Verfügbarkeit: Genes :: THWS Bibkatalog

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Bibliographische Detailangaben
1. Verfasser:	Lewin, Benjamin (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Oxford [u.a.] Oxford Univ. Press 1997
Ausgabe:	6. ed.
Schlagworte:	Gen Genetik Molekulargenetik Lehrbuch
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	XVIII, 1260 S. zahlr. Ill., graph. Darst.
ISBN:	0198577788 0198542879 0198577796

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Datensatz im Suchindex

_version_	1804125763240198144
adam_text	BENJAMIN LEWIN JECHNISCHE HOCHSCHULE DARMSTADT FACKBEREICH 10 - BIOLOGIE - BIBLIOTHEK- SCHNITTSPAHNSTRAFLE 10 0-64287 DARMSUAT, INV.-NR. OXFORD NEW YORK TOKYO OXFORD UNIVERSITY PRESS 1997 OUTLINE INTRODUCTION: CELLS AS MACROMOLECULAR ASSEMBLIES 1 1 PROTEINS 3 2 COMPARTMENTS 27 PART 1: DNA AS INFORMATION 49 3 GENES ARE MUTABLE UNITS 51 4 DNA IS THE GENETIC MATERIAL 71 5 NUCLEIC ACID STRUCTURE 97 6 ISOLATING THE GENE 115 PART 2: FROM GENE TO PROTEIN 151 7 MESSENGER RNA 153 8 PROTEIN SYNTHESIS 179 9 INTERPRETING THE GENETIC CODE 213 10 PROTEIN LOCALIZATION 244 PART 3: PROKARYOTIC GENE EXPRESSION 285 11 TRANSCRIPTION 287 12 THE OPERON 335 13 PHAGE STRATEGIES 395 PART 4: PERPETUATION OF DNA 427 14 THE REPLICON 429 15 DNA REPLICATION 471 16 RESTRICTION AND REPAIR 505 17 RECOMBINATION 531 18 TRANSPOSONS 563 19 RETROVIRUSES AND RETROPOSONS 597 PART 5: THE EUKARYOTIC GENOME 621 20 DNA BIOTECHNOLOGY 623 21 GENOMES 645 22 EXONS AND INTRONS 663 23 GENE NUMBERS 687 24 ORGANELLE GENOMES 713 25 SIMPLE SEQUENCE DNA 727 26 CHROMOSOMES 743 27 NUCLEOSOMES 769 PART 6: EUKARYOTIC GENE EXPRESSION 809 28 INITIATION OF TRANSCRIPTION 811 29 REGULATION OF TRANSCRIPTION 847 30 NUCLEAR SPLICING 885 31 CATALYTIC RNA 921 32 REARRANGEMENT OF DNA 947 33 IMMUNE DIVERSITY 989 PART 7: CELL GROWTH, CANCER, AND DEVELOPMENT 1025 34 PROTEIN TRAFFICKING 1027 35 SIGNAL TRANSDUCTION 1053 36 CELL CYCLE AND GROWTH REGULATION 1089 37 ONCOGENES AND CANCER 1131 38 GRADIENTS AND CASCADES 1173 EPILOGUE: LANDMARK SHIFTS IN PERSPECTIVES 1213 CONTENTS INTRODUCTION: CELLS AS MACROMOLECULAR ASSEMBLIES 1: PROTEINS MACROMOLECULES ARE ASSEMBLED BY POLYMERIZING SMALL MOLECULES PROTEINS CONSIST OF CHAINS OF AMINO ACIDS PROTEIN CONFORMATION DEPENDS ON THE AQUEOUS ENVIRONMENT PROTEIN STRUCTURES ARE EXTREMELY VERSATILE HOW DO PROTEINS FOLD INTO THE CORRECT CONFORMATION? 