Studies of Propionate Toxicity in Salmonella enterica Identify 2-Methylcitrate as a Potent Inhibitor of Cell Growth

Horswill, Alexander R.; Dudding, Andrea R.; Escalante‐Semerena, Jorge C.

doi:10.1074/jbc.m100244200

Cited by 86 publications

(83 citation statements)

References 51 publications

(42 reference statements)

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“…From a broader physiological perspective, all cells must control their pools of acyl-CoAs to avoid depletion of the pool of free CoA and/or synthesis of toxic metabolites (13,44). This suggests, by analogy with the work reported here and with earlier findings regarding acetyl CoA homeostasis (8), that there might well be other acyltransferase/deacylase systems that cells from all domains of life use to control the activity of acylCoA synthetases.…”

Section: Discussionmentioning

confidence: 61%

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N-Lysine Propionylation Controls the Activity of Propionyl-CoA Synthetase

Garrity

Gardner

Hawse

et al. 2007

Journal of Biological Chemistry

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184

229

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Reversible protein acetylation is a ubiquitous means for the rapid control of diverse cellular processes. Acetyltransferase enzymes transfer the acetyl group from acetyl-CoA to lysine residues, while deacetylase enzymes catalyze removal of the acetyl group by hydrolysis or by an NAD ؉ -dependent reaction. Propionyl-coenzyme A (CoA), like acetyl-CoA, is a high energy product of fatty acid metabolism and is produced through a similar chemical reaction. Because acetyl-CoA is the donor molecule for protein acetylation, we investigated whether proteins can be propionylated in vivo, using propionyl-CoA as the donor molecule. We report that the Salmonella enterica propionyl-CoA synthetase enzyme PrpE is propionylated in vivo at lysine 592; propionylation inactivates PrpE. The propionyl-lysine modification is introduced by bacterial Gcn-5-related N-acetyltransferase enzymes and can be removed by bacterial and human Sir2 enzymes (sirtuins). Like the sirtuin deacetylation reaction, sirtuin-catalyzed depropionylation is NAD ؉ -dependent and produces a byproduct, O-propionyl ADP-ribose, analogous to the O-acetyl ADP-ribose sirtuin product of deacetylation. Only a subset of the human sirtuins with deacetylase activity could also depropionylate substrate. The regulation of cellular propionylCoA by propionylation of PrpE parallels regulation of acetylCoA by acetylation of acetyl-CoA synthetase and raises the possibility that propionylation may serve as a regulatory modification in higher organisms.Protein acetylation is a ubiquitous means for the rapid control of diverse cellular processes (1, 2). Acetylation occurs at lysine residues, with acetyl-CoA (Ac-CoA) 5 serving as the acetyl group donor. In higher organisms, aberrant acetylation of lysine residues in histone tails correlates with diseases such as cancers and developmental disorders and may contribute to modulation of cell life span (3, 4). From bacteria to humans, N-Lys acetylation controls the activity of acetyl-coenzyme A synthetase (AMP-forming; Acs) and potentially that of other members of the AMP-forming family of enzymes (5-7). In Salmonella enterica, Acs is deacetylated by CobB, a member of the Sir2 family of NAD ϩ -dependent deacetylases (a.k.a. sirtuins) (8). Interestingly, strains of S. enterica lacking CobB deacetylase activity cannot grow on propionate because the propionyl-CoA synthetase (encoded by the prpE gene) that activates propionate to propionyl-CoA is not active (5, 9).Cells generate propionyl-CoA from several different processes, including the catabolism of odd chain fatty acids, the decarboxylation of succinate, the catabolism of amino acids (e.g. threonine), and the activation of propionate (10 -12). Propionate is a powerful inhibitor of cell growth that is widely used as a food preservative. Reports in the literature suggest that propionyl-CoA may be responsible for the cytotoxic effects of propionate. Although the direct effects of propionyl-CoA are unclear, it is clear that cells avoid accumulating this metabolite (13-15). The cell maintains...

