Succinate production and citrate catabolism by Cheddar cheese nonstarter lactobacilli

AIMS: To identify strains of Cheddar cheese nonstarter lactobacilli that synthesize succinate from common precursors and characterize the biochemical pathways utilized. METHODS AND RESULTS: Whole cell incubations of Lactobacillus plantarum, Lactobacillus casei, Lactobacillus zeae and Lactobacillus rhamnosus, were used to identify strains that accumulated succinate from citrate, l-lactate, aspartic acid or isocitrate. In vivo 13C-nuclear magnetic resonance spectroscopy (13C-NMR) identified the biochemical pathway involved at pH 7.0, and under conditions more representative of the cheese ripening environment (pH 5.1/4% NaCl/13 degrees C). Enzyme assays on cell-free extracts were used to support the pathway suggested by 13C-NMR. CONCLUSIONS: The Lact. plantarum strains studied synthesize succinate from citrate by the reductive tricarboxylic acid (TCA) cycle at either pH 7.0 or pH 5.1/4% NaCl/13 degrees C. Lactobacillus casei, Lact. zeae and Lact. rhamnosus strains lack one or more enzymatic activities present in this pathway, and do not accumulate succinate from any of the four precursors studied. SIGNIFICANCE AND IMPACT OF THE STUDY: The addition of Lact. plantarum strains to milk during cheese manufacture may increase the accumulation of the flavour enhancer succinate.     

Acute hibernation decreases myocardial pyruvate carboxylation and citrate release

In the well-perfused heart, pyruvate carboxylation accounts for 3-6% of the citric acid cycle (CAC) flux, and CAC carbon is lost via citrate release. We investigated the effects of an acute reduction in coronary flow on these processes and on the tissue content of CAC intermediates. Measurements were made in an open-chest anesthetized swine model. Left anterior descending coronary artery blood flow was controlled by a extracorporeal perfusion circuit, and flow was decreased by 40% for 80 min to induce myocardial hibernation (n = 8). An intracoronary infusion of [U-(13)C(3)]lactate and [U-(13)C(3)]pyruvate was given to measure the entry of pyruvate into the CAC through pyruvate carboxylation from the (13)C-labeled isotopomers of CAC intermediates. Compared with normal coronary flow, myocardial hibernation resulted in parallel decreases of 65% and 79% in pyruvate carboxylation and net citrate release by the myocardium, respectively, and maintenance of the CAC intermediate content. Elevation of the arterial pyruvate concentration by 1 mM had no effect. Thus a 40% decrease in coronary blood flow resulted in a concomitant decrease in pyruvate carboxylation and citrate release as well as maintenance of the CAC intermediates.     

Determination of pyruvate dehydrogenase and acetyl-CoA synthetase activities using citrate synthase

Methods are described for the assay of pyruvate dehydrogenase and acetyl-CoA synthetase activities in rat brain subcellular fractions. Citrate synthase and oxaloacetate serve as a trapping system in these assays. The methods permit the determination of a large number of samples of different turbidity with satisfactory precision. Highest activities of pyruvate dehydrogenase and acetyl-CoA synthetase (117.7 and 7.29 nmol/min/mg of protein, respectively) were found in rat brain mitochondria. A three times lower activity of acetyl-CoA synthetase and negligible of pyruvate dehydrogenase was found in brain cytosol.     

Metabolism of pyruvate and malate by isolated fat-cell mitochondria

1. Metabolism of pyruvate and malate by isolated fat-cell mitochondria incubated in the presence of ADP and phosphate has been studied by measuring rates of pyruvate uptake, malate utilization or production, citrate production and oxygen consumption. From these measurements calculations of the flow rates through pyruvate carboxylase, pyruvate dehydrogenase and citrate cycle have been made under various conditions. 2. In the presence of bicarbonate, pyruvate was largely converted into citrate and malate and only about 10% was oxidized by the citrate cycle; citrate and malate outputs were linear after lag periods of 6-9min and 3min respectively, and no other end products of pyruvate metabolism were detected. On the further addition of malate or hydroxymalonate, the lag in the rate of citrate output was less marked but no net malate disappearance was detected. If, however, bicarbonate was omitted then net malate uptake was observed. Addition of butyl malonate was found to greatly inhibit the metabolism of pyruvate to citrate and malate in the presence of bicarbonate. 3. These results are in agreement with earlier conclusions that in adipose tissue acetyl units for fatty acid synthesis are transferred to the cytoplasm as citrate and that this transfer requires malate presumably for counter transport. They also support the view that oxaloacetate for citrate synthesis is preferentially formed from pyruvate through pyruvate carboxylase rather than malate through malate dehydrogenase and that the mitochondrial metabolism of citrate in fat-cells is restricted. The possible consequences of these conclusions are discussed. 4. Studies on the effects of additions of adenine nucleotides to pyruvate metabolism by isolated fat-cell mitochondria are consistent with inhibition of pyruvate carboxylase in the presence of ADP and pyruvate dehydrogenase in the presence of ATP.     

