Structure and expression of the Chlorobium vibrioforme hemB gene and characterization of its encoded enzyme, porphobilinogen synthase.

Plasmids containing DNA from the green photosynthetic bacterium Chlorobium vibrioforme complement a heme-requiring Escherichia coli hemB mutant that is deficient in porphobilinogen (PBG) synthase activity. PBG synthase activity was detected in extract of complemented cells but not in that of cells transformed with control plasmid. The sequence of the C. vibrioforme hemB gene predicts a HemB protein that contains 328 amino acids, has a molecular weight of 36,407, and is 53% identical to the homologous proteins of Synechocystis sp. PCC 6301 and Rhodobacter capsulatus. The response of C. vibrioforme PBG synthase to divalent metals is unlike that of any previously described PBG synthase; Mg2+ stimulates but is not required for activity, and Zn2+ neither stimulates nor is required. This response correlates with predicted sequences of two putative variable metal binding regions of C. vibrioforme HemB. The C. vibrioforme hemB open reading frame begins 1585 bases downstream from the end of the hemD open reading frame and is transcribed in the same direction as hemA, hemC, and hemD. However, hemB is not part of the same transcription unit as these genes, and the hemB transcript is approximately the same size as the hemB gene alone. Between hemD and hemB there is an intervening open reading frame that is oriented in the opposite direction and encodes a protein with a predicted amino acid sequence significantly similar to that of inositol monophosphatase, an enzyme that is not involved in tetrapyrrole biosynthesis. The gene order within hem gene clusters is highly conserved in phylogenetically diverse prokaryotic organisms. This conservation suggests that there are functional constraints on the relative order of the hem genes.

The common origins of the pigments of life-early steps of chlorophyll biosynthesis.

The complex pathway of tetrapyrrole biosynthesis can be dissected into five sections: the pathways that produce 5-aminolevulinate (the C-4 and the C-5 pathways), the steps that transform ALA to uroporphyrinogen III, which are ubiquitous in the biosynthesis of all tetrapyrroles, and the three branches producing specialized end products. These end products include corrins and siroheme, chlorophylls and hemes and linear tetrapyrroles. These branches have been subjects of recent reviews. This review concentrates on the early steps leading up to uroporphyrinogen III formation which have been investigated intensively in recent years in animals, in plants, and in a wide range of bacteria.

Incorporation of body components of diverse microorganisms by larval mosquitoes.

A pulse-purge schedule of exposure to labeled microorganisms was used to compare their digestibility by larval mosquitoes. Larvae were placed for an hour in suspensions of diverse axenically grown microorganisms that had been labeled with radioactive carbon (in the form of glucose or glycine). The guts of these mosquitoes were then purged with nonlabeled Sephadex particles for 30 min, and retained radioactivity was measured. Larvae imbibed no dissolved material. Larval mosquitoes differ in their capacity to derive label from algae (sensu lato), and certain algae contribute more label to these mosquitoes than do others. The nature of any algal food, as well as the feeding habits and developmental stage of the larva, influence its capacity to derive label from algae. This pulse-purge method of analysis can assist in the selection of algal "vectors" suitable as vehicles for transgenic larvicide. Although larval mosquitoes fail to assimilate the contents of Palmellacoccus cells with which they are confined, as much as 1/3 of the body contents of a Euglena gracilis cells become incorporated into their bodies. Because larval mosquitoes internalize more material from Euglena than they do from various other algae, these microorganisms provide a promising candidate vehicle for transgenic Bacillus thuringiensis israelensis.

A gene cluster inChlorobium vibrioforme encoding the first enzymes of chlorophyll biosynthesis.

A cloned 5.8-kb genomic fragment of the green sulfur bacteriumChlorobium vibrioforme encodes the genes for three enzymes catalyzing early steps in the biosynthetic pathway of tetrapyrroles, common to chlorophyll and heme. ThehemA, hemC andhemD genes encode the enzymes glutamyl tRNA dehydrogenase, porphobilinogen deaminase and uroporphyrinogen III synthase, respectively. The cloned genes were expressed in transformedEscherichia coli orSalmonella typhimurium and conferred autotrophy on the respective auxotrophs. Activities of the enzymes encoded by the cloned genes were demonstrated in vitro, with cell extracts obtained from the transformed enterobacteria. The proximity of these genes indicates that they form a cluster inChlorobium vibrioforme, while in most other organisms they appear to be scattered. The presence of this cluster may imply coordinate regulation of the genes involved and they may constitute an operon.

