Bradyrhizobium japonicum delta-aminolevulinic acid dehydratase is essential for symbiosis with soybean and contains a novel metal-binding domain.

The Bradyrhizobium japonicum hemA gene product delta-aminolevulinic acid (ALA) synthase is not required for symbiosis of that bacterium with soybean. Hence, the essentiality of the subsequent heme synthesis enzyme, ALA dehydratase, was examined. The B. japonicum ALA dehydratase gene, termed hemB, was isolated and identified on the basis of its ability to confer hemin prototrophy and enzyme activity on an Escherichia coli hemB mutant, and it encoded a protein that was highly homologous to ALA dehydratases from diverse organisms. A novel metal-binding domain in the B. japonicum ALA dehydratase was identified that is a structural composite of the Mg(2+)-binding domain found in plant ALA dehydratases and the Zn(2+)-binding region of nonplant ALA dehydratases. Enzyme activity in dialyzed extracts of cells that overexpressed the hemB gene was reconstituted by the addition of Mg2+ but not by addition of Zn2+, indicating that the B. japonicum ALA dehydratase is similar to the plant enzymes with respect to its metal requirement. Unlike the B. japonicum hemA mutant, the hemB mutant strain KP32 elicited undeveloped nodules on soybean, indicated by the lack of nitrogen fixation activity and plant hemoglobin. We conclude that the hemB gene is required for nodule development and propose that B. japonicum ALA dehydratase is the first essential bacterial enzyme for B. japonicum heme synthesis in soybean root nodules. In addition, we postulate that ALA is the only heme intermediate that can be translocated from the plant to the endosymbiont to support bacterial heme synthesis in nodules.     

Cloning of tomato (Lycopersicon esculentum Mill.) arginine decarboxylase gene and its expression during fruit ripening.

Extracts of soybean (Glycine max) root nodules and greening etiolated leaves catalyzed radiolabeled delta-aminolevulinic acid (ALA) formation from 3,4-[3H]glutamate but not from 1-[14C]glutamate. Nevertheless, those tissue extracts expressed the activity of glutamate 1-semialdehyde (GSA) aminotransferase, the C5 pathway enzyme that catalyzes ALA synthesis from GSA for tetrapyrrole formation. A soybean nodule cDNA clone that conferred ALA prototrophy, GSA aminotransferase activity, and glutamate-dependent ALA formation activity on an Escherichia coli GSA aminotransferase mutant was isolated. The deduced product of the nodule cDNA shared 79% identity with the GSA aminotransferase expressed in barley leaves, providing, along with the complementation data, strong evidence that the cDNA encodes GSA aminotransferase. GSA aminotransferase mRNA and enzyme activity were expressed in nodules but not in uninfected roots, indicating that the Gsa gene is induced in the symbiotic tissue. The Gsa gene was strongly expressed in leaves of etiolated plantlets independently of light treatment and, to a much lesser extent, in leaves of mature plants. We conclude that GSA aminotransferase, and possibly the C5 pathway, is expressed in a nonphotosynthetic plant organ for nodule heme synthesis and that Gsa is a regulated gene in soybean.     

The Rhizobial hemA Gene Is Required for Symbiosis in Species with Deficient [delta]-Aminolevulinic Acid Uptake Activity

