Two biochemically distinct classes of fumarase in Escherichia coli

Biochemical studies with strains of Escherichia coli that are amplified for the products of the three fumarase genes, fumA (FUMA), fumB (FUMB) and fumC (FUMC), have shown that there are two distinct classes of fumarase. The Class I enzymes include FUMA, FUMB, and the immunologically related fumarase of Euglena gracilis. These are characteristically thermolabile dimeric enzymes containing identical subunits of Mr 60,000. FUMA and FUMB are differentially regulated enzymes that function in the citric acid cycle (FUMA) or to provide fumarate as an anaerobic electron acceptor (FUMB), and their affinities for fumarate and L-malate are consistent with these roles. The Class II enzymes include FUMC, and the fumarases of Bacillus subtilis, Saccharomyces cerevisiae and mammalian sources. They are thermostable tetrameric enzymes containing identical subunits Mr 48,000-50,000. The Class II fumarases share a high degree of sequence identity with each other (approx. 60%) and with aspartase (approx. 38%) and argininosuccinase (approx. 15%), and it would appear that these are all members of a family of structurally related enzymes. It is also suggested that the Class I enzymes may belong to a wider family of iron-dependent carboxylic acid hydro-lyases that includes maleate dehydratase and aconitase. Apart from one region containing a Gly-Ser-X-X-Met-X-X-Lys-X-Asn consensus sequence, no significant homology was detected between the Class I and Class II fumarases.     

Fumarase a from Escherichia coli: purification and characterization as an iron-sulfur cluster containing enzyme.

It has been shown previously that Escherichia coli contains three fumarase genes designated fumA, fumB, and fumC. The gene products fumarases A, B, and C have been divided into two classes. Class I contains fumarases A and B, which have amino acid sequences that are 90% identical to each other, but have almost no similarity to the sequence of porcine fumarase. Class II contains fumarase C and porcine fumarase, which have amino acid sequences 60% identical to each other [Woods, S.A., Schwartzbach, S.D., & Guest, J.R. (1988) Biochim. Biophys. Acta 954, 14-26]. In this work it is shown that purified fumarase A contains a [4Fe-4S] cluster. This conclusion is based on the following observations. Fumarase A contains 4 Fe and 4 S2- per mole of protein monomer. (The mobility of fumarase A in native polyacrylamide gel electrophoresis and the elution volume on a gel permeation column indicate that it is a homodimer.) Its visible and circular dichroism spectra are characteristic of proteins containing an Fe-S cluster. Fumarase A can be reduced to an EPR active-state exhibiting a spectrum consisting of a rhombic spectrum at high fields (g-values = 2.03, 1.94, and 1.88) and a broad peak at g = 5.4. Upon addition of substrate, the high field signal shifts upfield (g-values = 2.035, 1.92, and 1.815) and increases in total spins by 8-fold, while the g = 5.4 signal disappears.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nutritional regulation of organelle biogenesis inEuglena: Photo- and metabolite induction of mitochondria

Exposure of dark-grown restingEuglena gracilis Klebs var.bacillaris Cori to light, ethanol, or malate produced an increase in the specific activity of fumarase (EC. 4.2.1.2) and succinate dehydrogenase (EC. 1.3.99.1) during the first 8–12 h of exposure to inducer, followed by a decrease in the specific activity of both mitochondrial enzymes between 12 and 72 h. The increased specific activity represented a net increase in the level of active enzyme, and it was dependent upon cytoplasmic protein synthesis. The photoinduction of fumarase required continuous illumination while the subsequent decrease in fumarase specific activity was independent of light. Light had little effect on the ethanol and malate induction of fumarase and succinate dehydrogenase. In the mutant W₃BUL, which has no detectable protochlorophyll(ide) and chloroplast DNA, light induced both mitochondrial enzymes and the kinetics of enzyme induction were similar to the induction kinetics in wild-type cells. The induction of mitochondrial enzymes appears to be controlled by a non-chloroplast photoreceptor. Dark-grown resting cells of the plastidless mutant W₁₀SmL have lost the ability to regulate fumarase levels. In this mutant, the specific activity of fumarase fluctuated and light had little effect on these fluctuations, indicating that fumarase synthesis was uncoupled from the nonchloroplast photoreceptor. Ethanol addition produced transient changes in fumarase specific activity in W₁₀SmL indicating that in this mutant, mitochondrial enzymes are still inductible by metabolites. Fumarase synthesis in wild-type cells was not induced in the dark by levulinic acid, a chemical inducer of the breakdown ofEuglena storage carbohydrates. Taken together, our results indicate that the photoinduction of mitochondrial enzyme synthesis is not a result of the photoinduction of carbohydrate breakdown. The mechanisms by which light and organic carbon induce the synthesis ofEuglena mitochondria may differ.     

