HemA Protein Research Articles

A purified mutant HemA protein from Salmonella enterica serovar Typhimurium lacks bound heme and is defective for heme-mediated regulation in vivo

Archaea, plants, and most bacteria synthesize heme using the C5 pathway, in which the first committed step is catalyzed by the enzyme glutamyl-tRNA reductase (GluTR or HemA). In some cases, an overproduced and purified HemA enzyme contains noncovalently bound heme. The enteric bacteria Salmonella enterica and Escherichia coli also synthesize heme by the C5 pathway, and the HemA protein in these bacteria is regulated by proteolysis. The enzyme is unstable during normal growth due to the action of Lon and ClpAP, but becomes stable when heme is limiting for growth. We describe a method for the overproduction of S. enterica HemA that yields a purified enzyme containing bound heme, identified as a b-type heme by spectroscopy. A mutant of HemA (C170A) does not contain heme when similarly purified. The mutant was used to test whether heme is directly involved in HemA regulation. When expressed from the S. enterica chromosome in a wild-type background, the C170A mutant allele of hemA is shown to confer an unregulated phenotype, with high levels of HemA regardless of the heme status. These results strongly suggest that the presence of bound heme targets the HemA enzyme for degradation and is required for normal regulation.

The Molecular Chaperone, ClpA, Has a Single High Affinity Peptide Binding Site per Hexamer

Substrate recognition by Clp chaperones is dependent on interactions with motifs composed of specific peptide sequences. We studied the binding of short motif-bearing peptides to ClpA, the chaperone component of the ATP-dependent ClpAP protease of Escherichia coli in the presence of ATPgammaS and Mg2+ at pH 7.5. Binding was measured by isothermal titration calorimetry (ITC) using the peptide, AANDENYALAA, which corresponds to the SsrA degradation motif found at the C terminus of abnormal nascent polypeptides in vivo. One SsrA peptide was bound per hexamer of ClpA with an association constant (K(A)) of 5 x 10(6) m(-1). Binding was also assayed by changes in fluorescence of an N-terminal dansylated SsrA peptide, which bound with the same stoichiometry of one per ClpA hexamer (K(A) approximately 1 x 10(7) m(-1)). Similar results were obtained when ATP was substituted for ATPgammaS at 6 degrees C. Two additional peptides, derived from the phage P1 RepA protein and the E. coli HemA protein, which bear different substrate motifs, were competitive inhibitors of SsrA binding and bound to ClpA hexamers with K(A)' > 3 x 10(7) m(-1). DNS-SsrA bound with only slightly reduced affinity to deletion mutants of ClpA missing either the N-terminal domain or the C-terminal nucleotide-binding domain, indicating that the binding site for SsrA lies within the N-terminal nucleotide-binding domain. Because only one protein at a time can be unfolded and translocated by ClpA hexamers, restricting the number of peptides initially bound should avoid nonproductive binding of substrates and aggregation of partially processed proteins.

A mutant HemA protein with positive charge close to the N terminus is stabilized against heme-regulated proteolysis in Salmonella typhimurium.

The HemA enzyme (glutamyl-tRNA reductase) catalyzes the first committed step in heme biosynthesis in the enteric bacteria. HemA is mainly regulated by conditional protein stability; it is stable and, consequently, more abundant in heme-limited cells but unstable and less abundant in normally growing cells. Both the Lon and ClpAP energy-dependent proteases contribute to HemA turnover in vivo. Here we report that the addition of two positively charged lysine residues to the third and fourth positions at the HemA N terminus resulted in complete stabilization of the protein. By contrast, the addition of an N-terminal myc epitope tag did not affect turnover. This result confirms the importance of the N-terminal sequence for proteolysis of HemA. This region of the protein also contains a proline flanked by hydrophobic residues, a motif that has been suggested to be important for Lon-mediated proteolysis of UmuD. However, mutation of this motif did not affect the turnover of HemA protein. Cells expressing the stabilized HemA[KK] mutant protein display substantial defects in heme regulation.

Conditional stability of the HemA protein (glutamyl-tRNA reductase) regulates heme biosynthesis in Salmonella typhimurium.

