Loss of mismatch repair signaling impairs the WNT-bone morphogenetic protein crosstalk and the colonic homeostasis.

The fine balance between proliferation, differentiation, and apoptosis in the colonic epithelium is tightly controlled by the interplay between WNT, Notch, and bone morphogenetic protein (BMP) signaling. How these complex networks coordinate the colonic homeostasis, especially if cancer predisposing mutations such as mutations in the DNA mismatch repair (MMR) are present, is unclear. Inactivation of the MMR system has long been linked to colorectal cancer; however, little is known about its role in the regulation of the colonic homeostasis. It has been shown that loss of MMR promotes the proliferation of colon epithelial cells that renders them highly susceptible to transformation. The mechanism through which MMR mediates this effect, yet, remains to be determined. Using an MMR-deficient mouse model, we show that increased methylation of Dickkopf1 impacts its expression, and consequently, the ability to negatively regulate WNT signaling. As a result, excessive levels of active ß-catenin promote strong crypt progenitor-like phenotype and abnormal proliferation. Under these settings, the development and function of the goblet cells are affected. MMR-deficient mice have fewer goblet cells with enlarged mucin-loaded vesicles. We further show that MMR inactivation impacts the WNT-BMP signaling crosstalk.

The Inhibitory NKR-P1B:Clr-b Recognition Axis Facilitates Detection of Oncogenic Transformation and Cancer Immunosurveillance.

Natural killer (NK) cells express receptors specific for MHC class I (MHC-I) molecules involved in "missing-self" recognition of cancer and virus-infected cells. Here we elucidate the role of MHC-I-independent NKR-P1B:Clr-b interactions in the detection of oncogenic transformation by NK cells. Ras oncogene overexpression was found to promote a real-time loss of Clr-b on mouse fibroblasts and leukemia cells, mediated in part via the Raf/MEK/ERK and PI3K pathways. Ras-driven Clr-b downregulation occurred at the level of the Clrb (Clec2d) promoter, nascent Clr-b transcripts, and cell surface Clr-b protein, in turn promoting missing-self recognition via the NKR-P1B inhibitory receptor. Both Ras- and c-Myc-mediated Clr-b loss selectively augmented cytotoxicity of oncogene-transformed leukemia cells by NKR-P1B+ NK cells in vitro and enhanced rejection by WT mice in vivo Interestingly, genetic ablation of either one (Clr-b+/-) or two Clr-b alleles (Clr-b-/-) enhanced survival of Eµ-cMyc transgenic mice in a primary lymphoma model despite preferential rejection of Clr-b-/- hematopoietic cells previously observed following adoptive transfer into naïve wild-type mice in vivo Collectively, these findings suggest that the inhibitory NKR-P1B:Clr-b axis plays a beneficial role in innate detection of oncogenic transformation via NK-cell-mediated cancer immune surveillance, in addition to a pathologic role in the immune escape of primary lymphoma cells in Eµ-cMyc mice in vivo These results provide a model for the human NKR-P1A:LLT1 system in cancer immunosurveillance in patients with lymphoma and suggest it may represent a target for immune checkpoint therapy.Significance: A mouse model shows that an MHC-independent NK-cell recognition axis enables the detection of leukemia cells, with implications for a novel immune checkpoint therapy target in human lymphoma. Cancer Res; 78(13); 3589-603. ©2018 AACR.

Deficiency in the DNA glycosylases UNG1 and OGG1 does not potentiate c-Myc-induced B-cell lymphomagenesis.

C-Myc overexpression mediates lymphomagenesis; however, secondary genetic lesions are required for its full oncogenic potential. The origin and the mechanism of formation of these mutations are unclear. Using the lacI mutation detection system, we show that secondary mutations occur early in B-cell development and are repaired by Msh2. The mutations at the lacI gene were predominantly at C:G base pairs and CpG motifs, suggesting that they were formed due to cytosine deamination or oxidative damage of G. Therefore, we investigated the role of Ogg1 and UNG glycosylases in c-Myc-driven lymphomagenesis but found that their deficiencies did not influence disease outcome in the Eµ c-Myc mouse model. We also show that Rag proteins do not contribute to secondary lesions in this model. Our work suggests that mutations at C:G base pairs that are repaired primarily by the mismatch repair system arise early in B-cell ontogeny to promote c-Myc-driven lymphomagenesis.

