Release Of Pyruvate Research Articles

Enzyme-delivery Metal-organic Framework Composite Coatings for Restoration of Hyperglycemia-damaged Osteoblast Differentiation

There is a significant clinical need to develop effective treatments for bone defects in patients with diabetes mellitus (DM), as they are at higher risk of fractures and impaired healing. Guided bone tissue engineering using biocompatible and biodegradable polymers is a promising approach. However, current diabetic bone regenerative therapies often fail due to the accumulation of advanced glycation products, which can affect the integration of traditional tissue engineering scaffolds with native bone. Therefore, novel approaches are needed to improve the efficacy of diabetic bone regeneration. This study presents a proof-of-concept development of a multifunctional polymer composite coating tailored towards restoring diabetes-related damage in osteoblast differentiation. Our composite system involves 3D-printed poly(caprolactone fumarate) (PCLF) and poly(caprolactone) (PCL) blend scaffolds coated with multifunctional chitosan methacrylate (chiMA). The chiMA coating is embedded with a sustained-release formulation of glucose oxidase (GOx) from MIL-127 metal-organic frameworks making the coating a stimuli-responsive biomolecule delivery system. The multifunctional coating is designed for the sustained release of GOx and sodium pyruvate for in vitro glucose modulation and oxidative stress reduction, respectively. We propose that sustained release of GOx from MIL-127 embedded chiMA coatings can modulate the high glucose (HG) cellular milieu towards normal glucose (NG), enhancing osteoblast (OB) differentiation via downstream effects. Our results show successful synthesis of MIL-127, encapsulation of GOx, and fabrication of composite coating on the PCLF/PCL scaffolds with effective enzyme activity measured as a function of lowering glucose concentration in HG media for 144 h to normal levels. In vitro evaluation of OB viability, attachment, proliferation, and differentiation showed an overall decrease in cellular activity in HG conditions, which was restored through the glucose-modulating functionality of the GOx-releasing MIL-127 coatings. Our results also presented preliminary evidence of a statistical correlation between DM-related gene markers and osteogenic markers in vitro that requires further exploration. Although this proof-of-concept study holds promise for advancing precision biomaterials development for diabetic tissue engineering and meeting the unmet clinical need for effective treatments and warrants future in vivo evaluation of the composite coating and molecular biology understanding of correlations between DM and osteogenic markers.

Modulation of Pyruvate Export and Extracellular Pyruvate Concentration in Primary Astrocyte Cultures

Astrocyte-derived pyruvate is considered to have neuroprotective functions. In order to investigate the processes that are involved in astrocytic pyruvate release, we used primary rat astrocyte cultures as model system. Depending on the incubation conditions and medium composition, astrocyte cultures established extracellular steady state pyruvate concentrations in the range between 150 µM and 300 µM. During incubations for up to 2 weeks in DMEM culture medium, the extracellular pyruvate concentration remained almost constant for days, while the extracellular lactate concentration increased continuously during the incubation into the millimolar concentration range as long as glucose was present. In an amino acid-free incubation buffer, glucose-fed astrocytes released pyruvate with an initial rate of around 60 nmol/(h × mg) and after around 5 h an almost constant extracellular pyruvate concentration was established that was maintained for several hours. Extracellular pyruvate accumulation was also observed, if glucose had been replaced by mannose, fructose, lactate or alanine. Glucose-fed astrocyte cultures established similar extracellular steady state concentrations of pyruvate by releasing pyruvate into pyruvate-free media or by consuming excess of extracellular pyruvate. Inhibition of the monocarboxylate transporter MCT1 by AR-C155858 lowered extracellular pyruvate accumulation, while inhibition of mitochondrial pyruvate uptake by UK5099 increased the extracellular pyruvate concentration. Finally, the presence of the uncoupler BAM15 or of the respiratory chain inhibitor antimycin A almost completely abolished extracellular pyruvate accumulation. The data presented demonstrate that cultured astrocytes establish a transient extracellular steady state concentration of pyruvate which is strongly affected by modulation of the mitochondrial pyruvate metabolism.

