated with these extracts were rescued from dengue infection and pathogenesis [38].

NS2B/NS3

DENV NS3 protein is the major antiviral target due to its varied functions through multiple domains. Its major enzymatic activities include 5′-RNA triphosphatase, helicase, N-terminal protease domain cleaving the viral polyprotein and its C-terminal RNA helicase domain aiding in viral RNA replication and synthesis. NS2B acts as a cofactor for NS3 for proper folding and activity. Protegrin-1, disulfide cyclic peptide, and retrocyclin-1 show antiviral activity by inhibiting the NS2B-NS3 protease [39,40]. Nelfinavir, a repurposed drug, was able to selectively bind to this protease and inhibit the DENV infection.

The helicase domain of NS3 lacks binding pockets making it difficult to the develop drugs towards NS2B-NS3 protease. Some drugs have been shownto inhibit the NS3 helicase domain, Ivermectin is one such antiviral that inhibits NS3 helicase activity by non-competitively binding to the helicase domain [41]. ST-610, a benzoxazole compound and suramin a drug used to treat African sleeping sickness are found to non-competitively inhibiting NS3 helicase [63,64].

NS3/NS4A and B

Dengue NS4 comprises two full-length membrane proteins binding to the ER membrane replication complexes [137]. The NS4A as cofactor for NS3 act as a signal sequence to translocate NS4B into ER lumen. NS4B is known to inhibit STAT1 phosphorylation by blocking the signalling cascade initiated by IFNα/β [42,43]. Studies have shown that AM404 a metabolite generated from paracetamol metabolism is having an inhibitory effect on DENV replication by inhibiting NS4B. Mutations in NS4B are shown to render this metabolites effectivity indicating that this metabolite bind to NS4B to exert its activity [44]. Compound-1a which is further improved to Compound-14a, a spiropyrazolopyridone compound is found to inhibit DENV infection in AG129 mice. NITD-618, a nucleoside analog, is also found to be an inhibitor of NS4B. These compounds are confirmed to be the inhibitors of DENV NS4B through mutation screening assays [17,45]. JNJ-64281802 is another NS4B inhibitor that showed antiviral properties in vitro. Its analog JNJ-A07 was shown to be effective in decreasing the DENV load and pathogenesis in AG129 mice [97,129]. Both of these small molecules block the NS3-NS4 complex which is essential for the formation DENV replication complex.

NS5

NS5 is the largest dengue non-structural protein with various biological and enzymatic functions. NS5 has an N-terminal methyltransferase (MTase) domain for 5′ RNA cap synthesis and methylation, and a C-terminal RNA-dependent RNA polymerase (RdRp) domain for viral RNA synthesis. NS5 is found to be interacting with NS3 to promote DENV replication [46,47]. It is mostly conserved among all dengue serotypes, making it an excellent target for antiviral development. Cordycepin an adenosine derivative is known to inhibit the NS5 MTase activity by binding to SAM-binding site and it is also found to bind to another domain of NS5 to inhibit RdRp activity of NS5 [46]. RK-0404678, a small molecule bound to NS5 and inhibited DENV replication. One binding site is in the thumb domain and the other sits in the active site. Binding of RK-0404678 to active site brings in a conformational change around Tyr607 residues [9]. The small molecules, C9 and C30, are found to inhibit the interaction between NS3 and NS5 by binding to the cavity B of NS5. This site was highly conserved all across the DENV serotypes resulting in showing efficacy of these compounds on all four serotypes. These small molecules were also found to extend their antiviral spectrum across other Flaviviruses like ZIKA and WNV [106]. Using a cell-based assay a study has shown that compound 29 binds to an allosteric binding pocked in the interface of thumb, palm subdomains of DENV RdRp and inhibit the DENV NS5 activity. This site was highly conserved across all the four serotypes leading to its efficacy on all four serotypes [112]. Leaf and bark extracts of plants belonging to Myrtopsis corymbosa of the Rutaceae family strongly inhibit the dengue NS5 RdRp activity. The compounds further extracted shown lesser efficacy in comparison to crude extracts indicating the antiviral properties of these compounds need other molecules from the crude extracts [49]. Direct acting anti-virals are summarized in Table 1.

Table 1
Direct acting anti-virals
DrugTarget(s)Mechanism(s) of actionReference
1662G07 and analogs Envelope
protein 
Fusion inhibition [50
NITD448   [51
1OAN1   [52
Rolitetracycline    
Doxycycline    
A5   [53
Compound 6   [54
P02  Virus entry inhibition [55
EF  Block virus binding and inhibit entry [56
Geraniin   [57,58
DET2   [59
DET4   [59
MLH40 PrM/M
Protein 
Block interaction between dengue M and E proteins [60
VGTI-A3   [61
VGTI-A3-03    
Honeysuckle (Lonicera japonica Thunb.) extracts  Inhibition of viral replication and NS1 expression [38
Ivermectin NS3 helicase and NS2B-NS3 protease Inhibit the complex activity [41,62
ST-610 NS3 helicase Helicase inhibitor [63
Suramin   [64
Compound 25   [65
Compound 7   [66
Protegrin-1 NS
2B-NS3 complex 
Protease inhibitor [39
Retrocyclin-1   [40
Nelfinavir   [67
Carnosine   [68
Palmatine   [69
Thiazolidinone-peptide hybrids   [70
Compound 32   [71
Compound 1   [72
166347   [73
ARDP0006   [74
ARDP0009    
Compound 7n   [75
Diaryl(thio)ethers   [76
Compound C   [77
Compound D    
Compound F (tolcapone)    
SK-12   [78
Compound 104   [79
Ltc1   [80
BP13944   [81
Policresulen   [82
BP2109   [83
MB21   [19
Compound 45a   [84
Compound 14   [85
AM404 NS4B Inhibition of NS4B activity [44
Compound 1a   [45
Compound 14a   [45
NITD-618   [17
AZD0530   [31
Dasatinib    
JNJ-1A   [86
NITD-688   [87
JNJ-A07  Block interaction between NS4B and NS3 [88
Compound B NS4A Inhibit replication [89
Cordycepin NS5 Inhibit viral replication by blocking viral RNA capping (MTase) activity of NS5 [48
Azidothymidine-based triazoles   [90
Compound 10   [18
BG-323   [91
NSC 12155   [92
Myrtopsis corymbose extracts  Inhibit NS5 RdRp activity [49
RK-0404678   [9
Trigocherrins   [93
Trigocherriolides   [93
Chartaceones   [94
Avicularin   [95
Quercitrin    
Betulinic acid    
Spiraeoside    
Rutin    
Pyridobenzothiazolones   [96
(E)-tridec-2-en-4-ynedioic   [97
Octadeca-9,11,13-triynoic acid    
Octadic-13-en-9,11-diynoic acid    
Octadic-13-en-11-ynoic acid    
C29   [98
7-deaza-2′-C-methyl-adenosine  Viral replication inhibitor [99
INX-08189   [100
BCX4430   [101
Balapiravir   [102
NITD008   [102
2′-C-methylcytidine   [103
C9
C30 
NS3-NS5 complex Block interaction between NS3 and NS5 [104
DrugTarget(s)Mechanism(s) of actionReference
1662G07 and analogs Envelope
protein 
Fusion inhibition [50
NITD448   [51
1OAN1   [52
Rolitetracycline    
Doxycycline    
A5   [53
Compound 6   [54
P02  Virus entry inhibition [55
EF  Block virus binding and inhibit entry [56
Geraniin   [57,58
DET2   [59
DET4   [59
MLH40 PrM/M
Protein 
Block interaction between dengue M and E proteins [60
VGTI-A3   [61
VGTI-A3-03    
Honeysuckle (Lonicera japonica Thunb.) extracts  Inhibition of viral replication and NS1 expression [38
Ivermectin NS3 helicase and NS2B-NS3 protease Inhibit the complex activity [41,62
ST-610 NS3 helicase Helicase inhibitor [63
Suramin   [64
Compound 25   [65
Compound 7   [66
Protegrin-1 NS
2B-NS3 complex 
Protease inhibitor [39
Retrocyclin-1   [40
Nelfinavir   [67
Carnosine   [68
Palmatine   [69
Thiazolidinone-peptide hybrids   [70
Compound 32   [71
Compound 1   [72
166347   [73
ARDP0006   [74
ARDP0009    
Compound 7n   [75
Diaryl(thio)ethers   [76
Compound C   [77
Compound D    
Compound F (tolcapone)    
SK-12   [78
Compound 104   [79
Ltc1   [80
BP13944   [81
Policresulen   [82
BP2109   [83
MB21   [19
Compound 45a   [84
Compound 14   [85
AM404 NS4B Inhibition of NS4B activity [44
Compound 1a   [45
Compound 14a   [45
NITD-618   [17
AZD0530   [31
Dasatinib    
JNJ-1A   [86
NITD-688   [87
JNJ-A07  Block interaction between NS4B and NS3 [88
Compound B NS4A Inhibit replication [89
Cordycepin NS5 Inhibit viral replication by blocking viral RNA capping (MTase) activity of NS5 [48
Azidothymidine-based triazoles   [90
Compound 10   [18
BG-323   [91
NSC 12155   [92
Myrtopsis corymbose extracts  Inhibit NS5 RdRp activity [49
RK-0404678   [9
Trigocherrins   [93
Trigocherriolides   [93
Chartaceones   [94
Avicularin   [95
Quercitrin    
Betulinic acid    
Spiraeoside    
Rutin    
Pyridobenzothiazolones   [96
(E)-tridec-2-en-4-ynedioic   [97
Octadeca-9,11,13-triynoic acid    
Octadic-13-en-9,11-diynoic acid    
Octadic-13-en-11-ynoic acid    
C29   [98
7-deaza-2′-C-methyl-adenosine  Viral replication inhibitor [99
INX-08189   [100
BCX4430   [101
Balapiravir   [102
NITD008   [102
2′-C-methylcytidine   [103
C9
C30 
NS3-NS5 complex Block interaction between NS3 and NS5 [104

Besides, researchers developed small molecules targeting host factors like cellular receptors and signalling pathways, which are pro-viral for DENV replication. The major drawback of this approach is hindrance to the natural function of these targets in the host and increased cell cytotoxicity [105]. Bovine lactoferrin and carbohydrate-binding agents were found to inhibit the DENV entry in the DC-SIGN+ monocytes but not in DC-SIGN deficient monocytes indicating these compounds inhibit the virus entry by blocking the binding of DENV virus to DC-SIGN [106,107]. A linear PD1, CD44 peptide isolated from heparin sulphate receptor and a heparin sulphate mimic PG545 have shown an inhibitor effect on DENV entry in in vitro and in vivo experiments [108,109]. Studies have also shown that drugs like 3-MA and Ka-003 which inhibit autophagy has affected the viral replication, but other studies show that autophagy activators like rapamycin helps DENV propagation indicating host autophagy machinery has both anti-viral and pro-viral role in DENV replication [175,176]. Study from our lab has shown that a platelet chemokine released upon platelet activation during dengue infection acts as a proviral by binding to CXCR3 receptor on monocytes. Binding of PF4 to CXCR3 led to inhibition of IFN responses and autophagy resulting in enhanced viral replication. AMG487 a selective inhibitor of CXCR3 has reversed the effects of PF4 and rescued mice from dengue infection [1,33], but this drug was not passed through clinical trials due to its non-linear pharmacokinetics and efficacy problems. We further used computational studies and found a small molecule 7D which potently inhibits all four DENV serotypes in-vitro and DENV2 in in-vivo. So further exploration of host mechanisms involved in DENV replication are necessary to effectively manage the disease burden. The host-directed antiviral are summarized in (Table 2).

