Metabolism of some amino acids in relation to the photorespiratory nitrogen cycle of pea leaves

¹⁵N-labelled (amino group) asparagine (Asn), glutamate (Glu), alanine (Ala), aspartate (Asp) and serine (Ser) were used to study the metabolic role and the participation of each compound in the photorespiratory N cycle ofPisum sativum L. leaves. Asparagine was utilised as a nitrogen source by either deamidation or transamination, Glu was converted to Gln through NH₃ assimilation and was a major amino donor for transamination, and Ala was utilised by transamination to a range of amino acids. Transamination also provided a pathway for Asp utilisation, although Asp was also used as a substrate for Asn synthesis. In the photorespiratory synthesis of glycine (Gly), Ser, Ala, Glu and Asn acted as sources of amino-N, contributing, in the order given, 38, 28, 23, and 7% of the N for glycine synthesis; Asp provided less than 4% of the amino-N in glycine. Calculations based on the incorporation of¹⁵N into Gly indicated that about 60% (Ser), 20% (Ala), 12% (Glu) and 11% (Asn) of the N metabolised from each amino acid was utilised in the photorespiratory nitrogen cycle.Abbreviations Ala alamine - Asn asparagine - Asp aspartate - Glu glutamate - MOA methoxylamine - Ser serine     

The effect of 5 days of aspartate and asparagine supplementation on glucose transport activity in rat muscle

The consumption of protein supplements containing amino acids is increasing around the world. Aspartate (Asp) and asparagine (Asn) are amino acids metabolized by skeletal muscle. This metabolism involves biochemical pathways that are involved in increasing Krebs cycle activity via anaplerotic reactions, resulting in higher glutamine concentrations. A connection between amino acid supplementation, glycogen concentration, and glucose uptake has been previously demonstrated. The purpose of this study was to evaluate the effect of Asp and Asn supplementation on glucose uptake in rats using three different glycogen concentrations. The results indicate that Asp and Asn supplementation in rats with high glycogen concentrations (fed state) further increased the glycogen concentration in the muscle, and decreased in vitro 2‐deoxyglucose (a glucose analog) uptake by the muscle at maximal insulin concentrations. When animals had a medium glycogen concentration (consumed lard for 3 days), glucose uptake was higher in the supplemented group at sub‐maximal insulin concentrations. We conclude that supplementation of Asp and Asn reduced glucose transport in rat muscle only at higher levels of glycogen. The ingestion of lard for 3 days changed the responsiveness and sensitivity to insulin, and that group had higher levels of insulin sensitivity with Asp and Asn supplementation. Copyright © 2009 John Wiley & Sons, Ltd.     

Theoretical studies on protein-nucleic acid interactions. II. Hydrogen bonding of amino acid side chains with bases and base pairs of nucleic acids

With a view to understanding the role of hydrogen bonds in the recognition of nucleic acids by proteins, hydrogen bonding between the bases and base pairs of nucleic acids and the amino acids (Asn, Gln, Asp and Glu, and charged residues Arg⁺, Glu^?, and Asp^?) has been studied by a second-order perturbation theory. Binding energies have been calculated for all possible configurations involving a pair of hydrogen bonds between the base (or base pair) and the amino acid residue. Our results show that the hydrogen bonding in these cases has a large contribution from electrostatic interaction. In general, the charged amino acids, compared to the uncharged ones, form more stable complexes with bases or base pairs. The hydrogen-bond energies are an order of magnitude smaller than the Coulombic interaction energies between basic amino acids (Lys⁺, Arg⁺, and His⁺) and the phosphate groups of nucleic acids. The stabilities of the complexes of amino acids Asn, Gln, Asp, and Glu with bases are in the order: G–X > C–X > A–X U–X or T–X, and G · C–X > A · T(U)–X, where X is one of these amino acid residues. It has been shown that Glu^? and Asp^? can recognize guanine in single-stranded nucleic acids; Arg⁺ can recognize G · C base pairs from A · T base pairs in double-stranded structures.     

