Novel functions of a retroposed gene.

Retroposed protein-coding genes are commonly considered to be nonfunctional duplicates. However, they often gain transcriptional capability and have important roles. Amici et al. recently identified novel functions of a retroposed gene. HAPSTR2, a retrocopy of HAPSTR1, encodes a protein that stabilizes the HAPSTR1 protein and functionally buffers its loss.

mRNA Vaccines: Why Is the Biology of Retroposition Ignored?

The major advantage of mRNA vaccines over more conventional approaches is their potential for rapid development and large-scale deployment in pandemic situations. In the current COVID-19 crisis, two mRNA COVID-19 vaccines have been conditionally approved and broadly applied, while others are still in clinical trials. However, there is no previous experience with the use of mRNA vaccines on a large scale in the general population. This warrants a careful evaluation of mRNA vaccine safety properties by considering all available knowledge about mRNA molecular biology and evolution. Here, I discuss the pervasive claim that mRNA-based vaccines cannot alter genomes. Surprisingly, this notion is widely stated in the mRNA vaccine literature but never supported by referencing any primary scientific papers that would specifically address this question. This discrepancy becomes even more puzzling if one considers previous work on the molecular and evolutionary aspects of retroposition in murine and human populations that clearly documents the frequent integration of mRNA molecules into genomes, including clinical contexts. By performing basic comparisons, I show that the sequence features of mRNA vaccines meet all known requirements for retroposition using L1 elements-the most abundant autonomously active retrotransposons in the human genome. In fact, many factors associated with mRNA vaccines increase the possibility of their L1-mediated retroposition. I conclude that is unfounded to a priori assume that mRNA-based therapeutics do not impact genomes and that the route to genome integration of vaccine mRNAs via endogenous L1 retroelements is easily conceivable. This implies that we urgently need experimental studies that would rigorously test for the potential retroposition of vaccine mRNAs. At present, the insertional mutagenesis safety of mRNA-based vaccines should be considered unresolved.

Nuku, a family of primate retrocopies derived from KU70.

The gene encoding the ubiquitous DNA repair protein, Ku70p, has undergone extensive copy number expansion during primate evolution. Gene duplications of KU70 have the hallmark of long interspersed element-1 mediated retrotransposition with evidence of target-site duplications, the poly-A tails, and the absence of introns. Evolutionary analysis of this expanded family of KU70-derived "NUKU" retrocopies reveals that these genes are both ancient and also actively being created in extant primate species. NUKU retrocopies show evidence of functional divergence away from KU70, as evinced by their altered pattern of tissue expression and possible tissue-specific translation. Molecular modeling predicted that amino acid changes in Nuku2p at the interaction interface with Ku80p would prevent the assembly of the Ku heterodimer. The lack of Nuku2p-Ku80p interaction was confirmed by yeast two-hybrid assay, which contrasts the robust interaction of Ku70p-Ku80p. While several NUKU retrocopies appear to have been degraded by mutation, NUKU2 shows evidence of positive natural selection, suggesting that this retrocopy is undergoing neofunctionalization. Although Nuku proteins do not appear to antagonize retrovirus transduction in cell culture, the observed expansion and rapid evolution of NUKUs could be being driven by alternative selective pressures related to infectious disease or an undefined role in primate physiology.

RetroCHMP3 blocks budding of enveloped viruses without blocking cytokinesis.

Many enveloped viruses require the endosomal sorting complexes required for transport (ESCRT) pathway to exit infected cells. This highly conserved pathway mediates essential cellular membrane fission events, which restricts the acquisition of adaptive mutations to counteract viral co-option. Here, we describe duplicated and truncated copies of the ESCRT-III factor CHMP3 that block ESCRT-dependent virus budding and arose independently in New World monkeys and mice. When expressed in human cells, these retroCHMP3 proteins potently inhibit release of retroviruses, paramyxoviruses, and filoviruses. Remarkably, retroCHMP3 proteins have evolved to reduce interactions with other ESCRT-III factors and have little effect on cellular ESCRT processes, revealing routes for decoupling cellular ESCRT functions from viral exploitation. The repurposing of duplicated ESCRT-III proteins thus provides a mechanism to generate broad-spectrum viral budding inhibitors without blocking highly conserved essential cellular ESCRT functions.