Most rhizobial hemA mutants induce root nodules on their respective legume hosts that lack nitrogen fixation activity and leghemoglobin expression. However, a Bradyrhizobium japonicum hemA mutant elicits effective nodules on soybean, and we proposed previously that synthesis and uptake of the heme precursor [delta]-aminolevulinic acid (ALA) by the plant and bacterial symbiont, respectively, allow mutant rescue (I. Sangwan, M.R. O'Brian [1991] Science 251: 1220-1222). In the present work, the B. japonicum hemA mutant MLG1 elicited normal nodules on three hosts, including cowpea, a plant that is not effectively nodulated by a hemA mutant of Rhizobium sp. These data indicate that B. japonicum rather than soybean possesses the unique trait that allows normal nodule development by a hemA mutant. Cowpea expressed glutamate-dependent ALA formation activity in nodules induced by B. japonicum strains I110 or MLG1 and by Rhizobium sp. ANU240. Exogenous ALA was taken up by B. japonicum bacteroids isolated from soybean or cowpea nodules, and the kinetics of uptake were biphasic. By comparison, Rhizobium sp. ANU240 had very low ALA uptake activity. In addition, ALA uptake was observed in cultured cells of B. japonicum but not in cultured cells of three other rhizobial species tested. We suggest that the differential success of legume-rhizobial hemA symbioses is due to an ALA uptake activity in B. japonicum that is deficient in other rhizobia, thereby further validating the ALA rescue hypothesis.     

Aminolevulinic acid dehydratase in pea (Pisum sativum L.). Identification of an unusual metal-binding domain in the plant enzyme

Aminolevulinic acid dehydratase (ALA dehydratase) catalyzes the second step of tetrapyrrole synthesis leading to the formation of heme and chlorophyll in higher plant cells. Antibodies elicited against spinach leaf ALA dehydratase were used to immunoscreen lambda gt11 cDNA libraries constructed from etiolated pea (Pisum sativum L.) leaf poly(A)+ RNAs. A set of overlapping cDNAs was characterized that encode the pea enzyme. The predicted amino acid sequence of the pea ALA dehydratase is similar to those reported for other eukaryotic and prokaryotic ALA dehydratases. The pea enzyme has an active site domain centered on lysine that is highly conserved in comparison to other known ALA dehydratases. Consistent with the previously reported requirement of Mg2+ for catalytic activity by plant ALA dehydratases, the pea enzyme lacks the characteristic Zn(2+)-binding domain present in other eukaryotic ALA dehydratases, but contains a distinctive metal ligand-binding domain based upon aspartate. Northern blot analyses demonstrated that ALA dehydratase mRNA is present in leaves, stems, and to a lesser extent in roots. Steady state levels of mRNA encoding ALA dehydratase exhibit little or no change during light-induced greening.     

Characterization of delta-Aminolevulinic Acid Formation in Soybean Root Nodules

Formation of the heme precursor δ-aminolevulinic acid (ALA) was studied in soybean root nodules elicited by Bradyrhizobium japonicum. Glutamate-dependent ALA formation activity by soybean (Glycine max) in nodules was maximal at pH 6.5 to 7.0 and at 55 to 60°C. A low level of the plant activity was detected in uninfected roots and was 50-fold greater in nodules from 17-day-old plants; this apparent stimulation correlated with increases in both plant and bacterial hemes in nodules compared with the respective asymbiotic cells. The glutamate-dependent ALA formation activity was greatest in nodules from 17-day-old plants and decreased by about one-half in those from 38-day-old plants. Unlike the eukaryotic ALA formation activity, B. japonicum ALA synthase activity was not significantly different in nodules than in cultured cells, and the symbiotic activity was independent of nodule age. The lack of symbiotic induction of B. japonicum ALA synthase indicates either that ALA formation is not rate-limiting, or that ALA synthase is not the only source of ALA for bacterial heme synthesis in nodules. Plant cytosol from nodules catalyzed the formation of radiolabeled ALA from U-[¹⁴C]glutamate and 3,4-[³H]glutamate but not from 1-[¹⁴C]glutamate, and thus, operation of the C₅ pathway could not be confirmed.     

delta-Aminolevulinate uptake by Rhizobium bacteroids and its limitation by the peribacteroid membrane in Legume nodules.

