Starvation-induced lysosomal degradation of aldolase B requires glutamine 111 in a signal sequence for chaperone-mediated transport

Aldolase B is an abundant cytosolic protein found in all eukaryotic cells. Like many glycolytic enzymes, this protein was sequestered into lysosomes for degradation during nutrient starvation. We report here that the degradation of recombinant aldolase B was enhanced two-fold when rat and human hepatoma cells were starved for amino acid and serum. In addition, starvation-induced degradation of aldolase B was inhibited by chloroquine, an inhibitor of lysosomal proteinases and by 3-methyladenine, an inhibitor of autophagy. Aldolase B has three lysosomal targeting motifs (Q(12)KKEL, Q(58)FREL, and IKLDQ(111)) that have been proposed to interact with hsc73 thereby initiating its transport into lysosomes. In this study, we have mutated the essential glutamine residues in each of these hsc73-binding motifs in order to evaluate their roles in the lysosomal degradation of aldolase B during starvation. We have found that when glutamines 12 or 58 are mutated to asparagines enhanced degradation of aldolase B proceeded normally. However, when glutamine 111 was mutated to an asparagine or a threonine, starvation-induced degradation was completely suppressed. These mutations did not appear to alter the tertiary structure of aldolase B since enzymatic activity was not affected. Our results suggest that starvation-induced lysosomal degradation of aldolase B requires both autophagy and glutamine 111. We discuss the possible roles for autophagy and hsc73-mediated transport in the lysosomal sequestration of aldolase B.     

Localization of embryonic aldolase isoenzyme in rat liver cells after a single injection of the carcinogen, 4-dimethylaminoazobenzene, and its noncarcinogenic analog

The localization of a fetal isoenzyme of aldolase (A) in rat liver cells early after a single injection of carcinogen 4-dimethylaminoazobenzene and its noncarcinogenic analog 4-diethylaminoazobenzene has been studied using the immunofluorescent method. Aldolase A was found in the cytoplasm of oval and "transition" cells. These cells appeared in rat liver as a result of treatment with carcinogen and its analog. In mature hepatocytes aldolase A was not found either in intact rat liver, after the treatment with carcinogen or its analog.     

Molecular evolution of Aldolase A pseudogenes in mice: multiple origins, subsequent duplications, and heterogeneity of evolutionary rates

The Aldolase multigene family comprises three functional genes (A, B, and C) with tissue-specific expression regulated during ontogeny. DGGE analysis and nucleotide sequencing reveal a family of retropseudogenes of type A in species of MUS: Significant variation in rates of evolution of Aldolase A retropseudogenes is apparent. Our analyses demonstrate that (1) multiple events of retrotransposition are needed to account for the diversity of Aldolase A processed pseudogenes found in mice; (2) some of these sequences have undergone further duplication subsequent to the original retrotransposition event; (3) the patterns of nucleotide substitution are broadly comparable with previous estimates; and (4) estimates of rates of divergence for this array of sequences are up to four times higher than those reported in the literature.     

Differential distribution of aldolase A and C in the human central nervous system

We have analyzed the distribution of aldolase A and C mRNAs and proteins in various areas of the human brain using Northern blot analyses and immunohistochemistry. Aldolase A mRNA expression was higher than aldolase C mRNA expression in all areas of the brain examined. Aldolase C mRNA expression was highest in the cerebellum. Aldolase C protein was present in well-delimited regions of the CNS, and was distributed in stripes in the Purkinje cell layer of the cerebellum, in the inferior olives and in the sensory neurons of the posterior horn of the spinal cord. The novel finding of aldolase C in well-delimited cell compartments of the human cerebellum and in several other areas of the CNS lends weight to the hypothesis that this protein exerts other functions (e.g. sensory transmission) besides those characteristic of a glycolytic enzyme.     