RetroScan: An Easy-to-Use Pipeline for Retrocopy Annotation and Visualization.

Retrocopies, which are considered "junk genes," are occasionally formed via the insertion of reverse-transcribed mRNAs at new positions in the genome. However, an increasing number of recent studies have shown that some retrocopies exhibit new biological functions and may contribute to genome evolution. Hence, the identification of retrocopies has become very meaningful for studying gene duplication and new gene generation. Current pipelines identify retrocopies through complex operations using alignment programs and filter scripts in a step-by-step manner. Therefore, there is an urgent need for a simple and convenient retrocopy annotation tool. Here, we report the development of RetroScan, a publicly available and easy-to-use tool for scanning, annotating and displaying retrocopies, consisting of two components: an analysis pipeline and a visual interface. The pipeline integrates a series of bioinformatics software programs and scripts for identifying retrocopies in just one line of command. Compared with previous methods, RetroScan increases accuracy and reduces false-positive results. We also provide a Shiny app for visualization. It displays information on retrocopies and their parental genes that can be used for the study of retrocopy structure and evolution. RetroScan is available at https://github.com/Vicky123wzy/RetroScan.

Interpopulation differences of retroduplication variations (RDVs) in rice retrogenes and their phenotypic correlations.

Retroduplication variation (RDV), a type of retrocopy polymorphism, is considered to have essential biological significance, but its effect on gene function and species phenotype is still poorly understood. To this end, we analyzed the retrocopies and RDVs in 3,010 rice genomes. We calculated the RDV frequencies in the genome of each rice population; detected the mutated, ancestral and expressed retrogenes in rice genomes; and analyzed their RDV influence on rice phenotypic traits. Collectively, 73 RDVs were identified, and 14 RDVs in ancestral retrogenes can significantly affect rice phenotypes. Our research reveals that RDV plays an important role in rice migration, domestication and evolution. We think that RDV is a good molecular breeding marker candidate. To our knowledge, this is the first study on the relationship between retrogene function, expression, RDV and species phenotype.

Multiple FGF4 Retrocopies Recently Derived within Canids.

Two transcribed retrocopies of the fibroblast growth factor 4 (FGF4) gene have previously been described in the domestic dog. An FGF4 retrocopy on chr18 is associated with disproportionate dwarfism, while an FGF4 retrocopy on chr12 is associated with both disproportionate dwarfism and intervertebral disc disease (IVDD). In this study, whole-genome sequencing data were queried to identify other FGF4 retrocopies that could be contributing to phenotypic diversity in canids. Additionally, dogs with surgically confirmed IVDD were assayed for novel FGF4 retrocopies. Five additional and distinct FGF4 retrocopies were identified in canids including a copy unique to red wolves (Canis rufus). The FGF4 retrocopies identified in domestic dogs were identical to domestic dog FGF4 haplotypes, which are distinct from modern wolf FGF4 haplotypes, indicating that these retrotransposition events likely occurred after domestication. The identification of multiple, full length FGF4 retrocopies with open reading frames in canids indicates that gene retrotransposition events occur much more frequently than previously thought and provide a mechanism for continued genetic and phenotypic diversity in canids.

Retroposed copies of RET gene: a somatically acquired event in medullary thyroid carcinoma.

