The thrA gene of Escherichia coli codes for a single polypeptide chain having two enzymatic activities required for the biosynthesis of threonine, aspartokinase I and homoserine dehydrogenase I. This gene was cloned in a bacterial plasmid and its complete nucleotide sequence was established. It contains 2460 base pairs that encode for a polypeptide chain of 820 amino acids. The previously determined partial amino acid sequence of this protein is in good agreement with that predicted from the nucleotide sequence. The gene contains an internal sequence that resembles the structure of bacterial ribosome-binding sites, with an AUG preceded by four triplets, each of which can be converted to a nonsense coon by a single mutation. This suggests that the single polypeptide chain was formed by the fusion of two genes and that initiation of translation may occur inside the gene to give a protein fragment having only the homoserine dehydrogenase activity.The thrA gene is the first structural gene of the threonine operon of Escherichia coil K-12 (1, 2). It is composed of two parts, thrAl and thrA2 and codes for a bifunctional enzyme, aspartokinase I-homoserine dehydrbgenase I (EC 2.7.2.4 and EC 1.1.1.3). The native enzyme (3) is a tetramer with each chain carrying, on discrete domains, the aspartokinase I and homoserine dehydrogenase I activities, which are regulated allosterically by L-threonine. Limited proteolysis of the native enzyme leads to a homodimeric fragment having the same COOHterminal sequence as the native enzyme having only the dehydrogenase activity and no longer inhibited by threonine (3). On the other hand, a polypeptide chain synthesized by an ochre mutant that has the same NH2 terminus as the native enzyme assembles as a tetramer having only the aspartokinase activity, still regulated by threonine (3). The determination of the primary structure of aspartokinase I homoserine-dehydrogenase I seemed warranted for a number of reasons. Sequence information was important to understand enzyme structure-function relationships and to elucidate the allosteric properties of the enzyme. It should permit the study of possible evolutionary relationships between the different proteins coded by the threonine operon and the homology with the isofunctional enzymes in E. coli, aspartokinase II-homoserine dehydrogenase II, coded by metL, and aspartokinase III coded by lysC.
Protease I, a periplasmic endopeptidase from Escherichia coli has been further purified by a modified procedure. While the purified protein consists of a single polypeptide chain of about 21 000 daltons, its molecular weight in dilute salt solution was estimated to be near 43000, suggesting that the enzyme has a marked tendency to dimerize. It has only one disulphide bond and is very sensitive to urea.In agreement with previous evidence of a chymotrypsin-like specificity, hydrolytic assays of various p-nitrophenyl esters of N-substituted amino acids showed that phenylalanine and tyrosine derivatives are the best substrates for the enzyme. The K, (app) for N-benzoyloxycarbonyl-L-tyrosinep-nitrophenyl ester at pH 7.5 in 100 mM sodium phosphate buffer at 25 "C was found to be 0.2 mM. In contrast to chymotrypsin, protease I is unable to hydrolyse N-acetyl-L-phenylalanine ethyl ester and its tyrosine analogue. Moreover, the enzyme appears devoid of amidase activity and exhibits a low activity upon polypeptides. At 37 "C, it cleaves the carboxymethylated B-chain of bovine insulin at four points : Phe25-Tyr26, Phe24-Phe25, Leu"-Tyrt6 and Ser9-His". From a detailed study of peptides bonds hydrolyzed, it was concluded that protease I has a stringent requirement for both residues forming the scissile bond, and appears to possess an extended hydrophobic binding site.
We have previously reported the physicochemical and kinetic properties of glycogen phosphorylase modified by arginine-specific reagent under different conditions [Dreyfus, M., Vandenbunder, B., & Buc, H. (1980) Biochemistry 19, 3634-3642]. The properties of the modified enzyme depend upon the conformation adopted by the enzyme during the modification reaction. In this paper, we report the localization of the crucial modified arginine residues on the primary structure. The chymotryptic peptide extending from residue Asp-563 to residue Tyr-572 was shown to contain one arginine residue (Arg-568) which is chemically modified by phenylglyoxal in phosphorylase a and in activated phosphorlase b. Inclusion of glucose 1-phosphate in the modification medium protects this residue from modification, with a concomitant protection of the enzyme activity. Furthermore, this residue is not reactive toward phenylglyoxal in phosphorylase b in the absence of any effector. Addition of the AMP analogue 2'dAMP, which is not an activator of the enzyme, does not increase Arg-568 reactivity but protects from modification several arginine residues located between Arg-242 and Leu-348. The location and the role of Arg-568 in phosphorylase are discussed with reference to recent data from X-ray crystallography.
The molecular karyotypes of P. chabaudi and P. falciparum have been compared by pulse field gradient electrophoresis. P. chabaudi has 3 extra chromosomes in the 750-2000 Kb range although the overall number appears to be 14 as is the case for P. falciparum. The chromosomal location of the rRNA genes has been determined for P. chabaudi together with that of a 24 Kd antigen gene. The corresponding cDNA 443 may code for a protein unusually rich in tyrosine and contains sequences highly repetitive in P. falciparum.
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