Chikungunya virus molecular evolution in India since its re-emergence in 2005

Abstract Chikungunya virus (CHIKV), an alphavirus of the Togaviridae family, is among the most medically significant mosquito-borne viruses, capable of causing major epidemics of febrile disease and severe, chronic arthritis. Identifying viral mutations is crucial for understanding virus evolution and evaluating those genetic determinants that directly impact pathogenesis and transmissibility. The present study was undertaken to expand on past CHIKV evolutionary studies through robust genome-scale phylogenetic analysis to better understand CHIKV genetic diversity and evolutionary dynamics since its reintroduction into India in 2005. We sequenced the complete genomes of fifty clinical isolates collected between 2010 and 2016 from two geographic locations, Delhi and Mumbai. We then analysed them along with 753 genomes available on the Virus Pathogen Database and Analysis Resource sampled over fifteen years (2005–20) from a range of locations across the globe and identified novel genetic variants present in samples from this study. Our analyses show evidence of frequent reintroduction of the virus into India and that the most recent CHIKV outbreak shares a common ancestor as recently as 2006.


Introduction
The Alphavirus genus is a diverse group of small, spherical, enveloped viruses with single-stranded, positive-sense RNA genomes (Forrester et al. 2012;Lanciotti and Lambert 2016;Villero-Wolf et al. 2019). These viruses infect vertebrates such as primates, fish, and birds and are medically important owing to their ability to cause diseases in humans. Chikungunya virus (CHIKV) is among the most important of these human-pathogenic alphaviruses. It is known to cause epidemics of chikungunya fever (CHIKF), an acute febrile illness characterized by sudden onset of fever, rashes, headache, nausea, and muscle pain, and usually associated with severe, debilitating joint pain and swelling (Ganesan, Duan, and Reid 2017). The virus is transmitted by Aedes mosquitoes, including in urban settings, and is a significant public health concern in India. Isolated first during the 1952-3 epidemics of dengue-like illness from a patient in Tanganyika (now  Tanzania), CHIKV epidemics were subsequently reported in many parts of Africa. The first report of CHIKV in Asia surfaced during the late 1950s with an incidence rate of 46 per cent (India), 9 per cent (Thailand), and 6.81 per cent (Malaysia) (Wimalasiri-Yapa et al. 2019).
The CHIKV genome is about 11 kb in size and encodes the structural (C, E3, E2, 6K/TF, and E1) and non-structural (nsP1-4) proteins through two separate open reading frames. Structural and nonstructural proteins are translated as separate polyproteins and, subsequently, catalytically cleaved to the individual proteins. Furthermore, the genome is flanked by 5 ′ and 3 ′ untranslated regions (Hyde et al. 2015). Recent reports have identified mutations in the structural and non-structural proteins of CHIKV worldwide that can lead to changes in disease dynamics (Sasmono et al. 2017;Wong and Chu 2018). While mutations within the structural proteins affect vector specificity, epidemic potential, host response, and disease progression, variations in the non-structural proteins are responsible for altered CHIKV replication kinetics (Fros et al. 2010;Munoz-Medina et al. 2018).
Phylogenetic studies of CHIKV have demonstrated that the virus exists as three major, originally geographically distinct genotypes: Asian, East/Central/South African (ECSA), and West African (WA). ECSA CHIKV strains have caused most outbreaks and epidemics in recent times, and the availability of a large number of sequences, in addition to their in-depth analysis, has enabled their further segregation into distinct lineages, such as the Indian Ocean lineage (IOL) (Chen et al. 2016;Xavier et al. 2019). Times to most recent common ancestors (tMRCA) estimated using Bayesian coalescent analysis determined that Asian and ECSA lineages diverged around 100 years ago, but their earlier divergence from the WA was unclear until recently (Volk et al. 2010;Nasci 2014). Although CHIKV ECSA strains are considered highly virulent due to their scale of spread and Severity of chronic disease during recent epidemics, studies on viral pathogenesis in murine models revealed WA strains to be the most pathogenic followed by ECSA and Asian strains (Langsjoen et al. 2018;Jain et al. 2020).
In India, the first major CHIKF outbreak was reported in 1963 in Kolkata, West Bengal (Shah, Gibbs, and Banerjee 1964), and the disease spread to other states of India between 1964 and 1973 (Pavri 1986;Yadav et al. 2003). During this period, the strain that prevailed belonged to the Asian genotype (Yergolkar et al. 2006). After 1973, CHIKF disappeared from the Indian subcontinent until its re-emergence in 2005, when large-scale outbreaks were reported in several parts of India, confirming widespread re-emergence in the country. Since then, CHIKV transmission has continued sporadically in various parts of the country. Since the 2005 CHIKF emergence, the causative strain for outbreaks in India has been the ECSA strain, IOL (Arankalle et al. 2007;Chhabra et al. 2008;Dwibedi et al. 2011;Dikid et al. 2013).
CHIKV in India has unique epidemiological dynamics due to various factors: the presence of both urban vectors, Aedes aegypti and Aedes albopictus, distinct geographical distribution patterns of these vectors in the country, varying rainfall and temperature patterns, high migration rates of human populations within the country, and a steady inflow of travellers from other endemic geographical locations across the globe. These factors make studying CHIKV evolution within the country tedious and challenging. The present study was undertaken to infer the spatiotemporal evolution of CHIKV in India and to better define its evolutionary dynamics and genetic diversity. We studied CHIKV clinical strains collected from two geographically distinct locations with distinct disease patterns over a period of six years. The two geographical locations Mumbai and Delhi have similar total populations but distinct geographical conditions (Jain et al. 2017), as well as epidemiologic characteristics; Mumbai reported CHIKF since the 1970s with different circulating virus strains (Arankalle et al. 2007), whereas Delhi reported its first case of CHIKF in 2006, with the ESCA CHIKV strain as the causative agent (Chahar et al. 2009). Whole genomes of viruses were sequenced and genome-scale phylogenetic and evolutionary analyses of mosquito-and humanderived CHIKV strains from throughout India between 2005 and 2020 were conducted using whole genomes deposited in the Virus Pathogen Database and Analysis Resource (ViPR).

