Guadalupe Herrera

Different efficiency of UmuDC and MucAB proteins in UV light induced mutagenesis in Escherichia coli

SummaryTwo multicopy plasmids carrying either the umuDC or the mucAB operon were used to compare the efficiency of UmuDC and MucAB proteins in UV mutagenesis of Escherichia coli K12. It was found that in recA+uvr+bacteria, plasmid pIC80, mucAB+mediated UV mutagenesis more efficiently than did plasmid pSE117, umuDC+. A similar result was obtained in lexA51(Def) cells, excluding the possibility that this was due to a differential regulation by LexA of the umuDC and mucAB operons. We conclude that some structural characteristic of the UmuDC and MucAB proteins determines their different efficiency in UV mutagenesis. This characteristic could be also responsible for the observation that in the recA430 mutant, pIC80 but no pSE117 can mediate UV mutagenesis. In the recA142 mutant, pIC80 also promoted UV mutagenesis more efficiently than pSE117. In this mutant, the recombination proficiency, the protease activity toward LexA and the mutation frequency were increased by the presence of adenine in the medium. In recA+uvrB5 bacteria, plasmid pSE117,umuDC caused both an increase in UV sensitivity as well as a reduction in the mutation frequency. These nagative effects resulting from the overproduction of UmuDC proteins were higher in recA142 uvrB5 than in recA+uvrB5 cells. In contrast, overproduction of MucAB proteins in excision-deficient bacteria containing pIC80 led to a large increase in the mutation frequency. We suggest that the functional differences between UmuDC and MucAB proteins might be due to their different dependence on the direct role of RecA protease in UV mutagenesis.

The relevance of flow cytometry for biochemical analysis.

Flow cytometry (FCM) allows the simultaneous measurement of multiple fluorescences and light scatter induced by illumination of single cells or microscopic particles in suspension, as they flow rapidly through a sensing area. In some systems, individual cells or particles may be sorted according to the properties exhibited. By using appropriate fluorescent markers, FCM is unique in that multiple structural and functional parameters can be quantified simultaneously on a single‐particle basis, whereas up to thousands of biological particles per second may be examined. FCM is increasingly used for basic, clinical, biotechnological, and environmental studies of biochemical relevance. In this critical review, we summarize the main advantages and limitations of FCM for biochemical studies and discuss briefly the most relevant parameters and analytical strategies. Graphical examples of the biological information provided by multiparametric FCM are presented. Also, this review contains specific sections on flow cytoenzymology, FCM analysis of isolated subcellular organelles, and cell‐free FCM.

Increased mutability by oxidative stress in OxyR-deficient Escherichia coli and Salmonella typhimurium cells: clonal occurrence of the mutants during growth on nonselective media

Escherichia coli and Salmonella typhimurium strains deficient in the OxyR-regulated adaptive response to oxidative stress were used to study the mode in which spontaneous SOS-dependent mutations are generated in a distressed bacterial population. When assayed on supplemented selective medium, the E. coli strain IC3821 (trpE65), carrying the delta oxyR30 mutation and containing the plasmid pRW144 (mucA/B), showed a frequency of spontaneous Trp+ revertants similar to that of the oxyR+ control. Instead, the IC3821 strain exhibited an enhancement in the clonal occurrence of spontaneous revertants arising at random during growth on a nonselective medium. A similar enhancement was observed for the S. typhimurium strain TA4125 (hisG428 delta oxyR2). The mutator effect observed in oxyR- cells would be induced by an increased background of reactive oxygen species; it provides a model for studying the mutability of a cell population constantly exposed to mutation-inducing agents. In the IC3821 strain, revertants were induced by t-butyl hydroperoxide with higher efficiency than in oxyR+. We suggest that strain IC3821 could be useful for the detection of SOS-dependent mutagenesis induced by chemical oxidants.

