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Hartl D.L., Jones E.W. — Genetics: Principles and Analysis
Hartl D.L., Jones E.W. — Genetics: Principles and Analysis



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Íàçâàíèå: Genetics: Principles and Analysis

Àâòîðû: Hartl D.L., Jones E.W.

Àííîòàöèÿ:

In recent decades, few disciplines have experienced the explosion of knowledge and research that genetics has. Inspired in part by controversies and the publicity that this new information generates, many of today's students come to a course in genetics with great enthusiasm. Sustaining this enthusiasm while at the same time teaching students about the beauty, logical clarity, and unity of the subject can be a challenge for any teacher. In the fourth edition of Genetics: Principles and Analysis, Dan Hartl and Beth Jones have written a text that will provide you and your students with a clear, comprehensive, rigorous, and balanced introduction to genetics at the college level. It is a guide to learning a critically important and sometimes difficult subject. But the tools for learning extend beyond the confines of the textbook. Your students will have the opportunity to become active participants in the learning process by making full use of today's teaching and learning technology. Developed as an integrated and unified program, no other textbook will engage your students and connect them to the subject of genetics like Hartl/Jones!


ßçûê: en

Ðóáðèêà: Áèîëîãèÿ/

Ñòàòóñ ïðåäìåòíîãî óêàçàòåëÿ: Ãîòîâ óêàçàòåëü ñ íîìåðàìè ñòðàíèö

ed2k: ed2k stats

Èçäàíèå: 4-th

Ãîä èçäàíèÿ: 1998

Êîëè÷åñòâî ñòðàíèö: 840

Äîáàâëåíà â êàòàëîã: 14.06.2007

Îïåðàöèè: Ïîëîæèòü íà ïîëêó | Ñêîïèðîâàòü ññûëêó äëÿ ôîðóìà | Ñêîïèðîâàòü ID
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Ïðåäìåòíûé óêàçàòåëü
Philadelphia polytene      234—235 281 283 296
Philadelphia prokaryotic      222
Philadelphia reciprocal recombinant      160
Philadelphia recombination in      124—127
Philadelphia ring      260
Philadelphia sex      96—97 274—277
Philadelphia stability of      82—83
Philadelphia submetacentric      260 261
Philadelphia transposable elements      242—246 346—350
Philadelphia viral      222
Philadelphia X      96—97 103—104 275
Philadelphia Y      97 103—105 274
Phlox cuspidata      636 646
Phosphodiester bonds      175
Phosphorylation      712
Photo synthetic plastids      619
Photoreactivation      580—581
Photosynthesis      606
Phylogenetic tree      619—621
Physical distance, genetic distance and      145—146
Physical mapping      392—393
Physical mapping with sequence-tagged sites      395—397
Pin flowers      633
Plants development in higher      543—548
Plants genetic engineering in      380—382 386
Plants leaf variegation in four-o’clock      606—609
Plants male sterility in      612—613
Plants random mating in      636—637
Plaque      330—331
Plasmid vectors      364 365
Plasmids      222 314—317
Plasmids F (fertility) factor      314—317
Plasmids F’ (F prime)      322—323
Plasmids R      348
Plasmids Ti      381 382
Plasmodium falciparum      17—18 388
Plastids, photosynthetic      619
Pleiotropic effects      17
Pleiotropy      17—18 695
Pneumococcus      see “Streptococcus pneumoniae”
Pneumonia      3
Polarity      10
Pole cells      529
Pollen      545
Poly-A tail      425
Polycistronic mRNA      436
Polylinker      372
Polymerase      1 192
Polymerase a      192
Polymerase chain reaction (PCR)      207—210 369
Polymorphic      630
Polymorphisms      148—150 630—632
Polymorphisms enzyme      629—630
Polymorphisms restriction fragment length (RFLPs)      147—150 631
Polymorphisms serotonin transporter      733—734
Polymorphisms simple tandem repeat (STRP)      150 372—373 388 558—559 565 576—577 631 692—695
Polymorphisms typing and      639—645
Polymorphisms variable number of tandem repeats (VNTR)      140—144 148—149 640—644
Polynucleotide chain      175
Polypeptide chain      413—415 483 484—485
Polypeptides      15 412—415
Polypeptides genes and      415—418
Polypeptides leader      473
Polyploidy      261—266
Polysaccharides      68—69
Polysome      450
Polysomy      267
Polytene chromosomes      234—235 281 283 296
Polytene P1 bacteriophage      390
Population      628
Population fixed      629
