Disruption of the pdhB Pyruvate Dehydrogenase Gene Affects Colony Morphology,In Vitro Growth and Cell Invasiveness of Mycoplasma agalactiae

The utilization of available substrates, the metabolic potential and the growth rates of bacteria can play significant roles in their pathogenicity. This study concentrates on Mycoplasma agalactiae, which causes significant economic losses through its contribution to contagious agalactia in small ruminants by as yet unknown mechanisms. This lack of knowledge is primarily due to its fastidious growth requirements and the scarcity of genetic tools available for its manipulation and analysis. Transposon mutagenesis of M. agalactiae type strain PG2 resulted in several disruptions throughout the genome. A mutant defective in growth in vitro was found to have a transposon insertion in the pdhB gene, which encodes a component of the pyruvate dehydrogenase complex. This growth difference was quite significant during the actively dividing logarithmic phase but a gradual recovery was observed as the cells approached stationary phase. The mutant also exhibited a different and smaller colony morphology compared to the wild type strain PG2. For complementation, pdhAB was cloned downstream of a strong vpma promoter and upstream of a lacZ reporter gene in a newly constructed complementation vector. When transformed with this vector the pdhB mutant recovered its normal growth and colony morphology. Interestingly, the pdhB mutant also had significantly reduced invasiveness in HeLa cells, as revealed by double immunofluorescence staining. This deficiency was recovered in the complemented strain, which had invasiveness comparable to that of PG2. Taken together, these data indicate that pyruvate dehydrogenase might be an important player in infection with and colonization by M. agalactiae.     

Inhibiting Sperm Pyruvate Dehydrogenase Complex and Its E3 Subunit,Dihydrolipoamide Dehydrogenase Affects Fertilization in Syrian Hamsters

Background/Aims

The importance of sperm capacitation for mammalian fertilization has been confirmed in the present study via sperm metabolism. Involvement of the metabolic enzymes pyruvate dehydrogenase complex (PDHc) and its E3 subunit, dihydrolipoamide dehydrogenase (DLD) in hamster in vitro fertilization (IVF) via in vitro sperm capacitation is being proposed through regulation of sperm intracellular lactate, pH and calcium.

Methodology and Principal Findings

Capacitated hamster spermatozoa were allowed to fertilize hamster oocytes in vitro which were then assessed for fertilization, microscopically. PDHc/DLD was inhibited by the use of the specific DLD-inhibitor, MICA (5-methoxyindole-2-carboxylic acid). Oocytes fertilized with MICA-treated (MT) [and thus PDHc/DLD-inhibited] spermatozoa showed defective fertilization where 2^nd polar body release and pronuclei formation were not observed. Defective fertilization was attributable to capacitation failure owing to high lactate and low intracellular pH and calcium in MT-spermatozoa during capacitation. Moreover, this defect could be overcome by alkalinizing spermatozoa, before fertilization. Increasing intracellular calcium in spermatozoa pre-IVF and in defectively-fertilized oocytes, post-fertilization rescued the arrest seen, suggesting the role of intracellular calcium from either of the gametes in fertilization. Parallel experiments carried out with control spermatozoa capacitated in medium with low extracellular pH or high lactate substantiated the necessity of optimal sperm intracellular lactate levels, intracellular pH and calcium during sperm capacitation, for proper fertilization.

Conclusions

This study confirms the importance of pyruvate/lactate metabolism in capacitating spermatozoa for successful fertilization, besides revealing for the first time the importance of sperm PDHc/ DLD in fertilization, via the modulation of sperm intracellular lactate, pH and calcium during capacitation. In addition, the observations made in the IVF studies in hamsters suggest that capacitation failures could be a plausible cause of unsuccessful fertilization encountered during human assisted reproductive technologies, like IVF and ICSI. Our studies indicate a role of sperm capacitation in the post-penetration events during fertilization.     

