[Suicide attempts in epileptic patients during the years 1990-92. Analysis of patients in the Regional Poison Control Center in Sosnowiec]. / Próby samobójcze chorych na padaczke w latach 1990-92. Analiza chorych Regionalnego Osrodka Ostrych Zatruc w Sosnowcu.

During the years 1990-92 in the Regional Poisons Control Center in Sosnowiec 42 epileptics (20 females and 22 males) were hospitalized because of suicide attempt. It amounted to 9% of all attempters, treated there in this period. The majority of patients were males of age range from 21 to 62 years. In 23 patients the suicide attempts were performed for the first time. the main reason for suicide was the family conflicted situation. Additionally, in 14 patients the poisoning attempts have been done during alcohol abuse. In the suicide attempts the antiepileptic drugs were most frequently used, mainly carbamazepine (23 cases).

D-histidine utilization in Salmonella typhimurium is controlled by the leucine-responsive regulatory protein (Lrp).

A new class of D-histidine-utilizing mutants which carry mutations in the gene encoding the leucine-responsive regulatory protein (Lrp) has been identified in Salmonella typhimurium. The lrp mutations arise as suppressors of mutations in the genes encoding the histidine permease which drastically decrease the level of histidine transport activity. However, the suppressor effect is not exerted by elevating the level of the permease. Rather, the properties of the suppressor mutants are consistent with the notion that the parent permease mutants transport D-histidine at a low level and that in the suppressor mutants D-histidine is utilized effectively through elevated levels of racemization. The enzymatic activity of D-alanine dehydrogenase (Dad) is shown to be elevated in the suppressor mutants and is a possible pathway of D-histidine utilization. The suppressor mutations are located in the helix-turn-helix region of Lrp.

Organization and expression of the Escherichia coli K-12 dad operon encoding the smaller subunit of D-amino acid dehydrogenase and the catabolic alanine racemase.

A fragment of the Escherichia coli K-12 chromosome complementing the D-amino acid dehydrogenase and catabolic alanine racemase deficiency of a dad operon deletion mutant was cloned in a mini-Mu plasmid. The dadA and dadX genes were localized to a 3.5-kb part of the plasmid insert. The nucleotide sequence of this fragment revealed two open reading frames encoding 432- and 356-amino-acid-long proteins. We show here that they correspond to the dadA and dadX genes. The dadA gene can encode only the smaller of the two subunits of D-amino acid dehydrogenase. A computer search revealed the presence of a flavin adenine dinucleotide-binding motif in the N-terminal domain of the deduced DadA protein sequence. This is in agreement with biochemical data showing that the D-amino acid dehydrogenase contains flavin adenine dinucleotide in its active center. The predicted dadX gene product appeared to be 85% identical to a dadB-encoded catabolic alanine racemase of Salmonella typhimurium. The organization of the dadA and dadX genes confirmed our previous conclusion based on the genetic data (J. Wild, J. Hennig, M. Lobocka, W. Walczak, and T. Klopotowski, Mol. Gen. Genet. 198:315-322, 1985) that these genes form an operon. The main transcription start points of the dad operon were determined by primer extension. They are preceded by a putative sigma 70 promoter sequence and two cyclic AMP-cyclic AMP receptor protein (cAMP-CRP) binding sites, one of higher and one of lower affinity to CRP. We propose that the high-affinity site, centered 59.5 bp upstream of the main transcription start point, plays a role in cAMP-CRP-mediated activation of dad operon expression in the absence of glucose.

Two distinct types of mutations conferring to Escherichia coli K12 capability of D-tryptophan utilization.

We showed that the ability of Escherichia coli K12 tryptophan auxotrophs to utilize D-tryptophan as a substitute for L-tryptophan may result from two types of mutations. The first type consisted in changes in the dadR regulatory site of the dad operon increasing the synthesis of D-amino acid dehydrogenase. The mutations of the second type mapped within the dad A structural gene. They changed the apparent substrate specificity of D-amino acid dehydrogenase. We suppose that the change may be due to an altered enzyme structure which make it more accessible to D-tryptophan.

