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Enzyme Handbook 13

Class 2.5 - EC 2.7.1.104 Transferases

  • Dietmar Schomburg
  • Dörte Stephan

Table of contents

  1. Front Matter
    Pages I-XII
  2. Dietmar Schomburg, Dörte Stephan
    Pages 1-4
  3. Dietmar Schomburg, Dörte Stephan
    Pages 5-10
  4. Dietmar Schomburg, Dörte Stephan
    Pages 11-14
  5. Dietmar Schomburg, Dörte Stephan
    Pages 15-17
  6. Dietmar Schomburg, Dörte Stephan
    Pages 19-21
  7. Dietmar Schomburg, Dörte Stephan
    Pages 23-30
  8. Dietmar Schomburg, Dörte Stephan
    Pages 31-34
  9. Dietmar Schomburg, Dörte Stephan
    Pages 35-38
  10. Dietmar Schomburg, Dörte Stephan
    Pages 39-44
  11. Dietmar Schomburg, Dörte Stephan
    Pages 45-50
  12. Dietmar Schomburg, Dörte Stephan
    Pages 51-55
  13. Dietmar Schomburg, Dörte Stephan
    Pages 57-59
  14. Dietmar Schomburg, Dörte Stephan
    Pages 63-68
  15. Dietmar Schomburg, Dörte Stephan
    Pages 69-72
  16. Dietmar Schomburg, Dörte Stephan
    Pages 73-78
  17. Dietmar Schomburg, Dörte Stephan
    Pages 85-90
  18. Dietmar Schomburg, Dörte Stephan
    Pages 91-94
  19. Dietmar Schomburg, Dörte Stephan
    Pages 95-98
  20. Dietmar Schomburg, Dörte Stephan
    Pages 103-105
  21. Dietmar Schomburg, Dörte Stephan
    Pages 109-111
  22. Dietmar Schomburg, Dörte Stephan
    Pages 113-115
  23. Dietmar Schomburg, Dörte Stephan
    Pages 117-119
  24. Dietmar Schomburg, Dörte Stephan
    Pages 121-123
  25. Dietmar Schomburg, Dörte Stephan
    Pages 127-129
  26. Dietmar Schomburg, Dörte Stephan
    Pages 131-133
  27. Dietmar Schomburg, Dörte Stephan
    Pages 135-137
  28. Dietmar Schomburg, Dörte Stephan
    Pages 141-143
  29. Dietmar Schomburg, Dörte Stephan
    Pages 145-150
  30. Dietmar Schomburg, Dörte Stephan
    Pages 151-154
  31. Dietmar Schomburg, Dörte Stephan
    Pages 155-158
  32. Dietmar Schomburg, Dörte Stephan
    Pages 159-162
  33. Dietmar Schomburg, Dörte Stephan
    Pages 163-166
  34. Dietmar Schomburg, Dörte Stephan
    Pages 167-169
  35. Dietmar Schomburg, Dörte Stephan
    Pages 171-175
  36. Dietmar Schomburg, Dörte Stephan
    Pages 177-179
  37. Dietmar Schomburg, Dörte Stephan
    Pages 181-184
  38. Dietmar Schomburg, Dörte Stephan
    Pages 185-187
  39. Dietmar Schomburg, Dörte Stephan
    Pages 189-191
  40. Dietmar Schomburg, Dörte Stephan
    Pages 193-195
  41. Dietmar Schomburg, Dörte Stephan
    Pages 197-208
  42. Dietmar Schomburg, Dörte Stephan
    Pages 209-214
  43. Dietmar Schomburg, Dörte Stephan
    Pages 215-217
  44. Dietmar Schomburg, Dörte Stephan
    Pages 219-221
  45. Dietmar Schomburg, Dörte Stephan
    Pages 223-226
  46. Dietmar Schomburg, Dörte Stephan
    Pages 231-233
  47. Dietmar Schomburg, Dörte Stephan
    Pages 235-238
  48. Dietmar Schomburg, Dörte Stephan
    Pages 243-245
  49. Dietmar Schomburg, Dörte Stephan
    Pages 247-250
  50. Dietmar Schomburg, Dörte Stephan
    Pages 251-254

About this book

Introduction

Today, as the large international genome sequence projects are gaining a great amount of public attention and huge sequence data bases are created it be­ comes more and more obvious that we are very limited in our ability to access functional data for the gene products - the proteins, in particular for enzymes. Those data are inherently very difficult to collect, interpret and standardize as they are highly distributed among journals from different fields and are often sub­ ject to experimental conditions. Nevertheless a systematic collection is essential for our interpretation of the genome information and more so for possible appli­ cations of that knowledge in the fields of medicine, agriculture, etc .. Recent pro­ gress on enzyme immobilization, enzyme production, enzyme inhibition, coen­ zyme regeneration and enzyme engineering has opened up fascinating new fields for the potential application of enzymes in a large range of different areas. It is the functional profile of an enzyme that enables a biologist of physician to analyze a metabolic pathway and its disturbance; it is the substrate specificity of an enzyme which tells an analytical biochemist how to design an assay; it is the stability, specificity and efficiency of an enzyme which determines its usefulness in the biotechnical transformation of a molecule. And the sum of all these data will have to be considered when the designer of artificial biocatalysts has to choose the optimum prototype to start with.

Keywords

Datensammlung Enzym biotechnology enzymes reaction

Editors and affiliations

  • Dietmar Schomburg
    • 1
  • Dörte Stephan
    • 2
  1. 1.Institut für BiochemieUniversität zu KölnKölnGermany
  2. 2.GBF - Gesellschaft für Biotechnologische Forschung mbHBraunschweigGermany

Bibliographic information

  • DOI https://doi.org/10.1007/978-3-642-59176-1
  • Copyright Information Springer-Verlag Berlin Heidelberg 1997
  • Publisher Name Springer, Berlin, Heidelberg
  • eBook Packages Springer Book Archive
  • Print ISBN 978-3-540-62608-4
  • Online ISBN 978-3-642-59176-1
  • Buy this book on publisher's site
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