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100   $a20140908h20142014  uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aChemistry of metalloproteins $eproblems and solutions in bioinorganic chemistry /$fJoseph J. Stephanos, Anthony W. Addison
210  1$aHoboken, New Jersey :$cWiley,$d2014.
210  4$dİ2014
215   $a1 online resource (451 p.)
225 1 $aWiley Series in Protein and Peptide Science
300   $aDescription based upon print version of record.
311   $a1-118-47044-3 
320   $aIncludes bibliographical references and index.
327   $aChemistry of Metalloproteins: Problems and Solutions in Bioinorganic Chemistry; Contents; Preface; 1 Introduction; Proteins: Formation, Structures, and Metalloproteins; Organelles and Their Functions; Structure of DNA; Cell Growth and Division; Protein Synthesis; Common Natural ?-Amino Acids; Peptide Chain Formation; Protein physiological functions; Structural Features of Proteins; Causes of Polypeptide Chain Folding; Metal Amino Acid Complexes; Comparison of P-O versus M-O Bond Scission Rates for Row 3 Elements; Redox Advantages: Sulfur versus Phosphorus; Bioenergetic Phosphate Derivatives
327   $aReferences2 Alkali and Alkaline Earth Cations; References; 3 Nonredox Metalloenzymes; Carboxypeptidases; What are the main functions of carboxypeptidases?; What are the main types of carboxypeptidases?; What are the requirements to stimulate carboxypeptidase-A and carboxypeptidase-B?; What are the main structural features of carboxypeptidase-A and carboxypeptidase-B?; How can Zn2+ be extracted from carboxypeptidase-A and carboxypeptidase-B?What are the consequences of metal ion removal?; What are the spectral consequences when Zn2+ is replaced by Co2+ in carboxypeptidases?
327   $aDescribe the role of Zn2+ in carboxypeptidase-A and carboxypeptidase-B.Design models to mimic the role of the metal ion in carboxypeptidase-A and carboxypeptidase-B.; Carbonic Anhydrase; What are the main functions of carbonic anhydrase?; Conversion of carbonic acid to CO2 and H2O is a spontaneous process. Why is carbonic anhydrase needed?; What are the main structural and chemical features of carbonic anhydrase?; Describe the role of the metal ion in carbonic anhydrase.; What are the possible mechanisms that describe the action of carbonic anhydrase?
327   $aDesign models for the carbonic anhydrase, and what do they reveal?Rate Constants; Alcohol Dehydrogenase; What is the catalytic role and the structural features of the alcohol dehydrogenases?; What is the sequence of events during the reaction of alcohol dehydrogenase?; A number of model systems have been investigated to study the influence of Zn2+ on the reactivity of the carbonyl;  give an example.; References; 4 Copper Proteins; Introduction; Electronic Spectra of Copper Ions; What are the structural and spectral features of copper(II)-peptide complexes in the visible region?
327   $aESR Spectra of Copper IonsHow can  ESR spectra be used as a ``spectral probe ? ? to study copper enzymes?; Define; How do the nuclear-spin of Cu2+ ion and the attached ligands affect the ESR signal? How can the hyperfine and superhyperfine splitting be used as a ``spectral probe ? ? for studying the copper enzymes?; How may the spectrochemical series and the stereochemistry affect g-values of Cu2+ ion and what is the significance of All-gll trend?; Copper Proteins
327   $aIdentify the significant roles of copper in the biological process, classify, give examples, and explain their functions and main chemical properties.
330   $a"This question-and-answer guide on metalloproteins reflects the broad range of aspects within this branch of protein science. It is divided into seven parts, addressing: the cell, the alkali and alkaline earth cations, non-redox metalloenzymes, carboxypeptases, carbonic anhydrase, alcohol dehydrogenase, copper proteins, electronic and ESR spectra of copper ions, plastocyanin, stellacyanin, superoxide dismutase, electronic spectra of iron ions, Mossbauer spectroscopy of iron ions, ESR spectra of Iion (III), iron bioavailability, siderophores, non-heme iron proteins, ferritin, transferrin, dioxygenase-iron proteins, rubredoxin, 2Fe-2S Ferredoxins, 4FE-4S Ferredoxins and hiPIP, aconitase, hydroxylases, hydrogenases, nitrogenases, binuclear Fe proteins, hemerythrin, ribotide reductase, purple acid phosphate and methane mono-oxygenase, heme proteins, myoglobin and hemoglobin, electronic spectra of hemoproteins, cytochrome C, peroxidase, cytochrome P450, ESR spectra of hemoproteins, vitamin B12, and chlorophyll.  Each section ends with suggestions for further reading"--Provided by publisher.
410  0$aWiley series in protein and peptide science.
606   $aMetalloproteins
615  0$aMetalloproteins.
676   $a572/.6076
700   $aStephanos$b Joseph J.$01672532
702   $aAddison$b A. W.
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910827658903321
996   $aChemistry of metalloproteins$94035919
997   $aUNINA