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Agricultural Molecular Biology 555522

Agricultural Molecular Biology 555522. Agricultural Molecular Biology Teaching Team. ดร. อรรัตน์ มงคลพร เกษตร ดร. คนึงนิตย์ เหรียญวรากร เกษตร ดร. เสริมศิริ จันทร์เปรม เกษตร ผศ. ดร. สนธิชัย จันทร์เปรม เกษตร ดร. จุรีย์รัตน์ ชำนาญพันธ์ ศวท. ดร. ธีระพล ศิรินฤมิตร สัตวแพทย์.

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Agricultural Molecular Biology 555522

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  1. Agricultural Molecular Biology555522

  2. Agricultural Molecular BiologyTeaching Team • ดร. อรรัตน์ มงคลพร เกษตร • ดร. คนึงนิตย์ เหรียญวรากร เกษตร • ดร. เสริมศิริ จันทร์เปรม เกษตร • ผศ. ดร. สนธิชัย จันทร์เปรม เกษตร • ดร. จุรีย์รัตน์ ชำนาญพันธ์ ศวท. • ดร. ธีระพล ศิรินฤมิตร สัตวแพทย์

  3. Agricultural Molecular BiologyCourse Structure • Credit 3-0 : 45-hour program • Class schedules : Monday 9.00-10.30 Wednesday 9.00-10.30 CAB Lecture room 3rd floor • Evaluation : • Exam I, II, III 75%, TBA • Presentation 10% • Paper 10% • Class participation 5% • Grading system : Score-dependent

  4. Agricultural Molecular BiologyCourse Textbooks • Genes VII, 2000. By Benjamin Lewin. • 5 Reserved books, KPS library • Molecular Biology, International Edition. 1999. By Weaver RE. • Genomes, 1999. By TA Brown

  5. What is molecular biology? • A study of gene structure and function at the molecular level • Molecular biology grew out of the disciplines of genetics and biochemistry

  6. A brief history • Transmission of genetics • Mendel’s law of inheritance • Chromosome theory of inheritance • Genetic recombination and mapping • Physical evidence for recombination • Molecular genetics • Discovery of DNA • Composition of genes • Relationship between genes and proteins • Activities of genes

  7. Transmission of genetics 1856 Gregor Mendel: inheritance of 7 traits in garden pea

  8. Mendel’s laws of inheritance>> principle of segregation • Genes exist in different forms called alleles. • One allele can be dominant over the other. • Mendel’s work: yellow seed > green seed parents yellow x green F1yellow selfed F2 3 yellow : 1 green

  9. Mendel’s laws of inheritance>> principle of independent assortment • 7 genes operated independently • Combinations of 2 different genes 9:3:3:1

  10. Chromosome theory of inheritance • 1900 rediscovery Mendel’s findings • First chromosome theory: • Thomas Hunt Morgan: fruit fly (Drosophilamelanogaster) red-eyed x white-eyed most red-eyed F1

  11. red-eyed males x red-eyed females 1/4 white-eyed males + no white-eyed females • Eye color is sex-linked, X chromosome • male has 1 copy, female has 2 copies • Genes are located on chromosome : locus • Diploid organisms have 2 copies of chromosomes • homozygous and heterozygous • genotype • phenotype : wild-type vs mutant

  12. Genetic recombination and mapping • Genes on separate chromosome behave independently, same chromosome behave as if they are linked • Genes on same chromosome not perfect linked • Eye color and miniature wing on X chromosome are 65.5% linked, with new combination ‘recombinants’ • Answer is recombination process, a crossing over between homologous chromosomes during meiosis • Sturtevant: mathematical relationship between the distance of genes and the recombination frequency • Barbara McClintock : physical evidence for recombination in maize chromosomes

  13. Molecular genetics • DNA discovery : 1869 Friedrich Miescher - nuclein • deoxyribonucleic acid (DNA) • ribonucleic acid (RNA) and protein • Composition of genes • DNA or RNA or protein • Avery proved it was DNA • Bacteria transformation • virulent dead cells + avirulent living cells • Relationship : genes and protein

  14. Molecular genetics • Relationship : genes and protein • How do genes work? • Human disease alcaptonuria -- black pigment in urine • Defective enzyme • A gene responsible for enzyme (protein) production • Activities of genes • How do genes work? • Genes replicate faithfully • Genes direct production of RNAs and proteins • Genes accumulate mutations and allow evolution