2: COMPARTMENTS CELLULAR COMPARTMENTS ARE BOUNDED BY MEMBRANES THE CYTOPLASM CONTAINS NETWORKS OF MEMBRANES CELL SHAPE IS DETERMINED BY THE CYTOSKELETON SOME ORGANELLES ARE SURROUNDED BY AN ENVELOPE THE ENVIRONMENT OF THE NUCLEUS AND ITS REORGANIZATION THE ROLE OF CHROMOSOMES IN HEREDITY 3 6 8 13 17 19 27 29 33 36 39 41 43 PART 1: DNA AS INFORMATION 3: GENES ARE MUTABLE UNITS DISCOVERY OF THE GENE GENES LIE IN A LINEAR ARRAY ON CHROMOSOMES ONE GENE*ONE PROTEIN THE CISTRON MAPPING MUTATIONS AT THE MOLECULAR LEVEL THE NATURE OF MULTIPLE ALLELES 4: DNA IS THE GENETIC MATERIAL THE DISCOVERY OF DNA DNA IS THE (ALMOST) UNIVERSAL GENETIC MATERIAL THE COMPONENTS OF DNA DNA IS A DOUBLE HELIX 51 54 56 61 63 65 67 71 74 76 79 82 X I CONTENTS DNA REPLICATION IS SEMICONSERVATIVE THE GENETIC CODE IS READ IN TRIPLETS MUTATIONS CHANGE THE SEQUENCE OF DNA MUTATIONS ARE CONCENTRATED AT HOTSPOTS THE RATE OF MUTATION 5: NUCLEIC ACID STRUCTURE DNA CAN BE DENATURED AND RENATURED NUCLEIC ACIDS HYBRIDIZE BY BASE PAIRING SINGLE-STRANDED NUCLEIC ACIDS MAY HAVE SECONDARY STRUCTURE INVERTED REPEATS AND SECONDARY STRUCTURE DUPLEX DNA HAS ALTERNATIVE DOUBLE-HELICAL STRUCTURES CLOSED DNA CAN BE SUPERCOILED SUPERCOILING INFLUENCES THE STRUCTURE OF THE DOUBLE HELIX 6: ISOLATING THE GENE A RESTRICTION MAP IS CONSTRUCTED BY CLEAVING DNA INTO SPECIFIC FRAGMENTS RESTRICTION SITES CAN BE USED AS GENETIC MARKERS OBTAINING THE SEQUENCE OF DNA PROKARYOTIC GENES AND PROTEINS ARE COLINEAR M-ACTING SITES AND TRANS-ACTING MOLECULES EUKARYOTIC GENES ARE OFTEN INTERRUPTED SOME DNA SEQUENCES CODE FOR MORE THAN ONE PROTEIN GENETIC INFORMATION CAN BE PROVIDED BY DNA OR RNA THE SCOPE OF THE PARADIGM 82 86 89 91 94 97 98 99 101 105 107 109 111 115 117 122 129 134 136 139 141 143 146 PART 2: FROM GENE TO PROTEIN 7: MESSENGER RNA TRANSFER RNA IS THE ADAPTOR MESSENGER RNA IS TRANSLATED BY RIBOSOMES THE LIFE CYCLE OF MESSENGER RNA MOST BACTERIAL GENES ARE EXPRESSED VIA POLYCISTRONIC MESSENGERS TRANSLATION OF EUKARYOTIC MRNA EUKARYOTIC MRNAS ARE POLYADENYLATED AT THE 3 END EUKARYOTIC MRNAS HAVE A METHYLATED CAP AT THE 5 END PROCESSING AND STABILITY OF MRNA 8: PROTEIN SYNTHESIS ORGANIZATION OF THE RIBOSOME THE STAGES OF PROTEIN SYNTHESIS INITIATION IN BACTERIA NEEDS 30S SUBUNITS AND ACCESSORY FACTORS A SPECIAL INITIATOR TRNA STARTS THE POLYPEPTIDE CHAIN INITIATION INVOLVES BASE PAIRING BETWEEN MRNA AND RRNA SMALL SUBUNITS MIGRATE TO INITIATION SITES ON EUKARYOTIC MRNA ELONGATION FACTOR T BRINGS AMINOACYL-TRNA INTO THE A SITE 153 155 159 162 166 168 170 171 173 179 181 183 186 187 191 192 196 CONTENTS I XI TRANSLOCATION MOVES THE RIBOSOME THREE CODONS TERMINATE PROTEIN SYNTHESIS RIBOSOMES HAVE SEVERAL ACTIVE CENTERS THE ROLE OF RIBOSOMAL RNA IN PROTEIN SYNTHESIS 9: INTERPRETING THE GENETIC CODE CODON-ANTICODON RECOGNITION INVOLVES WOBBLING TRNA CONTAINS MODIFIED BASES THAT INFLUENCE ITS PAIRING PROPERTIES THE GENETIC CODE IS ALTERED IN MITOCHONDRIA TRNAS ARE CHARGED WITH AMINO ACIDS BY INDIVIDUAL SYNTHETASES ACCURACY DEPENDS ON PROOFREADING SUPPRESSOR TRNAS HAVE MUTATED ANTICODONS THAT READ NEW CODONS