Cellular Lipid Binding Proteins
Developments in Molecular and Cellular Biochemistry 38
Springer
ISBN 9781461348689237 Seiten, Taschenbuch/Paperback
CHF 171.90
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InhaltsangabePreface; J.F.C. Glatz.
1. Cellular lipid binding proteins as facilitators and regulators of lipid metabolism; J.F.C. Glatz, et al.
2. Critical steps in cellular fatty acid uptake and utilization; G.J. van der Vusse, et al.
3. Mechanism of cellular uptake of long-chain fatty acids: do we need cellular proteins? J.A. Hamilton, F. Kamp.
4. Human and rodent fatty acid-binding proteins from liver, intestine, adipose tissue and heart muscle display similar mechanisms of fatty acid transfer to membranes; J. Storch, et al.
5. Cytosolic fatty acid binding proteins catalyze two distinct steps in intracellular transport of their ligands; R.A. Weisiger.
6. Insights into binding of fatty acids by fatty binding proteins; T. Hanhoff, et al.
7. The effect of charge reversal mutations in the -helical region of liver fatty acid binding protein on the binding of fatty acul-CoAs, lysophospholipids and bile acids; R.M. Hagan, et al.
8. Solution structure of fatty acid-binding protein from human brain; M. Rademacher, et al.
9. Evolution of the family of intracellular lipid binding in vertebrates; F.G. Schaap, et al.
10. Intracellular lipid binding proteins of the small intestine; L.B. Agellon, et al.
11. Analysis on the phenotype of E-FABP-gene knock-out mice; Y. Owada, et al.
12. Sterol carrier protein-2: not just for cholesterol anymore; E.J. Murphy.
13. Fatty acid binding protein gene expression in different human adipose tissue depots in relation to rates of lipolysis and insulin concentration in obese individuals; R.M. Fischer, et al.
14. Protein acylation in the cardiac muscle like cell line, H9c2; D.M. Hasselbaink, et al.
15. Alternative lipid mobilization: the insect shuttle system; D.J. Van der Horst, et al.
16. Giant membrane vesicles as a model to study cellular substrate uptake dissected from metabolism; D.P.Y. Koonen, et al.
17. Peroxisome proliferator-activated receptors: lipid binding proteins controlling gene expression; M. van Bilsen, et al.
18. New insights into the fatty acid binding protein (FABP) family in the small intestine; P. Besnard, et al.
19. Regulation of the ileal bile acid-binding protein gene: an approach to determine its physiological function(s); J.-F. Landrier, et al.
20. Role of adipocyte lipid-binding protein (ALBP) and acyl-CoA binding protein (ACBP) in PPAR-mediated transactivation; T. Helledie, et al.
21. Analysis of tissue-specific and PPARa-dependent induction of FABP gene expression in the mouse liver by an in vivo DNA electroporation method; K. Fujishiro, et al.
22. Characterization of a new fatty acid response element that controls the expression of the locust muscle FABP gene; Q. Wu, et al.
23. Regulation of cellular fatty acid transport and membrane transporters in health and disease; A. Bonen, et al.
24. The impact of overexpression and deficiency of fatty acid translocase (FAT/CD36); M. Febbraio, et al.
25. Intestinal lipid absorption is not affected in CD36 deficient mice; J.R. Goudriaan, et al.
26. Surface expression of fatty acid translocase (FAT/CD36) on platelets in myeloproliferative disorders and non-insulin dependent diabetes mellitus: Effect on ara
1. Cellular lipid binding proteins as facilitators and regulators of lipid metabolism; J.F.C. Glatz, et al.
2. Critical steps in cellular fatty acid uptake and utilization; G.J. van der Vusse, et al.
3. Mechanism of cellular uptake of long-chain fatty acids: do we need cellular proteins? J.A. Hamilton, F. Kamp.
4. Human and rodent fatty acid-binding proteins from liver, intestine, adipose tissue and heart muscle display similar mechanisms of fatty acid transfer to membranes; J. Storch, et al.
5. Cytosolic fatty acid binding proteins catalyze two distinct steps in intracellular transport of their ligands; R.A. Weisiger.
6. Insights into binding of fatty acids by fatty binding proteins; T. Hanhoff, et al.
7. The effect of charge reversal mutations in the -helical region of liver fatty acid binding protein on the binding of fatty acul-CoAs, lysophospholipids and bile acids; R.M. Hagan, et al.
8. Solution structure of fatty acid-binding protein from human brain; M. Rademacher, et al.
9. Evolution of the family of intracellular lipid binding in vertebrates; F.G. Schaap, et al.
10. Intracellular lipid binding proteins of the small intestine; L.B. Agellon, et al.
11. Analysis on the phenotype of E-FABP-gene knock-out mice; Y. Owada, et al.
12. Sterol carrier protein-2: not just for cholesterol anymore; E.J. Murphy.
13. Fatty acid binding protein gene expression in different human adipose tissue depots in relation to rates of lipolysis and insulin concentration in obese individuals; R.M. Fischer, et al.
14. Protein acylation in the cardiac muscle like cell line, H9c2; D.M. Hasselbaink, et al.
15. Alternative lipid mobilization: the insect shuttle system; D.J. Van der Horst, et al.
16. Giant membrane vesicles as a model to study cellular substrate uptake dissected from metabolism; D.P.Y. Koonen, et al.
17. Peroxisome proliferator-activated receptors: lipid binding proteins controlling gene expression; M. van Bilsen, et al.
18. New insights into the fatty acid binding protein (FABP) family in the small intestine; P. Besnard, et al.
19. Regulation of the ileal bile acid-binding protein gene: an approach to determine its physiological function(s); J.-F. Landrier, et al.
20. Role of adipocyte lipid-binding protein (ALBP) and acyl-CoA binding protein (ACBP) in PPAR-mediated transactivation; T. Helledie, et al.
21. Analysis of tissue-specific and PPARa-dependent induction of FABP gene expression in the mouse liver by an in vivo DNA electroporation method; K. Fujishiro, et al.
22. Characterization of a new fatty acid response element that controls the expression of the locust muscle FABP gene; Q. Wu, et al.
23. Regulation of cellular fatty acid transport and membrane transporters in health and disease; A. Bonen, et al.
24. The impact of overexpression and deficiency of fatty acid translocase (FAT/CD36); M. Febbraio, et al.
25. Intestinal lipid absorption is not affected in CD36 deficient mice; J.R. Goudriaan, et al.
26. Surface expression of fatty acid translocase (FAT/CD36) on platelets in myeloproliferative disorders and non-insulin dependent diabetes mellitus: Effect on ara