Table 2
Host directed anti-virals
DrugTarget(s)Mechanism(s) of actionReference
NITD-451 Translation machinery Inhibition of viral RNA Translation [110
Narasin Ionophore Inhibit the release of viral RNA into cytoplasm [111
Lactimidomycin Translation Machinery Inhibition of viral RNA Translation [112
ST081006   [113
Bromocriptine   [114
Dasatinib c-Src kinase Inhibit dengue virion Assembly [115
Castanospermine calnexin Inhibit viral release [116
Brefeldin A Protein Trafficking Inhibit viral assembly, Maturation and release [117
Bovine lactoferrin DC-SIGN receptor Block the binding of DENV to DC-SIGN receptor [106
Hippeastrum hybrid (HHA)    
Urtica dioica (UDA)    
Galanthus nivalis (GNA)    
PD1 CD44 Heparan sulphate Inhibit the interaction of dengue envelope protein to heparan sulphate [108
PG545   [109
Fucoidan   [118
PI-88   [119
dl-galactan hybrid C2S-3   [120
iota-carrageenan G3d    
CF-238   [121
Sulfated galactomannan   [122
Curdlan sulfate   [123
Chondroitin sulfate E   [124
P4
P7 
β3 integrin Inhibit the interaction between DENV and β3 integrin [125
AMG487 CXCR3 inhibitor Inhibit PF4 interaction with CXCR3 [33
3-MA Autophagy machinery Inhibit autophagy initiation [175
Ka-003  Block autophagolysosome formation [176
DrugTarget(s)Mechanism(s) of actionReference
NITD-451 Translation machinery Inhibition of viral RNA Translation [110
Narasin Ionophore Inhibit the release of viral RNA into cytoplasm [111
Lactimidomycin Translation Machinery Inhibition of viral RNA Translation [112
ST081006   [113
Bromocriptine   [114
Dasatinib c-Src kinase Inhibit dengue virion Assembly [115
Castanospermine calnexin Inhibit viral release [116
Brefeldin A Protein Trafficking Inhibit viral assembly, Maturation and release [117
Bovine lactoferrin DC-SIGN receptor Block the binding of DENV to DC-SIGN receptor [106
Hippeastrum hybrid (HHA)    
Urtica dioica (UDA)    
Galanthus nivalis (GNA)    
PD1 CD44 Heparan sulphate Inhibit the interaction of dengue envelope protein to heparan sulphate [108
PG545   [109
Fucoidan   [118
PI-88   [119
dl-galactan hybrid C2S-3   [120
iota-carrageenan G3d    
CF-238   [121
Sulfated galactomannan   [122
Curdlan sulfate   [123
Chondroitin sulfate E   [124
P4
P7 
β3 integrin Inhibit the interaction between DENV and β3 integrin [125
AMG487 CXCR3 inhibitor Inhibit PF4 interaction with CXCR3 [33
3-MA Autophagy machinery Inhibit autophagy initiation [175
Ka-003  Block autophagolysosome formation [176

Animal models for dengue used in antiviral and vaccine testing

The animal models of infectious diseases play a very important role in understanding the disease pathophysiology as well as development of therapeutics. Unlike other viral diseases, animal models for dengue have been crucial in understanding the pathogenesis, immune response, and testing potential treatments or vaccines. Additionally, animal models have provided valuable insights into the development of severe dengue disease, such as dengue haemorrhagic fever (DHF) and dengue shock syndrome (DSS) [126–128]. However, developing suitable animal models for DENV infection presents several challenges. Several animal models have been used in dengue infection research, including mouse models, non-human primate models, swine models, and shrew models [126,130–132]. Mouse models have played a crucial role in understanding pathogenesis and developing potential therapeutics and vaccines against the DENV. The best mouse model to employ in DENV infection and pathogenesis research has not yet been discovered [130,133]. AG129 mice, which are deficient in both IFN-α/β and IFN-γ receptors, have shown replication of DENV and dengue symptoms like thrombocytopenia, vascular leakage, and high viremia. AG129 mice infected with the adapted DENV strains provided a robust platform for testing therapeutic antibodies and other antiviral compounds [130–132,134–136]. Humanized mice, which are immunodeficient mice engrafted with human cells or tissues, have become invaluable tools for studying DENV infection includes, NSG (NOD/SCID/IL2rγ-/-) immunodeficient mice engrafting with human CD34+ hematopoietic stem cells (HSCs) and BLT Mice (Bone Marrow, Liver, Thymus) mice are developed by transplanting human fetal liver and thymus tissues under the kidney capsule of immunodeficient mice, followed by the injection of human HSCs [130–133]. Non-human primate (NHP) models have been pivotal in the preclinical testing of antiviral therapies and vaccines against DENV, owing to their genetic, physiological, and immunological similarities to humans. Rhesus macaques (Macaca mulatta) and cynomolgus macaques (Macaca fascicularis) are among the most commonly used NHP species for dengue research. Studies evaluating antiviral therapies and candidate vaccines, including live attenuated, inactivated, and recombinant vaccines, have been tested in these models to assess safety, immunogenicity, and protective efficacy [130,132,137–140]. Swine have been identified as an important animal model for dengue infection research due to their physiological similarities to humans. Recent studies have demonstrated that a specific strain of Yucatan miniature pig, Sus scrofa, exhibits physiological and immunological responses closely mirroring those observed in humans. Moreover, swine models have been used to evaluate vaccine candidates and antiviral therapies against DENV [132,133,141,142]. The tree shrew (Tupaia belangeri) has emerged as an alternative animal model for studying DENV infection, offering unique advantages in dengue research. Tree shrews are susceptible to all DENV serotypes infection, showing signs of viremia and clinical symptoms similar to human dengue, including fever, thrombocytopenia, and vascular leakage [143–145]. The model has been used to study the dynamics of immune response to DENV, including the role of T cells, B cells, and cytokines in viral clearance and disease resolution. Studies testing antiviral therapies in tree shrews have demonstrated the efficacy of treatments in reducing viral load and improving clinical outcomes [132,133,147,148].

Preclinical trials are the important steps to understand the underlying mechanisms of a disease and also evaluating the potential efficacy of interventions. Although very few, compounds like geraniin, PG545, NITD-622 and HS-1 have been in the preclinical trial pipeline against dengue. Small animals and non-human primates have been utilized in these trial against dengue [149–152]. Besides, clinical trials for dengue using several drugs are in progress. Importantly, close monitoring of results and analysis of comprehensive data are the crucial steps of a clinical trial towards determining the better efficacy and safety of a drug in human.

Ivermectin

Ivermectin, an antiparasitic medication, has attracted interest for its potential antiviral properties, including its efficacy against all four serotypes of the DENV (DENV1-4). It inhibits the nuclear transport of viral proteins by binding to and inhibiting the importin α/β1 heterodimer, which disrupts the replication cycle of DENV by preventing the nuclear localization of dengue NS5, an RNA-dependent RNA polymerase (RdRp). Studies have shown that ivermectin significantly reduces viral RNA levels and the production of infectious virions in infected cell cultures. Clinical trials, such as the phase I/II trial (NCT02045069), have explored ivermectin as a dengue treatment, focusing on safety and efficacy. Participants received various doses over two or three days, with outcomes measuring the resolution of viremia, NS1 antigen clearance, and fever reduction. Initial results were promising in reducing NS1 protein levels, which are linked to dengue severity, but the trial did not meet its primary endpoint due to fluctuating dengue incidence rates during enrolment. While the clinical benefits of ivermectin for dengue remain inconclusive, ongoing studies are investigating its pharmacokinetics and higher doses to determine if they can effectively inhibit DENV replication and improve clinical outcomes [155–160] preclinical and clinical data for drugs against dengue virus are shown in (Table 3).

