A restriction enzyme cleavage map of the histidine utilization (hut) genes of Klebsiella aerogenes and deletions lacking regions of hut DNA

Friedel-Crafts-type mechanism for the enzymatic elimination of ammonia from histidine and phenylalanine

The surprisingly high catalytic activity and selectivity of enzymes stem from their ability to both accelerate the target reaction and suppress competitive reaction pathways that may even be dominant in the absence of enzymes. For example, histidine and phenylalanine ammonia-lyases (HAL and PAL) trigger the abstraction of the nonacidic beta protons of these amino acids while leaving the much more acidic ammonium hydrogen atoms untouched. Both ammonia-lyases have a catalytically important electrophilic group, which was believed to be dehydroalanine for 30 years but has now been revealed by X-ray crystallography and UV spectroscopy to be a highly electrophilic 5-methylene-3,5-dihydroimidazol-4-one (MIO) group. Experiments suggest that the reaction is initiated by the electrophilic attack of MIO on the aromatic ring of the substrate. This incomplete Friedel-Crafts-type reaction leads to the activation of a beta proton and its stereospecific abstraction, followed by the elimination of ammonia and regeneration of the MIO group. The plausibility of such a mechanism is supported by a synthetic model. The application of the PAL reaction in the biocatalytic synthesis of enantiomerically pure alpha-amino beta-aryl propionates from aryl acrylates is also discussed.

Methylidene-imidazolone: a novel electrophile for substrate activation

The recent three-dimensional structure of histidine ammonia-lyase revealed that the enzyme contains a 3,5-dihydro-5-methylidene-4H-imidazol-4-one (MIO) ring, which forms autocatalytically from an Ala-Ser143-Gly triad. This novel prosthetic group, which is also present in phenylalanine ammonia-lyase, activates substrates by electrophilic interaction. Modern analytical methods, theoretical calculations and molecular biology tools have given further insight into the mode of action of MIO.

The nitrogen assimilation control protein, NAC, is a DNA binding transcription activator in Klebsiella aerogenes

A 32-kDa polypeptide corresponding to NAC, the product of the Klebsiella aerogenes nac gene, was overexpressed from a plasmid carrying a tac'-'nac operon fusion and purified to near homogeneity by taking advantage of its unusual solubility properties. NAC was able to shift the electrophoretic migration of DNA fragments carrying the NAC-sensitive promoters hutUp, putPp1, and ureDp. The interaction between NAC and hutUp was localized to a 26-bp region centered approximately 64 bp upstream of the hutUp transcription initiation site. Moreover, NAC protected this region from DNase I digestion. Mobility shift and DNase I protection studies utilizing the putP and ureD promoter regions identified NAC-binding regions of sizes and locations similar to those found in hutUp. Comparison of the DNA sequences which were protected from DNase I digestion by NAC suggests a minimal NAC-binding consensus sequence: 5'-ATA-N9-TAT-3'. In vitro transcription assays demonstrated that NAC was capable of activating the transcription of hutUp by sigma 70-RNA polymerase holoenzyme when this promoter was presented as either a linear or supercoiled DNA molecule. Thus, NAC displays the in vitro DNA-binding and transcription activation properties which have been predicted for the product of the nac gene.

Identification of the hutUH operator (hutUo) from Klebsiella aerogenes by DNA deletion analysis

Expression of Klebsiella aerogenes histidine utilization operons hutUH and hutIG is negatively regulated by the product of hutC. Multiple copies of the hutUH promoter region [hut(P)] present in trans were able to titrate the limited amount of host-encoded hut repressor (HutC). Thus, the hut(P) region contains a specific binding site for HutC. To identify DNA sequences required for HutC titration, we constructed and characterized a set of 40 left-entering and 28 right-entering deletions within a 250-bp DNA sequence containing the hut(P) region. Mutants carrying deletions that altered a unique dyad symmetric sequence, ATGCTTGTATAGACAAGTAT, from -11 to -30 relative to the hutUH promoter (hutUp) were unable to titrate hut repressor; mutants carrying deletions that left this sequence intact retained their ability to titrate hut repressor. Thus, we identify ATGCTTGT ACAAGTAT as the hutUH operator.

Cloning and sequencing the urocanase gene (hutU) from Pseudomonas putida

A clone harbouring the entire urocanase gene (hutU) was obtained from a genomic library of Pseudomonas putida using oligonucleotide probes synthesised on the basis of known flanking sequences. One subunit of urocanase consists of 556 amino acids and has a molecular mass of 60,771 Da.

