Group II PLA 2 has been implicated in inflammatory processes in both man and other animals and has been shown to be involved in inflammatory conditions, such as arthritis and sepsis. Transgenic mice expressing the human group II PLA 2 gene have been generated using a 6.2-kb genomic fragment. These mice express the group II PLA 2 gene abundantly in liver, lung, kidney, and skin, and have serum PLA 2 activity levels approximately eightfold higher than nontransgenic littermates. The group II PLA 2 transgenic mice reported here exhibit epidermal and adnexal hyperplasia, hyperkeratosis, and almost total alopecia. The chronic epidermal hyperplasia and hyperkeratosis seen in these mice is similar to that seen in a variety of dermatopathies, including psoriasis. However, unlike what is seen with these dermatopathies, no significant inflammatory-cell influx was observed in the skin of these animals, or in any other tissue examined.
BackgroundTumor necrosis factor alpha (TNFα) is implicated in a wide variety of pathological and physiological processes, including chronic inflammatory conditions, coronary artery disease, diabetes, obesity, and cachexia. Transgenic mice expressing human TNFα (hTNFα) have previously been described as a model for progressive rheumatoid arthritis. In this report, we describe extensive characterization of an hTNFα transgenic mouse line.ResultsIn addition to arthritis, these hTNFα transgenic mice demonstrated major alterations in body composition, metabolic rate, leptin levels, response to a high-fat diet, bone mineral density and content, impaired fertility and male sexual function. Many phenotypes displayed an earlier onset and a higher degree of severity in males, pointing towards a significant degree of sexual dimorphism in response to deregulated expression of TNFα.ConclusionThese results highlight the potential usefulness of this transgenic model as a resource for studying the progressive effects of constitutively expressed low levels of circulating TNFα, a condition mimicking that observed in a number of human pathological conditions.
The role of the N-linked glycosylation sites in the major envelope glycoprotein, SU (gp7O), of Moloney murine leukemia virus has been examined. By using site-specific oligonucleotide-directed mutagenesis, each of the seven glycan addition sites has been individually eliminated. Mutations resulting in the loss of a single glycosylation site produced, intracellularly, stable precursor SU-TM proteins which were 4 to 5 kDa smaller than the wild-type virus SU-TM protein. Mutant A1,4,7, a trimutant lacking three N-linked glycan addition sites, resulted in a viable, infectious virus with a stable SU-TM protein approximately 12 to 15 kDa smaller than the wild-type SU-TM protein. Five of the seven single-site mutations resulted in viable virus as judged by the release of reverse transcriptase in transient-expression assays and XC syncytium assays. Mutations at two of the sites resulted in a detectable phenotype. Virus mutated at position 2 was temperature sensitive in Rat2 cells; viable virus was produced at 32°C but not at 37°C. Virus mutated at position 3 was noninfectious and yielded virions lacking detectable mature SU protein. The mutation results in the block of transport of the protein to the cell surface and assembly into virion particles.
The p12 protein of murine leukemia virus (MLV) Gag is associated with the preintegration complex (PIC), and mutants of p12 (PM14) exhibit defects in nuclear entry/retention. Mutants of the phosphorylated serine 61 also have been reported to have defects in the early life cycle. Here we show that a phosphorylated peptide motif derived from human papillomavirus 8 (HPV-8), the E2 hinge region including residues 240 to 255, can functionally replace the main phosphorylated motif of MLV p12 and can rescue the viral titer of a strain with the lethal p12-PM14 mutation. Complementation with the HPV-8 E2 hinge motif generated multiple second-site mutations in live viral passage assays. Additional p12 phosphorylation sites were detected, including the late domain of p12 (PPPY) as well as the late domain/protease cleavage site of matrix (LYPAL), by mass spectrometry and Western blotting. Chromatin binding of p12-green fluorescent protein (GFP) fusion protein and functional complementation of p12-PM14 occurred in a manner independent of the E2 hinge region phosphorylation. Replacement of serine 61 by alanine within the minimal tethering domain ( 61 SPMASRLRGRR 71 ) maintained tethering, but in the context of the full-length p12, mutants with substitutions in S61 remained untethered and lost infectivity, indicating phosphorylation of p12 serine 61 functions to temporally regulate early and late p12 functions. IMPORTANCE The p12 protein, required for both early and late viral functions, is the predominant phosphorylated viral protein of Moloney MLV and is required for virus viability. Our studies indicate that the N terminus of p12 represses the early function of the chromatin binding domain and that deletion of the N terminus activates chromatin binding in the wild-type Moloney MLV p12 protein. Mass spectrometry and mutagenesis studies suggest that phosphorylation of both the repression domain and the chromatin binding domain acts to temporally regulate this process at the appropriate stages during infection.T he murine leukemia virus (MLV) (genus Gammaretrovirus, family Retroviridae) Gag protein p12 is a multifunctional protein required in both early and late stages of viral replication. During the late stages of viral assembly, new virions must bud off their host cells, requiring membrane scission. The MLV p12 encodes a late-assembly (L) domain ( 31 PPPY 34 ) (1, 2), reported to interact with the host vesicular trafficking machinery, specifically the E3 ubiquitin ligases in the NEDD4 family, to facilitate Gag ubiquitylation and subsequent budding (3). In addition, the 25 DLL 27 motif in p12 has been reported to recruit clathrin to budding virions, which is required for correct particle morphogenesis and infectivity (4).In infected cells, two domains required for early replication were identified by mutational analysis: within the p12 N terminus at residues 10 to 24 (mutants PM5 to PM8) and within the p12 C terminus at residues 60 to 74 (mutants PM13 to PM15) (1, 5). The N terminus of p12 interacts with capsid (CA), ...
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