Genomic diversity of SARS-CoV-2 in Malaysia

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Microbiology

Introduction

Despite world-wide control efforts, the COVID-19 pandemic continues to ravage many populations since it was first reported in December 2019. This protraction has been attributed partially to the emergence of SARS-CoV-2 mutants that have been linked with increased infectivity and the ability to resist host immune responses. The best known variants with global spread since their introduction include the UK variant B.1.1.7 N501Y that has been shown to have higher transmissibility and risk of death than the wild-type virus (Challen et al., 2021), the S. African variant B.1.351 20H/501Y.V2 with spike protein mutations that apparently led to more frequent and more serious infections among young adults with no underlying illnesses and decreased neutralisation by antibodies (Planas et al., 2021) and the Brazilian variant P.1 GR/501Y.V3 with unique mutations in the receptor binding domain of the spike protein that has been linked with greatly increased transmissibility, higher mortality and lower susceptibility to inactivation by anti-S antibodies (Planas et al., 2021).

In South-East Asia, Malaysia is one of the countries to report COVID-19 infections as early as January 2020 when a few cases were imported from China. Since then, local transmission and further importation from different parts of the world increased the number of confirmed cases to 115,078 (an incidence of 352.14/100,000) with 474 (0.41%) deaths by 1 January 2021 and 514 clusters of infection reported in the 12-month period (Fun et al., 2021). One of the largest was associated with a Tablighi Jamaat religious mass gathering held in Kuala Lumpur between February 27 and March 3, 2020, that was attended by about 16,000 people (10% foreigners from many different countries) and 34 deaths among 3,375 infected individuals (Fun et al., 2021). From this event, the infection was spread all over Malaysia and to neighbouring countries as well. Other prominent outbreaks included the Pesantren cluster in April that was linked to Malaysian students returning from a religious school in East Java, Indonesia, and the Sivaganga cluster in July-August that was traced to a Malaysian who returned from India carrying the D614G variant (Danial et al., 2020). Non-Malaysians were predominant in a few clusters among construction workers and inmates of prisons and immigration detention centres. From October 2020 onwards, increasing cases occurred in the East Malaysian states of Sabah and Sarawak causing the incidence and the effective reproduction number (Rt) of COVID-19 there to exceed those in Peninsular Malaysia (WHO, 2021). Up to April 2021, five infections by B.1.1.7 N501Y and 21 by B.1.351 20H/501Y.V2 were reported by the Ministry of Health, Malaysia (Malaymail, 2021a; Malaymail, 2021b).

In this paper, we analysed 277 genome sequences from Malaysian SARS-CoV-2 isolates to study the diversity of the viral genomes over time, and to monitor the emergence of mutations that could affect the ability of the virus to spread or to cause more severe illness. We specifically looked out for rapidly spreading mutants that have emerged in other countries.

Methodology

Ethics statement

This study received waiver on informed consent by the Ministry of Health Medical Research Ethics Committee (no. KKM/NIHSEC/ P20-1094).

Source of SARS-CoV-2 genomes

The 277 SARS-CoV-2 genomes analysed comprised 30 sequenced (Table S1) by the National Public Health Laboratory Malaysia (MKAK) and 247 lodged in GISAID (Elbe & Buckland-Merrett, 2017) by other Malaysian research institutions, namely, the Institute for Medical Research (IMR), the Malaysian Genome Institute (MGI) and public universities (University Malaya Medical Centre and University Malaya Pahang). The genomes downloaded from the GISAID database were accessed on 5 January 2021. They represented 421 genomes deposited at different time points in Malaysia throughout the year 2020.

At the MKAK, nasopharyngeal and oropharyngeal swabs from patients seen in public hospitals were used for virus isolation in Vero E6 cells. From each patient, the isolate from the earliest available sample during illness and yielding the highest viral load was selected for whole genome sequencing using the MiSeq platform. The sequencing reads were evaluated in FastQC (Andrews, 2010) and the data obtained were preprocessed in PRINSEQ (Schmieder & Edwards, 2011), according to the quality assessments in the FastQC. In brief, the sequences were quality processed with phred probability mean score of Q20, 5′ and 3′ ends clipping, reads deduplication, removal of reads containing ambiguous nucleotide and removal of trimmed reads <67 bp. The preprocessed data were subjected to assembly in MEGAHIT (Li et al., 2015).