MicroRNAs at the epicenter of intestinal homeostasis.

Maintaining intestinal homeostasis is a key prerequisite for a healthy gut. Recent evidence points out that microRNAs (miRNAs) act at the epicenter of the signaling networks regulating this process. The fine balance in the interaction between gut microbiota, intestinal epithelial cells, and the host immune system is achieved by constant transmission of signals and their precise regulation. Gut microbes extensively communicate with the host immune system and modulate host gene expression. On the other hand, sensing of gut microbiota by the immune cells provides appropriate tolerant responses that facilitate the symbiotic relationships. While the role of many regulatory proteins, receptors and their signaling pathways in the regulation of the intestinal homeostasis is well documented, the involvement of non-coding RNA molecules in this process has just emerged. This review discusses the most recent knowledge about the contribution of miRNAs in the regulation of the intestinal homeostasis.

Gut microbial metabolism and colon cancer: can manipulations of the microbiota be useful in the management of gastrointestinal health?

The gut microbiota is an important component of the human body and its immune-modulating and metabolic activities are critical to maintain good health. Gut microbes, however, are sensitive to changes in diet, exposure to antibiotics, or infections, all of which cause transient disruptions in the microbial composition, a phenomenon known as dysbiosis. It is now recognized that microbial dysbiosis is at the root of many gastrointestinal disorders. However, the mechanisms through which bacterial dysbiosis initiates disease are not fully understood. Microbially-derived metabolites and their role in disease have also attracted significant attention. Identification of cancer-associated bacteria and understanding the contributions of microbial metabolism in health and disease are exciting but challenging areas that will allow defining microbial biomarkers for predicting gastrointestinal disorders. Understanding the complex interactions between gut microbiota, diet, host immune system and host genetics will be critical to developing more personalized therapies and approaches to treat disease.

Gut microbiota and colon cancer: the carbohydrate link.

Understanding the complex pathophysiology of colorectal cancer and the interaction between host genetics, the gut microbiome, and diet has attracted significant attention in the last few years. The discovery that gut microbial metabolites may dictate the course of colorectal cancer progression supports the development of microbial-targeted strategies.

Gut microbial metabolism drives transformation of MSH2-deficient colon epithelial cells.

The etiology of colorectal cancer (CRC) has been linked to deficiencies in mismatch repair and adenomatous polyposis coli (APC) proteins, diet, inflammatory processes, and gut microbiota. However, the mechanism through which the microbiota synergizes with these etiologic factors to promote CRC is not clear. We report that altering the microbiota composition reduces CRC in APC(Min/+)MSH2(-/-) mice, and that a diet reduced in carbohydrates phenocopies this effect. Gut microbes did not induce CRC in these mice through an inflammatory response or the production of DNA mutagens but rather by providing carbohydrate-derived metabolites such as butyrate that fuel hyperproliferation of MSH2(-/-) colon epithelial cells. Further, we provide evidence that the mismatch repair pathway has a role in regulating ß-catenin activity and modulating the differentiation of transit-amplifying cells in the colon. These data thereby provide an explanation for the interaction between microbiota, diet, and mismatch repair deficiency in CRC induction. PAPERCLIP:

The mitochondrial protein NLRX1 controls the balance between extrinsic and intrinsic apoptosis.

NLRX1 is a mitochondrial Nod-like receptor (NLR) protein whose function remains enigmatic. Here, we observed that NLRX1 expression was glucose-regulated and blunted by SV40 transformation. In transformed but not primary murine embryonic fibroblasts, NLRX1 expression mediated resistance to an extrinsic apoptotic signal, whereas conferring susceptibility to intrinsic apoptotic signals, such as glycolysis inhibition, increased cytosolic calcium and endoplasmic reticulum stress. In a murine model of colorectal cancer induced by azoxymethane, NLRX1-/- mice developed fewer tumors than wild type mice. In contrast, in a colitis-associated cancer model combining azoxymethane and dextran sulfate sodium, NLRX1-/- mice developed a more severe pathology likely due to the increased sensitivity to dextran sulfate sodium colitis. Together, these results identify NLRX1 as a critical mitochondrial protein implicated in the regulation of apoptosis in cancer cells. The unique capacity of NLRX1 to regulate the cellular sensitivity toward intrinsic versus extrinsic apoptotic signals suggests a critical role for this protein in numerous physiological processes and pathological conditions.

