Covalent structure of biodegradative threonine dehydratase of Escherichia coli: homology with other dehydratases

Sphingolipid biosynthesis in man and microbes

A new review covering up to 2018 Sphingolipids are essential molecules that, despite their long history, are still stimulating interest today. The reasons for this are that, as well as playing structural roles within cell membranes, they have also been shown to perform a myriad of cell signalling functions vital to the correct function of eukaryotic and prokaryotic organisms. Indeed, sphingolipid disregulation that alters the tightly-controlled balance of these key lipids has been closely linked to a number of diseases such as diabetes, asthma and various neuropathologies. Sphingolipid biogenesis, metabolism and regulation is mediated by a large number of enzymes, proteins and second messengers. There appears to be a core pathway common to all sphingolipid-producing organisms but recent studies have begun to dissect out important, species-specific differences. Many of these have only recently been discovered and in most cases the molecular and biochemical details are only beginning to emerge. Where there is a direct link from classic biochemistry to clinical symptoms, a number a drug companies have undertaken a medicinal chemistry campaign to try to deliver a therapeutic intervention to alleviate a number of diseases. Where appropriate, we highlight targets where natural products have been exploited as useful tools. Taking all these aspects into account this review covers the structural, mechanistic and regulatory features of sphingolipid biosynthetic and metabolic enzymes.

Serine metabolism in the brain regulates starvation-induced sleep suppression in Drosophila melanogaster

Foraging and sleep are two conflicting behaviors in starved animals; however, it remains elusive how metabolic status governs sleep drive. In this study, we show that a biosynthetic pathway for the amino acid serine is transcriptionally up-regulated by starvation in adult fly brains. The behavioral response to genetic manipulation of key enzymes involved in serine metabolism supports the sleep-suppressing effect of serine in response to starvation. In a society where daily diet is becoming increasingly important to the sleep quality of individuals, our study defines an amino acid metabolic pathway that underlies adaptive sleep behaviors upon dietary stress.

Sleep and metabolism are physiologically and behaviorally intertwined; however, the molecular basis for their interaction remains poorly understood. Here, we identified a serine metabolic pathway as a key mediator for starvation-induced sleep suppression. Transcriptome analyses revealed that enzymes involved in serine biosynthesis were induced upon starvation in Drosophila melanogaster brains. Genetic mutants of astray (aay), a fly homolog of the rate-limiting phosphoserine phosphatase in serine biosynthesis, displayed reduced starvation-induced sleep suppression. In contrast, a hypomorphic mutation in a serine/threonine-metabolizing enzyme, serine/threonine dehydratase (stdh), exaggerated starvation-induced sleep suppression. Analyses of double mutants indicated that aay and stdh act on the same genetic pathway to titrate serine levels in the head as well as to adjust starvation-induced sleep behaviors. RNA interference-mediated depletion of aay expression in neurons, using cholinergic Gal4 drivers, phenocopied aay mutants, while a nicotinic acetylcholine receptor antagonist selectively rescued the exaggerated starvation-induced sleep suppression in stdh mutants. Taken together, these data demonstrate that neural serine metabolism controls sleep during starvation, possibly via cholinergic signaling. We propose that animals have evolved a sleep-regulatory mechanism that reprograms amino acid metabolism for adaptive sleep behaviors in response to metabolic needs.

Catabolism of Amino Acids and Related Compounds

This review considers the pathways for the degradation of amino acids and a few related compounds (agmatine, putrescine, ornithine, and aminobutyrate), along with their functions and regulation. Nitrogen limitation and an acidic environment are two physiological cues that regulate expression of several amino acid catabolic genes. The review considers Escherichia coli, Salmonella enterica serovar Typhimurium, and Klebsiella species. The latter is included because the pathways in Klebsiella species have often been thoroughly characterized and also because of interesting differences in pathway regulation. These organisms can essentially degrade all the protein amino acids, except for the three branched-chain amino acids. E. coli, Salmonella enterica serovar Typhimurium, and Klebsiella aerogenes can assimilate nitrogen from D- and L-alanine, arginine, asparagine, aspartate, glutamate, glutamine, glycine, proline, and D- and L-serine. There are species differences in the utilization of agmatine, citrulline, cysteine, histidine, the aromatic amino acids, and polyamines (putrescine and spermidine). Regardless of the pathway of glutamate synthesis, nitrogen source catabolism must generate ammonia for glutamine synthesis. Loss of glutamate synthase (glutamineoxoglutarate amidotransferase, or GOGAT) prevents utilization of many organic nitrogen sources. Mutations that create or increase a requirement for ammonia also prevent utilization of most organic nitrogen sources.

A quantum mechanical/molecular mechanical study on the catalysis of the pyridoxal 5'-phosphate-dependent enzyme L-serine dehydratase

The catalytic mechanism of a pyridoxal 5'-phosphate-dependent enzyme, l-serine dehydratase, has been investigated using ab initio quantum mechanical/molecular mechanical (QM/MM) methods. New insights into the chemical steps have been obtained, including the chemical role of the substrate carboxyl group in the Schiff base formation step and a proton-relaying mechanism involving the phosphate of the cofactor in the beta-hydroxyl-leaving step. The latter step is of no barrier and follows sequentially after the elimination of the alpha-proton, leading to a single but sequential alpha, beta-elimination step. The rate-limiting transition state is specifically stabilized by the enzyme environment. At this transition state, charges are localized on the substrate carboxyl group, as well as on the amino group of Lys41. Specific interactions of the enzyme environment with these groups are able to lower the activation barrier significantly. One major difficulty associated with studies of complicated enzymatic reactions using ab initio QM/MM models is the appropriate choices of reaction coordinates. In this study, we have made use of efficient semiempirical models and pathway optimization techniques to overcome this difficulty.

Purification and characterization of serine racemase from a hyperthermophilic archaeon, Pyrobaculum islandicum

Pyrobaculum islandicum is an anaerobic hyperthermophilic archaeon that is most active at 100 degrees C. A pyridoxal 5'-phosphate-dependent serine racemase called Srr was purified from the organism. The corresponding srr gene was cloned, and recombinant Srr was purified from Escherichia coli. It showed the highest racemase activity toward L-serine, followed by L-threonine, D-serine, and D-threonine. Like rodent and plant serine racemases, Srr is bifunctional, showing high L-serine/L-threonine dehydratase activity. The sequence of Srr is 87% similar to that of Pyrobaculum aerophilum IlvA (a putative threonine dehydratase) but less than 32% similar to any other serine racemases and threonine dehydratases. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration analyses revealed that Srr is a homotrimer of a 44,000-molecular-weight subunit. Both racemase and dehydratase activities were highest at 95 degrees C, while racemization and dehydration were maximum at pH 8.2 and 7.8, respectively. Unlike other, related Ilv enzymes, Srr showed no allosteric properties: neither of these enzymatic activities was affected by either L-amino acids (isoleucine and valine) or most of the metal ions. Only Fe2+ and Cu2+ caused 20 to 30% inhibition and 30 to 40% stimulation of both enzyme activities, respectively. ATP inhibited racemase activity by 10 to 20%. The Km and Vmax values of the racemase activity of Srr for L-serine were 185 mM and 20.1 micromol/min/mg, respectively, while the corresponding values of the dehydratase activity of L-serine were 2.2 mM and 80.4 micromol/min/mg, respectively.