THE ACCURACY OF TRANSLATION TRNA MAY INFLUENCE THE READING FRAME 10: PROTEIN LOCALIZATION CHAPERONES MAY BE REQUIRED FOR PROTEIN FOLDING POST-TRANSLATIONAL MEMBRANE INSERTION DEPENDS ON LEADER SEQUENCES A HIERARCHY OF SEQUENCES DETERMINES LOCATION WITHIN ORGANELLES SIGNAL SEQUENCES INITIATE CO-TRANSLATIONAL TRANSFER THROUGH ER MEMBRANES HOW DO PROTEINS ENTER AND LEAVE MEMBRANES? THE TRANSLOCATION APPARATUS INTERACTS WITH SIGNAL AND ANCHOR SEQUENCES ANCHOR SIGNALS ARE NEEDED FOR MEMBRANE RESIDENCE BACTERIA USE BOTH CO-TRANSLATIONAL AND POST-TRANSLATIONAL TRANSLOCATION PORES CONTROL NUCLEAR INGRESS AND EGRESS PROTEIN DEGRADATION BY PROTEASOMES 198 202 204 207 213 215 217 221 223 228 231 235 237 244 246 251 254 257 258 263 266 269 271 278 PART 3: PROKARYOTIC GENE EXPRESSION 285 11: TRANSCRIPTION TRANSCRIPTION IS CATALYZED BY RNA POLYMERASE RNA POLYMERASE CONSISTS OF MULTIPLE SUBUNITS SIGMA FACTOR CONTROLS BINDING TO DNA PROMOTER RECOGNITION DEPENDS ON CONSENSUS SEQUENCES RNA POLYMERASE BINDS TO ONE FACE OF DNA SUBSTITUTION OF SIGMA FACTORS MAY CONTROL INITIATION SPORULATION UTILIZES A CASCADE OF MANY SIGMA FACTORS BACTERIAL RNA POLYMERASE HAS TWO MODES OF TERMINATION HOW DOES RHO FACTOR WORK? ANTITERMINATION DEPENDS ON SPECIFIC SITES MORE SUBUNITS FOR RNA POLYMERASE 12: THE OPERON STRUCTURAL GENE CLUSTERS ARE COORDINATELY CONTROLLED REPRESSOR IS CONTROLLED BY A SMALL MOLECULE INDUCER MUTATIONS IDENTIFY THE OPERATOR AND THE REGULATOR GENE 287 289 294 297 302 305 309 312 317 320 323 329 335 338 340 343 XII I CONTENTS REPRESSOR PROTEIN BINDS TO THE OPERATOR AND IS RELEASED BY INDUCER THE SPECIFICITY OF PROTEIN-DNA INTERACTIONS REPRESSION CAN OCCUR AT MULTIPLE LOCI DISTINGUISHING POSITIVE AND NEGATIVE CONTROL CATABOLITE REPRESSION INVOLVES POSITIVE REGULATION AT THE PROMOTER ADVERSE GROWTH CONDITIONS PROVOKE THE STRINGENT RESPONSE AUTOGENOUS CONTROL MAY OCCUR AT TRANSLATION ALTERNATIVE SECONDARY STRUCTURES CONTROL ATTENUATION SMALL RNA MOLECULES CAN REGULATE TRANSLATION REGULATION BY CLEAVAGE OF MRNA CLEAVAGES ARE NEEDED TO RELEASE PROKARYOTIC AND EUKARYOTIC RRNAS 13: PHAGE STRATEGIES LYTIC DEVELOPMENT IS CONTROLLED BY A CASCADE FUNCTIONAL CLUSTERING IN PHAGES T7 AND T4 THE LAMBDA LYTIC CASCADE RELIES ON ANTITERMINATION LYSOGENY IS MAINTAINED BY AN AUTOGENOUS CIRCUIT THE DNA-BINDING FORM OF REPRESSOR IS A DIMER REPRESSOR BINDS COOPERATIVELY AT EACH OPERATOR USING A HELIX-TURN-HELIX MOTIF HOW IS REPRESSOR SYNTHESIS ESTABLISHED? A SECOND REPRESSOR IS NEEDED FOR LYTIC INFECTION A DELICATE BALANCE: LYSOGENY VERSUS LYSIS 348 354 357 359 361 365 368 374 380 385 387 395 397 400 403 407 410 412 417 421 423 PART 4: PERPETUATION OF DNA 14: THE REPLICON ORIGINS CAN BE MAPPED BY AUTORADIOGRAPHY AND ELECTROPHORESIS THE BACTERIAL