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Section: Discussionmentioning

confidence: 61%

“…Reports in the literature suggest that propionyl-CoA may be responsible for the cytotoxic effects of propionate. Although the direct effects of propionyl-CoA are unclear, it is clear that cells avoid accumulating this metabolite (13)(14)(15). The cell maintains low levels of propionyl-CoA by using it as a source of carbon and energy.…”

mentioning

confidence: 99%

N-Lysine Propionylation Controls the Activity of Propionyl-CoA Synthetase

Garrity

Gardner

Hawse

et al. 2007

Journal of Biological Chemistry

Self Cite

184

229

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“…However, the mechanisms of propionate toxicity appear to be extremely diverse. Early studies argued that growth inhibition might be caused by generic, non-specific mechanisms such as the dissipation of the proton motive force, decreased intracellular pH or accumulation of the propionate anion in the cytoplasm [1]. More recent work has challenged these notions.…”

Section: Alleviating Propionate Toxicitymentioning

confidence: 98%

“…Consequently, propionate is produced in large quantities (50-100 mM) in the gastrointestinal tract of mammals [1,2]. Plants, insects and micro-organisms utilize several alternative pathways for metabolizing propionate as a carbon source.…”

Section: Introductionmentioning

confidence: 99%

Loving the poison: the methylcitrate cycle and bacterial pathogenesis

et al. 2018

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Propionate is an abundant catabolite in nature and represents a rich potential source of carbon for the organisms that can utilize it. However, propionate and propionate-derived catabolites are also toxic to cells, so propionate catabolism can alternatively be viewed as a detoxification mechanism. In this review, we summarize recent progress made in understanding how prokaryotes catabolize propionic acid, how these pathways are regulated and how they might be exploited to develop novel antibacterial interventions.

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“…MCA exerts several inhibitory effects on TCA cycle enzymes and on the mitochondrial citrate transporter, facilitating mitochondrial accumulation of MCA (34). Furthermore, MCA mainly contributes to propionate sensitivity of bacteria lacking the MCA cycle as detoxifying mechanism (40). Impairment of energy metabolism can interfere with the ability of neurons to maintain normal resting membrane potential due to ATP depletion and can decrease the activity of Na ϩ /K ϩ -ATPases (41).…”

Section: Discussionmentioning

confidence: 99%

Neurodegeneration in Methylmalonic Aciduria Involves Inhibition of Complex II and the Tricarboxylic Acid Cycle, and Synergistically Acting Excitotoxicity

Okun¹,

Hörster²,

Farkas³

et al. 2002

Journal of Biological Chemistry

162

151

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Methylmalonic acidurias are biochemically characterized by an accumulation of methylmalonate (MMA) and alternative metabolites. There is growing evidence for basal ganglia degeneration in these patients. The pathomechanisms involved are still unknown, a contribution of toxic organic acids, in particular MMA, has been suggested. Here we report that MMA induces neuronal damage in cultures of embryonic rat striatal cells at a concentration range encountered in affected patients. MMA-induced cell damage was reduced by ionotropic glutamate receptor antagonists, antioxidants, and succinate. These results suggest the involvement of secondary excitotoxic mechanisms in MMA-induced cell damage. MMA has been implicated in inhibition of respiratory chain complex II. However, MMA failed to inhibit complex II activity in submitochondrial particles from bovine heart. To unravel the mechanism underlying neuronal MMA toxicity, we investigated the formation of intracellular metabolites in MMA-loaded striatal neurons. There was a time-dependent intracellular increase in malonate, an inhibitor of complex II, and 2-methylcitrate, a compound with multiple inhibitory effects on the tricarboxylic acid cycle, suggesting their putative implication in MMA neurotoxicity. We propose that neuropathogenesis of methylmalonic aciduria may involve an inhibition of complex II and the tricarboxylic acid cycle by accumulating toxic organic acids, and synergistic secondary excitotoxic mechanisms.

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Studies of Propionate Toxicity in Salmonella enterica Identify 2-Methylcitrate as a Potent Inhibitor of Cell Growth

Cited by 86 publications

References 51 publications

N-Lysine Propionylation Controls the Activity of Propionyl-CoA Synthetase

N-Lysine Propionylation Controls the Activity of Propionyl-CoA Synthetase

Loving the poison: the methylcitrate cycle and bacterial pathogenesis

Neurodegeneration in Methylmalonic Aciduria Involves Inhibition of Complex II and the Tricarboxylic Acid Cycle, and Synergistically Acting Excitotoxicity

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