Genome analysis

All 421 sequenced and downloaded genomes were screened for bases other than IUPAC non-ambiguous nucleotides. This process resulted in 277 genomes for comparisons. All these genomes were aligned against Wuhan-Hu-1(NCBI Accession: NC_045512.2; GISAID Accession: EPI_ISL_402125) in MAFFT (Katoh et al., 2002). The mutations and corresponding amino acid changes were evaluated manually in MEGA X (Kumar et al., 2018). The clonal compositions of SARS-CoV-2 were evaluated with Minimum-Spanning Tree of Phyloviz 2.0 (Francisco et al., 2012). All genomes that emerged from a single founder were considered as belonging to a single cluster. Genomic and gene diversity studies were performed in DNASP 6 (Rozas et al., 2017). Additionally, DNASP 6 was further utilized to infer linkage disequilibrium which is the degree of non-random association of alleles (D′). Besides allele frequency, the linkage disequilibrium was calculated by considering the correlation coefficient of variant frequency (r2) (VanLiere & Rosenberg, 2008). A strong association of mutations was predicted by an r2 value > 0.8 and a Fisher one-tailed test of significance value < 0.01. All analyses were conducted with default parameters.

Results

The genome analysis results based on Pangolin COVID-19 Lineage Assigner (https://pangolin.cog-uk.io/) showed 22 lineages with the lineage group B.1.524 forming the majority (107, 38.6%), followed by B.6 (41, 14.8%), B (22, 7.9%), B.1.129 (21, 7.6%), B.6.1 (20, 7.2%) and other smaller groups (Fig. S1). All genomes were aligned at least 99% against the Wuhan-HU-1 genome except for two with only approximately 94% alignment.

Mutations in SARS-CoV-2 from Malaysia

Of the 277 genomes that underwent genome-wide alignment, nine were found to be identical to Wuhan-Hu-1. Of these, four were from Malaysian patients with no history of travel outside the country.

Viewing site-wise mutations, a total of 359 positions with variants were predicted, 63.8% of which were found to be solitary across the genomes analysed. These mutations were observed within nine protein encoding genes and four non-coding sites. Approximately 60% of mutations were non-synonymous and 67% involved a base substitution to Thymine. The highest number of mutations predicted in one genome was 19.

The most frequently seen mutations are listed in Table 1. Those shared by at least 100 genomes were at 13 genome positions (241, 3037, 6312, 8637, 10124, 14408, 17518, 21516, 21622, 23403, 23664, 28133, and 28854) with eight non-synonymous mutations in the ORF1ab (T2016I, T2791I, T3287A, P4715L, L5752F), S gene (D614G, A701V) and the N gene (S194L) respectively. The mutations shared by 50–99 genomes were at five positions (6312, 11083, 13730, 23929, and 28311). The non-synonymous mutations were in the ORF1ab (T2016K, L3606F, A4489V) and N (P13L). At the 6312 position there were two mutations, one with a T2016I (C- > T) change that was shared by >100 genomes and a second with a T2016K (C- > A) change that was shared by only 85 genomes. Excluding the substitution at position 241 in the 5′ UTR, the top three most frequent mutations were the C3037T (59.9%), C14408T (59.9%) and A23403G (D614G) (57.4%). These three mutations were reported to be found in SARS-CoV-2 genomes worldwide SARS-CoV-2 genomes worldwide.

Table 1:
Mutations in at least 50 genomes of SARS-CoV-2.
Nucleotide substitution position Impact of mutation Gene Number of strains
241 5′UTR 162
3037 Synonymous ORF1ab 168
6312 T2016I ORF1ab 106
8637 T2791I ORF1ab 106
10124 T3287A ORF1ab 107
14408 P4715L ORF1ab 166
17518 L5752F ORF1ab 106
21516 Synonymous ORF1ab 107
21622 Synonymous S 107
23403 D614G S 159
23664 A701V S 107
28133 Synonymous ORF8 107
28854 S194L N 112
6312 T2016K ORF1ab 85
11083 L3606F ORF1ab 91
13730 A4489V ORF1ab 87
23929 Synonymous S 81
28311 P13L N 82
DOI: 10.7717/peerj.12449/table-1