The multifaceted role of the intestinal microbiota in colon cancer.

In recent years, our understanding of the mechanisms underlying colorectal carcinogenesis has vastly expanded. Underlying inflammation within the intestine, diet, and most recently, the gut microbiota, have been demonstrated to influence the development of colorectal cancer. However, since cancer is ultimately a genetic disease, these factors are thought to create genotoxic stress within the intestinal environment to promote genetic and epigenetic alterations leading to cancer. In this review, we will focus on how gut microbes intersect with inflammation, diet, and host genetics to influence the development of colon cancer.

Elevated incidence of polyp formation in APC(Min/⁺)Msh2⁻/⁻ mice is independent of nitric oxide-induced DNA mutations.

Gut microbiota has been linked to a number of human diseases including colon cancer. However, the mechanism through which gut bacteria influence colon cancer development and progression remains unclear. Perturbation of the homeostasis between the host immune system and microbiota leads to inflammation and activation of macrophages which produce large amounts of nitric oxide that acts as a genotoxic effector molecule to suppress bacterial growth. However, nitric oxide also has genotoxic effects to host cells by producing mutations that can predispose to colon cancer development. The major DNA lesions caused by nitric oxide are 8oxoG and deamination of deoxycytosine bases. Cellular glycosylases that belong to the base excision repair pathway have been demonstrated to repair these mutations. Recent evidence suggests that the mismatch repair pathway (MMR) might also repair nitric oxide-induced DNA damage. Since deficiency in MMR predisposes to colon cancer, we hypothesized that MMR-deficient colon epithelial cells are incapable of repairing nitric-oxide induced genetic lesions that can promote colon cancer. Indeed, we found that the MMR pathway repairs nitric oxide-induced DNA mutations in cell lines. To test whether nitric oxide promotes colon cancer, we genetically ablated the inducible nitric oxide synthase (iNOS) or inhibited iNOS activity in the APC(Min/+)Msh2(-/-) mouse model of colon cancer. However, despite the fact that nitric oxide production was strongly reduced in the colon using both approaches, colon cancer incidence was not affected. These data show that nitric oxide and iNOS do not promote colon cancer in APC(Min/+)Msh2(-/-) mice.

Staphylococcus aureus methicillin-resistance factor fmtA is regulated by the global regulator SarA.

fmtA encodes a low-affinity penicillin binding protein in Staphylococcus aureus. It is part of the core cell wall stimulon and is involved in methicillin resistance in S. aureus. Here, we report that the transcription factor, SarA, a pleiotropic regulator of virulence genes in S. aureus, regulates the expression of fmtA. In vitro binding studies with purified SarA revealed that it binds to specific sites within the 541-bp promoter region of fmtA. Mutation of a key residue of the regulatory activity of SarA (Arg90) abolished binding of SarA to the fmtA promoter, suggesting that SarA binds specifically to the fmtA promoter region. In vivo analysis of the fmtA promoter using a lux operon reporter fusion show high level expression following oxacillin induction, which was abrogated in a sarA mutant strain. These data suggest that SarA is essential for the induction of fmtA expression by cell wall-specific antibiotics. Further, in vitro transcription studies show that SarA enhances fmtA transcription and suggest that regulation of fmtA could be via a SigA-dependent mechanism. Overall, our results show that SarA plays a direct role in the regulation of fmtA expression via binding to the fmtA promoter.

Negative supercoiling creates single-stranded patches of DNA that are substrates for AID-mediated mutagenesis.

Antibody diversification necessitates targeted mutation of regions within the immunoglobulin locus by activation-induced cytidine deaminase (AID). While AID is known to act on single-stranded DNA (ssDNA), the source, structure, and distribution of these substrates in vivo remain unclear. Using the technique of in situ bisulfite treatment, we characterized these substrates-which we found to be unique to actively transcribed genes-as short ssDNA regions, that are equally distributed on both DNA strands. We found that the frequencies of these ssDNA patches act as accurate predictors of AID activity at reporter genes in hypermutating and class switching B cells as well as in Escherichia coli. Importantly, these ssDNA patches rely on transcription, and we report that transcription-induced negative supercoiling enhances both ssDNA tract formation and AID mutagenesis. In addition, RNaseH1 expression does not impact the formation of these ssDNA tracts indicating that these structures are distinct from R-loops. These data emphasize the notion that these transcription-generated ssDNA tracts are one of many in vivo substrates for AID.

