Virus Nonstructural Protein Research Articles

Ubiquitin-like modifier-activating enzyme 1 interacts with Zika virus NS5 and promotes viral replication in the infected cell.

Translation errors, impaired folding or environmental stressors (e.g. infection) can all lead to an increase in the presence of misfolded proteins. These activate cellular responses to their removal, including intracellular protein degradation activities. Protein ubiquitylation is involved in two major degradation pathways, the ubiquitin-proteasome system and selective autophagy. In humans, the ubiquitin-like modifier-activating enzyme 1 (UBA1) is the primary E1 enzyme in the ubiquitin conjugation cascade. Viruses have evolved to exploit protein degradation pathways to complete their infection cycles. Zika virus (ZIKV) is an emerging orthoflavivirus causing serious neurologic disorders in neonates (congenital microcephaly) and adults (Guillain-Barré syndrome). Non-structural protein 5 (NS5), the largest and most conserved protein in the orthoflaviviruses, catalyses the synthesis and capping of new viral genomes. In addition to viral RNA replication in the cytoplasm, ZIKV NS5 is translocated into the nucleus to interfere with host antiviral responses. Here, we demonstrate that ZIKV NS5 co-immunoprecipitates with cellular UBA1. Immunofluorescence assays suggest that this interaction takes place primarily in the nucleus of an infected cell, although colocalization of both proteins is also detected in the cytosol. RNA interference-mediated depletion of UBA1 leads to reduced virus titres in the infected cells, while transient overexpression of UBA1 favours faster replication kinetics, with higher virus titres and protein levels detected. Moreover, UBA1-targeting drugs cause significant drops in virus infectivity. These results support a proviral role for UBA1 during ZIKV infection and encourage the potential use of inhibitors against this enzyme or its NS5-interacting epitopes as potential therapeutic targets.

RTP4 restricts influenza A virus infection by targeting the viral NS1 protein.

The influenza A virus evades the host innate immune response to establish infection by inhibiting RIG-I activation through its nonstructural protein 1 (NS1). Here, we reported that receptor-transporting protein 4 (RTP4), an interferon-stimulated gene (ISG), targets NS1 to inhibit influenza A virus infection. Depletion of RTP4 significantly increased influenza A virus multiplication, while NS1-deficient viruses were unaffected. Mechanistically, RTP4 interacts with NS1 in an RNA-dependent manner and sequesters it from the TRIM25-RIG-I complex, thereby restoring TRIM25-mediated RIG-I K63-linked ubiquitination and subsequent activation of IRF3. Antiviral activity of RTP4 requires the evolutionarily conserved CXXC motifs and an H149 residue in the zinc finger domain, mutations of which disrupted RTP4-NS1 interaction and abrogated the ability of RTP4 to rescue RIG-I-mediated signaling. Collectively, our findings provided insights into the mechanism by which an ISG restricts influenza A virus replication by reactivating host antiviral signaling.

Efficient Expression of Oropouche Virus Nonstructural Proteins NSs and NSm.

Oropouche fever, a mosquito- or midge-borne emerging zoonotic disease endemic to South and Central America, manifests as a dengue-like acute febrile illness with occasional occurrences of meningitis or meningoencephalitis. The causative agent, Oropouche virus (OROV), belongs to the genus Orthobunyavirus within the family Peribunyaviridae. Its tripartite negative-sense RNA genome comprises small (S), medium (M), and large (L) segments, encoding structural N, Gn/Gc, and L proteins, respectively. Additionally, the S- and M-segments encode nonstructural proteins: NSs and NSm, which may act as virulence factors. OROV NSs functions as an interferon antagonist with an unknown mechanism, while the roles of OROV NSm remain elusive. This chapter introduces efficient expression systems for OROV NSm and NSs proteins. Validating the presence of a signal peptide at the N-terminus of NSm protein is essential for its expression. Furthermore, expressing OROV NSs protein independently of an RNA polymerase II promoter is crucial to prevent restricted gene expression, potentially caused by NSs inhibiting cellular RNA polymerase II, as observed in closely related bunyavirus NSs proteins. These protein expression strategies offer insights into the molecular characterization of OROV NSm and NSs proteins, facilitating a deeper understanding of their virulence mechanisms.