Table 3
Comprehensive table including preclinical and clinical data for drugs against DENV
Drug and typeStageMechanism of actionPreclinical dataClinical dataReferences
Remdesivir Antiviral Preclinical Inhibit RNA-dependent RNA polymerase (RdRp) Inhibited DENV replication in cell culture and a significant reduction in viral load improves the survival rate of mice. Reduced viremia and improved clinical outcomes following dengue infection in NHP The study focused on safety, tolerability, and pharmacokinetics in healthy volunteers. It also evaluated efficacy in NS1-positive dengue patients; primary endpoints included a reduction in viral load and symptom improvement [153,154
Ivermectin Antiparasitic (repurposed) Phase 2 Inhibits nuclear import of viral proteins Demonstrated antiviral activity in vitro against DENV Mixed results in clinical trials; issues with dosage and bioavailability [151,156–159
Zanamivir Antiviral (Influenza) Phase 2 (ZAP-Dengue Trial) Neuraminidase inhibitor Limited preclinical data for dengue; primarily used for influenza Investigated for severe dengue with vascular permeability syndrome in Phase 2 trial [161,162
Niclosamide Anthelmintic (repurposed) Preclinical/Phase 1 Disrupts viral replication and host cell pathways Effective against DENV in vitro; challenges with bioavailability Early Phase 1 trials were initiated to assess safety and tolerability [163–165
JNJ-64281802 (Direct-acting antiviral) Phase 2 Inhibits NS3-NS4B protein interaction Effective in reducing viral load in non-human primates and mice. Potent activity against multiple dengue serotypes in animal models Phase 2 trials underway to determine efficacy and safety in humans [32,166,97
AT-752 (Direct-acting antiviral) Phase 1/2 Inhibits viral replication Preclinical studies showed a significant reduction in viral load in animal models Ongoing Phase 1/2 trials assessing safety, tolerability, and preliminary efficacy [167,168
Favipiravir Broad-spectrum antiviral Phase 2/3 Inhibits viral RNA polymerase Demonstrated broad antiviral activity including against dengue in vitro and in animal models Mixed results in reducing viral load and symptoms in Phase 2/3 trials [169,170
Balapiravir Direct-acting antiviral Phase 2 Inhibits viral RNA polymerase Initially promising in vitro results; limited efficacy in animal models Phase 2 trials showed mixed results, leading to discontinuation of further development [171
CelgosivirHost-directed antiviral Phase 2 Inhibits host α-glucosidase, disrupting viral glycoprotein processing | Shown to reduce viral replication in preclinical studies Phase 2 trials demonstrated some efficacy; potential for combination therapy [172
Vitamin D Phase 2 Immunomodulatory Modulating immune response and up-regulates the antimicrobial peptides and cytokines, which could potentially reduce the severity of dengue infection. Laboratory studies have suggested that Vitamin D3 can inhibit the replication of DENV in cell cultures Ongoing clinical trials are evaluating the efficacy of high-dose Vitamin D3 in patients with dengue fever. Participants receive doses of 200,000 IU or 400,000 IU Vitamin D3 orally to assess its impact on disease progression and severity [173,174
Drug and typeStageMechanism of actionPreclinical dataClinical dataReferences
Remdesivir Antiviral Preclinical Inhibit RNA-dependent RNA polymerase (RdRp) Inhibited DENV replication in cell culture and a significant reduction in viral load improves the survival rate of mice. Reduced viremia and improved clinical outcomes following dengue infection in NHP The study focused on safety, tolerability, and pharmacokinetics in healthy volunteers. It also evaluated efficacy in NS1-positive dengue patients; primary endpoints included a reduction in viral load and symptom improvement [153,154
Ivermectin Antiparasitic (repurposed) Phase 2 Inhibits nuclear import of viral proteins Demonstrated antiviral activity in vitro against DENV Mixed results in clinical trials; issues with dosage and bioavailability [151,156–159
Zanamivir Antiviral (Influenza) Phase 2 (ZAP-Dengue Trial) Neuraminidase inhibitor Limited preclinical data for dengue; primarily used for influenza Investigated for severe dengue with vascular permeability syndrome in Phase 2 trial [161,162
Niclosamide Anthelmintic (repurposed) Preclinical/Phase 1 Disrupts viral replication and host cell pathways Effective against DENV in vitro; challenges with bioavailability Early Phase 1 trials were initiated to assess safety and tolerability [163–165
JNJ-64281802 (Direct-acting antiviral) Phase 2 Inhibits NS3-NS4B protein interaction Effective in reducing viral load in non-human primates and mice. Potent activity against multiple dengue serotypes in animal models Phase 2 trials underway to determine efficacy and safety in humans [32,166,97
AT-752 (Direct-acting antiviral) Phase 1/2 Inhibits viral replication Preclinical studies showed a significant reduction in viral load in animal models Ongoing Phase 1/2 trials assessing safety, tolerability, and preliminary efficacy [167,168
Favipiravir Broad-spectrum antiviral Phase 2/3 Inhibits viral RNA polymerase Demonstrated broad antiviral activity including against dengue in vitro and in animal models Mixed results in reducing viral load and symptoms in Phase 2/3 trials [169,170
Balapiravir Direct-acting antiviral Phase 2 Inhibits viral RNA polymerase Initially promising in vitro results; limited efficacy in animal models Phase 2 trials showed mixed results, leading to discontinuation of further development [171
CelgosivirHost-directed antiviral Phase 2 Inhibits host α-glucosidase, disrupting viral glycoprotein processing | Shown to reduce viral replication in preclinical studies Phase 2 trials demonstrated some efficacy; potential for combination therapy [172
Vitamin D Phase 2 Immunomodulatory Modulating immune response and up-regulates the antimicrobial peptides and cytokines, which could potentially reduce the severity of dengue infection. Laboratory studies have suggested that Vitamin D3 can inhibit the replication of DENV in cell cultures Ongoing clinical trials are evaluating the efficacy of high-dose Vitamin D3 in patients with dengue fever. Participants receive doses of 200,000 IU or 400,000 IU Vitamin D3 orally to assess its impact on disease progression and severity [173,174

Zanamivir

Zanamivir is an antiviral drug primarily used for treating and preventing influenza by inhibiting the neuraminidase enzyme essential for viral replication and release. Although it is effective against influenza, zanamivir is not inherently effective against the DENV, which lacks neuraminidase. Consequently, zanamivir’s direct mechanism of action does not apply to DENV. However, preclinical studies have shown that zanamivir can reduce vascular leakage caused by dengue in mice, addressing a major cause of death in severe dengue infections [164]. Zanamivir is currently being investigated in a phase I clinical trial (NCT04597437) named ZAP-DENGUE, conducted by George Washington University and other institutions. This randomized, double-blind, placebo-controlled trial aims to evaluate the safety and efficacy of intravenous zanamivir for treating vascular permeability syndrome in severe dengue cases. The trial, involving 74 participants with dengue fever, started in March 2024 and is expected to be completed by September 2025. Primary outcomes include treatment-emergent adverse events and levels of endothelial glycocalyx biomarkers, which indicate vascular damage [161,162].

Niclosamide-based antiviral

Niclosamide, an anthelmintic drug approved for the treatment of tapeworm infections, has gained attention for its potential repurposing as a broad-spectrum antiviral agent. Researchers are exploring niclosamide’s efficacy against various viral infections, including DENV, due to its ability to inhibit viral replication and modulate host cell pathways. In vitro studies have demonstrated that niclosamide effectively inhibits the replication of DENV in cell cultures. It reduces viral RNA levels and the production of infectious virions. Niclosamide inhibits DENV infection by interfering with endosomal acidification, thereby preventing viral entry and replication within host cells, independent of mTOR signalling [163,164]. Additionally, preclinical studies in animal models have shown that niclosamide can decrease viremia and improve survival rates in dengue-infected subjects. Hyundai Bioscience is conducting clinical trials in Brazil, a region with a high burden of dengue. These trials aim to evaluate the effectiveness of a niclosamide-based antiviral formulation in reducing the severity of dengue symptoms and viral load. Niclosamide-based antivirals represent a promising avenue for dengue treatment, supported by preclinical efficacy and ongoing clinical trials. If proven effective, niclosamide could become an important tool in managing dengue, particularly in regions with high incidence rates. Continued research and clinical validation are essential to fully establish its therapeutic potential and address the challenges associated with its use [164,165].

JNJ-1802

Is an innovative antiviral compound shows significant promise against the DENV. This small molecule inhibits the DENV replication by blocking the interaction between the non-structural proteins NS3 and NS4B, which are critical for viral replication. This compound has shown strong efficacy in preclinical studies, demonstrating protection in non-human primates and mice against DENV serotypes DENV-1 and DENV-2 and effectiveness against all four dengue serotypes in mouse models with a favourable safety profile. In a Phase 1 clinical trial, JNJ-1802 was found to be safe and well-tolerated in humans. In a recent human challenge study, JNJ-1802 exhibited a dose-dependent antiviral effect against DENV serotype 3 (DENV-3), reducing the detectability of viral RNA and delaying the onset of detectable viremia [32,97,166 ]. These findings are encouraging as J&J continues to conduct a large-scale phase 2 trial (NCT05048875) involving 1,850 participants across several countries where dengue is endemic, such as Brazil, Colombia, and Thailand. Overall, JNJ-1802 represents a significant advancement in the fight against dengue, offering potential both as a prophylactic and therapeutic agent. If successful, it could greatly impact global health by providing a much-needed antiviral treatment for dengue, which affects millions of people annually and currently lacks specific therapeutic options. These trials are critical for understanding the safety, efficacy, and optimal dosing of JNJ-64281802 in combating dengue virus infections.

Dengue is an endemic with frequent outbreaks across the globe with significant disease burden due to global warming, environmental changes, pollution, rapid urbanization and increasing population. WHO has taken up the goal of decreasing the dengue related mortality and morbidity of dengue by 2020. Therefore, there is an urgent need for the countries to further increase the collaborations and also make the research results available for the peers in the field of dengue research. Research should be intensifying in the aspects of disease pathogenesis to better understand the course of pathological events in case of dengue.

Though multiple small molecules being reported to be having antiviral activity against the DENV, very few of them were able to be pursued further for clinical trials. This is due to lack of the complete understanding of the dengue disease pathogenesis. There is significant involvement of government agenesis along with private research institutes and medical professionals during COVID-19 pandemic in development of treatment regimens and vaccines. Researchers should collaborate with the medical professionals in better understanding the pathological events during the course of dengue fever. This will help in exploring the causes of disease with new perspectives. Due to unclear disease pathogenesis, till date there was no specific small molecule for clinical use is still lacking. The major setbacks for this also include difficulties in establishing an efficient screening platform for dengue anti-virals, development of pre-clinical animal models for drug efficacy testing and discovery of new strategies in development of small molecules against dengue. Therefore, there is an urgent need in understanding the dengue disease pathogenesis which help in development of preclinical animal models and discovering new target molecules against which small molecules can be designed and developed.

The authors declare that there are no competing interests associated with the manuscript.

The authors acknowledge the funding by grants [grant numbers BT/PR22881 and BT/PR22985] from the Department of Biotechnology, Government of India (to P.G.); and CRG/000092 from the Science and Engineering Research Board, Government of India (to P.G.).

Navya Chauhan: Writing—original draft, Writing—review & editing. Kishan Kumar Gaur: Writing—original draft, Writing—review & editing. Tejeswara Rao Asuru: Writing—original draft, Writing—review & editing. Prasenjit Guchhait: Conceptualization, Funding acquisition, Writing—original draft, Project administration, Writing—review & editing.

