Mutants of Clostridium thermocellum that had lost the ability to adhere to microcrystalline cellulose were isolated. Six of them that showed diminished ability to depolymerize crystalline cellulose were selected. Size exclusion chromatography of the proteins from the culture supernatant revealed the loss of the supramolecular enzyme complex, the cellulosome. However, denaturing sodium dodecyl sulfate-polyacrylamide gel electrophoresis resulted in extracellular protein patterns comparable to those of isolated cellulosomes, except for a missing CipA band. Sequencing of the six mutant cipA genes revealed a new insertion (IS) element, IS1447, belonging to the IS3 family. It was inserted into the cipA reading frame in four different locations: cohesin module 1, two different positions in the carbohydrate binding module, and cohesin module 3. The IS sequences were identical and consisted of a transposase gene and the inverted repeats IRR and IRS. The insertion resulted in an obviously nonspecific duplication of 3 base pairs within the target sequence. This lack of specificity allows transposition without the need of a defined target DNA sequence. Eighteen copies of IS1447 were identified in the genomic sequence of C. thermocellum ATCC 27405. At least one of them can be activated for transposition. Compared to the wild type, the mutant culture supernatant, with a completely defective CipA protein, showed equal specific hydrolytic activity against soluble -glucan but a 15-fold reduction in specific activity with crystalline cellulose. These results identify a genetic basis for the synergistic effect of complex formation on crystalline-cellulose degradation.
ABSTRACTArtificial cellulase complexes active on crystalline cellulose were reconstitutedin vitrofrom a native mix of cellulosomal enzymes and CipA scaffoldin. Enzymes containing dockerin modules for binding to the corresponding cohesin modules were prepared from culture supernatants of aC. thermocellum cipAmutant. They were reassociated to cellulosomes via dockerin-cohesin interaction. Recombinantly produced mini-CipA proteins with one to three cohesins either with or without the carbohydrate-binding module (CBM) and the complete CipA protein were used as the cellulosomal backbone. The binding between cohesins and dockerins occurred spontaneously. The hydrolytic activity against soluble and crystalline cellulosic compounds showed that the composition of the complex does not seem to be dependent on which CipA-derived cohesin was used for reconstitution. Binding did not seem to have an obvious local preference (equal binding to Coh1 and Coh6). The synergism on crystalline cellulose increased with an increasing number of cohesins in the scaffoldin. Thein vitro-formed complex showed a 12-fold synergism on the crystalline substrate (compared to the uncomplexed components). The activity of reconstituted cellulosomes with full-size CipA reached 80% of that of native cellulosomes. Complexation on the surface of nanoparticles retained the activity of protein complexes and enhanced their stability. Partial supplementation of the native cellulosome components with three selected recombinant cellulases enhanced the activity on crystalline cellulose and reached that of the native cellulosome. This opens possibilities forin vitrocomplex reconstitution, which is an important step toward the creation of highly efficient engineered cellulases.
Different penicillin-binding proteins PBPs are affected in cefotaxime-resistant laboratory mutants compared to piperacillin-resistant mutants. PBP2x acts as the primary PBP target in cefotaxime-resistant mutants, whereas PBP2b is the primary target in piperacillin-resistant mutants. Depending on the mutations in PBP2x, it functions as a resistance determinant for cefotaxime only, or for penicillins as well. Mutations in PBP2x of laboratory mutants are found exclusively in the penicillin-binding domain that contains three homology boxes common to all penicillin-interacting enzymes. Most mutations relevant for resistance occur close to the SXN or the KT/SG box, or at the C-terminal end of the penicillin-binding domain, similar to mutations described in PBP2b of laboratory mutants. Amino acid alterations occur at similar sites also in PBP2x of beta-lactam-resistant clinical isolates and most of these proteins also contain changes in the SXXK box with the active site serine, suggesting that these alterations may be critical for resistance development in clinical isolates.