NMAAP1 regulated macrophage polarizion into M1 type through glycolysis stimulated with BCG

Bacillus Calmette Guerin (BCG) perfusion is widely used as cancer adjuvant therapy, in which macrophages play an important role. Novel macrophage activated associated protein 1 (NMAAP1), upregulated after BCG's activation, was proved to promote macrophage polarization to the M1 type. We found that BCG could stimulate mice BMDM to the M1 type and kill tumor cells. After the deletion of NMAAP1, the tumor volume of mice became larger, and the number of M1 type macrophages in the tumor decreased significantly. When macrophages were induced into the M1 type, aerobic glycolysis, the Warburg effect manifested in the increased uptake of glucose and the conversion of pyruvate to lactic acid. NMAAP1 could bind with IP3R and regulate macrophage polarization to the M1 type. However, the specific mechanism of how NMAAP1 regulates macrophage polarization towards the M1 type and plays an antitumor role must be clarified. NMAAP1 could promote the release of lactic acid and pyruvate, enhance the glycolysis of macrophages, and affect the expression of HIF-1α. After inhibition of glycolysis by 2-DG and lactic acid generation by FX11, the effects of NMAAP1 promoting macrophage polarization to the antitumor M1 type were weakened. Furthermore, NMAAP1 upregulated the expression of HIF-1α, which is associated with glycolysis. Moreover, the Ca2+/NF-κB pathway regulated HIF-1α expression by NMAAP1 in the macrophages. NMAAP1 promotes the polarization of macrophages towards the M1 type by affecting the Warburg effect stimulated by BCG.

Abstract 040: Evidence Of Increased Glycolysis In Renal Cortex Of High Salt Fed Sprague Dawley Rats

To determine whole kidney O 2 and substance metabolism in an unanesthetized state, arterial (A), renal venous (Vr) blood and urine (U) were analyzed together with measurements of renal blood flow (RBF), blood pressure (BP) and GFR in conscious freely moving male SD rats. RBF and BP were measured continuously (24/7) via chronically implanted ultrasonic flow probe and A-line respectively. A and Vr blood through chronically implanted catheters and urine (U) were sampled intermittently when rats were fed a 0.4% NaCl (LS) diet and on days 7, 14, and 21 after switching to a 4.0% NaCl (HS) diet (HS7, HS14, HS21). A and Vr O 2 contents were determined by radiometer and a global metabolomic analysis was performed at the JAX Laboratory (LC-MS-MS). GFR was determined in another group of rats by transcutaneous detection of the attenuation of i.v. injected FITC sinistrin. Cortical (Cx) and outer medullary (OM) tissues were obtained from the other group of rats and underwent metabolomic and mRNAseq analyses (Novogene). From another group of rats, glomeruli (Glo), proximal tubules (PT) and non-PT were isolated for RT-PCR. BP and RBF slightly increased by HS3 (P<0.05) and were sustained at these levels. O 2 extraction rose progressively from 0.10 ± 0.01 at LS to 0.14 ± 0.01 at HS21 (P<0.05). GFR increased from 0.64 to 0.83 mL/min/100 g (P<0.05) at HS7 and sustained. Na + reabsorption and O 2 consumption were positively correlated. Clear distinctions were observed in a sparse partial least squares discriminant analysis of tissue metabolomics among LS, HS14, and HS21. The mRNAseq analysis found that the HS diet resulted in the activation of immune system-related genes in both Cx and OM and the downregulation of genes related to the TCA cycle and metabolism of amino acids and fatty acids in Cx only. In contrast, glycolysis-related genes including hexokinase ( Hk ) and pyruvate kinase ( Pkm ) were upregulated in Cx. Metabolic fluxes (A-Vr-U) showed the increased release of lactate and pyruvate from the kidney when fed HS. Increased mRNA expression of Hk and Pkm in HS21 was observed only in PT but not in Glo and non-PT. In summary, SD rats fed a HS diet underwent changes in RBF, O 2 extraction, and utilization of substrates with evidence of increased glycolysis.

Metabolic Responses of Normal Rat Kidneys to a High Salt Intake.