Amino acid metabolism in maize earshoots. Implications for assimilate preconditioning and nitrogen signaling

Nitrogen (N) is an essential requirement for kernel growth in maize (Zea mays); however, little is known about how N assimilates are metabolized in young earshoots during seed development. The objective of this study was to assess amino acid metabolism in cob and spikelet tissues during the critical 2 weeks following silking. Two maize hybrids were grown in the field for 2 years at two levels of supplemental N fertilizer (0 and 168 kg N/ha). The effects of the reproductive sink on cob N metabolism were examined by comparing pollinated to unpollinated earshoots. Earshoots were sampled at 2, 8, 14, and 18 d after silking; dissected into cob, spikelet, and/or pedicel and kernel fractions; then analyzed for amino acid profiles and key enzyme activities associated with amino acid metabolism. Major amino acids in the cob were glutamine (Gln), aspartic acid (Asp), asparagine (Asn), glutamate, and alanine. Gln concentrations dropped dramatically from 2 to 14 d after silking in both pollinated and unpollinated cobs, whereas all other measured amino acids accumulated over time in unpollinated spikelets and cobs, especially Asn. N supply had a variable effect on individual amino acid levels in young cobs and spikelets, with Asn being the most notably enhanced. We found that the cob performs significant enzymatic interconversions among Gln, alanine, Asp, and Asn during early reproductive development, which may precondition the N assimilate supply for sustained kernel growth. The measured amino acid profiles and enzymatic activities suggest that the Asn to Gln ratio in cobs may be part of a signal transduction pathway involving aspartate aminotransferase, Gln synthetase, and Asn synthetase to indicate plant N status for kernel development.     

Mutagenic analysis of an invariant aspartate residue in chorismate synthase supports its role as an active site base

Chorismate synthase catalyzes the anti-1,4-elimination of the 3-phosphate and the C(6proR) hydrogen from 5-enolpyruvylshikimate 3-phosphate (EPSP) to generate chorismate, the final product of the common shikimate pathway and a precursor for the biosynthesis of aromatic compounds. The enzyme has an absolute requirement for reduced FMN, which is thought to facilitate cleavage of C-O bonds by transiently donating an electron to the substrate. The crystal structure of the enzyme revealed that EPSP is bound near the flavin isoalloxazine ring with several invariant amino acid residues in contact with the substrate and/or cofactor. Here, we report the results of a mutagenesis study in which an invariant aspartate residue at position 367 of the Neurospora crassa chorismate synthase was replaced with alanine and asparagine. Both single mutant proteins (Asp367Ala and Asp367Asn) were comparable to the wild-type enzyme with respect to substrate and cofactor binding, indicating that Asp367 is not required for binding of either the flavin or the substrate. In sharp contrast to these results, the activity of both single mutant proteins was found to be 620 and 310 times lower for the Asp367Ala and Asp367Asn mutant proteins, respectively. This finding provides strong evidence that the carboxylate group of Asp367 plays a major role during the catalytic reaction. On the basis of the structure of the enzyme, our data provide the first experimental evidence that the carboxylate group of aspartate 367 participates in the deprotonation of N(5) of the reduced flavin cofactor, which in turn abstracts the C(6proR) hydrogen yielding chorismate as the product.     

Probing structural determinants specifying high thermostability in Bacillus licheniformis alpha-amylase

Bacillus licheniformis alpha-amylase (BLA) is a starch-degrading enzyme that is highly thermostable although it is produced by a rather mesophilic organism. Over the last decade, the origin of BLA thermal properties has been extensively investigated in both academic and industrial laboratories, yet it is poorly understood. Here, we have used structure-based mutagenesis in order to probe the role of amino acid residues previously proposed as being important for BLA thermostability. Residues involved in salt-bridges, calcium binding or potential deamidation processes have been selected and replaced with various amino acids using a site-directed mutagenesis method, based on informational suppression. A total of 175 amylase variants were created and analysed in vitro. Active amylase variants were tested for thermostability by measuring residual activities after incubation at high temperature. Out of the 15 target residues, seven (Asp121, Asn126, Asp164, Asn192, Asp200, Asp204 and Ala269) were found to be particularly intolerant to any amino acid substitutions, some of which lead to very unstable mutant enzymes. By contrast, three asparagine residues (Asn172, Asn188 and Asn190) could be replaced with amino acid residues that significantly increase the thermostability compared to the wild-type enzyme. The highest stabilization event resulted from the substitution of phenylalanine in place of asparagine at position 190, leading to a sixfold increase of the enzyme's half-life at 80 degrees C (pH 5.6, 0.1 mM CaCl(2)).These results, combined with those of previous mutational analyses, show that the structural determinants contributing to the overall thermostability of BLA concentrate in domain B and at its interface with the central A domain. This region contains a triadic Ca-Na-Ca metal-binding site that appears extremely sensitive to any modification that may alter or reinforce the network of electrostatic interactions entrapping the metal ions. In particular, a loop spanning from residue 178 to 199, which undergoes pronounced conformational changes upon removal of calcium, appears to be the key feature for maintaining the enzyme structural integrity. Outside this region, most salt-bridges that were destroyed by mutations were found to be dispensable, except for an Asp121-Arg127 salt-bridge that contributes to the enhanced thermostability of BLA compared to other homologous bacterial alpha-amylases. Finally, our studies demonstrate that the natural resistance of BLA against high temperature is not optimized and can be enhanced further through various means, including the removal of possibly deamidating residues.     