Tn1000-mediated insertion mutagenesis of the histidine utilization (hut) gene cluster from Klebsiella aerogenes: genetic analysis of hut and unusual target specificity of Tn1000

The histidine utilization (hut) genes from Klebsiella aerogenes were cloned in both orientations into the HindIII site of plasmid pBR325, and the two resulting plasmids, pCB120 and pCB121, were subjected to mutagenesis with Tn1000. The insertion sites of Tn1000 into pCB121 were evenly distributed throughout the plasmid, but the insertion sites into pCB120 were not. There was a large excess of Tn1000 insertions in the "plus" or gamma delta orientation in a small, ca. 3.5-kilobase region of the plasmid. Genetic analysis of the Tn1000 insertions in pCB120 and pCB121 showed that the hutUH genes form an operon transcribed from hutU and that the hutC gene (encoding the hut-specific repressor) is independently transcribed from its own promoter. The hutIG cluster appears not to form an operon. Curiously, insertions in hutI gave two different phenotypes in complementation tests against hutG504, suggesting either that hutI contains two functionally distinct domains or that there may be another undefined locus within the hut cluster. The set of Tn1000 insertions allowed an assignment of the gene boundaries within the hut cluster, and minicell analysis of the polypeptides expressed from plasmids carrying insertions in the hut genes showed that the hutI, hutG, hutU, and hutH genes encode polypeptides of 43, 33, 57, and 54 kilodaltons, respectively.

Nucleotide sequence of the gene encoding the repressor for the histidine utilization genes of Klebsiella aerogenes

The hutC gene of Klebsiella aerogenes encodes a repressor that regulates expression of the histidine utilization (hut) operons. The DNA sequence of a region known to contain hutC was determined and shown to contain two long rightward-reading open reading frames (ORFs). One of these ORFs was identified as the 3' portion of the hutG gene. The other ORF was the hutC gene. The repressor predicted from the hutC sequence contained a helix-turn-helix motif strongly similar to that seen in other DNA-binding proteins, such as lac repressor and the catabolite gene activator protein. This motif was located in the N-terminal portion of the protein, and this portion of the protein seemed to be sufficient to allow repression of the hutUH operon but insufficient to allow interaction with the inducer. The presence of a promoterlike sequence and a ribosome-binding site immediately upstream of the hutC gene explained the earlier observation that hutC can be transcribed independently of the other hut operon genes. The predicted amino acid sequence of hut repressor strongly resembled that of the corresponding protein from Pseudomonas putida (S. L. Allison and A. T. Phillips, J. Bacteriol. 172:5470-5476, 1990). An unexpected, leftward-reading ORF extending from about the middle of hutC into the preceding (hutG) gene was also detected. The deduced amino acid sequence of this leftward ORF was quite distinct from that of an unexpected ORF of similar size found immediately downstream of the P. putida hutC gene. The nonstandard codon usage of this leftward ORF and the expression of repressor activity from plasmids with deletions in this region made it unlikely that this ORF was necessary for repressor activity.

Organization and multiple regulation of histidine utilization genes in Pseudomonas putida

The arrangement of the histidine utilization (hut) genes in Pseudomonas putida was established by examining the structure of a DNA segment that had been cloned into Escherichia coli via a cosmid vector. Southern blot analysis revealed that the restriction patterns of the hut genes cloned into E. coli and present in the P. putida genome were identical, indicating that no detectable DNA rearrangement took place during the cloning. Expression of the hut genes from a series of overlapping clones indicated the gene order to be hutG-hutI-hutH-hutU-hutC-hutF. The transcription directions of the different hut genes were determined by cloning the genes under control of the lambda pL promoter. This showed that hutF, encoding formiminoglutamate hydrolase, was transcribed in a direction opposite to that of the other genes. Inactivation of the cloned hut genes by Tn1000 insertion revealed that the hut genes were divided into three major transcriptional units (hutF, hutC [the repressor gene], and hut UHIG), but hutG may also be independently transcribed. When cloned individually with hutC on the same vector, hutF and hutU (which encodes urocanase) expression was induced by urocanate, indicating that these two genes each possess an operator-promoter element. Tn1000 insertions (in the cloned genes) or Tn5 insertions (in the P. putida genome) affecting the hutI or hutH gene only partially eliminated hutG expression. Furthermore, hutG, which specifies N-formylglutamate amidohydrolase, was regulated by the hutC product when the two genes were cloned on the same vector and expressed in E. coli. Therefore, hutG can be expressed independently from its own promoter, in keeping with earlier observations that N-formylglutamate amidohydrolase synthesis is not coordinated with that of urocanase and histidase and can be induced by N-formylglutamate or urocanate.