Roles of DNA sequence and sigma A factor in transcription of the vraSR operon.

Cell wall damage in Staphylococcus aureus induces a rapid genome-wide response, referred to as the cell wall stress stimulon. This response is mediated by a two-component system, the vancomycin resistance-associated sensor/regulator (VraSR). The response regulator protein VraR is a transcription factor. Here, we demonstrate that two VraR binding sites in the vraSR operon control region are involved in the regulation of the vraSR operon. The sites are centered at the -60 and -35 nucleotide positions and are referred to as R1 and R2, respectively. DNase I footprinting and lux operon reporter vector studies showed that both of these sites communicate intimately with each other to fine-tune the activity of the vraSR operon. Mutagenesis of the VraR binding sites showed that dimerization of unphosphorylated VraR at R1 is driven by a hierarchy in VraR binding and by the proximity of the two tandem VraR binding sequences at this site. On the other hand, these studies show that the lack of sequence conservation and the distance between the VraR binding sequences in R2 ensure that VraR is recruited to this site only when phosphorylated (hence, under stress conditions). Furthermore, we demonstrate that sigma A (SigA) factor is involved in the regulation of the vraSR operon. Our study shows that sigma A factor does not bind to the vraSR operon control region in the absence of VraR, suggesting that VraR may interact directly with this factor.

The mismatch repair pathway functions normally at a non-AID target in germinal center B cells.

Deficiency in Msh2, a component of the mismatch repair (MMR) system, leads to an approximately 10-fold increase in the mutation frequency in most tissues. By contrast, Msh2 deficiency in germinal center (GC) B cells decreases the mutation frequency at the IgH V region as a dU:dG mismatch produced by AID initiates modifications by MMR, resulting in mutations at nearby A:T base pairs. This raises the possibility that GC B cells express a factor that converts MMR into a globally mutagenic pathway. To test this notion, we investigated whether MMR corrects mutations in GC B cells at a gene that is not mutated by AID. Strikingly, we found that GC B cells accumulate 5 times more mutations at a reporter gene than during the development of the mouse. Notably, the mutation frequency at this reporter gene was approximately 10 times greater in Msh2(-/-) compared with wild-type GC B cells cells. In contrast to the V region, the increased level of mutations at A:T base pairs in GC B cells was not caused by MMR. These results show that in GC B cells, (1) MMR functions normally at an AID-insensitive gene and (2) the frequency of background mutagenesis is greater in GC B cells than in their precursor follicular B cells.

Phosphorylation-induced activation of the response regulator VraR from Staphylococcus aureus: insights from hydrogen exchange mass spectrometry.

A two-component system consisting of the histidine kinase vancomycin-resistance-associated sensor and the response regulator vancomycin-resistance-associated regulator (VraR) allows Staphylococcus aureus to sense antibiotic-related cell wall stress and to mount a suitable response. An experimental structure of full-length VraR is not available yet, but previous work points to similarities between VraR and the well-characterized NarL. This work employs hydrogen exchange mass spectrometry to gain insights into the phosphorylation-induced activation of VraR, a process that primes the protein for dimerization and DNA binding. Whereas VraR is highly dynamic, phosphorylated VraR shows less extensive deuteration. This rigidification is most dramatic within the receiver domain, which carries the phosphorylation site D55. Alterations in the DNA-binding domain are much less pronounced. Changes in deuteration within the receiver domain are consistent with a Y-T coupling mechanism. In analogy to NarL, the activation of VraR is thought to involve separation and subsequent reorientation of the two domains, thereby allowing the alpha8-turn-alpha9 element to engage in DNA binding. The current work suggests that this structural transition is triggered by a reduction in the effective length of the linker through enhanced hydrogen bonding. In addition, separation of the two domains may be favored by the establishment of noncovalent protein-protein interactions and intradomain contacts at the expense of previously existing interdomain bonds. alpha9 appears to be packed against the receiver domain in nonactivated VraR. Support is presented for alpha1 as a dimerization interface in phosphorylated VraR, whereas protein-protein interactions for nonphosphorylated VraR are impeded by extensive disorder in this region.