Anaerobic growth of Escherichia coli on d-tartrate depends on the fumarate carrier DcuB and fumarase, rather than the l-tartrate carrier TtdT and l-tartrate dehydratase

Escherichia coli is able to grow under anaerobic conditions on D: -tartrate when glycerol is supplied as an electron donor (D-tartrate fermentation). D-Tartrate was converted to succinate. Growth was lost in strains deficient for DcuB, the fumarate/succinate antiporter of fumarate respiration. The L-tartrate/succinate antiporter TtdT of L-tartrate fermentation, or the C4-dicarboxylate carriers DcuA and DcuC, were not able to support D-tartrate transport and fermentation. Deletion of fumB demonstrated, that fumarase B is required for growth on D-tartrate. The mutant lost most (about 79%) of D-tartrate dehydratase activity. L-Tartrate dehydratase (TtdAB), and fumarase A or C, showed no or only a small contribution to D-tartrate dehydratase activity. Therefore D-tartrate is metabolised by a sequence of reactions analogous to that from L-tartrate fermentation, including dehydration to oxaloacetate, which is then converted to malate, fumarate and succinate. The stereoisomer specific carrier TtdT and dehydratase TtdAB of L-tartrate fermentation are substituted by enzymes from general anaerobic fumarate metabolism, the antiporter DcuB and fumarase B, which have a broader substrate specificity. No D-tartrate specific carriers and enzymes are involved in the pathway.     

Protective effects of ibuprofen and its major metabolites against in vitro inactivation of catalase and fumarase: relevance to cataract

Ibuprofen and its major metabolites were incubated with catalase and fumarase, in the presence of protein-modifying biomolecules, to explore the mode of action of ibuprofen in protection against cataract. Both 2 and 10 mM ibuprofen/metabolites protected catalase against fructose-, cyanate- and prednisolone-induced inactivation; the carboxy-metabolite gave the highest protection (31%). The 2 mM ibuprofen/metabolites protected fumarase against fructose- and cyanate-induced inactivation by up to 26%, but had no effect on prednisolone-induced inactivation. Ibuprofen/metabolites did not bind to catalase or fumarase. They penetrated into the lens in vitro. When in the lens, the metabolites may reduce the risk of cataract by protecting lenticular enzymes.     

Crystal structure of 3-carboxy-cis,cis-muconate lactonizing enzyme from Pseudomonas putida, a fumarase class II type cycloisomerase: enzyme evolution in parallel pathways

3-Carboxy-cis,cis-muconate lactonizing enzymes (CMLEs), the key enzymes in the protocatechuate branch of the beta-ketoadipate pathway in microorganisms, catalyze the conversion of 3-carboxy-cis,cis-muconate to muconolactones. We have determined the crystal structure of the prokaryotic Pseudomonas putida CMLE (PpCMLE) at 2.6 A resolution. PpCMLE is a homotetramer and belongs to the fumarase class II superfamily. The active site of PpCMLE is formed largely by three regions, which are moderately conserved in the fumarase class II superfamily, from three respective monomers. It has been proposed that residue His141, which is highly conserved in all fumarase class II enzymes and forms a charge relay with residue Glu275 (both His141 and Glu275 are in adenylosuccinate lyase numbering), acts as the general base in most fumarase class II superfamily members. However, this charge relay pair is broken in PpCMLE. The residues corresponding to His141 and Glu275 are Trp153 and Ala289, respectively, in PpCMLE. The structures of prokaryotic MLEs and that of CMLE from the eukaryotic Neurospora crassa are completely different from that of PpCMLE, indicating MLEs and CMLEs, as well as the prokaryotic and eukaryotic CMLEs, evolved from distinct ancestors, although they catalyze similar reactions. The structural differences may be related to recognition by substrates and to differences in the mechanistic pathways by which these enzymes catalyze their respective reactions.     