Whole-genome sequencing and assembly
A total of fifty confirmed CHIKV-positive sera were processed for whole-genome sequencing and further analysis (Table 1). Upon assembly of the complete set of samples, a total of 758.7X coverage was obtained. The coverage ranged from 0.08X (IND/2016/DEL/08) to 8,201.95X (IND/2011/MUM/02). Those regions with gaps were filled using RT-PCR and Sanger amplicon sequencing to complete the genome assembly.
These fifty samples were evaluated on the basis of coverage, and those sequences showing less than 4× coverage were removed from further analyses. Furthermore, the sequences were analysed for recombination events and five sequences, namely IND/2010/DEL/04, IND/2011/DEL/12, IND/2016/DEL/02, IND/2016/DEL/09, and IND/2016/DEL/10, were potential recombinant and thus removed from further analysis (data not shown). On the basis of the above criteria, a final set of forty-one CHIKV whole-genome sequences was taken for downstream analyses.

Phylogeography of CHIKV populations
Phylogenetic analysis of all complete CHIKV genome sequences was performed using two sequence data sets obtained from the ViPR on the basis of their geographical locations and year of sample collection. One data set consisted of ninety-nine sequences from India only, including fifty-eight sequences from public databases, and the other data set was generated using 794 sequences from strains present across the globe belonging to all the three CHIKV genotypes, including 753 sequences from the public database ( Fig. 1 and Supplementary Fig. S2). Phylogenetic analysis of the forty-one samples using the global strains revealed that all 2010-6 Indian samples belonged to the ECSA genotype. Detailed analysis of these samples that were collected over a span of six years with the global sequences revealed a distinct clustering ( Supplementary Fig. S2). The samples from 2010 to 2013 clustered together with all the 2010 samples, and the 2012 and 2013 samples formed a subcluster within this clade. The Indian samples from 2016 clustered separately along with samples from Hong Kong, Singapore, Kenya, and Pakistan collected in 2015-6 ( Supplementary Fig. S2). These findings suggest a possible reintroduction of CHIKV into India around 2015-6, leading to the major outbreak in 2016.
Additionally, we determined the phylogenetic relationships among CHIK viruses within India since 2006 (n = 99). Phylogenetic trees based on complete genome sequences were inferred using the maximum likelihood (ML) and the Markov chain Monte Carlo methods with bootstrap values of >70 (Fig. 1). The strains clustered into distinct temporal groups that were in some instances geographically distinct. Viruses sampled during 2010-3 clustered together, whereas the 2014-6 samples clustered into a different group. Samples of 2006 were from different states; however, they clustered together suggesting a common source, probably that of the initial 2006 re-emergence. Geographically close regions shared the same CHIKV sublineage in the later years, as was seen in Kerala and Andhra Pradesh. Most of the samples of these regions during 2009-13 clustered together, suggesting that CHIKV lineage variation is a major underlying determinant of epidemics. Tests of neutrality using Tajima's D test revealed an excess of low-frequency variants that might have resulted from population expansions.