Heme is overproduced during Rhizobium-Legume symbiosis and delta-aminolevulinate (ALA) is a common precursor in both bacterial and plant synthesis pathways of this molecule. ALA uptake by bacteroids from French bean and soybean nodules was characterized. The action of several metabolic inhibitors and the competition effect of malate on this uptake were studied. ALA transport appeared to be mediated by the dicarboxylate carrier system. Purified symbiosomes--bacteroids surrounded by the peribacteroid membrane--failed to accumulate significant amount of ALA. These experiments rule out the possibility for the plant cytosol to provide the bacteroid with ALA and strengthen the restrictive role of the peribacteroid membrane for exchanges between the two symbiotic partners.     

delta-Aminolevulinic acid dehydratase deficiency can cause delta-aminolevulinate auxotrophy in Escherichia coli

Ethylmethane sulfonate-induced mutants of several Escherichia coli strains that required delta-aminolevulinic acid (ALA) for growth were isolated by penicillin enrichment or by selection for respiratory-defective strains resistant to the aminoglycoside antibiotic kanamycin. Three classes of mutants were obtained. Two-thirds of the strains were mutants in hemA. Representative of a third of the mutations was the hem-201 mutation. This mutation was mapped to min 8.6 to 8.7. Complementation of the auxotrophic phenotype by wild-type DNA from the corresponding phage 8F10 allowed the isolation of the gene. DNA sequence analysis revealed that the hem-201 gene encoded ALA dehydratase and was similar to a known hemB gene of E. coli. Complementation studies of hem-201 and hemB1 mutant strains with various hem-201 gene subfragments showed that hem-201 and the previously reported hemB1 mutation are in the same gene and that no other gene is required to complement the hem-201 mutant. ALA-forming activity from glutamate could not be detected by in vitro or in vivo assays. Extracts of hem-201 cells had drastically reduced ALA dehydratase levels, while cells transformed with the plasmid-encoded wild-type gene possessed highly elevated enzyme levels. The ALA requirement for growth, the lack of any ALA-forming enzymatic activity, and greatly reduced ALA dehydratase activity of the hem-201 strain suggest that a diffusible product of an enzyme in the heme biosynthetic pathway after ALA formation is involved in positive regulation of ALA biosynthesis. In contrast to the hem-201 mutant, previously isolated hemB mutants were not ALA auxotrophs and had no detectable ALA dehydratase activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of culture conditions on production of 5-aminolevulinic acid by recombinant Escherichia coli

Aminolevulinic acid (ALA) is formed by the enzyme ALA synthase (hemA gene). Then ALA is converted to Porphobilinogen (PBG) by the ALA dehydratase (hemB gene). For the overproduction of ALA, we used an Escherichia coli BL21(DE3) containing a hemA gene from Bradyrhzobium japonicum, which was created in our previous work. The effects of pH on the ALA synthase and ALA dehydratase were investigated. The ALA synthase and ALA dehydratase activities were dependent on the pH of the medium, with maximal activities occurring at pH 6.5 and 8.0 respectively. At pH 6.5, extracellular ALA reached 23 mM in a jar-fermenter. In addition, the effects of some nutritional factors, such as nitrogen source and the ratio of carbon to nitrogen (C/N) on the fermentative production of ALA were investigated. The highest ALA production was found with 8:1 of C/N ratio. Among various nitrogen sources, the tryptone might be a useful one for ALA production.     

A soybean coproporphyrinogen oxidase gene is highly expressed in root nodules

In plants the enzyme coproporphyrinogen oxidase catalyzes the oxidative decarboxylation of coproporphyrinogen III to protoporphyrinogen IX in the heme and chlorophyll biosynthesis pathway(s).We have isolated a soybean coproporphyrinogen oxidase cDNA from a cDNA library and determined the primary structure of the corresponding gene. The coproporphyrinogen oxidase gene encodes a polypeptide with a predicted molecular mass of 43 kDa. The derived amino acid sequence shows 50% similarity to the corresponding yeast amino acid sequence. The main difference is an extension of 67 amino acids at the N-terminus of the soybean polypeptide which may function as a transit peptide.A full-length coproporphyrinogen oxidase cDNA clone complements a yeast mutant deleted of the coproporphyrinogen oxidase gene, thus demonstrating the function of the soybean protein.The soybean coproporphyrinogen oxidase gene is highly expressed in nodules at the stage where several late nodulins including leghemoglobin appear. The coproporphyrinogen oxidase mRNA is also detectable in leaves but at a lower level than in nodules while no mRNA is detectable in roots.The high level of coproporphyrinogen oxidase mRNA in soybean nodules implies that the plant increases heme production in the nodules to meet the demand for additional heme required for hemoprotein formation.     

