Abstract

The long term objective of this proposal is to understand the molecular basis of the abnormal energy metabolism of many transformed cells, which is characterized phenotypically by a high glucose catabolic rate. The major focus will be on the enzyme hexokinase which catalyzes the first and committed step of glucose catabolism. Significantly, hexokinase is markedly elevated in many transformed cells where it targets mitochondrial receptors. Recent progress has shown that hexokinase is the only glycolytic enzyme in tumor cells bound to the mitochondria, where it serves to preferentially phosphorylate glucose with mitochondrially generated ATP (Can. Res., 1988; JBC, 1988). The purification of the tumor enzyme and its mitochondrial receptor have been completed and a full-length cDNA of the enzyme has been cloned, sequenced and overexpressed in active form in E. coli (Biochem., 1986; Can. Res., 1988; JBC, 1990a, 1990b). Some very fundamental questions can now be addressed about the tumor hexokinase molecule, its capacity for mitochondrial binding, and its high expression during tumor cell growth.
Specific Aims are six-fold: 1. To clearly define, using deletion analysis and synthetic peptides, those regions of the tumor hexokinase molecule involved in mitochondrial binding, catalysis, and regulation by Glu-6-P. 2. To identify, using random and site directed mutational analysis, those amino acids most critical for binding the tumor hexokinase molecule to the outer mitochondrial membrane. 3. To establish, using approaches outlined in """"""""1"""""""" and """"""""2"""""""" above, the relationship between that region of the tumor hexokinase molecule involved in membrane binding and that region involved in ATP-dependent enzyme release. 4. To elucidate the molecular basis of the regulatory process in transformed cells that is primarily responsible for the high """"""""net"""""""" expression of the gene coding for mitochondrial hexokinase. 5. To determine to what extent tumor promoters and growth regulators induce normal cells to take on the cancer phenotype in which hexokinase levels, mitochondrial binding, and high glucose catabolic rates correlate. 6. To elucidate the mechanism of the antitumor drug Lonidamine which inhibits mitochondrial bound hexokinase and glucose catabolism in certain tumor cell lines. The proposed research is not only of fundamental significance to our understanding of glucose catabolism and its regulation, in normal and transformed cells, but may provide new insights into the design of antitumor drugs that target energy metabolism.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA032742-12
Application #
2088388
Study Section
Physical Biochemistry Study Section (PB)
Project Start
1982-08-01
Project End
1995-11-30
Budget Start
1993-12-01
Budget End
1994-11-30
Support Year
12
Fiscal Year
1994
Total Cost
Indirect Cost

  Institution

Name
Johns Hopkins University
Department
Biochemistry
Type
Schools of Medicine
DUNS #
045911138
City
Baltimore
State
MD
Country
United States
Zip Code
21218

  Publications

Mathupala, S P; Rempel, A; Pedersen, P L (1997) Aberrant glycolytic metabolism of cancer cells: a remarkable coordination of genetic, transcriptional, post-translational, and mutational events that lead to a critical role for type II hexokinase. J Bioenerg Biomembr 29:339-43
Mathupala, S P; Heese, C; Pedersen, P L (1997) Glucose catabolism in cancer cells. The type II hexokinase promoter contains functionally active response elements for the tumor suppressor p53. J Biol Chem 272:22776-80
Rempel, A; Mathupala, S P; Griffin, C A et al. (1996) Glucose catabolism in cancer cells: amplification of the gene encoding type II hexokinase. Cancer Res 56:2468-71
Rempel, A; Mathupala, S P; Perdersen, P L (1996) Glucose catabolism in cancer cells: regulation of the Type II hexokinase promoter by glucose and cyclic AMP. FEBS Lett 385:233-7
Arora, K K; Pedersen, P L (1995) Glucokinase of Escherichia coli: induction in response to the stress of overexpressing foreign proteins. Arch Biochem Biophys 319:574-8
Mathupala, S P; Rempel, A; Pedersen, P L (1995) Glucose catabolism in cancer cells. Isolation, sequence, and activity of the promoter for type II hexokinase. J Biol Chem 270:16918-25
Arora, K K; Filburn, C R; Pedersen, P L (1993) Structure/function relationships in hexokinase. Site-directed mutational analyses and characterization of overexpressed fragments implicate different functions for the N- and C-terminal halves of the enzyme. J Biol Chem 268:18259-66
Arora, K K; Pedersen, P L (1993) Glucose utilization by tumor cells: the enzyme hexokinase autophosphorylates both its N- and C-terminal halves. Arch Biochem Biophys 304:515-8
Arora, K K; Parry, D M; Pedersen, P L (1992) Hexokinase receptors: preferential enzyme binding in normal cells to nonmitochondrial sites and in transformed cells to mitochondrial sites. J Bioenerg Biomembr 24:47-53
Arora, K K; Filburn, C R; Pedersen, P L (1991) Glucose phosphorylation. Site-directed mutations which impair the catalytic function of hexokinase. J Biol Chem 266:5359-62

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