In this study, novel methods were developed, which allowed continuous (24/7) measurement of arterial blood pressure and renal blood flow in freely moving rats and the intermittent collection of arterial and renal venous blood to estimate kidney metabolic fluxes of O2 and metabolites. Specifically, the study determined the effects of a high salt (HS; 4.0% NaCl) diet upon whole kidney O2 consumption and arterial and renal venous plasma metabolomic profiles of normal Sprague-Dawley rats. A separate group of rats was studied to determine changes in the cortex and outer medulla tissue metabolomic and mRNAseq profiles before and following the switch from a 0.4% to 4.0% NaCl diet. In addition, targeted mRNA expression analysis of cortical segments was performed. Significant changes in the metabolomic and transcriptomic profiles occurred with feeding of the HS diet. A progressive increase of kidney O2 consumption was found despite a reduction in expression of most of the mRNA encoding enzymes of TCA cycle. A novel finding was the increased expression of glycolysis-related genes in Cx and isolated proximal tubular segments in response to an HS diet, consistent with increased release of pyruvate and lactate from the kidney to the renal venous blood. Data suggests that aerobic glycolysis (eg, Warburg effect) may contribute to energy production under these circumstances. The study provides evidence that kidney metabolism responds to an HS diet enabling enhanced energy production while protecting from oxidative stress and injury. Metabolomic and transcriptomic analysis of kidneys of Sprague-Dawley rats fed a high salt diet.

The effects of excess salt intake on the kidney metabolism in normal Sprague Dawley rats.

Introduction: This study aimed to determine the effects of a high salt diet upon the metabolism of O 2 and substances in the kidney in normal Sprague Dawley (SD) rats. Methods were developed enabling the intermittent collection of renal arteriovenous (A-Vr) blood and urine samples and to measure renal blood flow (RBF) and arterial pressure (BP) in conscious freely moving rats with GFR determined in a separate group of conscious rats. Other groups were studied to obtain cortical (Cx) and outer medullary (OM) tissue samples for associated transcriptomic and metabolomic profiles. Methods: SD rats were instrumented with a renal arterial ultrasonic flow probe, a femoral arterial and renal venous catheters, and RBF and BP measured continuously (24/7). Arterial (A) and renal venous (Vr) blood and urine were collected repeatedly before and 7, 14, and 21 days after increasing the salt diet from 0.4% (LS) to 4% (HS) NaCl. GFR was measured in age-matched rats and used as control shams for normalization. Blood O 2 content was determined by radiometry. A global metabolomic analysis was performed on plasma and Cx and OM tissue samples at JAX laboratories (Thermo Q-Exactive Orbitrap coupled to Vanquich UPLC system) and together with mRNAseq analysis for Cx and OM by Novogene Inc. Results: BP increased less than 5 mmHg by day 3 of the HS diet while RBF rose nearly 20% (P<0.05) and both were sustained at this level throughout the study. O 2 delivery, O 2 consumption (VO 2 ) and O 2 extraction rose over the 21 days of the HS diet (P<0.05). Total GFR increased from 0.64 to 0.83 mL/min/100 g bw (P<0.05) at HS 7 and remained elevated at HS 21. Whole kidney Na + reabsorption and kidney VO 2 were highly correlated positively (r=0.99). A sparse partial least squares discriminant analysis (sPLS-DA) of metabolomics for each of the 4 modes (C18 +/- and HILIC +/-) revealed clear distinctions between LS, HS14, and HS21 within Cx and OM. The mRNAseq tissue analysis found that the HS diet resulted in reduced expression of genes related to the TCA cycle and metabolism of amino acids and fatty acids. This was consistent with the metabolomic data showing a reduction of tissue citrate and succinate levels. In contrast, glycolysis-related genes including hexokinase, pyruvate kinase and lactate dehydrogenase were upregulated in the Cx tissue by HS. Minimal changes in metabolic pathways were observed in the OM tissue. A-Vr x RBF enabled metabolomic flux determination which showed the release of glucose on LS fed rats which was not evident with the HS diet. Uptake of citrate which was seen on LS was less evident on HS but there was a clear tendency observed for increased release of lactate, pyruvate, and α-ketoglutarate. Conclusions: Normal SD rats fed a HS underwent changes of RBF, O 2 extraction and utilization of metabolic substrates, most notably transitioning ATP production predominantly driven from TCA cycle to non-TCA cycle pathways which we are currently exploring more deeply. HL-116264, HL-151587 This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Catalytic Mechanism of Pyridoxal 5′-Phosphate-Dependent Aminodeoxychorismate Lyase: A Computational QM/MM Study

Aminodeoxychorismate lyase (ADCL) is a kind of pyridoxal-5'-phosphate (PLP)-dependent enzyme that catalyzes the conversion of 4-amino-4-deoxychorismate (ADC) to p-aminobenzoate (PABA), which is a key step for the biosynthesis of folate. To illuminate the reaction details at the atomistic level, an enzyme-substrate reactant model has been constructed, and QM/MM calculations have been performed. Our calculation results reveal that the overall catalytic cycle contains 11 elementary steps, which can be described by three stages, including the transamination reaction of PLP, the release of pyruvate and aromatization of ADC, and the recovery to the initial aldimine. During the reaction, a series of intramolecular proton transfer are involved, which are the key for the C-N bond formation and cleavage as well as the aromatization of the ADC ring. In addition to forming the Schiff base with the pocket residue Lys251 and substrate in the internal aldimine and the external aldimine, respectively, the coenzyme PLP also plays a critical role in the intramolecular proton transfer by employing its hydroxyl oxygen anion and phosphate group. These findings may provide useful information for further understanding the catalytic mechanism of other PLP-dependent enzymes.