Moderate overexpression of AIB1 triggers pre-neoplastic changes in mammary epithelium

Here we report a new model of pre‐clinical breast cancer which has been generated by overexpressing the steroid receptor coactivator AIB1 at moderate levels in breast epithelium. Transgenic female mice display mammary hyperplasia at the onset of puberty, consistent with enhanced proliferation of primary mammary epithelial cultures and augmented levels of cyclin D1 and E‐cadherin. Studies of BrdU incorporation revealed that AIB1 localizes to the nucleus during or after S phase, implicating a new role for AIB1 in cell‐cycle progression subsequent to G1. Our findings suggest that moderate overexpression of AIB1 may represent one of the pre‐neoplastic changes in breast tissue.

Detection of oxidative mutagenesis by isoniazid and other hydrazine derivatives in Escherichia coli WP2 tester strain IC203, deficient in OxyR: strong protective effects of rat liver S9

Strain IC203, deficient in the OxyR function, was sensitive to both cytotoxic and mutagenic effects of isoniazid (INH) whereas its parent, WP2 uvrA/pKM101, was resistant to these effects. Four other hydrazine compounds, hydrazine hydrate (HZH), phenylhydrazine (PHZ), hydralazine (HLZ) and nialamide (NLD), were mutagenic in WP2 uvrA/pKM101. Increases in mutagenicity were observed in IC203 for HZH and PHZ but not for HLZ and NLD. Growth inhibition zones by HZH, PHZ and NLD were larger in IC203 than in WP2 uvrA/pKM101. The enhancements in the effects of INH, HZH and PHZ in IC203 with respect to its oxyR+ parent are considered to be caused by the production of reactive oxygen species. This is consistent with its inhibition in IC203 by S9 from liver of uninduced rats, probably through the action of catalase. Mutagenicities of INH, PHZ and HLZ were low in strains IC204, a derivative of WP2 uvrA carrying a deletion of the umuDC genes, and IC206, a derivative of IC204 deficient in the MutY glycosylase. In these strains, HZH and NLD induced a high level of revertants which carry suppressor mutations resulting exclusively from G:C-A:T transitions, thus suggesting a direct reaction of the two hydrazines with cytosine.

Influence of recA mutations on gyrA dependent quinolone resistance

We examined, in Escherichia coli, the influence of recA mutant alleles on the level of quinolone resistance promoted by mutations in the gyrA gene. We found that the recA142 mutation, abolishing all the activities of RecA protein, greatly reduced the level of resistance to the quinolone ciprofloxacin, whereas the recA430 allele affecting the SOS inducing ability of RecA, reduced ciprofloxacin resistance to a lesser extent. The recA142 mutation did not cause enhancement of ciprofloxacin induced DNA breakage in gyrA mutants, indicating that the stabilization of DNA-gyrase complexes by the quinolone is not influenced by a RecA mutant protein. We suggest that RecA protein plays a role in the repair of quinolone damage, principally through a recombinational mechanism and, to a lesser degree, through the induction of the SOS response.

Detection of oxidative mutagens in strains of Escherichia coli deficient in the OxyR or MutY functions: dependence on SOS mutagenesis

The Escherichia coli strain IC3821, a delta oxyR derivative of WP2 uvrA trpE65, was more sensitive to mutagenicity promoted by t-butyl hydroperoxide and cumene hydroperoxide than the isogenic oxyR+ control. Mutagenicity of menadione, a redox cycling quinone, was clearly detected in the delta oxyR strain, whereas only a slight mutagenic response was observed in the oxyR+ strain. Plumbagin, another quinone structurally similar to menadione, was not mutagenic to any of the strains. These mutagenic responses appeared to involve the SOS processing of oxidative DNA lesions and were mediated by MucA/B proteins more efficiently than by UmuD/C. In cells lacking mutagenesis proteins, induction of SOS-independent mutations by the two alkyl hydroperoxides required a deficiency in the MutY DNA glycosylase and was increased by the presence of the delta oxyR mutation. In contrast, the two quinones assayed were unable to induce SOS-independent mutations in the MutY-deficient strains.