Physiological roles of two enzymes with fumarase activity in two Pseudomonads

Effects of Fe2+ ions on the levels of two enzymes (fumarase and mesaconase) with fumarase activity in two Pseudomonads grown under various nutritional conditions were investigated. Fe2+ ions decreased fumarase but increased mesaconase. A high level of mesaconase was found in Ps. arvilla which was unable to metabolize itaconate. The level of mesaconase in the itaconate-grown cells of Ps. fluorescens was almost the same as that in the glucose-grown cells. This suggests that mesaconase is not an enzyme involved in the metabolism of C5-branched-chain dicarboxylates but presumably, taking the place of fumarase, plays a role in the operation of the tricarboxylic acid cycle in the cells grown in the medium containing Fe2+ ions more than 10 nmol/ml.     

ENZYMES OF THE TRICARBOXYLIC ACID CYCLE IN SEA URCHIN EGGS AND EMBRYOS

Changes in the activity of some enzymes of the tricarboxylic acid cycle during development of sea urchins were investigated. Unfertilized eggs showed substantial activity of citrate synthase, aconitase, NAD- and NADP-specific isocitrate dehydrogenases, fumarase and malate dehydrogenase. During development, the activity of citrate synthase, aconitase, NADP-specific isocitrate dehydrogenase and malate dehydrogenase increases gradually, whereas the activity of fumarase remains rather constant. There is no close correlation between changes in the enzyme activity and the increase in oxygen consumption during development. Citrate synthase, aconitase, NADP-specific isocitrate dehydrogenase are mainly localized in the mitochondrial fraction, whereas fumarase and malate dehydrogenase are present in both mitochondrial and cytosol fractions. The intracellular localization of these enzymes does not change during development. A possible mechanism for the regulation of some enzymes of the tricarboxylic acid cycle in sea urchin eggs is discussed.     

The Evolution of Acetyl-CoA Synthase

Acetyl-coenzyme A synthases (ACS) are Ni-Fe-S containing enzymes found in archaea and bacteria. They are divisible into 4 classes. Class I ACS's catalyze the synthesis of acetyl-CoA from CO2 + 2e-, CoA, and a methyl group, and contain 5 types of subunits (alpha, beta, gamma, delta, and epsilon). Class II enzymes catalyze essentially the reverse reaction and have similar subunit composition. Class III ACS's catalyze the same reaction as Class I enzymes, but use pyruvate as a source of CO2 and 2e-, and are composed of 2 autonomous proteins, an alpha 2 beta 2 tetramer and a gamma delta heterodimer. Class IV enzymes catabolize CO to CO2 and are alpha-subunit monomers. Phylogenetic analyses were performed on all five subunits. ACS alpha sequences divided into 2 major groups, including Class I/II sequences and Class III/IV-like sequences. Conserved residues that may function as ligands to the B- and C-clusters were identified. Other residues exclusively conserved in Class I/II sequences may be ligands to additional metal centers in Class I and II enzymes. ACS beta sequences also separated into two groups, but they were less divergent than the alpha's, and the separation was not as distinct. Class III-like beta sequences contained approximately 300 residues at their N-termini absent in Class I/II sequences. Conserved residues identified in beta sequences may function as ligands to active site residues used for acetyl-CoA synthesis. ACS gamma-sequences separated into 3 groups (Classes I, II, and III), while delta-sequences separated into 2 groups (Class I/II and III). These groups are less divergent than those of alpha sequences. ACS epsilon-sequence topology showed greater divergence and less consistency vis-à-vis the other subunits, possibly reflecting reduced evolutionary constraints due to the absence of metal centers. The alpha subunit phylogeny may best reflect the functional diversity of ACS enzymes. Scenarios of how ACS and ACS-containing organisms may have evolved are discussed.     