GENOME IS A SINGLE CIRCULAR REPLICON EACH EUKARYOTIC CHROMOSOME CONTAINS MANY REPLICONS ISOLATING THE ORIGINS OF YEAST REPLICONS D LOOPS MAY BE MAINTAINED AT MITOCHONDRIAL ORIGINS THE PROBLEM OF LINEAR REPLICONS ROLLING CIRCLES PRODUCE MULTIMERS OF A REPLICON SINGLE-STRANDED GENOMES ARE GENERATED FOR BACTERIAL CONJUGATION CONNECTING BACTERIAL REPLICATION TO THE CELL CYCLE CELL DIVISION AND CHROMOSOME SEGREGATION MULTIPLE SYSTEMS ENSURE PLASMID SURVIVAL IN BACTERIAL POPULATIONS PLASMID INCOMPATIBILITY IS CONNECTED WITH COPY NUMBER 15: DNA REPLICATION DNA POLYMERASES: THE ENZYMES THAT MAKE DNA DNA SYNTHESIS IS SEMIDISCONTINUOUS AND PRIMED BY RNA THE PRIMOSOME INITIATES SYNTHESIS OF OKAZAKI FRAGMENTS COORDINATING SYNTHESIS OF THE LAGGING AND LEADING STRANDS THE REPLICATION APPARATUS OF PHAGE T4 CREATING THE REPLICATION FORKS AT AN ORIGIN 429 431 433 436 438 440 442 445 449 453 455 460 463 471 472 477 480 484 491 493 CONTENTS I XIII COMMON EVENTS IN PRIMING REPLICATION AT THE ORIGIN 496 DOES METHYLATION AT THE ORIGIN REGULATE INITIATION? 498 LICENSING FACTOR CONTROLS EUKARYOTIC REREPLICATION 500 16: RESTRICTION AND REPAIR 505 THE CONSEQUENCES OF MODIFICATION AND RESTRICTION 506 TYPE II RESTRICTION ENZYMES ARE COMMON 508 THE ALTERNATIVE ACTIVITIES OF TYPE I ENZYMES 510 THE DUAL ACTIVITIES OF TYPE III ENZYMES 513 DEALING WITH INJURIES IN DNA 515 EXCISION REPAIR SYSTEMS IN E. COLI 518 CONTROLLING THE DIRECTION OF MISMATCH REPAIR 521 RETRIEVAL SYSTEMS IN E. COLI 523 RECA TRIGGERS THE SOS SYSTEM 525 EUKARYOTIC REPAIR SYSTEMS 527 17: RECOMBINATION 531 BREAKAGE AND REUNION INVOLVES HETERODUPLEX DNA 534 DOUBLE-STRAND BREAKS INITIATE RECOMBINATION 537 DOUBLE-STRAND BREAKS MAY INITIATE SYNAPSIS 539 BACTERIAL RECOMBINATION INVOLVES SINGLE-STRAND ASSIMILATION 542 GENE CONVERSION ACCOUNTS FOR INTERALLELIC RECOMBINATION 548 TOPOLOGICAL MANIPULATION OF DNA 550 GYRASE INTRODUCES NEGATIVE SUPERCOILS IN DNA 553 SPECIALIZED RECOMBINATION INVOLVES BREAKAGE AND REUNION AT SPECIFIC SITES 555 18: TRANSPOSONS 563 INSERTION SEQUENCES ARE SIMPLE TRANSPOSITION MODULES 565 COMPOSITE TRANSPOSONS HAVE IS MODULES 567 TRANSPOSITION OCCURS BY BOTH REPLICATIVE AND NONREPLICATIVE MECHANISMS 569 COMMON INTERMEDIATES FOR TRANSPOSITION . 572 REPLICATIVE TRANSPOSITION PROCEEDS THROUGH A COINTEGRATE 574 NONREPLICATIVE TRANSPOSITION PROCEEDS BY BREAKAGE AND REUNION 576 TNA TRANSPOSITION REQUIRES TRANSPOSASE AND RESOLVASE 578 TRANSPOSITION OF TNLO HAS MULTIPLE CONTROLS 580 CONTROLLING ELEMENTS IN MAIZE CAUSE BREAKAGE AND REARRANGEMENTS 583 CONTROLLING ELEMENTS IN MAIZE FORM FAMILIES OF TRANSPOSONS 586 SPM ELEMENTS INFLUENCE GENE EXPRESSION 588 THE ROLE OF TRANSPOSABLE ELEMENTS IN HYBRID DYSGENESIS 589 19: RETROVIRUSES AND RETROPOSONS 597 THE RETROVIRUS