UV light-induced mutability in Salmonella strains containing the umuDC or the mucAB operon: evidence for a umuC function

Multicopy plasmids carrying either the umuDC operon of Escherichia coli or its analog mucAB operon, were introduced into Ames Salmonella strains in order to analyze the influence of UmuDC and MucAB proteins on repair and mutability after UV irradiation. It was found that in uvr+ bacteria, plasmid pICV80:mucAB increased the frequency of UV-induced His+ revertants whereas pSE117:umuDC caused a smaller increase in UV mutagenesis. In delta uvrB bacteria, the protective role of pSE117 against UV killing was weak, and there was a great reduction in the mutant yield. In contrast, in these cells, pICV80 led to a large increase in both cell survival and mutation frequency. These results suggest that in Salmonella, as in E. coli, MucAB proteins mediate UV mutagenesis more efficiently than UmuDC proteins do. Plasmid pICV84:umuD+ C- significantly increased UV mutagenesis of TA2659: delta uvrB cells whereas in them, pICV77:mucA+ B- had no effect on mutability indicating the presence in Salmonella TA2659 of a gene functionally homologous to umuC.

Mesenchymal stromal cells enhance the engraftment of hematopoietic stem cells in an autologous mouse transplantation model.

IntroductionStudies have proposed that mesenchymal stem cells (MSCs) improve the hematopoietic engraftment in allogeneic or xenogeneic transplants and this is probably due to the MSCs’ immunosuppressive properties. Our study aimed to discern, for the first time, whether MSC infusion could facilitate the engraftment of hematopoietic stem cells (HSCs) in autologous transplantations models, where no immune rejection of donor HSCs is expected.MethodsRecipient mice (CD45.2) mice, conditioned with moderate doses of radiation (5-7 Gy), were transplanted with low numbers of HSCs (CD45.1/CD45.2) either as a sole population or co-infused with increasing numbers of adipose-derived-MSCs (Ad-MSCs). The influence of Ad-MSC infusion on the short-term and long-term engraftment of donor HSCs was investigated. Additionally, homing assays and studies related with the administration route and with the Ad-MSC/HSC interaction were conducted.ResultsOur data show that the co-infusion of Ad-MSCs with low numbers of purified HSCs significantly improves the short-term and long-term hematopoietic reconstitution of recipients conditioned with moderate irradiation doses. This effect was Ad-MSC dose-dependent and associated with an increased homing of transplanted HSCs in recipients’ bone marrow. In vivo and in vitro experiments also indicate that the Ad-MSC effects observed in this autologous transplant model are not due to paracrine effects but rather are related to Ad-MSC and HSC interactions, allowing us to propose that Ad-MSCs may act as HSC carriers, facilitating the migration and homing of the HSCs to recipient bone marrow niches.ConclusionOur results demonstrate that Ad-MSCs facilitate the engraftment of purified HSCs in an autologous mouse transplantation model, opening new perspectives in the application of Ad-MSCs in autologous transplants, including HSC gene therapy.

Processing of MucA protein is required for spontaneous and benzo[a]pyrene-induced reversion of the Escherichia coli trpA23 missense mutation by G.C-T.A. transversions: effect of a deficiency in the MutY DNA glycosylase

We have studied the influence of the processing of MucA protein on the occurrence of base substitution mutations. Escherichia coli strains carrying the trpA23 missense mutation and having a full deletion of the chromosomal umuD/C operon were transformed with plasmids encoding the MucB protein together with either wild-type MucA or the nonprocessable MucA202 protein. The efficient reversion of the trpA23 allele by G.C-T.A transversions in benzo[a]pyrene (B[a]P)-treated cells required the function of a matured MucA protein. This processed protein was also necessary for the occurrence of G.C-T.A transversions targeted at spontaneous DNA lesions and for the SOS mutator effect dependent on the constitutive coprotease activity of the RecA730 protein. In contrast, G.C-T.A transversions reverting trpA23 were spontaneously generated by an SOS-independent mechanism in cells deficient in the MutY DNA glycosylase.