Cloning and nucleotide sequences of histidase and regulatory genes in the Bacillus subtilis hut operon and positive regulation of the operon

An 8-kilobase HindIII fragment carrying the histidase gene (hutH) and its regulatory region (hutP), from the Bacillus subtilis histidine utilization (hut) operon, was cloned in the temperate bacteriophage phi 105. Histidine utilization was restored in a hutH1 mutant by the specialized transducing phage (phi 105hutH11). The histidase gene in phi 105hutH11 was inducible and was shown to be under catabolite repression. The nucleotide sequence of 3,932 base pairs including the hutH and hutP loci revealed three open reading frames (ORFs). The molecular weights of ORF1 and ORF2 proteins were calculated to be 16,576 (151 amino acid residues) and 55,675 (508 amino acid residues), respectively. Reverse transcriptase mapping experiments showed that the putative promoter for the hut operon could be recognized by RNA polymerase sigma 43. The transcript starts at an adenosine residue 32 base pairs upstream from the initiation codon of ORF1. hutH+-transforming activity was found in ORF2, indicating that ORF2 encoded the histidase. A hutP1 mutation was determined as a substitution of an amino acid in ORF1. By using a specialized transducing phage containing the wild-type ORF1 gene, it was demonstrated that the presence of ORF1 protein in trans was absolutely required for the induction of the hut operon in a hutP1 mutant. These data strongly suggested that ORF1 encodes a positive regulator of the hut operon.

Bidirectional promoter in the hut(P) region of the histidine utilization (hut) operons from Klebsiella aerogenes

The hut(P) region (i.e., the region responsible for regulation of hutUH expression) of the Klebsiella aerogenes histidine utilization (hut) operons contains a bidirectional promoter. One transcript from this promoter encodes the hutUH operon; the role of the oppositely directed transcript is unknown, although it appears to be involved in regulating hutUH expression (A.J. Nieuwkoop, S.A. Boylan, and R.A. Bender, J. Bacteriol. 159:934-939, 1984). A 247-base-pair (bp) fragment containing hut(P) carries two RNA-polymerase-binding sites agree with the start sites of the two transcripts produced from hut(P) DNA in vitro and in vivo. The binding sites share a 4-bp region, suggesting that occupancy of the regulatory site precludes occupancy of the hutUH promoter, and vice versa. In the absence of positive effectors, the binding to the site responsible for hutUH transcription is weaker than the binding to the site responsible for regulation. The nucleotide sequence of the 250-bp fragment containing hut(P) contains two possible matches to the consensus sequence for Escherichia coli promoters, a better and worse match, corresponding in position to the stronger and weaker RNA-polymerase-binding sites, respectively. The sequence also contains a region similar to the consensus sequence for binding of the catabolite gene activator protein of E. coli. A sequence similar to the consensus for Ntr-dependent promoters was also found, overlapping both RNA-polymerase-binding sites, but it is not a functional promoter. Finally, an initiation codon preceded by a Shine-Dalgarno consensus sequence and followed by an open reading frame identifies a probable start of the hutU gene coding sequences.

Regulatory region of the divergent Klebsiella pneumoniae lac operon

The chromosomal DNA that lies between the lacI and lacZ genes of Klebsiella pneumoniae constitutes a 196-base pair intercistronic region that contains regulatory sequences for both genes. The probable locations of specific regulatory elements for both lacI and lacZ genes were determined by analogy with the corresponding Escherichia coli sequences. A recombinational event in ancestral DNA evidently has inverted the transcriptional direction of lacI in K. pneumoniae relative to the transcriptional direction of lacI in E. coli. One end of the inversion was located within a 19-base pair sequence in the K. pneumoniae regulatory region. Sequences partially homologous to these 19 base pairs were found in two locations on either side of the E. coli lacI gene. The nucleotide sequence of the lac regulatory region in K. pneumoniae exhibits more than one possibility for folded tertiary structures. The spatial relationships of transcriptional binding sites differ in two possible structures. Associations of regulatory and transcriptional proteins with the DNA might affect conformation of the regulatory sequences and, as a consequence, transcription of the lac genes.

Cloning and expression in Escherichia coli of histidine utilization genes from Pseudomonas putida

