Opposite evolutionary effects between different alternative splicing patterns

Alternative splicing (AS) has been recognized as a mechanism of relaxing selection pressure on protein subsequences. Here, we show that AS may also yield contrary evolutionary effects. We compare the evolutionary rates of 2 types of alternatively spliced exons (ASEs)-simple and complex. The former does not change the boundaries of its flanking exons, whereas the latter does. By analyzing over 26,000 human-mouse orthologous exons, we demonstrate that complex ASEs have lower Ka and Ka/Ks ratio and higher Ks than constitutively spliced exons (CSEs), whereas simple ASEs have evolutionary rates to the opposite of CSEs. Our results indicate that complex ASEs are subject to stronger selection pressure than CSEs at the protein level, but the trend is reversed at the RNA level. Therefore, the previous view that ASEs accelerate evolution of protein subsequences needs to be modified.     

RNA editing by the host ADAR system affects the molecular evolution of the Zika virus

Zika virus (ZIKV) is a mosquito‐transmitted flavivirus, linked to microcephaly and fetal death in humans. Here, we investigate whether host‐mediated RNA editing of adenosines (ADAR) plays a role in the molecular evolution of ZIKV. Using complete coding sequences for the ZIKV polyprotein, we show that potential ADAR substitutions are underrepresented at the ADAR‐resistant GA dinucleotides of both the positive and negative strands, that these changes are spatially and temporally clustered (as expected of ADAR editing) for three branches of the viral phylogeny, and that ADAR mutagenesis can be linked to its codon usage. Furthermore, resistant GA dinucleotides are enriched on the positive (but not negative) strand, indicating that the former is under stronger purifying selection than the latter. ADAR editing also affects the evolution of the rhabdovirus sigma. Our study now documents that host ADAR editing is a mutation and evolutionary force of positive‐ as well as negative‐strand RNA viruses.     

Evolutionary origin of RNA editing

The term "RNA editing" encompasses a wide variety of mechanistically and phylogenetically unrelated processes that change the nucleotide sequence of an RNA species relative to that of the encoding DNA. Two general classes of editing, substitution and insertion/deletion, have been described, with all major types of cellular RNA (messenger, ribosomal, and transfer) undergoing editing in different organisms. In cases where RNA editing is required for function (e.g., to generate a translatable open reading frame in a mRNA), editing is an obligatory step in the pathway of genetic information expression. How, when, and why individual RNA editing systems originated are intriguing biochemical and evolutionary questions. Here I review briefly what is known about the biochemistry, genetics, and phylogenetics of several very different RNA editing systems, emphasizing what we can deduce about their origin and evolution from the molecular machinery involved. An evolutionary model, centered on the concept of "constructive neutral evolution", is able to account in a general way for the origin of RNA editing systems. The model posits that the biochemical elements of an RNA editing system must be in place before there is an actual need for editing, and that RNA editing systems are inherently mutagenic because they allow potentially deleterious or lethal mutations to persist at the genome level, whereas they would otherwise be purged by purifying selection.     

Positive selection signatures in the TLR7 family

While adaptive immunity genes evolve rapidly under the influence of positive selection, innate immune system genes are known to evolve slowly due to strong purifying selection. Among the sensors of the innate immune system, Toll-like receptors (TLRs) are particularly important due to their ability to recognize and respond to pathogen-associated molecular patterns (PAMP), such as lipopolysaccharides, peptidoglycans, and nucleic acids from bacteria or viruses. In the present study, we examine the evolutionary process that has operated on the TLR7 family genes TLR7, TLR8, and TLR9. The results demonstrate that the average Ka/Ks (the ratio between nonsynonymous and synonymous substitution rates) of each TLR family gene is far lower than one regardless of estimating methods, supporting previous observations of strong purifying selection in this gene family. Interestingly, however, analysis of Ka/Ks ratios along the coding regions of TLR7 family genes by sliding-window analysis reveals a few narrow high peaks (Ka/Ks > 1). The most prominent peak corresponds to a specific region in the ectodomain, which exists only in the TLR7 family, suggesting that this unique structure of the TLR7 family might have been a target of positive selection in a variety of lineages. Furthermore, maximum likelihood model tests suggest that positive selection is the best explanation for a certain fraction of the amino acid substitutions in the TLR9.     

