Betaine aldehyde dehydrogenase from rat liver mitochondrial matrix

Exploring Thermal Sensitivities and Adaptations of Oxidative Phosphorylation Pathways

Temperature shifts are a major challenge to animals; they drive adaptations in organisms and species, and affect all physiological functions in ectothermic organisms. Understanding the origin and mechanisms of these adaptations is critical for determining whether ectothermic organisms will be able to survive when faced with global climate change. Mitochondrial oxidative phosphorylation is thought to be an important metabolic player in this regard, since the capacity of the mitochondria to produce energy greatly varies according to temperature. However, organism survival and fitness depend not only on how much energy is produced, but, more precisely, on how oxidative phosphorylation is affected and which step of the process dictates thermal sensitivity. These questions need to be addressed from a new perspective involving a complex view of mitochondrial oxidative phosphorylation and its related pathways. In this review, we examine the effect of temperature on the commonly measured pathways, but mainly focus on the potential impact of lesser-studied pathways and related steps, including the electron-transferring flavoprotein pathway, glycerophosphate dehydrogenase, dihydroorotate dehydrogenase, choline dehydrogenase, proline dehydrogenase, and sulfide:quinone oxidoreductase. Our objective is to reveal new avenues of research that can address the impact of temperature on oxidative phosphorylation in all its complexity to better portray the limitations and the potential adaptations of aerobic metabolism.

Decline in Liver Mitochondria Metabolic Function Is Restored by Hochuekkito Through Sirtuin 1 in Aged Mice With Malnutrition

Malnutrition impairs basic daily activities and leads to physical frailty, which is aggravated in the elderly compared with young adults. It is also well-known that the elderly are more vulnerable to metabolic stress. Therefore, in this study, using a food restricted (FR) mouse, we aimed to evaluate the effect of aging on locomotor activity and liver metabolic function. Further, we also investigated the involvement of hepatic mitochondria in liver metabolic function during aging, as well as the therapeutic benefit of the traditional Japanese medicine, hochuekkito (HET). Our findings indicated that following food restriction provided as 30% of ad libitum intake for 5 days, the locomotor activity was lower in 23–26-month-old (aged) mice than in 9-week-old (young) mice. Further, compared with young mice, aged mice exhibited significant decreases in the levels of metabolites related to the urea cycle, mitochondrial function, and anti-oxidative stress. The livers of the aged mice also showed a greater decrease in mitochondrial DNA copy number than young mice. Furthermore, the gene expression levels of sirtuin 1 (SIRT1) and mitochondrial biogenesis-related regulators were attenuated in aged mice. However, these changes were partially restored by HET treatment, which also improved locomotor activity, and combined treatment with alanine resulted in more significant effects in this regard. Therefore, our findings suggested that the decrease in locomotor activity in aged FR mice was associated with a decline in the metabolic function of hepatic mitochondria via decreased SIRT1 expression, which was restored by HET treatment. This implies that enhancing the metabolic function of liver mitochondria can contribute to alleviating energy deficiency in the elderly.

Betaine Aldehyde Dehydrogenase expression during physiological cardiac hypertrophy induced by pregnancy

Betaine Aldehyde Dehydrogenase (betaine aldehyde: NAD(P)⁺ oxidoreductase, (E.C. 1.2.1.8; BADH) catalyze the irreversible oxidation of betaine aldehyde (BA) to glycine betaine (GB) and is essential for polyamine catabolism, γ-aminobutyric acid synthesis, and carnitine biosynthesis. GB is an important osmolyte that regulates the homocysteine levels, contributing to a vascular risk factor reduction. In this sense, distinct investigations describe the physiological roles of GB, but there is a lack of information about the GB novo synthesis process and regulation during cardiac hypertrophy induced by pregnancy. In this work, the BADH mRNA expression, protein level, and activity were quantified in the left ventricle before, during, and after pregnancy. The mRNA expression, protein content and enzyme activity along with GB content of BADH increased 2.41, 1.95 and 1.65-fold respectively during late pregnancy compared to not pregnancy, and returned to basal levels at postpartum. Besides, the GB levels increased 1.53-fold during pregnancy and remain at postpartum. Our results demonstrate that physiological cardiac hypertrophy induced BADH mRNA expression and activity along with GB production, suggesting that BADH participates in the adaptation process of physiological cardiac hypertrophy during pregnancy, according to the described GB role in cellular osmoregulation, osmoprotection and reduction of vascular risk.