LIFE CYCLE INVOLVES TRANSPOSITION-LIKE EVENTS 598 RETROVIRUSES MAY TRANSDUCE CELLULAR SEQUENCES 607 YEAST TY ELEMENTS RESEMBLE RETROVIRUSES 609 MANY TRANSPOSABLE ELEMENTS RESIDE IN D. MELANOGASTER 611 RETROPOSONS FALL INTO TWO CLASSES 613 XIV I CONTENTS PART 5: THE EUKARYOTIC GENOME 621 20: DNA BIOTECHNOLOGY ANY DNA SEQUENCE CAN BE CLONED IN BACTERIA OR YEAST CONSTRUCTING THE CHIMERIC DNA COPYING MRNA INTO CDNA ISOLATING INDIVIDUAL GENES FROM THE GENOME WALKING ALONG THE CHROMOSOME EUKARYOTIC GENES CAN BE EXPRESSED IN PROKARYOTIC SYSTEMS 21: GENOMES THE C-VALUE PARADOX DESCRIBES VARIATIONS IN GENOME SIZE REASSOCIATION KINETICS DEPEND ON SEQUENCE COMPLEXITY EUKARYOTIC GENOMES CONTAIN SEVERAL SEQUENCE COMPONENTS NONREPETITIVE DNA COMPLEXITY CAN ESTIMATE GENOME SIZE EUKARYOTIC GENOMES CONTAIN REPETITIVE SEQUENCES MOST STRUCTURAL GENES LIE IN NONREPETITIVE DNA HOW MANY NONREPETITIVE GENES ARE EXPRESSED? GENES ARE EXPRESSED AT WIDELY VARYING LEVELS 22: EXONS AND INTRONS , ORGANIZATION OF INTERRUPTED GENES MAY BE CONSERVED GENES SHOW A WIDE DISTRIBUTION OF SIZES ONE DNA SEQUENCE MAY CODE FOR MULTIPLE PROTEINS EXON SEQUENCES ARE CONSERVED BUT INTRONS VARY GENES CAN BE ISOLATED BY THE CONSERVATION OF EXONS HOW DID INTERRUPTED GENES EVOLVE? 23: GENE NUMBERS ESSENTIAL GENES AND TOTAL GENE NUMBER GLOBIN GENES ARE ORGANIZED IN TWO CLUSTERS UNEQUAL CROSSING-OVER REARRANGES GENE CLUSTERS GENE CLUSTERS SUFFER CONTINUAL REORGANIZATION SEQUENCE DIVERGENCE IS THE BASIS FOR THE EVOLUTIONARY CLOCK PSEUDOGENES ARE DEAD ENDS OF EVOLUTION GENES FOR RRNA COMPRISE A REPEATED TANDEM UNIT AN EVOLUTIONARY DILEMMA: HOW ARE MULTIPLE ACTIVE COPIES MAINTAINED? 24: ORGANELLE GENOMES ORGANELLE GENOMES ARE CIRCULAR DNAS THAT CODE FOR ORGANELLE PROTEINS THE CHLOROPLAST GENOME CODES FOR -100 PROTEINS AND RNAS THE MITOCHONDRIAL GENOME IS LARGE IN YEAST BUT SMALL IN MAMMALS RECOMBINATION AND REARRANGEMENT OF ORGANELLE DNA 25: SIMPLE SEQUENCE DNA SATELLITE DNAS OFTEN LIE IN HETEROCHROMATIN ARTHROPOD SATELLITES HAVE VERY SHORT IDENTICAL REPEATS 623 624 626 629 631 636 640 645 646 648 650 651 652 654 657 659 663 665 668 672 674 676 679 687 689 692 694 698 699 703 704 708 713 715 719 720 723 727 729 730 CONTENTS I XV MAMMALIAN SATELLITES CONSIST OF HIERARCHICAL REPEATS EVOLUTION OF HIERARCHICAL VARIATIONS IN THE SATELLITE THE CONSEQUENCES OF UNEQUAL CROSSING-OVER CROSSOVER FIXATION COULD MAINTAIN IDENTICAL REPEATS MINISATELLITES ARE USEFUL FOR GENETIC MAPPING 26: CHROMOSOMES CONDENSING VIRAL GENOMES INTO THEIR COATS THE BACTERIAL GENOME IS A NUCLEOID WITH MANY SUPERCOILED LOOPS LOOPS, DOMAINS, AND SCAFFOLDS IN EUKARYOTIC DNA THE CONTRAST BETWEEN INTERPHASE CHROMATIN AND MITOTIC CHROMOSOMES THE EXTENDED STATE OF LAMPBRUSH CHROMOSOMES TRANSCRIPTION