A quantitative model for nonrandom generalized transduction, applied to the phage P22-Salmonella typhimurium system.

A mathematical model for nonrandom generalized transduction is proposed and analyzed. The model takes into account the finite number of transducing particle classes for any given marker. The equations for estimation of the distance between markers from contransduction frequency data are derived and standard errors of the estimates are given. The obtained relationships depend significantly on the number of classes of transducing fragments. The model was applied to estimate the number of transducing fragment classes for a given marker in transduction with phage P22 of Salmonella typhimurium. It was found that the literature data on frequencies of contransduction in crosses with mutual substitution of selective and nonselective markers can be rationalized most accurately by assuming that the mean number of classes is equal to 2. An improved method for analysis of cotransduction data is proposed on the basis of our model and the results of calculation. The method relies on solving a set of algebraic equations for cotransduction frequencies of markers located within one phage length. The method allows a relatively precise determination of distances between markers, positions of transducing particle ends and deletion or insertion lengths. The approach is applied to the trp-cysB-pyrF and aroC-hisT-purF-dhuA regions of the Salmonella typhimurium chromosome.

The Hfr status of Pseudomonas aeruginosa is stabilized by integrative suppression.

A temperature-sensitive mutant (dna-11) with the phenotype of a mutant defective in the initiation of DNA replication, was isolated from an Hfr-like FP2 donor of Pseudomonas aeruginosa. Reversion of its temperature-sensitive character was achieved by integrative suppression rather than by backmutation or an additional suppressor mutation. The dna-11 mutant proved to be helpful in stabilizing the Hfr status of the original host.

Identification of the dadX gene coding for the predominant isozyme of alanine racemase in Escherichia coli K12.

Evidence is presented that alanine racemase activity in E. coli K12 is due to two distinct gene products. The predominant isozyme is inducible by either alanine stereoisomer and repressible by glucose. The gene dadX coding for its structure is located by the dadA gene determining the structure of D-amino acid dehydrogenase. The regulatory site for the expression of both genes, dadR, is located on the other side of dadA. The orientation of the dad operon established by multiple-point crosses and deletion mapping is as follows: fadR ...dadRAX ...hemA. The dadX alanine racemase activity is unusually refractory to changes of incubation temperature. It differs strikingly from that of the other isozyme, probably the product of the alr gene. The latter isozyme shows a typical dependence upon incubation temperature. The synthesis of alr alanine racemase is constitutive in respect of both alanine and glucose. In dadX mutants, in which alanine racemase activity equals only 15% of that in wild-type cells grown in the absence of an inducer or catabolite repressor, the dad operon cannot be induced by D-alanine. We presume, therefore, that L-alanine is involved more directly than D-alanine in dad operon regulation.

D-Amino acid dehydrogenase of Escherichia coli K12: positive selection of mutants defective in enzyme activity and localization of the structural gene.

A method for the positive selection of dadA mutants defective in D-amino acid dehydrogenase has been devised. It consists in isolating mutants resistant to beta-chloro-D-alanine and screening for mutant colony color on a special agar medium. All 70 Escherichia coli K12 dadA mutants isolated either by this method or by other selection procedures map at a locus which is near to hemA and closely linked with dadR. Since some of the dadA mutants are thermosensitive in D-methionine utilization in vivo and have thermolabile D-amino acid dehydrogenase in vitro, it is proposed that the dadA gene codes for the enzyme structure. The broad substrate specificity, apparent membrane localization, inducibility by alanine, and repressibility by glucose strongly suggest that the D-amino acid dehydrogenase coded by the dadA gene is a species variant of the enzyme described under the same name in Salmonella typhimurium. It may be identical or homologous with the enzymes described under the names alaninase, D-alanine oxidase or D-alanine dehydrogenase in E. coli K12 or B.

