Abortive infection of bat fibroblasts with SARS-CoV-2.

Bats are tolerant to highly pathogenic viruses such as Marburg, Ebola, and Nipah, suggesting the presence of a unique immune tolerance toward viral infection. Here, we compared severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection of human and bat (Rhinolophus ferrumequinum) pluripotent cells and fibroblasts. Since bat cells do not express an angiotensin-converting enzyme 2 (ACE2) receptor that allows virus infection, we transduced the human ACE2 (hA) receptor into the cells and found that transduced cells can be infected with SARS-CoV-2. Compared to human embryonic stem cells-hA, infected bat induced Pluripotent Stem Cells (iPSCs)-hA produced about a 100-fold lower level of infectious virus and displayed lower toxicity. In contrast, bat embryonic fibroblast-hA produced no infectious virus while being infectable and synthesizing viral RNA and proteins, suggesting abortive infection. Indeed, electron microscopy failed to detect virus-like particles in infected bat fibroblasts in contrast to bat iPSCs or human cells, consistent with the latter producing infectious viruses. This suggests that bat somatic but not pluripotent cells have an effective mechanism to control virus replication. Consistent with previous results by others, we find that bat cells have a constitutively activated innate immune system, which might limit SARS-CoV-2 infection compared to human cells.

Multi-species genome-wide CRISPR screens identify conserved suppressors of cold-induced cell death.

Cells must adapt to environmental changes to maintain homeostasis. One of the most striking environmental adaptations is entry into hibernation during which core body temperature can decrease from 37°C to as low at 4°C. How mammalian cells, which evolved to optimally function within a narrow range of temperatures, adapt to this profound decrease in temperature remains poorly understood. In this study, we conducted the first genome-scale CRISPR-Cas9 screen in cells derived from Syrian hamster, a facultative hibernator, as well as human cells to investigate the genetic basis of cold tolerance in a hibernator and a non-hibernator in an unbiased manner. Both screens independently revealed glutathione peroxidase 4 (GPX4), a selenium-containing enzyme, and associated proteins as critical for cold tolerance. We utilized genetic and pharmacological approaches to demonstrate that GPX4 is active in the cold and its catalytic activity is required for cold tolerance. Furthermore, we show that the role of GPX4 as a suppressor of cold-induced cell death extends across hibernating species, including 13-lined ground squirrels and greater horseshoe bats, highlighting the evolutionary conservation of this mechanism of cold tolerance. This study identifies GPX4 as a central modulator of mammalian cold tolerance and advances our understanding of the evolved mechanisms by which cells mitigate cold-associated damage-one of the most common challenges faced by cells and organisms in nature.

Commercial human 3D corneal epithelial equivalents for modeling epithelial infection in herpes keratitis.

Herpes stromal keratitis is the leading cause of infectious blindness in the western world. Infection by HSV1 is most common, but VZV and hCMV also infect the cornea. Multiple models of HSV1 corneal infection exist, but none for VZV and hCMV because of their host specificity. Here, we used commercially available 3D human corneal epithelial equivalents (HCEE) to study infection by these herpesviruses. HCEE was infected by HSV-1 and hCMV without requiring scarification and resulted in spreading infections. Spread of HSV-1 infection was rapid, while that of hCMV was slow. In contrast, infections with VZV required damage to the HCEE and did not spread. Acyclovir dramatically reduced replication of HSV-1 in this model. We conclude that highly quality-controlled, readily available HCEE is a useful model to study human-restricted herpesvirus infection of the human corneal epithelium and for screening of antiviral drugs for treating HSK in an 3D model system.

Genomic and biological variation in bat IFNs: An antiviral treatment approach.

Bat-borne viruses have attracted considerable research, especially in relation to the Covid-19 pandemic. Although bats can carry multiple zoonotic viruses that are lethal to many mammalian species, they appear to be asymptomatic to viral infection despite the high viral loads contained in their bodies. There are several differences between bats and other mammals. One of the major differences between bats and other mammals is the bats' ability to fly, which is believed to have induced evolutionary changes. It may have also favoured them as suitable hosts for viruses. This is related to their tolerance to viral infection. Innate immunity is the first line of defence against viral infection, but bats have metamorphosed the type of responses induced by innate immunity factors such as interferons. The expression patterns of interferons differ, as do those of interferon-related genes such as interferon regulatory factors and interferon-stimulated genes that contribute to the antiviral response of infected cells. In addition, the signalling pathways related to viral infection and immune responses have been subject to evolutionary changes, including mutations compared to their homologues in other mammals and gene selection. This article discusses the differences in the interferon-mediated antiviral response in bats compared to that of other mammals and how these differences are correlated to viral tolerance in bats. The effect of bat interferons related genes on human antiviral response against bat-borne viruses is also discussed.

