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ویرایش: [5 ed.] نویسندگان: Strachan. Tom &, Read. Andrew سری: ISBN (شابک) : 9780815345893 ناشر: Garland Science سال نشر: 2019 تعداد صفحات: 0 زبان: English فرمت فایل : EPUB (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود) حجم فایل: 43 Mb
در صورت تبدیل فایل کتاب Human Molecular Genetics به فرمت های PDF، EPUB، AZW3، MOBI و یا DJVU می توانید به پشتیبان اطلاع دهید تا فایل مورد نظر را تبدیل نمایند.
توجه داشته باشید کتاب ژنتیک مولکولی انسان نسخه زبان اصلی می باشد و کتاب ترجمه شده به فارسی نمی باشد. وبسایت اینترنشنال لایبرری ارائه دهنده کتاب های زبان اصلی می باشد و هیچ گونه کتاب ترجمه شده یا نوشته شده به فارسی را ارائه نمی دهد.
ژنتیک مولکولی انسان به دقت در نسخه های متوالی ساخته شده است تا مقدمه ای معتبر از جنبه های مولکولی ژنتیک انسانی، ژنومیک و زیست شناسی سلولی ارائه کند. با حفظ ویژگی هایی که نسخه های قبلی را بسیار محبوب کرده است، این نسخه پنجم کاملاً مطابق با آخرین پیشرفت های این حوزه به روز شده است. فنآوریهای قدیمیتر مانند شبیهسازی و هیبریداسیون با هم ادغام و خلاصه شدهاند، پوشش فناوریهای جدیدتر توالییابی DNA گسترش یافته است، و ویرایش ژنهای جدید قدرتمند و فناوریهای ژنومیک تک سلولی اضافه شدهاند. پوشش GWAS، ژنومیکس عملکردی، سلول های بنیادی و مدل سازی بیماری گسترش یافته است. تمرکز بیشتر بر وراثت و تنوع در بافت جمعیت و نقش اپی ژنتیک در تنظیم ژن است.
Human Molecular Genetics has been carefully crafted over successive editions to provide an authoritative introduction to the molecular aspects of human genetics, genomics and cell biology. Maintaining the features that have made previous editions so popular, this fifth edition has been completely updated in line with the latest developments in the field. Older technologies such as cloning and hybridization have been merged and summarized, coverage of newer DNA sequencing technologies has been expanded, and powerful new gene editing and single-cell genomics technologies have been added. The coverage of GWAS, functional genomics, stem cells, and disease modeling has been expanded. Greater focus is given to inheritance and variation in the context of populations and on the role of epigenetics in gene regulation.
reface About the authors Contributors PART 1 BASICS OF DNA, CHROMOSOMES, CELLS, DEVELOPMENT AND INHERITANCE 1 Basic principles of nucleic acid structure and gene expression 1.1 Composition of nucleic acids and polypeptides 1.2 Base pairing in DNA and RNA, the double helix, and DNA replication 1.3 RNA transcription and gene expression 1.4 RNA processing 1.5 Translation, post-translational processing, and protein structure Summary Further reading 2 Fundamentals of cells and chromosomes 2.1 Cell structure and diversity, and cell evolution 2.2 DNA and chromosome copy number during the cell cycle 2.3 Cell division and transmission of DNA to daughter cells 2.4 Structure and function of chromosomes Summary Further reading 3 Fundamentals of cell–cell interactions and immune system biology 3.1 Principles of cell signaling 3.2 Cell proliferation and programmed cell death 3.3 Cell adhesion and tissue formation 3.4 Immune system biology Summary Further reading 4 Aspects of early mammalian development, cell differentiation, and stem cells 4.1 Cell lineages and tissue differentiation in early mammalian development 4.2 Stem cells and cell differentiation Summary Further reading 5 Patterns of inheritance 5.1 Monogenic versus multifactorial inheritance 5.2 Mendelian pedigree patterns 5.3 Mosaicism and new mutations 5.4 Non-Mendelian characters Summary Further reading PART 2 UNDERSTANDING GENOMES 6 Core DNA technologies: amplifying DNA, nucleic acid hybridization, and DNA sequencing 6.1 Cloning DNA in bacterial cells 6.2 Amplifying DNA by in vitro DNA replication 6.3 Nucleic acid hybridization: principles and uses 6.4 DNA sequencing principles and Sanger dideoxy sequencing 6.5 Massively-parallel DNA sequencing (next-generation sequencing) Summary Further reading 7 Analyzing the structure and expression of genes and genomes 7.1 Genome structure analysis and genome projects 7.2 Basic gene expression analyses 7.3 High-throughput gene expression analyses 7.4 Single-cell genomics Summary Further reading 8 Principles of genetic manipulation of mammalian cells An overview of genome editing, gene silencing, and germ-line transgenesis 8.1 Artificial transfer of genetic material into mammalian cells 8.2 Principles of transgene expression in mammalian cells 8.3 Genome editing using homologous recombination 8.4 Genome editing using programmable site-specific endonucleases 8.5 Gene silencing 8.6 Germ-line transgenesis and transgenic animals Summary Further reading 9 Uncovering the architecture