Theoretical studies on the pyridoxal-5'-phosphate dependent enzyme dopa decarboxylase: effect of thr 246 residue on the co-factor-enzyme binding and reaction mechanism

Decarboxylation of amino acid is a key step for biosynthesis of several important cellular metabolites in the biological systems. This process is catalyzed by amino acid decarboxylases and most of them use pyridoxal-5'-phosphate (PLP) as a co-factor. PLP is bound to the active site of the enzyme by various interactions with the neighboring amino acid residues. In the present investigation, density functional theory (DFT) and real-time dynamics studies on both ligand-free and ligand-bound dopa decarboxylases (DDC) have been carried out in order to elucidate the factors responsible for facile decarboxylation and also for proper binding of PLP in the active site of the enzyme. It has been found that in the crystal structure Asp271 interacts with the pyridine nitrogen atom of PLP through H-bonding in both native and substrate-bound DDC. On the contrary, Thr246 is in close proximity to the oxygen of 3-OH ofPLP pyridine ring only in the substrate-bound DDC. In the ligand-free enzyme, the distance between the oxygen atom of 3-OH group of PLP pyridine ring and oxygen atom of Thr246 hydroxyl group is not favorable for hydrogen bonding. Thus, present study reveals that hydrogen bonding with 03 of PLP with a hydrogen bond donor residue provided by the enzyme plays an important role in the decarboxylation process.     

Mutational analysis of potential pore-lining amino acids in TM IV of the Na(+)/H(+) exchanger

The Na(+)/H(+) exchanger isoform 1 (NHE1) is an integral membrane protein that regulates intracellular pH by extruding an intracellular H(+) in exchange for one extracellular Na(+). In this study we examined the effect of site-specific mutagenesis on the pore-lining amino acid Phe161 and effects of mutagenesis on the charged amino acids Asp159 and Asp172. There was no absolute requirement for a carboxyl side chain at amino acid Asp159 or Asp172. Mutation of Asp159 to Asn or Gln maintained or increased the activity of the protein. Similarly, for Asp172, substitution with a Gln residue maintained activity of the protein, even though substitution with an Asn residue was inhibitory. The Asp172Glu mutant possessed normal activity after correction for its aberrant expression and surface targeting. Replacement of Phe161 with a Leu demonstrated that it was not irreplaceable in NHE1 function. However, the mutation Phe161lys inhibited NHE1 function, while the Phe161Ala mutation caused altered NHE1 targeting and expression levels. Our results show that these three amino acids, while being important in NHE1 function, are not irreplaceable. This study demonstrates that multiple substitutions at a single amino acid residue may be necessary to get a clearer picture membrane protein function.     

Deracemization of Amino Acids by Partial Sublimation and via Homochiral Self-Organization

Deracemization of a 50/50 mixture of enantiomers of aliphatic amino acids (Ala, Leu, Pro, Val) can be achieved by a simple sublimation of a pre-solubilized solid mixture of the racemates with a huge amount of a less-volatile optically active amino acid (Asn, Asp, Glu, Ser, Thr). The choice of chirality correlates with the handedness of the enantiopure amino acids—Asn, Asp, Glu, Ser, and Thr. The deracemization, enantioenrichment and enantiodepletion observed in these experiments clearly demonstrate the preferential homochiral interactions and a tendency of natural amino acids to homochiral self-organization. These data may contribute toward an ultimate understanding of the pathways by which prebiological homochirality might have emerged.     