Estimates of average evolutionary divergence over sequence pairs within Indian states showed varying divergence both within and between states. Sequences derived from Kerala and Maharashtra showed maximum divergence, suggesting the existence of an ancestral population in Maharashtra until 2009. From 2010, similar evolutionary differences were observed in both Delhi and Maharashtra samples until 2013, and sequences from Delhi collected in the year 2016 were a part of a separate clade and thus were most divergent from the rest of the Indian samples. These findings suggest the emergence of distinct virus clades in the two geographical regions.

Evolutionary history of Indian CHIKV genetic groups
To infer the time scale of the emergence of CHIKV genotypes, we estimated the tMRCA. The evolutionary rates of each defined genetic group were derived based on maximum clade credibility (MCC) phylogeny under an uncorrelated log-normal relaxed molecular clock. The tree highlights the uncertainty within clades but the split at the root into two groups clearly shows the diversity within the samples. Collectively, the phylogenetic structure and tMRCA estimates of the CHIKV genotypes suggested that there has been increased genetic diversity owing to the emergence of fit variants that possibly emerged during the intermittent outbreaks in the country ( Fig. 2 and Supplementary Fig. S3).
To investigate changes in demographic patterns of CHIKV over time, we estimated the changes in relative genetic diversity using molecular clocks and coalescent models that allow the estimation of evolutionary rates and timescales. The MCC tree revealed a clustering pattern similar to that of the phylogenetic analysis  Table S1).

Amino acid variability analysis
Previous studies have shown that single amino acid substitutions at critical sites of CHIKV proteins have influenced the epidemiology of the virus as observed with E1-A226V, which enabled enhanced transmission by Ae. albopictus, a more globally dispersed vector, especially in temperate regions (Tsetsarkin et al. 2007). Another substitution, E2-L210Q, identified in the CHIKV populations of Kerala State, India, conferred a selective advantage by increasing the initial infection of Ae. albopictus midgut epithelial cells and subsequent CHIKV dissemination into the haemocoel, thereby promoting transmission by this vector (Tsetsarkin and Weaver 2011). Our complete coding sequence alignment revealed conservative and non-conservative amino acid substitutions in each major CHIKV protein. Even among those conservative amino acid substitutions that were not statistically significant in the entropy analysis, there were rapidly evolving variations (Supplementary Table S2). Overall, entropy analysis identified a total of thirteen codon positions with a high score (P < 0.05), indicating a higher possibility of tolerated variations at these positions.

Variant analysis
Mutation analysis of our forty-one CHIKV strains against a reference strain collected in 2006 from India (FJ000068) revealed a total of 211 mutations. Of these, thirty-nine mutations were non-synonymous, including twenty amino acid variants in the non-structural protein genes and nineteen in the structural genes (Fig. 3), with nsP1 the most variable. Sample-wise analysis of the mutations revealed that the IND/2010/DEL/108 strain carried a maximum of thirteen mutations, of which ten (Supplementary Table S3) were unique. Likewise, strain IND/2016/DEL/02 was found to contain twelve mutations, of which nsP2-P689S and C-Q58R were unique (Fig. 3). In addition to these substitutions, we detected a frameshift in sample IND/2012/MUM/54 at position 98 caused by the deletion of A and T nucleotides, corresponding to frameshift nsP1-I8 at the amino acid level. Mutations identified from this study are represented in Supplementary Table S3.

