Complete structure of the human transferrin gene. Comparison with analogous chicken gene and human pseudogene

The complete structure of the human transferrin gene is presented. This gene has a total size of about 33.5 kb and is organized in 17 exons separated by 16 introns. The chicken ovotransferrin gene has a size of 10.5 kb and is also organized in 17 exons and 16 introns. The analysis of the structure of the two genes confirm, at the gene level, that transferrins originated by a gene duplication phenomenon. Finally, the existence of a new member of the transferrin family, a human transferrin non-processed pseudogene is demonstrated.

Interactions of the Escherichia coli methionine repressor with the metF operator and with its corepressor, S-adenosylmethionine

The metJ gene encoding the methionine aporepressor was placed under the control of a strong and inducible promoter, ptac. Bacterial strains carrying the recombinant plasmid pIP35 overproduced the regulatory protein by a factor of 200 over the wild type strain as determined by the immunoblot technique. The purified metJ gene product negatively controls the expression of the metF gene, in a cell-free system as shown by repression of beta-galactosidase synthesis under the control of the metF promoter. The metJ protein binds to a DNA fragment containing the potential operator of the metF gene with an affinity which is 10 times greater in the presence of S-adenosylmethionine than in its absence. Equilibrium dialysis experiments showed that the met aporepressor binds 2 mol of S-adenosylmethionine per mol of dimer with a dissociation constant of 200 microM.

Evolution in biosynthetic pathways: two enzymes catalyzing consecutive steps in methionine biosynthesis originate from a common ancestor and possess a similar regulatory region

The metC gene of Escherichia coli K-12 was cloned and the nucleotide sequence of the metC gene and its flanking regions was determined. The translation initiation codon was identified by sequencing the NH2-terminal part of beta-cystathionase, the MetC gene product. The metC gene (1185 nucleotides) encodes a protein having 395 amino acid residues. The 5' noncoding region was found to contain a "Met box" homologous to sequences suggestive of operator structures upstream from other methionine genes that are controlled by the product of the pleiotropic regulatory metJ gene. The deduced amino acid sequence of beta-cystathionase showed extensive homology with that of the MetB protein (cystathionine gamma-synthase) that catalyzes the preceding step in methionine biosynthesis. The homology strongly suggests that the structural genes for the MetB and MetC proteins evolved from a common ancestral gene.

Nucleotide sequence of lysC gene encoding the lysine-sensitive aspartokinase III of Escherichia coli K12. Evolutionary pathway leading to three isofunctional enzymes

The lysC gene encoding the lysine-sensitive aspartokinase III of Escherichia coli K12 has been cloned and its nucleotide sequence determined. Analysis of the deduced protein sequence (449 amino acid residues) reveals that the entire sequence of aspartokinase III is homologous to the N-terminal part of the two iso- and bifunctional aspartokinase-homoserine dehydrogenases I and II of E. coli. An evolutionary pathway leading to the three molecular species present in the same organism is proposed, and the possible involvement of a highly conserved region in subunit interactions is discussed.

Reversible dissociation of aspartokinase I/homoserine dehydrogenase I from Escherichia coli K 12. The active species is the tetramer

Dimers of aspartokinase I/homoserine dehydrogenase I from Escherichia coli K 12 have been isolated under very mild conditions. The dimers which cannot be distinguished from the tetramers by their kinetic properties, reassociate in the presence of potassium ions or L-aspartate. The selective sensitivity of aspartokinase I/homoserine dehydrogenase I to mild proteolytic digestion of dimers has been used to probe the reassociation reaction under the conditions of aspartokinase assay. We demonstrate that rapid reassociation occurs and that the protein species present in the assay when dimers are used to test the activity is tetrameric. These results confirm the previously proposed model for the subunit association of aspartokinase I/homoserine dehydrogenase I.