DISRUPTS THE STRUCTURE OF POLYTENE CHROMOSOMES THE EUKARYOTIC CHROMOSOME AS A SEGREGATION DEVICE TELOMERES SEAL THE ENDS OF CHROMOSOMES 27: NUCLEOSOMES THE NUCLEOSOME IS THE SUBUNIT OF ALL CHROMATIN DNA IS COILED IN ARRAYS OF NUCLEOSOMES DNA STRUCTURE VARIES ON THE NUCLEOSOMAL SURFACE SUPERCOILING AND THE PERIODICITY OF DNA THE PATH OF NUCLEOSOMES IN THE CHROMATIN FIBER ORGANIZATION OF THE HISTONE OCTAMER REPRODUCTION OF CHROMATIN REQUIRES ASSEMBLY OF NUCLEOSOMES DO NUCLEOSOMES LIE AT SPECIFIC POSITIONS? ARE TRANSCRIBED GENES ORGANIZED IN NUCLEOSOMES? DNAASE HYPERSENSITIVE SITES CHANGE CHROMATIN STRUCTURE DOMAINS DEFINE REGIONS THAT CONTAIN ACTIVE GENES HETEROCHROMATIN IS CREATED BY INTERACTIONS WITH HISTONES 730 734 736 738 739 743 744 747 750 753 756 757 760 763 769 770 773 777 780 782 784 787 791 794 798 801 803 PART 6: EUKARYOTIC GENE EXPRESSION 809 28: INITIATION OF TRANSCRIPTION EUKARYOTIC RNA POLYMERASES CONSIST OF MANY SUBUNITS PROMOTER ELEMENTS ARE DEFINED BY MUTATIONS AND FOOTPRINTING RNA POLYMERASE I HAS A BIPARTITE PROMOTER RNA POLYMERASE III USES BOTH DOWNSTREAM AND UPSTREAM PROMOTERS THE BASAL APPARATUS CONSISTS OF RNA POLYMERASE II AND GENERAL FACTORS A CONNECTION BETWEEN TRANSCRIPTION AND REPAIR PROMOTERS FOR RNA POLYMERASE II HAVE SHORT SEQUENCE ELEMENTS ENHANCERS CONTAIN BIDIRECTIONAL ELEMENTS THAT ASSIST INITIATION INDEPENDENT DOMAINS BIND DNA AND ACTIVATE TRANSCRIPTION INTERACTION OF UPSTREAM FACTORS WITH THE BASAL APPARATUS 811 814 815 817 819 822 829 831 835 839 842 XVI I CONTENTS 29: REGULATION OF TRANSCRIPTION 847 RESPONSE ELEMENTS IDENTIFY GENES UNDER COMMON REGULATION 848 THERE ARE MANY TYPES OF DNA-BINDING DOMAINS 850 A ZINC FINGER MOTIF IS A DNA-BINDING DOMAIN 852 STEROID RECEPTORS HAVE SEVERAL INDEPENDENT DOMAINS 855 HOMEODOMAINS BIND RELATED TARGETS IN DNA 859 HELIX-LOOP-HELIX PROTEINS INTERACT BY COMBINATORIAL ASSOCIATION 862 LEUCINE ZIPPERS ARE INVOLVED IN DIMER FORMATION 864 DYNAMIC VERSUS PRE-EMPTIVE MODELS FOR GENE ACTIVATION 866 LONG RANGE REGULATION AND INSULATION OF DOMAINS 871 GENE EXPRESSION IS ASSOCIATED WITH DEMETHYLATION 875 METHYLATION IS RESPONSIBLE FOR IMPRINTING 878 30: NUCLEAR SPLICING 885 NUCLEAR SPLICE JUNCTIONS ARE INTERCHANGEABLE BUT ARE READ IN PAIRS 887 NUCLEAR SPLICING PROCEEDS THROUGH A LARIAT 891 SNRNAS ARE REQUIRED FOR SPLICING AND FORM A SPLICEOSOME 893 GROUP II INTRONS AUTOSPLICE VIA LARIAT FORMATION 901 ALTERNATIVE SPLICING INVOLVES DIFFERENTIAL USE OF SPLICE JUNCTIONS 904 EIS-SPLICING AND JRANS-SPLICING REACTIONS 907 YEAST TRNA SPLICING INVOLVES CUTTING AND REJOINING 911 3 ENDS ARE GENERATED BY TERMINATION AND BY CLEAVAGE REACTIONS 913 31: CATALYTIC RNA 921 GROUP I INTRONS UNDERTAKE SELF-SPLICING BY TRANSESTERIFICATION 922 GROUP I INTRONS FORM A CHARACTERISTIC SECONDARY STRUCTURE 926 RIBOZYMES HAVE VARIOUS CATALYTIC ACTIVITIES 928 SOME INTRONS CODE FOR PROTEINS THAT SPONSOR MOBILITY 931 RNA CAN HAVE RIBONUCLEASE ACTIVITIES . 