BACKGROUND: Different pathogenic germline mutations in the RET oncogene are identified in MEN 2, a hereditary syndrome characterized by medullary thyroid carcinoma (MTC) and other endocrine tumors. Although genetic predisposition is recognized, not all RET mutation carriers will develop the disease during their lifetime or, likewise, RET mutation carriers belonging to the same family may present clinical heterogeneity. It has been suggested that a single germline mutation might not be sufficient for development of MEN 2-associated tumors and a somatic bi-allelic alteration might be required. Here we investigated the presence of somatic second hit mutation in the RET gene in MTC. METHODS: We integrated Multiplex Ligation-dependent Probe Amplification (MLPA) and whole exome sequencing (WES) to search for copy number alteration (CNA) in the RET gene in MTC samples and medullary thyroid cell lines (TT and MZ-CR-1). We next found reads spanning exon-exon boundaries on RET, an indicative of retrocopy. We subsequently searched for RET retrocopies in the human reference genome (GRCh37) and in the 1000 Genomes Project data, by looking for reads reporting joined exons in the RET locus or distinct genomic regions. To determine RET retrocopy specificity and recurrence, DNA isolated from sporadic and MEN 2-associated MTC (n = 37), peripheral blood (n = 3) and papillary thyroid carcinomas with RET fusion (n = 10) samples were tested using PCR-sequencing methodology. RESULTS: Through MLPA we have found evidence of CNA in the RET gene in MTC samples and MTC cell lines. WES analysis reinforced the presence of the CNA and hinted for a retroposed copy of RET not found in the human reference genome and 1.000 Genomes Project. Extended analysis confirmed the presence of a somatic MTC-related retrocopy of RET in both sporadic and hereditary tumors. We further unveiled a recurrent (28%) novel point mutation (p.G548 V) found exclusively in the retrocopy of RET. The mutation was also found in cDNA of mutated samples, suggesting it might be functional. CONCLUSION: We here report a somatic specific RET retroposed copy in MTC samples and cell lines. Our results support the idea that generation of retrocopies in somatic cells is likely to contribute to MTC genesis and progression.

The Genomic Impact of Gene Retrocopies: What Have We Learned from Comparative Genomics, Population Genomics, and Transcriptomic Analyses?

Gene duplication is a major driver of organismal evolution. Gene retroposition is a mechanism of gene duplication whereby a gene's transcript is used as a template to generate retroposed gene copies, or retrocopies. Intriguingly, the formation of retrocopies depends upon the enzymatic machinery encoded by retrotransposable elements, genomic parasites occurring in the majority of eukaryotes. Most retrocopies are depleted of the regulatory regions found upstream of their parental genes; therefore, they were initially considered transcriptionally incompetent gene copies, or retropseudogenes. However, examples of functional retrocopies, or retrogenes, have accumulated since the 1980s. Here, we review what we have learned about retrocopies in animals, plants and other eukaryotic organisms, with a particular emphasis on comparative and population genomic analyses complemented with transcriptomic datasets. In addition, these data have provided information about the dynamics of the different "life cycle" stages of retrocopies (i.e., polymorphic retrocopy number variants, fixed retropseudogenes and retrogenes) and have provided key insights into the retroduplication mechanisms, the patterns and evolutionary forces at work during the fixation process and the biological function of retrogenes. Functional genomic and transcriptomic data have also revealed that many retropseudogenes are transcriptionally active and a biological role has been experimentally determined for many. Finally, we have learned that not only non-long terminal repeat retroelements but also long terminal repeat retroelements play a role in the emergence of retrocopies across eukaryotes. This body of work has shown that mRNA-mediated duplication represents a widespread phenomenon that produces an array of new genes that contribute to organismal diversity and adaptation.

Protein-Coding Genes' Retrocopies and Their Functions.

Transposable elements, often considered to be not important for survival, significantly contribute to the evolution of transcriptomes, promoters, and proteomes. Reverse transcriptase, encoded by some transposable elements, can be used in trans to produce a DNA copy of any RNA molecule in the cell. The retrotransposition of protein-coding genes requires the presence of reverse transcriptase, which could be delivered by either non-long terminal repeat (non-LTR) or LTR transposons. The majority of these copies are in a state of "relaxed" selection and remain "dormant" because they are lacking regulatory regions; however, many become functional. In the course of evolution, they may undergo subfunctionalization, neofunctionalization, or replace their progenitors. Functional retrocopies (retrogenes) can encode proteins, novel or similar to those encoded by their progenitors, can be used as alternative exons or create chimeric transcripts, and can also be involved in transcriptional interference and participate in the epigenetic regulation of parental gene expression. They can also act in trans as natural antisense transcripts, microRNA (miRNA) sponges, or a source of various small RNAs. Moreover, many retrocopies of protein-coding genes are linked to human diseases, especially various types of cancer.