Organization of the human transferrin gene: direct evidence that it originated by gene duplication

We present the characterization of two overlapping human transferrin genomic clones isolated from a liver DNA library. The two clones represent a total length of 24 kilobase pairs and code for 70% of the protein. The organization of this gene region was elucidated by restriction mapping and DNA sequencing. It contains 12 exons, ranging from 33 to 181 base pairs, separated by introns of 0.7-4.9 kilobase pairs. This gene can be divided into two unequal parts corresponding to the known domains of the protein. Each part is essentially composed of an equal number of exons; introns interrupt the coding sequences, creating homologous exons of similar size in each moiety. Moreover, the pattern of intron interruption of the codon sequence is identical for all the analyzed homologous exon pairs. Comparison with the organization of the ovotransferrin gene shows an identical exon size distribution. These data confirm, at the gene level, the hypothesis that transferrins originated by a gene-duplication event. A model accounting for the origin of the human transferrin gene is presented.

Structure and autoregulation of the metJ regulatory gene in Escherichia coli

The nucleotide sequence of the Escherichia coli metJ regulatory gene (312 nucleotides) has been determined as well as that of two mutations located within the gene. Analysis of the sequence downstream from the metJ gene has revealed inverted repeats homologous to several intercistronic regions, also reported to occur between operons. A hybrid protein that contains the 55 first amino acid residues of the metJ protein substituting for the 8 amino acid residues at the NH2 terminus of beta-galactosidase was produced by gene fusion. The hybrid protein retaining beta-galactosidase activity was purified. Its amino-terminal sequence was determined and this allowed us to locate the translational start codon of the metJ gene. Evidence was provided for autoregulation by repression of the metJ gene. By sequencing upstream from metJ, the region situated between the metJ and metB genes was found to contain putative operator structures that we propose to call "Met boxes."

E. coli aspartokinase II-homoserine dehydrogenase II polypeptide chain has a triglobular structure

E.coli aspartokinase II-homoserine dehydrogenase II is, as aspartokinase I-homoserine dehydrogenase I, composed of three globular domains: the N-terminal domain is endowed with kinase activity; the C-terminal domain carries the dehydrogenase activity. These two parts of the polypeptide chain are separated by a central inactive domain. Thus, the polypeptide chains of the two multifunctional proteins are homologous not only in their sequence but also in their triglobular domain structure.

Internal homologies in the two aspartokinase-homoserine dehydrogenases of Escherichia coli K-12

In Escherichia coli, AK I- HDH I and AK II- HDH II are two bifunctional proteins, derived from a common ancestor, that catalyze the first and third reactions of the common pathway leading to threonine and methionine. An extensive amino acid sequence comparison of both molecules reveals two main features on each of them: (i) two segments, each of about 130 amino acids, covering the first one-third of the polypeptide chain, are similar to each other and (ii) two segments, each of about 250 amino acids and covering the COOH-terminal 500 amino acids also present a significant homology. These findings suggest that these two regions may have evolved independently of each other by a process of gene duplication and fusion previous to the appearance of an ancestral aspartokinase-homoserine dehydrogenase molecule.

Structure of the metJBLF cluster in Escherichia coli K12. Sequence of the metB structural gene and of the 5'- and 3'-flanking regions of the metBL operon

The total nucleotide sequence (1,158 nucleotides) of the metB gene of Escherichia coli coding for cystathionine gamma-synthase (386 amino acid residues, Mr = 41,503/chain) is presented. The nucleotide sequences of the flanking regions of the metB and metL genes are also presented. Analysis of these sequences and identification of a promoter region upstream from the metB gene confirms that metB and metL form an operon. The transcription direction is from metB to metL; the start site of the gene transcription has been determined. There is no structural evidence of a classical attenuation mechanism in the regulation of this operon coding for enzymes implicated in an amino acid biosynthetic pathway. Finally, the overall organization of the metJBLF gene cluster is discussed.