Human iPS cell-derived sensory neurons can be infected by SARS-CoV-2.

COVID-19 has impacted billions of people since 2019 and unfolded a major healthcare crisis. With an increasing number of deaths and the emergence of more transmissible variants, it is crucial to better understand the biology of the disease-causing virus, the SARS-CoV-2. Peripheral neuropathies appeared as a specific COVID-19 symptom occurring at later stages of the disease. In order to understand the impact of SARS-CoV-2 on the peripheral nervous system, we generated human sensory neurons from induced pluripotent stem cells that we infected with the SARS-CoV-2 strain WA1/2020 and the variants delta and omicron. Using single-cell RNA sequencing, we found that human sensory neurons can be infected by SARS-CoV-2 but are unable to produce infectious viruses. Our data indicate that sensory neurons can be infected by the original WA1/2020 strain of SARS-CoV-2 as well as the delta and omicron variants, yet infectability differs between the original strain and the variants.

LINE1-mediated reverse transcription and genomic integration of SARS-CoV-2 mRNA detected in virus-infected but not in viral mRNA-transfected cells.

SARS-CoV-2 sequences can be reverse-transcribed and integrated into the genomes of virus-infected cells by a LINE1-mediated retrotransposition mechanism. Whole genome sequencing (WGS) methods detected retrotransposed SARS-CoV-2 subgenomic sequences in virus-infected cells overexpressing LINE1, while an enrichment method (TagMap) identified retrotranspositions in cells that did not overexpress LINE1. LINE1 overexpression increased retrotranspositions about 1,000-fold as compared to non-overexpressing cells. Nanopore WGS can directly recover retrotransposed viral and flanking host sequences but its sensitivity depends on the depth of sequencing (a typical 20-fold sequencing depth would only examine 10 diploid cell equivalents). In contrast, TagMap enriches for the host-virus junctions and can interrogate up to 20,000 cells and is able to detect rare viral retrotranspositions in LINE1 non-overexpressing cells. Although Nanopore WGS is 10 - 20-fold more sensitive per tested cell, TagMap can interrogate 1,000 - 2,000-fold more cells and therefore can identify infrequent retrotranspositions. When comparing SARS-CoV-2 infection and viral nucleocapsid mRNA transfection by TagMap, retrotransposed SARS-CoV-2 sequences were only detected in infected but not in transfected cells. Retrotransposition in virus-infected in contrast to transfected cells may be facilitated because virus infection in contrast to viral RNA transfection results in significantly higher viral RNA levels and stimulates LINE1-expression which causes cellular stress.

LINE1-Mediated Reverse Transcription and Genomic Integration of SARS-CoV-2 mRNA Detected in Virus-Infected but Not in Viral mRNA-Transfected Cells.

SARS-CoV-2 sequences can be reverse-transcribed and integrated into the genomes of virus-infected cells by a LINE1-mediated retrotransposition mechanism. Whole-genome sequencing (WGS) methods detected retrotransposed SARS-CoV-2 subgenomic sequences in virus-infected cells overexpressing LINE1, while an enrichment method (TagMap) identified retrotranspositions in cells that did not overexpress LINE1. LINE1 overexpression increased retrotranspositions about 1000-fold as compared to non-overexpressing cells. Nanopore WGS can directly recover retrotransposed viral and flanking host sequences, but its sensitivity depends on the depth of sequencing (a typical 20-fold sequencing depth would only examine 10 diploid cell equivalents). In contrast, TagMap enriches the host-virus junctions and can interrogate up to 20,000 cells and is able to detect rare viral retrotranspositions in LINE1 non-overexpressing cells. Although Nanopore WGS is 10-20-fold more sensitive per tested cell, TagMap can interrogate 1000-2000-fold more cells and, therefore, can identify infrequent retrotranspositions. When comparing SARS-CoV-2 infection and viral nucleocapsid mRNA transfection by TagMap, retrotransposed SARS-CoV-2 sequences were only detected in infected but not in transfected cells. Retrotransposition in virus-infected cells, in contrast to transfected cells, may be facilitated because virus infection, in contrast to viral RNA transfection, results in significantly higher viral RNA levels and stimulates LINE1 expression by causing cellular stress.