Cadmium induced oxidative stress in soybean plants also by the accumulation of δ-aminolevulinic acid

Cadmium toxicity has been extensively studied in plants, however its biochemical mechanism of action has not yet been well established. To fulfil this objective, four-weeks-old soybean nodulated plants were treated with 200 μM Cd²⁺ for 48 h. δ-aminolevulinic acid dehydratase (ALA-D, E.C. 4.2.1.24) activity and protein expression, as well as δ-aminolevulinic acid (ALA) and porphobilinogen (PBG) concentrations were determined in nodules, roots and leaves. In vitro experiments carried out in leaves were performed using leaf discs to evaluate the oxidant and antioxidant properties of ALA and S-adenosyl-l-methinone (SAM), respectively. Oxidative stress parameters such as thiobarbituric acid reactive substances (TBARS) and GSH levels as well as superoxide dismutase (SOD, E.C. 1.15.1.1), and guaiacol peroxidase (GPOX, E.C. 1.11.1.7) were also determined. Cadmium treatment caused 100% inhibition of ALA-D activity in roots and leaves, and 72% inhibition in nodules whereas protein expression remained unaltered in the three studied tissues. Plants accumulated ALA in nodules (46%), roots (2.5-fold) and leaves (104%), respect to controls. From in vitro experiments using leaf discs, exposed to ALA or Cd²⁺, it was found that TBARS levels were enhanced, while GSH content and SOD and GPOX activities and expressions were diminished. The protective role of SAM against oxidative stress generated by Cd²⁺ and ALA was also demonstrated. Data presented in this paper let us to suggest that accumulation of ALA in nodules, roots and leaves of soybean plants due to treatment with Cd²⁺ is highly responsible for oxidative stress generation in these tissues.     

The soybean NRAMP homologue,GmDMT1, is a symbiotic divalent metal transporter capable of ferrous iron transport

Iron is an important nutrient in N2-fixing legume root nodules. Iron supplied to the nodule is used by the plant for the synthesis of leghemoglobin, while in the bacteroid fraction, it is used as an essential cofactor for the bacterial N2-fixing enzyme, nitrogenase, and iron-containing proteins of the electron transport chain. The supply of iron to the bacteroids requires initial transport across the plant-derived peribacteroid membrane, which physically separates bacteroids from the infected plant cell cytosol. In this study, we have identified Glycine max divalent metal transporter 1 (GmDmt1), a soybean homologue of the NRAMP/Dmt1 family of divalent metal ion transporters. GmDmt1 shows enhanced expression in soybean root nodules and is most highly expressed at the onset of nitrogen fixation in developing nodules. Antibodies raised against a partial fragment of GmDmt1 confirmed its presence on the peribacteroid membrane (PBM) of soybean root nodules. GmDmt1 was able to both rescue growth and enhance 55Fe(II) uptake in the ferrous iron transport deficient yeast strain (fet3fet4). The results indicate that GmDmt1 is a nodule-enhanced transporter capable of ferrous iron transport across the PBM of soybean root nodules. Its role in nodule iron homeostasis to support bacterial nitrogen fixation is discussed.     