Overexpression of Arabidopsis Ceramide Synthases Differentially Affects Growth,Sphingolipid Metabolism,Programmed Cell Death,and Mycotoxin Resistance

Ceramide synthases catalyze an N-acyltransferase reaction using fatty acyl-coenzyme A (CoA) and long-chain base (LCB) substrates to form the sphingolipid ceramide backbone and are targets for inhibition by the mycotoxin fumonisin B₁ (FB₁). Arabidopsis (Arabidopsis thaliana) contains three genes encoding ceramide synthases with distinct substrate specificities: LONGEVITY ASSURANCE GENE ONE HOMOLOG1 (LOH1; At3g25540)- and LOH3 (At1g19260)-encoded ceramide synthases use very-long-chain fatty acyl-CoA and trihydroxy LCB substrates, and LOH2 (At3g19260)-encoded ceramide synthase uses palmitoyl-CoA and dihydroxy LCB substrates. In this study, complementary DNAs for each gene were overexpressed to determine the role of individual isoforms in physiology and sphingolipid metabolism. Differences were observed in growth resulting from LOH1 and LOH3 overexpression compared with LOH2 overexpression. LOH1- and LOH3-overexpressing plants had enhanced biomass relative to wild-type plants, due in part to increased cell division, suggesting that enhanced synthesis of very-long-chain fatty acid/trihydroxy LCB ceramides promotes cell division and growth. Conversely, LOH2 overexpression resulted in dwarfing. LOH2 overexpression also resulted in the accumulation of sphingolipids with C16 fatty acid/dihydroxy LCB ceramides, constitutive induction of programmed cell death, and accumulation of salicylic acid, closely mimicking phenotypes observed previously in LCB C-4 hydroxylase mutants defective in trihydroxy LCB synthesis. In addition, LOH2- and LOH3-overexpressing plants acquired increased resistance to FB₁, whereas LOH1-overexpressing plants showed no increase in FB₁ resistance, compared with wild-type plants, indicating that LOH1 ceramide synthase is most strongly inhibited by FB₁. Overall, the findings described here demonstrate that overexpression of Arabidopsis ceramide synthases results in strongly divergent physiological and metabolic phenotypes, some of which have significance for improved plant performance.Ceramides are central intermediates in sphingolipid biosynthesis and mediators of programmed cell death (PCD) in plants (Dunn et al., 2004; Saucedo-García et al., 2011; Ternes et al., 2011a). Ceramides are synthesized by ceramide synthase (or sphingosine N-acyltransferase; EC 2.3.1.24), which catalyzes the formation of an amide linkage between a sphingoid long-chain base (LCB) and a fatty acid using LCB and fatty acyl-CoA substrates (Mullen et al., 2012). The LCB substrate can have two or three hydroxyl groups that are referred to as dihydroxy or trihydroxy LCBs, respectively (Chen et al., 2010). The fatty acyl-CoA substrates typically have chain lengths of C16 or C22 to C26 (Dunn et al., 2004). The latter are referred to as very-long-chain fatty acids (VLCFAs). The ceramide product of ceramide synthase is used primarily as a substrate for the synthesis of either of the two major glycosphingolipids found in plants: glucosylceramide (GlcCer) and glycosyl inositolphosphoceramide (GIPC; Chen et al., 2010). These glycosphingolipids are major structural components of the plasma membrane and other endomembranes of plant cells (Verhoek et al., 1983; Sperling et al., 2005). In this role, they contribute to membrane physical properties that are important for the ability of plant cells to adjust to environmental extremes and to Golgi-mediated protein trafficking of proteins, including cell wall metabolic enzymes and auxin transporters that underlie plant growth (Borner et al., 2005; Markham et al., 2011; Mortimer et al., 2013; Yang et al., 2013). Alternatively, ceramides can be converted to ceramide-1-phosphates by ceramide kinase activity (Liang et al., 2003). The interchange of ceramides between their free and phosphorylated forms has been linked to the regulation of PCD and PCD-associated