Bendable genes of warm-blooded vertebrates.

It is shown that in the genomes of warm-blooded vertebrates the elevation of genic GC-content is associated with an increase in the bendability of the DNA helix, which is both absolute and relative as compared with random sequences. This trend takes place both in exons and introns, being more pronounced in the latter. At the same time, the free energy of melting (delta G) of exons and introns increases only absolutely with elevation of GC-content, whereas it decreases as compared with random sequences (again, this trend is stronger in the introns). In genes of cold-blooded animals, plants, and unicellular organisms, these regularities are weaker and often not consistent. Generally, there is a negative correlation between bendability and melting energy at any fixed GC-content value. This effect is stronger in the introns. These findings suggest that GC-enrichment of genes in the homeotherm vertebrates can be caused by selection for increased bendability of DNA.     

Selective constraints in cold‐region wild boars may defuse the effects of small effective population size on molecular evolution of mitogenomes

Spatial range expansion during population colonization is characterized by demographic events that may have significant effects on the efficiency of natural selection. Population genetics suggests that genetic drift brought by small effective population size (N_e) may undermine the efficiency of selection, leading to a faster accumulation of nonsynonymous mutations. However, it is still unknown whether this effect might be balanced or even reversed by strong selective constraints. Here, we used wild boars and local domestic pigs from tropical (Vietnam) and subarctic region (Siberia) as animal model to evaluate the effects of functional constraints and genetic drift on shaping molecular evolution. The likelihood‐ratio test revealed that Siberian clade evolved significantly different from Vietnamese clades. Different datasets consistently showed that Siberian wild boars had lower Ka/Ks ratios than Vietnamese samples. The potential role of positive selection for branches with higher Ka/Ks was evaluated using branch‐site model comparison. No signal of positive selection was found for the higher Ka/Ks in Vietnamese clades, suggesting the interclade difference was mainly due to the reduction in Ka/Ks for Siberian samples. This conclusion was further confirmed by the result from a larger sample size, among which wild boars from northern Asia (subarctic and nearby region) had lower Ka/Ks than those from southern Asia (temperate and tropical region). The lower Ka/Ks might be due to either stronger functional constraints, which prevent nonsynonymous mutations from accumulating in subarctic wild boars, or larger N_e in Siberian wild boars, which can boost the efficacy of purifying selection to remove functional mutations. The latter possibility was further ruled out by the Bayesian skyline plot analysis, which revealed that historical N_e of Siberian wild boars was smaller than that of Vietnamese wild boars. Altogether, these results suggest stronger functional constraints acting on mitogenomes of subarctic wild boars, which may provide new insights into their local adaptation of cold resistance.     

Widespread positive selection in synonymous sites of mammalian genes

Evolution of protein sequences is largely governed by purifying selection, with a small fraction of proteins evolving under positive selection. The evolution at synonymous positions in protein-coding genes is not nearly as well understood, with the extent and types of selection remaining, largely, unclear. A statistical test to identify purifying and positive selection at synonymous sites in protein-coding genes was developed. The method compares the rate of evolution at synonymous sites (Ks) to that in intron sequences of the same gene after sampling the aligned intron sequences to mimic the statistical properties of coding sequences. We detected purifying selection at synonymous sites in approximately 28% of the 1,562 analyzed orthologous genes from mouse and rat, and positive selection in approximately 12% of the genes. Thus, the fraction of genes with readily detectable positive selection at synonymous sites is much greater than the fraction of genes with comparable positive selection at nonsynonymous sites, i.e., at the level of the protein sequence. Unlike other genes, the genes with positive selection at synonymous sites showed no correlation between Ks and the rate of evolution in nonsynonymous sites (Ka), indicating that evolution of synonymous sites under positive selection is decoupled from protein evolution. The genes with purifying selection at synonymous sites showed significant anticorrelation between Ks and expression level and breadth, indicating that highly expressed genes evolve slowly. The genes with positive selection at synonymous sites showed the opposite trend, i.e., highly expressed genes had, on average, higher Ks. For the genes with positive selection at synonymous sites, a significantly lower mRNA stability is predicted compared to the genes with negative selection. Thus, mRNA destabilization could be an important factor driving positive selection in nonsynonymous sites, probably, through regulation of expression at the level of mRNA degradation and, possibly, also translation rate. So, unexpectedly, we found that positive selection at synonymous sites of mammalian genes is substantially more common than positive selection at the level of protein sequences. Positive selection at synonymous sites might act through mRNA destabilization affecting mRNA levels and translation.     