Population genetics      627—667 671
Population genetics allele frequencies and genotype frequencies      628—632 635—637 660
Population genetics defined      628
Population genetics DNA typing and population substructure      639—645
Population genetics evolution and      649—650
Population genetics inbreeding      54 634 645—649
Population genetics mating systems      632—639
Population genetics migration      650—652
Population genetics mutation      see “Mutations”
Population genetics natural selection      24 650 652—658
Population genetics random genetic drift      650 658—661
Population local      628
Population substructure      642—645
Position effects on gene expression      296—297
Position-effect variegation (PEV)      296—297
Positional cloning      372—374 401
Positional information      515 516
Positive assortative mating      633
Positive chromatid interference      141
Positive regulation      461 468—471
Positive regulator      490
Posterior genes      536
Postreplication repair      582 583
Posttranslocation state      434
Precursor fragments      194
Precursor fragments joining of      196 198
Prenatal diagnosis, restriction mapping and      388
Pretranslocation state      434
Primary transcript      424
Primase      196
Primer      191—192
Primer oligonucleotide      207 208 209 370
Primer oligonucleotides      207 208 209 370
Primosome      196
Primula      633
Prion      723
Prion protein      723
Prion repressor      344 461—462 464 489
Prion single-strand binding      198 199
Prion synthesis of      14—15
Prion TATA-box-binding (TBP)      495
Prion transcriptional activator      462 491—493
probability      48—51
Probability genetic prediction and      106—114
Probe      372
Probe DNA      206 372 630—631
Processing      412
Proflavin      440
Progeny phage      8
Programmed cell death      524—525
Prokaryotes      23
Prokaryotes chromosomes of      222
Prokaryotes DNA replication in      189
Prokaryotes gene regulation in      480
Prokaryotes genetic organization of      480
Prokaryotes mRNA of      424 449
Prokaryotes RNA processing in      424
Prokaryotes transcriptional regulation in      460—462
Prokaryotes translation units in      450—451
Prolactin      503
Proline, chemical structure of      413
Prolla, Tomas A.      579
Promoter mutations      422—423
Promoter recognition      418—421
Promoter region      465
Promoters      419
Promoters alternative      500—501
Promoters enhancers and      497—499
Proofreading function      192—193 194
Properties of      412 414
Prophage      341
Prophage induction      345
Prophase      85 86
Prophase I      89 92—93
Prophase II      94
Protanomaly      284
Protanopia      284 285—286
Protease enzyme      4
Protein electrophoresis      629—630 631
Protein infectious agent      723
Protein subunits      414—415
Proteins      412—415
Proteins amino acids and      412—415
Proteins genes and      12—15
Proteins genetic engineering and      386—387
Proteins helicase      198 199
Proto-oncogene      298
Prototrophs      312
Prozac      733
Pseudoalleles      161
Pseudoautosomal region      274—275
Pseudomonas fluorescens      386
PTC (phenylthiocarbamide) tasting      713 729
Pulsed-field gel electrophoresis (PFGE)      228 390
Punnett square      43 638
Purines      174 180
Pyloric stenosis      691
Pyrimidine dimers      571—572
Pyrimidines      174 180
Quantitative inheritance      670—675
Quantitative traits      68 669—701
Quantitative traits analysis of      680—683
Quantitative traits artificial selection and      683—687
Quantitative traits causes of variation      675—680
Quantitative traits correlation between relatives      687—690
Quantitative traits heritability of threshold traits      690—692
Quantitative traits linkage analysis of quantitative-trait loci      692—695
Quantitative traits number of genes affecting      681—682
Quantitative-trait locus (QTL)      692—695
Quetelet, Adolphe      674
R group of amino acids      412
R plasmids      348
Racial designations, in DNA typing      642
Ramanis, Zenta      608
Random genetic drift      650 658—661
Random mating      632—633
Random mating Hardy-Weinberg principle and      634—639
Random mating X-linked alleles and      639
Random-spore analysis      154
Reading frame      440