DC

dendritic cell

DENV

dengue virus

DENV-3

dengue virus serotype 3

DHF

dengue haemorrhagic fever

DSS

dengue shock syndrome

EGFR

epidermal growth factor receptor

ER

endoplasmic reticulum

ERK

epidermal growth factor receptor-related kinase

HSC

hematopoietic stem cell

ISG

interferon-stimulated gene

NHP

non-human primate

1.
Khanam
A.
,
Gutiérrez-Barbosa
H.
,
Lyke
K.E.
and
Chua
J.v.
(
2022
)
Immune-mediated pathogenesis in dengue virus infection
.
Viruses
14
,
2575
[PubMed]
2.
Roy
S.K.
and
Bhattacharjee
S.
(
2021
)
Dengue virus: epidemiology, biology, and disease aetiology
.
Can. J. Microbiol.
67
,
687
702
[PubMed]
3.
Bhatt
P.
,
Sabeena
S.P.
,
Varma
M.
and
Arunkumar
G.
(
2021
)
Current understanding of the pathogenesis of dengue virus infection
.
Curr. Microbiol.
78
,
17
32
,
[PubMed]
4.
Ng
W.C.
,
Soto-Acosta
R.
,
Bradrick
S.S.
,
Garcia-Blanco
M.A.
and
Ooi
E.E.
(
2017
)
The 5ʹ and 3ʹ untranslated regions of the flaviviral genome
.
Viruses
9
,
137
[PubMed]
5.
Gautam
S.
,
Thakur
A.
,
Rajput
A.
and
Kumar
M.
(
2024
)
Anti-dengue: a machine learning-assisted prediction of small molecule antivirals against dengue virus and implications in drug repurposing
.
Viruses
16
,
45
[PubMed]
6.
Tian
Y.-S.
,
Zhou
Y.
,
Takagi
T.
,
Kameoka
M.
and
Kawashita
N.
(
2018
)
Dengue virus and its inhibitors: a brief review
.
Chem. Pharm. Bull.
66
,
191
206
[PubMed]
7.
Kok
B.H.
,
Lim
H.T.
,
Lim
C.P.
,
Lai
N.S.
,
Leow
C.Y.
and
Leow
C.H.
(
2023
)
Dengue virus infection - a review of pathogenesis, vaccines, diagnosis and therapy
.
Virus Res.
324
,
199018
,
[PubMed]
8.
Swarbrick
C.M.D.
,
Basavannacharya
C.
,
Chan
K.W.K.
,
Chan
S.A.
,
Singh
D.
,
Wei
N.
et al.
(
2017
)
NS3 helicase from dengue virus specifically recognizes viral RNA sequence to ensure optimal replication
.
Nucleic Acids Res.
45
,
12904
12920
[PubMed]
9.
Shimizu
H.
,
Saito
A.
,
Mikuni
J.
,
Nakayama
E.E.
,
Koyama
H.
,
Honma
T.
et al.
(
2019
)
Discovery of a small molecule inhibitor targeting dengue virus NS5 RNA-dependent RNA polymerase
.
PLoS Negl. Trop. Dis.
13
,
e0007894
10.
Smith
J.L.
,
Stein
D.A.
,
Shum
D.
,
Fischer
M.A.
,
Radu
C.
et al.
(
2014
)
Inhibition of dengue virus replication by a class of small-molecule compounds that antagonize dopamine receptor D4 and downstream mitogen-activated protein kinase signaling
.
J. Virol.
88
,
5533
5542
[PubMed]
11.
Guzman
M.G.
,
Alvarez
M.
and
Halstead
S.B.
(
2013
)
Secondary infection as a risk factor for dengue hemorrhagic fever/dengue shock syndrome: an historical perspective and role of antibody-dependent enhancement of infection
.
Arch. Virol
158
,
1445
1459
[PubMed]
12.
Dejnirattisai
W.
,
Jumnainsong
A.
,
Onsirisakul
N.
,
Fitton
P.
,
Vasanawathana
S.
,
Limpitikul
W.
et al.
(
2010
)
Cross-reacting antibodies enhance dengue virus infection in humans
.
Science
328
,
745
748
[PubMed]
13.
Lai
Y.C.
,
Chao
C.H.
and
Yeh
T.M.
(
2020
)
Roles of macrophage migration inhibitory factor in dengue pathogenesis: From pathogenic factor to therapeutic target
.
Microorganisms
8
,
891
[PubMed]
14.
Obi
J.O.
,
Gutiérrez-Barbosa
H.
,
Chua
J.v.
and
Deredge
D.J.
(
2021
)
Current trends and limitations in dengue antiviral research
.
Tropical Med. Infectious Dis.
6
,
180
,
15.
Noble
C.G.
,
Chen
Y.L.
,
Dong
H.
,
Gu
F.
,
Lim
S.P.
,
Schul
W.
et al.
(
2010
)
Strategies for development of dengue virus inhibitors
.
Antiviral Res.
85
,
450
462
[PubMed]
16.
Leal
E.S.
,
Adler
N.S.
,
Fernández
G.A.
,
Gebhard
L.G.
,
Battini
L.
,
Aucar
M.G.
et al.
(
2019
)
De novo design approaches targeting an envelope protein pocket to identify small molecules against dengue virus
.
Eur. J. Med. Chem.
182
,
111628
[PubMed]
17.
Xie
X.
,
Wang
Q.-Y.
,
Xu
H.Y.
,
Qing
M.
,
Kramer
L.
,
Yuan
Z.
et al.
(
2011
)
Inhibition of dengue virus by targeting viral NS4B protein
.
J. Virol.
85
,
11183
11195
[PubMed]
18.
Lim
S.P.
,
Sonntag
L.S.
,
Noble
C.
,
Nilar
S.H.
,
Ng
R.H.
,
Zou
G.
et al.
(
2011
)
Small molecule inhibitors that selectively block dengue virus methyltransferase
.
J. Biol. Chem.
286
,
6233
6240
[PubMed]
19.
Raut
R.
,
Beesetti
H.
,
Tyagi
P.
,
Khanna
I.
,
Jain
S.K.
,
Jeankumar
V.U.
et al.
(
2015
)
A small molecule inhibitor of dengue virus type 2 protease inhibits the replication of all four dengue virus serotypes in cell culture
.
Virol. J.
12
,
16
[PubMed]
20.
Chang
J.
,
Warren
T.K.
,
Zhao
X.
,
Gill
T.
,
Guo
F.
,
Wang
L.
et al.
(
2013
)
Small molecule inhibitors of ER α-glucosidases are active against multiple hemorrhagic fever viruses
.
Antiviral Res.
98
,
432
440
[PubMed]
21.
Byrd
C.M.
,
Dai
D.
,
Grosenbach
D.W.
,
Berhanu
A.
,
Jones
K.F.
,
Cardwell
K.B.
et al.
(
2013
)
A novel inhibitor of dengue virus replication that targets the capsid protein
.
Antimicrob. Agents Chemother.
57
,
15
25
[PubMed]
22.
Martina
B.E.E.
,
Koraka
P.
and
Osterhaus
A.D.M.E.
(
2009
)
Dengue virus pathogenesis: An integrated view
.
Clin. Microbiol. Rev.
22
,
564
581
[PubMed]
23.
Durbin
A.P.
,
Vargas
M.J.
,
Wanionek
K.
,
Hammond
S.N.
,
Gordon
A.
,
Rocha
C.
et al.
(
2008
)
Phenotyping of peripheral blood mononuclear cells during acute dengue illness demonstrates infection and increased activation of monocytes in severe cases compared to classic dengue fever
.
Virology
376
,
429
435
[PubMed]
24.
Rawlinson
S.M.
,
Pryor
M.J.
,
Wright
P.J.
and
Jans
D.A.
(
2006
)
Dengue virus RNA polymerase NS5: a potential therapeutic target?
Curr. Drug Targets
7
,
1623
1638
[PubMed]
25.
Halstead
S.B.
(
2003
)
Neutralization and antibody-dependent enhancement of dengue viruses
.
Adv. Virus Res.
60
,
421
467
[PubMed]
26.
Idris
F.
,
Ting
D.H.R.
and
Alonso
S.
(
2021
)
An update on dengue vaccine development, challenges, and future perspectives
.
Expert Opin. Drug Discovery
16
,
47
58
,
Taylor and Francis Ltd
27.
Noisakran
S.
and
Guey
C.P.
(
2008
)
Alternate hypothesis on the pathogenesis of dengue hemorrhagic fever (DHF)/dengue shock syndrome (DSS) in dengue virus infection
.
Exp. Biol. Med.
233
,
401
408
28.
Stefanik
M.
,
Valdes
J.J.
,
Ezebuo
F.C.
,
Haviernik
J.
,
Uzochukwu
I.C.
et al.
(
2020
)
FDA-approved drugs efavirenz, tipranavir, and dasabuvir inhibit replication of multiple flaviviruses in vero cells
.
Microorganisms
8
,
4
599
[PubMed]
29.
Beesetti
H.
,
Khanna
N.
and
Swaminathan
S.
(
2014
)
Drugs for dengue: A patent review (2010-2014). Expert Opinion on Therapeutic Patents
.
Informa Healthcare
24
1171
1184
30.
Norshidah
H.
,
Leow
C.H.
,
Ezleen
K.E.
,
Wahab
H.A.
,
Vignesh
R.
,
Rasul
A.
et al.
(
2023
)
Assessing the potential of NS2B/NS3 protease inhibitors biomarker in curbing dengue virus infections: in silico vs. in vitro approach
.
Front. Cell. Infection Microbiol.
13
,
Frontiers Media S.A
31.
de Wispelaere
M.
,
LaCroix
A.J.
and
Yang
P.L.
(
2013
)
The small molecules AZD0530 and dasatinib inhibit dengue virus RNA replication via Fyn kinase
.
J. Virol.
87
,
7367
7381
[PubMed]
32.
Goethals
O.
,
Kaptein
S.J.F.
,
Kesteleyn
B.
,
Bonfanti
J.F.
,
van Wesenbeeck
L.
,
Bardiot
D.
et al.
(
2023
)
Blocking NS3-NS4B interaction inhibits dengue virus in non-human primates
.
Nature
615
,
678
686
[PubMed]
33.
Ojha
A.
,
Bhasym
A.
,
Mukherjee
S.
,
Annarapu
G.K.
,
Bhakuni
T.
,
Akbar
I.
et al.
(
2019
)
Platelet factor 4 promotes rapid replication and propagation of Dengue and Japanese encephalitis viruses
.
EBioMedicine
39
,
332
347
[PubMed]
34.
Low
J.G.
,
Gatsinga
R.
,
Vasudevan
S.G.
and
Sampath
A.
(
2018
)
Dengue antiviral development: a continuing journey
.
Adv. Exp. Med. Biol.
1062
,
319
332
,
Springer New York LLC
[PubMed]
35.
Boldescu
V.
,
Behnam
M.A.M.
,
Vasilakis
N.
and
Klein
C.D.
(
2017
)
Broad-spectrum agents for flaviviral infections: Dengue, Zika and beyond
.
Nat. Rev. Drug Discovery
16
,
565
586
,
Nature Publishing Group
36.
Troost
B.
and
Smit
J.M.
(
2020
)
Recent advances in antiviral drug development towards dengue virus
.
Curr. Opin. Virol.