Tertiary Structures of Haseki Tick Virus Nonstructural Proteins Are Similar to Those of Orthoflaviviruses.

Currently, a large number of novel tick-borne viruses potentially pathogenic to humans are discovered. Studying many of them by classical methods of virology is difficult due to the absence of live viral particles or a sufficient amount of their genetic material. In this case, the use of modern methods of bioinformatics and synthetic and structural biology can help. Haseki tick virus (HSTV) is a recently discovered tick-borne unclassified ssRNA(+) virus. HSTV-positive patients experienced fever and an elevated temperature. However, at the moment, there is no information on the tertiary structure and functions of its proteins. In this work, we used AlphaFold 3 and other bioinformatic tools for the annotation of HSTV nonstructural proteins, based on the principle that the tertiary structure of a protein is inextricably linked with its molecular function. We were the first to obtain models of tertiary structures and describe the putative functions of HSTV nonstructural proteins (NS3 helicase, NS3 protease, NS5 RNA-dependent RNA-polymerase, and NS5 methyltransferase), which play a key role in viral genome replication. Our results may help in further taxonomic identification of HSTV and the development of direct-acting antiviral drugs, POC tests, and vaccines.

Flaviviruses induce ER-specific remodelling of protein synthesis.

Flaviviruses orchestrate a unique remodelling of the endoplasmic reticulum (ER) to facilitate translation and processing of their polyprotein, giving rise to virus replication compartments. While the signal recognition particle (SRP)-dependent pathway is the canonical route for ER-targeting of nascent cellular membrane proteins, it is unknown whether flaviviruses rely on this mechanism. Here we show that Zika virus bypasses the SRP receptor via extensive interactions between the viral non-structural proteins and the host translational machinery. Remarkably, Zika virus appears to maintain ER-localised translation via NS3-SRP54 interaction instead, unlike other viruses such as influenza. Viral proteins engage SRP54 and the translocon, selectively enriching for factors supporting membrane expansion and lipid metabolism while excluding RNA binding and antiviral stress granule proteins. Our findings reveal a sophisticated viral strategy to rewire host protein synthesis pathways and create a replication-favourable subcellular niche, providing insights into viral adaptation.

Dengue virus non-structural protein 1 binding to thrombin as a dengue severity marker: Comprehensive patient analysis in south Taiwan.

Previously we identified a complex of non-structural protein (NS) 1 - Thrombin (NST) in dengue infected patients. Here, we investigated how the concentration of NS1 and NST differ in various dengue severity levels as well as their demographic and clinical features. Several comorbid (hypertension, diabetes, and chronic renal failure) often found in dengue patients were also measured and analyzed. A total of 86 dengue patients (52 not severe and 34 severe), were enrolled and had their blood taken. Blood samples were further verified for clinical blood parameters, including liver and renal function tests and serologic assays (NS1 and NST). Patients' severity was grouped based on WHO 2009 classification, which separates patients into dengue without warning signs (DNWS), dengue with warning signs (DWWS), and severe dengue (SD). DWWS is explained as DNWS with warning signs (persistent abdominal pain, persistent vomiting, liver enlargement, bleeding (any kind), fatigue, and restlessness). SD are those with severe plasma leakage, severe bleeding, or severe organ impairment. Multivariate regression analysis was used to predict the role of NST on the dengue severity development and receiver operating characteristic (AUROC) test was utilized to evaluate separability. The analysis revealed that NS1 significantly impacts the disease outcome (p 0.018, OR=2.467 (1.171-5.197)) but not beyond the effect through NST (p 0.108, OR=0.085 (0.004-1.719)). We also prove that NST was a better severity biomarker compared to NS1, as it can predict progression from DNWS to DWWS (AUC: NS1=0.771∗∗, NST=0.81∗∗) and SD (AUC: NS1=0.607, NST=0.754∗) significantly. This finding suggests the importance of NST in mediating the NS1 effect to promote dengue severity progression and its promising capability as an acute stage dengue severity biomarker.