In many bacteria, including the enteric species Salmonella typhimurium and Escherichia coli, heme is synthesized starting from glutamate by a pathway in which the first committed step is catalyzed by the hemA gene product, glutamyl-tRNA reductase (HemA). We have demonstrated previously that when heme limitation is imposed on cultures of S. typhimurium, HemA enzyme activity is increased 10- to 25-fold. Western (immunoblot) analysis with monoclonal antibodies reactive with HemA revealed that heme limitation results in a corresponding increase in the abundance of the enzyme. Similar regulation was also observed for E. coli. The near absence of regulation of hemA-lac operon fusions suggested a posttranscriptional control. We report here the results of pulse-labeling and immunoprecipitation studies of this regulation. The principal mechanism that contributes to elevated HemA abundance is protein stabilization. The half-life of HemA protein is approximately 20 min in unrestricted cells but increases to >300 min in heme-limited cells. Similar regulation was observed for a HemA-LacZ hybrid protein containing almost all of the HemA protein (416 residues). Sodium azide prevents HemA turnover in vivo, suggesting a role for energy-dependent proteolysis. This was confirmed by the finding that HemA turnover is completely blocked in a lon clpP double mutant of E. coli. Each single mutant shows only a small effect. The ClpA chaperone, but not ClpX, is required for ClpP-dependent HemA turnover. A hybrid HemA-LacZ protein containing just 18 amino acids from HemA is also stabilized in the lon clpP double mutant, but this shorter fusion protein is not correctly regulated by heme limitation. We suggest that the 18 N-terminal amino acids of HemA may constitute a degradation tag, whose function is conditional and modified by the remainder of the protein in a heme-dependent way. Several models are discussed to explain why the turnover of HemA is promoted by Lon-ClpAP proteolysis only when sufficient heme is available.

Regulation of heme biosynthesis in Salmonella typhimurium: activity of glutamyl-tRNA reductase (HemA) is greatly elevated during heme limitation by a mechanism which increases abundance of the protein.

In Salmonella typhimurium and Escherichia coli, the hemA gene encodes the enzyme glutamyl-tRNA reductase, which catalyzes the first committed step in heme biosynthesis. We report that when heme limitation is imposed on cultures of S. typhimurium, glutamyl-tRNA reductase (HemA) enzyme activity is increased 10- to 25-fold. Heme limitation was achieved by a complete starvation for heme in hemB, hemE, and hemH mutants or during exponential growth of a hemL mutant in the absence of heme supplementation. Equivalent results were obtained by both methods. To determine the basis for this induction, we developed a panel of monoclonal antibodies reactive with HemA, which can detect the small amount of protein present in a wild-type strain. Western blot (immunoblot) analysis with these antibodies reveals that the increase in HemA enzyme activity during heme limitation is mediated by an increase in the abundance of the HemA protein. Increased HemA protein levels were also observed in heme-limited cells of a hemL mutant in two different E. coli backgrounds, suggesting that the observed regulation is conserved between E. coli and S. typhimurium. In S. typhimurium, the increase in HemA enzyme and protein levels was accompanied by a minimal (less than twofold) increase in the expression of hemA-lac operon fusions; thus HemA regulation is mediated either at a posttranscriptional step or through modulation of protein stability.

The hemA gene encoding glutamyl-tRNA reductase from the archaeon Methanobacterium thermoautotrophicum strain Marburg

In archaea the first general tetrapyrrole precursor 5-aminolevulinic acid (ALA) is formed via the tRNA-dependent five-carbon pathway from glutamate. We have cloned the hemA gene encoding the central enzyme of the pathway glutamyl- tRNA reductase from the methanogenic archacon Methanobacterium thermoautotrophicum by complementation of an Escherichia coli hemA mutant to ALA prototrophy. An 1194 bp open reading frame that encodes a 398 amino acid polypeptide with the calculated M r 44,509 was detected. The deduced amino acid sequence showed 20–35% amino acid identity to bacterial HemAs with the highest identity score to the Pseudomonas aeruginosa HemA. An identity of approximately 22% was found to plant HemAs. Glutamyl-tRNA reductase activity was shown for the M. thermoautotrophicum HemA after overexpression in E. coli and partial purification. The enzymatic reaction catalyzed by the partially purified enzyme revealed a temperature optimum of 65 °C at an optimal pH of 7.0. The reductase utilized preferentially NADPH for the reduction of the activated carboxyl group. The presence of ATP and GTP showed no obvious influence on catalysis. The cloning and characterization of the hemA gene from Methanobacterium thermoautotrophicum encoding glutamyl tRNA reductase is reported. An initial biochemical characterization of the recombinant HemA protein is described.

Regulation of 5-aminolevulinic acid synthesis in Rhodobacter sphaeroides 2.4.1: the genetic basis of mutant H-5 auxotrophy.