A Genome-Wide Landscape of Retrocopies in Primate Genomes.

Gene duplication is a key factor contributing to phenotype diversity across and within species. Although the availability of complete genomes has led to the extensive study of genomic duplications, the dynamics and variability of gene duplications mediated by retrotransposition are not well understood. Here, we predict mRNA retrotransposition and use comparative genomics to investigate their origin and variability across primates. Analyzing seven anthropoid primate genomes, we found a similar number of mRNA retrotranspositions (∼7,500 retrocopies) in Catarrhini (Old Word Monkeys, including humans), but a surprising large number of retrocopies (∼10,000) in Platyrrhini (New World Monkeys), which may be a by-product of higher long interspersed nuclear element 1 activity in these genomes. By inferring retrocopy orthology, we dated most of the primate retrocopy origins, and estimated a decrease in the fixation rate in recent primate history, implying a smaller number of species-specific retrocopies. Moreover, using RNA-Seq data, we identified approximately 3,600 expressed retrocopies. As expected, most of these retrocopies are located near or within known genes, present tissue-specific and even species-specific expression patterns, and no expression correlation to their parental genes. Taken together, our results provide further evidence that mRNA retrotransposition is an active mechanism in primate evolution and suggest that retrocopies may not only introduce great genetic variability between lineages but also create a large reservoir of potentially functional new genomic loci in primate genomes.

Evolutionary origin and methylation status of human intronic CpG islands that are not present in mouse.

Imprinting of the human RB1 gene is due to the presence of a differentially methylated CpG island (CGI) in intron 2, which is part of a retrocopy derived from the PPP1R26 gene on chromosome 9. The murine Rb1 gene does not have this retrocopy and is not imprinted. We have investigated whether the RB1/Rb1 locus is unique with respect to these differences. For this, we have compared the CGIs from human and mouse by in silico analyses. We have found that the human genome does not only contain more CGIs than the mouse, but the proportion of intronic CGIs is also higher (7.7% vs. 3.5%). At least 2,033 human intronic CGIs are not present in the mouse. Among these CGIs, 104 show sequence similarities elsewhere in the human genome, which suggests that they arose from retrotransposition. We could narrow down the time points when most of these CGIs appeared during evolution. Their methylation status was analyzed in two monocyte methylome data sets from whole-genome bisulfite sequencing and in 18 published methylomes. Four CGIs, which are located in the RB1, ASRGL1, PARP11, and PDXDC1 genes, occur as methylated and unmethylated copies. In contrast to imprinted methylation at the RB1 locus, differential methylation of the ASRGL1 and PDXDC1 CGIs appears to be sequence dependent. Our study supports the notion that the epigenetic fate of the retrotransposed DNA depends on its sequence and selective forces at the integration site.

Diversity through duplication: whole-genome sequencing reveals novel gene retrocopies in the human population.

Gene retrocopies are generated by reverse transcription and genomic integration of mRNA. As such, retrocopies present an important exception to the central dogma of molecular biology, and have substantially impacted the functional landscape of the metazoan genome. While an estimated 8,000-17,000 retrocopies exist in the human genome reference sequence, the extent of variation between individuals in terms of retrocopy content has remained largely unexplored. Three recent studies by Abyzov et al., Ewing et al. and Schrider et al. have exploited 1,000 Genomes Project Consortium data, as well as other sources of whole-genome sequencing data, to uncover novel gene retrocopies. Here, we compare the methods and results of these three studies, highlight the impact of retrocopies in human diversity and genome evolution, and speculate on the potential for somatic gene retrocopies to impact cancer etiology and genetic diversity among individual neurons in the mammalian brain.

