Inteins are genetic elements that disrupt the coding sequence of genes. However, in contrast to introns, inteins are transcribed and translated together with their host protein. Inteins appear most frequently in Archaea, but they are found in organisms belonging to all three domains of life and in viral and phage proteins. Most inteins consist of two domains: One is involved in autocatalytic splicing, and the other is an endonuclease that is important in the spread of inteins. This review focuses on the evolution and technical application of inteins and only briefly summarizes recent advances in the study of the catalytic activities and structures of inteins. In particular, this review considers inteins as selfish or parasitic genetic elements, a point of view that explains many otherwise puzzling aspects of inteins.
The base excision repair system is vital to the repair of endogenous and exogenous DNA damage. This pathway is initiated by one of several DNA glycosylases that recognizes and excises specific DNA lesions in a coordinated fashion. Methyl-CpG Domain Protein 4 (MBD4) and Thymine DNA Glycosylase (TDG) are the two major G:T glycosylases that remove thymine generated by the deamination of 5-methylcytosine. Both of these glycosylase also remove a variety of other base lesions, including G:U and preferentially act at CpG sites throughout the genome. Many have questioned the purpose of seemingly redundant glycosylases, but new information has emerged to suggest MBD4 and TDG have diverse biological functions. MBD4 has been closely linked to apoptosis, while TDG has been clearly implicated in transcriptional regulation. This article reviews all these developments, and discusses the consequences of germline and somatic mutations that lead to non-synonymous amino acid substitutions on MBD4 and TDG protein function. In addition, we report the finding of alternately spliced variants of MBD4 and TDG and the results of functional studies of a tumor-associated variant of MBD4.
Summary A replication study of a previous genome-wide association study (GWAS) suggested that a single nucleotide polymorphism (SNP) linked to the POLB gene is associated with systemic lupus erythematosus (SLE). This SNP is correlated with decreased POLB expression (Pol β). To determine if decreased Pol β activity results in SLE, we constructed a mouse model of POLB that encodes an enzyme with slow DNA polymerase activity. Pol β is a key enzyme in the base excision repair (BER) pathway.. We show that mice expressing this hypomorphic POLB allele develop autoimmune pathology strongly resembling SLE. Of note, the immunoglobulin heavy chain junctions from the POL BY265C/C mice have shorter lengths, and somatic hypermutation is dramatically increased. These results demonstrate that decreased Pol β activity during the generation of immune diversity leads to lupus-like disease in mice and suggest that decreased expression of Pol β in humans is an underlying cause of SLE.
Background Inteins and introns are genetic elements that are removed from proteins and RNA after translation or transcription, respectively. Previous studies have suggested that these genetic elements are found in conserved parts of the host protein. To our knowledge this type of analysis has not been done for group II introns residing within a gene. Here we provide quantitative statistical support from an analyses of proteins that host inteins, group I introns, group II introns and spliceosomal introns across all three domains of life. Results To determine whether or not inteins, group I, group II, and spliceosomal introns are found preferentially in conserved regions of their respective host protein, conservation profiles were generated and intein and intron positions were mapped to the profiles. Fisher's combined probability test was used to determine the significance of the distribution of insertion sites across the conservation profile for each protein. For a subset of studied proteins, the conservation profile and insertion positions were mapped to protein structures to determine if the insertion sites correlate to regions of functional activity. All inteins and most group I introns were found to be preferentially located within conserved regions; in contrast, a bacterial intein-like protein, group II and spliceosomal introns did not show a preference for conserved sites. Conclusions These findings demonstrate that inteins and group I introns are found preferentially in conserved regions of their respective host proteins. Homing endonucleases are often located within inteins and group I introns and these may facilitate mobility to conserved regions. Insertion at these conserved positions decreases the chance of elimination, and slows deletion of the elements, since removal of the elements has to be precise as not to disrupt the function of the protein. Furthermore, functional constrains on the targeted site make it more difficult for hosts to evolve immunity to the homing endonuclease. Therefore, these elements will better survive and propagate as molecular parasites in conserved sites. In contrast, spliceosomal introns and group II introns do not show significant preference for conserved sites and appear to have adopted a different strategy to evade loss.
The Fragile X-related disorders (FXDs) are members of the Repeat Expansion Diseases, a group of human genetic conditions resulting from expansion of a specific tandem repeat. The FXDs result from expansion of a CGG/CCG repeat tract in the 5’ UTR of the FMR1 gene. While expansion in a FXD mouse model is known to require some mismatch repair (MMR) proteins, our previous work and work in mouse models of another Repeat Expansion Disease show that early events in the base excision repair (BER) pathway play a role in the expansion process. One model for repeat expansion proposes that a non-canonical MMR process makes use of the nicks generated early in BER to load the MMR machinery that then generates expansions. However, we show here that heterozygosity for a Y265C mutation in Polβ, a key polymerase in the BER pathway, is enough to significantly reduce both the number of expansions seen in paternal gametes and the extent of somatic expansion in some tissues of the FXD mouse. These data suggest that events in the BER pathway downstream of the generation of nicks are also important for repeat expansion. Somewhat surprisingly, while the number of expansions is smaller, the average size of the residual expansions is larger than that seen in WT animals. This may have interesting implications for the mechanism by which BER generates expansions.