Involvement of the L-cysteine biosynthetic pathway in azide-induced mutagenesis in Salmonella typhimurium.

L-Cystine and L-cysteine specifically reverse the mutagenic action of azide in Salmonella typhimurium and Escherichia coli. To establish whether the L-cysteine biosynthetic pathway is involved in azide-induced mutagenesis, several derivatives of a mutagen tester-strain of S. typhimurium bearing mutations in different cys genes were isolated. No mutagenic effect of azide was observed in a strain carrying mutation in the cysE gene, unless the incubation medium was supplemented with exogenous O-acetylserine. Our of 16 cysK mutants 14 were mutagenized by azide very poorly or not at all. These results indicate that the activity of O-acetylserine sulfhydrylase A, and the availability of O-acetylserine, one of the two co-substrates of the enzyme, are essential for the mutagenic action of azide in S. typhimurium.

Altered linkage values in phage P22--mediated transduction caused by distant deletions or insertions in donor chromosomes.

The effects of distant deletions or insertions in the Salmonella typhimurium donor strains on P22--mediated cotransducibility of genetic markers was studied. We found that deletions of histidine operon, unit 44 of the chromosome map, changed the linkage of markers purF and aroC (unit 49) and pyrF and trpA (unit 34). They did not change the linkage of more distant markers pyrE and cysE. The effect of three types of insertions was examined. The donor strains carried F factor, Tn10 transposon or pi-his duplication inserted close to histidine operon. These insertions caused alteration of purF-aroC linkage while pyrF-trpA cotransduction values were not affected. These data show that the effect of the chromosome rearrangements extends to at least 5% of S. typhimurium chromosome length and may reach as much as 10% of it. Our results are in agreement with the model of Chelala and Margolin (1974) concerning formation of transduction particles. They indicate that the cotransducibility changes caused by deletions or insertions extent further than it might have been expected from previous reports.

Methionine transport in Salmonella typhimurium: evidence for at least one low-affinity transport system.

The systems which transport methionine in Salmonella typhimurium LT2 have been studied. Fourteen mutants, isolated by three different selection procedures, had similar growth characteristics and defects in the specific transport process showing a Km of 0.3 microM for L-methionine, and therefore lack the high-affinity, metP transport system. The sites of mutation in four of the mutants were shown by P1-mediated transduction to be linked (0.3 to 1.1%) with a proline marker located at unit 7 on the S. typhimurium chromosome. The high-affinity system was subject to both repression and transinhibition by methionine, and it may also be regulated by the metJ and metK genes. There appeared to be at least two additional transport systems with relatively low affinities for methionine in the metP763 mutant strain, with apparent Km values for methionine of 24 microM and approximately 1.8 mM. The latter system, with a very low affinity for methionine, was inhibited by leucine. In addition, methionine inhibited leucine transport, suggesting that one of the low-affinity methionine transport systems may actually be a leucine transport system.

Azide-induced mutagenesis in gram-negative bacteria is recA-and lexA-independent.

Azide-induced mutagenesis was investigated in Salmonella typhimurium and Escherichia coli. Azide was highly effective in inducing mutation in uvrB, uvrB recA and uvrB recB mutants of S. typhimurium. The mutagenic effect of azide was also observed in uvrA lexA mutants of E. coli K12 and E. coli B/r. These results suggest that azide-induced mutagenesis is due to mis-replication of DNA.

Interference of azide with cysteine biosynthesis in Salmonella typhimurium.

The growth inhibition of Salmonella typhimurium aziA mutants by sodium azide is reversed by cystine and related compounds. NADPH-sulphite reductase (hydrogen-sulphide:NADP+ oxidoreductase; EC 1.8.1.2), an enzyme of cysteine biosynthesis, is inhibited in cell extracts by sodium azide. AziB mutants which are able to grow in the presence of the inhibitor without cystine were isolated. About half of them were mapped in the cysK gene and have only residual activity of its product, O-acetylserine sulphydrylase A [O-acetyl-L-serine acetate-lyase (adding hydrogen-sulphide); EC 4.2.99.8]. Sensitivity of wild type and aziA mutants to azide was also reversed by a constitutive mutation in cysB, the regulatory gene of cysteine biosynthesis. CysK and cysB mutants showed cross-resistance to azide and 1,2,4-triazole. It is suggested that the resistance of these mutants to azide is due to an increased activity of NADPH-sulphite reductase.

