DNA sequences of the D-serine deaminase control region and N-terminal portion of the structural gene

We determined the DNA sequence of the D-serine deaminase promoter region and of the N-terminal region of the structural gene. There are possibilities in the promoter for secondary structure and for initiation recognition sequences, and there is an open reading frame. The N-terminal sequence for the structural gene confirms that part of the amino acid sequence previously determined by E. Schlitz and W. Schmitt (FEBS Lett. 134:57-62, 1981), including the active site of the enzyme, and spans the two regions unresolved by their work.     

Role of small molecules in regulation of D-serine deaminase synthesis.

Cyclic AMP is required for optimal synthesis of D-serine deaminase synthesis from dsdO+ templates and for optimal hyperinducible synthesis from low constitutive dsdO templates both in vitro and in vivo. Neither D-serine, cyclic AMP, nor dsdC activator has an effect on expression of a high constitutive dsdO template. The synthesis of the dsdC activator itself in vitro is independent of cyclic AMP. Guanosine tetraphosphate does not have a significant effect on in vitro D-serine deaminase synthesis from dsdO+ or dsdO templates. A previously described class of dsdO mutants showing partial catabolite sensitivity of constitutive D-serine deaminase synthesis proved to be low dsdO types. They all contain a low constitutive dsdC mutation; the two effects are additive with regard to level of constitutivity, but only that portion of synthesis attributable to the dsdC mutation is cyclic AMP dependent.     

Escape synthesis of D-serine deaminase in lambda dsdC integration lysogens.

Heat shock of lysogens that contain lambda thermosensitive repressor mutants integrated into the dsdC gene results in escape synthesis of d-serine deaminase at a high differential rate.     

Physical mapping of the Escherichia coli D-serine deaminase region: contiguity of the dsd structural and regulatory genes.

The genes dsdA, dsdO, and dsdC have been located on a 3.0-kilobase pair (kb) fragment of the Escherichia coli chromosome by a combination of techniques. The loci were first cloned onto lambda and various plasmid vectors. dsd hybrid plasmids were then digested with restriction enzymes, and the fragments were recloned to test for the presence of dsdC or dsdA. In one case, a 4.2-kb restriction fragment containing the dsdA operon was used to form a heteroduplex with a well-defined lambda dsd deoxyribonucleic acid. The results show that dsdA, dsdO, and at least 0.6 kb of dsdC are present on this piece of deoxyribonucleic acid. On the basis of the mapping analysis and the molecular weight of D-serine deaminase, 1.9 kb of the 4.2-kb fragment is accounted for by the three dsd loci. We conclude that dsdO and dsdC are contiguous. A detailed dsd restriction map is presented.     

DNA sequence of the D-serine deaminase activator gene dsdC.

We have determined the DNA sequence of dsdC, the gene that encodes the D-serine deaminase activator protein of Escherichia coli K-12. The sequence contains a single open reading frame that terminates in a UGA codon. One the basis of the size of the protein, 33 kilodaltons, and the amino acid sequence encoded by the open reading frame, we identified a likely translation initiation codon 731 base pairs upstream of the translation initiation codon for the divergently transcribed D-serine deaminase gene. There is a broad range of codon usage, not surprising in view of the weak expression of the gene. The N-terminal two-thirds of the activator is arginine-lysine rich and quite polar; the remainder is more neutral. The segment of the protein that seems most likely to have potential to form the helix-turn-helix structure characteristic of DNA-regulatory proteins is located near the end of the polar region. The protein contains a region with significant homology to lambda attB.     

Purification and characterization of D-serine deaminase activator protein.

We purified the dsdC gene product, the specific activator of dsdA (D-serine deaminase) gene expression, to about 25% homogeneity from a strain in which its expression was amplified 100-fold. The purification involved, successively: DNase and high-salt treatment of cell extracts, DNA-cellulose chromatography, and Dyematrex (Amicon Corp.) column chromatography. We identified the protein as a discrete spot on two-dimensional O'Farrell gels after the DNA-cellulose step and quantitated it by densitometry. The active form was found to be a dimer. We estimated that there were eight activator dimers per wild-type cell. The activator is a slightly basic protein, with an experimental Km for its ligand D-serine of about 7 X 10(-6)M. The low concentration of the activator in wild-type cells and its autorepression may explain the previously observed partial dominance of dsdC+ in dsdCc/dsdC+ merodiploids.     

Thermosensitive regulation of D-serine deaminase synthesis in a mutant of Escherichia coli K 12

Summary A mutant strain of Escherichia coli K 12 is described, which exhibits thermosensitive regulation of D-serine deaminase synthesis. The mutant is distinct in its physiological properties from i ^TL and i ^TSS mutants of the lac systems, although it has elements of similarity with both. A model is presented to explain its properties.     

D-serine deaminase is a stringent selective marker in genetic crosses.

The presence of the locus for D-serine deaminase (dsd) renders bacteria resistant to growth inhibition by D-serine and enables them to grow with D-serine as the sole nitrogen source. The two properties permit stringent selection in genetic crosses and make the D-serine deaminase gene an excellent marker, especially in the construction of strains for which the use of antibiotic resistance genes as selective markers is not allowed.     

Escherichia coli K-12 mutant forming a temperature-sensitive D-serine deaminase.

A single-site mutant of Escherichia coli K-12 able to grow in minimal medium in the presence of D-serine at 30 C but not at 42 C was isolated. The mutant forms a D-serine deaminase that is much more sensitive to thermal denaturation in vitro at temperatures above but not below 47 C than that of the wild type. No detectable enzyme is formed by the mutant at 42 C, however, and very little is formed at 37 C. The mutant enzyme is probably more sensitive to intracellular inactivation at high temperatures than the wild-type enzyme. The mutation lies in the dsdA region. The mutant also contains a dsdO mutation, which does not permit hyperinduction of D-serine deaminase synthesis.     