Multicopy suppression underpins metabolic evolvability

Our understanding of the origins of new metabolic functions is based upon anecdotal genetic and biochemical evidence. Some auxotrophies can be suppressed by overexpressing substrate-ambiguous enzymes (i.e., those that catalyze the same chemical transformation on different substrates). Other enzymes exhibit weak but detectable catalytic promiscuity in vitro (i.e., they catalyze different transformations on similar substrates). Cells adapt to novel environments through the evolution of these secondary activities, but neither their chemical natures nor their frequencies of occurrence have been characterized en bloc. Here, we systematically identified multifunctional genes within the Escherichia coli genome. We screened 104 single-gene knockout strains and discovered that many (20%) of these auxotrophs were rescued by the overexpression of at least one noncognate E. coli gene. The deleted gene and its suppressor were generally unrelated, suggesting that promiscuity is a product of contingency. This genome-wide survey demonstrates that multifunctional genes are common and illustrates the mechanistic diversity by which their products enhance metabolic robustness and evolvability.

Stability of plant defense proteins in the gut of insect herbivores

Plant defense against insect herbivores is mediated in part by enzymes that impair digestive processes in the insect gut. Little is known about the evolutionary origins of these enzymes, their distribution in the plant kingdom, or the mechanisms by which they act in the protease-rich environment of the animal digestive tract. One example of such an enzyme is threonine (Thr) deaminase (TD), which in tomato (Solanum lycopersicum) serves a dual role in isoleucine (Ile) biosynthesis in planta and Thr degradation in the insect midgut. Here, we report that tomato uses different TD isozymes to perform these functions. Whereas the constitutively expressed TD1 has a housekeeping role in Ile biosynthesis, expression of TD2 in leaves is activated by the jasmonate signaling pathway in response to herbivore attack. Ingestion of tomato foliage by specialist (Manduca sexta) and generalist (Trichoplusia ni) insect herbivores triggered proteolytic removal of TD2's C-terminal regulatory domain, resulting in an enzyme that degrades Thr without being inhibited through feedback by Ile. This processed form (pTD2) of TD2 accumulated to high levels in the insect midgut and feces (frass). Purified pTD2 exhibited biochemical properties that are consistent with a postingestive role in defense. Shotgun proteomic analysis of frass from tomato-reared M. sexta identified pTD2 as one of the most abundant proteins in the excrement. Among the other tomato proteins identified were several jasmonate-inducible proteins that have a known or proposed role in anti-insect defense. Subtilisin-like proteases and other pathogenesis-related proteins, as well as proteins of unknown function, were also cataloged. We conclude that proteomic analysis of frass from insect herbivores provides a robust experimental approach to identify hyperstable plant proteins that serve important roles in defense.

Stability of plant defense proteins in the gut of insect herbivores

Plant defense against insect herbivores is mediated in part by enzymes that impair digestive processes in the insect gut. Little is known about the evolutionary origins of these enzymes, their distribution in the plant kingdom, or the mechanisms by which they act in the protease-rich environment of the animal digestive tract. One example of such an enzyme is threonine (Thr) deaminase (TD), which in tomato (Solanum lycopersicum) serves a dual role in isoleucine (Ile) biosynthesis in planta and Thr degradation in the insect midgut. Here, we report that tomato uses different TD isozymes to perform these functions. Whereas the constitutively expressed TD1 has a housekeeping role in Ile biosynthesis, expression of TD2 in leaves is activated by the jasmonate signaling pathway in response to herbivore attack. Ingestion of tomato foliage by specialist (Manduca sexta) and generalist (Trichoplusia ni) insect herbivores triggered proteolytic removal of TD2's C-terminal regulatory domain, resulting in an enzyme that degrades Thr without being inhibited through feedback by Ile. This processed form (pTD2) of TD2 accumulated to high levels in the insect midgut and feces (frass). Purified pTD2 exhibited biochemical properties that are consistent with a postingestive role in defense. Shotgun proteomic analysis of frass from tomato-reared M. sexta identified pTD2 as one of the most abundant proteins in the excrement. Among the other tomato proteins identified were several jasmonate-inducible proteins that have a known or proposed role in anti-insect defense. Subtilisin-like proteases and other pathogenesis-related proteins, as well as proteins of unknown function, were also cataloged. We conclude that proteomic analysis of frass from insect herbivores provides a robust experimental approach to identify hyperstable plant proteins that serve important roles in defense.

Crystallization and preliminary X-ray crystallographic analysis of biodegradative threonine deaminase (TdcB) from Salmonella typhimurium

Biodegradative threonine deaminase (TdcB) catalyzes the deamination of L-threonine to alpha-ketobutyrate, the first reaction in the anaerobic breakdown of L-threonine to propionate. Unlike the biosynthetic threonine deaminase, TdcB is insensitive to L-isoleucine and is activated by AMP. Here, the cloning of TdcB (molecular weight 36 kDa) from Salmonella typhimurium with an N-terminal hexahistidine affinity tag and its overexpression in Escherichia coli is reported. TdcB was purified to homogeneity using Ni-NTA affinity column chromatography and crystallized using the hanging-drop vapour-diffusion technique in three different crystal forms. Crystal forms I (unit-cell parameters a = 46.32, b = 55.30, c = 67.24 A, alpha = 103.09, beta = 94.70, gamma = 112.94 degrees) and II (a = 56.68, b = 76.83, c = 78.50 A, alpha = 66.12, beta = 89.16, gamma = 77.08 degrees) belong to space group P1 and contain two and four molecules of TdcB, respectively, in the asymmetric unit. Poorly diffracting form III crystals were obtained in space group C2 and based on the unit-cell volume are most likely to contain one molecule per asymmetric unit. Two complete data sets of resolutions 2.2 A (crystal form I) and 1.7 A (crystal form II) were collected at 100 K using an in-house X-ray source.

Role of type III secretion in Edwardsiella tarda virulence

Edwardsiella tarda is a Gram-negative enteric bacterium affecting both animals and humans. Recently, a type III secretion system (TTSS) was found in Ed. tarda. Such systems are generally used by bacterial pathogens to deliver virulence factors into host cells to subvert normal cell functions. Genome-walking was performed from the eseB and esrB genes (homologues of Salmonella sseB and ssrB, respectively) identified in previous studies, to determine the sequences of the TTSS. Thirty-five ORFs were identified which encode the TTSS apparatus, chaperones, effectors and regulators. Mutants affected in genes representing each category were generated and found to have decreased survival and growth in fish phagocytes. LD50 values of the mutants were increased by at least 10-fold in comparison to those of the wild-type strain. The adherence and invasion rates of the esrA and esrB mutants were enhanced while those of the other mutants remained similar to the wild-type. The eseC and eseD mutants showed slight autoaggregation in Dulbecco's Modified Eagle Medium, whereas the rest of the mutants failed to autoaggregate. Regulation of the TTSS was found to involve the two-component regulatory system esrA–esrB. This study showed that the TTSS is important for Ed. tarda pathogenesis. An understanding of this system will provide greater insight into the virulence mechanisms of this bacterial pathogen.