Preparation of a complementary DNA for leghaemoglobin and direct demonstration that leghaemoglobin is encoded by the soybean genome

In soybean root nodules, leghaemoglobin (Lb) accounts for 25--30% of the total soluble protein but is not detected in other tissues. In order to determine whether the Lb genes are plant or bacterial in origin a cDNA probe for Lb was prepared from 9S poly (A) containing mRNA of root nodules. Although this 9S mRNA directed synthesis of predominantly three forms of Lb in vitro, the kinetics of hybridisation of cDNA and the 9S mRNA showed a transition at about 30% hybridisation which suggested that the 9S-cDNA was not pure Lb-cDNA. The abundant, Lb-cDNA was prepared by two cycles of hybridising 9S mRNA and cDNA to a Rot of 3 X 10(-3) and isolation of the hybridised cDNA on hydroxyapatite. The Lb-cDNA was homogeneous in hybridisation analysis with 9S mRNA and electrophoresis in 98% formamide gels. This cDNA hybridised with soybean DNA and not with Rhizobium DNA, thus directly demonstrating that Lb genes are of plant origin. Titration of Lb-cDNA with soybean DNA showed that Lb genes are reiterated about forty-fold per haploid genome.     

Leaf Developmental Age Controls Expression of Genes Encoding Enzymes of Chlorophyll and Heme Biosynthesis in Pea (Pisum sativum L.)

The effects of leaf developmental age on the expression of three nuclear gene families in pea (Pisum sativum L.) coding for enzymes of chlorophyll and heme biosynthesis have been examined. The steady-state levels of mRNAs encoding aminolevulinic acid (ALA) dehydratase, porphobilinogen (PBG) deaminase, and NADPH:protochlorophyllide reductase were measured by RNA gel blot and quantitative slot-blot analyses in the foliar leaves of embryos that had imbibed for 12 to 18 h and leaves of developing seedlings grown either in total darkness or under continuous white light for up to 14 d after imbibition. Both ALA dehydratase and PBG deaminase mRNAs were detectable in embryonic leaves, whereas mRNA encoding the NADPH:protochlorophyllide reductase was not observed at this early developmental stage. All three gene products were found to increase to approximately the same extent in the primary leaves of pea seedlings during the first 6 to 8 d after imbibition (postgermination) regardless of whether the plants were grown in darkness or under continuous white-light illumination. In the leaves of dark-grown seedlings, the highest levels of message accumulation were observed at approximately 8 to 10 d postgermination, and, thereafter, a steady decline in mRNA levels was observed. In the leaves of light-grown seedlings, steady-state levels of mRNA encoding the three chlorophyll biosynthetic enzymes were inversely correlated with leaf age, with youngest, rapidly expanding leaves containing the highest message levels. A corresponding increase in the three enzyme protein levels was also found during the early stages of development in the light or darkness; however, maximal accumulation of protein was delayed relative to peak levels of mRNA accumulation. We also found that although protochlorophyllide was detectable in the leaves immediately after imbibition, the time course of accumulation of the phototransformable form of the molecule coincided with NADPH:protochlorophyllide reductase expression. In studies in which dark-grown seedlings of various ages were subsequently transferred to light for 24 and 48 h, the effect of light on changes in steady-state mRNA levels was found to be more pronounced at later developmental stages. These results suggest that the expression of these three genes and likely those genes encoding other chlorophyll biosynthetic pathway enzymes are under the control of a common regulatory mechanism. Furthermore, it appears that not light, but rather as yet unidentified endogenous factors, are the primary regulatory factors controlling gene expression early in leaf development.     