DNA-binding activity of the vancomycin resistance associated regulator protein VraR and the role of phosphorylation in transcriptional regulation of the vraSR operon.

In Staphylococcus aureus the VraSR two-component system acts as a sentinel that can rapidly sense cell wall peptidoglycan damage and coordinate a response to enhance the resistance phenotype. VraR is a transcription factor and its cognate kinase, VraS, modulates the DNA-binding activity of VraR by regulating its phosphorylation state and hence its dimerization state. Here we provide the first report on the VraR transcriptional activity by investigating the interaction with the vraSR operon control region. We found that this region contains three VraR-binding sites, each with unique VraR-binding features. VraR binding to the most conserved site is phosphorylation independent, and dimerization is proposed to be induced through binding to DNA. By contrast, binding to the less conserved site requires phosphorylation of VraR. This site overlaps with the binding site of the sigma subunit of the RNA polymerase complex, suggesting that VraR could be interacting with the transcription machinery in the presence of the cell wall stress signal. Mutagenesis studies on the VraR binding sites suggest that there is directionality in the binding of VraR to the target DNA, probably dictated by VraR dimerization. We also constructed a P(vraSR)-fused lux operon reporter vector to investigate in vivo the significance of our in vitro studies. These studies show that upon cell wall stress, induced by oxacillin, the expression level of the lux operon goes up and it is affected by the integrity of the two identified VraR-binding sites in agreement with the in vitro studies. Further, they demonstrate that the VraR most conserved binding site is essential to the vraSR operon expression. On the other hand, they suggest that the role of the VraR less conserved site could be that of mediating high levels of vraSR operon expression during cell wall stress conditions.

A close-up view of the VraSR two-component system. A mediator of Staphylococcus aureus response to cell wall damage.

Staphylococcus aureus remains a clinical scourge. Recent studies have revealed that S. aureus is capable of mounting a response to antibiotics that target cell wall peptidoglycan biosynthesis, such as beta-lactams and vancomycin. A phosphotransfer-mediated signaling pathway composed of a histidine protein kinase, VraS, and a response regulator protein, VraR, has been linked to the coordination of this response. Herein, we report for the first time on the signal transduction mechanism of the VraSR system. We found that VraS is capable of undergoing autophosphorylation in vitro and its phosphoryl group is rapidly transferred to VraR. In addition, phosphorylated VraR undergoes rapid dephosphorylation by VraS. Evidence is presented that VraR has adopted a novel strategy in regulating the output response of the VraSR-mediated signaling pathway. The VraR effector domain inhibits formation of inactive VraR dimers and, in doing so, it holds the regulatory domain into an intermediate active state. We show that only phosphorylation induces formation of the biological active VraR-dimer species. Furthermore, we propose that damage inflicted to cell wall peptidoglycan could be the main source of the stimuli that VraR responds to due to the tight control that VraS has on the phosphorylation state of VraR. Our findings provide for the first time insights into the molecular basis for the proposed role of VraSR as a "sentinel" system capable of rapidly sensing cell wall peptidoglycan damage and coordinating a response that enhances the resistance phenotype in S. aureus.

Effects of cigarette smoking on sperm plasma membrane integrity and DNA fragmentation.

Cigarette smoking is a serious health problem of our society. It is known that cigarette smoke is a cell mutagen and carcinogen, and that it may affect adversely male fertility. The possible detrimental effects on sperm cells are of great interest but the data available to support this statement are somewhat elusive. To approach this problem we examined conventional semen parameters, plasma membrane translocation of phosphatidylserine (PS) (annexin V/6-CFDA cell staining) and sperm DNA integrity (comet assay) in a group of healthy man smoking cigarettes on a regular basis. The results of the study were compared with the results of the same tests in healthy non-smoking donors. Significant difference in standard sperm parameters between the two groups was not found. Intensive expression of PS on the sperm plasma membrane surface (assayed by annexin V positive staining) was detected in the smokers group. There is a significant increase of population of apoptotic spermatozoa in ejaculates of smokers. Albeit DNA damages (high frequencies of double- and single- stranded DNA breaks) in spermatozoa of smokers are increased compared with non-smokers, but this difference is not statistically significant. Sperm DNA integrity of healthy smokers remains in the normal range, but a clear negative trend is observed, especially in respect of disturbance of plasma membrane phospholipid asymmetry.