Positive Selection of Iris, a Retroviral Envelope–Derived Host Gene in Drosophila melanogaster

Eukaryotic genomes can usurp enzymatic functions encoded by mobile elements for their own use. A particularly interesting kind of acquisition involves the domestication of retroviral envelope genes, which confer infectious membrane-fusion ability to retroviruses. So far, these examples have been limited to vertebrate genomes, including primates where the domesticated envelope is under purifying selection to assist placental function. Here, we show that in Drosophila genomes, a previously unannotated gene (CG4715, renamed Iris) was domesticated from a novel, active Kanga lineage of insect retroviruses at least 25 million years ago, and has since been maintained as a host gene that is expressed in all adult tissues. Iris and the envelope genes from Kanga retroviruses are homologous to those found in insect baculoviruses and gypsy and roo insect retroviruses. Two separate envelope domestications from the Kanga and roo retroviruses have taken place, in fruit fly and mosquito genomes, respectively. Whereas retroviral envelopes are proteolytically cleaved into the ligand-interaction and membrane-fusion domains, Iris appears to lack this cleavage site. In the takahashii/suzukii species groups of Drosophila, we find that Iris has tandemly duplicated to give rise to two genes (Iris-A and Iris-B). Iris-B has significantly diverged from the Iris-A lineage, primarily because of the “invention” of an intron de novo in what was previously exonic sequence. Unlike domesticated retroviral envelope genes in mammals, we find that Iris has been subject to strong positive selection between Drosophila species. The rapid, adaptive evolution of Iris is sufficient to unambiguously distinguish the phylogenies of three closely related sibling species of Drosophila (D. simulans, D. sechellia, and D. mauritiana), a discriminative power previously described only for a putative “speciation gene.” Iris represents the first instance of a retroviral envelope–derived host gene outside vertebrates. It is also the first example of a retroviral envelope gene that has been found to be subject to positive selection following its domestication. The unusual selective pressures acting on Iris suggest that it is an active participant in an ongoing genetic conflict. We propose a model in which Iris has “switched sides,” having been recruited by host genomes to combat baculoviruses and retroviruses, which employ homologous envelope genes to mediate infection.     

Evolution from retrotransposons to retroviruses: origin of the env gene

In genome of Drosophila melanogaster, various families of retrotransposons with different combination of functional domens and mechanisms of transposition are present. However only retrotransposons of gypsy family are retroviruses related to errantiviruses. Other families seemingly appeared as intermediate forms of retroviruses evolution. Despite the fact that the question on origin of retroviruses remains unclear, now the hypothesis of their origin from retrotransoposons can be considered the most consistent. Infectious properties of errantiviruses are linked to the presence of the third open reading frame (the env gene). Acquisition of the env gene conversed retrotransposons into retroviruses. So, origin of this gene is of special interest. Homologues of the env gene of errantiviruses are discovered in genomes of D. melanogaster, as well as in baculoviruses and in bacteria Wolbachia pipientis, the endosymbiont of Drosophila. It was shown that homologue of the env gene come to Wolbachia genome from Drosophila genome by horizontal transfer of the gypsy group retrotransposon. Thus, Wolbachia was not a donor of the env gene for errantiviruses. Seemingly, errantiviruses captured the baculoviral homologue of the env gene (f). However origin of the f gene is not clear. At the same time the env gene homologue in D. melanogaster genome exist (Iris). It must not be ruled out that the Iris gene was the source of the env gene of errantiviruses and baculoviruses.     

Envelope capture by retroviruses

Retroelement transposition is a major source of diversity in genome evolution. Among the retrotransposable elements, the retroviruses are distinct in that their "transposition" extends from their initial host cells to neighboring cells and organisms. A determining step in the conversion of a retrotransposable element into an infectious retrovirus is the acquisition of an envelope glycoprotein, designated Env. Here, we review some examples of envelope "capture" by mammal retroviruses and provide evidence for such a mechanism by HTLV. This phenomenon may explain the notable conservation of env genes observed between phylogenetically distant retroviruses. Elucidation of these recombination processes should help to clarify retroviral phylogeny, better understand retroviral pathogenesis, and may lead to the identification of new retroelements.     