Less frequent mutations (Table S2) included a unique 2 bp-deletion in ORF8 (genomic position 28066–28067) that was found in only one genome, and the mutations (C6310A, T7621C and C19524T) reported by neighbouring countries such as Singapore, Australia, and India (Chong et al., 2020). There was only one genome each with the T8782C and C28144T mutations that have been used to distinguish the type B variant predominant in East Asia from the type A variant predominant in North America and Europe (Forster et al., 2020)

Identification of super spreader mutations

We specifically looked for mutations that have been linked to increased transmission in various countries. As shown in Table 1 above, the D614G amino acid substitution in the S spike protein was observed in 159 of 277 (57.4%) genomes. Based on the isolation dates in GISAID, this mutation was present in the viruses isolated in March 2020, suggesting that D614G was present in Malaysia before it was first reported in the Sivaganga cluster in July-August 2020. None of our D614G mutations were accompanied by the S477N substitution noted to be frequently alongside D614G in the S protein (Singh et al., 2021). We did not find the genomes of the UK, S. African and Brazilian super spreaders, although the E: P71L and S: A701V mutations defining the S. African variant B.1.351 501Y.V2 were found separately, in one and 107 genomes, respectively.

Clonality and diversity of SARS-CoV-2 genomes

The genomic variations of the 277 SARS-CoV-2 genomes were summarized with the goeBURST full Minimum Spanning Tree algorithm designed to detect clusters defined by genetic sequence similarities (Fig. 1). The analysis indicated 115 groups, of which 13 formed clonal complexes. There were 178 sequence types (STs) with 26 being subgroup founder’s STs. The clonal complexes were not related to the month of virus isolation, or to other epidemiological features described for the outbreaks in different communities.

Diversity illustration of SARS-CoV-2 in Malaysia generated in Minimum Spanning Tree (MST).

Figure 1: Diversity illustration of SARS-CoV-2 in Malaysia generated in Minimum Spanning Tree (MST).

Each node represents either a strain or group of strains and linked based on MST. “D#” denotes downloaded genome and “S#” denotes genome sequenced in this study.

We further evaluated the trend of diversity in the SARS-CoV-2 genomes (Fig. 2). In 2020, the viral genomic diversity (the average number of nucleotide differences per site between sequences and its sampling variance) increased from 2.18 × 10−4 in the first quarter of the year to 3.34 × 10−4 in the second quarter and 3.86 × 10−4 in the third quarter before it fell to 3.65 × 10−4 in the final quarter. The mean genomic diversity was 3.26 ×10−4.

Graph of SARS-CoV-2 diversity in Malaysia in 2020.

Figure 2: Graph of SARS-CoV-2 diversity in Malaysia in 2020.

Although the number of viral genomes analyzed in this study was small, the changes in diversity reflected major events in the country. Early in 2020, the diversity value was low because there were only a few viruses in circulation. A steep incline in diversity soon occurred with the spread of infections and hence opportunities for mutations to occur in the local population, and further importation from other countries which would have brought in different lineages and genetic variants of the SARS-CoV-2 virus. From August to December, although the number of reported cases increased, virus diversity showed a decline. The reason could be that the genomes we analyzed were mostly from a few large clusters and did not include new cases responsible for the spike in infections in Sabah towards the end of the year, as there were no SARS-CoV-2 genomes from Sabah in GISAID at the time we accessed the database.

To study nucleotide diversity of the SARS-CoV-2 genes affected by mutations, we looked at the genes for the four structural proteins E (envelope), M (membrane), N (nucleocapsid), S (spike), and the ORFs (open-reading frames). Figure 3 shows the diversity indices of eight genes which were, in descending order, 1.7 × 10−3 (N), 1.69 × 10−3 (ORF8), 0.79 × 10−3 (ORF3a), 0.61 ×10−3 (S), 0.49 ×10−3 (M), 0.41 ×10−3 (ORF1ab), 0.14 × 10−3 (ORF7a) and 0.13 ×10−3 (E). The N, E, S and ORF1ab are genes often used in RT-PCR assays for the diagnosis of COVID-19. A high diversity in the N gene is expected to decrease its sensitivity in these assays (Hasan et al., 2021). The high diversity in ORF8 is consistent with reports describing it as a rapidly evolving gene (Ceraolo & Giorgi, 2020). Similarly, the lower diversity values in the M and ORF7a genes are not surprising as these genes have been reported to be stable genes that are suitable targets for vaccine development (Nguyen et al., 2020). There were 16 non-structural proteins (nsp) coded in ORF1ab. Both nsp1 and nsp11 showed a diversity index of 0, indicating high nsp conservation in the genomes. The most diverse nsp was nsp16 (diversity of 8.99 ×10−4). The diversity indices of the remaining nsp ranged from 4.47 ×10−5 to 6.17 ×10−4.