935 RNA EDITING UTILIZES INFORMATION FROM SEVERAL SOURCES 937 32: REARRANGEMENT OF DNA 947 THE MATING PATHWAY IS TRIGGERED BY SIGNAL TRANSDUCTION 948 YEAST CAN SWITCH SILENT AND ACTIVE LOCI FOR MATING TYPE 952 SILENT CASSETTES AT HML AND HMR ARE REPRESSED 956 UNIDIRECTIONAL TRANSPOSITION IS INITIATED BY THE RECIPIENT MAT LOCUS 958 REGULATION OF HO EXPRESSION 960 TRYPANOSOMES REARRANGE DNA TO EXPRESS NEW SURFACE ANTIGENS 962 INTERACTION OF TI PLASMID DNA WITH THE PLANT GENOME 967 SELECTION OF AMPLIFIED GENOMIC SEQUENCES 975 EXOGENOUS SEQUENCES CAN BE INTRODUCED INTO CELLS AND ANIMALS BY TRANSFECTION 979 33: IMMUNE DIVERSITY 989 CLONAL SELECTION AMPLIFIES LYMPHOCYTES THAT RESPOND TO INDIVIDUAL ANTIGENS 992 IMMUNOGLOBULIN GENES ARE ASSEMBLED FROM THEIR PARTS IN LYMPHOCYTES 994 THE DIVERSITY OF GERMLINE INFORMATION 1000 RECOMBINATION BETWEEN V AND C GENES GENERATES DELETIONS AND REARRANGEMENTS 1002 ALLELIC EXCLUSION IS TRIGGERED BY PRODUCTIVE, REARRANGEMENT 1007 DNA RECOMBINATION CAUSES CLASS SWITCHING 1009 EARLY HEAVY CHAIN EXPRESSION CAN BE CHANGED BY RNA PROCESSING 1011 CONTENTS I XVII SOMATIC MUTATION GENERATES ADDITIONAL DIVERSITY T-CELL RECEPTORS ARE RELATED TO IMMUNOGLOBULINS THE MAJOR HISTOCOMPATIBILITY LOCUS CODES FOR MANY GENES OF THE IMMUNE SYSTEM 1012 1015 1019 PART 7: CELL GROWTH, CANCER, AND DEVELOPMENT 102B 34: PROTEIN TRAFFICKING OLIGOSACCHARIDES ARE ADDED TO PROTEINS IN THE ER AND GOLGI COATED VESICLES TRANSPORT BOTH EXPORTED AND IMPORTED PROTEINS PROTEIN LOCALIZATION DEPENDS ON FURTHER SIGNALS RECEPTORS RECYCLE VIA ENDOCYTOSIS 35: SIGNAL TRANSDUCTION CARRIERS AND CHANNELS FORM WATER-SOLUBLE PATHS THROUGH THE MEMBRANE G PROTEINS MAY ACTIVATE OR INHIBIT TARGET PROTEINS PROTEIN TYROSINE KINASES INDUCE PHOSPHORYLATION CASCADES THE RAS PATHWAY ACTIVATING MAP KINASE PATHWAYS CYCLIC AMP AND ACTIVATION OF CREB THE JAR-STAT PATHWAY 36: CELL CYCLE AND GROWTH REGULATION CYCLE PROGRESSION DEPENDS ON DISCRETE CONTROL POINTS M PHASE KINASE IS A DIMER THAT REGULATES ENTRY INTO MITOSIS PROTEIN PHOSPHORYLATION AND DEPHOSPHORYLATION CONTROL THE CELL CYCLE P34 (CDC2 OR CDC28) IS THE KEY REGULATOR IN YEASTS CDC28 ACTS AT BOTH START AND MITOSIS IN 5. CEREVISIAE MANY CDK-CYCLIN COMPLEXES ARE FOUND IN ANIMAL CELLS FUNCTIONS OF CDC2-CYCLIN AND CDK-CYCLIN DIMERS G0/G1 AND GL/S TRANSITIONS INVOLVE CDK INHIBITORS REORGANIZATION OF THE CELL AT MITOSIS APOPTOSIS 37: ONCOGENES AND CANCER TRANSFORMING VIRUSES CARRY ONCOGENES RETROVIRAL ONCOGENES HAVE CELLULAR COUNTERPARTS RAS PROTO-ONCOGENES CAN BE ACTIVATED BY MUTATION INSERTION, TRANSLOCATION, OR