This study was approved by the Medical Ethics Committee of Qilu Hospital, Shandong University (Approval No. LL2021120). All participants provided written informed consent in accordance with the Declaration of Helsinki.

Blood samples were collected from six suspected SFTS patients in Jinan, Shandong Province. Following storage at −4°C for 1–2 h, the samples were centrifuged at 12,000 rpm for 10 min at 4°C. The resulting supernatants were stored at −80°C until further processing. Viral RNA was extracted using the QIAamp Viral RNA Mini Kit, and SFTSV detection was performed using a commercial nucleic acid quantitative detection kit, with Ct values ≤ 35 considered positive. Positive samples were submitted to Shanghai Berger Medical Technology Co., Ltd. for whole-genome sequencing using an Illumina platform. Sequencing data were analyzed through an in-house bioinformatics pipeline to generate SFTSV consensus sequences, with quality control parameters including genome coverage and sequencing depth. Reference-based assembly was performed using BWA-MEM alignment against the HB29 reference strain (GenBank: NC_018136.1-NC_018136.3). Consensus sequences were constructed only when meeting the following quality thresholds: ≥ 10 × coverage depth and ≥ 70% major base frequency at each position.

Complete genome sequences of SFTSV were retrieved from the ViPR and GenBank databases (data current as of July 2023), including associated metadata containing accession numbers, collection dates, geographic locations, sequence lengths, host information, and sample types. The dataset consisted of 1,407 L segment sequences, 1,424 M segment sequences, and 1,598 S segment sequences. The classification information of the dataset is attached in Supplementary Table 1. These sequences, along with our newly generated SFTSV sequences, were stored in FASTA format. Additionally, the HB29 reference strain (GenBank accession numbers NC_018136.1-NC_018138.1) was obtained from the RefSeq database.

Phylogenetic analysis was conducted on three datasets, with nucleotide substitution models selected using jModeltest (Nguyen et al., 2015). Maximum likelihood trees for the L, M, and S segments were constructed in IQ-TREE (v2.1.4) with 1,000 bootstrap replicates (Yu et al., 2017) and visualized using the R package ggtree (Martin et al., 2010). Recombination analysis was performed using Recombination Detection Program 4 (RDP4), which incorporates seven detection algorithms (RDP (Salminen et al., 1995), Bootscan (Posada and Crandall, 2001), Chimera (Boni et al., 2007), 3Seq (Smith, 1992), GENECONV (Wong et al., 2010), Lard, and SiScan). Sequences were considered recombinant when identified by four or more methods with statistical significance (P < 0.05). The sequences were compared against a reference dataset of established genotypes. Putative reassortant strains were then identified based on incongruent phylogenetic placements across the three segments. Specifically, a strain was classified as a potential reassortant, which were defined by their possession of a mosaic genome where at least two of the three segments originated from divergent genotypes. Potential reassortant strains, defined as containing two or more segments of distinct genotypes, were identified through comparative phylogenetic analysis of the L, M, and S segments.

Genetic distances for the three viral segments were calculated using the pairwise distance function in MEGA (v11.0) with the p-distance model. Nucleotide and amino acid sequence homology analyses for the L, M, and S segments were conducted using the Alignment-Sequence Identity Matrix function in BioEdit. Additionally, we employed the Nei-Gojobori method in MEGA to estimate non-synonymous (dN) and synonymous (dS) substitution rates for all three segments.

The Nucleotide composition function of the CALcal website¹ and CodonW (v1.4.4) were used to analyze several indices, including the GC content of the codon third position (GC3s), the base composition at the third codon-position (A3, U3, C3, and G3), and the codon GC content.

Relative Synonymous Codon Usage (RSCU) for the SFTSV genome was calculated using the RSCU Function of the CALcal website. The RSCU values were calculated by the following formula:

Where g_ij represents the count of the ith codon for the jth amino acid, and n_i is the total occurrence of the ith codon for that amino acid (Nakamura et al., 2024; Sharp and Li, 1986).