The smoB mutation suppressing cell filamentation and ability to support the multiplication of phage P22 in Salmonella typhimurium.

Isolation and properties of a Salmonella typhimurium mutant smoB are described. The mutation maps at unit 99 of the S. typhimurium chromosome between pyrB and deoC. It suppresses cell filamentation and temperature sensitivity of histidine-constitutive mutants, but does not restore the normal regulatory pattern to the histidine operon. Strains carrying the mutation have greatly reduced ability to support the growth of phage P22, but not of ES18 or Felix O.

Utilization of D-amino acids by dadR mutants of Salmonella typhimurium.

Utilization of D-amino acids being substrates of D-amino acid dehydrogenase of Salmonella typhimurium was examined. The experiments were done with wild type strains and the mutants dadA missing the enzyme activity and dadR in which its synthesis is released from catabolite repression. Growth on D-tryptophan, D-histidine and D-methionine used as precursors of the L-amino acids was faster when the respective auxotrophs carried dadR mutations. The dadR mutants grew faster when D-or L-alanine was present as a sole source of nitrogen. Experiments with D-amino acid dehydrogenase in vitro provided evidence that D-tryptophan is its substrate with a very low affinity to the dehydrogenase.

Insensitivity of D-amino acid dehydrogenase synthesis to catabolic repression in dadR mutants of Salmonella typhimurium.

It has been found that synthesis of D-amino acid dehydrogenase in Salmonella typhimurium is stimulated by cyclic AMP and crp gene product. This indicates that catabolic control of the dehydrogenase resembles other bacterial systems of catabolic repression. We have isolated S. typhimurium mutants, dadR, which are resistant to L-methionine-interference with D-histidine utilization and are able to utilize D-tryptophan as a precursor of L-tryptophan. Mapping data indicate that the dadR locus is closely linked to dadA coding for the structure of D-amino acid dehydrogenase. The synthesis of the dehydrogenase in dadR mutants is completely insensitive to the repression by glucose, but remains inducible by L-alanine. We conclude thereof that dadR mutants have changes in the promoter region which increase the expression of the dadA gene in the presence of glucose metabolism. A likely possibility that induction of the dad operon by alanine might be under positive control is discussed.

Regulation of the pool size of valine in Escherichia coli K-12.

Three mutations (ilvH611, ilvH612, and ilvH613) are described which make Escherichia coli K-12 resistant to valine inhibition and are located near leu. The expression of the ilv genes appears to be normal in these mutants since the isoleucine-valine biosynthetic enzymes are not derepressed relative to the wild type. The intracellular concentration of valine is, however, higher in the mutants than in the isogenic ilvH(+) strain. These mutants also excrete valine, probably because of the high intracellular concentration of this amino acid. The pool size of valine is regulated independently from that of isoleucine and leucine. The increased intracellular concentration of valine is due to a decreased feedback inhibition that valine exerts on its own biosynthetic pathway. In fact, acetolactate synthase activity assayed in extracts of ilvH612 and ilvH613 mutants is more resistant to valine inhibition than the activity assayed in the ilvH(+) isogenic strain. Two forms of acetolactate synthase activity can be separated from these extracts by adsorption and elution on hydroxylapatite. One of them is as sensitive to valine inhibition as that of the wild type, the other is more resistant to valine inhibition.

Multiplicity of isoleucine, leucine, and valine transport systems in Escherichia coli K-12.