A multiscale in silico approach to impede the interaction between Dengue NS1 and Human RPL18, aiming to suppress the Dengue viral translation and proliferation

ABSTRACT The Non-Structural protein 1 (NS1) of the Dengue virus is a crucial viral protein that plays a key role in host evasion and viral replication. The present study explores the pathophysiology of the host during the interaction with the viral protein via computational methods like protein–protein docking, virtual screening, and molecular dynamic simulation. Therefore, in this study we have focused on Dengue NS1 and the Human RPL18, to explore the binding mechanism and study their importance in viral proliferation. The results provided an insight into the vital amino acids of DENV NS1 (Gln_70 Glu_74 and Gly_161) which are responsible for viral-host interaction. The screening results showed that the Enamine_2436, NCI_99799, Malarial_19966, and FDA_54, had the strongest interaction with a docking score of −10.71, −8.11, −7.78, and −7.19 kcal/mol. In addition to the screening, the efficacy of the leads was validated through HOMO–LUMO studies. The Molecular dynamics simulation, PCA/FEL, and MMPBSA analysis showed that the Malarial_19966 maintained overall stability and binding affinity when compared to other leads. Hence the study comprehensively provides an insight into the biological phenomena of Dengue virus NS1 binding with Human RPL18 protein, along with possible inhibitors to suppress the Dengue viral translation and proliferation.

Enhancement of systemic and lung-localized CD4<sup>+</sup> T-cell immune responses by truncation of NS1 protein of a seasonal live influenza vaccine strain

Introduction. There is a large variety of licensed influenza vaccines worldwide, but their common limitation is rather narrow specificity and inability to protect against antigenic-drift variants of influenza virus. Therefore, optimization of immunogenic and cross-protective properties of licensed influenza vaccines is an urgent priority of public health agenda. One such approach is to modulate the immunogenic properties of live attenuated influenza vaccine (LAIV) by truncating the open reading frame of influenza virus non-structural protein 1 (NS1). The main objective of this study is to evaluate the immunogenic properties of the H1N1 seasonal LAIV strain by truncation of the NS1 protein to 126 amino acides. Materials and methods. Using reverse genetics technique, two H1N1 LAIV strains with full-length and truncated NS1 protein with three consecutive stop codons added after the 126th amino acid residue were obtained.C57BL/6J mice were immunized intranasally with the vaccine candidates, twice at a three-week interval. Seven days after the second immunization, cells were isolated from spleen and lung tissues and stimulated with whole wild-type H1N1 influenza virus. Levels of systemic and tissue-resident cytokine-producing CD4+ and CD8+ memory T cells were assessed by intracellular cytokine staining assay with flow cytometry. Replication of engineered vaccine strains in in vitro and in vivo systems was also evaluated. Results. Truncation of NS1 protein of the LAIV strain significantly increased the levels of virus-specific CD4+ effector memory T cells in spleens and the levels of CD4+ tissue-resident memory T cells in lungs of mice after two-dose immunization, indicating a higher potential for protection against influenza infection of the LAIV NS126 vaccine strain compared to the classical variant of LAIV. Importantly, the LAIV NS126 strain also had a more pronounced attenuated phenotype in mice than its classical counterpart.