Annual analysis of sequences
We attempted to understand the status of the mutations in our samples over the years since the 2005 CHIKV re-emergence in India. The samples from the present study collected from five different years (sixteen sera were collected in 2010, five in 2011, eleven in 2012, six in 2013, and four in 2016) were further analysed, revealing that the frequency of non-synonymous mutations was higher in structural protein genes as compared to non-structural in most of the CHIKV strains. The analysis further revealed that in non-structural proteins, four non-synonymous mutations (Supplementary Table S3) were common to all samples in certain years. Substitutions nsP1-G230R, nsP1-M314L, nsP2-Y374H, E3-V42I, E3-P59S, E2-G55R, and E2-H73Y were present in samples from 2010 to 2013; however, these mutations were absent in the 2016 samples. Likewise, seven mutations were present only in 2016 samples and not in any of the previous years. Mutation nsP4-S55N was seen in one sample collected from Delhi in 2012. We did a principal component analysis to understand the yearwise relationship between CHIKV strains ( Fig. 4; Leigh, Bryant, and Nakagawa 2015). Strains from 2010 and 2016 formed separate groups coinciding with major outbreaks in these respective years, while strains from 2011, 2012, and 2013 grouped together coinciding with episodic occurrences.

Regional analysis of sequences
Our analysis further revealed distinct mutations that may have been positively selected within the two main regions of our sample collections, i.e. Delhi and Mumbai. We analysed these mutations based on their presence in samples from these geographical locations. For the sake of unbiased comparison, samples collected from Delhi in 2016 were not included in the analysis as we did not have samples from Mumbai during that year. Our analysis revealed that thirty-one non-synonymous mutations were present in the isolates collected from Delhi, with sixteen present in structural protein genes and fifteen in non-structural genes.
In addition, nineteen non-synonymous mutations were identified in samples collected from the Mumbai region, of which eight were present in structural genes and ten in non-structural proteins.
Out of all fifty mutations, nineteen were either present in Delhi or in Mumbai strains. Twelve mutations were unique in Delhi samples, and six were unique in samples from Mumbai (Supplementary Table S3). Mutations nsP1-V103A, nsP1-G230R, nsP1-M314L, nsP2-Y374H, E1-K211E, E2-G55R, E2-H73Y, E2-V264A, E3-V42I, and E3-P59S were present in the isolates collected from both regions. We further observed that during the 2010-3 CHIKV outbreaks, six non-synonymous mutations were only seen in the Mumbai isolates, namely nsP1-R491W, nsP2-N442D, nsP2-F764L, nsP3-T459M, E2-K221R, and E2-H351R. Five non-synonymous mutations were of importance as they were mainly seen only in the Mumbai isolates along with 50 per cent occurrence in the Delhi isolates, namely nsP1-V103A, nsP1-M314L, nsP1-G230R, E1-K211E, and E2-V264A. The results revealed that in Mumbai strains, the mutations were more or less stabilized, whereas Delhi isolates were distributed as two separate groups, with these mutations present in one and absent in the other group. This result provides evidence that the major outbreaks observed in these regions might be attributed to different strains of CHIKV. We constructed a median-joining network of the Indian isolates used in this study using the POPART tool (Leigh, Bryant, and Nakagawa 2015), and it is depicted in Fig. 5. This network was used to visualize genealogical relationships at the intraspecific level. Numbers between strains represent the variation between them.