Detection of mRNAs present at low concentrations in rat liver by in situ hybridization: application to the study of metabolic regulation and azo dye hepatocarcinogenesis

In situ hybridization on tissue sections was used to detect mRNAs present at low concentrations during metabolic adaptation and azo dye carcinogenesis in rat liver. The method consisted of hybridizing the slices at relatively high stringency with [35S]-labeled single-stranded probes derived from cDNA insert clones into the M13 phage. L-pyruvate kinase mRNA was proved to be present at very low concentrations in hepatocytes of fasted rats and to be relatively abundant in all hepatocytes after 18 hr of refeeding on a carbohydrate-rich diet. Aldolase A mRNA concentrations have been previously shown to increase markedly in liver of 3'-methyl DAB-fed rats, with a maximum at the fourth week. We demonstrate here, using our in situ hybridization technique, that this phenomenon is not due to re-expression of this "fetal marker" in hepatocytes but to its abundancy in proliferating small cells (i.e., so-called oval and transitional cells). Small amounts were also detected in sinusoidal cells. In normal liver, aldolase A mRNAs were detected only in some sinusoidal cells.     

Characterization of fructose-bisphosphate aldolase regulated by gibberellin in roots of rice seedling

Fructose-bisphosphate aldolase is a glycolytic enzyme whose activity increases in rice roots treated with gibberellin (GA). To investigate the relationship between aldolase and root growth, GA-induced root aldolase was characterized. GA₃ promoted an increase in aldolase accumulation when 0.1 M GA₃ was added exogenously to rice roots. Aldolase accumulated abundantly in roots, especially in the apical region. To examine the effect of aldolase function on root growth, transgenic rice plants expressing antisense aldolase were constructed. Root growth of aldolase-antisense transgenic rice was repressed compared with that of the vector control transgenic rice. Although aldolase activity increased by 25% in vector control rice roots treated with 0.1 M GA₃, FBPA activity increased very little by 0.1 M GA₃ treatment in the root of aldolase-antisense transgenic rice. Furthermore, aldolase co-immunoprecipitated with antibodies against vacuolar H⁺-ATPase in rice roots. In the root of OsCDPK13-antisense transgenic rice, aldolase did not accumulate even after treatment with GA₃. These results suggest that the activation of glycolytic pathway function accelerates root growth and that GA₃-induced root aldolase may be modulated through OsCDPK13. Aldolase physically associates with vacuolar H-ATPase in roots and may regulate the vacuolar H-ATPase mediated control of cell elongation that determines root length.     

Studies on the activity of aldolase from rabbit muscles in the presence of liposomes]

Electronmicroscopic studies have been made on the structure of liposomes obtained by the method of Bangham [13] with subsequent ultrasonic desintegration. The effect of muscle aldolase on the structure of liposomes was also investigated. Parallel studies were made on the effect of storage of liposomes upon the activity of aldolase. It was shown that liposomes obtained from chromatographically pure egg lecithin present discrete partially aggregated bodies, 1.000-3.000 A in size, composed by concentric layers, which have a dimension of approximately 40 A and periodicity of about 70 A. Interaction of these particles with the protein results into their desintegration and enlargement, this process being accompanied by the formation of a "fringe" at the edge of the particles. Aldolase activity in these systems in higher than in control. During storage of phosphatide-aqueous system, obtained by the metod of Bungenberg de Jong, activation of aldolase is gradually replaced by its inactivation.     

A hydrophobic pocket in the active site of glycolytic aldolase mediates interactions with Wiskott-Aldrich syndrome protein

Aldolase plays essential catalytic roles in glycolysis and gluconeogenesis. However, aldolase is a highly abundant protein that is remarkably promiscuous in its interactions with other cellular proteins. In particular, aldolase binds to highly acidic amino acid sequences, including the C terminus of the Wiskott-Aldrich syndrome protein, an actin nucleation-promoting factor. Here we report the crystal structure of tetrameric rabbit muscle aldolase in complex with a C-terminal peptide of Wiskott-Aldrich syndrome protein. Aldolase recognizes a short, four-residue DEWD motif (residues 498-501), which adopts a loose hairpin turn that folds around the central aromatic residue, enabling its tryptophan side chain to fit into a hydrophobic pocket in the active site of aldolase. The flanking acidic residues in this binding motif provide further interactions with conserved aldolase active site residues Arg-42 and Arg-303, aligning their side chains and forming the sides of the hydrophobic pocket. The binding of Wiskott-Aldrich syndrome protein to aldolase precludes intramolecular interactions of its C terminus with its active site and is competitive with substrate as well as with binding by actin and cortactin. Finally, based on this structure, a novel naphthol phosphate-based inhibitor of aldolase was identified, and its structure in complex with aldolase demonstrated mimicry of the Wiskott-Aldrich syndrome protein-aldolase interaction. The data support a model whereby aldolase exists in distinct forms that regulate glycolysis or actin dynamics.     