Investigating the effect of linker peptides on the fragmentation of Fc-fusion proteins in transient gene expression of mammalian cells

Protein fragmentation is a critical quality attribute for Fc-fusion protein production in mammalian cells. In the production of viral non-structural proteins as the form of Fc-fusion protein, fragmentation of Fc-fusion proteins occurred in two transient gene expression (TGE) systems with human embryonic kidney (HEK) 293 and Chinese hamster ovary (CHO) cells. The introduction of a flexible empirical linker reduced fragmentation in HEK293 cells, but not in CHO cells. Additionally, two rigid empirical linkers failed to restore impaired Fc-fusion proteins in CHO cells. In vitro incubation assay using conditioned culture medium and cultures supplemented with protease inhibitor cocktail suggest that fragmentation of Fc-fusion proteins in CHO cells may be due to various host cell proteins released into the culture medium. These findings suggest that the introduction of linker peptides can improve the fragmentation of Fc-fusion proteins in mammalian cells, but exhibit different fragment patterns depending on the cell type.

A coronaviral pore-replicase complex links RNA synthesis and export from double-membrane vesicles.

Coronavirus-infected cells contain double-membrane vesicles (DMVs) that are key for viral RNA replication and transcription, perforated by hexameric pores connecting the vesicular lumen to the cytoplasm. How pores form and traverse two membranes, and how DMVs organize RNA synthesis, is unknown. Using structure prediction and functional assays, we show that the nonstructural viral membrane protein nsp4 is the key pore organizer, spanning the double membrane and forming most of the pore lining. Nsp4 interacts with nsp3 on the cytoplasmic side and with the viral replicase inside the DMV. Newly synthesized mRNAs exit the DMV into the cytoplasm, passing through a narrow ring of conserved nsp4 residues. Steric constraints imposed by the ring predict that modified nucleobases block mRNA transit, resulting in broad-spectrum anticoronaviral activity.

Chromatin mimicry by human JC virus.

Chronically persistent viruses are integral components of the organismal ecosystem in humans and animals 1 2 . Many of these viruses replicate and accumulate within the cell nucleus 3 . The nuclear location allows viruses to evade cytoplasmic host viral sensors and promotes viral replication 4 . One of the unexplored and puzzling aspects of the viral nuclear lifecycle involves the virus's ability to deal with the physical constraints of nuclear architecture. To replicate and accumulate within the nucleus in large numbers sufficient for infection spreading, DNA viruses need to overcome the spatial limitations imposed by chromatin and the nuclear matrix. We found that one of the most widespread and potentially lethal human viruses, the JC polyomavirus 5 , interferes with nuclear heterochromatin to create virus-occupied space. The JC virus's impact on heterochromatin is mediated by the viral nonstructural protein, Agnoprotein (Agno). Agno's interference with heterochromatin is governed by structurally diverse mimics of host epigenetic regulators that facilitate virus-induced chromatin reorganization and a dramatic decline in nuclear stiffness in the infected cells. The JCV epigenetic mimicry is critical for the virus infection, as evident from reduced replication of mimic-mutant viruses. Our data suggest that modulation of nuclear mechanical properties is a novel strategy enabling chronicity of the JC and possibly other nuclear virus infections.

Unraveling the impact of mutations on the functional dynamics, stability, and energetics of dengue virus non-structural protein 1

ABSTRACT The non-structural protein 1 (NS1), a viral toxin, is linked to serious consequences of dengue. Given its crucial role in the viral life cycle, NS1 has been a primary target for antiviral drug development. This study elucidates the mechanistic impact of specific NS1 mutations, V220D and A248V, identified by Tan and colleagues as potential inhibitors of viral replication. We developed an integrated computational framework to analyze these mutations relative to the native NS1 protein. Using conventional all-atom molecular dynamic simulations followed by site-directed in silico mutagenesis, significant alterations in protein structure were observed. Conformational ensembles over time showed average backbone deviations of 0.44 nm and 0.43 nm for V220D and A248V, respectively, compared to 0.37 nm for the wild type. Residue-wise fluctuations were higher in A248V compared to both wild type and V220D systems. Mutation-induced disruptions in the hydrogen bond network and altered protein structure graphs were also revealed. Principal component analysis and free energy landscape assessments showed the wild-type protein had a more constrained and stable conformation, whereas the mutants displayed scattered energy contours, suggesting reduced structural stability. This comprehensive assessment provides deep insight into the structural impact of NS1 mutations, informing future efforts in antiviral drug development targeting NS1.

