Post-translational modifications (PTMs) broadly contribute to the recent explosion of proteomic data and possess a complexity surpassing that of protein design. PTMs are the chemical modification of a protein after its translation, and have wide effects broadening its range of functionality. Based on previous estimates, it is widely believed that more than half of proteins are glycoproteins. Whereas mutations can only occur once per position, different forms of post-translational modifications may occur in tandem. With the number and abundances of modifications constantly being discovered, there is no method to readily assess their relative levels. Here we report the relative abundances of each PTM found experimentally and putatively, from high-quality, manually curated, proteome-wide data, and show that at best, less than one-fifth of proteins are glycosylated. We make available to the academic community a continuously updated resource (http://selene.princeton.edu/PTMCuration) containing the statistics so scientists can assess “how many” of each PTM exists.
The simian virus (SV40) 72-base pair (bp) tandem repeated sequences have recently been shown to function as activators or enhancers of early viral transcription. A recombinant viral genome was recently constructed by inserting 72-bp tandem repeats from the Moloney murine sarcoma virus (MSV) in place of the 72-bp repeats of SV40. Although this genome replicates in monkey kidney cells, its rateof large tumor antigen expression and replication is considerably slower than that of wild-type SV40. In mouse cells, however, equivalent levels of large tumor antigen appear to be expressed from both wild-type and recombinant genomes, suggesting a relationship between the level of enhancer activity and the host cell. To confirm this observation, we have applied a sensitive quantitative assay for gene expression based on the conversion of chloramphenicol to its acetylated forms. The gene encoding the enzymatic function chloramphenicol acetyltransferase was inserted into two vectors in which the enhancer sequences from SV40 or MSV were placed adjacent to the early SV40 promoter. The SV40.tandem repeats appear to activate gene expression to significantly higher levels in monkey kidney cells, but-the MSV repeats are more active in two lines of mouse cells. These findings suggest that the tandem repeat elements may interact with host-specific molecules and, furthermore, may constitute one of the elements determining the host range of these eukaryotic viruses.Characterization of the nucleotide signals that constitute eukaryotic promoters is essential to an-understanding ofgene regulation. In addition to the Goldberg-Hogness sequence (or T-A-T-A box) which participates 'in the precise positioning of the 5' ends of RNA-molecules (1-3), upstream elements have been implicated in the activation or enhancement oftranscription for certain viral or eukaryotic genes by a number of studies (4)(5)(6)(7)(8)(9)(10)(11)(12). It was initially demonstrated that the simian virus 40 (SV40) 72-base-pair (bp) repeats activate early viral gene expression (5, 6). Further studies indicated that these sequences could also function when they were removed from their original location and placed at positions distant from the other promoter elements (8, 9). The tandem repeats also retained activity when inserted in an inverse orientation (9, 13). Other studies have indicated that the 72-bp repeats ofSV40 could increase the transformation efficiency of the herpes simplex virus thymidine kinase gene (10). An analogous fragment from the polyoma virus genome was shown to enhance the transcriptional activity of heterologous genes such as rabbit /3-globin gene (11).We have recently demonstrated that a retrovirus, the Moloney murine sarcoma virus (MSV), contains sequences in the long terminal repeats (LTRs) which can functionally replace the 72-bp repeats of SV40 (12). Preliminary data on large tumor antigen (T antigen) expression has suggested the possibility that the tandem repeats of SV40 and MSV activate gene expression in a host-specific manner.In th...
The complete DNA sequence of human papovavirus BKV(Dun), consisting of 5153 nucleotide pairs, is presented. We describe the segments of the genome which correspond to the replication origin, the tandem repeated sequences, the 5' and 3' ends of the mRNAs, the splice sites, the early and late viral proteins and the putative viral polypeptides. These BKV DNA sequences are compared with analogous regions in the SV40 and Py virus genomes in an attempt to localize viral functions for lytic growth and transformation.
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Human T-lymphotropic virus type 1 (HTLV-1) is a suspected causative agent of adult T-cell leukemia. One of the viral genes encodes a protein (tat) that not only results in transactivation of viral gene expression but may also regulate the expression of certain cellular genes that are important for cell growth. Transgenic mice that expressed the authentic tat protein under the control of the HTLV-1 long terminal repeat were generated, and cell types that are permissive for the viral promoter and the effects of the tat gene on these cells were studied. Three of eight founder mice with high levels of expression of the transgene in muscle were bred and then analyzed. All developed soft tissue tumors at multiple sites between 13 to 17 weeks of age. This phenotype was transmitted to nine of nine offspring that inherited the tat gene and were available for analysis. The remaining five founders expressed the transgene in the thymus, as well as in muscle. This second group of mice all exhibited extensive thymic depletion and growth retardation; in all of these mice, death occurred between 3 to 6 weeks of age before tumors became macroscopically visible. The tat gene under the control of the HTLV-1 regulatory region showed tissue-specific expression and the tat protein efficiently induced mesenchymal tumors. The data establish tat as an oncogenic protein and HTLV-1 as a transforming virus.
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