Human iPS cell-derived sensory neurons can be infected by SARS-CoV-2 strain WA1/2020 as well as variants delta and omicron.

COVID-19 has impacted billions of people in the world since 2019 and unfolded a major healthcare crisis. With an increasing number of deaths and the emergence of more transmissible variants, it is crucial to better understand the biology of the disease-causing virus, the SARS-CoV-2. Peripheral neuropathies appeared as a specific COVID-19 symptom occurring at later stages of the disease. In order to understand the impact of SARS-CoV-2 on the peripheral nervous system, we generated human sensory neurons from induced pluripotent stem cells that we infected with the SARS-CoV-2 strain WA1/2020 and the variants delta and omicron. Using single cell RNA sequencing, we found that human sensory neurons can be infected by SARS-CoV-2 but are unable to produce new viruses. Our data suggests that sensory neurons can be infected by the original WA1/2020 strain of SARS-CoV-2 as well as the delta and omicron variants.

Studies of Infection and Experimental Reactivation by Recombinant VZV with Mutations in Virally-Encoded Small Non-Coding RNA.

Locked-nucleotide analog antagonists (LNAA) to four varicella zoster virus small non-coding RNA (VZVsncRNA 10-13) derived from the mRNA of the open reading frame (ORF) 61 gene individually reduce VZV replication in epithelial cells and fibroblasts. To study the potential roles VZVsncRNA 10-13 have in neuronal infection we generated two recombinant VZV; one in which 8 nucleotides were changed in VZVsncRNA10 without altering the encoded residues of ORF61 (VZVsnc10MUT) and a second containing a 12-nucleotide deletion of the sequence common to VZVsncRNA12 and 13, located in the ORF61 mRNA leader sequence (VZVsnc12-13DEL). Both were developed from a VZV BAC with a green fluorescent protein (GFP) reporter fused to the N terminal of the capsid protein encoded by ORF23. The growth of both mutant VZV in epithelial cells and fibroblasts was similar to that of the parental recombinant virus. Both mutants established productive infections and experimental latency in neurons derived from human embryonic stem cells (hESC). However, neurons that were latently infected with both VZV mutant viruses showed impaired ability to reactivate when given stimuli that successfully reactivated the parental virus. These results suggest that these VZVsncRNA may have a role in VZV latency maintenance and/or reactivation. The extension of these studies and confirmation of such roles could potentially inform the development of a non-reactivating, live VZV vaccine.

Locked-nucleotide antagonists to varicella zoster virus small non-coding RNA block viral growth and have potential as an anti-viral therapy.

Herpes zoster (HZ) remains a significant health burden with millions of cases in North America and Europe annually. HZ is frequently followed by long-term pain or post-herpetic neuralgia (PHN). Although effective vaccines for HZ are available, currently used nucleotide analogues often have limited effectiveness against HZ and especially PHN, so there remains a need for additional antiviral therapies for HZ. We recently identified a population of small non-coding RNA (sncRNA) encoded by Varicella Zoster Virus (VZV) and showed that single locked-nucleic acid antagonists (LNAA) to some sncRNA can modulate VZV replication in cell culture. In this work, we explored the antiviral effects of combinations of LNAA oligonucleotides targeting VZVsncRNA. Combinations of LNAA targeting three VZVsncRNA encoded in and near a critical viral regulatory gene were additive, achieving 96 % reduction in virus growth in a cell line. VZV growth was also inhibited by more than 90 % in primary human skin fibroblast cultures by individual and combinations of LNAA to VZVsncRNA. The inhibition by VZVsncRNA was specific and not a consequence of innate immune responses since LNAA to a different VZVsncRNA enhanced VZV growth. Targeted VZVsncRNA lack homologous sequences in the human transcriptome suggesting that LNAA to them would have reduced cytotoxicity if used as therapeutics. These results support further development of oligonucleotides targeting VZVsncRNA as a novel treatment for HZ.

Varicella-Zoster Virus (VZV) Small Noncoding RNAs Antisense to the VZV Latency-Encoded Transcript VLT Enhance Viral Replication.