Intermolecular nitrogen transfer in the enzymic conversion of glutamate to delta-aminolevulinic acid by extracts of Chlorella vulgaris.

delta-Aminolevulinic acid (ALA), the universal biosynthetic precursor of tetrapyrrole pigments, is synthesized from glutamate in plants, algae, and many bacteria via a three-step process that begins with activation by ligation of glutamate to tRNA(Glu), followed by reduction to glutamate-1-semialdehyde (GSA) and conversion of GSA to ALA. The GSA aminotransferase step requires no substrate other than GSA. A previous study examined whether the aminotransferase reaction proceeds via intramolecular or intermolecular N transfer and concluded that the reaction catalyzed by Chlamydomonas extracts occurs via intermolecular N transfer (Y.-H.L. Mau and W.-Y. Wang [1988] Plant Physiol 86: 793-797). However, in that study the possibility was not excluded that the result was a consequence of N exchange among product ALA molecules during the incubation, rather than intermolecular N transfer during the conversion of GSA to ALA. Therefore, this question was reexamined in another species and with additional controls. A gel-filtered extract of Chlorella vulgaris cells was incubated with ATP, Mg2+, NADPH, tRNA, and a mixture of L-glutamate molecules, one-half of which were labeled with 15N and the other half with 13C at C-1. The ALA product was purified, derivatized, and analyzed by gas chromatography-mass spectrometry. A significant fraction of the ALA molecules was heavy by two mass units, indicating incorporation of both 15N and 13C. These results show that the N and C atoms of each ALA molecule were derived from different glutamate molecules. Control experiments indicated that the results could not be attributed to exchange of N atoms between glutamate or ALA molecules during the incubation. These results confirm the earlier conclusion that GSA is converted to ALA via intermolecular N transfer and extend the results to another species. The labeling results, combined with the results of kinetic and inhibitor studies, support a model for the GSA aminotransferase reaction in which a single molecule of GSA is converted to ALA via an enzyme-bound 4,5-diaminovaleric acid intermediate.

Simultaneous and rapid isolation of bacterial and eukaryotic DNA and RNA: a new approach for isolating DNA.

A very simple procedure for the simultaneous preparation of genomic DNA and total RNA is described. The procedure is essentially the same for eukaryotes and prokaryotes except for the lysis buffer and can be used for small or large numbers of cells. Mammalian cells are lysed in sodium dodecyl sulfate and bacterial cells are lysed in Triton X-100, both in the presence of EDTA. RNA is obtained in the aqueous phase after phenol (acidic pH):chloroform:isoamyl alcohol extraction. DNA is eluted out of the organic phase (and the interface) into the aqueous phase by increasing the pH with highly basic 1 M Tris solution. The method is extremely rapid for small or large numbers of cells, and several large samples can be processed in one day. The qualities of both nucleic acids are excellent and the yield is high.

Structure and expression of the Chlorobium vibrioforme hemA gene.

The green sulfur bacterium, Chlorobium vibrioforme, synthesizes the tetrapyrrole precursor, delta-aminolevulinic acid (ALA), from glutamate via the RNA-dependent five-carbon pathway. A 1.9-kb clone of genomic DNA from C. vibrioforme that is capable of transforming a glutamyl-tRNA reductase-deficient, ALA-dependent, hemA mutant of Escherichia coli to prototrophy was sequenced. The transforming C. vibrioforme DNA has significant sequence similarity to the E. coli, Salmonella typhimurium, and Bacillus subtilis hemA genes and contains a 1245 base open reading frame that encodes a 415 amino acid polypeptide with a calculated molecular weight of 46174. This polypeptide has over 28% amino acid identity with the polypeptides deduced from the nucleic acid sequences of the E. coli, S. typhimurium, and B. subtilis hemA genes. No sequence similarity was detected, at either the nucleic acid or the peptide level, with the Rhodobacter capsulatus or Bradyrhizobium japonicum hemA genes, which encode ALA synthase, or with the S. typhimurium hemL gene, which encodes glutamate-1-semialdehyde aminotransferase. These results establish that hemA encodes glutamyl-tRNA reductase in species that use the five-carbon ALA biosynthetic pathway. A second region of the cloned DNA, located downstream from the hemA gene, has significant sequence similarity to the E. coli and B. subtilis hemC genes. This region contains a potential open reading frame that encodes a polypeptide that has high sequence identity to the deduced E. coli and B. subtilis HemC peptides. hemC encodes the tetrapyrrole biosynthetic enzyme, porphobilinogen deaminase, in these species.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning and sequence of the Salmonella typhimurium hemL gene and identification of the missing enzyme in hemL mutants as glutamate-1-semialdehyde aminotransferase.