resistance to pathogens via the hypersensitive response (HR; Liang et al., 2003; Bi et al., 2014; Simanshu et al., 2014).The Arabidopsis (Arabidopsis thaliana) genome contains three ceramide synthase genes denoted LONGEVITY ASSURANCE GENE ONE HOMOLOG1 (LOH1; At3g25540), LOH2 (At3g19260), and LOH3 (At1g13580; Markham et al., 2011; Ternes et al., 2011a). These studies suggest that LOH1 and LOH3 polypeptides are structurally related and catalyze primarily the amidation reaction of trihydroxy LCBs and CoA esters of VLCFAs. The LOH2 polypeptide is more distantly related to LOH1 and LOH3 and catalyzes primarily the condensation of dihydroxy LCBs and C16 fatty acyl-CoAs (Chen et al., 2008; Markham et al., 2011; Ternes et al., 2011a). The ceramide products of LOH1 and LOH3 are most prevalent in GIPC, whereas the ceramide products of LOH2 are more enriched in GlcCer (Markham and Jaworski, 2007; Chen et al., 2008; Ternes et al., 2011b). Similar to plants, the six ceramide synthase isoforms found in humans and mice have distinct specificities for their LCB and acyl-CoA substrates, and these specificities contribute to the formation of complex sphingolipids with differing structures and functions (Venkataraman et al., 2002; Riebeling et al., 2003; Mizutani et al., 2005, 2006; Laviad et al., 2008).In Arabidopsis, LOH1 and LOH3 are partially redundant, but the combined activities of the corresponding polypeptides are essential for plant cell viability, as null double mutants of these genes are lethal (Markham et al., 2011). In contrast, mutants of LOH2 are viable and display no apparent growth phenotype, which brings into question the role of LOH2 ceramide synthase in plant performance (Markham et al., 2011; Ternes et al., 2011a). Overall, these observations indicate that sphingolipids with LOH1-/LOH3-derived trihydroxy LCBs and VLCFA ceramides are essential, but LOH2-derived dihydroxy LCBs and C16 fatty acid ceramides are not required by plant cells. Related to this, LCB C-4 hydroxylase mutants that are deficient in trihydroxy LCBs accumulate elevated amounts of sphingolipids with dihydroxy LCB- and C16 fatty acid-containing ceramides via LOH2 activity (Chen et al., 2008). These mutants are severely impaired in growth and do not transition from vegetative to reproductive growth (Chen et al., 2008).Ceramide synthases are known targets for competitive inhibition by sphingosine analog mycotoxins, including fumonisin B₁ (FB₁) and AAL toxin, produced by pathogenic fungi such as various Fusarium spp. and Alternaria alternata f. sp. lycopersici (Abbas et al., 1994). Inhibition of ceramide synthase results in the accumulation of LCBs that are believed to trigger PCD and result in cytotoxicity (Abbas et al., 1994). In studies of LOH mutants, treatment of Arabidopsis seedlings with FB₁ resulted in not only increases in LCBs but also increases in C16 fatty acid-containing sphingolipids and decreases in VLCFA-containing sphingolipids (Markham et al., 2011; Ternes et al., 2011a). The interpretation of this observation was that FB₁ preferentially inhibits LOH1 and LOH3 ceramide synthases but inhibits LOH2 ceramide synthase to a lesser extent (Markham et al., 2011; Ternes et al., 2011a).Given the findings from Arabidopsis mutants that LOH1 and LOH3 ceramide synthases have distinct substrate specificities and sensitivity to FB₁ relative to LOH2, we hypothesized that the overexpression of each of these ceramide synthases would lead to the production of different sphingolipid compositions as well as different growth phenotypes. This report details experiments designed to test this hypothesis. Among the results presented is a large divergence in the effects of the overexpression of LOH1 and LOH3 versus LOH2 on the growth of Arabidopsis. LOH2 overexpression was also shown to result in sphingolipid compositional, growth, and physiological phenotypes that closely mimic those observed previously in LCB C-4 hydroxylase mutants (Chen et al., 2008).     