家蚕核型多角体病毒水平转移基因分析

为了探讨杆状病毒基因组的遗传进化模式,文章利用家蚕核型多角体病毒(BmNPV)和其宿主家蚕全基因组数据,进行了全基因组的同源性搜索和系统进化分析,结果显示,BmNPV的几丁质酶(Chi)基因、凋亡抑制蛋白3(IAP3)基因和尿苷二磷酸葡萄糖转移酶(UGT)基因为水平转移基因。这3个基因都来源于其宿主昆虫。通过核苷酸组成、密码子偏好性、选择压力等基因特征分析,发现BmNPV水平转移基因与其基因组序列存在明显差异,进一步验证水平转移基因的外源性。对3个水平转移基因的功能分析发现它们有利于杆状病毒在宿主昆虫中的侵染与繁殖,并提高杆状病毒在昆虫中的生存能力。     

A role for endogenous retroviral sequences in the regulation of lymphocyte activation

The genomes of most vertebrates contain numerous retroviral sequences, the great majority of which are non-infectious. These endogenous retroviral sequences are transcribed and translated in many host tissues, and are induced by mitogens. The function, if any, of endogenous retroviruses has been unclear. The transmembrane envelope proteins of some infectious type C retroviruses suppress lymphocyte activation, but it is unknown whether any endogenous type C retroviruses share this suppressive activity. To study the possible effects of murine endogenous retroviral expression, specific antisense oligonucleotides were synthesized complementary to type C retroviral sequences, and were cultured with murine spleen cells. If any of these endogenous retroviruses are suppressing lymphocyte activation, then inhibiting such endogenous retroviral-mediated suppression with antisense might result in lymphocyte stimulation. Three classes of endogenous type C retroviral sequences may be distinguished by antisense oligonucleotides (based on their homology to infectious retroviruses): ecotropic, xenotropic, and mink cell focus-forming (MCF). Antisense oligonucleotides to endogenous MCF envelope gene (env) initiation regions caused: i) doubling or tripling of spleen cell RNA synthesis, and ii) marked increases in lymphocyte surface Ia and Ig expression relative to control oligonucleotides. Antisense oligos to xenotropic or ecotropic env sequences or to endogenous MCF non-envelope sequences had no effect. These data suggest that endogenous MCF sequences exert an inhibitory influence on the murine immune system. Because endogenous MCF expression is inducible by immune stimuli, such expression could constitute an inhibitory feedback circuit that participates in the regulation of immune homeostasis.     

Crystal structure of a pivotal domain of human syncytin-2, a 40 million years old endogenous retrovirus fusogenic envelope gene captured by primates

HERV-FRD is a human endogenous retrovirus that entered the human genome 40 million years ago. Its envelope gene, syncytin-2, was diverted by an ancestral host most probably because of its fusogenic property, for a role in placenta morphogenesis. It was maintained in a functional state in all primate branches as a bona fide cellular gene, submitted to a very low mutation rate as compared to infectious retrovirus genomes. The structure of the syncytin-2 protein thus provides a good insight into that of the oldest mammalian retroviral envelope. Here, we report the crystal structure of a central fragment of its "fossil" ectodomain, allowing a remarkable superposition with the structures of the corresponding domains of present-day infectious retroviruses, in spite of a more than 60% divergent sequence. These results suggest the existence of a unique structural solution selected by these proteins for their fusogenic function.     

Spontaneous heteromerization of gammaretrovirus envelope proteins: a possible novel mechanism of retrovirus restriction

The env gene of gammaretroviruses encodes a glycoprotein conserved among diverse retroviruses, except for the domains involved in receptor binding. Here we show that pairs of gammaretrovirus envelope proteins (from Friend virus and GALV or xenotropic viruses) assemble into heteromers when coexpressed. This assembly results in a strong inhibition of infectivity. An unrelated envelope protein does not assemble in heteromers with the gammaretrovirus glycoproteins tested and does not affect their infectivity, demonstrating the specificity of the mechanism we describe. We propose that the numerous copies of endogenous retroviral env genes conserved within mammalian genomes act as restriction factors against infectious retroviruses.     

