Inhibition of key glycolytic enzymes from rabbit kidney medulla by free fatty acids in vitro.

In vitro incubation of key glycolytic enzymes in supernatant fluids from rabbit kidney medulla with increasing concentrations of sodium laurate resulted in progressive inhibition of hexokinase, phosphofructokinase and pyruvate kinase. A corresponding reduction in the production of lactate from glucose was also observed. The possible effects of these enzyme inhibitions on the naturesis observed during fasting are discussed.     

Multiple glycolytic enzymes are tightly bound to the fibrous sheath of mouse spermatozoa

The fibrous sheath is a cytoskeletal structure located in the principal piece of mammalian sperm flagella. Previous studies showed that glyceraldehyde 3-phosphate dehydrogenase, spermatogenic (GAPDHS), a germ cell-specific glycolytic isozyme that is required for sperm motility, is tightly bound to the fibrous sheath. To determine if other glycolytic enzymes are also bound to this cytoskeletal structure, we isolated highly purified fibrous sheath preparations from mouse epididymal sperm using a sequential extraction procedure. The isolated fibrous sheaths retain typical ultrastructural features and exhibit little contamination by axonemal or outer dense fiber proteins in Western blot analyses. Proteomic analysis using peptide-mass fingerprinting and MS/MS peptide fragment ion matching identified GAPDHS and two additional glycolytic enzyme subunits, the A isoform of aldolase 1 (ALDOA) and lactate dehydrogenase A (LDHA), in isolated fibrous sheaths. The presence of glycolytic enzymes in the fibrous sheath was also examined by Western blotting. In addition to GAPDHS, ALDOA, and LDHA, this method determined that pyruvate kinase is also tightly bound to the fibrous sheath. These data support a role for the fibrous sheath as a scaffold for anchoring multiple glycolytic enzymes along the length of the flagellum to provide a localized source of ATP that is essential for sperm motility.     

Electron microscopic study of free and ribosome bound rRNAs from E. coli

The morphology of ribosomal subunits, nucleoprotein cores, and free rRNAs from Escherichia coli has been studied by two high resolution electron microscopic techniques. Conventional transmission electron micrographs showed unfolding of 30S and 50S ribosomal subunits with increasing depletion of proteins. With dedicated (0.3 nm resolution) scanning transmission electron microscopy we were able to visualize unstained freeze dried ribosomal subunits and free rRNAs without artifacts of staining and structural distortion by air drying. By this technique, we have also determined the mass of individual ribosomal particles and rRNA molecules. While the ribosomal subunits displayed their characteristic structural features and mass, free rRNAs appeared unfolded and polydisperse. These results provide direct evidence for distinct conformational differences between free rRNAs and native ribosomal subunits of E. coli.     

Comparative levels of muscle glycolytic enzymes in mammals, fish, echinoderm and molluscs.

1. Levels of glycolytic enzymes were determined in terms of units of enzyme/mg protein in rat striated muscle, carp lateral muscle, holothuria longitudinal muscle of the body wall, and a snail foot muscle. 2. An attempt has been made to correlate levels of glycolytic enzymes as a parameter to establish a "biochemical distance" at molecular level and correlate this with the phylogenetic position in animals sufficiently separated in the animal tree of evolution. 3. The possibility of a peculiar kinetic behaviour of the glycolytic pathway in each muscle tissue studied, has been analyzed as the profiles of the ratios of pairs of enzymes bearing a substrate-product dependence. 4. A possible "futile synthesis" of some glycolytic enzymes, such as FDP-aldolase in the case of fish muscle, is proposed.     

Evolution of glycolytic enzymes

The requirements for glycolysis are examined in relation to other essential metabolic processes in the most primitive organisms. The construction of more complex enzymes from primitive domain building blocks is assessed with respect to glycolytic enzymes. Special attention is given to the evolution of the NAD binding domain in dehydrogenases and the related, frequently observed nucleotide binding domain. An attempt is made to differentiate between convergence and divergence of frequently observed domains. Consideration is given to the structure-function relation of these domains and the development of quaternary structure in later stages of evolution. Some attention is also given to the evolution of the structural adaptation to extreme environments as a means of differentiating between essential functions and specific modifications.     

Comparative activities of glycolytic enzymes in yeast and mycelial forms of Candida albicans

Through use of a synthetic defined medium which allows for the exclusive growth of yeast or mycelial forms of Candida albicans the activity of several major glycolytic enzymes in these forms were examined and compared. The results indicate vast metabolic differences between the forms. These data are discussed in relationship to the phenomenon of morphogenesis in C. albicans which in turn relates to problems in immunology and pathogenics of this important opportunistic organism.     

Microcompartmentation of glycolytic enzymes in cultured cells.