Mice have a transcribed L-threonine aldolase/GLY1 gene, but the human GLY1 gene is a non-processed pseudogene

Background

There are three pathways of L-threonine catabolism. The enzyme L-threonine aldolase (TA) has been shown to catalyse the conversion of L-threonine to yield glycine and acetaldehyde in bacteria, fungi and plants. Low levels of TA enzymatic activity have been found in vertebrates. It has been suggested that any detectable activity is due to serine hydroxymethyltransferase and that mammals lack a genuine threonine aldolase.

Results

The 7-exon murine L-threonine aldolase gene (GLY1) is located on chromosome 11, spanning 5.6 kb. The cDNA encodes a 400-residue protein. The protein has 81% similarity with the bacterium Thermotoga maritima TA. Almost all known functional residues are conserved between the two proteins including Lys242 that forms a Schiff-base with the cofactor, pyridoxal-5'-phosphate. The human TA gene is located at 17q25. It contains two single nucleotide deletions, in exons 4 and 7, which cause frame-shifts and a premature in-frame stop codon towards the carboxy-terminal. Expression of human TA mRNA was undetectable by RT-PCR. In mice, TA mRNA was found at low levels in a range of adult tissues, being highest in prostate, heart and liver. In contrast, serine/threonine dehydratase, another enzyme that catabolises L-threonine, is expressed very highly only in the liver. Serine dehydratase-like 1, also was most abundant in the liver. In whole mouse embryos TA mRNA expression was low prior to E-15 increasing more than four-fold by E-17.

Conclusion

Mice, the western-clawed frog and the zebrafish have transcribed threonine aldolase/GLY1 genes, but the human homolog is a non-transcribed pseudogene. Serine dehydratase-like 1 is a putative L-threonine catabolising enzyme.

Some biochemical and histochemical properties of human liver serine dehydratase

In rat, serine dehydratase (SDH) is abundant in the liver and known to be a gluconeogenic enzyme, while there is little information about the biochemical property of human liver serine dehydratase because of its low content and difficulty in obtaining fresh materials. To circumvent these problems, we purified recombinant enzyme from Escherichia coli, and compared some properties between human and rat liver serine dehydratases. Edman degradation showed that the N-terminal sequence of about 75% of human serine dehydratase starts from MetSTART-Met2-Ser3- and the rest from Ser3-, whereas the N-terminus of rat enzyme begins from the second codon of MetSTART-Ala2-. The heterogeneity of the purified preparation was totally confirmed by mass spectrometry. Accordingly, this observation in part fails to follow the general rule that the first Met is not removed when the side chain of the penultimate amino acid is bulky such as Met, Arg, Lys, etc. There existed the obvious differences in the local structures between the two enzymes as revealed by limited-proteolysis experiments using trypsin and Staphylococcus aureus V8 protease. The most prominent difference was found histochemically: expression of rat liver serine dehydratase is confined to the periportal region in which many enzymes involved in gluconeogenesis and urea cycle are known to coexist, whereas human liver serine dehydratase resides predominantly in the perivenous region. These findings provide an additional support to the previous notion suggested by physiological experiments that contribution of serine dehydratase to gluconeogenesis is negligible or little in human liver.

Crystal structure of the pyridoxal-5'-phosphate-dependent serine dehydratase from human liver

L-serine dehydratase (SDH), a member of the beta-family of pyridoxal phosphate-dependent (PLP) enzymes, catalyzes the deamination of L-serine and L-threonine to yield pyruvate or 2-oxobutyrate. The crystal structure of L-serine dehydratase from human liver (hSDH) has been solved at 2.5 A-resolution by molecular replacement. The structure is a homodimer and reveals a fold typical for beta-family PLP-dependent enzymes. Each monomer serves as an active unit and is subdivided into two distinct domains: a small domain and a PLP-binding domain that covalently anchors the cofactor. Both domains show the typical open alpha/beta architecture of PLP enzymes. Comparison with the rSDH-(PLP-OMS) holo-enzyme reveals a large structural difference in active sites caused by the artifical O-methylserine. Furthermore, the activity of hSDH-PLP was assayed and it proved to show catalytic activity. That suggests that the structure of hSDH-PLP is the first structure of the active natural holo-SDH.

Cloning, expression, purification, crystallization and preliminary X-ray diffraction analysis of propionate kinase (TdcD) from Salmonella typhimurium

In the cell, propionate is mainly formed during beta-oxidation of odd-numbered carbon-chain fatty acids, fermentation of carbohydrates and degradation of the amino acids threonine, valine, isoleucine and methionine. Recently, it has been shown that L-threonine is non-oxidatively cleaved to propionate via 2-ketobutyrate. The last step in this process, conversion of propionyl phosphate and ADP to propionate and ATP, is catalysed by propionate kinase (EC 2.7.1.-). Here, the cloning of propionate kinase (molecular weight 44 kDa) from Salmonella typhimurium with an N-terminal hexahistidine affinity tag and its overexpression in Escherichia coli are reported. Purified propionate kinase was found to cocrystallize with ADP in the hanging-drop vapour-diffusion and microbatch methods. Crystals belong to space group P3(1)21 or P3(2)21, with unit-cell parameters a = b = 111.47, c = 66.52 A. A complete data set to 2.2 A resolution has been collected using an image-plate detector system mounted on a rotating-anode X-ray generator.

The iron-sulfur cluster in thel-serine dehydratase TdcG fromEscherichia coliis required for enzyme activity

The anaerobically inducible L-serine dehydratase, TdcG, from Escherichia coli was characterized. Based on UV-visible spectroscopy, iron and labile sulfide analyses, the homodimeric enzyme is proposed to have two oxygen-labile [4Fe-4S]2+ clusters. Anaerobically isolated dimeric TdcG had a kcat of 544 s(-1) and an apparent KM for L-serine of 4.8 mM. L-threonine did not act as a substrate for the enzyme. Exposure of the active enzyme to air resulted in disappearance of the broad absorption band at 400-420 nm, indicating a loss of the [4Fe-4S]2+ cluster. A concomitant loss of dehydratase activity was demonstrated, indicating that integrity of the [4Fe-4S]2+ cluster is essential for enzyme activity.

Crystal structure of serine dehydratase from rat liver

SDH (L-serine dehydratase, EC 4.3.1.17) catalyzes the pyridoxal 5'-phosphate (PLP)-dependent dehydration of L-serine to yield pyruvate and ammonia. Liver SDH plays an important role in gluconeogenesis. Formation of pyruvate by SDH is a two-step reaction in which the hydroxyl group of serine is cleaved to produce aminoacrylate, and then the aminoacrylate is deaminated by nonenzymatic hydrolysis to produce pyruvate. The crystal structure of rat liver apo-SDH was determined by single isomorphous replacement at 2.8 A resolution. The holo-SDH crystallized with O-methylserine (OMS) was also determined at 2.6 A resolution by molecular replacement. SDH is composed of two domains, and each domain has a typical alphabeta-open structure. The active site is located in the cleft between the two domains. The holo-SDH contained PLP-OMS aldimine in the active site, indicating that OMS can form the Schiff base linkage with PLP, but the subsequent dehydration did not occur. Apo-SDH forms a dimer by inserting the small domain into the catalytic cleft of the partner subunit so that the active site is closed. Holo-SDH also forms a dimer by making contacts at the back of the clefts so that the dimerization does not close the catalytic cleft. The phosphate group of PLP is surrounded by a characteristic G-rich sequence ((168)GGGGL(172)) and forms hydrogen bonds with the amide groups of those amino acid residues, suggesting that the phosphate group can be protonated. N(1) of PLP participates in a hydrogen bond with Cys303, and similar hydrogen bonds with N(1) participating are seen in other beta-elimination enzymes. These hydrogen bonding schemes indicate that N(1) is not protonated, and thus, the pyridine ring cannot take a quinone-like structure. These characteristics of the bound PLP suggest that SDH catalysis is not facilitated by forming the resonance-stabilized structure of the PLP-Ser aldimine as seen in aminotransferases. A possible catalytic mechanism involves the phosphate group, surrounded by the characteristic sequence, acting as a general acid to donate a proton to the leaving hydroxyl group of serine.

