Azhar Alhasawi scite author profile

SummaryBacteria have survived, and many have thrived, since antiquity in the presence of the highly-reactive chalcogen-oxygen (O 2 ). They are known to evoke intricate strategies to defend themselves from the reactive by-products of oxygenreactive oxygen species (ROS). Many of these detoxifying mechanisms have been extensively characterized; superoxide dismutase, catalases, alkyl hydroperoxide reductase and the glutathione (GSH)-cycling system are responsible for neutralizing specific ROS. Meanwhile, a pool of NADPH-the reductive engine of many ROS-combating enzymes-is maintained by metabolic enzymes including, but not exclusively, glucose-6 phosphate dehydrogenase (G6PDH) and NADPdependent isocitrate dehydrogenase (ICDH-NADP). So, it is not surprising that evidence continues to emerge demonstrating the pivotal role metabolism plays in mitigating ROS toxicity. Stemming from its ability to concurrently decrease the production of the pro-oxidative metabolite, NADH, while augmenting the antioxidative metabolite, NADPH, metabolism is the fulcrum of cellular redox potential. In this review, we will discuss the mounting evidence positioning metabolism and metabolic shifts observed during oxidative stress, as critical strategies microbes utilize to thrive in environments that are rife with ROS. The contribution of ketoacids-moieties capable of non-enzymatic decarboxylation in the presence of oxidants-as ROS scavengers will be elaborated alongside the metabolic pathways responsible for their homeostases. Further, the signalling role of the carboxylic acids generated following the ketoacid-mediated detoxification of the ROS will be commented on within the context of oxidative stress.

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Dysfunctional mitochondrial bioenergetics and the pathogenesis of hepatic disorders

Auger

Alhasawi

Contavadoo

et al. 2015

Front. Cell Dev. Biol.

107

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The liver is involved in a variety of critical biological functions including the homeostasis of glucose, fatty acids, amino acids, and the synthesis of proteins that are secreted in the blood. It is also at the forefront in the detoxification of noxious metabolites that would otherwise upset the functioning of the body. As such, this vital component of the mammalian system is exposed to a notable quantity of toxicants on a regular basis. It therefore comes as no surprise that there are over a hundred disparate hepatic disorders, encompassing such afflictions as fatty liver disease, hepatitis, and liver cancer. Most if not all of liver functions are dependent on energy, an ingredient that is primarily generated by the mitochondrion, the power house of all cells. This organelle is indispensable in providing adenosine triphosphate (ATP), a key effector of most biological processes. Dysfunctional mitochondria lead to a shortage in ATP, the leakage of deleterious reactive oxygen species (ROS), and the excessive storage of fats. Here we examine how incapacitated mitochondrial bioenergetics triggers the pathogenesis of various hepatic diseases. Exposure of liver cells to detrimental environmental hazards such as oxidative stress, metal toxicity, and various xenobiotics results in the inactivation of crucial mitochondrial enzymes and decreased ATP levels. The contribution of the latter to hepatic disorders and potential therapeutic cues to remedy these conditions are elaborated.

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Reactive nitrogen species (RNS)-resistant microbes: adaptation and medical implications

Tharmalingam

Alhasawi

Appanna

et al. 2017

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Nitrosative stress results from an increase in reactive nitrogen species (RNS) within the cell. Though the RNS - nitric oxide (·NO) and peroxynitrite (ONOO-) - play pivotal physiological roles, at elevated concentrations, these moieties can be poisonous to both prokaryotic and eukaryotic cells alike due to their capacity to disrupt a variety of essential biological processes. Numerous microbes are known to adapt to nitrosative stress by elaborating intricate strategies aimed at neutralizing RNS. In this review, we will discuss both the enzymatic systems dedicated to the elimination of RNS as well as the metabolic networks that are tailored to generate RNS-detoxifying metabolites - α-keto-acids. The latter has been demonstrated to nullify RNS via non-enzymatic decarboxylation resulting in the production of a carboxylic acid, many of which are potent signaling molecules. Furthermore, as aerobic energy production is severely impeded during nitrosative stress, alternative ATP-generating modules will be explored. To that end, a holistic understanding of the molecular adaptation to nitrosative stress, reinforces the notion that neutralization of toxicants necessitates significant metabolic reconfiguration to facilitate cell survival. As the alarming rise in antimicrobial resistant pathogens continues unabated, this review will also discuss the potential for developing therapies that target the alternative ATP-generating machinery of bacteria.

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Glycine metabolism and anti-oxidative defence mechanisms in Pseudomonas fluorescens

Alhasawi

Castonguay

Appanna

et al. 2015

Microbiological Research

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The role of metabolism in anti-oxidative defence is only now beginning to emerge. Here, we show that the nutritionally-versatile microbe, Pseudomonas fluorescens, reconfigures its metabolism in an effort to generate NADPH, ATP and glyoxylate in order to fend off oxidative stress. Glyoxylate was produced predominantly via the enhanced activities of glycine dehydrogenase-NADP(+) (GDH), glycine transaminase (GTA) and isocitrate lyase (ICL) in a medium exposed to hydrogen peroxide (H₂O₂). This ketoacid was utilized to produce ATP by substrate-level phosphorylation and to neutralize reactive oxygen species with the concomitant formation of formate. The latter was also a source of NADPH, a process mediated by formate dehydrogenase-NADP(+) (FDH). The increased activities of phosphoenolpyruvate carboxylase (PEPC) and pyruvate orthophosphate dikinase (PPDK) worked in tandem to synthesize ATP in the H₂O₂-challenged cells that had markedly diminished capacity for oxidative phosphorylation. These metabolic networks provide an effective means of combating ROS and reveal therapeutic targets against microbes resistant to oxidative stress.

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The role of formate in combatting oxidative stress

Thomas

Alhasawi

Auger

et al. 2015

Antonie van Leeuwenhoek

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As all aerobic organisms are exposed to oxidative stress, they are known to devise intricate mechanisms to counter reactive oxygen species (ROS). Metabolic networks contributing to the production of ketoacids are prominent in alleviating the oxidative burden. When glyoxylate detoxifies ROS, formate is the principal by-product generated.In this study the contribution of formate in enabling the survival of the microbe Pseudomonas fluorescens challenged by hydrogen peroxide (H2O2) has been elucidated.When grown in the presence of H2O2 (stressed culture), the levels of formate were higher in the spent fluid and the soluble cell-free extracts compared to the controls. Formate was subsequently utilized as a reducing factor to produce NADPH and succinate. The former is mediated by formate dehydrogenase (FDH-NADP), whose activity was enhanced in the stressed cells. Fumarate reductase (FRD) that catalyzes the conversion of fumarate into succinate was also markedly increased in the stressed cells. Metabolic adaptation is a pivotal tool in combatting oxidative stress. Formate, a by-product of glyoxylate-mediated detoxification of ROS is recuperated as a potent reductive fuel. It is becoming quite evident that this simple metabolite has other biological roles that have not been fully appreciated.

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Azhar Alhasawi

Metabolic defence against oxidative stress: the road less travelled so far

Dysfunctional mitochondrial bioenergetics and the pathogenesis of hepatic disorders

Reactive nitrogen species (RNS)-resistant microbes: adaptation and medical implications

Glycine metabolism and anti-oxidative defence mechanisms in Pseudomonas fluorescens

The role of formate in combatting oxidative stress

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