The effective number of codons (ENC) was computed to assess synonymous codon usage bias (Comeron and Aguadé, 1998). The ENC for each protein of the SFTSV strain was calculated using CodonW, following the formula below:

Fi (where i = 2, 3, 4, 6) represents the average values of Fi for the i-fold simplified amino acids, defined as:

ENC-Plot was utilized to evaluate the primary factors affecting codon usage bias. Expected ENC values were calculated by the following formula:

Where s represents the GC3 content. If the points on the graph align with the standard curve, it suggests that gene evolution is primarily driven by mutational pressure. Conversely, points deviating from the curve indicate with a low ENC value, suggest that codon preference may also be influenced by additional factors, such as natural selection (Wright, 1990).

To assess the relative contributions of natural selection and mutational pressure on codon usage bias, we performed Parity Rule 2 (PR2) analysis. We generated a scatter plot with A3/(A3+U3) as the x-axis and G3/(G3+C3) as the y-axis, where the central point (0.5, 0.5) represents perfect parity (A = U and G = C) according to PR2. Coordinates at this origin indicate an equilibrium state where mutational pressure and natural selection exert equal influence on codon usage.

To further evaluate the relative contributions of mutational pressure versus natural selection in shaping codon usage patterns, we performed neutrality analysis. This approach examines the relationship between GC content at first and second codon positions (GC12, y-axis) and GC content at third synonymous sites (GC3s, x-axis) through linear regression analysis. The stronger the correlation between GC12 and GC3, the closer the slope of the regression curve approaches 1, indicating that codon usage bias is primarily influenced by mutation pressure. Conversely, a smaller slope of the regression line implies a greater role of natural selection pressure in shaping codon usage preferences.

We performed principal component analysis (PCA) to identify major variation patterns in codon usage (Sueoka, 1988). The analysis incorporated relative synonymous codon usage (RSCU) values from four SFTSV genes, with each gene represented as a 59-dimensional vector corresponding to its synonymous codon RSCU values. The first two principal components were analyzed to determine the primary factors influencing codon usage bias, including both mutational pressure and natural selection forces. The differences in genotype distribution were assessed using PERMANOVA.

The Codon Adaptation Index (CAI) quantifies the similarity between viral codon usage patterns and those of the host’s cellular machinery, with values ranging from 0 to 1. Values approaching 1 indicate optimal codon adaptation and potentially higher gene expression efficiency. Conversely, the Relative Codon Deoptimization Index (RCDI) assesses the divergence between viral codon usage and host reference genes, where values near 1 suggest greater codon usage similarity between virus and host. In this study, we calculated CAI and RCDI values for four SFTSV genes (L, M, NP, and NS) across seven host species: humans (Homo sapiens), domestic cats (Felis catus), dogs (Canis lupus familiaris), sheep (Ovis aries), hedgehogs (Erinaceus europaeus), raccoons (Procyon lotor), and ticks (Ixodes scapularis). Host codon usage tables were obtained from the CoCoPUTs database (Athey et al., 2017), and all indices were computed using the CAIcal web server (Hoxie and Dennehy, 2021).

RT-qPCR analysis yielded Ct values of 19.31, 20.08, 23.02, 28.41, 27.96, and 21.06 for the six serum samples. Subsequent sequencing using the Illumina MiSeq platform generated total read counts ranging from 9,453,765 to 38,737,189, with 32.2 to 32.9% of the reads aligning to the reference genome sequence. Among the six samples, the L, M, and S fragments of SFTSV achieved 100% genome coverage at a sequencing depth of 100 × .

Using jModelTest, we identified the GTR+G nucleotide substitution model as the optimal fit for all three SFTSV gene fragments. Among the six strains isolated from SFTS patient serum samples in this study, five (SD2023–1, SD2023–2, SD2023–3, SD2023–4, and SD2023–5) were classified as clade C3, while SD2023–6 belong to clade C1 (Supplementary Figures 1–3). Phylogenetic analysis revealed that SFTSV strains segregated into nine clades (C1-C6 and J1-J3; Supplementary Figure 4). Clades C2 and C4 contained the highest number of sequences, whereas clades J1 and J2 exhibited the broadest host diversity, encompassing human, cat, tick, dog, and hedgehog isolates. Geographically, SFTSV sequences from China predominantly clustered within the C lineage, while those from Japan and Korea primarily belong to the J lineage, with J1 as the dominant genotype-a group that also included certain strains from Zhejiang and Henan, China.

