Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.1.1 (hexokinase)
 5,274 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Data have been obtained suggesting that the complex porin-hexokinase of brain mitochondria may be related to the contact sites between the outer and inner membrane. In the attempt to isolate from brain mitochondria the inner and outer membranes and the boundary membrane contacts, a procedure was developed based on swelling and shrinking of the organelles, followed by sonication and reverse discontinuous density gradient centrifugation. Three fractions were obtained by this technique, which were identified by measuring the relative specific activities of marker enzymes, namely succinate-cytochrome c reductase; NADH-cytochrome c reductase (rotenone insensitive); hexokinase and glutathione transferase, for the inner and outer membranes and contact sites, respectively. The fraction which contains the contact sites is characterized by the highest specific activity of hexokinase and glutathione transferase and by the highest calcium binding capacity; physiological concentrations of this cation produces a sharper separation of this fraction. Results indicate that both the porin-hexokinase gating system of the outer membrane and the calcium transporting complex of the inner membrane are present in the fraction which contains the contact sites.
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PMID:Influence of Ca2+ on the isolation from rat brain mitochondria of a fraction enriched of boundary membrane contact sites. 319 26

By enrichment of contact sites between the two mitochondrial boundary membranes it has been shown that this fraction contained a high activity of glutathione transferase and hexokinase which was bound to the outer membrane pore protein (Ohlendieck, K. et al. (1986) Biochim. Biophys. Acta 860, 672-689). Therefore, an interaction between the three proteins in the contact sites has been suggested. Cross-linking experiments with isolated outer membrane of yeast mitochondria show that glutathione transferase and the pore protein are already associated in the free outer membrane. Porin appeared to adopt four different oligomeric complexes in the membrane, including interactions with a 14 kDa polypeptide, which has glutathione transferase activity. The latter polypeptide could be phosphorylated by intrinsic or extrinsic protein kinases, while the porin itself was not phosphorylated. Yeast hexokinase, when bound to the outer membrane, was able to cross-link to the pore protein.
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PMID:Cross-linking analysis of yeast mitochondrial outer membrane. 352 67

The involvement of the mitochondrial bound hexokinase in aerobic glycolysis was investigated in two subpopulations of the HT 29 human colon cancer cell line: a poorly differentiated one with high aerobic lactate production (referred as undifferentiated or standard cells), and an enterocyte-like differentiated one with lower lactate production (referred as differentiated or Glc- cells). After mild digitonin treatment, 85% of the total cellular hexokinase activity remained in the particulate fraction in both cell types. In both cases mitochondria appeared to be tightly coupled but the Glc- cells exhibited a significantly higher oxidation rate in the presence of glucose. Electron microscopy of freeze-fractured cells revealed the absence of contacts between the two limiting mitochondrial membranes in the highly glycolytic standard cells, whereas the contacts were present in the Glc- cells. Furthermore, we investigated the functional relationship between bound hexokinase (as hexokinase-porin complex) and the inner compartment of mitochondria isolated from standard and Glc- HT 29 cells. In contrast to the differentiated cells the hexokinase in undifferentiated standard cells was not functionally coupled to the oxidative phosphorylation. This suggests that the high rate of lactate formation in neoplastic cells is not caused by an increase of particulate hexokinase activity but rather by a disregulation of the hexokinase-porin complex caused by the absence of contact sites between the two mitochondrial membranes. In agreement with this interpretation, the hexokinase-porin complex could be completely removed by digitonin treatment in standard HT 29 cells, while this was not possible in mitochondria from Glc- cells.
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PMID:Regulation of mitochondrial hexokinase in cultured HT 29 human cancer cells. An ultrastructural and biochemical study. 362 Apr 64

The present study shows that in brain mitochondria the active calcium uptake and the sodium-dependent calcium efflux are modulated by the porin-bound enzyme hexokinase. The release of the enzyme, promoted by glucose-6-phosphate (G-6-P), under conditions which do not affect mitochondrial functions, is accompanied by a decrease of the rates of fluxes of the cation. This phenomenon is discussed and correlated with the formation of microcompartments between the inner and outer mitochondrial membranes, where the hexokinase-porin complex may constitute a regulating gate system for calcium.
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PMID:The role of hexokinase as a possible modulator of Ca2+ movements in isolated rat brain mitochondria. 403 8

The contents of mitochondrial inner membrane protein complexes were compared in normal liver and in Zajdela hepatoma mitochondria by the immunotransfer technique. Antibodies against core proteins 1 and 2, cytochrome c1, the iron-sulfur protein of Complex III, subunits I and II of cytochrome oxidase, and the alpha and beta subunits of the F1-ATPase were used. In addition, antibodies against a primary dehydrogenase, beta-hydroxybutyrate dehydrogenase, as well as the outer membrane pore protein were used. The results indicate that the components of the cytochrome chain and porin are greatly enriched in hepatoma mitochondria compared to normal rat liver mitochondria. This enrichment was also reflected in the rates of respiration in tumor mitochondria using a variety of substrates. Enrichment of porin may partially account for increased hexokinase binding to tumor mitochondria. In contrast to the respiratory chain components, the F1-ATPase and F0 (measured by DCCD binding) were not increased in tumor mitochondria. Thus, Zajdela hepatoma mitochondria components are nonstoichiometric, being enriched in oxidative capacity but relatively deficient in ATP synthesizing capacity. Finally, beta-hydroxybutyrate dehydrogenase, which is often decreased in hepatoma mitochondria, was shown here by immunological methods to be decreased by only 40%, whereas enzyme activity was less than 5% of that in normal rat liver.
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PMID:Immunochemical analysis of the membrane proteins of rat liver and Zajdela hepatoma mitochondria. 609 64

