Genomes of animals as different as sponges and humans show conservation of global architecture. Here we show that multiple genomic features including transposon diversity, developmental gene repertoire, physical gene order, and intron-exon organization are shattered in the tunicate Oikopleura, belonging to the sister group of vertebrates and retaining chordate morphology. Ancestral architecture of animal genomes can be deeply modified and may therefore be largely nonadaptive. This rapidly evolving animal lineage thus offers unique perspectives on the level of genome plasticity. It also illuminates issues as fundamental as the mechanisms of intron gain.
The HIV-1 viral infectivity factor (Vif) allows productive infection of non-permissive cells (including most natural HIV-1 targets) by counteracting the cellular cytosine deaminases APOBEC-3G (hA3G) and hA3F. The Vif-induced degradation of these restriction factors by the proteasome has been extensively studied, but little is known about the translational repression of hA3G and hA3F by Vif, which has also been proposed to participate in Vif function. Here, we studied Vif binding to hA3G mRNA and its role in translational repression. Filter binding assays and fluorescence titration curves revealed that Vif tightly binds to hA3G mRNA. Vif overall binding affinity was higher for the 3′UTR than for the 5′UTR, even though this region contained at least one high affinity Vif binding site (apparent Kd = 27 ± 6 nM). Several Vif binding sites were identified in 5′ and 3′UTRs using RNase footprinting. In vitro translation evidenced that Vif inhibited hA3G translation by two mechanisms: a main time-independent process requiring the 5′UTR and an additional time-dependent, UTR-independent process. Results using a Vif protein mutated in the multimerization domain suggested that the molecular mechanism of translational control is more complicated than a simple physical blockage of scanning ribosomes.
Highlights d Genome size varies up to 123 in larvaceans, chordates with a distinctive anatomy d Small and large species have the smallest and largest genomes, respectively d Transposable elements have driven multiple independent genome expansions d Genomes mainly increased through accumulations of nonautonomous elements (SINEs)
SUMMARY The viral infectivity factor (Vif) is dispensable for human immunodeficiency virus type 1 (HIV-1) replication in so-called permissive cells but is required for replication in nonpermissive cell lines and for pathogenesis. Virions produced in the absence of Vif have an aberrant morphology and an unstable core and are unable to complete reverse transcription. Recent studies demonstrated that human APOBEC-3G (hA3G) and APOBEC-3F (hA3F), which are selectively expressed in nonpermissive cells, possess strong anti-HIV-1 activity and are sufficient to confer a nonpermissive phenotype. Vif induces the degradation of hA3G and hA3F, suggesting that its main function is to counteract these cellular factors. Most studies focused on the hypermutation induced by the cytidine deaminase activity of hA3G and hA3F and on their Vif-induced degradation by the proteasome. However, recent studies suggested that several mechanisms are involved both in the antiviral activity of hA3G and hA3F and in the way Vif counteracts these antiviral factors. Attempts to reconcile the studies involving Vif in virus assembly and stability with these recent findings suggest that hA3G and hA3F partially exert their antiviral activity independently of their catalytic activity by destabilizing the viral core and the reverse transcription complex, possibly by interfering with the assembly and/or maturation of the viral particles. Vif could then counteract hA3G and hA3F by excluding them from the viral assembly intermediates through competition for the viral genomic RNA, by regulating the proteolytic processing of Pr55Gag, by enhancing the efficiency of the reverse transcription process, and by inhibiting the enzymatic activities of hA3G and hA3F.
The HIV-1 viral infectivity factor (Vif) is a small basic protein essential for viral fitness and pathogenicity. Some "non-permissive" cell lines cannot sustain replication of Vif(؊) HIV-1 virions. In these cells, Vif counteracts the natural antiretroviral activity of the DNA-editing enzymes APOBEC3G/3F. Moreover, Vif is packaged into viral particles through a strong interaction with genomic RNA in viral nucleoprotein complexes. To gain insights into determinants of this binding process, we performed the first characterization of Vif/nucleic acid interactions using Vif intrinsic fluorescence. We determined the affinity of Vif for RNA fragments corresponding to various regions of the HIV-1 genome. Our results demonstrated preferential and moderately cooperative binding for RNAs corresponding to the 5-untranslated region of HIV-1 (5-untranslated region) and gag (cooperativity parameter ϳ 65-80, and K d ؍ 45-55 nM). In addition, fluorescence spectroscopy allowed us to point out the TAR apical loop and a short region in gag as primary strong affinity binding sites (K d ؍ 9.5-14 nM). Interestingly, beside its RNA binding properties, the Vif protein can also bind the corresponding DNA oligonucleotides and their complementary counterparts with an affinity similar to the one observed for the RNA sequences, while other DNA sequences displayed reduced affinity. Taken together, our results suggest that Vif binding to RNA and DNA offers several nonexclusive ways to counteract APOBEC3G/3F factors, in addition to the well documented Vif-induced degradation by the proteasome and to the Vif-mediated repression of translation of these antiviral factors.The RNA genome of all retroviruses contains gag, pol, and env genes. The genome of lentiviruses, including the human immunodeficiency virus type 1 (HIV-1), 3 is more complex and encodes additional proteins. It is now well established that these proteins, previously considered as "accessory," are essential for infection spreading and pathogenesis. Among them, the HIV-1 Vif is a 23-kDa basic protein required for HIV-1 replication in T-lymphocytes, macrophages, and several T-cell lines known as "non-permissive," but dispensable in many other "permissive" cells (1-3). The non-permissive character is caused by the expression of two cellular factors, APOBEC3G and APOBEC3F, which belong to the cytidine deaminase family of nucleic acid-editing enzymes (3). In ⌬vif virions, APOBEC3G interacts with the nucleocapsid (NC) domain of HIV-1 Pr55Gag and this interaction is further stabilized by RNA recruitment (4, 5). Once encapsidated, APOBEC3G/3F induce proviral DNA hypermutation by deaminating cytidines into uridines (6, 7). Moreover, independently from their catalytic activity APOBEC3G/3F factors also impair particle infectivity by affecting virion morphology and by destabilizing the reverse transcription complex (8 -10). Vif counteracts the antiviral activity of these two HIV-1 inhibitors by promoting their degradation by the proteasome, indirectly preventing APOBEC3G/3F encapsidation (7...
