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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
McWhir, Jim      380
Mean      672 674—675
Media minimal      312
Media nonselective and selective      312
Megabase pairs (Mb)      222
Megaspore      89
Meiocytes      88
Meiosis      83 87—95
Melting curve      199 200
Melting temperature      199—200
Mendel, Gregor      2 30 32 96 246
Mendel, Gregor experiments of      2 32—48 82 112 114—115
Mendel, Gregor genetic hypothesis of      36—39
Mendelian genetics      32
Mendelian inheritance      48—51 600 628
Mendelian inheritance Down syndrome and      271 274 275 281 294 730
Mendelian inheritance fragile-X syndrome and      279—280 518 730
Mendelian inheritance genetic and environmental effects on      730
Mendelian inheritance Klinefelter syndrome and      279
Mendelian inheritance phenylketonuria and      730
Mendelian inheritance trisomy-X syndrome and      278
Meristematic tissue      267
Meristems      543—544
Meristic traits      671 677
Merodiploids      see “Partial diploids”
MERRF (myoclonic epilepsy associated with ragged-red muscle fibers)      601—602
Meselson, Matthew      183 184 439
Meselson-Stahl experiment      183—185
Messenger RNA (mRNA)      12 369 423—424 430 439
Messenger RNA (mRNA) masked      503
Messenger RNA (mRNA) polycistronic      436
Messenger RNA (mRNA) prokaryotic      424 449
Messenger RNA (mRNA) translation and      14
Metabolism, inborn error of      12 729 730
Metacentric      260
Metallothionein      382—383
Metaphase      85 86 88
Metaphase I      89 93—94
Metaphase II      95
Metaphase plate      86
Methanethiol      729—730
Methionine      312 413
Methyl-accepting chemotaxis proteins (MCP)      712
Methylation      487—488 712 214
Methylation cytosine      565
Micrococcal nuclease      230
Micromeres      517
Middle-repetitive sequences      239 241—242
Miescher, Johann Friedrich      2
Migration      650—652
Minimal medium      312
Minisatellites      641
Minor groove      179
Mirabilis jalapa      606
Misalignment mutagenesis      571
Mismatch repair      578—580
Mismatch repair enzymes      375—376
Mismatch repair resulting in gene conversion      587
Missense mutations      444 558
Mitochondria      601 605 613
Mitochondria heteroplasmy of      602—603
Mitochondrial genetic diseases      601—602
Mitochondrial mutants, respiration defective      610—612
Mitochondrial “Eve”      618—621
Mitosis      83—87
Mitotic recombination      158—160
Mitotic spindle      85 86
MN blood group      628 635—636
Modified $F_2$ dihybrid ratios      61—64
Molecular continuity of life      22—23
Monod, Jacques      465 467 476
Monohybrid crosses      32—41
Monohybrids      33
Monoploidy      261 262 266—267
Monosomic      269
Morgan, Lilian V.      137
Morgan, Thomas Hunt      97—99 101 128
Morphogens      515
Mosaicism      276
Motor components      707
mRNA      see “Messenger RNA (mRNA)”
Muller, Hermann J.      67 248 566—567 574
Multifactorial traits      670 (see also “Quantitative traits”)
Multiple alleles      60—61
Multiple alleles Hardy-Weinberg principle and      638—639
Multiple cloning site (MCS)      372
Multiple nonchemotaxis      706 707 709
Multiplication rule, probability and      50—51
Murry, Jeffrey C      693
Mus      517
Mutagenesis      574
Mutagenesis enhancer-trap      499—500
Mutagenesis misalignment      571
Mutagenesis oligonucleotide site-directed      374—376
Mutagenesis transposable-element      559—561
Mutagens      556
Mutagens base-analog      567—569
Mutagens detection of      585—586
Mutant screen      55
Mutants antibiotic-resistant      311 348—349 608 609—610
Mutants bacterial      311—312 348—349
Mutants bacteriophage      330—331
Mutants carbon-source      312
Mutants constitutive      464 489
Mutants lac      462—463
Mutants nutritional      311—312 322
Mutants petite      610—612
Mutants respiration-defective mitochondrial      610—612
Mutants uninducible      489
Mutation rates      563—565
Mutations      15—16 23—24 182 512 556—577 650—652
Mutations affecting cell lineages      522
Mutations affecting chemotaxis      706—709
Mutations affecting floral development in Arabidopsis      545 546
Mutations allelism of      55—56
Mutations base-substitution      557—558
Mutations complementation and      160—161
Mutations conditional      333 556
Mutations execution      524
Mutations forward      583 652
Mutations frameshift      440 559
Mutations gain-of-function      526 527
Mutations germ-line      556
Mutations heterochronic      525—526
Mutations homeotic      523
Mutations hot spots of      339 565—566
Mutations induced      557 566—577
Mutations insertions and deletions      558—559
Mutations irreversible      650—651
Mutations lineage, types of      522—526
Mutations loss-of-function      526 527
Mutations missense      444 558
Mutations molecular basis of      557—561
Mutations nonadaptive nature of      561—563
Mutations nonmotile      707
Mutations nonsense      444 558
Mutations promoter      422—423
Mutations properties of      556—557
Mutations reverse      583—586 652
Mutations segregation      523—524
Mutations selectively neutral      650
Mutations sickle-cell hemoglobin and      657
Mutations silent      444 557
