Restriction factors, such as the retroviral complementary DNA deaminase APOBEC3G, are cellular proteins that dominantly block virus replication1-3. The AIDS virus, human immunodeficiency virus type 1 (HIV-1), produces the accessory factor Vif, which counteracts the host’s antiviral defence by hijacking a ubiquitin ligase complex, containing CUL5, ELOC, ELOB and a RING-box protein, and targeting APOBEC3G for degradation4-10. Here we reveal, using an affinity tag/purification mass spectrometry approach, that Vif additionally recruits the transcription cofactor CBF-β to this ubiquitin ligase complex. CBF-β, which normally functions in concert with RUNX DNA binding proteins, allows the reconstitution of a recombinant six-protein assembly that elicits specific polyubiquitination activity with APOBEC3G, but not the related deaminase APOBEC3A. Using RNA knockdown and genetic complementation studies, we also demonstrate that CBF-β is required for Vif-mediated degradation of APOBEC3G and therefore for preserving HIV-1 infectivity. Finally, simian immunodeficiency virus (SIV) Vif also binds to and requires CBF-β to degrade rhesus macaque APOBEC3G, indicating functional conservation. Methods of disrupting the CBF-β–Vif interaction might enable HIV-1 restriction and provide a supplement to current antiviral therapies that primarily target viral proteins.
15 APOBEC3 GENES ARE UNIQUE TO MAMMALS, BUT COPY NUMBERS VARY SIGNIFICANTLYAPOBEC3 (A3) proteins are of considerable interest because most are potent DNA cytidine deaminases that have the capacity to restrict the replication and/or edit the sequences of a wide variety of parasitic elements, including many retroviruses and retrotransposons (reviewed in references 5, 8-10, and 14). Likely substrates include (i) lentiviruses, such as human immunodeficiency virus type 1, human immunodeficiency virus type 2, simian immunodeficiency virus, maedi-visna virus, feline immunodeficiency virus, and equine infectious anemia virus; (ii) alpha-, beta-, gamma-, and deltaretroviruses, such as Rous sarcoma virus, MasonPfizer monkey virus or mouse mammary tumor virus, murine leukemia virus or feline leukemia virus, and human T-cell leukemia virus or bovine leukemia virus, respectively; (iii) spumaviruses, such as primate foamy virus and feline foamy virus; (iv) hepadnaviruses, such as hepatitis B virus; (v) endogenous retroviruses and long terminal repeat retrotransposons, such as human endogenous retrovirus K, murine intracisternal A particle, murine MusD, and porcine endogenous retrovirus; (vi) non-long terminal repeat retroposons, such as L1 and Alu; and (vii) DNA viruses, such as adenoassociated virus and human papillomavirus. Over the past few years, there has also been an increasing appreciation for the multiple, distinct mechanisms that parasitic elements use to coexist with the A3 proteins of their hosts. Together, these observations indicate that the evolution of the A3 proteins has been driven by a requirement to minimize the spread of exogenous and endogenous genetic threats. The likelihood that the A3 proteins might exist solely for this purpose has been supported recently by studies indicating that A3-deficient mice have no obvious phenotypes apart from a notable increase in susceptibility to retrovirus infection (16,19,21,23).A3 genes are specific to mammals and are organized in a tandem array between two vertebrate-conserved flanking genes, CBX6 and CBX7 (Fig. 1A) (e.g., see reference 13). Based on a limited number of genomic sequences, it is already clear that the A3 copy number can vary greatly from mammal to mammal. For instance, mice have one A3 gene (10, 16), pigs have two (13), cattle and sheep have three (13), cats have four (17), horses have six (2), and humans and chimpanzees have seven (4, 10, 11). Other mammals are likely to have copy numbers within this range, but the cat and horse loci, in particular, highlight the difficulty in making such predictions (2, 17).
Osteosarcomas are sarcomas of the bone, derived from osteoblasts or their precursors, with a high propensity to metastasize. Osteosarcoma is associated with massive genomic instability, making it problematic to identify driver genes using human tumors or prototypical mouse models, many of which involve loss of Trp53 function. To identify the genes driving osteosarcoma development and metastasis, we performed a Sleeping Beauty (SB) transposon-based forward genetic screen in mice with and without somatic loss of Trp53. Common insertion site (CIS) analysis of 119 primary tumors and 134 metastatic nodules identified 232 sites associated with osteosarcoma development and 43 sites associated with metastasis, respectively. Analysis of CIS-associated genes identified numerous known and new osteosarcoma-associated genes enriched in the ErbB, PI3K-AKT-mTOR and MAPK signaling pathways. Lastly, we identified several oncogenes involved in axon guidance, including Sema4d and Sema6d, which we functionally validated as oncogenes in human osteosarcoma.
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