25 research outputs found
L'interaction des inhibiteurs de la peptidyltransférase avec l'ARNr 23S : le rôle des bases du domaine V
Doctorat en sciences biologiques -- UCL, 199
Chemical probing of a virginiamycin M-promoted conformational change of the peptidyl-transferase domain
Previous findings suggest the location of the central loop of domain V of 23S rRNA within the peptidyltransferase domain of ribosomes. This enzymatic activity is inhibited by some antibiotics, including type A (virginiamycin M or VM) and type B (virginiamycin S or VS) synergimycins, antibiotics endowed with a synergistic action in vivo. In the present work, the ability of VM and VS to modify the accessibility of 23S rRNA bases within ribosomes to chemical reagents has been explored. VM afforded a protection of rRNA bases A2037, A2042, G2049 and C2050. Moreover, when ribosomes were incubated with the two virginiamycin components, the base A2062, which was protected by VS alone, became accessible to dimethyl sulphate (DMS). Modified reactivity to chemical reagents of different rRNA bases located either in the central loop of domain V or in its proximity furnishes experimental evidence for conformational ribosome alterations induced by VM binding
The Role of Ribosomal-rna Bases in the Interaction of Peptidyltransferase Inhibitors With Bacterial-ribosomes
Synergism of streptogramins A (virginiamycin M, VM) and B (virginiamycin S, VS), peptidyltransferase inhibitors, was explored in EM4/pLC7-21 (wild type) and EM4/pERY (VS-resistant). These bacterial strains contained multicopy plasmids carrying an rrnH operon with wild type (pLC7-21) or mutated (A2058 --> U transversion) 23 S rRNA gene. Ribosomes with wild type and mutated rRNA were both present in EM4/pERY. The latter particles did not bind VS; in the presence of VM, however, high affinity VS binding occurred. As shown previously, VS protected against chemical reagents certain bases in domain V rRNA and VM in the stems flanking this loop. Differences between wild type and mutant ribosomes were observed: A2058, A2059, A2062, and G2505, protected by VS and ERY in EM4/pLC7-21, were unshielded in EM4/pERY. A2062 was shielded by VM in EM4/pERY, not in EM4/pLC7-21, and G2505 of mutant ribosomes became protected by VS when VM was simultaneously present. Induction by VM of a high affinity VS binding site in VS-sensitive and -resistant ribosomes indicates A2058 mutation to entail a conformational change of this site, which is counteracted by VM fixation. Accessibility of A2062 to chemical reagents (unlike behavior of EM4/pERY and EM4/pLC7-21 in the presence of VM) implies different conformations for wild type and mutant ribosomes
Identification of a single base change in ribosomal RNA leading to erythromycin resistance.
The molecular basis of a mutation conferring an erythromycin-resistance phenotype was explored, as an approach to the role of 23 S rRNA in the peptidyl-transferase activity of 50 S ribosomal subunits. Mutagenization of an Escherichia coli strain, which carried the multicopy plasmid pLC7-21 containing the rrnH operon, led to the production of an erythromycin-resistant strain. Plasmid pBFL1 isolated from this mutant was able to transform the sensitive RecA- strain EM4 and to induce a "dissociated" type of antibiotic resistance. Two ribosome populations occurred in EM4/pBFL1: normal particles coded for by the seven rrn chromosomal genes and mutated particles containing rRNA of plasmid origin. The latter particles displayed in vitro lower affinity and susceptibility to erythromycin than wild type particles. The mutation within plasmid pBFL1 was mapped by a multiple primer extension technique. Three synthetic primers were used to sequence the central loop in domain V of 23 S rRNA, leading to identification of a C to U transition at position 2611. This base change was proved to be responsible for the erythromycin-resistance phenotype by the plasmid-plasmid marker rescue technique. A molecular explanation for the rrn mutations leading, respectively, to undissociated and to dissociated types of resistance to the MLSb (macrolide-lincosamide-synergimycin B) group of antibiotics is proposed. These results and some literature data support the notion that rRNA bases involved in antibiotic resistance play a conformational role in the ribosomal binding sites for the MLSb antibiotics
Pathology of the bone marrow and spleen in a case of myelodysplastic/myeloproliferative neoplasm associated with t(8;9)(p22;p24) involving PCM1 and JAK2 genes
Formation, isolation, and identification of products from the inactivation of virginiamycin M1 by Actinoplanes utahensis
Rapid and easy prenatal diagnosis of sickle cell anemia using double-dye LNA probe technology [1]
SCOPUS: le.jFLWINinfo:eu-repo/semantics/publishe
Paratuberculosis
Paratuberculosis (Johne's disease) is a chronic, wasting, widespread mycobacteriosis of ruminants. It involves extensive mycobacterial shedding, which accounts for the high contagiousness, and ends with a fatal enteritis. Decreases in weight, milk production, and fertility produce severe economic loss. The DNA of the etiological agent (Mycobacterium paratuberculosis) has a base composition (66 to 67% G+C) within the range of that of mycobacteria (62 to 70% G+C), a size (4.4 x 10(6) to 4.7 x 10(6) bp) larger than that of most pathogenic mycobacteria (2.0 x 10(6) to 4.2 x 10(6) bp), and a high relatedness (> 90%) to Mycobacterium avium DNA. However, the DNAs of the two organisms can be distinguished by restriction fragment length polymorphism analysis. M. paratuberculosis genes coding for a transposase, a cell wall-associated protein (P34), and two heat shock proteins have been cloned and sequenced. Nucleic acid probes (two of which are species specific) are used, after PCR amplification, for M. paratuberculosis identification in stools and milk. As in leprosy, with disease progression, cellular immune reactions decrease and humoral immune reactions increase. Cutaneous testing with sensitins, lymphocyte proliferation assays, and cytokine tests are used to monitor cellular immune reactions in paratuberculosis, but these tests lack specificity. Complement fixation, immunodiffusion, and enzymometric tests based on antibodies to M. paratuberculosis extracts, to mycobacterial antigen complex A36, to glycolipids, and to proteins help identify affected cattle but are not species specific. The carboxyl-terminal portion of the 34-kDa cell wall-associated A36 protein (P34) carries species-specific B-cell epitopes and is the basis for an enzyme-linked immunosorbent assay. Diagnostic tests for paratuberculosis are also used in Crohn's disease, a chronic human ileitis mimicking Johne's disease, in which isolates identified as M. paratuberculosis have been found
Occurrence, in Crohn's disease, of antibodies directed against a species-specific recombinant polypeptide of Mycobacterium paratuberculosis
Sera from patients with Crohn's disease and control were analyzed by an enzyme-linked immunosorbent assay based on the Mycobacterium paratuberculosis-specific recombinant polypeptide a362. Anti-a362 immunoglobulin G (IgG) (P < 0.05) and IgA (P < 0.001) titers were higher in patients with Crohn's disease than in controls. A monomodal Gaussian distribution of anti-a362 IgA levels were found for controls, and a bimodal distribution was found for patients with Crohn's disease. An M. paratuberculosis etiology is suggested for the 36% of patients with Crohn's disease who had an anti-a362 IgA level higher than that of controls