Salmonella typhimurium forms the heme precursor delta-aminolevulinic acid (ALA) exclusively from glutamate via the five-carbon pathway, which also occurs in plants and some bacteria including Escherichia coli, rather than by ALA synthase-catalyzed condensation of glycine and succinyl-coenzyme A, which occurs in yeasts, fungi, animal cells, and some bacteria including Bradyrhizobium japonicum and Rhodobacter capsulatus. ALA-auxotrophic hemL mutant S. typhimurium cells are deficient in glutamate-1-semialdehyde (GSA) aminotransferase, the enzyme that catalyzes the last step of ALA synthesis via the five-carbon pathway. hemL cells transformed with a plasmid containing the S. typhimurium hemL gene did not require ALA for growth and had GSA aminotransferase activity. Growth in the presence of ALA did not appreciably affect the level of extractable GSA aminotransferase activity in wild-type cells or in hemL cells transformed with the hemL plasmid. These results indicate that GSA aminotransferase activity is required for in vivo ALA biosynthesis from glutamate. In contrast, extracts of both wild-type and hemL cells had gamma,delta-dioxovalerate aminotransferase activity, which indicates that this reaction is not catalyzed by GSA aminotransferase and that the enzyme is not encoded by the hemL gene. The S. typhimurium hemL gene was sequenced and determined to contain an open reading frame of 426 codons encoding a 45.3-kDa polypeptide. The sequence of the hemL gene bears no recognizable similarity to the hemA gene of S. typhimurium or E. coli, which encodes glutamyl-tRNA reductase, or to the hemA genes of B. japonicum or R. capsulatus, which encode ALA synthase. The predicted hemL gene product does show greater than 50% identity to barley GSA aminotransferase over its entire length. Sequence similarity to other aminotransferases was also detected.

Cloning and expression of a structural gene from Chlorobium vibrioforme that complements the hemA mutation in Escherichia coli.

Escherichia coli SASX41B carries the hemA mutation and requires delta-aminolevulinic acid for growth. Strain SASX41B was transformed to prototrophy with pYA1, a plasmid vector carrying a 5.8-kilobase insert of genomic DNA from the green sulfur bacterium Chlorobium vibrioforme. Cell extracts prepared from transformed cells are able to catalyze transfer of label from [1-14C]glutamate or [3,4-3H]glutamyl-tRNA to delta-aminolevullinic acid at rates much higher than extracts of wild-type cells can, whereas extracts prepared from untransformed strain SASX41B cells lack both activities. By comparing the relative abilities of glutamyl-tRNAs derived from several heterologous cell types to function as substrates for the dehydrogenase reaction in extracts of HB101 and SASX41B cells transformed by pYA1, it was determined that the expressed dehydrogenase in the transformed cells resembled that of C. vibrioforme and not that of E. coli. Thus it can be concluded that plasmid pYA1 contains inserted DNA that codes for a structural component of C. vibrioforme glutamyl-tRNA dehydrogenase which confers glutamyl-tRNA substrate specificity.

Identification of the enzymatic basis for delta-aminolevulinic acid auxotrophy in a hemA mutant of Escherichia coli.

The hemA mutation of Escherichia coli K-12 confers a requirement for delta-aminolevulinic acid (ALA). Cell extract prepared from the hemA strain SASX41B was incapable of producing ALA from either glutamate or glutamyl-tRNA, whereas extract of the hem+ strain HB101 formed colorimetrically detectable amounts of ALA and transferred label from 1-[14C]glutamate and 3,4-[3H]glutamyl-tRNA to ALA. Extracts of both strains converted glutamate-1-semialdehyde to ALA and were capable of aminoacylating tRNAGlu. Glutamyl-tRNA formed by extracts of both strains could be converted to ALA by the extract of hem+ cells. The extract of hemA cells did not convert glutamyl-tRNA formed by either strain to ALA. However, the hemA cell extract, when supplemented in vitro with glutamyl-tRNA dehydrogenase isolated from Chlorella vulgaris cells, formed about as much ALA as did the unsupplemented hem+ cell extract. We conclude from these observations that the enzyme activity that is lacking in the ALA auxotrophic strain carrying the hemA mutation is that of glutamyl-tRNA dehydrogenase.