43
,
9
21
,
Elsevier B.V
[PubMed]
37.
Songprakhon
P.
,
Thaingtamtanha
T.
,
Limjindaporn
T.
,
Puttikhunt
C.
,
Srisawat
C.
,
Luangaram
P.
et al.
(
2020
)
Peptides targeting dengue viral nonstructural protein 1 inhibit dengue virus production
.
Sci. Rep.
10
,
[PubMed]
38.
Lee
Y.R.
,
Chang
C.M.
,
Yeh
Y.C.
,
Huang
C.Y.F.
et al.
(
2021
)
Honeysuckle aqueous extracts induced let-7a suppress ev71 replication and pathogenesis in vitro and in vivo and is predicted to inhibit sars-cov-2
.
Viruses
13
,
39.
Rothan
H.A.
,
Abdulrahman
A.Y.
,
Sasikumer
P.G.
,
Othman
S.
et al.
(
2012
)
Protegrin-1 inhibits dengue NS2B-NS3 serine protease and viral replication in MK2 cells
.
J. Biomed. Biotechnol.
2012
,
251482
[PubMed]
40.
Rothan
H.A.
,
Han
H.C.
,
Ramasamy
T.S.
,
Othman
S.
et al.
(
2012
)
Inhibition of dengue NS2B-NS3 protease and viral replication in Vero cells by recombinant retrocyclin-1
.
BMC Infectious Diseases
12
,
314
[PubMed]
41.
Mastrangelo
E.
,
Pezzullo
M.
,
de burghgraeve
T.
,
Kaptein
S.
,
Pastorino
B.
,
Dallmeier
K.
et al.
(
2012
)
Ivermectin is a potent inhibitor of flavivirus replication specifically targeting NS3 helicase activity: New prospects for an old drug
.
J. Antimicrob. Chemother.
67
,
1884
1894
[PubMed]
42.
Miller
S.
,
Kastner
S.
,
Krijnse-Locker
J.
,
Bühler
S.
and
Bartenschlager
R.
(
2007
)
The non-structural protein 4A of dengue virus is an integral membrane protein inducing membrane alterations in a 2K-regulated manner
.
J. Biol. Chem.
282
,
8873
8882
[PubMed]
43.
Muñ Oz-Jordá
J.L.
,
Sá Nchez-Burgos
G.G.
,
Laurent-Rolle
M.
and
García-Sastre
A.
(
2003
)
Inhibition of interferon signaling by dengue virus
.
Proc. Natl. Acad. Sci. U.S.A.
100
,
14333
14338
[PubMed]
44.
van Cleef
K.W.R.
,
Overheul
G.J.
,
Thomassen
M.C.
,
Marjakangas
J.M.
et al.
(
2016
)
Escape mutations in NS4B render dengue virus insensitive to the antiviral activity of the paracetamol metabolite AM404
.
Antimicrob. Agents Chemother.
60
,
2554
2557
[PubMed]
45.
Wang
Q.-Y.
,
Dong
H.
,
Zou
B.
,
Karuna
R.
,
Wan
K.F.
,
Zou
J.
et al.
(
2015
)
Discovery of dengue virus NS4B inhibitors
.
J. Virol.
89
,
8233
8244
[PubMed]
46.
Zhao
Y.
,
Soh
T.S.
,
Zheng
J.
,
Chan
K.W.K.
,
Phoo
W.W.
et al.
(
2015
)
A crystal structure of the dengue virus NS5 protein reveals a novel inter-domain interface essential for protein flexibility and virus replication
.
PLoS Pathog.
11
,
1
27
47.
Bujalowski
P.J.
,
Bujalowski
W.
,
Choi
K.H.
and
Michael Diamond
E.S.
(
2017
)
Interactions between the dengue virus polymerase ns5 and stem-loop a genome replication and regulation of viral gene expression crossm
.
J. Virol.
91
,
47
64
48.
Panya
A.
,
Songprakhon
P.
,
Panwong
S.
,
Jantakee
K.
,
Kaewkod
T.
,
Tragoolpua
Y.
et al.
(
2021
)
Cordycepin inhibits virus replication in dengue virus-infected vero cells
.
Molecules
26
,
3118
49.
Coulerie
P.
,
Maciuk
A.
,
Lebouvier
N.
,
Hnawia
E.
,
Guillemot
J.-C.
,
Canard
B.
et al.
(
2013
)
Phytochemical Study of Myrtopsis corymbosa, Perspectives for Anti-Dengue Natural Compound Research
.
Nat. Prod
7
,
250
253
,
50.
Schmidt
A.G.
,
Lee
K.
,
Yang
P.L.
and
Harrison
S.C.
(
2012
)
Small-molecule inhibitors of dengue-virus entry
.
PLoS Pathog.
8
,
51.
Poh
M.K.
,
Yip
A.
,
Zhang
S.
,
Priestle
J.P.
,
Ma
N.L.
et al.
(
2009
)
A small molecule fusion inhibitor of dengue virus
.
Antiviral Res.
84
,
260
266
[PubMed]
52.
Yang
J.M.
,
Chen
Y.F.
,
Tu
Y.Y.
,
Yen
K.R.
and
Yang
Y.L.
(
2007
)
Combinatorial computational approaches to identify tetracycline derivatives as flavivirus inhibitors
.
PloS ONE
2
,
53.
Kampmann
T.
,
Yennamalli
R.
,
Campbell
P.
,
Stoermer
M.J.
,
Fairlie
D.P.
,
Kobe
B.
et al.
(
2009
)
In silico screening of small molecule libraries using the dengue virus envelope E protein has identified compounds with antiviral activity against multiple flaviviruses
.
Antiviral Res.
84
,
234
241
[PubMed]
54.
Wang
Q.Y.
,
Patel
S.J.
,
Vangrevelinghe
E.
,
Hao
Y.X.
,
Rao
R.
et al.
(
2009
)
A small-molecule dengue virus entry inhibitor
.
Antimicrob. Agents Chemother.
53
,
1823
1831
[PubMed]
55.
Zhou
Z.
,
Khaliq
M.
,
Suk
J.E.
,
Patkar
C.
,
Li
L.
,
Kuhn
R.J.
et al.
(
2008
)
Antiviral compounds discovered by virtual screening of small-molecule libraries against dengue virus E protein
.
ACS Chem. Biol.
3
,
765
775
[PubMed]
56.
Panya
A.
,
Bangphoomi
K.
,
Choowongkomon
K.
and
Yenchitsomanus
P.T.
(
2014
)
Peptide inhibitors against dengue virus infection
.
Chem. Biol. Drug Des.
84
,
148
157
[PubMed]
57.
Abdul Ahmad
S.A.
,
Palanisamy
U.D.
,
Khoo
J.J.
et al.
(
2019
)
Efficacy of geraniin on dengue virus type-2 infected BALB/c mice
.
Virol. J.
16
,
[PubMed]
58.
Abdul Ahmad
S.A.
,
Palanisamy
U.D.
,
Tejo
B.A.
et al.
(
2017
)
Geraniin extracted from the rind of Nephelium lappaceum binds to dengue virus type-2 envelope protein and inhibits early stage of virus replication
.
Virol. J.
14
,
229
[PubMed]
59.
Alhoot
M.A.
,
Rathinam
A.K.
,
Wang
S.M.
,
Manikam
R.
and
Sekaran
S.D.
(
2013
)
Inhibition of dengue virus entry into target cells using synthetic antiviral peptides
.
Int. J. Med. Sci.
10
,
719
729
[PubMed]
60.
Panya
A.
,
Sawasdee
N.
,
Junking
M.
,
Srisawat
C.
,
Choowongkomon
K.
and
Yenchitsomanus
P.T.
(
2015
)
A peptide inhibitor derived from the conserved ectodomain region of DENV membrane (M) Protein with activity against dengue virus infection
.
Chem. Biol. Drug Des.
86
,
1093
1104
[PubMed]
61.
Smith
J.L.
,
Sheridan
K.
,
Parkins
C.J.
,
Frueh
L.
,
Jemison
A.L.
,
Strode
K.
et al.
(
2018
)
Characterization and structure-activity relationship analysis of a class of antiviral compounds that directly bind dengue virus capsid protein and are incorporated into virions
.
Antiviral Res.
155
,
12
19
[PubMed]
62.
Tomlinson
S.M.
and
Watowich
S.J.
(
2012
)
Use of parallel validation high-throughput screens to reduce false positives and identify novel dengue NS2B-NS3 protease inhibitors
.
Antiviral Res.
93
,
245
252
[PubMed]
63.
Byrd
C.M.
,
Grosenbach
D.W.
,
Berhanu
A.
,
Dai
D.
,
Jones
K.F.
et al.
(
2013
)
Novel benzoxazole inhibitor of dengue virus replication that targets the NS3 helicase
.
Antimicrob. Agents Chemother.
57
,
1902
1912
[PubMed]
64.
Basavannacharya
C.
and
Vasudevan
S.G.
(
2014
)
Suramin inhibits helicase activity of NS3 protein of dengue virus in a fluorescence-based high throughput assay format
.
Biochem. Biophys. Res. Commun.
453
,
539
544
[PubMed]
65.
Sweeney
N.L.
,
Hanson
A.M.
,
Mukherjee
S.
,
Ndjomou
J.
,
Geiss
B.J.
,
Steel
J.J.
et al.
(
2015
)
Benzothiazole and pyrrolone flavivirus inhibitors targeting the viral helicase
.
ACS Infectious Dis.
1
,
140
148
66.
Ndjomou
J.
,
Kolli
R.
,
Mukherjee
S.
,
Shadrick
W.R.
,
Hanson
A.M.
,
Sweeney
N.L.
et al.
(
2012
)
Fluorescent primuline derivatives inhibit hepatitis C virus NS3-catalyzed RNA unwinding, peptide hydrolysis and viral replicase formation
.
Antiviral Res.
96
,
245
255
[PubMed]
67.
Bhakat
S.
,
Delang
L.
,
Kaptein
S.
,
Neyts
J.
,
Leyssen
P.
and
Jayaprakash
V.
(
2015
)
Reaching beyond HIV/HCV: Nelfinavir as a potential starting point for broad-spectrum protease inhibitors against dengue and chikungunya virus
.
RSC Adv.
5
,
85938
85949
68.
Rothan
H.A.
,
Abdulrahman
A.Y.
,
Khazali
A.S.
,
Nor Rashid
N.
,
Chong
T.T.
and
Yusof
R.
(
2019
)
Carnosine exhibits significant antiviral activity against Dengue and Zika virus
.
J. Pept. Sci.
25
,
[PubMed]
69.
Jia
F.
,
Zou
G.
,
Fan
J.
and
Yuan
Z.
(
2010
)
Identification of palmatine as an inhibitor of West Nile virus
.
Arch. Virol
155
,
1325
1329
[PubMed]
70.
Nitsche
C.
,
Behnam
M.A.M.
,
Steuer
C.
and
Klein
C.D.
(
2012
)
Retro peptide-hybrids as selective inhibitors of the Dengue virus NS2B-NS3 protease
.
Antiviral Res.
94
,
72
79
[PubMed]
71.
Steuer
C.
,
Gege
C.
,
Fischl
W.
,
Heinonen
K.H.
,
Bartenschlager
R.
et al.
(
2011
)
Synthesis and biological evaluation of α-ketoamides as inhibitors of the Dengue virus protease with antiviral activity in cell-culture