1342-P: Reduction of Glucokinase and Glucokinase Regulatory Protein Expression by siRNA Is Associated with the Reduction of Lactate and Pyruvate Export from Canine Hepatocytes

Glucokinase (GCK) mediates hepatic glucose uptake during hyperglycemia and is crucial for the regulation of glucose-responsive glycolysis genes. Mutations in GCK are responsible for maturity-onset diabetes of the young, and glucokinase regulatory protein (GKRP) , the regulator of hepatic GCK, is also a diabetes susceptibility locus. Recently in in vivo experiments, we used hepatic lactate export as a surrogate for GCK activity, which was a measure of “glucose effectiveness.” We hypothesized that in vitro GCK and GKRP suppression in hepatocytes promotes a reduction in lactate and pyruvate export from the liver. We used cryopreserved canine hepatocytes and knocked down GCK and GKRP via lipid delivery of siRNA. A control group did not receive siRNA. We measured lactate dehydrogenase D (LDHD) and pyruvate kinase (PK) gene expression and lactate and pyruvate release into the medium 24 and 48 h after siRNA delivery. Selective blocking of GCK and GKRP did not change cell proliferation but reduced the expression of these genes by 90% and 85%, respectively (P<0.0vs. controls; n=4) . GCK and GKRP knockdown reduced LDHD by 71% and 74%, respectively (P<0.001) ; similarly, PK was reduced by 84% and 82%, respectively (P<0.001) . Lactate exported into the medium was reduced by 36% (P<0.001) and 26% (P<0.05) by GCK and GKRP siRNA, respectively, after 48 h of hepatocyte culture. However, pyruvate was reduced by 17% only after 48 h culture of GCK siRNA (P<0.05) . Thus, we showed that direct suppression of GCK and GKRP genes by siRNA in vitro affects glucose-responsive glycolysis genes, consequently reducing lactate export which can be used as a surrogate for reduced glucokinase activity in hepatocytes. The use of antisense oligonucleotides or CRISPR gene-editing methods in animals will be useful methods to study the glucose-lactate relationship in vivo and will evaluate the role of glucose effectiveness in the pathogenesis of type 2 diabetes. Disclosure M.Kabir: None. M.Ader: None. R.N.Bergman: Consultant; Fractyl Health, Inc., Novo Nordisk, Research Support; AstraZeneca, Janssen Research & Development, LLC. Funding National Institutes of Health R01- DK027619-28

Glutamate-induced modulation in energy metabolism contributes to protection of rat cortical slices against ischemia-induced damage.

Glutamate excitotoxicity contributes to neurodegeneration during cerebral ischemia. Recent studies in the protective effect of glutamate against ischemia and hypoxia have shown the need for questioning the role of glutamate in energy metabolism during ischemia. Current study investigates the effect of glutamate on energy substrate metabolites such as alpha-ketoglutarate, lactate, and pyruvate release during control, oxygen-glucose deprivation (OGD), and reoxygenation (REO) conditions. The effects of 0.5 and 2 mM glutamate on spontaneous alpha-ketoglutarate, lactate, and pyruvate release were tested in vitro, on acute rat cortical slices. Alpha-ketoglutarate, lactate, and pyruvate levels were determined by HPLC with UV detector. We observed that glutamate added into medium significantly increased alpha-ketogluarate release under control conditions. Although OGD and REO also had a glutamate-like effect, only REO-induced rise further enhanced by glutamate. In contrast to alpha-ketoglutarate, both OGD and REO conditions caused significant declines in pyruvate and lactate outputs. While OGD and REO-induced declines in pyruvate outputs were further potentiated, lactate output was not altered by glutamate added into the medium. Glutamate and alpha-ketoglutarate, moreover, also ameliorated OGD- and REO-induced losses in 2,3,5-triphenyltetrazolium chloride staining with a similar degree. These results indicate that glutamate probably increases alpha-ketoglutarate production as an alternative energy source for use in the TCA cycle under energy-depleted conditions. Thus, increasing the alpha-ketoglutarate production may represent a new therapeutic intervention for neurodegenerative disorders, including cerebral ischemia.