Gene Diversity of SARS-CoV-2 in Malaysia.

Figure 3: Gene Diversity of SARS-CoV-2 in Malaysia.

Nucleotide substitution association analyses

The temporal study on viral mutations showed that in January and February 2020, there were only a few mutations. From March to December, substitutions appeared consistently at the genomic positions C241T, C3037T, C14408T and A23403G. In addition, 10 more mutations appeared from September to December. These mutations were C5869T, C8637T, A10124G, C17518T, C21365T, C21516T, C21622A, C23664T, A28133T and C28854T. Two mutations, C13730T and C23929T were noted to be present in viruses isolated in March to August. At the genomic position of 6312, one mutation was observed in March to August (C6312A) and another appeared from September to December (C6312T). Month-specific mutations were the highest in May and not in November and December, the two months with the largest number of reported cases (Fig. 4).

Heatmap of mutations in SARS-CoV-2 against months.

Figure 4: Heatmap of mutations in SARS-CoV-2 against months.

The number in each cell indicates the number of strains having the mutation.

When we checked for non-random mutational associations, we hypothesized that non-random association of mutations should be present in accordance with the frequency of occurrence. For this, we inferred based on r2 and supported with Fisher one-tailed test of significance on the parsimony informative sites. The analyses returned seven sets of non-redundant site comparisons above the threshold with the r2 ranging from 0.8 to 1.0 and with coefficient of linkage disequilibrium (LD) ranging from 0.93 to 1.0 (Table S3). All the positions identified were supported with a p-value of 0. The first LD set was observed in the viruses isolated in October 2020, at the genomic positions of A1904G, C12488T and G23236T. They were all non-synonymous mutations in ORF1ab. The second LD set comprised C3037T, C14408T and A23403G mutations in viruses isolated from March to December and involving a single synonymous and non-synonymous mutation in ORF1ab, together with a single non-synonymous mutation in the S protein. These are the mutations also reported by others (Rouchka, Chariker & Chung, 2020) to be linked. The third LD set was found in eight genomic positions, namely C8637T, A10124G, C17518T, C21516T, C21622A, C23664T, A28133T and C28854T. Except for C21516T, C21622A and A28133T, all were non-synonymous mutations, spanning ORF1ab, S protein, ORF8 and N protein in viruses isolated from September to December 2020. The fourth LD set involved four mutations across three different proteins, at the genomic positions of G11083T, C13730T, C23929T and C28311T. The mutations were synonymous in the S protein, non-synonymous in N protein and non-synonymous in two positions in the ORF1ab. The fifth LD set involved genomic positions C13329T, C20823T, C26607T and A29086T. C20823T and A29086T caused non-synonymous mutations in the ORF1ab and N genes respectively, in viruses isolated in May and June. In the sixth LD set, C18877T, C26735T and G25563T were observed, the former two as synonymous mutations in ORF1ab and M protein, respectively, and the third as a non-synonymous mutation in ORF3a. Lastly, LD was observed in C24382T and G28307T causing a synonymous mutation in the S protein, and a non-synonymous mutation in the N protein, respectively. All in, the LD sets involved 21 non-synonymous and eight synonymous mutations in the ORF1ab, ORF8, ORF3a, M, N and S genes. While the LD sets were observed to be associated with the month of virus isolation, they were not clustered in the Minimum Spanning Tree.

Discussion

The World Health Organisation has strongly advocated routine genomic surveillance for the SARS-CoV-2 virus (WHO, 2021). A principal aim is to look out for new variants that might cause adverse consequences such as increased viral infectivity and virulence, resistance to therapeutic agents, and immune evasion. As countries world-wide adopt vaccination to end the COVID-19 pandemic, many fear that under vaccine pressure, SARS-CoV-2 variants will emerge with new strategies to escape vaccine-induced immunity.