.
Bioorg. Med. Chem.
19
,
4067
4074
[PubMed]
72.
Bodenreider
C.
,
Beer
D.
,
Keller
T.H.
,
Sonntag
S.
et al.
(
2009
)
A fluorescence quenching assay to discriminate between specific and nonspecific inhibitors of dengue virus protease
.
Anal. Biochem.
395
,
195
204
[PubMed]
73.
Cregar-Hernandez
L.
,
Jiao
G.S.
,
Johnson
A.T.
,
Lehrer
A.T.
et al.
(
2011
)
Small molecule pan-dengue and West Nile virus NS3 protease inhibitors
.
Antivir. Chem. Chemother.
21
,
209
218
[PubMed]
74.
Tomlinson
S.M.
,
Malmstrom
R.D.
,
Russo
A.
,
Mueller
N.
,
Pang
Y.P.
et al.
(
2009
)
Structure-based discovery of dengue virus protease inhibitors
.
Antiviral Res.
82
,
110
114
[PubMed]
75.
Lai
H.
,
Dou
D.
,
Aravapalli
S.
,
Teramoto
T.
,
Lushington
G.H.
,
Mwania
T.M.
et al.
(
2013
)
Design, synthesis and characterization of novel 1,2-benzisothiazol-3(2H)- one and 1,3,4-oxadiazole hybrid derivatives: Potent inhibitors of Dengue and West Nile virus NS2B/NS3 proteases
.
Bioorg. Med. Chem.
21
,
102
113
[PubMed]
76.
Wu
H.
,
Bock
S.
,
Snitko
M.
,
Berger
T.
,
Weidner
T.
,
Holloway
S.
et al.
(
2015
)
Novel dengue virus NS2B/NS3 protease inhibitors
.
Antimicrob. Agents Chemother.
59
,
1100
1109
[PubMed]
77.
Balasubramanian
A.
,
Manzano
M.
,
Teramoto
T.
,
Pilankatta
R.
and
Padmanabhan
R.
(
2016
)
High-throughput screening for the identification of small-molecule inhibitors of the flaviviral protease
.
Antiviral Res.
134
,
6
16
[PubMed]
78.
Pambudi
S.
,
Kawashita
N.
,
Phanthanawiboon
S.
,
Omokoko
M.D.
,
Masrinoul
P.
,
Yamashita
A.
et al.
(
2013
)
A small compound targeting the interaction between nonstructural proteins 2B and 3 inhibits dengue virus replication
.
Biochem. Biophys. Res. Commun.
440
,
393
398
[PubMed]
79.
Behnam
M.A.M.
,
Graf
D.
,
Bartenschlager
R.
,
Zlotos
D.P.
et al.
(
2015
)
Discovery of nanomolar dengue and west nile virus protease inhibitors containing a 4-benzyloxyphenylglycine residue
.
J. Med. Chem.
58
,
9354
9370
[PubMed]
80.
Rothan
H.A.
,
Bahrani
H.
,
Rahman
N.A.
and
Yusof
R.
(
2014
)
Identification of natural antimicrobial agents to treat dengue infection: In vitro analysis of latarcin peptide activity against dengue virus
.
BMC Microbiol.
14
,
140
,
[PubMed]
81.
Yang
C.C.
,
Hu
H.S.
,
Wu
R.H.
,
Wu
S.-J.
et al.
(
2014
)
A novel dengue virus inhibitor, BP13944, discovered by high-Throughput screening with dengue virus replicon cells selects for resistance in the viral NS2B/NS3 protease
.
Antimicrob. Agents Chemother.
58
,
110
119
[PubMed]
82.
Wu
D.W.
,
Mao
F.
,
Ye
Y.
,
Li
J.
et al.
(
2015
)
Policresulen, a novel NS2B/NS3 protease inhibitor, effectively inhibits the replication of DENV2 virus in BHK-21 cells
.
Acta Pharmacol. Sin.
36
,
1126
1136
[PubMed]
83.
Yang
C.C.
,
Hsieh
Y.C.
,
Lee
S.J.
et al.
(
2011
)
Novel dengue virus-specific NS2B/NS3 protease inhibitor, BP2109, discovered by a high-throughput screening assay
.
Antimicrob. Agents Chemother.
55
,
229
238
[PubMed]
84.
Weigel
L.F.
,
Nitsche
C.
,
Graf
D.
,
Bartenschlager
R.
and
Klein
C.D.
(
2015
)
Phenylalanine and phenylglycine analogues as arginine mimetics in dengue protease inhibitors
.
J. Med. Chem.
58
,
7719
7733
[PubMed]
85.
Li
L.
,
Basavannacharya
C.
,
Chan
K.W.K.
,
Shang
L.
et al.
(
2015
)
Structure-guided discovery of a novel non-peptide inhibitor of dengue virus NS2B-NS3 protease
.
Chem. Biol. Drug Des.
86
,
255
264
,
Blackwell Publishing Ltd
[PubMed]
86.
Hernandez-Morales
I.
,
Geluykens
P.
,
Clynhens
M.
,
Strijbos
R.
,
Goethals
O.
,
Megens
S.
et al.
(
2017
)
Characterization of a dengue NS4B inhibitor originating from an HCV small molecule library
.
Antiviral Res.
147
,
149
158
[PubMed]
87.
Moquin
S.A.
,
Simon
O.
,
Karuna
R.
,
Lakshminarayana
S.B.
et al.
(
2021
)
NITD-688, a pan-serotype inhibitor of the dengue virus NS4B protein, shows favorable pharmacokinetics and efficacy in preclinical animal models
.
Sci. Transl. Med.
13
,
eabb2181
,
[PubMed]
88.
Kaptein
S.J.F.
,
Goethals
O.
,
Kiemel
D.
,
Marchand
A.
,
Kesteleyn
B.
et al.
(
2021
)
A pan-serotype dengue virus inhibitor targeting the NS3-NS4B interaction
.
Nature
598
,
504
509
[PubMed]
89.
Nobori
H.
,
Toba
S.
,
Yoshida
R.
,
Hall
W.W.
,
Orba
Y.
et al.
(
2018
)
Identification of Compound-B, a novel anti-dengue virus agent targeting the non-structural protein 4A
.
Antiviral Res.
155
,
60
66
[PubMed]
90.
Vernekar
S.K.v.
,
Qiu
L.
,
Zhang
J.
,
Kankanala
J.
,
Li
H.
et al.
(
2015
)
5′-silylated 3′-1,2,3-triazolyl thymidine analogues as inhibitors of West Nile Virus and Dengue virus
.
J. Med. Chem.
58
,
4016
4028
[PubMed]
91.
Bullard
K.M.
,
Gullberg
R.C.
,
Soltani
E.
,
Steel
J.J.
et al.
(
2015
)
Murine efficacy and pharmacokinetic evaluation of the flaviviral NS5 capping enzyme 2-thioxothiazolidin-4-one inhibitor BG-323
.
PloS ONE
10
,
e0130083
[PubMed]
92.
Brecher
M.
,
Chen
H.
,
Li
Z.
,
Banavali
N.K.
,
Jones
S.A.
et al.
(
2016
)
Identification and characterization of novel broad-spectrum inhibitors of the flavivirus methyltransferase
.
ACS Infectious Dis.
1
,
340
349
93.
Allard
P.M.
,
Leyssen
P.
,
Martin
M.T.
et al.
(
2012
)
Antiviral chlorinated daphnane diterpenoid orthoesters from the bark and wood of Trigonostemon cherrieri
.
Phytochemistry
84
,
160
168
[PubMed]
94.
Allard
P.M.
,
Dau
E.T.H.
,
Eydoux
C.
,
Guillemot
J.-C.
et al.
(
2011
)
Alkylated flavanones from the bark of cryptocarya chartacea as dengue virus NS5 polymerase inhibitors
.
J. Nat. Prod.
74
,
2446
2453
[PubMed]
95.
Coulerie
P.
,
Eydoux
C.
,
Hnawia
E.
,
Stuhl
L.
,
MacIuk
A.
,
Lebouvier
N.
et al.
(
2012
)
Biflavonoids of Dacrydium balansae with potent inhibitory activity on dengue 2 NS5 polymerase
.
Planta Med.
78
,
672
677
[PubMed]
96.
Cannalire
R.
,
Ki Chan
K.W.
,
Burali
M.S.
et al.
(
2020
)
Pyridobenzothiazolones Exert Potent Anti- Dengue Activity by Hampering Multiple Functions of NS5 Polymerase
.
ACS Med. Chem. Lett.
11
,
773
782
[PubMed]
97.
Bourjot
M.
,
Leyssen
P.
,
Eydoux
C.
,
Guillemot
J.C.
et al.
(
2012
)
Chemical constituents of Anacolosa pervilleana and their antiviral activities
.
Fitoterapia
83
,
1076
1080
[PubMed]
98.
Arora
R.
,
Liew
C.W.
,
Soh
T.S.
et al.
(
2020
)
Two RNA Tunnel Inhibitors Bind in Highly Conserved Sites in Dengue Virus NS5 Polymerase: Structural and Functional Studies
.
J. Virol.
94
,
e01130
e01220
[PubMed]
99.
Olsen
D.B.
,
Eldrup
A.B.
,
Bartholomew
L.
et al.
(
2004
)
A 7-deaza-adenosine analog is a potent and selective inhibitor of hepatitis C virus replication with excellent pharmacokinetic properties
.
Antimicrob. Agents Chemother.
48
,
3944
3953
[PubMed]
100.
Vernachio
J.H.
,
Bleiman
B.
,
Bryant
K.D.
et al.
(
2011
)
INX-08189, a phosphoramidate prodrug of 6-O-methyl-2′-C-methyl guanosine, is a potent inhibitor of hepatitis C virus replication with excellent pharmacokinetic and pharmacodynamic properties
.
Antimicrob. Agents Chemother.
55
,
1843
1851
[PubMed]
101.
Warren
T.K.
,
Wells
J.
,
Panchal
R.G.
et al.
(
2014
)
Protection against filovirus diseases by a novel broad-spectrum nucleoside analogue BCX4430
.
Nature
508
,
402
405
[PubMed]
102.
Chen
Y.-L.
,
Abdul Ghafar
N.
,
Karuna
R.
et al.
(
2014
)
Activation of peripheral blood mononuclear cells by dengue virus infection depotentiates balapiravir
.
J. Virol.
88
,
1740
1747
[PubMed]
103.
Lee
J.C.
,
Tseng
C.K.
,
Wu
Y.H.
et al.
(
2015
)
Characterization of the activity of 2′-C-methylcytidine against dengue virus replication
.
Antiviral Res.
116
,
1
9
[PubMed]
104.
Lim
S.P.
,
Noble
C.G.
,
Seh
C.C.
et al.
(
2016
)
Potent allosteric dengue virus NS5 polymerase inhibitors: mechanism of action and resistance profiling
.
PLoS Pathog.
12
,
e1005737
[PubMed]
105.
Mahajan
S.
,
Choudhary
S.
,
Kumar
P.
et al.
(
2021
)
Antiviral strategies targeting host factors and mechanisms obliging +ssRNA viral pathogens
.
Bioorg. Med. Chem.
46
,
116356
[PubMed]
106.
Chen
J.M.
,