Epidemic vs. episodic strain mutation analysis
There were two epidemic phases of CHIKV in India in 2010 and 2016. With respect to outbreak-specific mutations, we observed unique mutations in isolates from both outbreaks. Between these years, CHIK occurred as episodic events during 2011-3. To understand the impact of mutations during the outbreaks and episodic events, we compared the inter-episodic mutations with those during the outbreaks of 2010 and 2016. Our analysis revealed that the inter-episodic events clustered together away from the two epidemic outbreaks in 2010 and 2016 (Fig. 4). A total of twenty-seven non-synonymous mutations were present, twelve in non-structural protein genes and fifteen in structural genes (Supplementary Table S3). Interestingly, in all the other samples from 2011 to 2013, six unique mutations, namely nsP1-R491W, Figure 3. Hierarchical clustering of non-synonymous mutations in CHIK samples. A total of thirty-nine non-synonymous mutations was observed in the structural (E1, E2, E3, C, and 6K/TF) and non-structural (nsP1, nsP2, nsP3, and nsP4) protein genes in a total of forty-one samples collected between 2010 and 2016. The blue colour represents the absence of mutation in the respective sample, while the red colour shows the mutation's presence.

Selection pressure analysis
After identifying mutations, we performed selection pressure analysis of Indian strains to understand the potential impact of mutations on recent outbreaks. Selection pressure analysis performed using all Indian strains (n = 99) revealed several sites in the CHIKV genome under purifying selection ( Table 2). The low non-synonymous/synonymous (dN/dS) ratio suggested purifying selection in the non-structural gene open reading frame. In total, sixteen amino acids positions were found to be positively selected by the single-likelihood ancestor counting (SLAC) method, fourteen by mixed-effect model of evolution (MEME) method, fourteen by fixed-effect likelihood method (FEL) and twelve by fast, unconstrained Bayesian approximation for inferring selection (FUBAR) method (Table 2).

Discussion
We analysed the genetic diversity in the CHIKV genomes obtained directly from the serum samples of patients between 2010 and 2013, and then again in 2016. These years are important, as the pattern of CHIKV outbreaks was quite diverse. The year 2010 witnessed a huge outbreak, and in the following years, there were very few cases (Jain et al. 2017). Thereafter, the year 2016 again saw a huge outbreak (Kaur et al. 2017;Jain et al. 2020). Multiple waves of CHIKV infection have occurred over the past two decades both in India and across the globe, with outbreaks traced from Africa to Southeast Asia, South Asia, and the Americas. Both the Asian and ECSA genotypes have been implicated in these outbreaks (Rezza 2014;Sahadeo et al. 2017). Historically, in India, the Asian genotype was present during the earlier outbreaks in the 1960s and 70s, but the ECSA has been the causative genotype for recent outbreaks, as seen in other Asian countries, such as Malaysia, China, and Indonesia (Dash et al. 2007;Sam et al. 2015;Zeller, Van Bortel, and Sudre 2016). Our phylogenetic analyses reveal that there has been a reintroduction of the virus into the country in addition to local transmission.
Deep sequencing analysis revealed novel insights into the seemingly non-random nature of variants that are present at higher frequencies (>20 per cent) among the geographic population in the country. The fact that a subset of these minor variants is observed across multiple strains is of interest. How these highand low-frequency variants contribute to viral evolution, host specificity, and/or the host innate and adaptive immune response over time is largely unknown and warrants additional investigation. Previous genomic analyses of CHIKV have reported amino acid substitutions in structural and non-structural genes ranging from two to thirty-two (Stapleford et al. 2016;Silva and Dermody 2017). In the present study, variations in the structural and non-structural genes ranged up to 39, with more mutations observed in the non-structural genes. In the case of the envelope proteins, substitutions such as E1-K211E, E2-G55R, E2-H73Y, E2-V264A, E3-V42I, and E3-P59S have implications for neurovirulence during pathogenesis (Barr and Vaidhyanathan 2019;Cardoso et al. 2019). With respect to non-structural proteins, we observed variants such as nsP1-G230R and nsP3-STOP524R in our samples that have been implicated in increased replication and fitness (Jones et al. 2017;Mounce et al. 2017).
Of special interest are the genetic characteristics among CHIKV isolates in the 2016 outbreak in comparison with those of the outbreaks in previous years. Comparison between the 2016 and 2010 outbreaks have been well characterized in a previous study (Jain et al. 2020); however, the 2016 outbreak shows distinct differences even with the isolates from the years 2011, 2012, and 2013. Our further analysis suggests that the 2016 outbreak could have resulted from a new introduction event rather than from ongoing local transmission. Selection analysis of the viruses from these outbreaks further revealed a low ratio of non-synonymous to synonymous substitution in most comparisons, which may indicate that CHIKV populations in nature are generally subject to strong purifying selection (Zanotto et al. 1996;Yang et al. 2000). Significantly lower rates of nucleotide substitution have been observed in vector-borne compared to other RNA viruses (Jenkins et al. 2002).
In summary, we report a large number of CHIKV complete genome sequences collected from the Delhi and Mumbai regions of India, revealing the epidemiological and evolutionary dynamics of the CHIKV ECSA genotype in India since its first re-emergence in 2005.