As reported previously (Zhang et al., 2024), we detected 99 potential recombination events among 89 strains using RDP4 software (Supplementary Table 2). Recombination events were more prevalent in human-derived samples (75/89) than in tick and livestock samples (10/89). Among the newly sequenced samples in this study, only the L fragment of the viral strain SD3 exhibited recombination. However, no reassortant strains were identified in the analyzed samples (Supplementary Figure 5; Ding et al., 2013; Lv et al., 2017; Yun et al., 2013; Zu et al., 2022).

Comparative sequence analysis with the reference strain revealed nucleotide and amino acid homology across all four open reading frames (ORFs). The results are presented in Table 1. The SFTSV strains demonstrated high sequence conservation, with nucleotide homologies of 97.9–100% (L segment), 87.8–100% (M segment), and 89.6–100% (S segment). At the amino acid level, homologies were 97.9–100% for RdRp, 92.7–100% for GP, 90.7–100% for NS, and 86.9–100% for NP (Supplementary Table 3). Genetic distances calculations showed the following values: 0.005 (range: 0.00–0.02) for the L segment, 0.015 (0.00–0.06) for the M segment, and 0.047 (0.00–0.11) for the S segment (Supplementary Table 4). Analysis of the six newly sequenced strains compared to the reference strain revealed amino acid homologies of 95.2–100% across all four proteins, with NP showing complete conservation (100%). These findings indicate that the NS gene displays significantly lower nucleotide and amino acid conservation compared to the RdRp and GP genes, consistent with its greater genetic distance relative to the L and M segments.

Global dN/dS analysis of the four SFTSV-encoded proteins was performed using MEGA 11.0 (Table 2). The analysis revealed dN/dS ratios of 0.06 for RdRp, 0.13 for GP, 0.02 for NP, and 0.18 for NS, with all values significantly below 1. These findings suggest that all four proteins have undergone strong purifying selection throughout evolution. Notably, the NSs protein exhibited the highest dN/dS value, while NP showed the lowest, indicating that NSs has been subject to relatively weaker purifying selection compared to the other proteins.

A comprehensive analysis revealed numerous recurrent mutations across RdRp, GP, NSs, and NP proteins. GP contained the highest number of mutations (70), followed by RdRp (65), NSs (26), and NP (3) (Supplementary Table 5). Among these, 27 were genotype-specific, and 9 were associated with SFTS mortality. We also identified novel mutation sites—18 in RdRp, 19 in GP, 9 in NS, and 1 in NP—highlighting previously unrecognized yet potentially significant mutational sites.

Sequence analysis further identified two conserved mutations present in all six specimens: R962S in the M segment (located within GP) and L197M in the NS segment (within NS). The NP segment exhibited the fewest amino acid mutations, with only the SD3 strain showing a V237A substitution. Additionally, strains SD4 and SD6 shared three identical mutations in the L segment (RdRp): K835R, T1038S, and A1433T. These conserved and co-occurring mutations suggest potential roles in viral adaptation or functional modulation.

The effective number of codons (ENC) values were 56.67 ± 0.71 for L, 52.19 ± 0.40 for M, 49.11 ± 3.18 for NP, and 50.20 ± 2.37 for NS, all significantly exceeding the threshold of 35 (Figure 1). The L protein exhibited the highest ENC value, indicatting the weakest codon usage bias, whereas NP showed the lowest ENC. Moreover, the mean ENC values for all four proteins (L, M, NP, and NS) varied significantly among genotypes (P < 0.05) (Figure 2).

We analyzed synonymous codon usage patterns in SFTSV by calculating relative synonymous codon usage (RSCU) values for the L, M, NP, and NS genes using CAIcal. The majority of codons exhibited RSCU values between 0.6 and 1.6, while 19 codons were identified as overrepresented (RSCU > 1.6) across the four genes. These overrepresented codons included CUC (leucine, Leu), CUG (leucine, Leu), AUC (isoleucine, Ile). Noblely, overrepresented codons (RSCU > 1.6) predominantly ended in U and C, whereas underrepresented codons (RSCU < 0.6) tended to end in A and G.