Small noncoding RNAs (sncRNA), including microRNA (miR), are expressed by many viruses to provide an additional layer of gene expression regulation. Our work has shown that varicella-zoster virus (VZV; also called human herpesvirus 3 [HHV3]), the human alphaherpesvirus causing varicella and herpes zoster, expresses 24 virally encoded sncRNA (VZVsncRNA) in infected cells. Here, we demonstrate that several VZVsncRNA can modulate VZV growth, including four VZVsncRNA (VZVsncRNA10, -11, -12, and -13) that are antisense to VLT, a transcript made in lytic infections and associated with VZV latency. The influence on productive VZV growth and spread was assessed in epithelial cells transfected with locked nucleotide analog antagonists (LNAA). LNAA to the four VZVsncRNA antisense to VLT significantly reduced viral spread and progeny titers of infectious virus, suggesting that these sncRNA promoted lytic infection. The LNAA to VZVsncRNA12, encoded in the leader to ORF61, also significantly increased the levels of VLT transcripts. Conversely, overexpression of VZVsncRNA13 using adeno-associated virus consistently increased VZV spread and progeny titers. These results suggest that sncRNA antisense to VZV may regulate VZV growth, possibly by affecting VLT expression. Transfection of LNAA to VZVsncRNA14 and VZVsncRNA9 decreased and increased VZV growth, respectively, while LNAA to three other VZVsncRNA had no significant effects on replication. These data strongly support the conclusion that VZV replication is modulated by multiple virally encoded sncRNA, revealing an additional layer of complexity of VZV regulation of lytic infections. This may inform the development of novel anti-sncRNA-based therapies for treatment of VZV diseases.IMPORTANCE Varicella-zoster virus (VZV) causes herpes zoster, a major health issue in the aging and immunocompromised populations. Small noncoding RNAs (sncRNA) are recognized as important actors in modulating gene expression. This study extends our previous work and shows that four VZVsncRNA clustering in and near ORF61 and antisense to the latency-associated transcript of VZV can positively influence productive VZV infection. The ability of multiple exogenous small oligonucleotides targeting VZVsncRNA to inhibit VZV replication strengthens the possibility that they may inform development of novel treatments for painful herpes zoster.

Bioinformatically-predicted varicella zoster virus small non-coding RNAs are expressed in lytically-infected epithelial cells and neurons.

Most herpesviruses use both host and viral small non-coding RNAs (sncRNA), especially microRNA, to modulate infection. Bioinformatic analyses of NGS data obtained from Varicella Zoster virus (VZV)-infected cells predicted 24 VZVsncRNA, seven of which were confirmed to be expressed in infected fibroblasts and neurons using stem-loop quantitative reverse transcription PCR (SL-PCR). We here assayed for the expression of all 24 of the bioinformatically predicted VZVsncRNA in cells productively infected by VZV using SL-PCR. 23 of the 24 predicted sequences were detected in VZV-infected ARPE19 cells and 19 of the 24 sequences in infected human neurons generated by two methods from embryonic stem cells. We also show that blocking one of two newly-tested VZV-encoded sncRNA using locked nucleotide antagonists significantly increased viral replication. These findings suggest that further study of VZV encoded sncRNA could elucidate an additional level of regulation of the life cycle of this pathogenic human herpesvirus.

Engineering foot-and-mouth disease virus serotype O IND R2/1975 for one-step purification by immobilized metal affinity chromatography.

Immobilized metal affinity chromatography (IMAC) allows for the efficient protein purification via metal affinity tag such as hexa-histidine (His6) sequence. To develop a new chromatography strategy for the purification and concentration of foot-and-mouth disease virus (FMDV) particles, we inserted the His6-tag at the earlier reported site in the VP1 G-H loop of the FMD virus serotype O vaccine strain IND R2/1975. Display of the His6-tag on the capsid surface, endowed the virus with an increased affinity for immobilized nickel ions. We demonstrated that the His6-tagged FMDV could be produced to high titre and purified from the infected BHK-21 cell lysates by IMAC efficiently. Further, a 1150-fold reduction in protein contaminant level and an 8400-fold reduction in DNA contaminant level were achieved in the IMAC purification of His6-tagged FMDV. Through various functional assays it has been found that the tagged virus retains its functionality and infectivity similar to the non-tagged virus. The affinity purification of the His6-tagged FMDV may offer a feasible, alternative approach to the current methods of FMDV antigen purification, concentration and process scalability.

A new lineage of foot-and-mouth disease virus serotype O in India.