Inhibition of Mitochondrial Respiration Impairs Nutrient Consumption and Metabolite Transport in Human Retinal Pigment Epithelium.

Mitochondrial respiration in mammalian cells not only generates ATP to meet their own energy needs but also couples with biosynthetic pathways to produce metabolites that can be exported to support neighboring cells. However, how defects in mitochondrial respiration influence these biosynthetic and exporting pathways remains poorly understood. Mitochondrial dysfunction in retinal pigment epithelium (RPE) cells is an emerging contributor to the death of their neighboring photoreceptors in degenerative retinal diseases including age-related macular degeneration. In this study, we used targeted-metabolomics and 13C tracing to investigate how inhibition of mitochondrial respiration influences the intracellular and extracellular metabolome. We found inhibition of mitochondrial respiration strikingly influenced both the intracellular and extracellular metabolome in primary RPE cells. Intriguingly, the extracellular metabolic changes sensitively reflected the intracellular changes. These changes included substantially enhanced glucose consumption and lactate production; reduced release of pyruvate, citrate, and ketone bodies; and massive accumulation of multiple amino acids and nucleosides. In conclusion, these findings reveal a metabolic signature of nutrient consumption and release in mitochondrial dysfunction in RPE cells. Testing medium metabolites provides a sensitive and noninvasive method to assess mitochondrial function in nutrient utilization and transport.

Pyruvate secretion by oral streptococci modulates hydrogen peroxide dependent antagonism.

Many commensal oral streptococci generate H2O2 via pyruvate oxidase (SpxB) to inhibit the growth of competing bacteria like Streptococcus mutans, a major cariogenic species. In Streptococcus sanguinis SK36 (SK36) and Streptococcus gordonii DL1 (DL1), spxB expression and H2O2 release are subject to carbon catabolite repression by the catabolite control protein A (CcpA). Surprisingly, ccpA deletion mutants of SK36 and DL1 fail to inhibit S. mutans despite their production of otherwise inhibitory levels of H2O2. Using H2O2-deficient spxB deletion mutants of SK36 and DL1, it was subsequently discovered that both strains confer protection in trans to other bacteria when H2O2 is added exogenously. This protective effect depends on the direct detoxification of H2O2 by the release of pyruvate. The pyruvate dependent protective effect is also present in other spxB-encoding streptococci, such as the pneumococcus, but is missing from spxB-negative species like S. mutans. Targeted and transposon-based mutagenesis revealed Nox (putative H2O-forming NADH dehydrogenase) as an essential component required for pyruvate release and oxidative protection, while other genes such as sodA and dps play minor roles. Furthermore, pyruvate secretion is only detectable in aerobic growth conditions at biofilm-like cell densities and is responsive to CcpA-dependent catabolite control. This ability of spxB-encoding streptococci reveals a new facet of the competitive interactions between oral commensals and pathobionts and provides a mechanistic basis for the variable levels of inhibitory potential observed among H2O2-producing strains of commensal oral streptococci.

Release of sodium pyruvate from sacral prophylactic dressings: A computational model.

The use of sacral dressings for pressure ulcer prevention is growing rapidly. In addition to their passive biomechanical role in pressure and shear reduction, in the near future, prophylactic dressings may also provide active tissue protection by releasing preventive agents or drugs into skin and deeper tissues. We investigated delivery of sodium pyruvate (NaPy) from an active dressing to potentially protect the sacral skin and underlying tissues in addition. We used four finite element model variants describing different skin roughness levels to determine time profiles of NaPy diffusion from the dressing into the skin layers. The NaPy concentrations for the different modelled cases stabilised after 1 to 6.5 hours from the time of application of the dressings, at 1% to 3% of the NaPy concentration in the dressing reservoir, which is considered potent. We conclude that prophylactic sacral dressings have the potential to deliver NaPy into skin and subdermally, to potentially increase soft tissue tolerance to sustained bodyweight-caused cell and tissue deformations. The time durations to achieve the steady-state potent NaPy dermal concentrations are clinically feasible, for example, for preparation of patients for surgery or for use in intensive care units.