Forcing expression of a soybean root glutamine synthetase gene in tobacco leaves induces a native gene encoding cytosolic enzyme

Glutamine synthetase (GS; EC 6.3.1.2) is present in different subcellular compartments in plants. It is located in the cytoplasm in root and root nodules while generally present in the chloroplasts in leaves. The expression of GS gene(s) is enhanced in root nodules and in soybean roots treated with ammonia. We have isolated four genes encoding subunits of cytosolic GS from soybean (Glycine max L. cv. Prize). Promoter analysis of one of these genes (GS15) showed that it is expressed in a root-specific manner in transgenic tobacco and Lotus corniculatus, but is induced by ammonia only in the legume background. Making the GS15 gene expression constitutive by fusion with the CaMV-35S promoter led to the expression of GS in the leaves of transgenic tobacco plants. The soybean GS was functional and was located in the cytoplasm in tobacco leaves where this enzyme is not normally present. Forcing this change in the location of GS caused concomitant induction of the mRNA for a native cytosolic GS in the leaves of transgenic tobacco. Shifting the subcellular location of GS in transgenic plants apparently altered the nitrogen metabolism and forced the induction in leaves of a native GS gene encoding a cytosolic enzyme. The latter is normally expressed only in the root tissue of tobacco. This phenomenon may suggest a hitherto uncharacterized metabolic control on the expression of certain genes in plants.     

Expression of a Soybean Gene Encoding the Tetrapyrrole-Synthesis Enzyme Glutamyl-tRNA Reductase in Symbiotic Root Nodules

Heme and chlorophyll accumulate to high levels in legume root nodules and in photosynthetic tissues, respectively, and they are both derived from the universal tetrapyrrole precursor δ-aminolevulinic acid (ALA). The first committed step in ALA and tetrapyrrole synthesis is catalyzed by glutamyl-tRNA reductase (GTR) in plants. A soybean (Glycine max) root-nodule cDNA encoding GTR was isolated by complementation of an Escherichia coli GTR-defective mutant for restoration of ALA prototrophy. Gtr mRNA was very low in uninfected roots but accumulated to high levels in root nodules. The induction of Gtr mRNA in developing nodules was subsequent to that of the gene Enod2 (early nodule) and coincided with leghemoglobin mRNA accumulation. Genomic analysis revealed two Gtr genes, Gtr1 and a 3′ portion of Gtr2, which were isolated from the soybean genome. RNase-protection analysis using probes specific to Gtr1 and Gtr2 showed that both genes were expressed, but Gtr1 mRNA accumulated to significantly higher levels. In addition, the qualitative patterns of expression of Gtr1 and Gtr2 were similar to each other and to total Gtr mRNA in leaves and nodules of mature plants and etiolated plantlets. The data indicate that Gtr1 is universal for tetrapyrrole synthesis and that a Gtr gene specific for a tissue or tetrapyrrole is unlikely. We suggest that ALA synthesis in specialized root nodules involves an altered spatial expression of genes that are otherwise induced strongly only in photosynthetic tissues of uninfected plants.Soybean (Glycine max) and numerous other legumes can establish a symbiosis with rhizobia, resulting in the formation of root nodules comprising specialized plant and bacterial cells (for review, see Mylona et al., 1995). Rhizobia reduce atmospheric nitrogen to ammonia within nodules, which is assimilated by the plant host to fulfill its nutritional nitrogen requirement. The high energy requirement for nitrogen fixation necessitates efficient respiration by the prokaryote within the microaerobic milieu of the nodule. The plant host synthesizes a nodule-specific hemoglobin (leghemoglobin) that serves to facilitate oxygen diffusion to the bacterial endosymbiont and to buffer the free oxygen concentration at a low tension (for review, see Appleby, 1992). Both of these functions require that the hemoglobin concentration be high, and, indeed, it exceeds 1 mm in soybean nodules (Appleby, 1984) and is the predominant plant protein in that organ. Once thought to be confined to legume nodules, hemoglobins are found throughout the plant kingdom, and leghemoglobin likely represents a specialization of a general plant phenomenon (for review, see Hardison, 1996). A gene encoding a nonsymbiotic hemoglobin has been identified in soybean and other legumes (Andersson et al., 1996); therefore, expression in nodules involves the specific activation of a subset of genes within a gene family. Leghemoglobin genes may have arisen from gene duplication, followed by specialization (Andersson et al., 1996).Hemes and chlorophyll are tetrapyrroles synthesized from common precursors; chlorophyll is quantitatively the major tetrapyrrole in plants, with heme and other tetrapyrroles being present in minor amounts. Legume root nodules represent an exception, in which heme is synthesized in high quantity in the absence of chlorophyll, thus requiring the activity of enzymes not normally expressed highly in nonphotosynthetic tissues. Heme is synthesized from the universal tetrapyrrole precursor ALA by seven successive enzymatic steps; chlorophyll formation diverges after the synthesis of protoporphyrin, the immediate heme precursor (for review, see O''Brian, 1996). Biochemical and genetic evidence shows that soybean heme biosynthesis genes are strongly induced in root nodules (Sangwan and O''Brian, 1991, 1992, 1993; Madsen et al., 1993; Kaczor et al., 1994; Frustaci et al., 1995; Santana et al., 1998), and immunohistochemical studies demonstrate that induction is concentrated in infected nodule cells (Santana et al., 1998).ALA is synthesized from Glu in plants by a three-step mechanism called the C₅ pathway (Fig. ​(Fig.1);1); the latter two steps are committed to ALA synthesis and are catalyzed by GTR and GSAT, respectively (for review, see Beale and Weinstein, 1990; Jahn et al., 1991). Plant cDNA or genes encoding GTR (Gtr, also called HemA) and GSAT (Gsa) have been identified in several plant species (Grimm, 1990; Sangwan and O''Brian, 1993; Hofgen et al., 1994; Ilag et al., 1994; Frustaci et al., 1995; Wenzlau and Berry-Lowe, 1995; Bougri and Grimm, 1996; Kumar et al., 1996; Tanaka et al., 1996). Two genes for each enzyme have been described, and some genes are reported to be specific to a tissue, tetrapyrrole, or light regimen (Bougri and Grimm, 1996; Kumar et al., 1996; Tanaka et al., 1996). However, soybean Gsa1 is highly expressed in both leaves and nodules and contains a cis-acting element in its promoter that binds to a nuclear factor found in both tissues. (Frustaci et al., 1995). In this study we isolated soybean Gtr1 and characterized the genetic basis of GTR expression in root nodules. Figure 1C₅ pathway for ALA synthesis. The committed steps for ALA synthesis catalyzed by GTR and GSAT are boxed. Glutamyl-tRNA synthetase (GluRS) and glutamyl-tRNA^Glu also participate in protein synthesis. The gene designations in plants are shown in parentheses ...     