Hybridization between fructose diphosphate aldolase subunits derived from diverse biological systems: anomolous hybridization behavior of some aldolase subunit types

In the present studies we investigated the abilities of fructose diphosphate aldolase subunits derived from diverse biological sources to form stable heterotetramers with each other in vitro. Aldolase C subunits isolated from chicken brain readily "hybridized" with aldolase subunits derived from lobster muscle and wheat germ following reversible acid dissociation of mixtures of these enzymes; however, appreciable amounts of stable heterotetramers containing chicken C subunits and aldolase subunits isolated from two other invertebrates (Ascaris and squid) were not produced under the same conditions. In contrast to the situation with chicken C subunits, aldolase B subunits isolated from rat liver did not "hybridize" appreciably with lobster muscle or wheat germ aldolase subunits. The present observations are not consistent with the hypothesis that the abilities of different aldolase subunit types to form heterotetramers in vitro is governed solely by the evolutionary relationships which exist between the organisms from which the enzymes are derived.     

The cellular distribution of aldolase isozymes in rat kidney and brain determined in tissue sections by the immuno-histochemical method.

The use of the immuno-histochemical method permits the localization of aldolase isozymes in tissue sections. Upon incubating a section with a monomer-specific antiserum, isozymes containing that monomer remain in the section, whereas other cytoplasmic enzymes diffuse out of the section. If soluble antigen is added subsequently, it is bound by the tissue-bound antibody. These antibody fixed aldolases can then be stained by the use of a tetrazolium test linked to substrate hydrolysis. In this way it was demonstrated that isozymes of aldolase containing mostly the A monomer are predominantly localized in the distal tubules, the collecting tubules, the vessels and capillaries of the kidney, the ganglia, the Purkinje cells, the neurons, the white matter and the chorioid plexus of the brain. Aldolase containing mostly B-monomers were found in the proximal tubules. Aldolase isozymes particularly rich in C-monomers were seen in the nervus opticus, the pia mater, the vessels of cerebrum and the molecular layer of the cortex cerebelli.     

A comparative study of aldolase from human muscle and liver

Aldolase was purified from human skeletal muscle and human liver by techniques capable of processing large quantities (10-20kg) of tissue. The methods used also proved convenient for isolating aldolase on a large scale from other mammalian and avian sources. Aldolase from both human liver and muscle was crystallized; each gave two crystalline forms, depending on the conditions of crystallization. X-ray studies on the muscle aldolase crystals suggest a close structural similarity between human and rabbit muscle aldolase. Aldolases from human muscle and liver have similar pH optima and pH stability but their stability to heat treatment differs. The effect of heat on the enzymes may therefore provide an easy means of distinguishing them. The kinetic constants K(m) and k(cat.) for these aldolases are similar to other mammalian aldolases. Amino acid analyses and tryptic peptide ;mapping' show that the primary structures of the two aldolases differ greatly.     

Enzyme make-up of trichophyton rubrum and t. mentagrophytes

Summary Aldolase activity in the cell-free extracts of two dermatophytes,T. mentagrophytes andT. rubrum, was investigated. The kinetics of the enzyme and the effects of metal ions and metal-binders are also reported. The enzyme was more active inT. mentagrophytes than inT. rubrum. The optimum pH for the enzyme action was 7.2 and it was completely inactivated at 60° C. Cobalt and magnesium ions and cysteine activated the enzyme. Inhibition caused by EDTA and o-phenanthroline was partially reversed by cobalt ions. The dermatophyte aldolase resembles bacterial aldolase in its properties.     

Enzymatic studies on the spores of aspergillus niger

Summary Aldolase, phosphoglucomutase and phosphohexoisomerase have been shown to be active in spores of Aspergillus niger after 18 hours of incubation in a synthetic germinating medium. No activity of hexokinase could be detected at this stage.     