Samples pre-processing
Recruited patients were part of previous studies funded by the Department of Biotechnology and Department of Science and Technology, Government of India (Jain et al. 2017(Jain et al. , 2020Kaur et al. 2017). Details of samples used in the present study are provided in Table 1. Viral RNA was isolated directly from patient sera using the High Pure Viral Nucleic Acid kit (Product No: 11858874001; Roche, Germany) according to the manufacturer's instructions. The integrity of RNA was estimated using the bioanalyser, and those samples with an RNA integrity number value of 8 was taken for further processing.

Illumina sequencing
Viral nucleic acid fragmentation, first-and second-strand complementary DNA synthesis and amplification, cluster formation, and paired-end fifty base sequencing on an IlluminaHiSeq 1000 were performed as described previously (Sahadeo et al. 2017). Briefly, viral RNA was fragmented by incubation at 94 • C for eight minutes in 19.5 µl of fragmentation buffer (Illumina, Inc., San Diego, CA). First-and second-strand complementary DNA synthesis, adapter ligation, and amplification of the library were performed using the IlluminaTruSeq RNA Sample Preparation kit v2 under conditions prescribed by the manufacturer (Illumina Inc., San Diego, CA). Cluster formation of the library DNA templates was performed using the TruSeq PE Cluster Kit v3 (Illumina Inc., San Diego, CA) and the IlluminacBot workstation using conditions recommended by the manufacturer. Paired-end fifty base sequencing by synthesis was performed using TruSeq SBS kit v3 (Illumina Inc., San Diego, CA) on an IlluminaHiSeq 1000 using the manufacturer's protocol. Cluster density per lane was 820-940 k/mm 2, and post-filter reads ranged from 148 to 218 million per lane.

Sequence analysis
Adapters were removed by the Cutadapt tool (Martin 2011) from all the samples. To assemble complete genomic sequences, we assessed the quality of the paired-end reads using FastQC (https:// www.bioinformatics.babraham.ac.uk/projects/fastqc/); low base quality ends including untranslated regions were trimmed using the FASTX tool kit (http://hannonlab.cshl.edu/fastx_ toolkit/). The remaining paired-end reads were aligned to an Indian strain isolated during an outbreak in 2006 (accession no. FJ000068), using Burrows-Wheeler Alignment (BWA) and default parameters. The reference sequence was the first genome that was submitted to Genbank after CHIKV re-emergence in India. The complete sequences of all samples have been submitted to Genbank (Table 1). An additional 753 CHIKV complete genomic sequences were retrieved from the ViPR (Pickett et al. 2012) that includes seventy-two Indian sequences and 681 sequences from

Phylogenetic analysis
A dataset of 794 whole genome sequences were inferred for evolutionary relationship. All sequences were aligned using CLUSTALW software. The midpoint rooted phylogenetic tree analysis was done using the MEGAX (Kumar et al. 2018) software with ML methods, and bootstrap values were determined using 1000 replicates. Furthermore, a set of ninety-nine whole genomes of CHIKV (Indian isolates) reported from different regions of India between 2005 and 2016 was analysed for different evolutionary models using the MEGAX software to find the best-fit model of nucleotide substitutions for the sequence alignment before proceeding with the evolutionary analysis. The iTOL https://itol.embl.de/ (Interactive Tree Of Life (embl.de)) software has been used to visualize the phylogenetic tree. The neutrality of mutations in the sequences was determined using Tajima's D test.