The microcompartmentation of aldolase and glyceraldehyde-3-phosphate-dehydrogenase (GAPDH) was investigated in four different cell types (3T3 cells, SV 40 transformed 3T3 cells, mouse fibroblasts, chick embryo cardiomyocytes) combining cell permeabilization and indirect immunofluorescence technique. Permeabilization of the cells prior to fixation released the soluble fractions, whilst the total amount of enzymes was preserved in nonpermeabilized cells. Both enzymes exist in a soluble as well as in a structure-bound form. The soluble fraction of aldolase and GAPDH is distributed homogeneously throughout the cytoplasm, excluding the nucleus and vesicles. The permeabilization-resistant form is associated with the actin cytoskeleton. A considerable amount of both enzymes is located in the perinuclear region and cannot be attributed to a definite structure. Comparing the staining patterns of aldolase and GAPDH in four different cell types we found that the distribution of the enzymes corresponds with diverse forms of actin cytoskeletal organization of these cells. The codistribution is maintained in cells treated with cytochalasin D.     

Inhibition of glycolytic enzymes by 2-phosphotartronate.

2-Phosphotartronate has been synthesized by permanganate oxidation of glycerol 2-phosphate and has been tested as an inhibitor of five glycolytic enzymes that bind phosphoglycerate or phosphoglycollate. Competitive inhibition of rabbit muscle phosphoglycerate mutase, enolase and pyruvate kinase was observed. Triose phosphate isomerase and 3-phosphoglycerate kinase were not inhibited.     

Supramolecular organization of glycolytic enzymes

On the basis of the analysis of the data on adsorption of glycolytic enzymes to structural proteins of skeletal muscles and to the erythrocyte membranes, the data on enzyme-enzyme interactions and the data on the regulation of activity of glycolytic enzymes by cellular metabolites, the structure of the glycolytic enzymes complex adsorbed to a biological support has been proposed. The key role in the formation of multienzyme complex belongs to 6-phosphofructokinase. The enzyme molecule has two association sites, one of which provides the fixation of 6-phosphofructokinase on the support and another is saturated by fructose-1,6-bisphosphate aldolase. The multienzyme complex contains one tetrameric molecule of 6-phosphofructokinase and two molecules of each of other glycolytic enzymes. Hexokinase is not a part of the complex. The molecular mass of the multienzyme complex is about 2.6 X 10(6) daltons. The multienzyme complex has symmetry axis of second order. The formation of the multienzyme complex leads to the compartmentation of glycolytic process. The problem of integration of physico-chemical mechanisms of enzyme activity regulation (allosteric, dissociative and adsorptive mechanisms) is discussed.     

Supramolecular organization of glycolytic enzymes

On the basis of the analysis of the data on adsorption of glycolytic enzymes to structural proteins of skeletal muscle and to erythrocyte membranes, the data on enzyme-enzyme interactions and the data on the regulation of activity of glycolytic enzymes by cellular metabolites the structure of glycolytic enzyme complex adsorbed to a biological support has been proposed. The key role in the formation of the multienzyme complex belongs to 6-phosphofructokinase. The enzyme molecule has two association sites, one of which provides the fixation of 6-phosphofructokinase on the support and another is saturated by fructose-1,6-bisphosphate aldolase. The multienzyme complex fixed on structural proteins of skeletal muscle contains one tetrameric molecule of 6-phosphofructokinase and at two molecules of other glycolytic enzymes. Hexokinase is not involved in the complex composition. The molecular mass of the multienzyme complex is about 2,6 X 10(6) Da. The formation of the multienzyme complex leads to the compartmentation of the glycolytic process. The problem of integration of physico-chemical mechanisms of enzyme activity regulation (allosteric, dissociative and adsorptive mechanisms) is discussed.     

The brush border of rabbit kidney, a cellular compartment free of glycolytic enzymes

Activities of four enzymes of the glycolytic pathway, hexokinase, glyceraldehyde 3-phosphate dehydrogenase, pyruvate kinase and lactate dehydrogenase, were determined in a vesicular brush-border preparation from rabbit kidneys. The specific activities of the enzymes were decreased several-hundredfold in the brush-border preparation compared with a kidney homogenate, but the enzymes were not totally absent. Density-gradient centrifugation of the brush-border preparation yielded brush border of even higher purity and also a characteristic pattern of distribution for each of the contaminating intracellular membranes. The presence of hexokinase in the brush-border preparation could be traced to contaminating mitochondria, and that of glyceraldehyde 3-phosphate dehydrogenase, pyruvate kinase and lactate dehydrogenase to contaminating vesicles derived from the endoplasmic reticulum. The brush-border vesicles contained some ATP. An intravesicular concentration of 0.1mm was estimated, indicating that the vesicles had retained at least a part of their original content. Experiments in which fluorescein isothiocyanate-dextran (mol.wt. 20000) was present during cell lysis revealed that much, but not all, of the brush-border contents had been exchanged with the medium. The complete absence of glycolytic enzymes from brush-border vesicles, which had retained part of their original content, indicates that the brush border does not contain glycolytic enzymes in vivo and can be thought of as a compartment of its own, somehow separated from the cytoplasm.