Fan
Y.C.
,
Lin
J.W.
et al.
(
2017
)
Bovine lactoferrin inhibits dengue virus infectivity by interacting with heparan sulfate, low-density lipoprotein receptor, and DC-SIGN
.
Int. J. Mol. Sci.
18
,
1957
[PubMed]
107.
Alen
M.M.F.
,
de Burghgraeve
T.
,
Kaptein
S.J.F.
et al.
(
2011
)
Broad antiviral activity of carbohydrate-binding agents against the four serotypes of dengue virus in monocyte-derived dendritic cells
.
PloS ONE
6
,
e21658
[PubMed]
108.
Recalde-Reyes
D.P.
,
Rodríguez-Salazar
C.A.
,
Castaño-Osorio
J.C.
et al.
(
2022
)
CD44 antiviral peptide as an inhibitor of the protein-protein interaction in dengue virus invasion
.
Peptides
153
,
170797
,
PD1
[PubMed]
109.
Modhiran
N.
,
Gandhi
N.S.
,
Wimmer
N.
et al.
(
2019
)
Dual targeting of dengue virus virions and NS1 protein with the heparan sulfate mimic PG545
.
Antiviral Res.
168
,
121
127
[PubMed]
110.
Wang
Q.Y.
,
Kondreddi
R.R.
,
Xie
X.
et al.
(
2011
)
A translation inhibitor that suppresses dengue virus in vitro and in vivo
.
Antimicrob. Agents Chemother.
55
,
4072
4080
[PubMed]
111.
Low
J.S.Y.
,
Wu
K.X.
,
Chen
K.C.
et al.
(
2011
)
Narasin, a novel antiviral compound that blocks dengue virus protein expression
.
Antivir. Ther.
16
,
1203
1218
[PubMed]
112.
Carocci
M.
and
Yang
P.L.
(
2016
)
Lactimidomycin is a broad-spectrum inhibitor of dengue and other RNA viruses
.
Antiviral Res.
128
,
57
62
[PubMed]
113.
Lee
J.K.
,
Chui
J.L.M.
,
Lee
R.C.H.
et al.
(
2019
)
Antiviral activity of ST081006 against the dengue virus
.
Antiviral Res.
171
,
104589
[PubMed]
114.
Kato
F.
,
Ishida
Y.
,
Oishi
S.
et al.
(
2016
)
Novel antiviral activity of bromocriptine against dengue virus replication
.
Antiviral Res.
131
,
141
147
[PubMed]
115.
Chu
J.J.H.
and
Yang
P.L.
(
2006
)
c-Src protein kinase inhibitors block assembly and maturation of dengue virus
.
Harvard Medical School
104
116.
Whitby
K.
,
Pierson
T.C.
,
Geiss
B.
,
Lane
K.
et al.
(
2005
)
Castanospermine, a potent inhibitor of dengue virus infection in vitro and in vivo
.
J. Virol.
79
,
8698
8706
[PubMed]
117.
Raekiansyah
M.
,
Mori
M.
,
Nonaka
K.
et al.
(
2017
)
Identification of novel antiviral fungus-derived brefeldin A against dengue viruses
.
Tropical Med. Health
45
,
118.
Hidari
K.I.P.J.
,
Takahashi
N.
,
Arihara
M.
,
Nagaoka
M.
et al.
(
2008
)
Structure and anti-dengue virus activity of sulfated polysaccharide from a marine alga
.
Biochem. Biophys. Res. Commun.
376
,
91
95
[PubMed]
119.
Lee
E.
,
Pavy
M.
,
Young
N.
,
Freeman
C.
et al.
(
2006
)
Antiviral effect of the heparan sulfate mimetic, PI-88, against dengue and encephalitic flaviviruses
.
Antiviral Res.
69
,
31
38
[PubMed]
120.
Talarico
L.B.
,
Pujol
C.A.
,
Zibetti
R.G.M.
et al.
(
2005
)
The antiviral activity of sulfated polysaccharides against dengue virus is dependent on virus serotype and host cell
.
Antiviral Res.
66
,
103
110
[PubMed]
121.
Rees
C.R.
,
Costin
J.M.
,
Fink
R.C.
,
McMichael
S.F.
et al.
(
2008
)
In vitro inhibition of dengue polysaccharides against dengue virus is dependent on virus serotype and host cell. chemistries
.
Antiviral Res.
80
,
135
142
[PubMed]
122.
Pujol
C.A.
,
Ray
S.
,
Ray
B.
et al.
(
2012
)
Antiviral activity against dengue virus of diverse classes of algal sulfated polysaccharides
.
Int. J. Biol. Macromol.
51
,
412
416
[PubMed]
123.
Ichiyama
K.
,
Gopala Reddy
S.B.
,
Zhang
L.F.
et al.
(
2013
)
Sulfated polysaccharide, curdlan sulfate, efficiently prevents entry/fusion and restricts antibody-dependent enhancement of dengue virus infection in vitro: a possible candidate for clinical application
.
PLoS Negl. Trop. Dis.
7
,
e2188
[PubMed]
124.
Kato
D.
,
Era
S.
,
Watanabe
I.
et al.
(
2010
)
Antiviral activity of chondroitin sulphate E targeting dengue virus envelope protein
.
Antiviral Res.
88
,
236
243
[PubMed]
125.
Cui
X.
,
Wu
Y.
,
Fan
D.
et al.
(
2018
)
Peptides P4 and P7 derived from E protein inhibit entry of dengue virus serotype 2 via interacting with β3 integrin
.
Antiviral Res.
155
,
20
27
[PubMed]
126.
Peng
T.
,
Zhang
J.
and
An
J.
(
2004
)
The animal models for dengue virus infection
.
Dengue Bulletin
28
168
173
WHO IRIS page: https://iris.who.int/handle/10665/163991
127.
Byrne
A.B.
,
García
A.G.
,
Brahamian
J.M.
,
Mauri
A.
,
Ferretti
A.
,
Polack
F.P.
et al.
(
2021
)
A murine model of dengue virus infection in suckling C57BL/6 and BALB/c mice
.
Animal Models Exp. Med.
4
,
16
26
128.
Chokephaibulkit
K.
,
Chien
Y.W.
,
Abubakar
S.
,
Pattanapanyasat
K.
and
Perng
G.C.
(
2020
)
Use of animal models in studying roles of antibodies and their secretion cells in dengue vaccine development
.
Viruses
12
,
MDPI AG
[PubMed]
129.
Zou
J.
,
Xie
X.
,
Wang
Q.-Y.
et al.
(
2015
)
Characterization of dengue virus NS4A and NS4B protein interaction
.
J. Virol.
89
,
3455
3470
[PubMed]
130.
Zompi
S.
and
Harris
E.
(
2012
)
Animal models of dengue virus infection
.
Viruses
4
,
62
82
[PubMed]
131.
Zellweger
R.M.
and
Shresta
S.
(
2014
)
Mouse models to study dengue virus immunology and pathogenesis
.
Front. Immunol.
5
,
151
,
Frontiers Research Foundation
[PubMed]
132.
Kayesh
M.E.H.
and
Tsukiyama-Kohara
K.
(
2022
)
Mammalian animal models for dengue virus infection: a recent overview
.
Arch. Virol
167
,
31
44
,
Springer
[PubMed]
133.
Na
W.
,
Yeom
M.
,
Choi
I.K.
,
Yook
H.
and
Song
D.
(
2017
)
Animal models for dengue vaccine development and testing
.
Clin. Exp. Vaccine Res.
6
,
104
110
,
Korean Vaccine Society
[PubMed]
134.
Byrne
A.B.
,
García
C.C.
,
Damonte
E.B.
and
Talarico
L.B.
(
2022
)
Murine models of dengue virus infection for novel drug discovery
.
Expert Opin. Drug Discovery
17
,
397
412
135.
Shresta
S.
,
Sharar
K.L.
,
Prigozhin
D.M.
,
Beatty
P.R.
and
Harris
E.
(
2006
)
Murine model for dengue virus-induced lethal disease with increased vascular permeability
.
J. Virol.
80
,
10208
10217
[PubMed]
136.
Schul
W.
,
Liu
W.
,
Xu
H.Y.
,
Flamand
M.
and
Vasudevan
S.G.
(
2007
)
A dengue fever viremia model in mice shows reduction in viral replication and suppression of the inflammatory response after treatment with antiviral drugs
.
J. Infect. Dis.
195
,
665
674
[PubMed]
137.
Onlamoon
N.
,
Noisakran
S.
,
Hsiao
H.-M.
,
Duncan
A.
,
Villinger
F.
,
Ansari
A.A.
et al.
(
2010
)
Dengue virus-induced hemorrhage in a nonhuman primate model
.
Blood
115
,
1823
1834
[PubMed]
138.
Estes
J.D.
,
Wong
S.W.
and
Brenchley
J.M.
(
2018
)
Nonhuman primate models of human viral infections
.
Nat. Rev. Immunol.
18
,
390
404
,
Nature Publishing Group
[PubMed]
139.
Althouse
B.M.
,
Durbin
A.P.
,
Hanley
K.A.
,
Halstead
S.B.
,
Weaver
S.C.
and
Cummings
D.A.T.
(
2014
)
Viral kinetics of primary dengue virus infection in non-human primates: a systematic review and individual pooled analysis
.
Virology
452-453
,
237
246
[PubMed]
140.
Azami
N.A.M.
,
Takasaki
T.
,
Kurane
I.
and
Moi
M.L.
(
2020
)
Non-human primate models of dengue virus infection: A comparison of viremia levels and antibody responses during primary and secondary infection among old world and new world monkeys
.
Pathogens
9
,
1
16
,
MDPI AG
141.
Carrington
L.B.
,
Ponlawat
A.
,
Nitatsukprasert
C.
,
Khongtak
P.
,
Sunyakumthorn
P.
,
Ege
C.A.
et al.
(
2020
)
Virological and immunological outcomes in rhesus monkeys after exposure to dengue virus-infected aedes aegypti mosquitoes
.
Am. J. Trop. Med. Hyg.
103
,
112
119
[PubMed]
142.
Barban
V.
,
Mantel
N.
,
de Montfort
A.
,
Pagnon
A.
,
Pradezynski
F.
,
Lang
J.
et al.
(
2018
)
Improvement of the Dengue Virus (DENV) nonhuman primate model via a reverse translational approach based on dengue vaccine clinical efficacy data against DENV-2 and-4
.
J. Virol.
92
,
e00440
e00518
[PubMed]
143.
Cassetti
M.C.
and
Thomas
S.J.
(
2014
)
Dengue human infection model: introduction
.
J. Infect. Dis.
209
,
Oxford University Press
[PubMed]
144.
Clark
K.B.
,
Onlamoon
N.
,
Hsiao
H.-M.
,
Perng
G.C.
and
Villinger
F.
(
2013
)