The complete nucleotide sequence of a new lineage of foot and mouth disease virus (FMDV) serotype O was determined. The lineage designated as Ind2011 first appeared during 2011 in the Southern region of India. Excluding the poly C tract and poly A tail, the genome of Ind2011 ranged from 8,169 to 8,172 nucleotides. Variation in the genome length was due to insertions/deletions in LF-UTR. The lineage had a higher sequence identity with lineage PanAsia-1 at P1 and P2 regions, and with lineage PanAsia-2 at P3 and L regions. Phylogenetically, the isolates were placed closely to both PanAsia-1 and 2 lineages, and appear to be a novel variant of the PanAsian lineage.

Application of a recombinant capsid polyprotein (P1) expressed in a prokaryotic system to detect antibodies against foot-and-mouth disease virus serotype O.

Foot-and-mouth disease (FMD) is a highly contagious epidemic disease of transboundary importance. In India, the disease is endemic in nature and is controlled primarily by prophylactic bi-annual mass vaccination. In this control programme, liquid-phase blocking ELISA (LPBE) is being used widely for post vaccination seromonitoring. In order to develop an alternative assay to LPBE, the recombinant capsid polyprotein (rP1) of FMD virus (FMDV) serotype O was expressed in Escherichia coli and used as an antigen for the detection of antibodies to FMDV. The capsid polyprotein of FMDV serotype O could be expressed successfully as a recombinant 6xHis-SUMO tagged protein in soluble form. In a Western blot assay, the rP1 protein reacted strongly with anti-FMDV serotype O guinea pig and bovine serum. Further, in this study, an rP1 protein-based solid phase competitive ELISA (rP1-SPCE) was developed and evaluated with a set of serum samples representing the various epidemiological situation of the country. The performance of the rP1-SPCE was compared with the in-house LPBE, and overall, an excellent agreement (kappa = 0.95) was observed between the two tests. This report demonstrates that the recombinant capsid polyprotein-based ELISA has the potential to be an easy-to-perform, safe alternative to the conventional LPBE for the quantitative detection of antibodies to FMDV serotype O.

A positively charged lysine residue at VP2 131 position allows for the enhanced adaptability of foot-and-mouth disease virus serotype A in BHK-21 cells.

Field outbreak strains of foot-and-mouth disease virus (FMDV) infect host cells through certain Arg-Gly-Asp (RGD) dependent integrin family of cellular receptors. In contrast, FMDV adapted in non-host cell cultures are reported to acquire the ability to infect cells via heparin sulphate (HS) or other unidentified cell surface molecules. It has been reported that during the serial passage of FMDV serotype A in BHK-21 cell culture, VP2 E131K (E2131K) substitution was fixed within the heparin sulphate binding site. The fixation of positively charged residue at position VP2 131 of serotype A is considered to associate with the ability to utilise alternative receptor. In this study, an infectious full-length cDNA clone for Indian FMDV vaccine strain A IND 40/2000 was constructed. Through site-directed mutagenesis on the cDNA clone, recombinant virus containing positive charged amino acid residue at position VP2 131 was rescued. The recombinant mutated virus was shown to have specific and strong affinity for HS and demonstrated an enhanced infectivity in BHK-21 cell line. The introduction of lysine residue at VP2 131 position that allows cell culture adaptation of FMDV serotype A could be exploited for the generation of vaccine seed stocks with improved growth properties in BHK-21 cell line.

The expression of IL6 and 21 in crossbred calves upregulated by inactivated trivalent FMD vaccine.

Foot and mouth disease (FMD) is an economically important disease and a whole-virus inactivated trivalent virus vaccine is the mainstay for controlling the disease in India. The protective humoral immune response to FMD vaccination is a complex, but, tightly regulated process mediated by the interplay of interleukins (IL). Based on the specific role of IL6 and 21 in adaptive immune response, we hypothesized that inactivated trivalent FMD vaccine would stimulate IL6 and 21 expression in the circulating lymphocytes. The expressions of IL6 and 21 were assayed on 0, 28, 60, 90, and 120 d post-vaccination (DPV) by quantitative PCR (qPCR) with simultaneous assessment of FMDV antibody titer by liquid phase blocking ELISA. The results revealed that the peak expression of IL6 and 21 was on DPV 28 which correlated well with the FMDV antibody titer and plummeted to the prevaccination titer level by 60 DPV. As IL21 is the final effector of antibody production as compared to IL6, we investigated the expression of IL21 in calves that had protective titer (>1.8) with the unprotected group (<1.8). Expression of IL21 on 28 DPV was numerically higher in the protected than that of the unprotected group of calves.