Betaine is accumulated via transient choline dehydrogenase activation during mouse oocyte meiotic maturation

Betaine (N,N,N-trimethylglycine) plays key roles in mouse eggs and preimplantation embryos first in a novel mechanism of cell volume regulation and second as a major methyl donor in blastocysts, but its origin is unknown. Here, we determined that endogenous betaine was present at low levels in germinal vesicle (GV) stage mouse oocytes before ovulation and reached high levels in the mature, ovulated egg. However, no betaine transport into oocytes was detected during meiotic maturation. Because betaine can be synthesized in mammalian cells via choline dehydrogenase (CHDH; EC 1.1.99.1), we assessed whether this enzyme was expressed and active. Chdh transcripts and CHDH protein were expressed in oocytes. No CHDH enzyme activity was detected in GV oocyte lysate, but CHDH became highly active during oocyte meiotic maturation. It was again inactive after fertilization. We then determined whether oocytes synthesized betaine and whether CHDH was required. Isolated maturing oocytes autonomously synthesized betaine in vitro in the presence of choline, whereas this failed to occur in Chdh^-/- oocytes, directly demonstrating a requirement for CHDH for betaine accumulation in oocytes. Overall, betaine accumulation is a previously unsuspected physiological process during mouse oocyte meiotic maturation whose underlying mechanism is the transient activation of CHDH.

Mechanisms of protection against irreversible oxidation of the catalytic cysteine of ALDH enzymes: Possible role of vicinal cysteines

The catalytic mechanism of the NAD(P)⁺-dependent aldehyde dehydrogenases (ALDHs) involves the nucleophilic attack of the essential cysteine (Cys302, mature HsALDH2 numbering) on the aldehyde substrate. Although oxidation of Cys302 will inactivate these enzymes, it is not yet well understood how this oxidation is prevented. In this work we explore possible mechanisms of protection by systematically analyzing the reported three-dimensional structures and amino acid sequences of the enzymes of the ALDH superfamily. Specifically, we considered the Cys302 conformational space, the structure and residues conservation of the catalytic loop where Cys302 is located, the observed oxidation states of Cys302, the ability of physiological reductants to revert its oxidation, and the presence of vicinal Cys in the catalytic loop. Our analyses suggested that: 1) In the apo-enzyme, the thiol group of Cys302 is quite resistant to oxidation by ambient O₂ or mild oxidative conditions, because the protein environment promotes its high pK_a. 2) NAD(P)⁺ bound in the "hydride transfer" conformation afforded total protection against Cys302 oxidation by an unknown mechanism. 3) If formed, the Cys302-sulfenic acid is protected against irreversible oxidation. 4) Of the physiological reductant agents, the dithiol lipoic acid could reduce a sulfenic or a disulfide bond in the ALDHs active site; glutathione cannot because its thiol group cannot reach Cys302, and other physiological monothiols may be ineffective in those ALDHs where their active site cannot sterically accommodate two molecules of the monothiols. 5) Formation of the disulfides Cys301-Cys302, Cys302-Cys304, Cys302-Cys305 and Cys-302-Cys306 in those ALDHs that have these Cys residues is not probable, because of the permitted Cys conformers as well as the conserved structure and low flexibility of the catalytic loop. 6) Only in some ALDH2, ALDH9, ALDH16 and ALDH23 enzymes, Cys303, alone or in conjunction with Cys301, allows disulfide formation. Interestingly, several of these enzymes are mitochondrial.

Cloning and molecular characterization of the betaine aldehyde dehydrogenase involved in the biosynthesis of glycine betaine in white shrimp (Litopenaeus vannamei)