Pyrvinium pamoate changes alternative splicing of the serotonin receptor 2C by influencing its RNA structure

The serotonin receptor 2C plays a central role in mood and appetite control. It undergoes pre-mRNA editing as well as alternative splicing. The RNA editing suggests that the pre-mRNA forms a stable secondary structure in vivo. To identify substances that promote alternative exons inclusion, we set up a high-throughput screen and identified pyrvinium pamoate as a drug-promoting exon inclusion without editing. Circular dichroism spectroscopy indicates that pyrvinium pamoate binds directly to the pre-mRNA and changes its structure. SHAPE (selective 2′-hydroxyl acylation analysed by primer extension) assays show that part of the regulated 5′-splice site forms intramolecular base pairs that are removed by this structural change, which likely allows splice site recognition and exon inclusion. Genome-wide analyses show that pyrvinium pamoate regulates >300 alternative exons that form secondary structures enriched in A–U base pairs. Our data demonstrate that alternative splicing of structured pre-mRNAs can be regulated by small molecules that directly bind to the RNA, which is reminiscent to an RNA riboswitch.     

The generality of Constructive Neutral Evolution

Constructive Neutral Evolution (CNE) is an evolutionary mechanism that can explain much molecular inter-dependence and organismal complexity without assuming positive selection favoring such dependency or complexity, either directly or as a byproduct of adaptation. It differs from but complements other non-selective explanations for complexity, such as genetic drift and the Zero Force Evolutionary Law, by being ratchet-like in character. With CNE, purifying selection maintains dependencies or complexities that were neutrally evolved. Preliminary treatments use it to explain specific genetic and molecular structures or processes, such as retained gene duplications, the spliceosome, and RNA editing. Here we aim to expand the scope of such explanation beyond the molecular level, integrating CNE with Multi-Level Selection theory, and arguing that several popular higher-level selection scenarios are in fact instances of CNE. Suitably contextualized, CNE occurs at any level in the biological hierarchy at which natural selection as normally construed occurs. As examples, we focus on modularity in protein–protein interaction networks or “interactomes,” the origin of eukaryotic cells and the evolution of co-dependence in microbial communities—a variant of the “Black Queen Hypothesis” which we call the “Gray Queen Hypothesis”.     

Evidence for purifying selection against synonymous mutations in mammalian exonic splicing enhancers

Silent sites in mammals have classically been assumed to be free from selective pressures. Consequently, the synonymous substitution rate (Ks) is often used as a proxy for the mutation rate. Although accumulating evidence demonstrates that the assumption is not valid, the mechanism by which selection acts remain unclear. Recent work has revealed that the presence of exonic splicing enhancers (ESEs) in coding sequence might influence synonymous evolution. ESEs are predominantly located near intron-exon junctions, which may explain the reduced single-nucleotide polymorphism (SNP) density in these regions. Here we show that synonymous sites in putative ESEs evolve more slowly than the remaining exonic sequence. Differential mutabilities of ESEs do not appear to explain this difference. We observe that substitution frequency at fourfold synonymous sites decreases as one approaches the ends of exons, consistent with the existing SNP data. This gradient is at least in part explained by ESEs being more abundant near junctions. Between-gene variation in Ks is hence partly explained by the proportion of the gene that acts as an ESE. Given the relative abundance of ESEs and the reduced rates of synonymous divergence within them, we estimate that constraints on synonymous evolution within ESEs causes the true mutation rate to be underestimated by not more than approximately 8%. We also find that Ks outside of ESEs is much lower in alternatively spliced exons than in constitutive exons, implying that other causes of selection on synonymous mutations exist. Additionally, selection on ESEs appears to affect nonsynonymous sites and may explain why amino acid usage near intron-exon junctions is nonrandom.     