F-actin, β-tubulin,aldolase, and fructose-1,6-bisphosphatase in heteropteran ovarioles—I. Immunocytochemical investigations of whole-mounted ovarioles

The distribution of F-actin, -tubulin, aldolase, and fructose-1,6-bisphosphatase (FBPase) in ovarioles of four heteropteran species (Ilyocoris cimicoides, Coreus marginatus, Lygus pratensis, and Notostira elongata) was investigated biochemically and immunocytochemically. Aldolase was found to be uniformly distributed in the cytoplasm of trophocytes and follicular cells, with the highest concentration in prefollicular cells. Its concentration in follicular cells increased during differentiation and reached a peak in ovarian follicles at the stage of late choriogenesis. FBPase was observed in the cytoplasm (weak reaction) and on cell borders (strong reaction) of both germ line and somatic cells. No FBPase or aldolase signal was observed on the F-actin trophic core mesh or on stress fibers.     

Subcellular localization of aldolase B

The localization of the aldolase B isozyme was determined immunohistochemically in rat kidney and liver using a polyclonal antibody. Aldolase B was preferentially localized in a nuclear region of hepatocytes from the periportal region and was absent in those from the perivenous region. Aldolase B was also preferentially localized in the proximal tubules and was absent in other structures of the renal cortex as well as in the renal medulla. Using reflection confocal microscopy, the enzyme was preferentially localized in a nuclear position in liver and renal cells, which was similar to the cellular and intracellular location found for the gluconeogenic enzyme fructose-1,6-bisphosphatase (Sáez et al. [1996] J. Cell. Biochem. 63:453-462). Subcellular fractionation studies followed by enzyme activity assays revealed that aldolase activity was associated with subcellular particulate structures. Overall, the data suggest that different aldolase isoenzymes are needed in the glycolytic and gluconeogenic pathways.     

Soluble and particulate glycolysis in developing castor bean endosperm.

Proplastids from developing castor bean endosperm have been isolated in a discontinuous sucrose density gradient. There was little contamination of the proplastids by mitochondria. Pyruvate kinase activity and phosphofructokinase activity closely correlated with triose phosphate isomerase activity, a proplastid marker, suggesting these two enzymes were contained in the proplastid. Aldolase was also found in the proplastids. The presence of these enzymes indicates that a glycolytic pathway operates in the proplastid.     

Isolation and characterization of pig muscle aldolase. A comparative study

Aldolase with a specific activity of 10.8 units/mg protein was isolated from pig muscle. Its molecular weight was found to be 150,000. The optimum pH for the catalytic activity was 7.25 and the apparent temperature optimum was 313 K. The Km value was 2.9 X 10(-5) M with FDP as substrate, and 2.8 X 10(-3) M with F1P as substrate. The thermal stability of this pig muscle enzyme was higher than that of the rabbit muscle enzyme. The thermal inactivation of the pig aldolase did not show simple first-order kinetics. The higher conformational stability of the pig aldolase than that of the rabbit enzyme was demonstrated by its higher resistance to the denaturing effect of urea.     

Tyrosine nitration impairs mammalian aldolase A activity

Protein tyrosine nitration increases in vivo as a result of oxidative stress and is elevated in numerous inflammatory-associated diseases. Mammalian fructose-1,6-bisphosphate aldolases are tyrosine nitrated in lung epithelial cells and liver, as well as in retina under different inflammatory conditions. Using two-dimensional gel electrophoresis and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry, we now show that aldolase A is nitrated in human skin fibroblasts. To reveal the consequences of tyrosine nitration, we studied the impact of peroxynitrite on the glycolytic functions of aldolase A. A peroxynitrite concentration-dependent decrease in fructose-1,6-bisphosphate cleavage activity was observed with a concomitant increase in nitrotyrosine immunoreactivity. Both V(max) and the K(m) for fructose-1,6-bisphosphate decreased after incubation with peroxynitrite. Aldolase nitrotyrosine immunoreactivity diminished following carboxypeptidase Y digestion, demonstrating that tyrosine residues in the carboxyl-terminal region of aldolase are major targets of nitration. Aldolase A contains a carboxyl-terminal tyrosine residue, Tyr(363), that is critical for its catalytic activity. Indeed, tandem mass spectrometric analysis of trypsin-digested aldolase showed that Tyr(363) is the most susceptible to nitration, with a modification of Tyr(342) occurring only after nitration of Tyr(363). These tyrosine nitrations likely result in altered interactions between the carboxyl-terminal region and enzyme substrate or reaction intermediates causing the decline in activity. The results suggest that tyrosine nitration of aldolase A can contribute to an impaired cellular glycolytic activity.