and workings of the human genome 9.1 An overview of the human genome 9.2 Gene organization and distribution in the human genome 9.3 Heterochromatin DNA and transposon repeats 9.4 A start on working out how our genome functions Summary Further reading 10 Gene regulation and the epigenome 10.1 Chromatin accessibility and conformation 10.2 Histones and other DNA-binding proteins 10.3 Regulation by DNA methylation and noncoding RNAs 10.4 X-inactivation, imprinting, and epigenetic memory 10.5 Making the transcript: promoters and enhancers 10.6 Post-transcriptional regulation Summary Further reading PART 3 GENETIC VARIATION BETWEEN INDIVIDUALS AND SPECIES 11 An overview of human genetic variation 11.1 Origins of DNA sequence variation 11.2 DNA repair 11.3 Population genomics and the scale of human genetic variation 11.4 Functional genetic variation and protein variation 11.5 Extraordinary genetic variation in the adaptive immune system Summary Further reading 12 Human population genetics 12.1 Allele frequencies and genotype frequencies: the Hardy–Weinberg relationship 12.2 Haplotype frequencies and linkage disequilibrium 12.3 Changing allele frequencies 12.4 Population structure and inbreeding Summary Further reading 13 Comparative genomics and genome evolution 13.1 Comparative genomics 13.2 Gene duplication, species differences in gene number, and evolutionary advantages of exons 13.3 Evolution of mammalian chromosomes 13.4 Regulatory sequence evolution and transposon origins of functional sequences 13.5 Phylogenetics and our place in the tree of life Summary Further reading 14 Human evolution 14.1 Human origins 14.2 Human evolutionary history from genome sequences 14.3 Inferring female and male histories using mitochondrial DNA and the Y chromosome 14.4 Health consequences of our evolutionary history Summary Further reading PART 4 HUMAN GENETIC DISEASE 15 Chromosomal abnormalities and structural variants 15.1 Studying human chromosomes 15.2 Gross chromosome abnormalities 15.3 Structural variants, microdeletions, and microduplications Summary Further reading 16 Molecular pathology: connecting phenotypes to genotypes 16.1 Loss of function 16.2 Gain of function 16.3 Dynamic mutations: unstable repeat expansions 16.4 Molecular pathology of mitochondrial disorders 16.5 Genotype–phenotype correlations Summary Further reading 17 Mapping and identifying genes for monogenic disorders 17.1 Positional cloning seeks to identify disease genes by first mapping them to a precise chromosomal location 17.2 Haplotype sharing and autozygosity 17.3 Whole-exome and whole-genome sequencing allow an unbiased and hypothesis-free approach to identifying the cause of a monogenic condition 17.4 Strategies for exome-based disease-gene identification 17.5 Confirming that the candidate gene is the correct one Summary Further reading 18 Complex disease: identifying susceptibility factors and understanding pathogenesis Introduction 18.1 Investigation of complex disease: epidemiological approaches 18.2 Investigation of complex disease using linkage 18.3 Investigation of complex disease using association 18.4 The limitations of genome-wide association studies 18.5 What have we learned about the genetics of complex characters? Summary Further reading 19 Cancer genetics and genomics Introduction 19.1 Oncogenes 19.2 Tumor suppressor genes 19.3 Key oncogenes and tumor suppressor genes work mainly to regulate cell cycle checkpoints and genome maintenance 19.4 A genome-wide view of cancer 19.5 Using our new understanding of cancer Summary Further reading PART 5 APPLIED HUMAN MOLECULAR GENETICS 20 Genetic testing in healthcare and the law 20.1 What to test and why 20.2 Testing for a specific genetic variant 20.3 Clinical diagnostic testing 20.4 Population screening 20.5 Pharmacogenetics and personalized medicine 20.6 DNA forensics: identifying individuals and relationships Summary Further reading 21 Model organisms and modeling disease 21.1 An overview of model organisms 21.2 Cellular disease models 21.3 Origins of animal models of genetic disorders 21.4 How useful are animal models of genetic disorders? Summary Further reading 22 Genetic approaches to treating disease 22.1 An overview of treating genetic disease and of genetic treatment of disease 22.2 Treating disease with genetically-engineered therapeutic proteins 22.3 Basic principles of gene therapy and RNA therapeutics 22.4 The practice of gene augmentation therapy for treating recessively inherited disorders 22.5 RNA therapeutics, therapeutic genome editing prospects, and genetic approaches to preventing disease Summary Further reading Glossary Index