Comparative study of nuclear RNA of the liver and experimental hepatoma by the method of DNA-RNA molecular hybridization]

DNA:RNA molecular hybridization of rat liver and hepatoma nyclear RNAs was carried out under controlled conditions as to nucleotide composition and quantitative ratios of competing RNAs and the time of labelling. These factors are shown to influence the results of competition hybridization experiments. For instance a lower competitive ability of rat liver nuclear RNA as compared to that of hepatoma nuclear RNA stems to certain from a relatively higher GC-content of the former. However differences in the competitive efficiency of nuclear RNAs studied could be revealed even with preparations of equal nucleotide composition, these differences being but of quantitative character. The results of the experiments suggest that hepatoma nuclear RNAs are relatively rich in the fast-hybridizable fraction which does not differ qualitatively from the corresponding fraction is characterized by a high metabolic activity and certain tissue specifity.     

Average allozyme heterozygosity in vertebrates correlates with Ka/Ks measured in the human-mouse lineage

It is well established that different allozyme proteins vary in heterozygosity in averages made over large numbers of species. For example, the enzyme 6-phosphogluconate dehydrogenase has a much higher average heterozygosity than glutamate dehydrogenase. Allozyme data alone provide insufficient power to determine the evolutionary cause of such a difference. Many studies have now been carried out on the DNA sequences coding for allozymes. These have identified diverse selective and nonselective causes of polymorphisms at individual loci. However the studies are mainly in a small number of model species; thus, it is difficult to identify from these DNA studies specific causes of global average heterozygosity differences among allozyme proteins. Here we demonstrate that estimates of average heterozygosity for 37 allozyme proteins in vertebrates correlate positively with Ka and Ka/Ks but not with Ks, measured in the human-mouse lineage. The values of Ka/Ks are less than 0.25, and Ka/Ks is negatively correlated with subunit number (quaternary structure), a measure of structural constraint. Proteins with lower levels of constraint have higher values of both Ka/Ks and heterozygosity. These results better support the hypothesis that differences in average allozyme diversity between proteins are more closely related to differences in the level of purifying selection than to differences in the underlying mutation rate or level of positive selection.     

The Functional Role of Pack-MULEs in Rice Inferred from Purifying Selection and Expression Profile

Gene duplication is an important mechanism for evolution of new genes. In plants, a special group of transposable elements, called Pack-MULEs or transduplicates, is able to duplicate and amplify genes or gene fragments on a large scale. Despite the abundance of Pack-MULEs, the functionality of these duplicates is not clear. Here, we present a comprehensive analysis of expression and purifying selection on 2809 Pack-MULEs in rice (Oryza sativa), which are derived from 1501 parental genes. At least 22% of the Pack-MULEs are transcribed, and 28 Pack-MULEs have direct evidence of translation. Chimeric Pack-MULEs, which contain gene fragments from multiple genes, are much more frequently expressed than those derived only from a single gene. In addition, Pack-MULEs are frequently associated with small RNAs. The presence of these small RNAs is associated with a reduction in expression of both the Pack-MULEs and their parental genes. Furthermore, an assessment of the selection pressure on the Pack-MULEs using the ratio of nonsynonymous (Ka) and synonymous (Ks) substitution rates indicates that a considerable number of Pack-MULEs likely have been under selective constraint. The Ka/Ks values of Pack-MULE and parental gene pairs are lower among Pack-MULEs that are expressed in sense orientations. Taken together, our analysis suggests that a significant number of Pack-MULEs are expressed and subjected to purifying selection, and some are associated with small RNAs. Therefore, at least a subset of Pack-MULEs are likely functional and have great potential in regulating gene expression as well as providing novel coding capacities.     

RNA editing in trans-splicing intron sequences of nad2 mRNAs in Oenothera mitochondria.

The complete open reading frame of subunit 2 of the NADH dehydrogenase in Oenothera mitochondria is split into five exons. The first two and the last three exons are encoded in distant genomic locations and are transcribed separately. Three tRNA genes coding for tRNA(Cys), tRNA(Asn), and tRNA(Tyr) are located upstream of the terminal three exons c, d, and e. The genomic distance, the interspersed tRNA genes, and the group II intron sequences flanking the two separated exons suggest trans-splicing to be required to connect exons b and c. Maturation of the mRNA includes RNA editing at 36 sites in the open reading frame. Three RNA editing events are observed in the split group II intron sequences. Two of these events allow after editing additional base pairings in the secondary structure, one in the stem of domain I, the other in the putative trans-pairing region of domain IV. These RNA editings may thus be involved in the trans-splicing reaction.