The enzyme betaine aldehyde dehydrogenase (BADH) catalyzes the irreversible oxidation of betaine aldehyde to glycine betaine (GB), a very efficient osmolyte accumulated during osmotic stress. In this study, we determined the nucleotide sequence of the cDNA for the BADH from the white shrimp Litopenaeus vannamei (LvBADH). The cDNA was 1882 bp long, with a complete open reading frame of 1524 bp, encoding 507 amino acids with a predicted molecular mass of 54.15 kDa and a pI of 5.4. The predicted LvBADH amino acid sequence shares a high degree of identity with marine invertebrate BADHs. Catalytic residues (C-298, E-264 and N-167) and the decapeptide VTLELGGKSP involved in nucleotide binding and highly conserved in BADHs were identified in the amino acid sequence. Phylogenetic analyses classified LvBADH in a clade that includes ALDH9 sequences from marine invertebrates. Molecular modeling of LvBADH revealed that the protein has amino acid residues and sequence motifs essential for the function of the ALDH9 family of enzymes. LvBADH modeling showed three potential monovalent cation binding sites, one site is located in an intra-subunit cavity; other in an inter-subunit cavity and a third in a central-cavity of the protein. The results show that LvBADH shares a high degree of identity with BADH sequences from marine invertebrates and enzymes that belong to the ALDH9 family. Our findings suggest that the LvBADH has molecular mechanisms of regulation similar to those of other BADHs belonging to the ALDH9 family, and that BADH might be playing a role in the osmoregulation capacity of L. vannamei.

Structural determinants of substrate specificity in aldehyde dehydrogenases

Within the aldehyde dehydrogenase (ALDH) superfamily, proteins belonging to the ALDH9, ALDH10, ALDH25, ALDH26 and ALDH27 families display activity as ω-aminoaldehyde dehydrogenases (AMADHs). These enzymes participate in polyamine, choline and arginine catabolism, as well as in synthesis of several osmoprotectants and carnitine. Active site aromatic and acidic residues are involved in binding the ω-aminoaldehydes in plant ALDH10 enzymes. In order to ascertain the degree of conservation of these residues among AMADHs and to evaluate their possible relevance in determining the aminoaldehyde specificity, we compared the known amino acid sequences of every ALDH family that have at least one member with known crystal structure, as well as the electrostatic potential surface of the aldehyde binding sites of these structures. Our analyses showed that four or three aromatic residues form a similar "aromatic box" in the active site of the AMADH enzymes, being the equivalents to Phe170 and Trp177 (human ALDH2 numbering) strictly conserved in all of them, which supports their relevance in binding the aminoaldehyde by cation-π interactions. In addition, all AMADHs exhibit a negative electrostatic potential surface in the aldehyde-entrance tunnel, due to side-chain carboxyl and hydroxyl groups or main-chain carbonyl groups. In contrast, ALDHs that have non-polar or negatively charged substrates exhibit neutral or positive electrostatic potential surfaces, respectively. Finally, our comparative sequence analyses revealed that the residues equivalent to Asp121 and Phe170 are highly conserved in many ALDH families irrespective of their substrate specificity-suggesting that they perform a role in catalysis additional or different to binding of the substrate-and that the positions Met124, Cys301, and Cys303 are hot spots changed during evolution to confer aldehyde specificity to several ALDH families.

Aldehyde sources, metabolism, molecular toxicity mechanisms, and possible effects on human health

Aldehydes are organic compounds that are widespread in nature. They can be formed endogenously by lipid peroxidation (LPO), carbohydrate or metabolism ascorbate autoxidation, amine oxidases, cytochrome P-450s, or myeloperoxidase-catalyzed metabolic activation. This review compares the reactivity of many aldehydes towards biomolecules particularly macromolecules. Furthermore, it includes not only aldehydes of environmental or occupational concerns but also dietary aldehydes and aldehydes formed endogenously by intermediary metabolism. Drugs that are aldehydes or form reactive aldehyde metabolites that cause side-effect toxicity are also included. The effects of these aldehydes on biological function, their contribution to human diseases, and the role of nucleic acid and protein carbonylation/oxidation in mutagenicity and cytotoxicity mechanisms, respectively, as well as carbonyl signal transduction and gene expression, are reviewed. Aldehyde metabolic activation and detoxication by metabolizing enzymes are also reviewed, as well as the toxicological and anticancer therapeutic effects of metabolizing enzyme inhibitors. The human health risks from clinical and animal research studies are reviewed, including aldehydes as haptens in allergenic hypersensitivity diseases, respiratory allergies, and idiosyncratic drug toxicity; the potential carcinogenic risks of the carbonyl body burden; and the toxic effects of aldehydes in liver disease, embryo toxicity/teratogenicity, diabetes/hypertension, sclerosing peritonitis, cerebral ischemia/neurodegenerative diseases, and other aging-associated diseases.

