In yeast, histone H2B monoubiquitination is a cotranscriptional event regulating histone H3 methylation at lysines 4 and 79. However, mammalian H2B monoubiquitination remains poorly understood. We report that in humans, the 600 kDa RNF20/40 complex is the E3 ligase and UbcH6 is the ubiquitin E2-conjugating enzyme for H2B-Lys120 monoubiquitination. RNF20 and RNF40 are both homologs of Bre1, the E3 ligase in the yeast case. UbcH6 physically interacts with RNF20/40 and with the hPAF complex. Formation of a trimeric complex with hPAF stimulates H2B monoubiquitination activity in vitro. Accordingly, UbcH6, RNF20/40, and the hPAF complex are recruited to transcriptionally active genes in vivo. RNF20 overexpression leads to elevated H2B monoubiquitination, subsequently higher levels of methylation at H3 lysines 4 and 79, and stimulation of HOX gene expression. In contrast, RNAi against the RNF20/40 complex or hPAF complex reduces H2B monoubiquitination, lowers methylation levels at H3 lysines 4 and 79, and represses HOX gene expression.
Recently, APOBEC3G has been identified as a host factor that blocks retroviral replication. It introduces G to A hypermutations in newly synthesized minus strand viral cDNA at the step of reverse transcription in target cells. Here, we identified the human APOBEC3F protein as another host factor that blocks human immunodeficiency virus type 1 (HIV-1) replication. Similar to APOBEC3G, APOBEC3F also induced G to A hypermutations in HIV genomic DNA, and the viral Vif protein counteracted its activity. Thus, APOBEC family members might have evolved as a general defense mechanism of the body against retroviruses, retrotransposons, and other mobile genetic elements.
The yeast PAF (yPAF) complex interacts with RNA polymerase II and coordinates the setting of histone marks associated with active transcription. We report the isolation and functional characterization of the human PAF (hPAF) complex. hPAF shares four subunits with yPAF (hCtr9, hPaf1, hLeo1, and hCdc73), but contains a novel higher eukaryotic-specific subunit, hSki8. RNAi against hSki8 or hCtr9 reduces the cellular levels of other hPAF subunits and of mono-and trimethylated H3-Lys 4 and dimethylated H3-Lys 79. The hSki8 subunit is also a component of the human SKI (hSKI) complex. Yeast SKI complex is cytoplasmic and together with Exosome mediates 3 -5 mRNA degradation. However, hSKI complex localizes to both nucleus and cytoplasm. Immunoprecipitation experiments revealed that hPAF and hSKI complexes interact, and ChIP experiments demonstrated that hSKI associates with transcriptionally active genes dependent on the presence of hPAF. Thus, in addition to coordinating events during transcription (initiation, promoter clearance, and elongation), hPAF also coordinates events in RNA quality control.Supplemental material is available at http://www.genesdev.org.
A tandem arrayed gene cluster encoding seven cytidine deaminase genes is present on human chromosome 22. These are APOBEC3A, APOBEC3B, APOBEC3C, APOBEC3DE, APOBEC3F, APOBEC3G, and APOBE C3H. Three of them, APOBEC3G, APOBEC3F, and APOBEC3B, block replication of human immunodeficiency virus type 1 (HIV-1) and many other retroviruses. In addition, APOBEC3A and APOBEC3C block intracellular retrotransposons and simian immunodeficiency virus (SIV), respectively. In opposition to AP OBEC genes, HIV-1 and SIV contain a virion infectivity factor (Vif) that targets APOBEC3F and APOBEC3G for polyubiquitylation and proteasomal degradation. Herein, we studied the antiretroviral activities of the human APOBEC3DE and APOBEC3H. We found that only APOBEC3DE had antiretroviral activity for HIV-1 or SIV and that Vif suppressed this antiviral activity. APOBEC3DE was encapsidated and capable of deaminating cytosines to uracils on viral minus-strand DNA, resulting in disruption of the viral life cycle. Other than GG-to-AG and AG-to-AA mutations, it had a novel target site specificity, resulting in introduction of GC-to-AC mutations on viral plus-strand DNA. Such mutations have been detected previously in HIV-1 clinical isolates. In addition, APOBEC3DE was expressed much more extensively than APOBEC3F in various human tissues and it formed heteromultimers with APOBEC3F or APOBEC3G in the cell. From these studies, we concluded that APOBEC3DE is a new contributor to the intracellular defense network, resulting in suppression of retroviral invasion.
Human APOBEC3H (A3H) has one cytidine deaminase domain (CDD) and inhibits the replication of retrotransposons and human immunodeficiency virus type 1 (HIV-1) in a Vif-resistant manner. Human A3H has five single amino acid polymorphisms (N15⌬, R18L, G105R, K121D, and E178D), and four haplotypes (I to IV) have previously been identified in various human populations. Haplotype II was primarily found in African-derived populations, and it was the only one that could be stably expressed. Here, we identified three new haplotypes from six human population samples, which we have named V, VI, and VII. Haplotypes V and VII are stably expressed and inhibit HIV-1 replication. Notably, haplotype V was identified in samples from all African-, Asian-, and Caucasian-derived populations studied. Using haplotype VII, we investigated the A3H anti-HIV-1 mechanism. We found that A3H virion packaging is independent of its CDD but dependent on a 112 YYXW 115 motif. This motif binds HIV-1 nucleocapsid in an RNA-dependent manner, and a single Y112A mutation completely disrupts A3H virion incorporation. We further studied the mechanism of A3H resistance to Vif. Although the previously identified APOBEC3G Vif-responsive motif 128 DPDY 131 is not conserved in A3H, placement of this motif into A3H does not make it become less resistant to HIV-1 Vif. We conclude that stably expressed A3H haplotypes may be more broadly distributed in humans than previously realized, and A3H protein is resistant to Vif. These results have important implications for the role of A3H in retrotransposon and HIV-1 inhibition.