Nerve Growth Factor Affects Cyclic AMP Metabolism, but Not by Directly Stimulating Adenylate Cyclase Activity

Published experiments both support and contradict the hypothesis that nerve growth factor (NGF) can regulate adenylate cyclase activity. Using a sensitive assay that measures the conversion of [2-3H]adenine to [3H]cyclic AMP, we have shown that NGF alone cannot measurably stimulate cyclic AMP production, whereas the adenosine analog phenylisopropyladenosine (PIA) stimulates adenylate cyclase 20-fold over basal activity. NGF potentiates the capacity of both PIA and cholera toxin to stimulate cyclic AMP accumulation at all concentrations tested. This potentiation occurs at the earliest measurable times and does not require RNA synthesis. Therefore, we conclude that cyclase activation alone does not account for the effect of NGF on cyclic AMP accumulation and we discuss possible mechanisms.     

Daily Temperature Amplitude Affects the Vegetative Growth and Carbon Metabolism of Orange Trees in a Rootstock-Dependent Manner

Both instantaneous and average growth temperatures affect plant metabolism, and the physiological importance of daily variations in temperature is frequently underestimated. To improve our understanding of the environmental regulation of citrus trees, we hypothesized that vegetative growth would be stimulated in orange plants subjected to large daily temperature variations, even without changes in the average daily air temperature or the amount of energy given by degree-days. This hypothesis was tested with orange plants grafted onto Rangpur lime or Swingle citrumelo rootstocks and grown for 20?days under thermal regimes (day/night) of 25/25°C or 32.5/17.5°C. Such regimes imposed growth conditions with daily temperature variations of 0 and 15°C. Plant growth, photosynthesis, respiration, and carbohydrate availability in leaves, stems, and roots were measured under both thermal conditions. The daily temperature variation affected the carbon metabolism of young citrus trees; plants grown under daily variation of 15°C used more of the carbon stored in mature leaves and roots and the energy generated by respiration for the biosynthesis of vegetative structures, such as leaves and branches. Thus, there was a significant increase in the leaf area of plants subjected to high daily temperature variation. Current photosynthesis was similar in the two thermal regimes; however, the photosynthetic rates increased under the 15°C variation when measurements were normalized to 25°C. In addition to the stimulatory effect of the source?Csink relationship on photosynthesis, we suggest a probable involvement of hormonal regulation of plant growth through gibberellin metabolism. The rootstock affected the response of the canopy to daily temperature amplitude, with the Rangpur lime improving plant growth through higher carbohydrate availability in roots. This is the first report that highlights the importance of daily temperature variations for citrus growth and physiology under nonlimiting conditions.     

Intertissue Differences for the Role of Glutamate Dehydrogenase in Metabolism

The enzyme glutamate dehydrogenase (GDH) plays an important role in integrating mitochondrial metabolism of amino acids and ammonia. Glutamate may function as a respiratory substrate in the oxidative deamination direction of GDH, which also yields α-ketoglutarate. In the reductive amination direction GDH produces glutamate, which can then be used for other cellular needs such as amino acid synthesis via transamination. The production or removal of ammonia by GDH is also an important consequence of flux through this enzyme. However, the abundance and role of GDH in cellular metabolism varies by tissue. Here we discuss the different roles the house-keeping form of GDH has in major organs of the body and how GDH may be important to regulating aspects of intermediary metabolism. The near-equilibrium poise of GDH in liver and controversy over cofactor specificity and regulation is discussed, as well as, the role of GDH in regulation of renal ammoniagenesis, and the possible importance of GDH activity in the release of nitrogen carriers by the small intestine.     

Metabolism Changes During Aging in the Hippocampus and Striatum of Glud1 (Glutamate Dehydrogenase 1) Transgenic Mice

The decline in neuronal function during aging may result from increases in extracellular glutamate (Glu), Glu-induced neurotoxicity, and altered mitochondrial metabolism. To study metabolic responses to persistently high levels of Glu at synapses during aging, we used transgenic (Tg) mice that over-express the enzyme Glu dehydrogenase (GDH) in brain neurons and release excess Glu in synapses. Mitochondrial GDH is important in amino acid and carbohydrate metabolism and in anaplerotic reactions. We monitored changes in nineteen neurochemicals in the hippocampus and striatum of adult, middle aged, and aged Tg and wild type (wt) mice, in vivo, using proton (¹H) magnetic resonance spectroscopy. Significant differences between adult Tg and wt were higher Glu, N-acetyl aspartate (NAA), and NAA + NAA–Glu (NAAG) levels, and lower lactate in the Tg hippocampus and striatum than those of wt. During aging, consistent changes in Tg and wt hippocampus and striatum included increases in myo-inositol and NAAG. The levels of glutamine (Gln), a key neurochemical in the Gln-Glu cycle between neurons and astroglia, increased during aging in both the striatum and hippocampus of Tg mice, but only in the striatum of the wt mice. Age-related increases of Glu were observed only in the striatum of the Tg mice.     