Porcine reproductive and respiratory syndrome virus nonstructural protein 2 promotes the autophagic degradation of adaptor protein SH3KBP1 to antagonize host innate immune responses by enhancing K63-linked polyubiquitination of RIG-I.

Non-structural protein 2 (NSP2) of PRRSV is highly variable and plays crucial roles in the virus's life cycle. To elucidate the function of NSP2 during PRRSV infection, we identified SH3KBP1 as an NSP2-interacting host protein using mass spectrometry. Exogenous SH3KBP1 expression significantly inhibited PRRSV replication by enhancing IFN-I and related ISGs production. Conversely, SH3KBP1 knockdown promoted viral replication by downregulating IFN-I and ISGs levels. In vivo experiments revealed that Sh3kbp1-/- mice were more susceptible to VSV infection, exhibiting reduced serum IFN-β levels. Further investigation showed that SH3KBP1 enhances RIG-I signal transduction by increasing K63-linked polyubiquitination through interaction with the E3 ubiquitin ligase TRIM25. We also found that PRRSV infection and NSP2 overexpression induce the autophagic degradation of SH3KBP1, counteracting the host's innate immune response. A critical interaction site was identified within the third polyproline-arginine motif in NSP2 (453PVPAPR458). Recombinant PRRSV lacking this motif displayed reduced virulence and decreased SH3KBP1 degradation. This study advances our understanding of how PRRSV interferes with the host immune response and offers valuable insights for developing novel attenuated vaccines against PRRSV.

Non-lytic spread of poliovirus requires the nonstructural protein 3CD.

Non-enveloped viruses like poliovirus (PV) have evolved the capacity to spread by non-lytic mechanisms. For PV, this mechanism exploits the host secretory autophagy pathway. Virions are selectively incorporated into autophagosomes, double-membrane vesicles that travel to the plasma membrane, fuse, and release single-membrane vesicles containing virions. Loading of cellular cargo into autophagosomes relies on direct or indirect interactions with microtubule-associated protein 1B-light chain 3 (LC3) that are mediated by motifs referred to as LC3-interaction regions (LIRs). We have identified a PV mutant with a severe defect in non-lytic spread. An F-to-Y substitution in a putative LIR of the nonstructural protein 3CD prevented virion incorporation into LC3-positive autophagosomes and virion trafficking to the plasma membrane for release. Using high-angle annular dark-field scanning transmission electron microscopy to monitor PV-induced autophagosome biogenesis, for the first time, we show that virus-induced autophagic signals yield normal autophagosomes, even in the absence of virions. The F-to-Y derivative of PV 3CD was unable to support normal autophagosome biogenesis. Together, these studies make a compelling case for a direct role of a viral nonstructural protein in the formation and loading of the vesicular carriers used for non-lytic spread that may depend on the proper structure, accessibility, and/or dynamics of its LIR. The studies of PV 3CD protein reported here will hopefully provoke a more deliberate look at the presence and function of LIR motifs in viral proteins of viruses known to use autophagy as the basis for non-lytic spread.

Broad-Spectrum Antiviral Agents against SARS-CoV-2 Variants Inhibit the Conserved Viral Protein Nsp1-RNA Interaction.