Decrease of hepatic delta-aminolevulinate dehydratase activity in an animal model of fatigue

Fatigue can be defined physiologically as inability to maintain the expected power output. At present, no standard of fatigue are yet available. In order to find biomarkers of fatigue, we investigated the level of delta-aminolevulinic acid (ALA), the first intermediate metabolite in the heme biosynthetic pathway, in the plasma and urine of an animal model of fatigue. To prepare fatigued animals, we kept rats for 5 days in a cage filled with water to a height of 1.5 cm. As a result, the plasma and urinary ALA levels were increased in the fatigued animals as compared with those in the control animals. One day after the rats had been returned to their normal cages, these increased levels were restored to the control ones. We also examined the activity of the enzyme ALA dehydratase (ALAD), which is the second enzyme in the heme biosynthetic pathway, and ALAD gene expression during the fatigue and its recovery sessions. The ALAD activity, as well as its gene expression, in the liver of the fatigued animals was decreased as compared with those of the control animals. Both activity and gene expression of ALAD were recovered to their respective control levels after the rats had been allowed to rest in their normal cages for 1 day. Furthermore, the activity of ALA synthase (ALAS), the rate-limiting enzyme in the heme biosynthesis, in the liver was increased after the fatigue session for 5 days. Although this level of increase in the plasma concentration of ALA may not induce fatigue, increase in plasma and urinary ALA levels can be biomarkers of fatigue.