Malonate Metabolism, Stimulation of Conidiation and Succinate Dehydrogenase Activity in Neurospora crassa

Malonate was studied for its effect on succinate dehydrogenase activity and conidiation. It Was found to stimulate the succinate dehydrogenase activity and also conidiation of Neurospora crassa. The efficiency of sucrose metabolization for cellular synthesis was improved in malonate supplemented cultures. High Concentration (0.5 M) had a distinct toxic effect on conidiation and economic efficiency. Teratological structures were observed at 0.5 M malonate concentration. A stimulation of the glyoxylate cycle is considered to be one of the factors responsible for the conidiogenic effect.     

Deanol Affects Choline Metabolism in Peripheral Tissues of Mice

Abstract: The enzymatic hydrolysis of UDP-galactose in rat and calf brain was studied. The hydrolysis occurs in two steps: The first is the conversion of UDP-galactose to galactose-1-phosphate catalyzed by nucleotide pyrophosphatase (EC 3.6.1.9), and the second is the conversion of the latter to free galactose by alkaline phosphatase (EC 3.1.3.1). The overall conversion has a pH optimum of 9.0, but there is considerable activity at pH 7.4, which is the optimum for UDP-galactose:ceramide galactosyltransferase in the synthesis of cerebrosides. Preparations from cytosol from calf brain cerebellum or stem that were enriched in UDP-galactose hydrolytic activity inhibit cerebroside synthesis under conditions optimal for the synthesis. Microsome-rich and nuclear debris fractions contain the highest apparent specific activity among the subcellular fractions studied. Hydrolysis of UDP-galactose occurs in all areas of brain, brainstem having the highest activity. The apparent specific activity in jimpy mouse brain homogenate is nearly twice as high as in the control brain homogenate.     

Genetic Analysis of Central Carbon Metabolism Unveils an Amino Acid Substitution That Alters Maize NAD-Dependent Isocitrate Dehydrogenase Activity

Background

Central carbon metabolism (CCM) is a fundamental component of life. The participating genes and enzymes are thought to be structurally and functionally conserved across and within species. Association mapping utilizes a rich history of mutation and recombination to achieve high resolution mapping. Therefore, applying association mapping in maize (Zea mays ssp. mays), the most diverse model crop species, to study the genetics of CCM is a particularly attractive system.

Methodology/Principal Findings

We used a maize diversity panel to test the CCM functional conservation. We found heritable variation in enzyme activity for every enzyme tested. One of these enzymes was the NAD-dependent isocitrate dehydrogenase (IDH, E.C. 1.1.1.41), in which we identified a novel amino-acid substitution in a phylogenetically conserved site. Using candidate gene association mapping, we identified that this non-synonymous polymorphism was associated with IDH activity variation. The proposed mechanism for the IDH activity variation includes additional components regulating protein level. With the comparison of sequences from maize and teosinte (Zea mays ssp. Parviglumis), the maize wild ancestor, we found that some CCM genes had also been targeted for selection during maize domestication.

Conclusions/Significance

Our results demonstrate the efficacy of association mapping for dissecting natural variation in primary metabolic pathways. The considerable genetic diversity observed in maize CCM genes underlies heritable phenotypic variation in enzyme activities and can be useful to identify putative functional sites.     

Dynamic Regulation of ME1 Phosphorylation and Acetylation Affects Lipid Metabolism and Colorectal Tumorigenesis

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Mediators of Lipid A Modification, RNA Degradation, and Central Intermediary Metabolism Facilitate the Growth of Legionella pneumophila at Low Temperatures