The diversity of SARS-CoV-2 is analysed to understand its pathogenicity, origin, and evolutionary implications (Forster et al., 2020; Parlikar et al., 2020). In this study, we found a mean genomic diversity index of 3.26 ×10−4 for Malaysian viruses sequenced between January and December 2020. This value is lower than those reported by Flores-Alanis et al. (2021) for Asia (4.2 ×10−4) and six other geographical regions in the world (0.44 × 10−4). The generally low diversity in the SARS-CoV-2 virus has been noted by other researchers (Dearlove et al., 2020; Rauscha et al., 2020) and has been surmised to be due to the virus having an RNA polymerase with proofreading ability to correct errors during RNA synthesis (Ogando et al., 2019) as well as genetic drift and bottleneck events in the evolution of the virus (Rausch, 2020). Although low diversity is currently an advantage for vaccine design, it is expected that this landscape will soon be changed after the world-wide implementation of mass vaccination which would exert a tremendous immune pressure on the evolving virus.

As in most parts of Asia, the B lineage predominated among the 22 lineages identified in our Malaysian viral genomes. The largest lineage group was B.1.524 described in Pango Lineages as a Malaysian lineage that formed 65.0% and 26.0% of SARS-CoV-2 in Malaysia and Singapore, respectively, after it was first reported on 1 Sep 2020 (https://cov-lineages.org/lineages/lineage_B.1.html). Other major lineages (B.6, B.6.1, B.6.2 and B.6.6) were also those originally reported from India, Malaysia, and Singapore, possibly reflecting the frequent population movement among the three countries. There were more non-synonymous than synonymous mutations overall and among the LD sets. Among the mutation hotspots only D614G and A701V in the spike protein as well as P4715L and T2015I in ORF1ab are known to have a world-wide prevalence. Only one mutation, a 2 bp-deletion in ORF8, is possibly unique (not found among the genome sequences in GISAID).

The pattern of linkage disequilibrium (LD) in a genome is said to reflect the evolutionary history of an organism (Illingworth & Mustonen, 2012). We found seven sets of mutations showing LD, each with at least one non-synonymous mutation, distributed in the ORF1ab, ORF8, ORF3a, N, M and S genes. One of the LD sets included A23403G (D164G), C14408T and C3037T which were reported to be the most frequent mutations in many parts of the world (Nguyen et al., 2020; Rouchka, Chariker & Chung, 2020) and also found to be the most frequent mutations in this study. The linkage between D641G in the S gene and P4715L in ORF1ab is consistent with their presence together in >75% of global sequences (Flores-Alanis et al., 2021). While the LD sets were observed to be associated with the month of virus isolation, they were not clustered in the Minimum Spanning Tree, indicating independent evolution of each of the LD sets. As the linkages we observed were also reported by other researchers using different approaches and different cohorts (Rouchka, Chariker & Chung, 2020; Haddad et al., 2021), it is possible that the linked mutations might have evolutionary or survival significance in SARS-CoV-2. However, for most of the LD sets, we could not predict any association between the mutations showing LD and characteristics such as better adaptation to the host or potential for immune evasion.

This study is limited by the small number of SARS-CoV-2 genomes analyzed. Sampling bias could not be ruled out as it was not known how individual researchers selected the viral genomes they deposited in the GISAID database. As the downloaded genomes were only available in the form of assemblies in GISAID, we were unable to evaluate their quality and standardize the data preprocessing with the use of sequencing reads. There was also limited patient and epidemiological data on the genomes we analyzed. Thus, we were unable to discuss issues such as intra-host viral heterogeneity (Tang et al., 2020) or the association of genetic variations with viral infectivity and pathogenicity.

Conclusions

This sample of SARS-CoV-2 genome sequences showed that within the first year of its appearance in Malaysia, the virus appeared to have accumulated an abundance of mutations including one possibly novel mutation in ORF8. Continuous genomic surveillance will provide information on the evolutionary trend of the virus, but adequate coverage of the circulating viruses is necessary to generate truly representative viral genetic characteristics that can be used along with epidemiological data to guide public health control strategies. This would require more extensive genome studies to enable the capture of all important developments in the evolution of the SARS-CoV-2 virus.

Supplemental Information

Information on 30 Sequenced Genomes

DOI: 10.7717/peerj.12449/supp-1

Mutations in lesser than 50 genomes of SARS-CoV-2

DOI: 10.7717/peerj.12449/supp-2

List of linkage disequilibrium

DOI: 10.7717/peerj.12449/supp-3

Distribution of SARS-CoV-2 lineages included in this study

DOI: 10.7717/peerj.12449/supp-4
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