HIV-1 Vif (viral infectivity factor) is associated with the assembly complexes and packaged at low level into the viral particles, and is essential for viral replication in non-permissive cells. Viral particles produced in the absence of Vif exhibit structural defects and are defective in the early steps of reverse transcription. Here, we show that Vif is able to anneal primer tRNALys3 to the viral RNA, to decrease pausing of reverse transcriptase during (–) strand strong-stop DNA synthesis, and to promote the first strand transfer. Vif also stimulates formation of loose HIV-1 genomic RNA dimers. These results indicate that Vif is a bona fide RNA chaperone. We next studied the effects of Vif in the presence of HIV-1 NCp, which is a well-established RNA chaperone. Vif inhibits NCp-mediated formation of tight RNA dimers and hybridization of tRNALys3, while it has little effects on NCp-mediated strand transfer and it collaborates with nucleocapsid (NC) to increase RT processivity. Thus, Vif might negatively regulate NC-assisted maturation of the RNA dimer and early steps of reverse transcription in the assembly complexes, but these inhibitory effects would be relieved after viral budding, thanks to the limited packaging of Vif in the virions.
Animal genomes vary in size by orders of magnitude 1 . While genome size expansion relates to transposable element mobilisation 2-5 and polyploidisation 6-9 , the causes and consequences of genome reduction are unclear 1 . This is because our understanding of genome compaction relies on animals with extreme lifestyles, such as parasites 10,11 , and free-living animals with exceptionally high rates of evolution 12-15 . Here, we decode the extremely compact genome of the annelid Dimorphilus gyrociliatus, a morphologically miniature meiobenthic segmented worm 16 . With a ~68 Mb size, Dimorphilus genome is the second smallest ever decoded for a free-living animal. Yet, it retains many traits classically associated with larger and slower-evolving genomes, such as an ordered, intact Hox cluster, a generally conserved developmental toolkit, and traces of ancestral 3 bilaterian linkage. Unlike animals with small genomes, the analysis of Dimorphilus epigenome revealed canonical features of genome regulation, excluding the presence of operons and trans-splicing. Instead, the gene dense Dimorphilus genome presents divergent kynurenine and Myc pathways, key physiological regulators of growth, proliferation and genome stability in animal cells that can cause small body size when impaired 17-21 . Altogether, our results uncover a novel, conservative route to extreme genome compaction, suggesting a mechanistic relationship between genome size reduction and morphological miniaturisation in animals.Animals, and eukaryotes generally, exhibit a striking range of genome sizes across species 1 , seemingly uncorrelated with morphological complexity and gene content, which has been deemed the "C-value enigma" 22 . Animal genomes often increase in size mobilising their transposable element (TE) repertoire (e.g. in rotifers 2 , chordates 3,4 and insects 5 ) and through chromosome rearrangements and polyploidisation (e.g. in vertebrates and teleosts 6-8 , and insects 9 ), which is usually counterbalanced through TE removal 23 , DNA deletions 24,25 and rediploidisation 26 . Although the adaptive impact of these changes is complex and probably often influenced by neutral nonadaptive population dynamics 27 , genome expansions might also increase the evolvability of a lineage by providing new genetic material that can stimulate species radiation 6 and the evolution of new genome regulatory contexts 28 and gene architectures 29 . By contrast, the adaptive value of genome compaction is more debated and hypotheses are often based on correlative associations 1 , e.g. with changes in metabolic 30 and developmental rates 31 , cell sizes 1,32 , and the evolution of radically new lifestyles (e.g. powered flight in birds and bats 25,33 , and parasitism in nematodes 11 and orthonectids 10 ).Besides, extreme genomic compaction leading to minimal genome sizes, as in some freeliving species of nematodes 34 , tardigrades 35 and appendicularians 4,36 , co-occurs with 4 prominent changes in gene repertoire 37,38 , genome architecture (e.g. loss of macrosynt...
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