Structure and function correlations between the rat liver threonine deaminase and aminotransferases

The rat liver threonine deaminase is a cytoplasmic enzyme that catalyses the pyridoxal-phosphate-dependent dehydrative deamination of L-threonine and L-serine to ammonia and alpha-ketobutyrate and pyruvate, respectively, in vivo. During deamination, a molecule of the cofactor is converted to pyridoxamine phosphate. Recently, the ability of this enzyme to accomplish an inverse half-reaction, restoring pyridoxal-phosphate and L-alanine or L-aminobutyrate, respectively, from pyruvate or 2-oxobutyrate, was reported. In order to investigate the molecular mechanisms of this transaminating activity, a molecular model of rat liver threonine deaminase was constructed on the basis of sequence homology with the biosynthetic threonine deaminase of Escherichia coli, the crystal structure of which is known. The model has structural features shared by aminotransferases, suggesting that tertiary structural elements may be responsible for the transaminating activity observed for rat liver threonine deaminase.

A novel mechanism controls anaerobic and catabolite regulation of the Escherichia coli tdc operon

The tdc operon is subject to CRP-controlled catabolite repression. Expression of the operon is also induced anaerobically, although this regulation does not rely on direct control by either FNR or ArcA. Recently, the anaerobic expression of the tdc operon was found to be fortuitously induced in the presence of glucose by a heterologous gene isolated from the Gram-positive anaerobe Clostridium butyricum. The gene, termed tcbC, encoded a histone-like protein of 14.5 kDa. Using tdc-lacZ fusions, it was shown that TcbC did not activate tdc expression by functionally replacing any of the operon regulators. In vitro transcription analyses with RNA polymerase and CRP revealed that faithful CRP-dependent transcription initiation occurred only on supercoiled templates. No specific, CRP-dependent transcription initiation was observed on relaxed or linear DNA templates. Surprisingly, purified His-tagged TcbC activated transcription from a relaxed, circular template, but not from supercoiled or linear templates. Examination of the CRP binding site of the tdc promoter revealed that it was located 43.5 bp upstream of the transcription initiation site. Repositioning of the CRP site at -41.5 bp abolished activation by the TcbC protein and allowed CRP-dependent transcription to occur on linear, relaxed and supercoiled templates. TcbC bound DNA non-specifically; however, in topoisomerase I relaxation assays, it was demonstrated that TcbC imposed torsional constraints on negatively supercoiled DNA, which influenced the ability of the enzyme to relax the topoisomers. Taken together, these results strongly suggest that TcbC activates transcription of tdc by altering the local topological status of the tdc promoter and that, in the wild-type tdc promoter, the CRP binding site is misaligned to allow transcription to occur only under optimal conditions. Indeed, in vivo transcription analyses revealed that repositioning of the CRP binding site to -41.5 bp resulted in high-level, CRP-dependent transcription, even under catabolite-repressing conditions, and that transcription was no longer influenced by TcbC. Remarkably, however, anaerobic regulation of the mutant promoter was retained. This indicates that the other tdc regulators, TdcA and TdcR, govern anaerobic transcription activation by CRP.

Rat liver serine dehydratase. Bacterial expression and two folding domains as revealed by limited proteolysis

A pCW vector harboring rat liver serine dehydratase cDNA was expressed in Escherichia coli. The expressed level was about 5-fold higher in E. coli BL21 than in JM109 cell extract; the former lacked two kinds of proteases. Immunoblot analysis revealed the occurrence of a derivative other than serine dehydratase in the JM109 cell extract. The recombinant enzyme was purified to homogeneity. Staphylococcus aureus V8 protease and trypsin cleaved the enzyme at Glu-206 and Lys-220, respectively, with a concomitant loss of enzyme activity. Spectrophotometrically, the nicked enzyme showed a approximately 50% reduced capacity for binding of the coenzyme pyridoxal phosphate and no spectral change of circular dichroism in the region at 300-480 nm, whereas circular dichroism spectra of both enzymes in the far-UV region were similar, suggesting that proteolysis impairs the coenzyme binding without an accompanying gross change of the secondary structure. Whereas the nicked enzyme behaved like the intact enzyme on Sephadex G-75 column chromatography, it was dissociated into two fragments on the column containing 6 M urea. Upon the removal of urea, both fragments spontaneously refolded. These results suggest that serine dehydratase consists of two folding domains connected by a region that is very susceptible to proteases.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

A glycyl radical solution: oxygen-dependent interconversion of pyruvate formate-lyase

Pyruvate formate-lyase (PFL) catalyses the non-oxidative dissimilation of pyruvate to formate and acetyl-CoA using a radical-chemical mechanism. The enzyme is enzymically interconverted between inactive and active forms, the active form contains an organic free radical located on a glycyl residue in the C-terminal portion of the polypeptide chain. Introduction of the radical into PFL only occurs anaerobically, and the activating enzyme responsible is an iron-sulphur protein that uses S-adenosyl methionine as cofactor and reduced flavodoxin as reductant. As the radical form of PFL is inactivated by molecular oxygen it is safeguarded during the transition to aerobiosis by conversion back to the radical-free, oxygen-stable form. This reaction is catalysed by the anaerobically induced multimeric enzyme alcohol dehydrogenase. The genes encoding PFL and its activating enzyme are adjacent on the chromosome but form discrete transcriptional units. This genetic organization is highly conserved in many, but not all, organisms that have PFL. Recent studies have shown that proteins exhibiting significant similarity to PFL and its activating enzyme are relatively widespread in facultative and obligate anaerobic eubacteria, as well as archaea. The physiological function of many of these PFL-like enzymes remains to be established. It is becoming increasingly apparent that glycyl radical enzymes are more prevalent than previously surmised. They represent a class of enzymes with unusual biochemistry and probably predate the appearance of molecular oxygen.

The glycyl radical enzyme TdcE can replace pyruvate formate-lyase in glucose fermentation

Mutants of Escherichia coli unable to synthesize a functional pyruvate formate-lyase (PFL) are severely impaired in their capacity to grow by glucose fermentation. In a functional complementation assay designed to isolate the pfl gene from Clostridium butyricum, we fortuitously identified a gene that did not encode a PFL but nonetheless was able to complement the phenotypic defects caused by an E. coli pfl mutation. The clostridial gene encoded a basic 14. 5-kDa protein (TcbC) which, based on amino acid similarity and analysis of immediately adjacent DNA sequences, was part of a transposase exhibiting extensive similarity to the product of the site-specific transposon Tn554 from Staphylococcus aureus. Our studies revealed that the clostridial TcbC protein activated the transcription of the E. coli tdcABCDEFG operon, which encodes an anaerobic L-threonine-degradative pathway. Normally, anaerobic synthesis of the pathway is optimal when E. coli grows in the absence of catabolite-repressing sugars and in the presence of L-threonine. Although anaerobic control of pathway synthesis was maintained, TcbC alleviated glucose repression. One of the products encoded by the tdc operon, TdcE, has recently been shown to be a 2-keto acid formate-lyase (C. Hesslinger, S. A. Fairhurst, and G. Sawers, Mol. Microbiol. 27:477-492, 1998) that can accept pyruvate as an enzyme substrate. Here we show that TdcE is directly responsible for the restoration of fermentative growth to pfl mutants.