Biosynthesis of Tetrapyrrole Pigment Precursors : Pyridoxal Requirement of the Aminotransferase Step in the Formation of delta-Aminolevulinate from Glutamate in Extracts of Chlorella vulgaris.

The aminotransferase that catalyzes the formation of delta-aminolevulinic acid from glutamate-1-semialdehyde or from glutamate in a reconstituted enzyme system was isolated and partially purified from Chlorella vulgaris. The apparent molecular weight of the aminotransferase was determined by Sephadex G-100 and Ultrogel AcA 54 gel filtration to be 60,000 +/- 5,000. Catalytic activity of the aminotransferase required pyrixodal phosphate (PALP). The cofactor could not be removed by gel filtration after exposure of the enzyme to PALP. Aminotransferase was inhibited by gabaculine (3-amino-2,3-dihydrobenzoic acid). The concentration of gabaculine required for half maximal inhibition was about 0.05 micromolar. Aminotransferase activity could be regained upon the removal of gabaculine by gel filtration and supplementing the assay medium with PALP. Neither the inhibitory action of gabaculine nor its reversibility was affected by preincubation of the enzyme with the keto acids levulinate and delta-aminolevulinic acid.

Distribution of delta-aminolevulinic acid biosynthetic pathways among phototrophic bacterial groups.

Two biosynthetic pathways are known for the universal tetrapyrrole precursor, delta-aminolevulinic acid (ALA). In the ALA synthase pathway which was first described in animal and some bacterial cells, the pyridoxal phosphate-dependent enzyme ALA synthase catalyzes condensation of glycine and succinyl-CoA to form ALA with the loss of C-1 of glycine as CO2. In the five-carbon pathway which was first described in plant and algal cells, the carbon skeleton of glutamate is converted intact to ALA in a proposed reaction sequence that requires three enzymes, tRNA(Glu), ATP, Mg2+, NADPH, and pyridoxal phosphate. We have examined the distribution of the two ALA biosynthetic pathways among various genera, using cell-free extracts obtained from representative organisms. Evidence for the operation of the five-carbon pathway was obtained by the measurement of RNase-sensitive label incorporation from glutamate into ALA, using 3,4-[3H]glutamate or 1-[14C]glutamate as substrate. ALA synthase activity was indicated by RNase-insensitive incorporation of label from 2-[14C]glycine into ALA. The distribution of the two pathways among the bacteria tested was in general agreement with their previously established phylogenetic relationships and clearly indicates that the five-carbon pathway is the more ancient process, whereas the pathway utilizing ALA synthase probably evolved much later. The five-carbon pathway is apparently the more widely utilized one among bacteria, while the ALA synthase pathway seems to be limited to the alpha subgroup of purple bacteria.

Biosynthesis of Tetrapyrrole Pigment Precursors : Formation and Utilization of Glutamyl-tRNA for delta-Aminolevulinic Acid Synthesis by Isolated Enzyme Fractions from Chlorella Vulgaris.

The universal tetrapyrrole precursor delta-aminolevulinic acid (ALA) is formed from glutamate (Glu) in algae and higher plants. In the postulated reaction sequence, Glu-tRNA is produced by a Glu-tRNA synthetase, and the product serves as a substrate for a reduction step catalyzed by a pyridine nucleotide-requiring Glu-tRNA dehydrogenase. The reduced intermediate is then converted into ALA by a transaminase. An RNA and three enzyme fractions required for ALA formation from Glu have been isolated from soluble Chlorella extracts. The recombined fractions catalyzed ALA production from Glu or Glu-tRNA. The fraction containing the synthetase produced Glu-tRNA from Glu and tRNA in the presence of ATP and Mg(2+). The isolated product of this reaction served as substrate for ALA production by the partially reconstituted enzyme system lacking the synthetase fraction and incapable of producing ALA from Glu. The production of ALA from Glu-tRNA by this partially reconstituted system did not require free Glu or ATP, and was not affected by added ATP. These results show that (a) free Glu-tRNA is an intermediate in the formation of ALA from Glu, (b) ATP is required only in the first step of the reaction sequence, and NADPH only in a later step, (c) Glu-tRNA production is the essential reaction catalyzed by one of the enzyme fractions, (d) this enzyme fraction is active in the absence of the other enzymes and is not required for activity of the others. The specific Glu-tRNA synthetase required for ALA formation has an approximate molecular weight of 73,000 +/- 5,000 as determined by Sephadex G-100 gel filtration and native polyacrylamide gel electrophoresis. Other Glu-tRNA synthetases were present in the cell extracts but were ineffective in the the ALA-forming process.