The pivotal role of glutamate dehydrogenase (GDH) in the mobilization of N and C from storage material to asparagine in germinating seeds of yellow lupine

In germinating seeds of legumes, amino acids liberated during mobilization of storage proteins are partially used for synthesis of storage proteins of the developing axis, but some of them are respired. The amino acids are catabolized by both glutamate dehydrogenase (GDH) and transaminases. Ammonium is reassimilated by glutamine synthetase (GS) and, through the action of asparagine synthetase (AS), is stored in asparagine (Asn).This review presents the ways in which amino acids are converted into Asn and their regulation, mostly in germinating seeds of yellow lupine, where Asn can make up to 30% of dry matter. The energy balance of the synthesis of Asn from glutamate, the most common amino acid in lupine storage proteins, also shows an adaptation of lupine for oxidation of amino acids in early stages of germination.Regulation of the pathway of Asn synthesis is described with regard to the role of GDH and AS, as well as compartmentation of particular metabolites. The regulatory effect of sugar on major links of the pathway (mobilization of storage proteins, induction of genes and activity of GDH and AS) is discussed with respect to recent genetic and molecular studies. Moreover, the effect of glutamate and phytohormones is presented at various stages of Asn biosynthesis.     

Mutational analysis of potential pore-lining amino acids in TM IV of the Na/H exchanger

The Na⁺/H⁺ exchanger isoform 1 (NHE1) is an integral membrane protein that regulates intracellular pH by extruding an intracellular H⁺ in exchange for one extracellular Na⁺. In this study we examined the effect of site-specific mutagenesis on the pore-lining amino acid Phe161 and effects of mutagenesis on the charged amino acids Asp159 and Asp172. There was no absolute requirement for a carboxyl side chain at amino acid Asp159 or Asp172. Mutation of Asp159 to Asn or Gln maintained or increased the activity of the protein. Similarly, for Asp172, substitution with a Gln residue maintained activity of the protein, even though substitution with an Asn residue was inhibitory. The Asp172Glu mutant possessed normal activity after correction for its aberrant expression and surface targeting. Replacement of Phe161 with a Leu demonstrated that it was not irreplaceable in NHE1 function. However, the mutation Phe161lys inhibited NHE1 function, while the Phe161Ala mutation caused altered NHE1 targeting and expression levels. Our results show that these three amino acids, while being important in NHE1 function, are not irreplaceable. This study demonstrates that multiple substitutions at a single amino acid residue may be necessary to get a clearer picture membrane protein function.     

Surface charge engineering of a Bacillus gibsonii subtilisin protease

In proteins, a posttranslational deamidation process converts asparagine (Asn) and glutamine (Gln) residues into negatively charged aspartic (Asp) and glutamic acid (Glu), respectively. This process changes the protein net charge affecting enzyme activity, pH optimum, and stability. Understanding the principles which affect these enzyme properties would be valuable for protein engineering in general. In this work, three criteria for selecting amino acid substitutions of the deamidation type in the Bacillus gibsonii alkaline protease (BgAP) are proposed and systematically studied in their influence on pH-dependent activity and thermal resistance. Out of 113 possible surface amino acids, 18 (11 Asn and 7 Gln) residues of BgAP were selected and evaluated based on three proposed criteria: (1) The Asn or Gln residues should not be conserved, (2) should be surface exposed, and (3) neighbored by glycine. “Deamidation” in five (N97, N253, Q37, Q200, and Q256) out of eight (N97, N154, N250, N253, Q37, Q107, Q200, and Q256) amino acids meeting all criteria resulted in increased proteolytic activity. In addition, pH activity profiles of the variants N253D and Q256E and the combined variant N253DQ256E were dramatically shifted towards higher activity at lower pH (range of 8.5–10). Variant N253DQ256E showed twice the specific activity of wild-type BgAP and its thermal resistance increased by 2.4 °C at pH?8.5. These property changes suggest that mimicking surface deamidation by substituting Gln by Glu and/or Asn by Asp might be a simple and fast protein reengineering approach for modulating enzyme properties such as activity, pH optimum, and thermal resistance.     

beta-Hydroxyaspartic acid or beta-hydroxyasparagine in bovine low density lipoprotein receptor and in bovine thrombomodulin

All of the vitamin K-dependent plasma proteins with domains that are homologous to the epidermal growth factor (EGF) precursor have 1 hydroxylated aspartic acid residue in the NH2-terminal EGF-homology region. In addition, protein S has 1 hydroxylated asparagine residue in each of the three COOH-terminal EGF-homology regions. All of these proteins have been found to have the amino acid sequence, CX(D or N)XXXX(F or Y)XCXC (corresponding to residues 20 to 33 in EGF), where the Asp or Asn residue is hydroxylated. This sequence also appears in two of the three EGF-homology regions of the human low density lipoprotein receptor and in two of the six EGF-homology regions of bovine thrombomodulin so far identified, suggesting that they may have the modified amino acid. We have now identified beta-hydroxyaspartic acid in acid hydrolysates of both these proteins.     