Possible role of alteration of aldehyde's scavenger enzymes during aging

Apoptosis in tissues is induced by different kind of signals including endogenous aldehydes, such as 4-hydroxy-2, 3-nonenal. The accumulation rate of aldehydes in the cell is affected by conditions of oxidative stress. In the cell, aldehydes can be metabolized by various isoforms of aldehyde dehydrogenase, aldehyde reductase, and glutathione-S-transferase. There is evidence suggesting that the catalytic properties of these enzymes change during ontogenesis, and that aging is accompanied by their reduced activities. These functional changes may contribute substantially to the alteration in the organism sensitivity to damaging action of stress factors during aging, to age-related modulation of the action of endogenous aldehydes as a signal for apoptosis, and finally, to the origin of diseases associated with aging. In this context, the stimulation of enzymes' expression, and the activation of the catalytic properties of enzymes responsible for catabolism of endogenous aldehydes could become a perspective direction in increasing the organism resistance to the action of damaging factors during aging.

Purification and characterization of two distinct aldehyde-oxidizing enzymes from the liver of black seabream

Two aldehyde dehydrogenases (ALDH) were purified from the liver of black seabream (Acanthopagrus schlegeli). Chromatography of the liver homogenate on an alpha-cyanocinnamate-Sepharose affinity column results in two activity peaks using acetaldehyde as the substrate. The eluate was subjected to another affinity chromatography on p-hydroxyacetophenone-Sepharose. The final preparation showed a single band on SDS-PAGE with a subunit M.W. of 56,000. N-terminal amino acid sequencing of the first 29 residues followed by blastp analysis on the NCBI database revealed this protein as ALDH-2, as it exhibited 69% identity with human mitochondrial ALDH-2. Chromatography of the alpha-cyanocinnamate-Sepharose column flow-through fractions on Affi-gel Blue agarose yielded another ALDH. The purified protein, with a subunit M.W. of 57,500, was identified as antiquitin (turgor ALDH) by its first 18 N-terminal amino acid residues, which showed 83% identity with the deduced amino acid sequence of human antiquitin. Kinetically, both ALDHs showed maximal activity at pH around 8.5-9.0. They differed, however, in their catalytic efficiency towards the oxidation of acetaldehyde. Antiquitin had much lower affinity towards acetaldehyde; the Km value being approximately 220-fold higher than that of ALDH-2. The Vmax of antiquitin was only approximately 12% of ALDH-2. Antiquitin is believed to be involved in the regulation of cellular turgor pressure. However, all previous studies on antiquitin have been confined to the nucleotide level and the protein has never been isolated from any source. The development of an effective purification procedure and the demonstration that this protein is an enzyme with aldehyde-oxidizing activity would be highly valuable for further investigations on the physiological significance of this evolutionarily conserved protein.

First purification of the antiquitin protein and demonstration of its enzymatic activity

Antiquitin is an evolutionarily conserved protein believed to play a role in the regulation of cellular turgor. Based on sequence analysis, this protein is classified as a member of the aldehyde dehydrogenase superfamily. All previous studies on antiquitin have been confined to the nucleotide level, and the protein has never been purified and characterized. In the present investigation, the antiquitin protein was purified for the first time. An acetaldehyde-oxidizing protein was isolated from the liver of black seabream (Mylio macrocephalus) by chromatographies on alpha-cyanocinnamate Sepharose and Affi-gel Blue agarose, followed by ammonium sulfate precipitation. The purified protein was identified as antiquitin by the first 18 N-terminal amino acid residues which showed 83.3% identity with the deduced sequence of human antiquitin. Electrophoretic mobility studies indicated that black seabream antiquitin is a tetramer with a subunit molecular mass of 57.5 kDa. Kinetic analysis of the purified protein indicated that it catalyzes the oxidation of acetaldehyde with K(m) and V(max) values of 2.0 mM and 1.3 U/mg, respectively. The longer aliphatic propionaldehyde and the aromatic benzaldehyde are also substrates of the purified enzyme. The enzyme is highly specific towards NAD+ as the coenzyme and is totally inactive towards NADP+. Maximal enzymatic activity was found at about pH 9-10.