Thermostability of enzymes of the tricarboxylic acid cycle ofBacillus coagulans

The thermostability of four enzymes of the tricarboxylic acid cycle has been studied in the facultative thermophile,Bacillus coagulans. Although isocitrate dehydrogenase appeared to be more temperature-sensitive in whole-cell extracts of cultures grown at 30°C compared with that in cultures grown at 55°C, this difference could be largely eliminated by the removal of cell-wall material. The specific activity of each of the enzymes examined was approximately threefold higher in cultures grown at 55°C than in those grown at 30°C. The maximum temperature, Arrhenius plot and effect of stabilizing agents for each enzyme were examined and found to be independent of growth temperature. Sodium chloride (10% w/v) was an effective protective agent for fumarase, aconitase and malate dehydrogenase. Protection from thermal denaturation of isocitrate dehydrogenase, aconitase and fumarase but not malate dehydrogenase was also given when the enzymes were heated in the presence of their substrates. These results are discussed in light of the generalized theories of facultative thermophily which have been proposed.     

The activities of the citric acid-cycle enzymes in rat bone-marrow cells

The activities of the eight citric acid-cycle enzymes of rat bone-marrow cells were determined along with several other mitochondrial and non-mitochondrial enzymes. Four of the citric acid-cycle enzymes (aconitase, succinyl-CoA thiokinase, α-oxoglutarate dehydrogenase and succinate dehydrogenase) have closely similar low activities; two [isocitrate dehydrogenase (NAD) and citrate synthase] have intermediate activities; the remaining two (malate dehydrogenase and fumarase) have high activities. The other enzymes surveyed also exhibited a spread of three orders of magnitude, the mitochondrial enzymes showing no less variation than the others.     

Protective Effect of Betaine on Respiratory Enzymes

Effects of betaine and NaC1 in various concentrations on the activities of enzymes in tricarboxylic acid cycle (isocitric dehydrogenase, malic dehydrogenase, succinic dehydrogenase and fumarase), terminal oxidation (cytochrome oxidase) and photorespiratory pathway (glycolate oxidase and hydroxypyruvate reductase) have been studied. Betaine, in contrast to electolyte NaC1 was non-inhibitory to these enzymes up to 500 mmol/L. Partial protection against NaC1 inhibition to the activities of these enzymes were afforded by betaine. These results were consistent with the postulated role of betaine in cytoplasmic osmoregulation. These results showed that betaine was a superior compatible solute.     

甜菜碱对呼吸酶的保护效应

以菠菜（Ｓｐｉｎａｃｉａ ｏｌｅｒａｃｅａ Ｌ．）叶片为材料,研究了不同浓度的甜菜碱和ＮａＣｌ对三羧酸循环、末端氧化和光呼吸的组成酶的活性的影响。与电解质ＮａＣｌ不同,高浓度的甜菜碱对这些酶的活性是非抑制性的,并对ＮａＣｌ的抑制作用有一定保护效应。甜菜碱是很好的有机渗透调节剂。这与甜菜碱在细胞质中起渗透调节作用,以及是无机渗透调节剂的配伍溶质的假设是一致的。     

Citric acid cycle: gene-enzyme relationships in Bacillus subtilis

The genetic location of mutations affecting the citric acid cycle and the properties of mutants of Bacillus subtilis possessing these mutations have been examined. Genes coding for the component enzymes of the cycle were found to be unlinked to each other and thus do not form an operon. The mutational defect in a mutant lacking fumarase mapped between thr-5 and cysB3. Mutations causing inability to produce isocitrate dehydrogenase and succinate dehydrogenase were found to map between argA11 and leu-1. The alpha-ketoglutarate dehydrogenase mutations were mapped at the terminal end of the B. subtilis chromosome through a weak linkage in phage PBS-1 transduction of one class of these mutations of ilvA2 and metB4. A second class of alpha-ketoglutarate dehydrogenase mutations mapped closer to ilvA2 and metB4 but still terminal with respect to these markers. Aconitaseless mutants possessed mutations that could not be linked to any of the known transducing segments of the chromosome. An effect of mutation conferring loss of one enzyme of the cycle on the specific activity of the other enzymes in the cycle was observed.     

An inverse relation between mitochondrial hexokinase content and phosphoglucomutase activity of rat tissues

Summary The hexokinase: fumarase ratios of mitochondria isolated from ten tissues of the rat were determined, and compared with the tissue content of phosphoglucomutase and phosphorylase, taken as representatives of enzymes concerned with glycogen metabolism. A generally inverse relationship was found between the mitochondrial hexokinase: fumarase ratio and phosphoglucomutase levels. The cytochrome: fumarase ratios were relatively invariant in these same mitochondria. The results are interpreted as indicating a specialization of mitochondria, with increased amounts of hexokinase being associated with the mitochondria in tissues exhibiting less dependence on glycogen metabolism, as judged from phosphoglucomutase levels.     