Novel keto acid formate-lyase and propionate kinase enzymes are components of an anaerobic pathway in Escherichia coli that degrades L-threonine to propionate

An immunological analysis of an Escherichia coli strain unable to synthesize the main pyruvate formate-lyase enzyme Pfl revealed the existence of a weak, cross-reacting 85 kDa polypeptide that exhibited the characteristic oxygen-dependent fragmentation typical of a glycyl radical enzyme. Polypeptide fragmentation of this cross-reacting species was shown to be dependent on Pfl activase. Cloning and sequence analysis of the gene encoding this protein revealed that it coded for a new enzyme, termed TdcE, which has 82% identity with Pfl. On the basis of RNA analyses, the tdcE gene was shown to be part of a large operon that included the tdcABC genes, encoding an anaerobic threonine dehydratase, tdcD, coding for a propionate kinase, tdcF, the function of which is unknown, and the tdcG gene, which encodes a L-serine dehydratase. Expression of the tdcABCDEFG operon was strongly catabolite repressed. Enzyme studies showed that TdcE has both pyruvate formate-lyase and 2-ketobutyrate formate-lyase activity, whereas the TdcD protein is a new propionate/acetate kinase. By monitoring culture supernatants from various mutants using 1H nuclear magnetic resonance (NMR), we followed the anaerobic conversion of L-threonine to propionate. These studies confirmed that 2-ketobutyrate, the product of threonine deamination, is converted in vivo by TdcE to propionyl-CoA. These studies also revealed that Pfl and an as yet unidentified thiamine pyrophosphate-dependent enzyme(s) can perform this reaction. Double null mutants deficient in phosphotransacetylase (Pta) and acetate kinase (AckA) or AckA and TdcD were unable to metabolize threonine to propionate, indicating that propionyl-CoA and propionyl-phosphate are intermediates in the pathway and that ATP is generated during the conversion of propionyl-P to propionate by AckA or TdcD.

Isolation and characterization of D-threonine aldolase, a pyridoxal-5'-phosphate-dependent enzyme from Arthrobacter sp. DK-38

D-Threonine aldolase is an enzyme that catalyzes the cleavage of D-threonine into glycine and acetaldehyde. Its activity was found in several genera of bacteria such as Arthrobacter, Alcaligenes, Xanthomonas, and Pseudomonas, but not in yeasts or fungi. The enzyme was purified to homogeneity from one strain, Arthrobacter sp. DK-38. The enzyme appeared to consist of a single polypeptide chain with an apparent molecular mass of 51 kDa. This enzyme, as well as L-threonine aldolase, requires pyridoxal 5'-phosphate (pyridoxal-P) as a coenzyme. Unlike other pyridoxal-P enzymes, D-threonine aldolase also requires a divalent cation such as Co2+, Ni2+, Mn2+, or Mg2+ for its catalytic activity. The enzyme completely lost its activity in the absence of either pyridoxal-P or a divalent cation. A divalent cation was also essential for the thermal stability of the enzyme. The metal-free enzyme tends to become thermally unstable, resulting in the irreversible loss of its catalytic activity. The enzyme is strictly D-specific for the alpha-position, whereas it cannot distinguish between threo and erythro forms at the beta-position. Thus, D-threonine and D-allothreonine act as substrates of the enzyme, but their kinetic parameters are different; the Km and Vmax values are 3.81 mM and 38.8 micromol x min(-1) x mg(-1) toward D-threonine, and 14.0 mM and 102 micromol x min(-1) x mg(-1) toward D-allothreonine. respectively. The aldolase reaction is reversible, and the enzyme is therefore able to produce nearly equimolar amounts of D-threonine and D-allothreonine through C-C bond formation between glycine and acetaldehyde. The enzyme also acts, in the same manner, on several other D-beta-hydroxy-alpha-amino acids, including D-beta-phenylserine, D-beta-hydroxy-alpha-aminovaleric acid, D-beta-3,4-dihydroxyphenylserine, and D-beta-3,4-methylenedioxyphenylserine.

Mutation of cysteine 111 in Dopa decarboxylase leads to active site perturbation

Cysteine 111 in Dopa decarboxylase (DDC) has been replaced by alanine or serine by site-directed mutagenesis. Compared to the wild-type enzyme, the resultant C111A and C111S mutant enzymes exhibit Kcat values of about 50% and 15%, respectively, at pH 6.8, while the K(m) values remain relatively unaltered for L-3,4-dihydroxyphenylalanine (L-Dopa) and L-5-hydroxytryptophan (L-5-HTP). While a significant decrease of the 280 nm optically active band present in the wild type is observed in mutant DDCs, their visible co-enzyme absorption and CD spectra are similar to those of the wild type. With respect to the wild type, the Cys-111-->Ala mutant displays a reduced affinity for pyridoxal 5'-phosphate (PLP), slower kinetics of reconstitution to holoenzyme, a decreased ability to anchor the external aldimine formed between D-Dopa and the bound co-enzyme, and a decreased efficiency of energy transfer between tryptophan residue(s) and reduced PLP. Values of pKa and pKb for the groups involved in catalysis were determined for the wild-type and the C111A mutant enzymes. The mutant showed a decrease in both pK values by about 1 pH unit, resulting in a shift of the pH of the maximum velocity from 7.2 (wild-type) to 6.2 (mutant). This change in maximum velocity is mirrored by a similar shift in the spectrophotometrically determined pK value of the 420-->390 nm transition of the external aldimine. These results demonstrate that the sulfhydryl group of Cys-111 is catalytically nonessential and provide strong support for previous suggestion that this residue is located at or near the PLP binding site (Dominici P, Maras B, Mei G, Borri Voltattorni C. 1991. Eur J Biochem 201:393-397). Moreover, our findings provide evidence that Cys-111 has a structural role in PLP binding and suggest that this residue is required for maintenance of proper active-site conformation.

Involvement of Fnr and ArcA in anaerobic expression of the tdc operon of Escherichia coli

Anaerobic expression of the tdcABC operon in Escherichia coli, as measured by LacZ activity from single-copy tdc-lacZ transcriptional and translational fusions, is greatly reduced in strains lacking two global transcriptional regulators, Fnr and ArcA. The nucleotide sequence of the tdc promoter around -145 shows significant similarity with the consensus Fnr-binding site; however, extensive base substitutions within this region had no effect on Fnr regulation of the tdc genes. A genetic analysis revealed that the effect of Fnr on tdc is not mediated via ArcA. Furthermore, addition of cyclic AMP to the anaerobic incubation medium completely restored tdc expression in fnr and arcA mutants as well as in strains harboring mutations in the Fnr- and ArcA-dependent pfl gene and the Fnr-regulated glpA and frd genes. These results, taken together with the earlier finding that tdc expression is subject to catabolite repression by intermediary metabolites, strongly suggest that the negative regulatory effects of mutations in the fnr and arcA genes are mediated physiologically due to accumulation of a metabolite(s) which prevents tdc transcription in vivo.