Pros and cons of insulin administration on liver glucose metabolism in strength-trained healthy mice.

Non-diabetic individuals use hormones like insulin to improve muscle strength and performance. However, as insulin also leads the liver and the adipose tissue to an anabolic state, the purpose of this study was to investigate the effects of insulin on liver metabolism in trained non-diabetic Swiss mice. The mice were divided into four groups: sedentary treated with saline (SS) or insulin (SI) and trained treated with saline (TS) or insulin (TI). Training was made in a vertical stair, at 90% of the maximum load, three times per week. Insulin (0.3 U/kg body weight) or saline were given intraperitoneally five times per week. After eight weeks, tissue and blood were collected and in situ liver perfusion with glycerol+lactate or alanine+glutamine (4 mM each) was carried out. The trained animals increased their muscle strength (+100%) and decreased body weight gain (–11%), subcutaneous fat (–42%), mesenteric fat (–45%), and peritoneal adipocyte size (–33%) compared with the sedentary groups. Insulin prevented the adipose effects of training (TI). The gastrocnemius muscle had greater density of muscle fibers (+60%) and less connective tissue in the trained groups. Liver glycogen was increased by insulin (SI +40% and TI +117%), as well as liver basal glucose release (TI +40%). Lactate and pyruvate release were reduced to a half by training. The greater gluconeogenesis from alanine+glutamine induced by training (TS +50%) was reversed by insulin (TI). Insulin administration had no additional effect on muscle strength and reversed some of the lipolytic and gluconeogenic effects of the resistance training. Therefore, insulin administration does not complement training in improving liver glucose metabolism.

Unraveling the Mechanism of Cysteine Persulfide Formation Catalyzed by 3-Mercaptopyruvate Sulfurtransferases

Sulfhydration of reactive cysteines in target proteins is now recognized as a major route by which H2S mediates signal transduction and regulates various cellular processes. Among the enzymatic systems permitting the formation of cysteine persulfide from nonactivated sulfur compounds, 3-mercaptopyruvate sulfurtransferases can be considered as a model of thiolate-based chemistry for carbon–sulfur bond breaking. These ubiquitous enzymes transfer a sulfur atom from 3-mercaptopyruvate (3-MP) to a thiol acceptor via a cysteine-persulfide intermediate, but the mechanistic basis for its formation is still unclear. To address this question, kinetic approaches were developed for studying the reaction catalyzed by the human and Escherichia coli enzymes and the role of several conserved residues was also investigated. We showed that the first step of sulfur transfer that leads to pyruvate release and formation of the persulfide intermediate is very efficient for both enzymes. It critically depends on the electrostat...

Conformational flexibility related to enzyme activity: evidence for a dynamic active-site gatekeeper function of Tyr(215) in Aerococcus viridans lactate oxidase.

L-Lactate oxidase (LOX) belongs to a large family of flavoenzymes that catalyze oxidation of α-hydroxy acids. How in these enzymes the protein structure controls reactivity presents an important but elusive problem. LOX contains a prominent tyrosine in the substrate binding pocket (Tyr215 in Aerococcus viridans LOX) that is partially responsible for securing a flexible loop which sequesters the active site. To characterize the role of Tyr215, effects of substitutions of the tyrosine (Y215F, Y215H) were analyzed kinetically, crystallographically and by molecular dynamics simulations. Enzyme variants showed slowed flavin reduction and oxidation by up to 33-fold. Pyruvate release was also decelerated and in Y215F, it was the slowest step overall. A 2.6-Å crystal structure of Y215F in complex with pyruvate shows the hydrogen bond between the phenolic hydroxyl and the keto oxygen in pyruvate is replaced with a potentially stronger hydrophobic interaction between the phenylalanine and the methyl group of pyruvate. Residues 200 through 215 or 216 appear to be disordered in two of the eight monomers in the asymmetric unit suggesting that they function as a lid controlling substrate entry and product exit from the active site. Substitutions of Tyr215 can thus lead to a kinetic bottleneck in product release.