Rhodobacter sphaeroides H-5 was isolated as a 5-aminolevulinic acid (ALA) auxotroph following treatment of wild-type cells with N-methyl-N-nitroso-N'-nitroguanidine (J. Lascelles and T. Altshuler, J. Bacteriol. 98:721-727, 1969). The existence in R. sphaeroides 2.4.1 of the genes hemA and hemT, each encoding the enzyme 5-aminolevulinic acid synthase (EC 2.3.1.37), raised questions as to the genetic basis for the ALA auxotrophy in mutant H-5. We therefore cloned both the hemA and hemT genes from mutant H-5. The hemA gene has been sequenced in its entirety and bears four base pair substitutions which encode three amino acid changes relative to the sequence of wild-type strain 2.4.1. Complementation analysis of an Escherichia coli ALA auxotroph has revealed that the loss of ALA synthase activity in the HemA mutant enzyme could be localized to two of the amino acid substitutions. On the other hand, the hemT gene from mutant H-5 was able to complement an E. coli mutant requiring ALA for growth. Complementation analyses were also carried out by introducing the cloned hemA or hemT gene of mutant H-5 or wild-type 2.4.1 in trans into H-5 and, in parallel, into our previously described HemA-HemT double mutant strain AT1 (E. L. Neidle and S. Kaplan, J. Bacteriol. 175:2304-2313, 1993). This analysis revealed that while the complementation pattern of mutant AT1 parallels that for the E. coli ALA auxotroph, mutant H-5 could only be complemented by the wild-type hemA gene. The ability of the hemT gene of either mutant H-5 or wild-type 2.4.1 to complement the ALA auxotrophy of mutant AT1 but not mutant H-5 was consistent with beta-galactosidase activities obtained with hemT-lacZ transcriptional fusions. We conclude that the ALA auxotrophy of mutant H-5 arises from (i) a nonfunctional HemA protein containing multiple missense substitutions and (ii) an inability of the normal hemT gene to be expressed in the mutant H-5 genetic background, i.e., an additional mutation of unknown origin is required for hemT expression. These studies bear directly on the regulation of the expression of the hemA and hemT genes of R. sphaeroides 2.4.1.

The hemX gene of the Bacillus subtilis hemAXCDBL operon encodes a membrane protein, negatively affecting the steady-state cellular concentration of HemA (glutamyl-tRNA reductase).

The Bacillus subtilis hemAXCDBL operon encodes enzymes for the biosynthesis of uroporphyrinogen III from glutamyl-tRNA. The function of the hemX gene product was studied in this work. The deduced amino acid sequence suggests HemX to be an integral 32 kDa membrane protein. This was confirmed by experiments using Escherichia coli minicells and hemX-phoA gene fusions. Deletion of the hemX gene from the Bacillus subtilis chromosome demonstrated that this gene is not required for haem synthesis. However, the deletion strain was found to overexpress the hemA gene product, glutamyl-tRNA reductase. A combination of results obtained with B. subtilis hemA and hemX in Escherichia coli and Bacillus subtilis shows that HemX negatively affects the steady-state cellular concentration of HemA protein. The mechanism by which HemX affects the HemA concentration is unclear.

Light regulation of chlorophyll biosynthesis at the level of 5-aminolevulinate formation in Arabidopsis.

5-Aminolevulinic acid (ALA) is the universal precursor of tetrapyrroles, such as chlorophyll and heme. The major control of chlorophyll biosynthesis is at the step of ALA formation. In the chloroplasts of plants, as in Escherichia coli, ALA is derived from the glutamate of Glu-tRNA via the two-step C5 pathway. The first enzyme, Glu-tRNA reductase, catalyzes the reduction of Glu-tRNA to glutamate 1-semialdehyde with the release of intact tRNA. The second enzyme, glutamate 1-semialdehyde 2,1-aminomutase, converts glutamate 1-semialdehyde to ALA. To further examine ALA formation in plants, we isolated Arabidopsis genes that encode the enzymes of the C5 pathway via functional complementation of mutations in the corresponding genes of E. coli. The Glu-tRNA reductase gene was designated HEMA and the glutamate 1-semialdehyde 2,1-aminomutase gene, GSA1. Each gene contains two short introns (149 and 241 nucleotides for HEMA, 153 and 86 nucleotides for GSA1). The deduced amino acid sequence of the HEMA protein predicts a protein of 60 kD with substantial similarity (30 to 47% identity) to sequences derived from the known hemA genes from microorganisms that make ALA by the C5 pathway. Purified Arabidopsis HEMA protein has Glu-tRNA reductase activity. The GSA1 gene encodes a 50-kD protein whose deduced amino acid sequence shows extensive homology (55 to 78% identity) with glutamate 1-semialdehyde 2,1-aminomutase proteins from other species. RNA gel blot analyses indicated that transcripts for both genes are found in root, leaf, stem, and flower tissues and that their levels are dramatically elevated by light. Thus, light may regulate ALA, and hence chlorophyll formation, by exerting coordinated transcriptional control over both enzymes of the C5 pathway.