A library of the Pseudomonas putida chromosome, prepared through the use of the cosmid pJB8 ligated to a partial Sau3A digest of bacterial DNA, followed by in vitro packaging into bacteriophage lambda particles, was used to construct a strain of Escherichia coli which contained the genes for histidine utilization. This isolate produced a repressor product and all five enzymes required in Pseudomonas spp. for histidine dissimilation, whereas none of these could be detected in the nontransduced parent E. coli strain. When this transductant was grown on various media containing histidine or urocanate as the inducer, it was observed that production of the cloned histidine degradative enzymes was influenced somewhat by the choice of nitrogen source used but not by the carbon source. The recombinant cosmid was isolated and found to consist of 21.1 kilobase pairs of DNA, with approximately 16 kilobase pairs derived from Pseudomonas DNA and the remainder being from the pJB8 vector. Digestion of this insert DNA with EcoRI provided a 6.1-kilobase-pair fragment which, upon ligation in pUC8 and transformation into an E. coli host, was found to encode histidine ammonia-lyase and urocanase. The inducible nature of this production indicated that the hut repressor gene also was present on this fragment. Insertional inactivation of the histidine ammonia-lyase and urocanase genes by the gamma-delta transposon has permitted location of these structural genes and has provided evidence that transcription proceeds from urocanase through histidine ammonia-lyase. Mapping of the 16-kilobase-pair Pseudomonas DNA segment with restriction enzymes and subcloning of additional portions, one of which contained the gene for formiminoglutamate hydrolase and another that could constitutively express activities for both imidazolone propionate hydrolase and formylglutamate hydrolase, has provided evidence for the organization of all hut genes.

In vivo synthesis of histidine by a cloned histidine ammonia-lyase in Escherichia coli

Histidine ammonia-lyase catalyzes the first step in histidine catabolism, the deamination of histidine to urocanate and ammonia. In vitro experiments have shown that histidine ammonia-lyase also can catalyze the reverse (amination) reaction, histidine synthesis, relatively efficiently under extreme reaction conditions (4 M NH4OH, pH 10). An Escherichia coli hisB deletion strain was transformed with a pBR322 derivative plasmid (pCB101) containing the entire Klebsiella aerogenes histidine utilization (hut) operon to determine whether the catabolic histidine ammonia-lyase could function biosynthetically in vivo to satisfy the histidine auxotrophy. Although the initial construct did not grow on media containing urocanate and ammonia as a source of histidine, spontaneous mutants possessing this ability were isolated. Four mutants characterized grew at doubling times of 4 h compared with 1 h when histidine was present, suggesting that histidine synthesis, although unequivocally present, remained growth limiting. Each mutant contained a plasmid-encoded mutation which eliminated urocanase activity, the second enzyme in the Hut catabolic pathway. This genetic block led to the accumulation of high intracellular levels of urocanate, which was subsequently converted to histidine via histidine ammonia-lyase, thus satisfying the histidine auxotrophic requirement.

Regulation of hutUH operon expression by the catabolite gene activator protein-cyclic AMP complex in Klebsiella aerogenes

RNA polymerase transcribed the hutUH operon of Klebsiella aerogenes if the catabolite gene activator protein (CAP) and cyclic AMP (cAMP) were present or if the DNA template was derived from a promoter mutant in which hutUH expression was independent of the need for positive effectors. In the absence of CAP or cAMP, not only was hutUH transcription absent, but transcription in the opposite direction (toward hutC) was initiated at a site (pC) ca. 70 base pairs from the site (pUH) of hutUH mRNA initiation. When the pC promoter was cloned in front of a promoterless galK gene, active expression of galK was observed. Thus, the pC promoter is active in vivo as well as in vitro. Transcription from pUH and pC may be mutually exclusive, with the major effect of CAP and cAMP being to prevent transcription from pC, thus relieving the antagonistic effect on transcription from pUH. This "double-negative" control by CAP-cAMP is supported by two observations: (i) CAP-cAMP was unable to activate transcription from pUH if RNA polymerase had been previously bound to pC and (ii) a mutation that allowed transcription from pUH in the absence of positive effectors simultaneously eliminated the activity of pC. An alternative model, in which CAP-cAMP is required for pUH expression and RNA polymerase binding at pC serves to modulate this control in some unknown way, is also considered. The physiological role of the transcript from pC other than regulation of pUH is unknown.

Genetic and physical maps of Klebsiella aerogenes genes for histidine utilization (hut)

Deletion derivatives of the hut-containing plasmid pCB101 were tested against point mutants defective in individual genes of the histidine utilization (hut) operons using a complementation/recombination assay. Location of the genes of the right operon, hutU and hutH, was confirmed by direct assay of the gene products, urocanase and histidase; location of the repressor gene was identified by measuring the ability of the plasmid-carried genes to repress the formation of histidase from a chromosomal location. The analysis of eight deletion plasmids unambiguously confirms the map order of the hut genes as hutI-G-C-U-H, and demonstrates that, in Klebsiella aerogenes, the hutU and hutH genes are transcribed from their own promoter. In addition, the genetic map of hut can be aligned with the restriction map of the hut DNA in plasmid pCB101. One of the deletion plasmids studied apparently encodes a defective histidase subunit that is trans-dominant to active histidase. Another deletion, which completely removes the left operon, hutIG, allows high level expression of the hutUH operon and thus overproduction of a toxic intermediate.