Detection of antibodies specific for foot-and-mouth disease virus infection using indirect ELISA based on recombinant nonstructural protein 2B.

Foot-and-mouth disease (FMD) is a highly contagious viral disease of transboundary importance. In India, since the launch of the FMD control programme, there has been a substantial increase in the vaccinated bovine population. In this scenario, there is a need for additional locally developed non-structural protein (NSP)-based immnoassays for efficient identification of FMD virus (FMDV)-infected animals in the vaccinated population. The 2B NSP of FMDV, lacking the transmembrane domain (Δ2B), was expressed successfully in a prokaryotic system, and an indirect ELISA (I-ELISA) was developed and validated in this study. The diagnostic sensitivity and specificity of the Δ2B I-ELISA were found to be 95.3 % and 94.6 %, respectively. In experimentally infected cattle, the assay could consistently detect Δ2B-NSP-specific antibodies from 10 to approximately 400 days postinfection. The assay was further validated with bovine serum samples collected randomly from different parts of the country. The performance of the Δ2B I-ELISA was compared with the in-house r3AB3 I-ELISA, and the overall concordance in test results was found to be 86.49 %. The Δ2B I-ELISA could be useful as a screening or confirmatory assay in the surveillance of FMD irrespective of vaccination.

Efficient rescue of foot-and-mouth disease virus in cultured cells transfected with RNA extracted from clinical samples.

In this study, an RNA transfection was used to rescue infectious foot-and-mouth disease (FMD) virus from clinical samples in BHK-21 cell line for diagnosis of FMD. Tissue samples (n=190) were subjected to FMD virus isolation by conventional cell culture and also by RNA transfection. FMD virus was isolated from 62% of the clinical samples by RNA transfection, whereas virus was isolated only from 16% of the clinical samples in conventional cell culture method, suggesting better performance of the RNA transfection. Virus was rescued from 67% and 10% of ELISA negative but multiplex PCR positive samples by RNA transfection and conventional cell culture, respectively. The efficiency of transfection was studied on clinical samples subjected to temperature as high as 37°C and varying pH (pH 4-9). Except up to 1 week of storage at 4°C at pH 7.5, virus isolation was not possible by cell culture. Virus was rescued by transfection from samples stored at 4°C for any of the applied pH up to 4 weeks, and when stored at 37°C virus could be rescued up to 4 weeks at pH 7.5 suggesting the fitness of transfection to isolate virus from clinical samples stored under inappropriate conditions. The sequence data and antigenic relationships with the vaccine strains, between virus rescued by transfection and conventional cell culture, were comparable. The RNA transfection will help to increase the efficiency of virus isolation, diagnosis and molecular epidemiological studies.

Emergence of a novel lineage genetically divergent from the predominant Ind2001 lineage of serotype O foot-and-mouth disease virus in India.

In India, emergence of Ind2001 lineage of foot-and-mouth disease virus (FMDV) serotype O was recorded in the year 2001. After causing sporadic incidences, the Ind2001 lineage that re-surged in 2008 out-competed PanAsia from the field during 2009 and continued its dominance during 2010 and 2011 as well. The lineage has diversified in due course of time, leading to two sub-lineages (Ind2001a and Ind2001b). The sub-lineage Ind2001a include isolates collected during 2001-2002 and sub-lineage Ind2001b is constituted largely by isolates collected during 2008-2012. The nucleotide substitution rate of sub-lineage Ind2001b was estimated at 6.58×10⁻³ substitutions/site/year. The most stable PanAsia lineage is restricted only to few outbreaks. During 2011, emergence of a new genetic group with >9% nucleotide divergence from rest of the lineages circulating in the country was detected and named as lineage Ind2011. Two specific amino acid substitutions at positions VP1-36 (F) and VP2-133 (T) were observed in the Ind2011 lineage. The new lineage at present is restricted only to southern states of the country. It is uncertain whether the emergence was triggered by immune pressure or due to a bottleneck in transmission or selected for higher fitness value. Six sites (4, 68, 83, 135, 138 and 209) in VP1 protein were identified to undergo episodic diversifying selection in serotype O field isolates. Both emerging and re-emerging lineages had appropriate antigenic match with currently used vaccine strain, INDR2/1975. Irrespective of genetic variability, the field isolates showed remarkable conservation at antigenically critical residues that might contribute to the observed antigenic stability. With the emergence of a new genetic group after a span of 10 years, the overall epidemiological scenario in the region is expected to change in the coming years.