Determinants of retroviral-mediated gene delivery to mouse spermatogonia

Spermatogonia represent a new route to transgenesis in mice and potentially in some commercially important domesticated animals. In addition, these cells are also a potential target for viral integration in patients receiving somatic cell gene therapy. But the factors influencing retroviral transduction into spermatogonia are not well understood. Because retroviral transduction is affected in part by the proliferative status of the host cell, we developed an improved cell culture system in which spermatogonia survive and proliferate for several days. We used this system to test the ability of a variety of murine and avian retroviruses to infect spermatogonia. We investigated the factors influencing retroviral transduction of spermatogonia, including the proliferative status of the infected cell, the type of viral envelope, the type of retroviral long terminal repeat, and the method of viral delivery. Here we show that many of the widely used retroviral vector systems can be used to successfully transduce spermatogonia at high efficiency. Moreover, we show that retroviral delivery of MDM2, the major downregulator of p53, promotes spermatogonial survival in culture, suggesting that p53 plays a role in regulating spermatogonial apoptosis induced by growth factor deprivation. These results further demonstrate the usefulness of this novel system of targeting substances of interest to the testis. These data have important implications for improving animal transgenesis and for understanding the risks associated with somatic cell gene therapy.     

Protein coding potential of retroviruses and other transposable elements in vertebrate genomes

We suggest an annotation strategy for genes encoded by retroviruses and transposable elements (RETRA genes) based on a set of marker protein domains. Usually RETRA genes are masked in vertebrate genomes prior to the application of automated gene prediction pipelines under the assumption that they provide no selective advantage to the host. Yet, we show that about 1000 genes in four vertebrate gene sets analyzed contain at least one RETRA gene marker domain. Using the conservation of genomic neighborhood (synteny), we were able to discriminate between RETRA genes with putative functionality in the vertebrates and those that probably function only in the context of mobile elements. We identified 35 such genes in human, along with their corresponding mouse and rat orthologs; which included almost all known human genes with similarity to mobile elements. The results also imply that the vast majority of the remaining RETRA genes in current gene sets are unlikely to encode vertebrate functions. To automatically annotate RETRA genes in other vertebrate genomes, we provide as a tool a set of marker protein domains and a manually refined list of domesticated or ancestral RETRA genes for rescuing genes with vertebrate functions.     

Syncytins - retroviral envelope genes captured for the benefit of placental development

In the past, germline infections by retroviruses have led to vertical transmission of "endogenized" retroviruses. Escaping genetic drift, some of the viral genes have been conserved until now because of beneficial effects on their host. Here we present the syncytin genes that encode envelope proteins from endogenous retroviruses. Syncytins have inherited fusogenic properties from their infectious ancestor and are specifically expressed in the placenta. Both properties have suggested their involvement in the formation of the syncytiotrophoblast, a multinucleated layer that mediates feto-maternal exchanges in the placenta. The capture of syncytin genes occurred on several independent occasions during evolution of mammals. Knock-out experiments of syncytins in the mouse definitively confirmed the role of these genes in placentation. Finally, a second function for syncytins, i.e. an immunosuppressive activity, could contribute to materno-fetal immune tolerance. This constitutes a remarkable example of convergent evolution where the properties of retroviral envelope genes are subverted to play a major physiological role.     

家蚕免疫相关基因和信号途径的鉴定和比较分析

家蚕Bombyx mori是一种重要的经济昆虫, 在中国约有5 000年的驯化历史。家蚕分子免疫学方面的最新研究已经初步勾勒出其先天免疫的轮廓。本研究基于更新的家蚕基因组数据, 通过与黑腹果蝇Drosophila melanogaster、冈比亚按蚊Anopheles gambiae、意大利蜜蜂Apis mellifera和赤拟谷盗Tribolium castaneum基因组的比较分析, 鉴定了家蚕21个免疫相关基因家族的218个基因, 其编码产物包括模式识别受体、信号传导因子、效应分子和氧化防御相关的酶类。尽管信号传导因子的序列分化较大, 但系统进化分析显示它们在不同昆虫间呈明显的直系同源关系。相反, 与识别、调制和效应因子相关的基因的序列保守性更高, 但是这些基因家族明显缺乏直系同源基因, 由此推测这些基因是由物种特异的基因复制机制产生的。结果提示家蚕拥有与其他昆虫相同的免疫应答调控的分子机制, 而且家蚕同样可以通过基因复制及其序列分化等方式调节防御策略。     