A hybrid proteolytic fragment of Escherichia coli aspartokinase I-homoserine dehydrogenase I. Structure, inhibition pattern, dissociation properties, and generation of two homodimers

A hybrid dimeric fragment of Escherichia coli aspartokinase I-homoserine dehydrogenase I (Fazel, A., Müller, K., Le Bras, G., Garel, J.-R., Véron, M., and Cohen, G. N. (1983) Biochemistry 22, 158-165) has been purified and shown to possess both aspartokinase and homoserine dehydrogenase activities and is rather stable in the presence of L-threonine. Its two activities are still inhibited by threonine, but noncooperatively in contrast to the native protein. The aspartokinase activity is found to be more sensitive to threonine than the dehydrogenase activity. In the absence of threonine, the different chains of the hybrid (Mr = 89,000 + 59,000) dissociate first into monomers, this being followed by the pairing of two homologous chains to form two homodimers. In the presence of L-threonine, the two homodimers do not dissociate to re-form the hybrid fragment. The NH2-terminal analysis of different chains of the hybrid shows that the homodimers correspond, respectively, to the dimer of the native protein (Mr = 2 X 89,000) and to a dimer already described (Véron, M., Falcoz-Kelly, F., and Cohen, G. N. (1972) Eur. J. Biochem. 28, 520-527).

Nucleotide sequence of thrC and of the transcription termination region of the threonine operon in Escherichia coli K12

The entire threonine operon (thrABC) of Escherichia coli K12 was cloned, and the nucleotide sequence of the thrC gene and its 3' flanking region was determined. The translation initiation codon was identified by sequencing the N-terminal part of threonine synthase, the thrC gene product. Analysis of the deduced protein sequence (428 amino acid residues) revealed a region of homology, 35 amino acids long, between the three enzymes encoded by the threonine operon. During examination of the nucleotide sequence of the 1045 base pair fragments following the thrC gene, we detected some potential rho-independent and rho-dependent transcription termination signals.

Nucleotide sequence of metF, the E. coli structural gene for 5-10 methylene tetrahydrofolate reductase and of its control region

The nucleotide sequence of the E.coli metF gene (888 nucleotides), coding for 5-10 methylene tetrahydrofolate reductase, has been determined. The metF gene product was identified in maxicells and found to be a protein of subunit molecular weight 33,000, in agreement with the size of the coding region. The starting point for metF transcription was determined by S1 nuclease mapping. No structural evidence was found for an attenuation mechanism regulating the independent metF transcriptional unit. Comparison of the regulatory region preceding the metF structural gene with the 5' flanking region of the metBL operon shows some homology spanning 24 nucleotides. These homologous sequences could be operator structures belonging to the two transcriptional units, metF and metBL, and recognized by the same regulatory protein.

A triglobular model for the polypeptide chain of aspartokinase I-homoserine dehydrogenase I of Escherichia coli

Limited proteolysis of aspartokinase I-homoserine dehydrogenase I from Escherichia coli by type VI protease from Streptomyces griseus yields five proteolytic fragments, three of which are dimeric, the other two being monomeric. One of the monomeric fragments (27 kilodaltons) exhibits residual aspartokinase activity, while the second one (33 kilodaltons) possesses residual homoserine dehydrogenase activity. The smallest of the dimeric species (2 X 25 kilodaltons) is inactive; the two other dimers exhibit either only homoserine dehydrogenase activity (2 X 59 kilodaltons) or both activities (hybrid fragment, 89 + 59 kilodaltons). This characterization of the proteolytic species in terms of molecular weight, subunit structure, and activity leads to the proposal of a triglobular model for the native enzyme. In addition, the time course of the formation of the various fragments was followed by measuring enzymatic activity and performing gel electrophoretic analysis of the protein mixture at defined time intervals during proteolysis. On the basis of the results of these studies, a reaction scheme describing the succession of events during proteolysis is given.

Construction and physical mapping of plasmids containing the metJBLF gene cluster of E. coli K12

In vitro recombination techniques were used to clone the E. coli metJBLF gene cluster in a plasmid vector. Several chimeric plasmids were obtained, analyzed by restriction mapping and characterized genetically. The combined results establish that the met gene cluster is contained on an approximately 5.6 kilobase segment of bacterial DNA with metL between metB and metF. The origin of metL was localized precisely by its DNA sequence and its transcription direction was established.