Can non-human primates serve as models for investigating dengue disease pathogenesis?
Front. Microbiol.
4
,
305
[PubMed]
145.
Balsitis
S.J.
,
Williams
K.L.
,
Lachica
R.
,
Flores
D.
,
Kyle
J.L.
,
Mehlhop
E.
et al.
(
2010
)
Lethal antibody enhancement of dengue disease in mice is prevented by Fc modification
.
PLoS Pathog.
6
,
e1000790
[PubMed]
146.
Shimizu
H.
,
Saito
A.
,
Mikuni
J.
,
Nakayama
E.E.
,
Koyama
H.
,
Honma
T.
et al.
(
2019
)
Discovery of a small molecule inhibitor targeting dengue virus NS5 RNA-dependent RNA polymerase
.
PLoS Negl. Trop. Dis.
13
,
e0007894
[PubMed]
147.
Kayesh
M.E.H.
,
Sanada
T.
,
Kohara
M.
and
Tsukiyama-Kohara
K.
(
2021
)
Tree shrew as an emerging small animal model for human viral infection: A recent overview
.
Viruses
13
,
1641
,
MDPI
[PubMed]
148.
Cassetti
M.C.
,
Durbin
A.
,
Harris
E.
,
Rico-Hesse
R.
,
Roehrig
J.
,
Rothman
A.
et al.
(
2010
)
Report of an NIAID workshop on dengue animal models
.
Vaccine
28
,
4229
4234
[PubMed]
149.
Watanabe
S.
,
Low
J.G.H.
and
Vasudevan
S.G.
(
2018
)
Preclinical antiviral testing for dengue virus infection in mouse models and its association with clinical studies
.
ACS Infectious Dis.
4
,
1048
1057
,
American Chemical Society
150.
Manoff
S.B.
,
George
S.L.
,
Bett
A.J.
,
Yelmene
M.L.
,
Dhanasekaran
G.
,
Eggemeyer
L.
et al.
(
2015
)
Preclinical and clinical development of a dengue recombinant subunit vaccine
.
Vaccine
33
,
7126
7134
[PubMed]
151.
Lee
M.F.
,
Wu
Y.S.
and
Poh
C.L.
(
2023
)
Molecular Mechanisms of Antiviral Agents against Dengue Virus
.
Viruses
15
,
705
,
MDPI
[PubMed]
152.
Monteiro
J.M.C.
,
Oliveira
M.D.
,
Dias
R.S.
,
Nacif-Marçal
L.
,
Feio
R.N.
,
Ferreira
S.O.
et al.
(
2018
)
The antimicrobial peptide HS-1 inhibits dengue virus infection
.
Virology
514
,
79
87
[PubMed]
153.
Radoshitzky
S.R.
,
Iversen
P.
,
Lu
X.
,
Zou
J.
,
Kaptein
S.J.F.
,
Stuthman
K.S.
et al.
(
2023
)
Expanded profiling of Remdesivir as a broad-spectrum antiviral and low potential for interaction with other medications in vitro
.
Sci. Rep.
13
,
3131
[PubMed]
154.
Konkolova
E.
,
Dejmek
M.
,
Hřebabecký
H.
,
Šála
M.
,
Böserle
J.
,
Nencka
R.
et al.
(
2020
)
Remdesivir triphosphate can efficiently inhibit the RNA-dependent RNA polymerase from various flaviviruses
.
Antiviral Res.
182
,
104899
[PubMed]
155.
Botta
L.
,
Rivara
M.
,
Zuliani
V.
and
Radi
M.
(
1996
)
Drug repurposing approaches to fight Dengue virus infection and related diseases
.
156.
Tan
Y.L.
,
Tan
K.S.W.
,
Chu
J.J.H.
and
Chow
V.T.
(
2021
)
Combination treatment with remdesivir and ivermectin exerts highly synergistic and potent antiviral activity against murine coronavirus infection
.
Front. Cell. Infection Microbiol.
11
,
700502
157.
Xu
T.L.
,
Han
Y.
,
Liu
W.
,
Pang
X.Y.
,
Zheng
B.
et al.
(
2018
)
Antivirus effectiveness of ivermectin on dengue virus type 2 in Aedes albopictus
.
PLoS Negl. Trop. Dis.
12
,
e0006934
[PubMed]
158.
Suputtamongkol
Y.
,
Avirutnan
P.
,
Mairiang
D.
,
Angkasekwinai
N.
,
Niwattayakul
K.
,
Yamasmith
E.
et al.
(
2021
)
Ivermectin accelerates circulating nonstructural protein 1 (NS1) clearance in adult dengue patients: a combined phase 2/3 randomized double-blinded placebo controlled trial
.
Clin. Infect. Dis.
72
,
E586
E593
[PubMed]
159.
Niranjan
R.
,
Saxena
N.
and
Das
A.
(
2024
)
Dengue control, if not by vaccination and vector strategies, then possibly by therapeutics
.
Lancet Infect. Dis.
24
,
e144
,
Elsevier Ltd
[PubMed]
160.
Denolly
S.
,
Guo
H.
,
Martens
M.
,
Płaszczyca
A.
,
Scaturro
P.
,
Prasad
V.
et al.
(
2023
)
Dengue virus NS1 secretion is regulated via importin-subunit β1 controlling expression of the chaperone GRp78 and targeted by the clinical drug ivermectin
.
MBio
14
,
e0144123
[PubMed]
161.
Palanichamy Kala
M.
,
st. John
A.L.
and
Rathore
A.P.S.
(
2023
)
Dengue: update on clinically relevant therapeutic strategies and vaccines
.
Curr. Treatment Options Infectious Dis.
15
,
27
52
162.
Glasner
D.R.
,
Ratnasiri
K.
,
Puerta-Guardo
H.
,
Espinosa
D.A.
,
Beatty
P.R.
and
Harris
E.
(
2017
)
Dengue virus NS1 cytokine-independent vascular leak is dependent on endothelial glycocalyx components
.
PLoS Pathog.
13
,
e1006673
[PubMed]
163.
Kao
J.C.
,
HuangFu
W.C.
,
Tsai
T.T.
,
Ho
M.R.
,
Jhan
M.K.
,
Shen
T.J.
et al.
(
2018
)
The antiparasitic drug niclosamide inhibits dengue virus infection by interfering with endosomal acidification independent of mTOR
.
PLoS Negl. Trop. Dis.
12
,
e0006715
[PubMed]
164.
Jung
E.
,
Nam
S.
,
Oh
H.
,
Jun
S.
,
Ro
H.J.
,
Kim
B.
et al.
(
2019
)
Neutralization of acidic intracellular vesicles by niclosamide inhibits multiple steps of the dengue virus life cycle in vitro
.
Sci. Rep.
9
,
8682
[PubMed]
165.
Xu
J.
,
Shi
P.Y.
,
Li
H.
and
Zhou
J.
(
2020
)
Broad Spectrum Antiviral Agent Niclosamide and Its Therapeutic Potential
.
ACS Infectious Dis.
6
,
909
915
,
American Chemical Society
166.
Goethals
O.
,
Voge
N.v.
,
Kesteleyn
B.
,
Chaltin
P.
,
Jinks
T.
,
de Marez
T.
et al.
(
2023
)
A pan-serotype antiviral to prevent and treat dengue: A journey from discovery to clinical development driven by public-private partnerships
.
Antiviral Res.
210
,
105495
[PubMed]
167.
Good
S.S.
,
Shannon
A.
,
Lin
K.
,
Moussa
A.
,
Julander
J.G.
,
la Colla
P.
et al.
(
2021
)
Evaluation of AT-752, a double prodrug of a guanosine nucleotide analog with in vitro and in vivo activity against dengue and other flaviviruses
.
Antimicrob. Agents Chemother.
65
,
e0098821
[PubMed]
168.
Zhou
X.-J.
,
Lickliter
J.
,
Montrond
M.
,
Ishak
L.
,
Pietropaolo
K.
,
James
D.
et al.
(
2024
)
First-in-human trial evaluating safety and pharmacokinetics of AT-752, a novel nucleotide prodrug with pan-serotype activity against dengue virus
.
Antimicrob. Agents Chemother.
68
,
e0161523
[PubMed]
169.
Franco
E.J.
,
de Mello
C.P.P.
and
Brown
A.N.
(
2021
)
Antiviral evaluation of uv-4b and interferon-alpha combination regimens against dengue virus
.
Viruses
13
,
771
[PubMed]
170.
Qiu
L.
,
Patterson
S.E.
,
Bonnac
L.F.
and
Geraghty
R.J.
(
2018
)
Nucleobases and corresponding nucleosides display potent antiviral activities against dengue virus possibly through viral lethal mutagenesis
.
PLoS Negl. Trop. Dis.
12
,
e0006421
[PubMed]
171.
Nguyen
N.M.
,
Tran
C.N.B.
,
Phung
L.K.
,
Duong
K.T.H.
,
Huynh
H.L.A.
,
Farrar
J.
et al.
(
2013
)
A randomized, double-blind placebo controlled trial of balapiravir, a polymerase inhibitor, in Adult dengue patients
.
J. Infect. Dis.
207
,
1442
1450
[PubMed]
172.
Sung
C.
,
Wei
Y.
,
Watanabe
S.
,
Lee
H.S.
,
Khoo
Y.M.
,
Fan
L.
et al.
(
2016
)
Extended evaluation of virological, immunological and pharmacokinetic endpoints of CELADEN: a randomized, placebo-controlled trial of celgosivir in dengue fever patients
.
PLoS Negl. Trop. Dis.
10
,
e0004851
[PubMed]
173.
Puerta-Guardo
H.
,
de la Cruz Hernández
S.I.
,
Rosales
V.H.
,
Ludert
J.E.
and
del Angel
R.M.
(
2012
)
The 1α,25-dihydroxy-vitamin D3 reduces dengue virus infection in human myelomonocyte (U937) and hepatic (Huh-7) cell lines and cytokine production in the infected monocytes
.
Antiviral Res.
94
,
57
61
[PubMed]
174.
Ejembi
J.
,
Garba
I.
,
Emma-Ukaegbu
U.C.
,
Omale
A.
,
Dogo
B.
and
Taiwo
L.
(
2020
)
Knowledge and attitude of community members and health care workers on Lassa fever during an outbreak in Kogi State, Nigeria 2016
.
Int. J. Infect. Dis.
101
,
259
260
[PubMed]
175.
Khakpoor
A.
,
Panyasrivanit
M.
,
Wikan
N.
and
Smith
D.R.
(
2009
)
A role for autophagolysosomes in dengue virus 3 production in HepG2 cells
.
J. Gen. Virol.
90
,
1093
1103
[PubMed]
176.
Limthongkul
J.
,
Akkarasereenon
K.
,
Yodweerapong
T.
,
Songthammawat
P.
,
Tong-Ngam
P.
,
Tubsuwan
A.
et al.
(
2023
)
Novel potent autophagy inhibitor Ka-003 inhibits dengue virus replication
.
Viruses
15
,
2012
[PubMed]

Author notes

*

These authors contributed equally in this work.

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