Peroxisome proliferator-activated receptor gamma (PPARγ) is a transcription factor that regulates lipid and glucose metabolism. Although studies of PPARγ ligands have demonstrated its regulatory functions in inflammation and adaptive immunity, its intrinsic role in T cells and autoimmunity has yet to be fully elucidated. Here we used CD4-PPARγKO mice to investigate PPARγ-deficient T cells, which were hyper-reactive to produce higher levels of cytokines and exhibited greater proliferation than wild type T cells with increased ERK and AKT phosphorylation. Diminished expression of IκBα, Sirt1, and Foxo1, which are inhibitors of NF-κB, was observed in PPARγ-deficient T cells that were prone to produce all the signature cytokines under Th1, Th2, Th17, and Th9 skewing condition. Interestingly, 1-year-old CD4-PPARγKO mice spontaneously developed moderate autoimmune phenotype by increased activated T cells, follicular helper T cells (TFH cells) and germinal center B cells with glomerular inflammation and enhanced autoantibody production. Sheep red blood cell immunization more induced TFH cells and germinal centers in CD4-PPARγKO mice and the T cells showed increased of Bcl-6 and IL-21 expression suggesting its regulatory role in germinal center reaction. Collectively, these results suggest that PPARγ has a regulatory role for TFH cells and germinal center reaction to prevent autoimmunity.
DNA is susceptible to damage by a wide variety of chemical agents that are generated either as byproducts of cellular metabolism or exposure to man-made and harmful environments. Therefore, to maintain genomic integrity, having reliable DNA repair systems is important. DNA polymerase β is known to be a key player in the base excision repair pathway, and mice devoid of DNA polymerase beta do not live beyond a few hours after birth. In this study, we characterized mice harboring an impaired pol β variant. This Y265C pol β variant exhibits slow DNA polymerase activity but WT lyase activity and has been shown to be a mutator polymerase. Mice expressing Y265C pol β are born at normal Mendelian ratios. However, they are small, and 60% die within a few hours after birth. Slow proliferation and significantly increased levels of cell death are observed in many organs of the E14 homozygous embryos compared with WT littermates. Mouse embryo fibroblasts prepared from the Y265C pol β embryos proliferate at a rate slower than WT cells and exhibit a gap-filling deficiency during base excision repair. As a result of this, chromosomal aberrations and single-and double-strand breaks are present at significantly higher levels in the homozygous mutant versus WT mouse embryo fibroblasts. This is study in mice is unique in that two enzymatic activities of pol β have been separated; the data clearly demonstrate that the DNA polymerase activity of pol β is essential for survival and genome stability. Thus, having a reliable DNA repair system is crucial to maintain the integrity of cellular DNA (1-3). DNA polymerase beta (pol β) is a 39-kDa protein (4) that is a member of the X family group of DNA polymerases. pol β is a key player in base excision repair (BER) (4-6). During BER, damaged bases are recognized and excised by lesion-specific DNA glycosylases (7). Subsequently, the DNA backbone is cleaved by AP endonuclease (APE1), creating 3′-OH and 5′-deoxyribose phosphate (5′-dRP) ends. pol β, the major polymerase during BER, fills in the gap by adding nucleotide/s onto the 3′-OH using polymerase activity, and removes the 5′-dRP group using its lyase activity. The nick is then sealed by XRCC1-DNA ligase IIIα (8). For oxidative damage, bifunctional glycosylases play a major role and cleave the backbone. The DNA ends are remodeled by phosphatases or phosphodiesterases (9) before pol β fills in the gap. Therefore, pol β functions in the gapfilling step of all short-patch BER subpathways.Results from small-scale studies have shown that about one third of all human tumors express pol β variant proteins (10). We have shown that some of these tumor-associated variant forms of pol β can induce a mutator phenotype and chromosomal aberrations by either error-prone or slow gap filling, respectively (10-12). The Y265C pol β variant was identified in a gastric carcinoma and has been shown to be a strong mutator polymerase, both in vitro and in vivo (13,14). In murine LN12 cells, expression of Y265C leads to an eightfold increase in mutation frequency...
Outer membrane vesicles (OMVs) are spherical bodies containing proteins and nucleic acids that are released by Gram-negative bacteria, including Borrelia burgdorferi, the causative agent of Lyme disease. The functional relationship between B. burgdorferi OMVs and host neuron homeostasis is not well understood. The objective of this study was to examine how B. burgdorferi OMVs impact the host cell environment. First, an in vitro model was established by co-culturing human BE2C neuroblastoma cells with B. burgdorferi B31. B. burgdorferi was able to invade BE2C cells within 24 h. Despite internalization, BE2C cell viability and levels of apoptosis remained unchanged, but resulted in dramatically increased production of MCP-1 and MCP-2 cytokines. Elevated secretion of MCP-1 has previously been associated with changes in oxidative stress. BE2C cell mitochondrial superoxides were reduced as early as 30 min after exposure to B. burgdorferi and OMVs. To rule out whether BE2C cell antioxidant response is the cause of decline in superoxides, superoxide dismutase 2 (SOD2) gene expression was assessed. SOD2 expression was reduced upon exposure to B. burgdorferi, suggesting that B. burgdorferi might be responsible for superoxide reduction. These results suggest that B. burgdorferi modulates cell antioxidant defense and immune system reaction in response to the bacterial infection. In summary, these results show that B. burgdorferi OMVs serve to directly counter superoxide production in BE2C neurons, thereby ‘priming’ the host environment to support B. burgdorferi colonization.
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