Functional analysis of the tdcABC promoter of Escherichia coli: roles of TdcA and TdcR

The efficient expression of the tdc operon of Escherichia coli requires the products of two regulatory genes, tdcR and tdcA. We have identified the transcription site of tdcR by primer extension mapping and established the translation start site of TdcR by mutational analysis of its reading frame. In a tdcR tdcABC deletion strain, tdcR+ promoted high-level LacZ expression from a lambda tdcAB-lacZ lysogen and mutations introduced in tdcR resulted in a greater than sixfold decrease in LacZ level. In-frame deletions of tdcA also reduced LacZ expression, and chromosomal and plasmid-borne tdcA+ increased the LacZ level in tdcA mutant lysogens. Interestingly, multicopy tdcA+ plasmids introduced into tdcR mutant strains completely restored tdc expression. In separate experiments we found that mutations in the tdc promoter DNA around positions -70, -140, and -175 greatly reduced tdc expression relative to that for the wild-type promoter and the tdcP mutation around -175 prevented multicopy tdcA+ from rescuing tdcR mutants. Furthermore, competition experiments revealed that a wild-type promoter fragment encompassing the -175 region cloned into a plasmid reduced tdc expression by titrating TdcA in vivo, and this effect was reversed with excess TdcA. These results suggest that in tdcR+ cells TdcR interacts with tdcP and/or TdcA to enhance tdc transcription whereas in tdcR mutant cells a new tdcP-TdcA complex around -175 in the native promoter bypasses the requirement for TdcR. On the basis of the accumulated data summarized here and elsewhere we propose that multiple transcription factors enhance tdc operon expression by bending and looping of the promoter DNA to form an active transcription complex.

Threonine dehydratases of Corynebacterium glutamicum with altered allosteric control: their generation and biochemical and structural analysis

Threonine dehydratase is the key enzyme in L-isoleucine synthesis, since it is allosterically feedback-inhibited by L-isoleucine. With the aim of obtaining regulatorily altered mutants of the threonine dehydratase of Corynebacterium glutamicum, amino acids were specifically exchanged and a new biological system of mutant selection was developed, based on the intoxication of Escherichia coli by ketobutyrate, which is the dehydratase reaction product. A collection of 19 mutant enzymes was generated and genetically and biochemically characterized comprising a whole range of regulatorily and catalytically altered enzymes. Of particular interest is the mutant Val-323-Ala, which is characterized by the fact that the L-isoleucine inhibition is entirely abolished so that the enzyme is always present in a relaxed, high-activity state. Correspondingly, the Hill coefficient is 1.4, in contrast to the value of 3.4 characteristic of the wild-type enzyme. Another peculiar mutant generated is the double mutant His-278-Arg-Leu-351-Ser. Here, again, L-isoleucine no longer inhibits catalytic activity, but the effector still promotes major structural changes of the protein, as ascertained from the L-isoleucine-dependent loss of pyridoxal-5'-phosphate from this mutant enzyme. Further enzymes obtained are reduced in L-isoleucine inhibition to a varying degree. Detailed studies on the structure of the enzyme revealed a partially very high similarity of the secondary structure to the mechanistically identical beta-subunit of the tryptophan synthase. This provides further indications concerning the localization of the regulatory and catalytic domain of the threonine dehydratase.

The complete sequencing of a 24.6 kb segment of yeast chromosome XI identified the known loci URA1, SAC1 and TRP3, and revealed 6 new open reading frames including homologues to the threonine dehydratases, membrane transporters, hydantoinases and the phospholipase A2-activating protein

We report the entire sequence of a 26.4 kb segment of chromosome XI of Saccharomyces cerevisiae. Identification of the known loci URA1, TRP3 and SAC1 revealed a translocation compared to the genetic map. Additionally, six unknown open reading frames have been identified. One of them is similar to catabolic threonine dehydratases. Another one contains characteristic features of membrane transporters. A third one is homologous in half of its length to the prokaryotic hydantoinase HyuA and in the other half to hydatoinase HyuB. A fourth one is homologous to the mammalian phospholipase A2-activating protein. A fifth one, finally, is homologous to the hypothetical open reading frame YCR007C of chromosome III. The sequence has been deposited in the EMBL data library under Accession Number X75951.

Evolutionary relationships among pyridoxal-5'-phosphate-dependent enzymes. Regio-specific alpha, beta and gamma families

Pyridoxal-5'-phosphate-dependent enzymes catalyze manifold reactions in the metabolism of amino acids. A comprehensive comparison of amino acid sequences has shown that most of these enzymes can be assigned to one of three different families of homologous proteins. The sequences of the enzymes of each family were aligned and their homology confirmed by profile analysis. Scrutiny of the reactions catalyzed by the enzymes showed that their affiliation with one of the three structurally defined families correlates in most cases with their regio-specificity. In the largest family, the covalency changes of the substrate occur at the same carbon atom that carries the amino group forming the imine linkage with the coenzyme. This family was thus named alpha family. It comprises glycine hydroxymethyltransferase, glycine C-acetyltransferase, 5-aminolevulinate synthase, 8-amino-7-oxononanoate synthase, all aminotransferases (with the possible exception of subgroup III), a number of other enzymes relatively closely related with the aminotransferases and very likely a certain group of amino acid decarboxylases as well as tryptophanase and tyrosine phenol-lyase which, however, catalyze beta-elimination reactions. The beta family includes L- and D-serine dehydratase, threonine dehydratase, the beta subunit of tryptophan synthase, threonine synthase and cysteine synthase. These enzymes catalyze beta-replacement or beta-elimination reactions. The gamma family incorporates O-succinylhomoserine (thiol-lyase, O-acetylhomoserine (thiol)-lyase, and cystathionine gamma-lyase, which catalyze gamma-replacement or gamma-elimination reactions, as well as cystathionine beta-lyase. The alpha and gamma family might be distantly related with one another, but are clearly not homologous with the beta family. Apparently, the primordial pyridoxal-5'-phosphate-dependent enzymes were regio-specific catalysts, which first specialized for reaction specificity and then for substrate specificity. The following pyridoxal-5'-phosphate-dependent enzymes seem to be unrelated with the alpha, beta or gamma family by the criterion of profile analysis:alanine racemase, selenocysteine synthase, and many amino acid decarboxylases. These enzymes may represent yet other families of B6 enzymes.

Functions of the gene products of Escherichia coli

A list of currently identified gene products of Escherichia coli is given, together with a bibliography that provides pointers to the literature on each gene product. A scheme to categorize cellular functions is used to classify the gene products of E. coli so far identified. A count shows that the numbers of genes concerned with small-molecule metabolism are on the same order as the numbers concerned with macromolecule biosynthesis and degradation. One large category is the category of tRNAs and their synthetases. Another is the category of transport elements. The categories of cell structure and cellular processes other than metabolism are smaller. Other subjects discussed are the occurrence in the E. coli genome of redundant pairs and groups of genes of identical or closely similar function, as well as variation in the degree of density of genetic information in different parts of the genome.