Glutamyl-tRNA reductase from Escherichia coli and Synechocystis 6803. Gene structure and expression.

In the cyanobacterium Synechocystis sp. PCC 6803 and in the enterobacterium Escherichia coli delta-amino-levulinic acid (ALA) is formed from glutamyl-tRNA by the sequential action of two enzymes, glutamyl-tRNA reductase (GluTR) and glutamate-1-semialdehyde aminotransferase. E. coli has two GluTR proteins with sizes of 45 kDa (GluTR45) and 85 kDa (GluTR85) (Jahn, D., Michelsen, U., and Söll, D. (1991) J. Biol. Chem. 266, 2542-2548). The hemA gene, isolated from E. coli and several other eubacteria, has been proposed to encode a structural component of GluTR. Because of the inability to overexpress this gene in E. coli, we demonstrate directly GluTR function for the E. coli hemA gene product by its expression and functional analysis in yeast, which does not form ALA from Glu-tRNA. Gel filtration experiments demonstrated definitively that the yeast-expressed HemA protein corresponded to GluTR45. Furthermore, analysis of GluTR activity in an E. coli strain with a disrupted hemA gene displayed GluTR85, but not GluTR45 activity. The hemA gene from Synechocystis 6803 was cloned by functional complementation in E. coli. DNA sequence analysis revealed an open reading frame capable of encoding a 427-amino acid polypeptide (molecular mass of 47,525 Da). The Synechocystis 6803 amino acid sequence shows significant similarity upon alignment with HemA sequences from E. coli, Bacillus subtilis, Salmonella typhimurium, and Chlorobium vibrioforme but does not contain the amino acid sequence derived from the N terminus of the previously purified GluTR protein (Rieble, S., and Beale, S. I. (1991) J. Biol. Chem. 266, 9740-9745). These experiments are the first direct demonstration of GluTR activity of the HemA protein and provide further evidence for two pathways of ALA formation in prokaryotes.

Glutamyl-tRNA reductase activity in Bacillus subtilis is dependent on the hemA gene product.

The Bacillus subtilis hemAXCDBL operon encodes enzymes for the synthesis of 5-aminolaevuline acid via the C5 pathway (hemA and hemL) and uroporphyrinogen III (hemB, hemC and hemD). B. subtilis HemA protein (molecular mass 50 kDa) was overexpressed in hemA mutant of both Escherichia coli and B. subtilis. A mutant B. subtilis HemA protein with a Cys to Tyr change at position 105 was also overexpressed. Both wild-type and mutant HemA proteins migrated as oligomers (molecular mass greater than or equal to 230 kDa) on gel-filtration columns. All column fractions containing wild-type HemA protein had glutamyl-tRNA reductase activity. No glutamyl-tRNA reductase activity was found with the mutant HemA protein. It is concluded that the B. subtilis hemA gene product is identical to, or part of, the glutamyl-tRNA reductase of the C5 pathway.

Cloning and nucleotide sequence of the hemA gene of Agrobacterium radiobacter

The hemA gene of Agrobacterium radiobacter ATCC4718 was identified by hybridization with a hemA probe from Rhizobium meliloti and cloned by complementation of a hemA mutant of Escherichia coli K12. E. coli hemA transformants carrying the hemA gene of Agrobacterium showed delta-aminolevulinic acid synthetase (delta-ALAS) activity in vitro. The hemA gene was carried on a 4.4 kb EcoRI fragment which could be reduced to a 2.6 kb EcoRI-SstI fragment without affecting its complementing or delta-ALAS activity. The sequence of the hemA gene showed an open reading frame of 1215 nucleotides, which could code for a protein of 44,361 Da. This is very close to the molecular weight of the HemA protein obtained using an in vitro coupled transcription-translation system (45,000 Da). Comparison of amino acid sequences of the delta-ALAS of A. radiobacter and Bradyrhizobium japonicum showed strong homology between the two enzymes; less, but still significant, homology was observed when A. radiobacter and human delta-ALAS were compared. Primer extension experiments enabled us to identify two promoters for the hemA gene of A. radiobacter. One of these promoters shows some similarity to the first promoter of the hemA gene of R. meliloti.