HIV buds from lipid rafts and requires cholesterol for its egress from and entry into cells. Viral accessory protein Nef plays a major role in this process. In this study, it not only increased the biosynthesis of lipid rafts and viral particles with newly synthesized cholesterol, but also enriched them. Furthermore, via the consensus cholesterol recognition motif at its C terminus, Nef bound cholesterol. When this sequence was mutated, Nef became unable to transport newly synthesized cholesterol into lipid rafts and viral particles. Interestingly, although its levels in lipid rafts were not affected, this mutant Nef protein was poorly incorporated into viral particles, and viral infectivity decreased dramatically. Thus, Nef also transports newly synthesized cholesterol to the site of viral budding. As such, it provides essential building blocks for the formation of viruses that replicate optimally in the host.T he negative effector (Nef) protein from human and simian immunodeficiency viruses is a membrane-associated myristoylated protein that measures 27-35 kDa (1-3). It is critical for high levels of viremia and the progression to AIDS in infected humans (4) and monkeys (5). This phenotype has been correlated with increased viral infectivity in vitro, which provides a convenient assay to study its effects in cultured cells (6, 7). This infectivity enhancement can be dependent on or independent of CD4 that serves as the receptor for viral entry. In the former case, Nef decreases the expression of CD4 on the cell surface, thereby increasing the incorporation of viral envelope (Env) proteins into virions (8). In the latter case, Nef still increases viral infectivity significantly (9, 10). This enhancement cannot be complemented by the expression of Nef in target cells. Although no differences were identified in major structural components and morphology between wild-type and mutant virions that lack Nef, ⌬Nef viruses displayed less efficient reverse transcription in target cells. Because Nef is expressed abundantly at the earliest stages of the viral replicative cycle (11), Nef could affect viral morphogenesis and budding to increase the fitness of the virus and facilitate its entry into recipient cells.Lipid rafts, also known as detergent-resistant membranes (DRMs), are microdomains in the plasma membrane that are enriched in sphingolipids, cholesterol, and a subset of cellular proteins (12, 13). Two major pathways contribute to cholesterol homeostasis in mammalian cells (14). Most exogenous cholesterol, which originates from low-density lipoproteins, is internalized via coated pits and distributed to intracellular pools. In addition, cells can synthesize cholesterol in their endoplasmic reticulum when the uptake of exogenous cholesterol is blocked. The newly synthesized cholesterol is then transported into the Golgi apparatus and distributed to various intracellular pools. Because cellular cholesterol is compartmentalized, some sites (including DRMs) are enriched in this newly synthesized lipid (15,16).Previous...
Moloney leukemia virus 10 (MOV10) protein is a superfamily-1 RNA helicase, and it is also a component of the RNA-induced silencing complex. Recent studies have shown that MOV10 plays an active role in the RNA interference pathway. Here, we report that MOV10 inhibits retrovirus replication. When it was overexpressed in viral producer cells, MOV10 was able to reduce the infectivity of human immunodeficiency virus type 1 (HIV-1), simian immunodeficiency virus, and murine leukemia virus. Conversely, when MOV10 expression was reduced by small interfering RNAs, HIV-1 infectivity was increased. Consistently, silencing of MOV10 expression in a human T cell line enhanced HIV-1 replication. Furthermore, we found that MOV10 interacts with HIV-1 nucleocapsid protein in an RNAdependent manner and is packaged into virions. It blocks HIV-1 replication at a postentry step. In addition, we also found that HIV-1 could suppress MOV10 protein expression to counteract this cellular resistance. All of these results indicate that MOV10 has a broad antiretroviral activity that can target a wide range of retroviruses, and it could be actively involved in host defense against retroviral infection.Helicases share seven conserved motifs (I, Ia, II, III, IV, V, and VI), and are classified into three superfamilies (SF-1 to SF-3) and two smaller families (F4 and F5) (1, 2). Most helicases belong to SF-2 and are known as DExH/D (DEAD, DEAH, DExH) box proteins that are named for a sequence fingerprint in the motif II.The MOV10 gene was discovered from the MOV-10 mouse strain. The MOV mouse strains were derived from preimplantation embryos infected with Moloney murine leukemia virus (MLV).2 A total of nine strains that carry a single copy of the provirus at different chromosomal positions were created and designated MOV-5 to MOV-13.
Lipid rafts, also known as detergent-resistant membranes (DRM), are microdomains in the plasma membrane enriched in sphingolipids and cholesterol (reviewed in [1, 2]). Human immunodeficiency virus 1 (HIV) buds via lipid rafts [3, 4]. However, the targeting of viral structural components to DRM and its consequences for viral replication are not understood. Moreover, the negative factor Nef from HIV increases viral infectivity (reviewed in [5, 6]). With no apparent differences in structural components and morphology between wild-type and DeltaNef virons, the latter viruses display less efficient reverse transcription in target cells. As Nef is expressed abundantly early in the viral replicative cycle [7], we hypothesized that Nef could affect viral morphogenesis and budding to render viruses more infectious. In this report, we demonstrated first that Nef increases viral budding from lipid rafts. Second, in the presence of Nef, viral envelopes contain more ganglioside (GM1), which is a major component of lipid rafts. This finding correlated directly with the increased infectivity of HIV. Finally, the depletion of exogenous and endogenous cholesterol biochemically and genetically, which disrupted lipid rafts, decreased viral infectivity only in the presence of Nef. Importantly, HIV lacking the nef gene remained unaffected by these manipulations. We conclude that lipids in virions are essential for viral infectivity. Thus, HIV becomes more infectious when it buds from lipid rafts, and Nef plays a major role in this process.
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