000 | 00343nam a2200145Ia 4500 | ||
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_c162436 _d162436 |
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020 | _a0849392144 | ||
040 | _cCUS | ||
082 |
_a579.31758 _bROB/T |
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245 | 0 |
_aThermophiles: biology and technology at high tempertatures/ _cedited by Frank Robb [et al.]. |
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250 | _a1st ed. | ||
260 |
_aLondon: _bCRC Press, _c2008. |
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300 |
_axiii, 353 p. : _bill. ; _c25 cm. |
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505 | _aPart I Overview 1 Introduction Part II Molecular Basis of Thermostability 2 Compatible solutes of (hyper)thermophiles and their role in protein stabilization 3 Relationships among catalytic activity, structural flexibility, and conformational stability as deduced from the analysis of mesophilic-thermophilic enzyme pairs and protein engineering studies 4 Membranes and transport proteins of thermophilic microorganisms 5 Thermophilic protein-folding systems 6 Physical properties of membranes composed of tetraether archaeal lipids Part III Heat-Stable Enzymes and Metabolism 7 Glycolysis in hyperthermophiles 8 Industrial relevance of thermophiles and their enzymes 9 Denitrification pathway enzymes of thermophiles Part IV Genetics of Thermophiles 10 DNA stability and repair 11 Plasmids and cloning vectors for thermophilic archaea 12 Genetic analysis in extremely thermophilic bacteria : an overview 13 Targeted gene disruption as a tool for establishing gene function in hyperthermophilic archaea 14 Nanobiotechnological potential of viruses of hyperthermophilic archaea Part V Minimal Complexity Model Systems 15 Master keys to DNA replication, repair, and recombination from the structural biology of enzymes from thermophiles 16 DNA replication in thermophiles 17 DNA-binding proteins and DNA topology 18 Structure and evolution of the Thermus thermophilus ribosome 19 Protein phosphorylation at 80°C and above 20 Archaeal 20S proteasome: a simple and thermostable model system for the core particle | ||
650 | _aThermophilic Microorganisms | ||
700 | _aedited by Robb, Frank | ||
942 | _cSC79 |