Relatively semi-conservative replication and a folded slippage model for short tandem repeats.

BACKGROUND: The ubiquitous presence of short tandem repeats (STRs) in virtually all genomes implicates their functional relevance, while a widely-accepted definition of STR is yet to be established. Previous studies majorly focus on relatively longer STRs, while shorter repeats were generally excluded. Herein, we have adopted a more generous criteria to define shorter repeats, which has led to the definition of a much larger number of STRs that lack prior analysis. Using this definition, we analyzed the short repeats in 55 randomly selected segments in 55 randomly selected genomic sequences from a fairly wide range of species covering animals, plants, fungi, protozoa, bacteria, archaea and viruses. RESULTS: Our analysis reveals a high percentage of short repeats in all 55 randomly selected segments, indicating that the universal presence of high-content short repeats could be a common characteristic of genomes across all biological kingdoms. Therefore, it is reasonable to assume a mechanism for continuous production of repeats that can make the replicating process relatively semi-conservative. We have proposed a folded replication slippage model that considers the geometric space of nucleotides and hydrogen bond stability to explain the mechanism more explicitly, with improving the existing straight-line slippage model. The folded slippage model can explain the expansion and contraction of mono- to hexa- nucleotide repeats with proper folding angles. Analysis of external forces in the folding template strands also suggests that expansion exists more commonly than contraction in the short tandem repeats. CONCLUSION: The folded replication slippage model provides a reasonable explanation for the continuous occurrences of simple sequence repeats in genomes. This model also contributes to the explanation of STR-to-genome evolution and is an alternative model that complements semi-conservative replication.

Comparative analysis of microsatellites and compound microsatellites in T4-like viruses.

Microsatellites or simple sequence repeats (SSRs) are known to present ubiquitously in genomes of eukaryotes and prokaryotes, as well as viruses. A comprehensive analysis of microsatellites and compound microsatellites (CM) was performed for 67 T4-like bacteriophage genomes. We found that the number of repeats was generally proportional to the size of the genome. CM were more abundant in genic regions, while their relative abundance was higher in intergenic regions. Meanwhile, the number of CM rapidly decreased with the increase of complexity but gradually increased with higher dMAX (maximum distance between any two adjacent microsatellites). (A)n/(T)n, (AT)n/(TA)n and (AAG)n were the most abundant repeats of mono-, di- and trinucleotide microsatellites, respectively. The number of microsatellites in reference sequences was significantly lower than that in corresponding random sequences. This result was mainly attributed to mono- and dinucleotide repeats which hardly exceeded 6bp in T4-like viruses. These observations may be helpful to understand the distribution of microsatellites and viral genetic diversity in T4-like viruses.

The analysis of microsatellites and compound microsatellites in 56 complete genomes of Herpesvirales.

Simple sequence repeats (SSRs), or microsatellites, are special DNA/RNA sequences with repeated unit of 1-6 bp. The genomes of Herpesvirales have many repeating structures, which is an excellent system to study the evolution and roles of microsatellites and compound microsatellites in viruses. Therefore, 56 genomes of Herpesvirales were selected and the occurrence, composition and complexity of different repeats were investigated in the genomes. A total of 63,939 microsatellites and 5825 compound microsatellites were extracted from 56 genomes. It found that GC content has a significant strong correlation with both the counts of microsatellites (CM) and the counts of compound microsatellites (CCM). However, genome size has a moderate correlation only with CM and almost no correlation with CCM. The compound microsatellites occurring in genic regions are obviously more than that in intergenic regions. In general, the number of compound microsatellite decreases with the increase of complexity (C) (the count of individual microsatellites being part of a compound microsatellite) and the complexity hardly exceeds C=4. The vast majority of compound microsatellites exist in intergenic regions, when C≥10. The distributions of SSRs tend to be organism-specific rather than host-specific in herpesvirus genomes. The diversity of microsatellites and compound microsatellites may be helpful for a better understanding of the viral genetic diversity, genotyping, and evolutionary biology in herpesviruses genomes.

Survey and analysis of simple sequence repeats (SSRs) present in the genomes of plant viroids.

Extensive simple sequence repeat (SSR) surveys have been performed for eukaryotic prokaryotic and viral genomes, but information regarding SSRs in viroids is limited. We undertook a survey to examine the presence of SSRs in viroid genomes. Our results show that the distribution of SSRs in viroids may influence secondary structure, and that SSRs could play a role in generating genetic diversity. We also discuss the potential evolutionary role of repeated sequences in the viroid genome. This is the first report of SSR loci in viroids, and our study could be helpful in understanding the structure and evolution of viroid genomes.

Coevolution between simple sequence repeats (SSRs) and virus genome size.

BACKGROUND: Relationship between the level of repetitiveness in genomic sequence and genome size has been investigated by making use of complete prokaryotic and eukaryotic genomes, but relevant studies have been rarely made in virus genomes. RESULTS: In this study, a total of 257 viruses were examined, which cover 90% of genera. The results showed that simple sequence repeats (SSRs) is strongly, positively and significantly correlated with genome size. Certain repeat class is distributed in a certain range of genome sequence length. Mono-, di- and tri- repeats are widely distributed in all virus genomes, tetra- SSRs as a common component consist in genomes which more than 100 kb in size; in the range of genome < 100 kb, genomes containing penta- and hexa- SSRs are not more than 50%. Principal components analysis (PCA) indicated that dinucleotide repeat affects the differences of SSRs most strongly among virus genomes. Results showed that SSRs tend to accumulate in larger virus genomes; and the longer genome sequence, the longer repeat units. CONCLUSIONS: We conducted this research standing on the height of the whole virus. We concluded that genome size is an important factor in affecting the occurrence of SSRs; hosts are also responsible for the variances of SSRs content to a certain degree.

High GC content of simple sequence repeats in Herpes simplex virus type 1 genome.

The presence, locations and composition of simple sequence repeats (SSRs) in Herpes simplex virus type 1 (HSV-1) genome were extracted and analyzed by using the software Imperfect Microsatellite Extractor (IMEx). There were 663 mon-, 502 di-, 184 tri-, 20 tetra-, 4 penta- and 4 hexanucleotide SSRs that were observed in different distribution between coding and noncoding regions in the HSV-1 genome. G/C, GC/CG, and (GGC)(n) were predominant in mononucleotide, dinucletide, trinucleotide repeats respectively. Indeed, the results showed that GC content in simple sequence repeats was notably higher than that in entire HSV-1 genome. Our data might be helpful for studying the pathogenesis, genome structure and evolution of HSV-1.

Microsatellites in different Potyvirus genomes: survey and analysis.

Simple sequence repeats (SSRs) have been extensively used for various genetic and evolutionary studies in eukaryotic and prokaryotic organisms, while few relevant researches have been made in viruses. The Potyvirus is a fine system to study roles and evolution of SSRs in viruses. The densities, relative abundances, compositions and evolutionary inferences of SSRs in 45 different Potyvirus genomes have been analyzed in this study. Results showed that the densities and relative abundances of SSRs are similar in all those Potyvirus genomes. The number of SSRs decreases with an increase in the length of repeat unit. Dinucleotide repeats are the most abundant and followed by trinucleotide repeats, and the numbers of tetra-, penta- and hexanucleotide repeats are very small. Repeats of AC/CA, AG/GA and AAG/GAA predominate, whereas repeats of CG/GC, ATA and CAC are rare. The genome sizes of the Potyvirus species have little influence on the total number and relative abundance of SSRs. Our study suggested that the variety of SSRs may be related to the genome diversity of Potyvirus. Maybe Potyvirus and HIV genomes have the similar evolution mode and parallel evolution level.