New Type of Outer Membrane Vesicle Produced by the Gram-Negative Bacterium Shewanella vesiculosa M7 T : Implications for DNA Content
bOuter membrane vesicles (OMVs) from Gram-negative bacteria are known to be involved in lateral DNA transfer, but the presence of DNA in these vesicles has remained difficult to explain. An ultrastructural study of the Antarctic psychrotolerant bacterium Shewanella vesiculosa M7 T has revealed that this Gram-negative bacterium naturally releases conventional one-bilayer OMVs through a process in which the outer membrane is exfoliated and only the periplasm is entrapped, together with a more complex type of OMV, previously undescribed, which on formation drag along inner membrane and cytoplasmic content and can therefore also entrap DNA. These vesicles, with a double-bilayer structure and containing electron-dense material, were visualized by transmission electron microscopy (TEM) after high-pressure freezing and freeze-substitution (HPF-FS), and their DNA content was fluorometrically quantified as 1.8 ؎ 0.24 ng DNA/g OMV protein.The new double-bilayer OMVs were estimated by cryo-TEM to represent 0.1% of total vesicles. The presence of DNA inside the vesicles was confirmed by gold DNA immunolabeling with a specific monoclonal IgM against double-stranded DNA. In addition, a proteomic study of purified membrane vesicles confirmed the presence of plasma membrane and cytoplasmic proteins in OMVs from this strain. Our data demonstrate the existence of a previously unobserved type of double-bilayer OMV in the Gram-negative bacterium Shewanella vesiculosa M7T that can incorporate DNA, for which we propose the name outer-inner membrane vesicle (O-IMV).
We have shown previously that a variant allele of the short-chain acyl-CoA dehydrogenase ( SCAD ) gene, 625G-->A, is present in homozygous form in 7% of control individuals and in 60% of 135 patients with elevated urinary excretion of ethylmalonic acid (EMA). We have now characterized three disease-causing mutations (confirmed by lack of enzyme activity after expression in COS-7 cells) and a new susceptibility variant in the SCAD gene of two patients with SCAD deficiency, and investigated their frequency in patients with elevated EMA excretion. The first SCAD-deficient patient was a compound heterozygote for two mutations, 274G-->T and 529T-->C. These mutations were not present in 98 normal control alleles, but the 529T-->C mutation was found in one allele among 133 patients with elevated EMA excretion. The second patient carried a 1147C-->T mutation and the 625G-->A polymorphism in one allele, and a single point mutation, 511C-->T, in the other. The 1147C-->T mutation was not present in 98 normal alleles, but was detected in three alleles of 133 patients with elevated EMA excretion, consistently as a 625A-1147T allele. On the other hand, the 511C-->T mutation was present in 13 of 130 and 15 of 67 625G alleles, respectively, of normal controls and patients with elevated EMA excretion, and was never associated with the 625A variant allele. This over-representation of the haplotype 511T-625G among the common 625G alleles in patients compared with controls was significant ( P < 0.02), suggesting that the allele 511T-625G-like 511C-625A-confers susceptibility to ethylmalonic aciduria. Expression of the variant R147W SCAD protein, encoded by the 511T-625G allele, in COS-7 cells showed 45% activity at 37 degrees C in comparison with the wild-type protein, comparable levels of activity at 26 degrees C, and 13% activity when incubated at 41 degrees C. This temperature profile is different from that observed for the variant G185S SCAD protein, encoded by the 511C-625A allele, where higher than normal activity was found at 26 and 37 degrees C, and 58% activity was present at 41 degrees C. These results corroborate the notion that the 511C-625A variant allele is one of the possible underlying causes of ethylmalonic aciduria, and suggest that the 511C-->T mutation represents a second susceptibility variation in the SCAD gene. We conclude that ethylmalonic aciduria, a commonly detected biochemical phenotype, is a complex multifactorial/polygenic condition where, in addition to the emerging role of SCAD susceptibility alleles, other genetic and environmental factors are involved.