Baculoviruses: diversity,evolution and manipulation of insects

Baculoviruses, members of the family Baculoviridae, are large, enveloped viruses that contain a double‐stranded circular DNA genome of 80–180 kbp, encoding 90–180 putative proteins. These viruses are exclusively pathogenic for arthropods, particularly insects, and have been developed, or are being developed, as environmentally sound pesticides and eukaryotic vectors for foreign protein expression, surface display, gene delivery for gene therapy, vaccine production and drug screening. The baculoviruses contain a set of approximately 30 core genes that are conserved among all baculovirus genomes sequenced to date. Individual baculoviruses also contain a number of lineage‐ or species‐specific genes that have greatly impacted the diversification and evolution of baculoviruses. In this review, we first describe the general properties and biology of baculoviruses and then focus on the baculovirus genes and mechanisms involved in the replication, spread and survival of baculoviruses within the context of their diversity, evolution and insect manipulation.     

Compositional bimodality and evolution of retroviral genomes.

The compositional distributions of genomes, genes (and their third codon positions) and long terminal repeats from retroviruses of warm-blooded vertebrates are characterized by a striking bimodality which is accompanied by a remarkable compositional homogeneity within each retroviral genome. A first, major class of retroviral genomes is GC-rich, whereas a second, minor class is GC-poor. Representative expressed viral genomes from the two classes integrate in GC-rich and GC-poor isochores, respectively, of host genomes. The first class comprises all oncoviruses (except B-types and some D-types), the second, lentiviruses, spumaviruses, as well as B-type and some D-type oncoviruses (e.g., mouse mammary tumor virus and simian retroviruses type D, respectively). The compositional bimodal distribution of retroviral genomes and the accompanying compositional homogeneity within each retroviral genome appear to be the result of the compositional evolution of retroviral genomes in their integrated form.     

Retroviral infection of hES cells produces random-like integration patterns

Retroviral integration provides us with a powerful tool to realize prolonged gene expressions that are often critical to gene therapy. However, the perturbation of gene regulations in host cells by viral genome integration can lead to detrimental effects, yielding cancer. The oncogenic potential of retroviruses is linked to the preference of retroviruses to integrate into genomic regions that are enriched in gene regulatory elements. To better navigate the double-edged sword of retroviral integration we need to understand how retroviruses select their favored genomic loci during infections. In this study I showed that in addition to host proteins that tether retroviral pre-integration complexes to specific genomic regions, the epigenetic architecture of host genome might strongly affect retroviral integration patterns. Specifically, retroviruses showed their characteristic integration preference in differentiated somatic cells. In contrast, retroviral infections of hES cells, which are known to display decondensed chromatin, produced random-like integration patterns lacking of strong preference for regulatory-element-rich genomic regions. Better identification of the cellular and viral factors that determine retroviral integration patterns will facilitate the design of retroviral vectors for safer use in gene therapy.     

Nucleotide sequence analysis of avian retroviruses: structural similarities with transposable elements

Integrated retroviral genomes are flanked by direct repeats of sequences derived from the termini of the viral RNA genome. These sequences are designated long terminal repeats (LTRs). We have determined and analyzed the nucleotide sequence of the LTRs from several exogenous and endogenous avian retroviruses. These LTRs possess several structural similarities with eukaryotic and prokaryotic transposable elements: 1) inverted complementary repeats at the termini, 2) deletions of sequences adjacent to the LTR, 3) small duplications of host sequences flanking the integrated provirus, and 4) sequence homologies with transposable and other genetic elements. These observations suggest that LTRs function in the integration and perhaps transposition of retrovirus genomes. Evidence exists for the presence of a strong promoter sequence within the LTR. The retroviral LTR also contains a "Hogness box" up-stream of the capping site and a poly(A) signal. These features suggest an additional role for the LTR in the regulation of gene expression.