84 PORCINE EMBRYOS UTILIZE SMALL AMOUNTS OF PYRUVATE, LACTATE, AND GLUCOSE IN VITRO

Porcine embryo culture systems are suboptimal to the in vivo environment, and significant effort has been made to improve development to the blastocyst stage in vitro. Since metabolism of the early embryo has many similarities to the Warburg effect, our goal was to determine the role of glucose on development, gene expression, and metabolism of other energy substrates in the blastocyst stage embryo. Pig embryos were in vitro produced and cultured in MU1 containing pyruvate, lactate, amino acids, and either 0, 7.5, 15, or 250 µM glucose, N = 1164, 4 replications. There was no difference in blastocyst percentage between the 0 µM and 7.5 µM glucose (34% ± 6.5 v. 29% ± 8.2), but there was a decrease in development in response to 15 and 250 µM compared with 0 µM glucose (25% ± 8.5, 23% ± 8.7 v. 34% ± 6.5; P ≤ 0.01). Glucose transporters (SLC2A1 and SLC2A2) and hexokinases (HK1 and HK2) were analysed by qPCR to detect differences in gene expression, 3 replicates containing 10 blastocyst pools. The abundance of both HK1 and HK2 was decreased in blastocysts cultured with 7.5 µM glucose compared with 0 µM (P ≤ 0.04). Glucose transporters were not affected by glucose supplementation (P ≥ 0.5). Metabolic data were collected to determine if embryos were adjusting their energy substrate use in response to glucose. Two assays were completed to determine lactate and pyruvate consumption or release into the media by embryos, in comparison with media without embryos. In vitro-produced embryos were cultured in MU1 with 0 or 7.5 µM glucose N = 360, 4 replications. Both treatments consumed lactate, but there were no differences between treatments (6.8 ± 9.4 pmol/blastocyst/h v. 12.5 ± 1.6 pmol/blastocyst/h; P = 0.6). Blastocysts cultured in 7.5 µM glucose consumed pyruvate, whereas blastocysts without glucose produced pyruvate (–0.34 ± 0.3 pmol/blastocyst/h v. 0.73 ± 0.2 pmol/blastocyst/h; P < 0.01). It has been suggested that fructose is a more efficient replacement for glucose in pig embryo culture. Therefore, we produced pig embryos in vitro and cultured these embryos in MU1, MU1 + 2 mM glucose, or MU1 + 2 mM fructose to the blastocyst stage, 4 replications, N = 389. Again, there was a decrease in embryos that developed to the blastocyst stage in 2 mM glucose compared with MU1 control blastocysts (26% ± 5.8 v. 11% ± 2.5; P = 0.001), but there was only a trend for a decrease in development in response to 2 mM fructose (17 ± 2.3%; P = 0.06). There was no difference in total cell number between MU1, 2 mM glucose, and 2 mM fructose (30.6 ± 2.2, 30.5 ± 3.7, and 32.6 ± 3.0, respectively; P ≥ 0.9) 3 replications, N = 32. Because there is very little consumption of lactate and very low levels of pyruvate are being consumed when glucose is present, it does not appear that any of these energy substrates are major players for the developing pig embryo. Future experiments should be conducted to determine other means of energy production and metabolism in these embryos. The research was funded by Food for the 21st Century.

From population ecology to metabolism: growth of Trypanosoma evansi, and implications of glucose depletion, in a live host

Little attention has been paid to the potential top-down effects of population ecology on metabolism. Because it is capable of a fast growth that dramatically modifies its blood environment, the parasitic protozoan, Trypanosoma evansi, is a promising model for the study of density-dependent metabolic processes. We assess the in vivo growth rate, doubling time, biomass yield, glycolytic flux, and enzyme expression of T. evansi. Then, we explore the metabolic changes likely occurring during its growth. At low T. evansi densities, most host glucose is used to produce energy, which results in the release of pyruvate. Part of glucose is used for NADPH production through the pentose phosphate pathway. At high T. evansi densities, fructose, mannose, and glycerol become additional energy sources. Part of host glucose is used for biosynthesis and for NADPH production through alternative metabolic pathways, which results in the release of succinate, alanine, and acetate. The ability of organisms to adjust to resource changes is crucial to their survival. Irrespective if the triggering mechanism is direct (nutrient limitation) or indirect (a pheromone-like factor), nutrient availability is necessarily the main evolutionary factor responsible for the density-dependent metabolic properties of trypanosome populations.

