The plasmid pO61 that was isolated from an E. coli genomic DNA library and codes for O6-alkylguanine (O6AG) DNA alkyltransferase (ATase) activity (1) has been further characterised. Subclones of the 9 Kb insert of pO61 showed that the ATase activity was encoded in a 2Kb Pst1 fragment but a partial restriction endonuclease map of this was different to that of the E. coli ada gene that codes for O6-AG and alkylphosphotriester dual ATase protein. Fluorographic analyses confirmed that the molecular weight of the pO61-encoded ATase was 19KDa i.e. similar to that of the O6AG ATase function that is cleaved from the 39KDa ada protein but rabbit polyclonal antibodies to the latter reacted only very weakly with the pO61-encoded protein. A different set of hybridisation signals was produced when E. coli DNA, which had been digested with a variety of restriction endonucleases was probed with 2Kb Pst 1 fragment or the ada gene. These results provided evidence for the existence of a second ATase gene in E. coli. The 2Kb Pst-1 fragment of pO61 was therefore sequenced and an open reading frame (ORF) that would give rise to a 19KDa protein was identified. The derived amino acid sequence of this showed a 93 residue region with 49% homology with the O6AG ATase region of the ada protein and had a pentamer and a heptamer of identical sequence separated by 34 amino acids in both proteins. The pentamer included the alkyl accepting cysteine residue of the ada O6AG ATase. The hydrophobic domains were similarly distributed in both proteins. Shine-Dalgarno, -10 and -35 sequences were identified and the origin of transcription was located by primer extension and S1 nuclease mapping. The amino-terminal amino acid sequence of the protein was as predicted from the ORF.
The 500‐MHz and 600‐MHz 1H‐NMR spectra of recombinant human transforming growth factor α have been recorded at pH values of 3.8, 6.5 and 9.4. Analysis of various two‐dimensional spectra has enabled sequence‐specific assignments to be made and the secondary structure to be identified. Information on the tertiary fold has also been obtained from observed nuclear Overhauser effects and titration of histidine residues. The overall fold of the protein is very similar to that of epidermal growth factor, as might be expected from the sequence similarity. However, the structure of transforming growth factor α at pH 3.8 is found to show interesting differences from those at the two higher pHs and from that of epidermal growth factor.
Variants of chloramphenicol acetyltransferase from a variety of bacterial species have been isolated and purified to homogeneity. They constitute a heterogeneous group of proteins as judged by analytical affinity and hydrophobic (‘detergent’) chromatography, native and sodium dodecyl sulfate electrophoresis, sensitivity to sulfhydryl specific reagents, steady state kinetic analysis, and reaction with antisera.
The most striking observation is that three variants of chloramphenicol acetyltransferase (R factor type III, Streptomyces acrimycini, and Agrobacterium tumefaciens) possess an apparent subunit molecular weight (24500) which is significantly greater than that of all other variants examined (22500). The three atypical variants are not identical since they show marked differences in a number of important parameters.
Although the fundamental mechanism of catalysis may prove to be identical for all chloramphenicol acetyltransferase variants, there is a wide range of sensitivity to thiol‐directed inhibitors among the enzymes studied.
Amino acid sequence analysis of the N‐termini of selected variants suggests that the qualitative differences among chloramphenicol acetyltransferase variants is a reflection of structural heterogeneity which is most marked in comparisons between variants from Gram‐positive and Gram‐negative species.
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