A retrotransposição de mRNAs como fator de variabilidade genética no genoma humano e de outros primatas / The retrotransposition of mRNAs as a factor of genetic variability in the human and other primates genomes

Duplicação genica é uma das principais forças levando a evolução dos genomas eucarioto. O impacto de duplicações gênicas/genômicas vem sendo investigado a muito tempo em humanos e outros primatas. Um segundo mecanismo de duplicação gênica, a retrotransposição baseada em RNA maduros, vem sendo menos estudada devido ao seu potencial menor de gerar cópias funcionais. No entanto, recentemente, publicações descreveram retrocópias funcionais em humanos, roedores e mosca de fruta. Nesta tese, para investigar sobre retrocópias causando variabilidade genética no genoma de primatas, nós desenvolvemos a implementamos os métodos para detectar estas inserções. Utilizando nove genomas e transcriptomas publicamente disponíveis (sete primatas e dois roedores) nós confirmamos um número similar, porém, com origem independente, de retrocópias em primatas e roedores. Nós também encontramos um enriquecimento de retrocópias no genoma de Platyrrhini, possivelmente explicado pela expansão de L1PA7 e L1P3 nestes genomas. Posteriormente, nós analisamos a ortologia de retrocópias no genoma de primatas e encontramos 127 eventos específicos à linhagem humana. Nós também exploramos dados do projeto 1000 Genomes para detectar retrocópias polimórficas (retroCNVs germinativos) e encontramos 17 eventos, presentes no genoma referência humano, mas ausentes em mais de um indivíduo. Similarmente, nós investigamos novas retroduplicações de mRNAs no genoma humano, detectando 21 eventos ausentes do genoma referência. Finalmente, investigamos a existência de retroCNVs somáticos e descrevemos sete possíveis retrocópias somáticas. Apesar de sua possível insignificância, nós encontramos que algumas retrocópias compartilhadas entre todos os primatas, espécie específicas, e polimórficas podem ser expressas per se ou como transcritos quiméricos com genes hospedeiros. Sobretudo, nós encontramos que retrocópias são um fator importante da variabilidade genética inter-espécie, intra-espécie e intra-indivíduo e podem estar influenciando a evolução de mamíferos ao criar reservatórios de duplicações potencialmente funcionais

Gene duplication is a major driving force of evolution in eukaryotic genome. The impact of gene/genomic duplication has long been investigated in human and other primates. A second mechanism of gene duplication, retrotransposition, which is based on mature RNA, has been traditionally less studied due to their lower potential to generate functional copies. Recently, however, publications described functional retrocopies in humans, murines and drosophila. Here, to gain insights of the genetic variability arising from retrocopies on primate genomes, we developed and implemented the methods to detect these insertions. Using nine publicly available reference genomes and transcriptomes (seven primates and two rodents) we described a similar number independently arisen retrocopies in primates and rodents. We also found an enrichment of retrocopies in Platyrhinni genomes, putatively explained by the expansion of L1PA7 and L1P3 in these genomes. Next, we evaluated the orthology of retrocopies in primate genomes and found 127 events specific to human lineage. We also explored 1000 Genomes Project data to detect polymorphic events (germinative retroCNVs) on human populations and found 17 events, present on the reference genome, absent in more than one individual. Conversely, we also investigated new insertions of mRNA retroduplications in the human genome, detecting 21 events absent to the human reference genome. Finally, we evaluated the existence of somatic retroCNVs and described seven putative somatic retrocopies. Despite their putative insignificance, we found that some of these shared, specie-specific and polymorphic events may be expressed per se and as chimeric transcripts within host genes. Taken together, we found that retrocopies are a great factor of genetic variation interspecie, intraspecie e intraindividual and may be affecting mammal evolution by creating reservoirs of potentially functional duplications

The role of mRNA-based duplication in the evolution of the primate genome.

Analysis of the human genome suggests novel genes created by retroposition may play an important role in primate evolution. However, data from non-human primates is still scarce. A comprehensive comparison was thus performed among four primate genomes (human, chimpanzee, orangutan, and macaque), which detects elevated rates of retroposition in both the common ancestor of hominoids and macaques. Further analysis shows approximately 10% of intact retrocopies may be under positive selection and at least 4% of retrocopies become functional copies eventually. Moreover, human intact retrocopies were found enriched in transcription-related functions. Collectively, these findings emphasize the important contribution of retroposition to primate genome evolution.