Side-chain structures in the first turn of the alpha-helix

The first three residues at the N terminus of the alpha-helix are called N1, N2 and N3. We surveyed 2102 alpha-helix N termini in 298 high-resolution, non-homologous protein crystal structures for N1, N2 and N3 amino acid and side-chain rotamer propensities and hydrogen-bonding patterns. We find strong structural preferences that are unique to these sites. The rotamer distributions as a function of amino acid identity and position in the helix are often explained in terms of hydrogen-bonding interactions to the free N1, N2 and N3 backbone NH groups. Notably, the "good N2" amino acid residues Gln, Glu, Asp, Asn, Ser, Thr and His preferentially form i, i or i,i+1 hydrogen bonds to the backbone, though this is hindered by good N-caps (Asp, Asn, Ser, Thr and Cys) that compete for these hydrogen bond donors. We find a number of specific side-chain to side-chain interactions between N1 and N2 or between the N-cap and N2 or N3, such as Arg(N-cap) to Asp(N2). The strong energetic and structural preferences found for N1, N2 and N3, which differ greatly from positions within helix interiors, suggest that these sites should be treated explicitly in any consideration of helical structure in peptides or proteins.     

Classification of pseudo pairs between nucleotide bases and amino acids by analysis of nucleotide-protein complexes

Nucleotide bases are recognized by amino acid residues in a variety of DNA/RNA binding and nucleotide binding proteins. In this study, a total of 446 crystal structures of nucleotide-protein complexes are analyzed manually and pseudo pairs together with single and bifurcated hydrogen bonds observed between bases and amino acids are classified and annotated. Only 5 of the 20 usual amino acid residues, Asn, Gln, Asp, Glu and Arg, are able to orient in a coplanar fashion in order to form pseudo pairs with nucleotide bases through two hydrogen bonds. The peptide backbone can also form pseudo pairs with nucleotide bases and presents a strong bias for binding to the adenine base. The Watson-Crick side of the nucleotide bases is the major interaction edge participating in such pseudo pairs. Pseudo pairs between the Watson-Crick edge of guanine and Asp are frequently observed. The Hoogsteen edge of the purine bases is a good discriminatory element in recognition of nucleotide bases by protein side chains through the pseudo pairing: the Hoogsteen edge of adenine is recognized by various amino acids while the Hoogsteen edge of guanine is only recognized by Arg. The sugar edge is rarely recognized by either the side-chain or peptide backbone of amino acid residues.     

Mutational studies using a cation-conducting GABAA receptor reveal the selectivity determinants of the Cys-loop family of ligand-gated ion channels

The present study evaluates how four key amino acid residue positions (- 4' to - 1') within the M1-M2 linker of the GABA(A) receptor beta subunit influences ion selectivity of a cation-conducting GABA receptor. Cation selectivity was found to be highly dependent on the side-chains of the amino acid residues present. The critical factor for cation selectivity was the presence of a negatively charged Glu or Asp residue in the -1' position. Receptors containing the neutral amino acids Gln or Asn or a positively charged Arg residue were anion selective. In the presence of a -1' Glu residue, the amino acids in adjacent positions were also found to be important determinants of cation selectivity. Moreover, the length of the M1-M2 linker as well as the presence of a Pro residue within this segment also affected ion selectivity, suggesting that the local environment and three-dimensional position of the -1' Glu are essential determinants of cation permeation. Conversely, no specific amino acid residues were found to be essential for anion selectivity, suggesting that the basic architecture of the selectivity segment of this class of receptor channels is optimally suited for anion conduction.     

Dissection of helix capping in T4 lysozyme by structural and thermodynamic analysis of six amino acid substitutions at Thr 59.

