The influence of cadmium on stress protein production in Escherichia coli K-12 (strain MG1655) was analysed using two-dimensional polyacrylamide gel electrophoresis and the gene-protein database of E. coli K-12. Cadmium (273 pM) caused complete but transient inhibition of growth accompanied by the synthesis of cadmium-induced proteins (CDPs). It was found that some CDPs induced during the growth-arrested phase belong to the heat-shock, oxidation stress, SO5 and stringent response regulons, while others are general stress inducible proteins (e.g. H-NS, UspA). In addition, trigger factor, adenylate kinase, W-protein, the cold shock protein G041.2, and seven unknown proteins whose synthesis is not known to be controlled by a global regulator, were identified as immediate responders to cadmium exposure. The rate of synthesis of most of the immediate responders to cadmium exposure decreased when the growth of the cells resumed. However, seven CDPs, including those encoded by argl, tyrA and xthA, maintained a high production rate during growth in the presence of cadmium. Two of the unidentified proteins were N-terminally sequenced by Edman degradation. The N-terminal amino acid sequence of one of these proteins (designated F023.3) matches the E. coli open reading frame 0216. This ORF is similar to the N-terminal third of the copper-binding protein amine oxidases (encoded by maoA) of both E. coli and Klehiella pneumoniae (K. aerogenes). The other N-terminally sequenced protein (designated C044.6) matches perfectly the product of the metK gene, S-adenosylmethionine synthetase 1. In comparison to untreated cells, cadmium-stressed cells were found to recover more rapidly during subsequent stress conditions, such as ethanol, osmotic, heat shock, and nalidixic acid treatment. The role of the CDPs is discussed in view of their physiological assignments in the cell.
This study deals with establishing the characteristics of a microbial community isolated from indoor artworks and the surrounding air environment. It is one of the few studies on microbial degradation of indoor artworks. It shows the potential biodegradative risk that can occur if artworks are not exhibited and conserved in an appropriate environment. The microbial community isolated from the indoor artworks and air environment was examined by cultural and molecular methods. Different plate assays were used to screen the biodegradative activity of the isolated microflora: Remazol Brilliant Blue R, phenol red, and Azure B for the ligninolytic properties; Ostazin brilliant red H-3B for cellulose degradation; CaCO3 glucose agar for solubilization activity; and B4 agar for biomineralization. To type the bacterial and fungal isolates, 2 PCR methods, repetitive extragenic palindromes (REP) and random amplified microsatellite polymorphisms (RAMP) were used. The art objects were principally colonized by fungi. The most commonly isolated strains were represented by hyphomycetes of the genera Penicillium, Aspergillus, Cladosporium, and Chaetomium. Members of these genera showed intensive biodegradation activity, both on wood and on stone. Bacteria were predominant in the air, exhibiting complex communities, both in the air and on the artworks. The most frequently isolated genera were Bacillus and Staphylococcus with extensive biodegradation abilities. REP-PCR revealed high variability within strains belonging to the same genus. RAMP is a new PCR-based method, used in this research for the first time to cluster the microfilamentous fungi and to characterize and select especially Penicillium and Aspergillus strains, which were isolated in a large number.
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