Cloning and characterization of the hemA region of the Bacillus subtilis chromosome

A 3.8-kilobase DNA fragment from Bacillus subtilis containing the hemA gene has been cloned and sequenced. Four open reading frames were identified. The first is hemA, encoding a protein of 50.8 kilodaltons. The primary defect of a B. subtilis 5-aminolevulinic acid-requiring mutant was identified as a cysteine-to-tyrosine substitution in the HemA protein. The predicted amino acid sequence of the B. subtilis HemA protein showed 34% identity with the Escherichia coli HemA protein, which is known to code for the NAD(P)H:glutamyl-tRNA reductase of the C5 pathway for 5-aminolevulinic acid synthesis. The B. subtilis HemA protein also complements the defect of an E. coli hemA mutant. The second open reading frame in the cloned fragment, called ORF2, codes for a protein of about 30 kilodaltons with unknown function. It is not the proposed hemB gene product porphobilinogen synthase. The third open reading frame is hemC, coding for porphobilinogen deaminase. The fourth open reading frame extends past the sequenced fragment and may be identical to hemD, coding for uroporphyrinogen III cosynthase. Analysis of deletion mutants of the hemA region suggests that (at least) hemA, ORF2, and hemC may be part of an operon.

Cloning and sequencing of the hemA gene of Rhodobacter capsulatus and isolation of a δ-aminolevulinic acid-dependent mutant strain

The Rhodobacter capsulatus hemA gene, coding for the enzyme delta-aminolevulinic acid synthase (ALAS), was isolated from a genome bank by hybridization with a hemT probe from Rhodobacter sphaeroides. Subcloning of the initial 3.9 kb HindIII fragment allowed the isolation of a 2.5 kb HindIII-BglII fragment which was able to complement the delta-aminolevulinic acid-requiring (ALA-requiring) Escherichia coli mutant SHSP19. DNA sequencing revealed an open reading frame coding for a protein with 401 amino acids which displayed similarity to the amino acid sequences of other known ALASs. However, no resemblance was seen to the HemA protein of E. coli K12. Based on the sequence data, an ALA-requiring mutant strain of R. capsulatus was constructed by site-directed insertion mutagenesis. Introduction of a plasmid, containing the hemA gene of R. capsulatus on the 3.9 kb HindIII fragment, restored ALA-independent growth of the mutant indicating that there is only one gene for ALA biosynthesis in R. capsulatus. Transfer of the R' factor pRPS404 and hybridization analysis revealed that the ALAS gene is not located within the major photosynthetic gene cluster.

Cloning, genetic characterization, and nucleotide sequence of the hemA-prfA operon of Salmonella typhimurium

The first step in heme biosynthesis is the formation of 5-aminolevulinic acid (ALA). Mutations in two genes, hemA and hemL, result in auxotrophy for ALA in Salmonella typhimurium, but the roles played by these genes and the mechanism of ALA synthesis are not understood. I have cloned and sequenced the S. typhimurium hemA gene. The predicted polypeptide sequence for the HemA protein shows no similarity to known ALA synthases, and no ALA synthase activity was detected in extracts prepared from strains carrying the cloned hemA gene. Genetic analysis, DNA sequencing of amber mutations, and maxicell studies proved that the open reading frame identified in the DNA sequence encodes HemA. Another surprising finding of this study is that hemA lies directly upstream of prfA, which encodes peptide chain release factor 1 (RF-1). A hemA::Kan insertion mutation, constructed in vitro, was transferred to the chromosome and used to show that these two genes form an operon. The hemA gene ends with an amber codon, recognized by RF-1. I suggest a model for autogenous control of prfA expression by translation reinitiation.

Isolation and nucleotide sequence of the hemA gene of Escherichia coli K12.

The hemA gene of Escherichia coli K12 was cloned by complementation of a hemA mutant of this organism. Subcloning of the initial 6.0 kb HindIII fragment allowed the isolation of a 1.5 kb NheI-AvaI fragment which retained the ability to complement the hemA mutant. DNA sequencing by the dideoxy chain terminator method of Sanger showed the presence of an open reading frame (ORF) of 1254 nucleotides, which ends 6 nucleotides beyond the AvaI site. Primer extension experiments showed the existence of a putative transcription initiation site for the hemA gene, located at position 130. A possible promoter sequence was identified upstream from this transcription initiation site, and its functional activity was confirmed by the use of the pK01 promoter-probe vector. Protein synthesis in an in vitro coupled transcription-translation system showed a 46 kDa protein, which corresponds to the mol. wt. of the hemA protein, as deduced from the nucleotide sequence of the gene. No homology was found between the amino acid sequence of the hemA protein of E. coli K12 and known sequences of other delta-aminolevulinic acid synthases (delta-ALAS), suggesting that this protein is different from other delta-ALAS enzymes.