Isolation and characterization of D-serine deaminase constitutive mutants by utilization of D-serine as sole carbon or nitrogen source.

Mutants constitutive for D-serine deaminase (Dsdase) synthesis were isolated by utilizing D-serine as sole nitrogen or carbon source in the chemostat. This method generated only regulatory constitutive (dsdC) mutants. The altered dsdC gene product in these strains is apparently able to bind D-serine more efficiently than the wild-type dsdC+ gene product--a selective advantage. Constitutive synthesis of Dsdase in all of these dsdC mutants is extremely sensitive to catabolite repression, and catabolite repression is reversed by the addition of D-serine. Of the 15 mutants generated by this method, none are suppressible by supD, supE, or supF. Mutations to a low level of constitutivity (maximal specific activity of 9) occur much more frequently than mutations to a high level (maximal specific activity of 79). High level constitutive synthesis of Dsdase results from the synthesis of an altered dsdC gene product--not from loss of ability to form the dsdC product. Dsdase synthesis is not regulated by the nitrogen supply in the medium, as nitrogen starvation does not result in the derepression of Dsdase synthesis.     

Catabolite repression in the D-serine deaminase system of Escherichia coli K-12

The induced synthesis of d-serine deaminase in Escherichia coli is subject to three catabolic effects: inhibition on inducer uptake, transient repression, and catabolite repression. Inhibition on d-serine uptake is not significant at the d-serine concentration normally used for induction. Transient repression and catabolite repression of d-serine deaminase synthesis are abolished by mutations in dsdCy, which appears to be an operator locus. The decline in the rate of constitutive synthesis observed in dsdCx mutants growing with glycerol as carbon source at temperatures above 37 C is due to catabolite repression. The low level of constitutivity at 37 C and the partial cis dominance of dsdCx mutants are not artifacts of catabolite repression. It is suggested that a product of one of the genes of the dsd operon may regulate the expression of the operon.     

Specific in vivo cleavage of D-serine deaminase and properties of tetrameric polypeptide aggregates of the fragments.

The primary D-serine deaminase (D-serine dehydratase, EC 4.2.1.14) of Escherichia coli K-12 is unstable within the cell. The protein, a single polypeptide chain, is cleaved at a lysine residue by a cellular proteolytic activity. Fragments containing the active site then aggregate into tetramers, which retain substrate affinity and show very low catalytic activity. Such degradations may represent an evolutionary mechanism for the generation of new enzymes.     

Isolation and characterization of catabolite-resistant mutants in the D-serine deaminase system of Escherichia coli K-12.

Two classes of D-serine deaminase (Dsdase)-specific secondary mutants of Escherichia coli K-12 were isolated from a Dsdase low constitutive nonhyperinducible mutant as types which could grow in the presence of both D-serine and glucose. These strains contain cis dominant, nonsuppressible mutations in the dsdO (operator-initiator) region. In the first class of mutants (e.g., FB4010), Dsdase synthesis is completely insensitive to catabolite repression, and synthesis occurs at a high constitutive rate in the absence of cyclic adenosine 5'-monophosphate. In the second class (e.g., FB4005), Dsdase synthesis is partially insensitive to catabolite repression, and catabolite repression is reversed by the addition of cyclic adenosine 5'-monophosphate. Dsdase synthesis in strain FB4005 is partially independent of the cyclic adenosine 5'-monophosphate binding protein, as constitutive synthesis is reduced only 65% (relative to the cap+ strain) in strains unable to synthesize the cyclic adenosine 5'-monophosphate binding protein. Surprisingly, the constitutive rate of Dsdase synthesis is fourfold higher in all mutants of both classes than in the parent, indicating a close interrelationship between the sites of response to induction and catabolite repression.     

Selection aid properties of hyperproducing D-serine deaminase mutants of Escherichia coli

Summary Hyperproducing constitutive D-serine deaminase mutant E. coli were selected by a chemostat method. The specific activity of the enzyme in these mutants is 25fold higher in comparison with the fully induced parental strain.     

Reconstitution of apo-porphobilinogen deaminase: structural changes induced by cofactor binding

Expression of porphobilinogen deaminase in a hemB- strain of E. coli has permitted the isolation of the apoenzyme, i.e. deaminase lacking the porphobilinogen-derived dipyrromethane cofactor. Incubation of purified apoenzyme with porphobilinogen resulted in reconstitution of the covalently attached dipyrromethane cofactor, indicating no additional cofactors or enzymes are required for biosynthesis of holoenzyme. Electrophoretic and 13C-NMR spectroscopic analyses demonstrate that the apoenzyme exists in a conformationally unstable form which is converted to a highly stable tertiary structure on covalent attachment of the dipyrromethane cofactor.     

Dominance studies with stable merodiploids in the D-serine deaminase system of Escherichia coli K-12

An episome, F32, which carries the genetic markers dsdA(+), the presumed structural gene for d-serine deaminase, dsdC(+), a regulatory locus governing the synthesis of d-serine deaminase, aroC(+), and purC(+) was obtained from strain AB311 of Escherichia coli K-12, and was used to construct appropriate merodiploids with dsdC markers. In all dsdC / dsdC(+) diploids examined, dsdC was found to be cis dominant, trans recessive, to dsdC(+). In two cases, however, the cis dominance was only partial. Moreover, complementation was observed between one of the dsdC markers which is fully cis dominant and one which is partially cis dominant. Because of the size of the dsdC region, the phenotypes of the mutants, and the partial trans dominance of dsdC(+) over some of the dsdC mutations, it is suggested that the dsdC region specifies a product, but that this product does not move with facility through the cytoplasm