This study analyzed relative synonymous codon usage (RSCU) patterns in virulent SFTSV strains across multiple host species (humans, ticks, and dogs). Among overrepresented codons, 11 showed consistent usage across all hosts, including CUG, AUC, and UCA. Notably, arginine codons AGA and AGG maintained high expression levels in all four viral genes (L, M, NP, NS) regardless of host species. In striking contrast, histidine codons (CAU and CAC) displayed distinct host—and gene-specific expression patterns, revealing divergent and often opposing codon usage trends.

We performed principal component analysis (PCA) on relative synonymous codon usage (RSCU) values of 59 codons from the four SFTSV genes, stratified by genotype (Figure 3). The analysis revealed distinct contributions of the first and second principal components (PC1 and PC2) to codon usage variation. For the L gene, PC1 and PC2 accounted for 25.2 and 15.5% of the variance, respectively (P < 0.001); for the M gene, the contributions were 25.6 and 17.2% (P < 0.001); the NP gene exhibited contributions of 20.8 and 14.5% (P < 0.001); while the NS gene had contributions of 27.5 and 17.6% (P < 0.001). PC1 emerged as the dominant factor influencing codon bias across all genes, though no single component fully explained codon usage patterns. Genotype-specific clustering along principal axes aligned with phylogenetic analysis results. Notably, J1 strains exhibited greater dispersion in clustering, reflecting higher genotypic diversity compared to other genotypes.

Both PC1 and PC2 demonstrated correlations with multiple genetic parameters, including CAI, Codon Bias Index (CBI), Frequency of Optimal Codons (Fop), ENC, GC3s, GC, GRAVY scores, and aromaticity (Aromo). Most correlation coefficients between these parameters and either PC1 or PC2 were below 0.5. These findings suggest that SFTSV’s codon usage bias arises from the combined influence of multiple evolutionary factors rather than being dominated by any single parameter.

We conducted ENC-plot analysis to investigate the determinants of codon usage bias in SFTSV strains (Figure 4a). All four genes exhibited data points distributed below the standard curve, suggesting that SFTSV codon usage patterns are shaped by both natural selection and additional factors beyond mutational pressure. Notably, data points for the NS protein clustered nearer to the standard curve, implying a relatively stronger influence of mutational pressure. When analyzed by genotype, distinct clustering patterns emerged, with the NP gene displaying greater dispersion of data points compared to the other three genes.

Furthermore, we performed PR2 (Parity Rule 2) analysis to evaluate the relative contributions of mutational pressure and natural selection on codon usage patterns across the four SFTSV genes (Figure 4b). The majority of SFTSV strains plotted significantly distant from the graph’s central point (0.5, 0.5), demonstrating substantial combined effects of both mutational pressure and natural selection in shaping codon usage bias.

Through neutrality analysis (Figure 5), we quantified the relative contributions of mutational pressure and natural selection in shaping codon usage bias. Our results revealed a significant positive correlation between GC3 and GC12 content. Regression analysis demonstrated that mutational pressure accounted for only 0.49% (L gene), 1.00% (M gene), 6.29% (NP gene), and 17.68% (NS gene) of the observed variation. In contrast, natural selection dominated as the primary evolutionary force, contributing 99.51, 99.00, 93.71, and 82.32% to these respective genes. These findings clearly establish natural selection as the predominant driver of codon usage bias across all four SFTSV genes. Additionally, the NS segment exhibited the lowest dN/dS ratio, indicating it experiences weaker purifying selection compared to the other genes.

In this study, we calculated the Codon Adaptation Index (CAI) and Relative Codon Deoptimization Index (RCDI) values for SFTSV across seven host species (Figure 5). All analyzed genes (L, M, NP, and NS) exhibited CAI values > 0.5, indicating high translational efficiency potential. Notably, the L and M genes exhibited the highest CAI values in hedgehogs, with values of 0.813 and 0.823, respectively. In contrast, the NP and NS genes reached their maximum CAI values in dogs, at 0.772 and 0.792, suggesting higher protein synthesis efficiency in this host. Among examined hosts, the NP gene demonstrated highest adaptability to humans, while the NS gene showed the lowest. RCDI analysis revealed significantly higher values for the L gene compared to M, NP, and NS genes (Figure 6), indicating stronger codon usage similarity between the viral L gene and host genes. The remaining genes exhibited progressively lower similarity to host genes, with the following host similarity ranking: tick, cat, dog, sheep, human, raccoon, hedgehog.