  15. Replication • 1953 Watson and Crick • DNA structure is double helix • 4 bases composition : A, G, T and C • A - T, G- C • semiconservative replication

  16. Production of polypeptides • Gene product is either RNA or polypeptides • gene expression • Transcription : a single copy of DNA strand (RNA) • Translation : protein production • mRNA carries genetic code to ribosomes • genetic code = codon consisting of 3 bases • 61 amino acids, 3 stop signals • Accumulate mutations • one base change -- sickle cell disease • deletions or insertions • transposon

  17. Gene cloning • Isolate genes and place them in new organisms • Benefits : • raw materials for studies in molecular biology • protein product ie human insulin • Bt cotton

  18. Genome structure and organisation>>what is genome? • Genome is the entire DNA content of a cell, including all of the genes and all the intergenic regions • Most genome are made of DNA • 2 types of living organisms • prokaryotes: cells lack extensive internal compartmetns • eukaryotes: cells contain membrane-bound compartments ie. Nucleus, mitochondria, chloroplast • animals, plants, fungi and protozoa are eukaryotes

  19. Why are genome projects important

  20. Why are genome projects important? • Genome sequences are the key to the continued development --opens the way to a comprehensive description of the molecular activities of living cells and the ways in which these activities are controlled • Gene catalog -- isolation and untilisation of important genes • Additional benefits -- study role of noncoding DNA • Challenge of unknown

  21. Genomes of eukaryotes • Eukaryotic genome is split into 3 components • nuclear genome • mitochondrial genome • chloroplast genome

  22. Human genome • made up of 2 components: nuclear and mitochondria

  23. Human genome • nuclear genome: • 3000 Mb DNA • linear genome divided into 24 (22 autosomes + 2 sex chromosome, X and Y) • shortest 55 Mb and longest 250 Mb • mitochondrial genome: • circular DNA 16,569 bp

  24. Human genome • immensity of human genome • analog with normal font size --60 nt = 10 cm • genome sequence stretch for 5,000 km

  25. Nuclear genome • Genome size ranges <10 Mb to >100,000 Mb • size broadly coincides with organism complexity • larger genome --high repeats

  26. Nuclear genome • Split into a set of linear DNA molecules -chromosomes • chromosome number not related to organism features

  27. Where are genes in a genome?>>Human EST map --expressed sequence tags

  28. Families of genes • Multigene family --groups of genes of identical or similar sequence • rRNA genes : 5S, 28S, 5.8S and 18S • globin gene families • alpha-globin family, on chr#16 • beta-globin family, on chr#11 • Supergene family • globin supergene family --alpha and beta evolve from a single ancestral globin gene

  29. Pseudogenes • Genes which for one reason or another have become nonfunctional • conventional pseudogenes --inactivation by mutation ie. Create termination codon within coding region • processed pseudogenes -- abnormality during gene expression

  30. Organelle genomes • Mitochondria and chloroplasts • Extra chromosomal genes --unusual inheritance patterns • Most mitochondrial and chloroplast genomes are circular

  31. Genetic content of organelle genomes • Mitochondria display greater variability • number of genes : 12-92 • genes for mitochondrial rRNAs, protein components for respiratory chain • Chloroplasts are less variable • gene number ~ 200 • coding for rRNAs, tRNAs and ribosomal proteins and proteins involved in photosynthesis

  32. Prokaryotic genome • Physical structure: size < 5 Mb • Genome is contained in a single circular DNA molecule in nucleoid • Circular E. coli chromosome circumference is 1.6 mm, while cell is 1x2 um

  33. Supercoiling

  34. Prokaryotic genome • Plasmid: small piece DNA, often circular, coexist with main chromosome in a bacteria cell • plasmids carry genes not present in main chromosome

  35. Prokaryotic genome • Controversy: should plasmid be part of genome? • E. coli : main chromosme 4.6 Mb+ few kb of plasmid DNA which are not essential • Borrelia burgdorferi: 910 kb main chromosome carrying 853 genes + 17 linear and circular plasmids of 533 kb with 430 genes, some of which are essential

  36. Prokaryotic genome • Genetic organisation: bacterial genomes have compact genetic organisations with little space between genes

  37. Genetic organisation • Operons: an operon is a group of genes located adjacent to one another in the genome • All genes in an operon are expressed as a single unit

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