Laboratory mutants of Streptococcus pneumoniae resistant to either cefotaxime or piperacillin reveal defects in competence development independent of the selective beta-lactam. A resistance determinant ciaH encoding a putative histidine kinase of a two-component signal-transducing system that is also involved in competence regulation was recently identified in cefotaxime-resistant mutants. We show now that the CiaH protein can be phosphorylated by ATP in vitro, and that it also phosphorylates the cognate response regulator CiaR. The mutant C306 containing the CiaH mutation Thr-230-Pro is completely noncompetent. It does not release competence-inducing activity (competence factor) into the medium nor can such an activity be released from the cells. Competence in C306 cannot be induced upon addition of external competence factor, in contrast to the competence-defective piperacillin-resistant mutants P506 and P408. A novel resistance determinant cpoA specific for piperacillin was identified in piperacillin-resistant mutants. CpoA is responsible for the competence defect in P506 but not in P408. The results document a tight link between the action of beta-lactams and competence development in the pneumococcus and confirm that the two beta-lactams piperacillin and cefotaxime act via different primary targets.
Cefotaxime resistance in laboratory mutant C604 of Streptococcus pneumoniae, for which the MIC is 1.5 microg/ml, is independent of alterations in high-molecular-mass penicillin-binding protein (PBP) 1a. Instead, a point mutation in PBP 3, the D,D-carboxypeptidase of this organism, caused a reduced affinity for penicillin and contributed to the decreased susceptibility. The mutation Thr-242 to Ile was located directly adjacent to the triad Lys-239-Thr-Gly, a position known to be important for beta-lactam interaction with high-molecular-mass PBPs and beta-lactamases. This mutation was absent in the PBP 3's of four genetically distinct clinical isolates resistant to high levels of penicillin. None of the pbp3 genes had a mosaic structure, but in three cases there was evidence for a site-specific recombination event within a BOX element immediately downstream of pbp3.
<b><i>Introduction:</i></b> Epidermolysis bullosa (EB) describes a family of rare genetic blistering skin disorders. Various subtypes are clinically and genetically heterogeneous, and a lethal postpartum form of EB is the generalized severe junctional EB (gs-JEB). gs-JEB is mainly caused by premature termination codon (PTC) mutations in the skin anchor protein LAMB3 (laminin subunit beta-3) gene. The ribosome in majority of translational reads of LAMB3PTC mRNA aborts protein synthesis at the PTC signal, with production of a truncated, nonfunctional protein. This leaves an endogenous readthrough mechanism needed for production of functional full-length Lamb3 protein albeit at insufficient levels. Here, we report on the development of drugs targeting ribosomal protein L35 (rpL35), a ribosomal modifier for customized increase in production of full-length Lamb3 protein from a LAMB3PTC mRNA. <b><i>Methods:</i></b> Molecular docking studies were employed to identify small molecules binding to human rpL35. Molecular determinants of small molecule binding to rpL35 were further characterized by titration of the protein with these ligands as monitored by nuclear magnetic resonance (NMR) spectroscopy in solution. Changes in NMR chemical shifts were used to map the docking sites for small molecules onto the 3D structure of the rpL35. <b><i>Results:</i></b> Molecular docking studies identified 2 FDA-approved drugs, atazanavir and artesunate, as candidate small-molecule binders of rpL35. Molecular interaction studies predicted several binding clusters for both compounds scattered throughout the rpL35 structure. NMR titration studies identified the amino acids participating in the ligand interaction. Combining docking predictions for atazanavir and artesunate with rpL35 and NMR analysis of rpL35 ligand interaction, one binding cluster located near the N-terminus of rpL35 was identified. In this region, the nonidentical binding sites for atazanavir and artesunate overlap and are accessible when rpL35 is integrated in its natural ribosomal environment. <b><i>Conclusion:</i></b> Atazanavir and artesunate were identified as candidate compounds binding to ribosomal protein rpL35 and may now be tested for their potential to trigger a rpL35 ribosomal switch to increase production of full-length Lamb3 protein from a LAMB3PTC mRNA for targeted systemic therapy in treating gs-JEB.
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