Nucleotide substitution rate, divergence times, recombination, and geographical structure of CHIKV
Bayesian Evolutionary Analysis Sampling Tree (BEAST2; Bouckaert et al. 2014) was used to calculate the phylogenetic relationships and the time to the most recent common ancestor for the coding region of all ninety-nine Indian CHIKV sequences. The necessary parameters and data were prepared in XML format using BEAUti version 2. The general time reversible (GTR) substitution model was selected with all estimated base frequencies and the gamma + invariant site heterogeneity model. BEAST2 was run using relaxed uncorrelated models. Multiple combinations of molecular clocks and coalescent models based on Bayes factor (>1) were run for the chain length of 100 million with a tree sampling every 10,000 chains, which was adequate to achieve stationarity. The time to the most recent common ancestor and the nucleotide substitutions per site per year were estimated. Using Tracer version 1.7.1, the Markov chain Monte Carlo steps and convergence of the runs were visualized as used to ensure stationarity was achieved, and TreeAnnotator version 2.6.0 was used to summarize the posterior tree distribution and generate the MCC tree. The phylogenetic tree with estimated divergence, Table 2. Summary of positively selected amino acid positions from the present study. posterior probability, 95 per cent highest posterior density, and variable timeline was generated and displayed using Figtree 1.4.2 (http://tree.bio.ed.ac.uk/software/figtree/). Bayesian hierarchical clustering of the phylogenetic tree was visualized and edited in DensiTree software of BEAST2 package. Determination of potential recombinant events, parental sequences, and localization of recombinant break points were performed triplet by triplet using the recombination detection program (RDP4; Martin et al. 2015) GENECONV, MaxChi, CHIMAERA, SiScan, and 3SEQ. The sequences were set to linear, and P values <0.05 were considered statistically significant.
Shannon entropy calculations were performed to identify the highly variable sites within each amino acid sequence with high entropy values. We used forty-one whole-genome sequences of CHIKV strains from our study for this analysis. The BioEdit 7.2 (https://bioedit.software.informer.com/7.2) stand-alone version was used to calculate the Shannon entropy of each amino acid site. A cut-off value of 0.2 was set, and the sites with values >0.2 were considered to be variable.

Variant analysis
Single-nucleotide polymorphism variants were identified using the Snippy variant identification tool (https://github.com/ tseemann/snippy). Variants were visualized using the network and hierarchical clustering to facilitate the identification and analysis of similarities and differences arising from genome comparisons. Hierarchical clustering was done using the Morpheus software (https://software.broadinstitute.org/morpheus). Furthermore, a worldwide analysis was done using the MEGAX software.

Selection pressure analysis
The selection pressure acting on CHIKV genomes was investigated using the online facility at the web server http://www.data monkey.org (Weaver et al. 2018). The complete data set of Indian strains (n = 99) with the ML statistical method has been used for this analysis. The ω ratios (non-synonymous (dN)/synonymous (dS)) substitutions) were calculated using methods such as SLAC, FEL, FUBAR, and MEME. Sites showing evidence of positive selection with a high statistical significance (P value <0.05 or Bayes factor >50) were considered to be under positive selection (Agarwal et al. 2016).

Data availability
The data were obtained from the publically available ViPR. Samples from this study have been submitted to the National Center for Biotechnology Information.

Supplementary data
Supplementary data is available at Virus Evolution online.

Funding
Financial support for this study was received from the Department of Biotechnology, Ministry of Science and Technology (BT/PR14725/AGR/36/672/2010 to S.S.), Government of India, and the For this work we have received funding from NIH (Grant no R24AI120942 to S.C.W. and R0AI153433 to A.J.A.).