Role of N-terminal protein formylation in central metabolic processes in Staphylococcus aureus

BackgroundBacterial protein biosynthesis usually depends on a formylated methionyl start tRNA but Staphylococcus aureus is viable in the absence of Fmt, the tRNAMet formyl transferase. fmt mutants exhibit reduced growth rates indicating that the function of certain proteins depends on formylated N-termini but it has remained unclear, which cellular processes are abrogated by the lack of formylation.ResultsIn order to elucidate how global metabolic processes are affected by the absence of formylated proteins the exometabolome of an S. aureus fmt mutant was compared with that of the parental strain and the transcription of corresponding enzymes was analyzed to identify possible regulatory changes. The mutant consumed glucose and other carbon sources slower than the wild type. While the turnover of several metabolites remained unaltered fmt inactivation led to increases pyruvate release and, concomitantly, reduced pyruvate dehydrogenase activity. In parallel, the release of the pyruvate-derived metabolites lactate, acetoin, and alanine was reduced. The anaerobic degradation of arginine was also reduced in the fmt mutant compared to the wild-type strain. Moreover, the lack of formylated proteins caused increased susceptibility to the antibiotics trimethoprim and sulamethoxazole suggesting that folic acid-dependant pathways were perturbed in the mutant.ConclusionsThese data indicate that formylated proteins are crucial for specific bacterial metabolic processes and they may help to understand why it has remained important during bacterial evolution to initiate protein biosynthesis with a formylated tRNAMet.

Neuroprotective effects of chronic exposure of SH-SY5Y to low lithium concentration involve glycolysis stimulation, extracellular pyruvate accumulation and resistance to oxidative stress

Recent studies suggest that lithium protects neurons from death induced by a wide array of neurotoxic insults, stimulates neurogenesis and could be used to prevent age-related neurodegenerative diseases. In this study, SH-SY5Y human neuronal cells were cultured in the absence (Con) or in the presence (Li+) of a low lithium concentration (0.5 mm Li2CO3, i.e. 1 mm lithium ion) for 25-50 wk. In the course of treatment, growth rate of Con and Li+ cells was regularly analysed using Alamar Blue dye. Resistance to oxidative stress was investigated by evaluating: (1) the adverse effects of high concentrations of lithium (4-8 mm) or glutamate (20-90 mm) on cell growth rate; (2) the levels of lipid peroxidation (TBARS) and total glutathione; (3) the expression levels of the anti-apoptotic Bcl-2 protein. In addition, glucose metabolism was investigated by analysing selected metabolites in culture media and cell extracts by 1H-NMR spectroscopy. As compared to Con, Li+ cells multiplied faster and were more resistant to stress, as evidenced by a lower dose-dependent decrease of Alamar Blue reduction and dose-dependent increase of TBARS levels induced by toxic doses of lithium and glutamate. Total glutathione content and Bcl-2 level were increased in Li+ cells. Glucose consumption and glycolytic activity were enhanced in Li+ cells and an important release of pyruvate was observed. We conclude that chronic exposure to lithium induces adaptive changes in metabolism of SH-SY5Y cells involving a higher cell growth rate and a better resistance to oxidative stress.

Metabolic characteristics of human subcutaneous abdominal adipose tissueafter overnight fast

Subcutaneous abdominal adipose tissue is one of the largest fat depots and contributes the major proportion of circulating nonesterified fatty acids (NEFA). Little is known about aspects of human adipose tissue metabolism in vivo other than lipolysis. Here we collated data from 331 experiments in 255 healthy volunteers over a 23-year period, in which subcutaneous abdominal adipose tissue metabolism was studied by measurements of arterio-venous differences after an overnight fast. NEFA and glycerol were released in a ratio of 2.7:1, different (P < 0.001) from the value of 3.0 that would indicate no fatty acid re-esterification. Fatty acid re-esterification was 10.2 ± 1.4%. Extraction of triacylglycerol (TG) (fractional extraction 5.7 ± 0.4%) indicated intravascular lipolysis by lipoprotein lipase, and this contributed 21 ± 3% of the glycerol released. Glucose uptake (fractional extraction 2.6 ± 0.3%) was partitioned around 20-25% for provision of glycerol 3-phosphate and 30% into lactate production. There was release of lactate and pyruvate, with extraction of the ketone bodies 3-hydroxybutyrate and acetoacetate, although these were small numerically compared with TG and glucose uptake. NEFA release (expressed per 100 g tissue) correlated inversely with measures of fat mass (e.g., with BMI, r(s) = -0.24, P < 0.001). We examined within-person variability. Systemic NEFA concentrations, NEFA release, fatty acid re-esterification, and adipose tissue blood flow were all more consistent within than between individuals. This picture of human adipose tissue metabolism in the fasted state should contribute to a greater understanding of adipose tissue physiology and pathophysiology.