Legionella pneumophila is an aquatic bacterium that is also the agent of Legionnaires’ disease pneumonia. Since L. pneumophila is transmitted directly from the environment to the lung, it is important to understand how legionellae survive at low temperatures. To identify genes that are needed for L. pneumophila growth at low temperature, we screened a population of mutagenized legionellae for strains that are specifically impaired for growth at 17°C. From the 7,400 mutants tested, 11 displayed defects ranging from ca. 10-fold to a complete inability to grow at the low temperature. PCR and sequence analysis were then utilized to identify the genes whose loss had compromised growth. The proteins thereby implicated in low-temperature growth included components of the type II secretion system (LspE, LspG, LspH), a lipid A biosynthetic enzyme (LpxP), a ribonuclease (RNAse R), an RNA helicase (CsdA/DeaD), TCA cycle enzymes (citrate synthase), enzymes linked to fatty acid (FadB) or amino acid (aspartate aminotransferase) catabolism, and two putative membrane proteins that were, based upon their sequences, unlike previously characterized proteins. Given the magnitude of their mutant’s defect, the aspartate aminotransferase, RNA helicase, and one of the putative membrane proteins were the factors most critical for L. pneumophila low-temperature growth. Thus, L. pneumophila not only employs some of the same processes and factors as other bacteria do in order to survive at low temperatures (e.g., LpxP, CsdA), but it also appears to possess novel modes of cold adaptation.     

Dietary Chromium Picolinate Supplementation Affects Growth,Whole-Body Composition,and Gene Expression Related to Glucose Metabolism and Lipogenesis in Juvenile Blunt Snout Bream,Megalobrama amblycephala

Biological Trace Element Research - An 11-week feeding trial was carried out to investigate the effects of supplemented chromium picolinate (Cr-Pic) on the growth, whole-body composition, and...     

Arsenic Exposure Affects Plasma Insulin-Like Growth Factor 1 (IGF-1) in Children in Rural Bangladesh

Background

Exposure to inorganic arsenic (As) through drinking water during pregnancy is associated with lower birth size and child growth. The aim of the study was to assess the effects of As exposure on child growth parameters to evaluate causal associations.

Methodology/Findings

Children born in a longitudinal mother-child cohort in rural Bangladesh were studied at 4.5 years (n=640) as well as at birth (n=134). Exposure to arsenic was assessed by concurrent and prenatal (maternal) urinary concentrations of arsenic metabolites (U-As). Associations with plasma concentrations of insulin-like growth factor 1 (IGF-1), calcium (Ca), vitamin D (Vit-D), bone-specific alkaline phosphatase (B-ALP), intact parathyroid hormone (iPTH), and phosphate (PO₄) were evaluated by linear regression analysis, adjusted for socioeconomic factor, parity and child sex. Child U-As (per 10 µg/L) was significantly inversely associated with concurrent plasma IGF-1 (β=-0.27; 95% confidence interval: -0.50, -0.0042) at 4.5 years. The effect was more obvious in girls (β=-0.29; -0.59, 0.021) than in boys, and particularly in girls with adequate height (β=-0.491; -0.97, -0.02) or weight (β=-0.47; 0.97, 0.01). Maternal U-As was inversely associated with child IGF-1 at birth (r=-0.254, P=0.003), but not at 4.5 years. There was a tendency of positive association between U-As and plasma PO₄ in stunted boys (β=0.27; 0.089, 0.46). When stratified by % monomethylarsonic acid (MMA, arsenic metabolite) (median split at 9.7%), a much stronger inverse association between U-As and IGF-1 in the girls (β=-0.41; -0.77, -0.03) was obtained above the median split.

Conclusion

The results suggest that As-related growth impairment in children is mediated, at least partly, through suppressed IGF-1 levels.     

Neonatal Hypothyroidism Affects the Adenine Nucleotides Metabolism in Astrocyte Cultures from Rat Brain

Neonatal hypothyroidism is associated with multiple and severe brain alterations. We recently demonstrated a significant increase in hydrolysis of AMP to adenosine in brain of hypothyroid rats at different ages. However, the origin of this effect was unclear. Considering the effects of adenine nucleotides to brain functions and the harmful effects of neonatal hypothyroidism to normal development of the central nervous system, in this study we investigated the metabolism of adenine nucleotides in hippocampal, cortical and cerebellar astrocyte cultures from rats submitted to neonatal hypothyroidism. ATP and AMP hydrolysis were enhanced by 52 and 210%, respectively, in cerebellar astrocytes from hypothyroid rats. In hippocampus of hypothyroid rats, the 47% increase in AMP hydrolysis was significantly reverted when the astrocytes were treated with T3. Therefore, the imbalance in the ATP and adenosine levels in astrocytes, during brain development, may contribute to some of the effects described in neonatal hypothyroidism.Elizandra Braganhol and Alessandra Nejar Bruno are first authors.