Recent studies implicate Wnt/beta-catenin signaling in lens differentiation (Stump, R. J., et al., 2003. A role for Wnt/beta-catenin signaling in lens epithelial differentiation. Dev Biol;259:48-61). Beta-catenin is a component of adherens junctions and functions as a transcriptional activator in canonical Wnt signaling. We investigated the effects of Cre/LoxP-mediated deletion of beta-catenin during lens development using two Cre lines that specifically deleted beta-catenin in whole lens or only in differentiated fibers, from E13.5. We found that beta-catenin was required in lens epithelium and during early fiber differentiation but appeared to be redundant in differentiated fiber cells. Complete loss of beta-catenin resulted in an abnormal and deficient epithelial layer with loss of E-cadherin and Pax6 expression as well as abnormal expression of c-Maf and p57(kip2) but not Prox1. There was also disrupted fiber cell differentiation, characterized by poor cell elongation, decreased beta-crystallin expression, epithelial cell cycle arrest at G(1)-S transition and premature cell cycle exit. Despite cell cycle arrest there was no induction of apoptosis. Mutant fiber cells displayed altered apical-basal polarity as evidenced by altered distribution of the tight junction protein, ZO1, disruption of apical actin filaments and abnormal deposition of extracellular matrix, resulting in a deficient lens capsule. Loss of beta-catenin also affected the formation of adhesion junctions as evidenced by dissociation of N-cadherin and F-actin localization in differentiating fiber cells. However, loss of beta-catenin from terminally differentiating fibers had no apparent effects on adhesion junctions between adjacent embryonic fibers. These data indicate that beta-catenin plays distinct functions during lens fiber differentiation and is involved in both Wnt signaling and adhesion-related mechanisms that regulate lens epithelium and early fiber differentiation.
Abstract. Although many of the molecular interactions in kidney development are now well understood, the molecules involved in the specification of the metanephric mesenchyme from surrounding intermediate mesoderm and, hence, the formation of the renal progenitor population are poorly characterized. In this study, cDNA microarrays were used to identify genes enriched in the murine embryonic day 10.5 (E10.5) uninduced metanephric mesenchyme, the renal progenitor population, in comparison with more rostral derivatives of the intermediate mesoderm. Microarray data were analyzed using R statistical software to determine accurately genes differentially expressed between these populations. Microarray outliers were biologically verified, and the spatial expression pattern of these genes at E10.5 and subsequent stages of early kidney development was determined by RNA in situ hybridization. This approach identified 21 genes preferentially expressed by the E10.5 metanephric mesenchyme, including Ewing sarcoma homolog, 14-3-3 , retinoic acid receptor-␣, stearoyl-CoA desaturase 2, CD24, and cadherin-11, that may be important in formation of renal progenitor cells. Cell surface proteins such as CD24 and cadherin-11 that were strongly and specifically expressed in the uninduced metanephric mesenchyme and mark the renal progenitor population may prove useful in the purification of renal progenitor cells by FACS. These findings may assist in the isolation and characterization of potential renal stem cells for use in cellular therapies for kidney disease.There is increasing evidence from a number of organ systems that cells with at least multipotentiality (1,2) and possibly pluripotentiality (3) exist in adult organs that previously were thought not to contain such populations. Although cell division is infrequent in the adult kidney, this organ possesses the capacity for regeneration as evidenced by the cellular proliferation observed during recovery from conditions such as acute tubular necrosis (4). Although cell lineage relationships during renal repair and regeneration are poorly defined, it is possible that these processes recapitulate some aspects of embryonic renal development. The permanent kidney (metanephros) arises via reciprocal interactions between two tissues, the ureteric bud (UB) and the metanephric mesenchyme (MM) (5). Each of these tissues is initially derived from the intermediate mesoderm (IM), although the UB develops as a caudal outgrowth from the nephric duct (ND), whereas the MM develops from the nephrogenic cord, the same block of tissue that gives rise to the pronephroi and the mesonephroi (5). After invasion by the UB, cells of the MM are induced to differentiate into specific renal lineages. The central dogma of kidney development suggests that the UB forms the ureter and collecting duct system of the mature kidney, whereas the MM gives rise to the remaining portions of the nephrons, from Bowman's capsule to distal tubule (6). Although many of the interactions between the UB and MM are now well chara...
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