The ongoing global threats posed by COVID-19 pandemic, catalyzed by SARS-CoV-2, underscores the pressing need for effective antiviral strategies. The viral non-structural protein 1 (Nsp1) significantly influences pathogenicity by impeding host protein expression and enhancing viral RNA translation through its interaction with the stem-loop 1 (SL1) in the 5' untranslated region (UTR). We have developed a novel dual-luciferase reporter assay, designed to investigate the critical Nsp1-SL1 interaction, and identified P23E02 as a potential inhibitor. Our investigation, combining molecular docking studies and alanine mutagenesis, has unveiled that P23E02 disrupts Nsp1-40S ribosomal subunit interaction, liberating translational inhibition and empowering host antiviral responses. P23E02 exhibits antiviral efficacy against various sarbecoviruses, making it a promising candidate for combatting COVID-19 and related diseases. This study underscores the therapeutic potential of targeting the Nsp1/SL1 axis and lays the foundation for innovative antiviral interventions, ultimately fortifying global preparedness against future viral threats.

Distinct chikungunya virus polymerase palm subdomains contribute to viral protein accumulation and virion production.

Alphaviruses encode an error-prone RNA-dependent RNA polymerase (RdRp), nsP4, required for genome synthesis, yet how the RdRp functions in the complete alphavirus life cycle is not well-defined. Previous work using chikungunya virus has established the importance of the nsP4 residue cysteine 483 in replication. Given the location of residue C483 in the nsP4 palm domain, we hypothesized that other residues within this domain and surrounding subdomains would also contribute to polymerase function. To test this hypothesis, we designed a panel of nsP4 variants via homology modeling based on the coxsackievirus B3 3D polymerase. We rescued each variant in mammalian and mosquito cells and discovered that the palm domain and ring finger subdomain contribute to host-specific replication. In C6/36 cells, we found that while the nsP4 variants had replicase function similar to that of wild-type CHIKV, many variants presented changes in protein accumulation and virion production even when viral nonstructural and structural proteins were produced. Finally, we found that WT CHIKV and nsP4 variant replication and protein production could be enhanced in mammalian cells at 28°C, yet growing virus under these conditions led to changes in virus infectivity. Taken together, these studies highlight that distinct nsP4 subdomains are required for proper RNA transcription and translation, having major effects on virion production.

Avian deltacoronaviruses encode fusion-associated small transmembrane proteins that can induce syncytia formation

Fusion-associated small transmembrane (FAST) proteins are nonstructural viral proteins that induce cell-cell fusion. FAST proteins, which previously were identified in the genomes of double-stranded RNA viruses, typically contain an acylated N-terminal ectodomain, central transmembrane domain, and C-terminal endodomain with a polybasic region. Using sequence homology and protein motif prediction, we identified accessory proteins in a subset of avian deltacoronaviruses as putative FAST proteins. Transient expression of thrush coronavirus NS7b or common moorhen coronavirus NS7a, but not night heron coronavirus NS7b, induced cell-cell fusion. Syncytia were detected in primate kidney epithelial cells or fibroblasts but not chicken embryo fibroblasts, and addition of an N-terminal FLAG peptide to the proteins ablated fusion activity. These findings suggest that multiple avian deltacoronaviruses, positive-sense RNA viruses, encode nonstructural proteins that can mediate cell-cell fusion and share features with known FAST proteins. Additional studies are needed to understand contributions of these proteins to deltacoronavirus biology.

Cellular NS1-BP protein interacts with the mRNA export receptor NXF1 to mediate nuclear export of influenza virus M mRNAs

Influenza A viruses have eight genomic RNAs that are transcribed in the host cell nucleus. Two of the viral mRNAs undergo alternative splicing. The M1 mRNA encodes the matrix protein 1 (M1) and is also spliced into M2 mRNA, which encodes the proton channel matrix protein 2 (M2). Our previous studies have shown that the cellular NS1-binding protein (NS1-BP) interacts with the viral non-structural protein 1 (NS1) and M1 mRNA to promote M1 to M2 splicing. Another pool of NS1 protein binds the mRNA export receptor NXF1 (nuclear RNA export factor-1), leading to nuclear retention of cellular mRNAs. Here we show a series of biochemical and cell biological findings that suggest a model for nuclear export of M1 and M2 mRNAs despite the mRNA nuclear export inhibition imposed by the viral NS1 protein. NS1-BP competes with NS1 for NXF1 binding, allowing the recruitment of NXF1 to the M mRNAs after splicing. NXF1 then binds GANP (Germinal-center Associated Nuclear Protein), a member of the TRanscription and EXport complex (TREX)-2. Although both NS1 and NS1-BP remain in complex with GANP-NXF1, they dissociate once this complex docks at the nuclear pore complex (NPC), and the M mRNAs are translocated to the cytoplasm. Since this mRNA nuclear export pathway is key for expression of M1 and M2 proteins that function in viral intracellular trafficking and budding, these viral-host interactions are critical for influenza virus replication.

