1. Genetics

2. Mitosis & Meiosis Review p 45-47 A.The Cell Cycle 1.The dividing cell goes through a cycle of events known as the cell cycle 2.Cycle divided into interphase and mitosis B.Interphase 1.Period of DNA replication in preparation of nucleus dividing 2.Divided into 3 periods, G 1 (1 st growth or gap period), S (synthesis), and G 2 (2 nd growth or gap period)

3. Mitosis C.Mitosis 1.Terms a.Mitosis = division of the nucleus b.Cytokinesis = division of the cytoplasm c.Meristem = regions in plants where mitosis occurs (growing site) 2.Prophase a.Chromosomes become shorter, thicker and double move toward equatorial plate 1)Chromatids double threads of chromosomes 2)Centromeres hold chromatids together 3)Kinetochore near centromere, spindle fibers attach here 4)Other constrictions may occur on individual chromosomes called satellites b.Nucleolus and nuclear envelope disappear c.Centrioles and asters form (only in algae, fungi, and animal cells)

4. 3. Metaphase a. Spindle forms b. Chromosomes become aligned at the equatorial plate and connect to spindle fiber at the kinetochore (part of the centromere) 4. Anaphase a. sister chromatids separate b. once separated, daughter chromosomes are pulled by the kinetochore along spindle fibers to opposite poles 5. Telophase a. Each group of daughter chromosomes becomes surrounded by a new nuclear envelope b. Daughter chromosomes become longer and thinner c. New nucleoli appear d. Phragmoplast appears e. Cell plate forms 1)Vesicles from the Golgi fuse to form the cell plate 2)Plasmodesmata form as ER becomes trapped in cell plate

6. Phragmoplast

7. Alternation of Generations review A. Terminology: n and x B.Sporophyte Phase (2n) 1.Diploid (2x) 2.Meiosis takes place in special spore mother cells (meiocytes) C.Gametophyte Phase (n) 1.Haploid (x) 2.Meiospores begin this phase 3.Meiospores develop by mitosis into multicellular gametophyte 4.Gametes are produced which upon fertilization produce the zygote, the first cell of the new sporophyte (2n) phase D. Many Plant Species Are Polyploid E. Six Rules Pertaining to Alternation of Generations

8. Six Rules Pertaining to Alternation of Generations (from the book) 1. the first cell of any gametophyte generation is normally a spore (sexual spore or meiospore), and the last cell is normally a gamete 2. any cell of a gametophyte generation (n) is usually haploid (x) 3. the first cell of any sporophyte generation is normally a zygote, and the last cell is normally a sporocyte (meiocyte)

9. 4. any cell of a sporophyte generation (2n) is usually diploid (2x) 5. the change from a sporophyte to a gametophyte generation occurs as a result of meiosis 6. the change from a gametophyte to a sporophyte generation occurs as a result of fertilization (fusion of gametes) which is also called syngamy

10. Meiosis First meiosis Interphase: replication of DNA and chromosomes Prophase I: chromosomes of diploid nucleus becomes visible as long thin threads (each consists of 2 chromosomes) – Example: 2 chromosomes with 4 chromotids – 2 homologous pairs of chromosomes

11. Prophase cont. – Prophase I cont: 2 chromosomes with 4 chromotids – 2 homologous pairs of chromosomes – N = 2

12. Prophase cont. Homologues chromosomes pair up (synapses); each chromosome now with 4 chromatids (tetrad) and there is ½ the original number of chromosomes ========o========== Above is a tetrad

13. Prophase cont. Chromosomes condense as homologous chromatids exchange parts (crossing over)

14. Prophase cont. Nuclear membrane disappears Nucleolus disappears Homologous chromatids separate at the centramers but remain attached by schismatic

15. Metaphase I Paired chromosomes move to equatorial plane Centromeres of paired chromosomes line up on opposite sides of the equatorial plate

16. Anaphase I See above Homologues chromosomes separate and move toward poles Two sister chromatids comprise each chromosome Homologues separate (not the sister chromatids) Homologs differ because of crossing over

17. Telophase I Chromosomes at each pole relax and become elongate and indistinct Nuclear envelope forms Nucleoli appear Each of the two new nuclei have ½ of the original chromosome number Reduction completed Cytokinesis may occur or nuclei may proceed immediately to the second division of meiosis

18. Meiosis II No additional duplication Prophase II: nuclear envelope disappears nucleolus disappears Metaphase II: chromosomes line up at equator plate Anaphase II chromatids separate and move to opposite poles Telophase II: new nuclear envelope and nucleolus reappear