Threonine 59, a helix-capping residue at the amino terminus of the longest helix in T4 phage lysozyme, was substituted with valine, alanine, glycine, serine, asparagine, and aspartic acid. The valine, alanine, and glycine replacements were observed to be somewhat more destabilizing than serine, asparagine, and aspartic acid. The crystal structures of the different variants showed that changes in conformation occurred at the site of substitution, including Asp 61, which is nearby, as well as displacement of a solvent molecule that is hydrogen-bonded to the gamma-oxygen of Thr 59 in wild-type lysozyme. Neither the structures nor the stabilities of the mutant proteins support the hypothesis of Serrano and Fersht (1989) that glycine and alanine are better helix-capping residues than valine because a smaller-sized residue allows better hydration at the end of the helix. In the aspartic acid and asparagine replacements the substituted side chains form hydrogen bonds with the end of the helix, as does threonine and serine at this position. In contrast, however, the Asp and Asn side chains also make unusually close contacts with carbon atoms in Asp 61. This suggests a structural basis for the heretofore puzzling observations that asparagine is more frequently observed as a helix-capping residue than threonine [Richardson, J. S., & Richardson, D. C. (1988) Science 240, 1648-1652] yet Thr----Asn replacements at N-cap positions in barnase were found to be destabilizing [Serrano, L., & Fersht, A. R. (1989) Nature 342, 296-299].(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification and characterisation of the catalytic triad of the alkaliphilic thermotolerant PHA depolymerase PhaZ7 of Paucimonas lemoignei

The recently discovered extracellular poly[(R)-3-hydroxybutyrate] (PHB) depolymerase PhaZ7 of Paucimonas lemoignei represents the first member of a new subgroup (EC 3.1.1.75) of serine hydrolases with no significant amino acid similarities to conventional PHB depolymerases, lipases or other hydrolases except for a potential lipase box-like motif (Ala-His-Ser136-Met-Gly) and potential candidates for catalytic triad and oxyanion pocket amino acids. In order to identify amino acids essential for activity 11 mutants of phaZ7 were generated by site-directed mutagenesis and expressed in recombinant protease-deficient Bacillus subtilis WB800. The wild-type depolymerase and 10 of the 11 mutant proteins (except for Ser136Cys) were expressed and efficiently secreted by B. subtilis as shown by Western blots of cell-free culture fluid proteins. No PHB depolymerase activity was detected in strains harbouring one of the following substitutions: His47Ala, Ser136Ala, Asp242Ala, Asp242Asn, His306Ala, indicating the importance of these amino acids for activity. Replacement of Ser136 by Thr resulted in a decrease of activity to about 20% of the wild-type level and suggested that the hydroxy group of the serine side chain is important for activity but can be partially replaced by the hydroxy function of threonine. Alterations of Asp256 to Ala or Asn or of the putative serine hydrolase pentapeptide motif (Ala-His-Ser136-Met-Gly) to a lipase box consensus sequence (Gly134-His-Ser136-Met-Gly) or to the PHB depolymerase box consensus sequence (Gly134-Leu135-Ser136-Met-Gly) had no significant effect on PHB depolymerase activity, indicating that these amino acids or sequence motifs were not essential for activity. In conclusion, the PHB depolymerase PhaZ7 is a serine hydrolase with a catalytic triad and oxyanion pocket consisting of His47, Ser136, Asp242 and His306.     

Asparagine catabolism in rat liver mitochondria

A large portion of mitochondrial asparagine (Asn) is degraded by asparagine amino-transferase to produce alpha-ketosuccinamate (alpha KSA), which is then hydrolized by omega-amidase to produce oxaloacetate (OAA) and ammonia. This is in contrast to the catabolism in the cytosol, where the main catabolic route for Asn occurs initially via asparaginase-catalyzed hydrolysis to form aspartate and ammonia. Mitochondrial production of OAA from Asn was followed by monitoring the decrease in the rate of succinate oxidation (which is inhibited by OAA) in both coupled and uncoupled mitochondria. Rapid OAA production was found to be dependent on the presence of both Asn and glyoxylate, and was eliminated by the aminotransferase inhibitor, aminooxyacetate (AOX). HPLC separation and quantitation of alpha-keto acids and amino acids allowed direct observation of the proposed mitochondrial pathway. Studies using L-[U-14C]Asn in mitochondria yielded labeled carbon in alpha KSA, OAA, and CO2 when either an alpha-keto acid or glyoxylate was provided. The extent of the labeled carbon in these products was greatly influenced by factors that affected the citric acid cycle and oxidative phosphorylation. Carbon dioxide production from Asn alone, even in the presence of AOX, suggested the existence of at least one additional Asn catabolic pathway in the rat liver mitochondria which does not involve alpha KSA as an intermediate.