Metabolism of pyruvate and carnitine esters in bovine epididymal sperm mitochondria

Filipin-treated bovine epididymal spermatozoa have been used to study mitochondrial l-acetylcarnitine, l-palmitoylcarnitine, and pyruvate metabolism. The cells were supplemented with malate to allow rapid rates of substrate oxidation. The rate of l-palmitoylcarnitine-supported state 3 respiration was slow. In contrast, pyruvate, acetylcarnitine, or lactate supported rapid and approximately equal respiratory rates. l-Palmitoylcarnitine was a weak inhibitor of pyruvate-supported respiration and pyruvate use and a more potent inhibitor of l-acetylcarnitine. l-Carnitine was an effective inhibitor of l-acetylcarnitine oxidation; however, it did not influence l-palmitoylcarnitine oxidation or inhibit pyruvate utilization. Pyruvate (1.4 mm) disappearance was rapid and was complete within 6–7 min; the lactate produced during pyruvate metabolism was then oxidized. ATP synthesis was constant throughout the 20-min incubation. With pyruvate plus l-acetylcarnitine as substrate, the l-acetylcarnitine concentration initially dropped and then recovered to a level that was dependent on free carnitine addition. Data obtained from experiments using [2-¹⁴C]pyruvate indicated that the ¹⁴C label from pyruvate and lactate entered the l-acetylcarnitine pool and labeling was maximal when free l-carnitine was added. The rate of citrate synthesis was maximal when pyruvate was being metabolized; the largest total accumulation occurred when all three substrates were included in the incubation. The data suggest that the high NAD⁺/ NADH maintained during pyruvate metabolism may restrict flux through the citric acid cycle. The relationships of l-carnitine and the l-carnitine esters to pyruvate metabolism are discussed.     

Metabolism and some characteristics of lactobacilli isolated from the rumen of young calves

Fourteen strains of lactobacilli isolated from the rumen of young calves were studied to determine their biochemical characteristics, growth parameters, metabolism on lactose and sensitivity to 28 antimicrobial agents. Thirteen homofermentative strains belonged to Lactobacillus acidophilus and one heterofermentative strain resembled Lact. fermentum. The relevance of rumen lactobacilli to the nutrition of calves is discussed.     

Metabolism and some characteristics of lactobacilli isolated from the rumen of young calves

Fourteen strains of lactobacilli isolated from the rumen of young calves were studied to determine their biochemical characteristics, growth parameters, metabolism on lactose and sensitivity to 28 antimicrobial agents. Thirteen homofermentative strains belonged to Lactobacillus acidophilus and one heterofermentative strain resembled Lact. fermentum. The relevance of rumen lactobacilli to the nutrition of calves is discussed.     

Fermentation of trans-aconitate via citrate,oxaloacetate, and pyruvate by Acidaminococcus fermentans

Growing cells of Acidaminococcus fermentans (DSM 20731 and ATCC 25085) fermented trans-aconitate via citrate, oxaloacetate, and pyruvate to approximately 2 CO₂, 1.8 acetate, 0.1 butyrate and 0.9 H₂. The carbon and electron recoveries were close to 100%. On citrate no growth was observed and washed cells were unable to ferment this tricarboxylate. In cell-free extracts, however, citrate as well as trans-aconitate were readily fermented to CO₂ and acetate. Under these conditions, also cis-aconitate, oxaloacetate, and pyruvate were formed, whereas butyrate and intermediates of glutamate fermentation, 2-oxoglutatrate and glutaconate, could not be detected. Citrate Si-lyase, a Mg²⁺-dependent oxaloacetate decarboxylase, and pyruvate synthase were present in quantities that corresponded to the growth rate of the organism. Received: 3 May 1996 / Accepted: 12 August     

Comparative development of the pyruvate dehydrogenase complex and citrate synthase in rat brain mitochondria.

The enzyme activity of the pyruvate dehydrogenase complex (PDHC) was measured in mitochondria prepared from developing rat brain, before and after steady-state dephosphorylation of the E1 alpha subunit. A marked increase in dephosphorylated (fully activated) PDHC activity occurred between days 10 and 15 post partum, which represented approx. 60% of the difference in fully activated PDHC activity measured in foetal and adult rat brain mitochondria. There was no detectable change in the active proportion of the enzyme during mitochondrial preparation nor any qualitative alteration in the detectable catalytic and regulatory components of the complex, which might account for developmental changes in PDHC activity. The PDHC protein content of developing rat brain mitochondria and homogenates was measured by an enzyme-linked immunoadsorbent assay. The development of PDHC protein in both fractions agreed closely with the development of the PDHC activity. The results suggest that the developmental increase in PDHC activity is due to increased synthesis of PDHC protein, which is partly a consequence of an increase in mitochondrial numbers. However, the marked increase in PDHC activity measured between days 10 and 15 post partum is mainly due to an increase in the amount of PDHC per mitochondrion. The development of citrate synthase enzyme activity and protein was measured in rat brain homogenates and mitochondria. As only a small increase in citrate synthase activity and protein was detected in mitochondria between days 10 and 15 post partum, the marked increase in PDHC protein and enzyme activity may represent specific PDHC synthesis. As several indicators of acquired neurological competence become apparent during this period, it is proposed that preferential synthesis of PDHC may be crucial to this process. The results are discussed with respect to the possible roles played by PDHC in changes of respiratory-substrate utilization and the acquisition of neurological competence occurring during the development of the brain of a non-precocial species such as the rat.