5-Aminolevulinate Synthesis in Permeabilized Filaments of the Blue-Green Alga Anabaena variabilis.

Filaments of the blue-green alga Anabaena variabilis permeabilized by dimethylsulfoxide (DMSO) produce increased amounts of 5-aminolevulinate in the presence of levulinic acid. The metabolic activity of the filaments remains unperturbed in the presence of up to 7.5% (v/v) DMSO. Studies utilizing DMSO-permeabilized filaments confirm that 5-aminolevulinate is synthesized preferably from glutamate and, to a lesser extent, from alpha-ketoglutarate in this organism.

Biosynthesis of 5-aminolevulinate from glutamate in Anabaena variabilis.

Anabaena variabilis filaments excrete 5-aminolevulinate into the medium when incubated in the presence of levulinic acid, a competitive inhibitor of the 5-aminolevulinate utilizing enzyme, 5-aminolevulinate dehydratase (5-aminolevulinate hydro-lyase, EC 4.2.1.24). Although 5-aminolevulinate accumulation is independent of an external supply of substrate, the accumulating 5-aminolevulinate can be readily labeled by [14C]glutamate or alpha-[14C]ketoglutarate. Glycine and succinate, substrates of the classical 5-aminolevulinate synthesizing enzyme, 5-aminolevulinate synthase (succinyl-CoA:glycine C-succinyltransferase (decarboxylating), EC 2.3.1.37), label 5-aminolevulinate only to a very small extent. Studies with glutamate and alpha-ketoglutarate labeled in specific carbon atoms show that in A. variabilis, as in higher plants and eukaryotic algae, all five carbon atoms of these substrates are incorporated into 5-aminolevulinate, with carbon 1 of glutamate or of alpha-ketoglutarate becoming carbon 5 of 5-amino-levulinate. These findings are consistent with the theory that chloroplasts evolved from cyanobacteria or from closely related organisms.

Stimulation of tetrapyrrole formation in Rhizobium japonicum by restricted aeration.

Cultures of Rhizobium japonicum were grown with vigorous aeration to stationary phase and were then incubated under restricted aeration for several days. Under these "microaerobic" conditions, cellular heme content increased 10-fold, and visible amounts of porphyrins were released into the culture medium. The two predominant porphyrins produced were identified, on the basis of their spectrophotometric and chromatographic properties, as protoporphyrin and coproporphyrin. The cytochrome complement of microaerobic cells partially resembled that of the symbiotic bacteria in that cytochromes alpha-alpha3 were absent and a CO-binding cytochrome 552 was present. During the period of restricted aeration, at the time that the heme content was increasing, there was a similar 10-fold increase in the activities of the first two enzymes of heme biosynthesis, delta-aminolevulinic acid synthase and delta-aminolevulinic acid dehydrase. However, during the same period, the activity of succinyl thiokinase (an enzyme that is required in large amounts whether or not heme is being produced) increased only twofold. These results suggest that reduced oxygen tension may play a role in inducing heme synthesis necessary for leghemoglobin formation and bacterial differentiation in soybean root nodules.

Heme Synthesis in Soybean Root Nodules: I. On the Role of Bacteroid delta-Aminolevulinic Acid Synthase and delta-Aminolevulinic Acid Dehydrase in the Synthesis of the Heme of Leghemoglobin.

During nodulation of soybean (Glycine max) by Rhizobium japonicum, variations in the activities of two enzymes of heme biosynthesis, delta-aminolevulinic acid synthase (ALAS) and delta-aminolevulinic acid dehydrase (ALAD) are described. delta-Aminolevulinic acid synthase activity is found in the bacteroid fraction of nodules, but is not detected in the plant fraction. Bacteroid ALAS activity parallels heme accumulation during nodule development. delta-Aminolevulinic acid dehydrase activity is found in both bacteroid and plant cytosol fractions. Bacteroid ALAD activity is constant or increases during nodulation while plant ALAD activity falls.Bacteroid ALAD activity is found in effective, not in inefficient nodules. Plant ALAD activity is found in both effective and inefficient nodules. Plant ALAD activity falls during development of both types of root nodules.These results support the contention that it is the bacteroid ALAS and ALAD activities, not those of the plant, that are directly involved in formation of leghemoglobin heme, suggesting that the bacteroid may be solely responsible for formation of leghemoglobin heme in the nodule symbiosis.