TdcA, a transcriptional activator of the tdcABC operon of Escherichia coli, is a member of the LysR family of proteins

The tdcB and tdcC genes of the tdcABC operon of Escherichia coli encode threonine dehydratase and a threonine-serine permease, respectively. These proteins are involved in transport and metabolism of threonine and serine during anaerobic growth. In this study, we functionally characterized tdcA, which encodes a 35 kDa polypeptide consisting of 312 amino acid residues. Non-polar and partially polar mutations introduced into tdcA drastically reduced the expression of the genes down-stream from tdcA. Complementation studies using single-copy chromosomal integrants of a tdcB-lacZ fusion harboring an in-frame deletion of tdcA with chromosomal or plasmid-borne tdcA+ in trans showed complete restoration of tdc operon expression in vivo. The amino acid sequence at the amino-terminal end of TdcA revealed a significant homology to the helix-turn-helix motifs of typical DNA binding proteins. Sequence alignment of TdcA with LysR also showed considerable sequence similarity throughout their entire lengths. Our results suggest that TdcA is related to the LysR family of proteins by common ancestry and, based on its functional role in tdc expression, belongs to the LysR family of transcriptional activators.

Sequencing and characterization of the sdaB gene from Escherichia coli K-12

The sdaB gene which codes for the second L-serine deaminase (L-SD) of Escherichia coli K-12 has been sequenced and shown to be very similar to the sdaA gene which codes for the first L-serine deaminase. sdaB is transcribed in rich medium, particularly in the absence of glucose, and is under the control of catabolite activator protein. A mutation which established expression of the sdaB gene and synthesis of L-serine deaminase 2 in minimal medium has been demonstrated to result in a change in the ribosome-binding site of the sdaB gene.

Functional and structural analyses of threonine dehydratase from Corynebacterium glutamicum

Threonine dehydratase activity is an important element in the flux control of isoleucine biosynthesis. The enzyme of Corynebacterium glutamicum demonstrates a marked sigmoidal dependence of initial velocity on the threonine concentration, a dependence that is consistent with substrate-promoted conversion of the enzyme from a low-activity to a high-activity conformation. In the presence of the negative allosteric effector isoleucine, the K0.5 increased from 21 to 78 mM and the cooperativity, as expressed by the Hill coefficient increased from 2.4 to 3.7. Valine promoted opposite effects: the K0.5 was reduced to 12 mM, and the enzyme exhibited almost no cooperativity. Sequence determination of the C. glutamicum gene for this enzyme revealed an open reading frame coding for a polypeptide of 436 amino acids. From this information and the molecular weight determination of the native enzyme, it follows that the dehydratase is a tetramer with a total mass of 186,396 daltons. Comparison of the deduced polypeptide sequence with the sequences of known threonine dehydratases revealed surprising differences from the C. glutamicum enzyme in the carboxy-terminal portion. This portion is greatly reduced in size, and a large gap of 95 amino acids must be introduced to achieve homology. Therefore, the C. glutamicum enzyme must be considered a small variant of threonine dehydratase that is typically controlled by isoleucine and valine but has an altered structure reflecting a topological difference in the portion of the protein most likely to be important for allosteric regulation.

Catabolite gene activator protein and integration host factor act in concert to regulate tdc operon expression in Escherichia coli

Anaerobic expression of the tdcABC operon of Escherichia coli requires cyclic AMP and the catabolite gene activator protein (CAP). Purified CAP binds to a 30-bp sequence in the tdc promoter between positions -55 and -26, and a mutant CAP site with base substitutions at positions -48, -47, and -45 failed to bind CAP and also drastically reduced the beta-galactosidase expression from a tdcB'-'lacZ fusion plasmid. Recently, we showed that efficient expression of the tdc operon also requires a functional integration host factor (IHF) and an IHF-binding site in the tdc promoter between positions -118 and -88. The levels of beta-galactosidase activity from the tdcB'-'lacZ fusion plasmids were also reduced in an IHF-deficient strain with the wild-type or mutant plasmid CAP sequence. In vitro footprinting experiments revealed that CAP and IHF occupy their specific binding sites on tdc DNA when they are present separately or together. These regulatory proteins also induced significant bending of the tdc promoter DNA. Our results suggest that CAP and IHF act in concert as positive transcription factors for tdc operon expression in vivo.

Serine and threonine catabolism in Saccharomyces cerevisiae: the CHA1 polypeptide is homologous with other serine and threonine dehydratases

The catabolic L-serine (L-threonine) dehydratase of Saccharomyces cerevisiae allows the yeast to grow on media with L-serine or L-threonine as sole nitrogen source. Previously we have cloned the CHA1 gene by complementation of a mutant, cha1, lacking the dehydratase activity. Here we present the DNA sequence of a 1,766-bp fragment of the CHA1 region encompassing an open reading frame of 1080 bp. Comparison of the predicted amino acid sequence of the CHA1 polypeptide with that of other serine/threonine dehydratases revealed several blocks of sequence homology. Thus, the amino acid sequence of rat liver serine dehydratase (SDH2) and the CHA1 polypeptide are 44% homologous allowing for conservative substitutions, while 36% similarity is found between the catabolic threonine dehydratase (tdcB) of Escherichia coli and the CHA1 protein. This strongly suggests that CHA1 is the structural gene for the yeast catabolic serine (threonine) dehydratase. S1-nuclease mapping of the CHA1 mRNA ends showed a major transcription initiation site corresponding to an untranslated leader of about 19 nucleotides, while a major polyadenylation site was located about 86 nucleotides downstream from the open reading frame. Furthermore, we have mapped the chromosomal position of the CHA1 gene to less than 0.5 kb centromere proximal to HML on the left arm of chromosome III.

Integration host factor is required for positive regulation of the tdc operon of Escherichia coli

A 14-bp segment in the promoter region of the tdcABC operon of Escherichia coli shows sequence identity with the consensus binding site for the E. coli integration host factor (IHF). In an himA (IHF-deficient) strain, expression of beta-galactosidase from a tdcB'-'lacZ protein fusion plasmid was about 10% of that seen with an isogenic himA+ strain. Threonine dehydratase activity from the chromosomal tdcB gene in the himA mutant was also about 10% of the wild-type enzyme level. Two different mutations introduced into the putative IHF-binding site in the fusion plasmid greatly reduced the plasmid-coded beta-galactosidase activity in cells containing IHF. In vitro gel retardation and DNase I footprinting analyses showed binding of purified IHF to the wild-type but not to the mutant promoter. IHF protected a 31-bp region between -118 and -88 encompassing the conserved IHF consensus sequence. These results suggest that efficient expression of the tdc operon in vivo requires a functional IHF and an IHF-binding site in the tdc promoter.

Physical linkage and transcriptional orientation of the tdc operon on the Escherichia coli chromosome

The physical and genetic structure of 37 kilobases of DNA encompassing the tdc region at 68.3 min of the Escherichia coli chromosome was determined by DNA sequence analysis and restriction mapping. Re-examination of new data concerning the direction of transcription of the tdc operon revealed that in strain W3110 the tdc region is located on a transposable segment of DNA.