Mutations somatic      556
Mutations spontaneous      557 561—566
Mutations suppressor      583—586
Mutations temperature-sensitive      556
Mutations transformation      522—523
Mutations transition      557
Mutations transversion      557
Mutually exclusive events      48—49
Mycoplasma genitalium      416—418
Myoclonic epilepsy associated with ragged-red muscle fibers (MERRF)      601—602
N-wyc      481
Nanos      536 538
Narrow-sense heritability      684—686 726
Narrow-sense heritability estimation of      689—690
Narrow-sense heritability of liability      691 692
Natural selection      24 650 652—658
Natural selection in diploids      654
Natural selection in Escherichia coli      653
Natural selection selection-mutation balance and      655—656
Nature versus nurture      730—731
Negative assortative mating      633
Negative chromatid interference      141
Negative regulation      461
Negative regulator      490
Negatively supercoiled      225
Nematodes      246 515—516
Nematodes development in      520—522
Nematodes genome of      222
Neuroblastoma      481
Neurospora      150 157 420 586 614 223
Neurospora crassa      154—155 156 415
Neuroticism      731 733—734
Neutral petites      612
Ngeli, Carl      32 82
Nicholas II, Tsar      602—603
Nick      225
Nicotiana longiflora      684
Nitrogen mustard, mutagenicity of      570
Nitrous acid, mutagenicity of      569
Nomarski microscopy      521
Nonchemotaxis      706—707
Nonchemotaxis general      706—707 710
Nonchemotaxis multiple      706 707 709
Nonchemotaxis specific      706 707
Noncomplementation      55
Nondisjunction      103—104 274
Nonmotile mutations      707
Nonparental ditype      150 151
Nonrecombinant      588
Nonselective medium      312
Nonsense mutations      444 558
Nonsense suppression      447—449 585
Nontaster      713 729
Nopaline      381
Normal distribution      673—675
Notch deletions      281—282
Notch gene      527
Nuclease      192
Nucleic acid hybridization      200—202
Nucleic acids      4
Nucleic acids polynucleotide chains in      175
Nucleic acids replication of      182—183
Nucleoid      225—227 308
Nucleoli      85 86
Nucleoside      174—175 213
Nucleosomes      228—230 231
Nucleotide      9 174—175
Nucleotide analog      568—569
Nucleotide components of      174 175
Nucleotide repetitive sequences      235—239
Nucleotide sequence composition      239—242
Numerator genes      105
Nurture, nature versus      730—731
Nutritional mutants      311—312 322
Nysslein-Volhard, Christiane      61 529 535
Octopine      381
Octoploidy      261 262
Odd-skipped gene      538
Oenothera      292
Oil spills, genetic engineering and      385
Okazaki fragments      see “Precursor fragments”
Oligonucleotide primer      207 208 209 370
Oligonucleotide site-directed mutagenesis      374—376
Oliver, C.P.      160
Olson, Maynard V.      393
Oncogene      298 481
Oocytes      88 518—519
Open reading frame (ORF)      400 424
Openness      731
Operator      465 467
Operator region      464—465
Operon model      465—467
Operons lac      462—463 466—471
Operons trp      471—476
Organelle heredity      604—613
Organelle heredity brganelles      600
Organelle heredity evolutionary origin of      613—614
Organelle heredity genetic codes of      605—606
Ovalbumin      369
Overdominance      see “Heterozygote superiority”
Overlapping genes      449—450
Oxytricha, telomeric DNA of      251 252
Ozone      572
P (peptidyl) site      431
P element      377
P1 bacteriophage      390
P1 bacteriophage vector      364 365
Pachytene      92—93
Pair-rule genes      533 538
Palindrome      204 631
Paracentric inversion      287 288
Paramecium aurelia autogamy in      614—615 616
Paramecium aurelia killer phenomenon in      614 616
Parasegment genes      532
Parental combinations      124
Parental ditype      150 151
Parental strand      10—11 182—183
Partial digestion      392
Partial diploids      322
Pascal’s triangle      107
Patent ductus arteriosus      691
Paternal inheritance      601
Paternity testing      641 644—645
Path      646
Pathogens      348
Pattern formation      513 532—534
Pea plant flower of      32 33
Pea plant seeds of      33—35
Pearson, K.      727
Pedigree      51
Pedigree calculation of inbreeding coefficient from      647—649
Pedigree genetic mapping in human      146—150
Pedigree segregation in human      51—54
Penetrance      71—72
Peptide bond      412
Peptidyl transferase      433—434
Percent G + C      175
Pericentric inversion      287—288 289
Period (per) gene      716 717
Period (per) gene molecular genetics of      720—723
Permissive conditions      556
Perrin, David      467
Personality, genetic factors in      730 731—734
Petals      545
Petes, Thomas D.      579
Petite mutants      610—612
PFGE (pulsed-field gel electrophoresis)      228 390
Phage      see “Bacteriophage(s)”
Phenotype      41 628
Phenotype blood-group      639
Phenotype phenotypic change with selection      684—686
Phenotype phenylalanine, chemical structure of      413
Phenotype total variance in      678
Phenylketonuria      61 730
Phenylthiocarbamide (PTC)      713 729
Philadelphia      298
Philadelphia chromosome      298
1 2 3 4 5 6 7 8
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