Recessive      35 36
Reciprocal crosses      35 97—100
Reciprocal recombinant chromosomes      160
Reciprocal translocation      288—293
Recombinant DNA technology      360 (see also “Genetic engineering”)
Recombinant molecules      588
Recombinant molecules detection of      370—372
Recombinant molecules DNA      362—365
Recombinant molecules screening for      372
Recombinants      124
Recombination      124 586—592
Recombination frequency      144
Recombination frequency of      125 128 129 130 140 144 145
Recombination Hfr cells      317—319
Recombination Holliday model of      138 139 587—590
Recombination in temperate bacteriophages      340—346
Recombination in virulent bacteriophages      331—336 (see “Genetic recombination”)
Recombination linkage and      124—127
Recombination lytic cycle and      330
Recombination mitotic      158—160
Recombination site-specific      330
Recombination within genes      160
Recruitment      495
Red-green color blindness      283—286
Reductional division (first meiotic division)      89—94
Redundancy      445—447
Regulation      see “Gene regulation”
Relative fitness      653
Relatives, correlation between      687—690
Relaxed DNA      224
Renaturation      200 201 202 208 236—239
Renaturation analysis of genome size and repetitive sequences by      238—239
Renaturation kinetics of      236—238
Repair mechanisms of DNA      577—583
Repair process      565—566
Repellents      704—705
Repetitive sequences      235—239
Replica plating      561—563
Replication      10—11 182—191
Replication discontinuous      194—199
Replication fork      187
Replication fork fragments in      194—195
Replication geometry of      183—191 194
Replication in eukaryotes      189
Replication in nucleic acids, basic rule      182—183
Replication multiple origins of      189
Replication origin      187
Replication other proteins needed for DNA      196—199
Replication plasmids and      315
Replication rolling-circle      189—191 316
Replication semiconservative      183—186
Replication slippage      559 579
Replication theta (q)      187
Reporter gene      500
Repressible      461
Repressor protein      344 461—462 464 489
Repulsion configuration      126 127
Research, recombinant DNA technology and      386
Respiration-defective mitochondrial mutants      610—612
Restriction endonuclease      147 148 202—205
Restriction enzymes      147 148 202—205 360—362
Restriction fragment      205
Restriction fragment length polymorphisms (RFLPs)      147—150 631
Restriction map      205 393
Restriction site      204 360
Restrictive conditions      556
Retinoblastoma      298—299
Retroviruses, genetic engineering and      378 387
Reverse genetics      377—382 386
Reverse mutations      583—586 652
Reverse transcriptase      369—370
Reverse transcriptase PCR (RT-PCR)      370
reversion      583
Reversion for detecting mutagens and carcinogens      585—586
RFLPs (restriction fragment length polymorphisms)      147—150 631
Rhodopsin      283—284
Ribonucleic acid      see “RNA (ribonucleic acid)”
Ribose      195
Ribosomal RNA (rRNA)      12—13
Ribosome binding site      432
Ribosomes      13 430—431 439
Ribozymes      427
Ring chromosomes      260
Rll gene in bacteriophage T4      334 336—340
RNA (ribonucleic acid)      4 12
RNA (ribonucleic acid) DNA compared      195—196
RNA (ribonucleic acid) guide      248
RNA (ribonucleic acid) messenger      see “Messenger RNA (mRNA)”
RNA (ribonucleic acid) ribosomal      12—13
RNA (ribonucleic acid) transcription of DNA and      12—14 412 418—424
RNA (ribonucleic acid) transfer      see “Transfer RNA (tRNA)”
RNA (ribonucleic acid) translation of      14—15
RNA editing      605
RNA polymerase      195 196 412 418—419 421 422 423
RNA polymerase holoenzyme      495
RNA polymerase subunits of      414—415
RNA primer      195—196
RNA processing      412 424—430 460
RNA splicing      425—426 427
RNA synthesis      418—423
RNase enzyme      4 5
Robertsonian translocation      293—296
Rolling-circle replication      189—191 316
Romanov, Georgij      603
Rotman, Raquel      329
Rradiation, units of      573
rRNA (ribosomal RNA)      12—13
RT-PCR (reverse transcriptase PCR)      370
Rubella virus      730
1 2 3 4 5 6 7 8
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