Hexokinase-binding protein and mitochondrial porin were isolated from rat liver mitochondria by different procedures. It was found that the hexokinase-binding protein made lipid vesicles permeable to ADP and formed asymmetric pores in lipid bilayer membranes identical to those obtained from the mitochondrial porin. On the other hand, the mitochondrial porin confers the ability to bind hexokinase. In addition, evidence is presented that both hexokinase-binding protein and mitochondrial porin bind glycerol kinase.
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PMID:Evidence for identity between the hexokinase-binding protein and the mitochondrial porin in the outer membrane of rat liver mitochondria. 628 67

Twelve individuals have been described with glycerol kinase deficiency. Five of these individuals are adults who were noted incidentally to have pseudohypertriglyceridemia. Six of these individuals are children who manifest a clinical complex which includes adrenal hypoplasia/insufficiency and developmental delay. Another child has intermittent coma, a normal IQ, and no evidence of adrenal insufficiency. Genetic and biochemical hypotheses are proposed to explain this clinical variability. Glycerol kinase binds specifically and reversibly to the porin, the pore-forming protein of the outer mitochondrial membrane, which also binds hexokinase. Mutations affecting any component of this kinase-binding system will alter the properties of this system. Glycerol kinase deficiency, as an inborn error of this compartmented metabolic system, offers an investigational opportunity for studying this microenvironment.
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PMID:Human glycerol kinase deficiency: an inborn error of compartmental metabolism. 631 39

The mitochondrial porin or VDAC (Voltage-Dependent Anion Channel), the pore-forming structure responsible for the high permeability of the outer mitochondrial membrane, was found to be one of only three mitochondrial proteins bound by [14C]dicyclohexylcarbodiimide (DCCD) at low dosages (1.5 nmol/mg of mitochondrial porin) (De Pinto, V., Tommasino, M., Benz, R., and Palmieri, F. (1985) Biochim. Biophys. Acta 813, 230-242). Treatment of intact mitochondria with DCCD results in the inhibition of their ability to binding hexokinase (Nakashima, R. A., Mangan, P. S., Colombini, M., and Pedersen, P. L. (1986) Biochemistry 25, 1015-1021). In the present study, mitochondrial porin was purified from [14C]DCCD-labeled mitochondria. The purified labeled porin was treated with the cleavage reagent CNBr and with the endoproteases trypsin and V8 from Staphylococcus aureus and blotted to polyvinylidene difluoride membrane. The transferred peptides were detected with Coomassie Blue dye, excised, and sequenced. The sequences of several labeled and unlabeled peptides were obtained and then overlapped. The region containing the [14C]DCCD radioactivity was limited to 50 amino acid residues and completely sequenced. Covalently incorporated [14C]DCCD was exclusively released at the position corresponding to glutamate 72. The DCCD-reactive residue is located in the 4th of 16 predicted transmembrane amphipathic beta-strands. When the sequence surrounding the DCCD site was compared to those surrounding the DCCD-reactive residue of other membrane proteins, no homology was apparent.
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PMID:Location of the dicyclohexylcarbodiimide-reactive glutamate residue in the bovine heart mitochondrial porin. 768 55

Transport properties of mitochondrial porin were investigated on the basis of changes in the activity of hexokinase utilizing external ATP. Production of glucose 6-phosphate is inhibited by polyanion both in intact brain mitochondria and in contact point vesicles. Hexokinase activity is restored by solubilization of the enzyme by high ionic strength or 0.5-1% Triton X-100. In very low concentrations (0.001-0.005%) Triton does not mobilize hexokinase from its binding sites but it is able to release polyanion-inhibition completely. This finding provides an explanation for the discrepancy observed in the transport properties of porin when studied 'in situ' or in artificial lipid membranes.
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PMID:Trace amounts of Triton X-100 modify the inhibitor sensitivity of the mitochondrial porin. 769 1

Electron microscopy showed the organization of several kinases at the mitochondrial surface as complexes between outer membrane (porin), kinase, and inner membrane (presumably adenine nucleotide translocator?). The complexes were enriched in the isolated contact site fraction. Interaction of porin with the kinases in vitro led to formation of tetramers of hexokinase and active creatine kinase. Kinetic analyses of mitochondria with intact outer compartment showed separate ATP/ADP exchange between kinases and oxidative phosphorylation. Considering these results, we postulate that the mitochondrial metabolism in intact cells is not regulated by free ADP, but induced by substrates wf kinases such as glucose or creatine (Fig 1). Increased ATP turnover in muscle during contraction results in only a small change in the free ADP but causes a larger change of creatine because the equilibrium constant of the creatine kinase reaction at pH 7.2 favours ATP formation (ATP creatine/ADP phosphocreatine = 104.7) [38]. In addition, the level of phosphocreatine is roughly 10-times higher compared to ATP. Considering the higher concentration and the equilibrium constant, it can be calculated that a change of ADP between 40 and 70 microM results in creatine increasing from 8 to 12 mM. Thus creatine can be the signal that stimulates the mitochondrial metabolism transmitted by the mitochondrial creatine kinase [39]. Likewise, increased blood glucose in muscle at rest or in the liver stimulates the mitochondrial metabolism transmitted by the activity of bound hexokinase utilizing external ATP. The mitochondrial metabolism provides the UTP for glycogen synthesis through mitochondrial nucleoside-diphosphate kinase activity (Fig 1).
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PMID:Function of the outer mitochondrial compartment in regulation of energy metabolism. 807 20


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