Fluorescence depolarization studies of conformation changes in pyrene-butyryl–fumarase

Measurements of fluorescence depolarization on fumarase labeled with the dye pyrene-butyryl were used to test for previously reported structural changes in this enzymes. These apparent conformation changes were of interest because they seemed to correlate with variation in catalytic activity provoked by changing temperature or pH, or by the presence of a competitive inhibitor. In the present studies, the bound dye pyrene-butyryl and the enzymes were investigated systematically to ensure that simple interpretation of fluorescence depolarization results would be meaningful. This analysis showed that carefully controlled experimental condition were necessary to eliminate a dye component with a short fluorescence lifetime and that it was essential to allow for small variations of lifetime with temperature. Contrary to the previous report, a constant rotational relaxation time of the magnitude expected for a nearly spherical molecule of fumarase was found. No changes were detectable by fluorescence depolarization in the size or shape of pyrene-butyryl–fumarase under the solution conditions tested that caused variation in enzyme activity.     

Dual localization of fumarase is dependent on the integrity of the glyoxylate shunt

Fumarase and aconitase in yeast are dual localized to the cytosol and mitochondria by a similar targeting mechanism. These two tricarboxylic acid cycle enzymes are single translation products that are targeted to and processed by mitochondrial processing peptidase in mitochondria prior to distribution. The mechanism includes reverse translocation of a subset of processed molecules back into the cytosol. Here, we show that either depletion or overexpression of Cit2 (cytosolic citrate synthase) causes the vast majority of fumarase to be fully imported into mitochondria with a tiny amount or no fumarase in the cytosol. Normal dual distribution of fumarase (similar amounts in the cytosol and mitochondria) depends on an enzymatically active Cit2. Glyoxylate shunt deletion mutations ( Δmls1 , Δaco1 and Δicl1 ) exhibit an altered fumarase dual distribution (like in Δcit2 ). Finally, when succinic acid, a product of the glyoxylate shunt, is added to the growth medium, fumarase dual distribution is altered such that there are lower levels of fumarase in the cytosol. This study suggests that the cytosolic localization of a distributed mitochondrial protein is governed by intracellular metabolite cues. Specifically, we suggest that metabolites of the glyoxylate shunt act as 'nanosensors' for fumarase subcellular targeting and distribution. The possible mechanisms involved are discussed.     

Oxygen- and growth rate-dependent regulation of Escherichia coli fumarase (FumA, FumB, and FumC) activity

Escherichia coli contains three biochemically distinct fumarases which catalyze the interconversion of fumarate to L-malate in the tricarboxylic acid cycle. Batch culture studies indicated that fumarase activities varied according to carbon substrate and cell doubling time. Growth rate control of fumarase activities in the wild type and mutants was demonstrated in continuous culture; FumA and FumC activities were induced four- to fivefold when the cell growth rate (k) was lowered from 1.2/h to 0.24/h at 1 and 21% O(2), respectively. There was a twofold induction of FumA and FumC activities when acetate was utilized instead of glucose as the sole carbon source. However, these fumarase activities were still shown to be under growth rate control. Thus, the activity of the fumarases is regulated by the cell growth rate and carbon source utilization independently. Further examination of FumA and FumC activities in a cya mutant suggested that growth rate control of FumA and FumC activities is cyclic AMP dependent. Although the total fumarase activity increased under aerobic conditions, the individual fumarase activities varied under different oxygen levels. While FumB activity was maximal during anaerobic growth (k = 0.6/h), FumA was the major enzyme under anaerobic cell growth, and the maximum activity was achieved when oxygen was elevated to 1 to 2%. Further increase in the oxygen level caused inactivation of FumA and FumB activities by the high oxidized state, but FumC activity increased simultaneously when the oxygen level was higher than 4%. The same regulation of the activities of fumarases in response to different oxygen levels was also found in mutants. Therefore, synthesis of the three fumarase enzymes is controlled in a hierarchical fashion depending on the environmental oxygen that the cell encounters.