AMPLIFICATION MAY ACTIVATE PROTO-ONCOGENES ONCOGENES CODE FOR COMPONENTS OF SIGNAL TRANSDUCTION CASCADES GROWTH FACTOR RECEPTOR KINASES AND CYTOPLASMIC TYROSINE KINASES ONCOPROTEINS MAY REGULATE GENE EXPRESSION RB IS A TUMOR SUPPRESSOR THAT CONTROLS THE CELL CYCLE THE TUMOR SUPPRESSOR P53 SUPPRESSES GROWTH OR TRIGGERS APOPTOSIS IMMORTALIZATION AND TRANSFORMATION 1027 1030 1033 1042 1044 1053 1056 1061 1064 1070 1076 1081 1082 1089 1090 1095 1098 1100 1108 1111 1113 1116 1119 1122 1131 1135 1139 1141 1144 1149 1151 1156 1160 1162 1167 XVIII I CONTENTS 38: GRADIENTS AND CASCADES 1173 A GRADIENT MUST BE CONVERTED INTO DISCRETE COMPARTMENTS 1175 MATERNAL GENE PRODUCTS ESTABLISH GRADIENTS IN EARLY EMBRYOGENESIS 1177 ANTERIOR-POSTERIOR DEVELOPMENT USES LOCALIZED GENE REGULATORS 1180 DORSAL-VENTRAL DEVELOPMENT USES LOCALIZED RECEPTOR-IIGAND INTERACTIONS 1184 CELL FATE IS DETERMINED BY COMPARTMENTS THAT FORM BY THE BLASTODERM STAGE 1191 COMPLEX LOCI ARE EXTREMELY LARGE AND INVOLVED IN REGULATION 1198 THE HOMEOBOX IS A COMMON CODING MOTIF IN HOMEOTIC GENES 1205 EPILOGUE: LANDMARK SHIFTS IN PERSPECTIVES 1213 GLOSSARY 1217 INDEX 1241
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spelling	Lewin, Benjamin Verfasser aut Genes Benjamin Lewin Genes VI 6. ed. Oxford [u.a.] Oxford Univ. Press 1997 XVIII, 1260 S. zahlr. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Gen (DE-588)4128987-0 gnd rswk-swf Genetik (DE-588)4071711-2 gnd rswk-swf Molekulargenetik (DE-588)4039987-4 gnd rswk-swf 1\p (DE-588)4123623-3 Lehrbuch gnd-content Genetik (DE-588)4071711-2 s DE-604 Molekulargenetik (DE-588)4039987-4 s 2\p DE-604 Gen (DE-588)4128987-0 s 3\p DE-604 HEBIS Datenaustausch Darmstadt application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=007559360&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk 2\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk 3\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk
spellingShingle	Lewin, Benjamin Genes Gen (DE-588)4128987-0 gnd Genetik (DE-588)4071711-2 gnd Molekulargenetik (DE-588)4039987-4 gnd
subject_GND	(DE-588)4128987-0 (DE-588)4071711-2 (DE-588)4039987-4 (DE-588)4123623-3
title	Genes
title_alt	Genes VI
title_auth	Genes
title_exact_search	Genes
title_full	Genes Benjamin Lewin
title_fullStr	Genes Benjamin Lewin
title_full_unstemmed	Genes Benjamin Lewin
title_short	Genes
title_sort	genes
topic	Gen (DE-588)4128987-0 gnd Genetik (DE-588)4071711-2 gnd Molekulargenetik (DE-588)4039987-4 gnd
topic_facet	Gen Genetik Molekulargenetik Lehrbuch
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=007559360&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT lewinbenjamin genes AT lewinbenjamin genesvi

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