Purification and properties of an iron-sulfur-containing and pyridoxal-phosphate-independent L-serine dehydratase from Peptostreptococcus asaccharolyticus

L-Serine dehydratase with a specific activity of 15 nkat/mg protein was present in the anaerobic eubacterium Peptostreptococcus asaccharolyticus grown either on L-glutamate or L-serine. The enzyme was highly specific for L-serine with the lowest Km = 0.8 mM ever reported for an L-serine dehydratase. L-Threonine (Km = 22 mM) was the only other substrate. V/Km for L-serine was 500 times higher than that for L-threonine. L-Cysteine was the best inhibitor (Ki = 0.3 mM, competitive towards L-serine). The enzyme was purified 400-fold to homogeneity under anaerobic conditions (specific activity 6 mukat/mg). PAGE in the presence of SDS revealed two subunits with similar intensities (alpha, 30 kDa; beta, 25 kDa). The molecular mass of the native enzyme was estimated as 200 +/- 20 kDa (gel filtration) and 180 kDa (gradient PAGE). In the absence of oxygen the enzyme was moderately stable even in the presence of sodium borohydride or phenylhydrazine (5 mM each). However, by exposure to air the activity was lost, especially when the latter agent was added. The enzyme was reactivated by ferrous ion under anaerobic conditions. The inability of several nucleophilic agents to inactivate the enzyme indicated the absence of pyridoxal phosphate. This was confirmed by a microbiological determination of pyridoxal phosphate. However, the enzyme contained 3.8 +/- 0.2 mol Fe and 5.6 +/- 0.3 mol inorganic sulfur/mol heterodimer (55 kDa) indicating the presence of an [Fe-S] center. The enzyme was successfully applied to measure L-serine concentrations in bacterial media and in human sera.

Biosynthetic threonine deaminase gene of tomato: isolation, structure, and upregulation in floral organs

The gene encoding the plant biosynthetic threonine deaminase (Td; EC 4.2.1.16) has been cloned as a result of its unusual upregulation in tomato flowers. The Td gene of tomato encodes a polypeptide of 595 residues, the first 80 of which comprise a putative two-domain transit peptide cleaved at position 51. Comparison of the amino acid sequence with the corresponding enzymes from yeast and bacteria reveals a near identity of the important catalytic regions and greater than 40% overall similarity. The Td gene is unique in the tomato genome and its coding region is interrupted by eight introns. Its expression is greater than 50-fold higher in sepals and greater than 500-fold higher in the rest of the flower than in leaves or roots. Its overexpression, however, is strictly confined to the parenchymal cells of the floral organs. In young tomato leaves, the chloroplast-bound enzyme is found almost exclusively in the subepidermal spongy mesophyll cells.

A novel membrane-associated threonine permease encoded by the tdcC gene of Escherichia coli

A novel L-threonine transport system is induced in Escherichia coli cells when incubated in amino acid-rich medium under anaerobic conditions. Genetic and biochemical analyses with plasmids harboring mutations in the anaerobically expressed tdcABC operon indicated that the tdcC gene product was responsible for L-threonine uptake. Competition experiments revealed that the L-threonine transport system is also involved in L-serine uptake and is partially shared for L-leucine transport; L-alanine, L-valine, and L-isoleucine did not affect L-threonine uptake. Transport of L-threonine was inhibited by the respiratory chain inhibitors KCN and carbonyl cyanide m-chlorophenylhydrazone and was Na+ independent. These results identify for the first time an E. coli gene encoding a permease specific for L-threonine-L-serine transport that is distinct from the previously described threonine-serine transport systems. A two-dimensional topological model predicted from the amino acid composition and hydropathy plot showed that the TdcC polypeptide appears to be an integral membrane protein with several membrane-spanning domains exhibiting a striking similarity with other bacterial permeases.

Yeast homoserine kinase. Characteristics of the corresponding gene, THR1, and the purified enzyme, and evolutionary relationships with other enzymes of threonine metabolism

THR1, the gene from Saccharomyces cerevisiae, encoding homoserine kinase, one of the threonine biosynthetic enzymes, has been cloned by complementation. The nucleotide sequence of a 3.1-kb region carrying this gene reveals an open reading frame of 356 codons, corresponding to about 40 kDa for the encoded protein. The presence of three canonical GCN4 regulatory sequences in the upstream flanking region suggests that the expression of THR1 is under the general amino acid control. In parallel, the enzyme was purified by four consecutive column chromatographies, monitoring homoserine kinase activity. In SDS gel electrophoresis, homoserine kinase migrates like a 40-kDa protein; the native enzyme appears to be a homodimer. The sequence of the first 15 NH2-terminal amino acids, as determined by automated Edman degradation, is in accordance with the amino acid sequence deduced from the nucleotide sequence. Computer-assisted comparison of the yeast enzyme with the corresponding activities from bacterial sources showed that several segments among these proteins are highly conserved. Furthermore, the observed homology patterns suggest that the ancestral sequences might have been composed from separate (functional) domains. A block of very similar amino acids is found in the homoserine kinases towards the carboxy terminus that is also present in many other proteins involved in threonine (or serine) metabolism; this motif, therefore, may represent the binding site for the hydroxyamino acids. Limited similarity was detected between a motif conserved among the homoserine kinases and consensus sequences found in other mono- or dinucleotide-binding proteins.

Analysis of the THR4 region on chromosome III of the yeast Saccharomyces cerevisiae

The gene encoding threonine synthase (THR4) from the yeast Saccharomyces cerevisiae was cloned by complementation of a thr4 mutant. This gene was also found on a lambda clone (5239) consisting of a fragment of chromosome III inserted in the vector lambdaMG3. The THR4 gene encodes a protein of 514 amino acids (M.W. 58 kDa), which has extensive homologies with E. coli threonine synthase (thrC) and B subtilis threonine synthase. The 5' flanking region of the gene contains three regulatory sequences [TGACT(C)] for the general amino acid control (GCN). About 130 bp downstream of the THR4 gene another large open reading frame (563 amino acids) is found in the opposite orientation. This may imply that this open reading frame, called CTR86, shares a terminator region with THR4. The function of the protein encoded by CTR86 is not yet clear, but the fact that the upstream region contains a GCN4 responsive site suggests that the gene product may also be involved in amino acid biosynthesis.

Linkage map of Escherichia coli K-12, edition 8

The linkage map of Escherichia coli K-12 depicts the arrangement of genes on the circular chromosome of this organism. The basic units of the map are minutes, determined by the time-of-entry of markers from Hfr into F- strains in interrupted-conjugation experiments. The time-of-entry distances have been refined over the years by determination of the frequency of cotransduction of loci in transduction experiments utilizing bacteriophage P1, which transduces segments of DNA approximately 2 min in length. In recent years, the relative positions of many genes have been determined even more precisely by physical techniques, including the mapping of restriction fragments and the sequencing of many small regions of the chromosome. On the whole, the agreement between results obtained by genetic and physical methods has been remarkably good considering the different levels of accuracy to be expected of the methods used. There are now few regions of the map whose length is still in some doubt. In some regions, genetic experiments utilizing different mutant strains give different map distances. In other regions, the genetic markers available have not been close enough to give accurate cotransduction data. The chromosome is now known to contain several inserted elements apparently derived from lambdoid phages and other sources. The nature of the region in which the termination of replication of the chromosome occurs is now known to be much more complex than the picture given in the previous map. The present map is based upon the published literature through June of 1988. There are now 1,403 loci placed on the linkage group, which may represent between one-third and one-half of the genes in this organism.