Zika virus NS3 drives the assembly of a viroplasm-like structure.

Zika virus (ZIKV) is a mosquito-transmitted flavivirus that caused an epidemic in 2015-2016 in the Americas and raised serious global health concerns due to its association with congenital brain developmental defects in infected pregnancies. Upon infection, ZIKV assembles virus particles in a virus-generated toroidal compartment next to the nucleus called the replication factory, or viroplasm, which forms by remodeling the host cell endoplasmic reticulum (ER). How the viral proteins control viroplasm assembly remains unknown. Here we show that the ZIKV non-structural protein 3 (NS3) is sufficient to drive the assembly of a viroplasm-like structure (VLS) in human cells. NS3 encodes a dual-function protease and RNA helicase. The VLS is similar to the ZIKV viroplasm in its assembly near centrosomes at the nuclear periphery, its deformation of the nuclear membrane, its recruitment of ER, Golgi, and dsRNA, and its association with microtubules at its surface. While sufficient to generate a VLS, NS3 is less efficient in several aspects compared to viroplasm formation upon ZIKV infection. We further show that the helicase domain and not the protease domain is required for optimal VLS assembly and dsRNA recruitment. Overall, this work advances our understanding of the mechanism of viroplasm assembly by ZIKV and likely will extend to other flaviviruses.

The greasy finger region of DTMUV NS1 plays an essential role in NS1 secretion and viral proliferation

Duck Tembusu virus (DTMUV) of the Orthoflavivirus genus poses a significant threat to waterfowl aquaculture. Nonstructural protein 1 (NS1), a multifunctional glycoprotein, exists in various oligomeric forms and performs diverse functions. The Greasy Finger (GF) region within NS1 of other flaviviruses has been shown to be a crucial component of the hydrophobic protrusion aiding in anchoring NS1 to the endoplasmic reticulum (ER). However, detailed studies on the role of the GF region in viral proliferation in vitro and the biological properties of NS1 remain scarce. A series of recombinant DTMUV (rDTMUV) with mutations in the GF region, including NS1-F158A, G159A, F160A, G161A, V162A, L163A, F160R, multipoint mutations (GF-4M), or regional deletions (ΔGF), were rescued using a DNA-based reverse genetics system. Only five rDTMUV variants (G159A, F160A, G161A, V162A, and L163A) could be rescued successfully, and these mutations were found to impair replication, reduce virulence, and decrease plaque size, as shown by growth kinetics, duck embryo virulence, and plaque assays, respectively. Upon examining NS1 expression by western blot, we discovered that secreted NS1 (sNS1) presented in large quantities in the supernatant of cells infected with rDTMUV-NS1-G159A, whereas intracellular NS1 was less abundant. These mutations also impacted the primary forms and secretion rates of NS1 in cases of overexpression by western blot and indirect ELISA. Exception for F160A and G161A, which showed decreased secretion rates, all other mutations increased sNS1 expression, with the most pronounced increase observed in F158A and ΔGF, and rDTMUV with these mutations can't be rescued. Co-localization studies of NS1 with the ER demonstrated that the ΔGF mutation attenuated NS1 anchoring to the ER, thereby inhibiting its intracellular residence and promoting secretion. Although these effects vary between flaviviruses, our data reveal that the GF region of NS1 is crucial for viral proliferation and NS1 secretion.