The kinetics of isoleucine, leucine, and valine transport in Escherichia coli K-12 has been analyzed as a function of substrate concentration. Such analysis permits an operational definition of several transport systems having different affinities for their substrates. The identification of these transport systems was made possible by experiments on specific mutants whose isolation and characterization is described elsewhere. The transport process with highest affinity was called the "very-high-affinity"process. Isoleucine, leucine, and valine are substrates of this transport process and their apparent K(m) values are either 10(-8), 2 x 10(-8), or 10(-7) M, respectively. Methionine, threonine, and alanine inhibit this transport process, probably because they are also substrates. The very-high-affinity transport process is absent when bacteria are grown in the presence of methionine, and this is due to a specific repression. Methionine and alanine were also found to affect the pool size of isoleucine and valine. Another transport process is the "high-affinity" process. Isoleucine, leucine, and valine are substrates of this transport process, and their apparent K(m) value is 2 x 10(-6) M for all three. Methionine and alanine cause very little or no inhibition, whereas threonine appears to be a weak inhibitor. Several structural analogues of the branched-chain amino acids inhibit the very-high-affinity or the high-affinity transport process in a specific way, and this confirms their existence as two separate entities. Three different "low-affinity" transport processes, each specific for either isoleucine or leucine or valine, show apparent K(m) values of 0.5 x 10(-4) M. These transport processes show a very high substrate specificity since no inhibitor was found among other amino acids or among many branched-chain amino acid precursors or analogues tried. The evolutionary significance of the observed redundancy of transport systems is discussed.

Mutations affecting the different transport systems for isoleucine, leucine, and valine in Escherichia coli K-12.

Uptake of isoleucine, leucine, and valine in Escherichia coli K-12 is due to several transport processes for which kinetic evidence has been reported elsewhere. A very-high-affinity transport process, a high-affinity transport process, and three different low-affinity transport processes were described. In this paper the existence of these transport processes is confirmed by the isolation and preliminary characterization of mutants altered in one or more of them. The very-high-affinity transport process is missing either in strains carrying the brnR6(am) mutation or in strains carrying the brn-8 mutation. This appears to be a pleiotropic effect since other transport systems are also missing. Mutant analysis shows that more than one transport system with high affinity is present. One of them, high-affinity 1, which needs the activity of a protein produced by the brnQ gene, transports isoleucine, leucine, and valine and is unaffected by threonine. The other, high-affinity 2, which needs the activity of a protein produced by the brnS gene, transports isoleucine, leucine, and valine; this uptake is inhibited by threonine which probably is a substrate. Another protein, produced by the brnR gene, is required for uptake through both high-affinity 1 and high-affinity 2 transport systems. The two systems therefore appear to work in parallel, brnR being a branching point. The brnQ gene is located close to phoA at 9.5 min on the chromosome of E. coli, the brnR gene is located close to lac at 9.0 min, and the brnS gene is close to pdxA at 1 min. A mutant lacking the low-affinity transport system for isoleucine was isolated from a strain in which the high-affinity system was missing because of a brnR mutation. This strain also required isoleucine for growth because of an ilvA mutation. The mutant lacking the low-affinity transport system was unable to grow on isoleucine but could grow on glycylisoleucine. This mutant had lost the low-affinity transport for isoleucine, whereas those for leucine and valine were unaffected. A pleiotropic consequence of this mutation (brn-8) was a complete absence of the very-high-affinity transport system due either to the alteration of a common gene product or to any kind of secondary interference which inhibits it. Mutants altered in isoleucine-leucine-valine transport were isolated by taking advantage of the inhibition that valine exerts on the K-12 strain of E. coli. Mutants resistant both to valine inhibition (Val(r)) and to glycylvaline inhibition are regulatory mutants. Val(r) mutants that are sensitive to glycylvaline inhibition are transport mutants. When the very-high-affinity transport process is repressed (for example by methionine) the frequency of transport mutants among Val(r) mutants is higher, and it is even higher if the high-affinity transport process is partially inhibited by leucine.