19. Review

21. Stop here Wednesday, 7 November 2012

22. Mendelian Genetics A.Mendel’s Studies 1.Austrian monk, born 1822 2.Scientific and mathematical studies 3.Experiments with pea plants a.Crosses between tall and short plants b.Crosses between plants with smooth seeds and wrinkled seeds c.Determination of factors

24. 4.Law of Unit Characters factors which always occur in pairs, control the inheritance of various characteristics Paired factors now known as gene "alleles"

25. 5.Law of Dominance in any given pair of factors (alleles), one may suppress or mask the expression of the other Dominant allele: the expressed factor Recessive allele: the factor not expressed Phenotype: what something looks like (pink flowers, wide leaves) Genotype: 1)Homozygous: both alleles of a pair are identical (e.g., YY or yy) 2)Heterozygous: allele pair is composed of contrasting alleles (e.g., Yy) Incomplete dominance:

26. 6.Law of Segregation members of allele pairs become separated during meiosis 7.The Monohybrid Cross a.F 2 genotype ratio is 1:2:1 b.F 2 phenotype ratio is 3:1 8.The Dihybrid Cross a.Law of independent assortment b.Punnett square c.F 2 genotype ratio is 1:2:2:4:1:2:1:2:1 d.F 2 phenotype ratio is 9:3:3:1

27. 9.The Backcross between homozygous recessive parent and F 1 offspring 10. Incomplete Dominance 11.Interactions Among Genes 12.How Genotype Controls Phenotype 13. Polyploidy in plants

28. Incomplete Dominance

29. How Genotype Controls Phenotype

30. Polyploidy in plants

31. Polyploidy in agricultural plants

32. Science 25 April 2008: Vol. 320 no. 5875 pp. 481-483 AT SCHOOL: go to Google and put the above into the search line. Print out the article and bring it to class. We will make plans

33. Hardy-Weinberg Law We will go into this in lab.

34. DNA and RNA Two kinds of nucleic acids – 1. RNA = ribose nucleic acid – 2. DNA = deoxy ribo nucleic acid

35. nucleotides

36. Sugars

37. D-Ribose 5-phosphate

38. DNA & RNA A.Structure of DNA 1.Nucleotides a.Nitrogenous base b.5-carbon sugar c.Phosphate group 2.Nitrogenous bases a.Purines, adenine and guanine (2 linked rings) b.Pyrimidines, cytosine and thymine (single ring)

39. DNA Structure

40. B.DNA Functions 1.Storage of Genetic Information a.A “Gene” molecular unit of of heredity of a living organism b.Codons and amino acids (see table) 2.Replication (Duplication) of Information a.Semi-conservative replication would produce two copies that each contained one of the original strands and one new strand. b.DNA polymerase 3.Expression of Information a.Transcription b.Translation 4.Mutation

41. Codons

42. DNA polymerase

43. Transcription

44. 1. DNA unzips and RNA polymerase enzyme binds to one strand of DNA. 2. RNA polymerase makes an elongating chain of RNA nucleotides, each new RNA nucleotide is complementary to the DNA nucleotide. 3. The completed mRNA molecule is released from RNA polymerase - DNA complex and can begin translation. In eukaryotic cells this means first moving from the nucleus into the cytoplasm.

45. Translation

46. 1. the ribosome binds to mRNA at a specific area (promoter region) 2. the ribosome starts matching tRNA anticodon sequences to the mRNA codon sequence 3. each time a new tRNA comes into the ribosome, the amino acid that it was carrying gets added to the elongating polypeptide chain 4. the ribosome continues until it hits a stop sequence, then it releases the polypeptide and the mRNA 5. the polypeptide forms into its native shape and starts acting as a functional protein in the cell

47. Mutations Somatic: occurs in a body cell and will occur in all cells produced by mitosis 1. source of new types of horticultural plants Germ line: occurs in tissue that will produce gametes. 1. passed on to future generations 2. important for the genetic improvement of plants (example very sweet corn)

48. Little Review DNA – 1. must carry genetic material from cell to cell and form generation to generation. Must carry a great deal of information – 2. must be able to self replicate with great precision – 3. must be able to be modified or changed (mutation) – 4. must have mechanism to read stored information and transfer it into the living system to be used to carry out activities

49. DNA replication – semi conservative – 1. each strand has ½ of the original strand – 2. after replication both strands are the same 3. occurs in s phase of mitosis DNA strand is very long to have all of the information – 1. carried on triplicate sequences of DNA – 2. begin reading on a specific sequence – 3 There are 16 combinations of those same 4 bases

50. Little Review RNA Three kinds of RNA – 1. tRNA – 2. rRNA – structural portion, rough ER – 3. mRNA – carries sequences of triplet codes

51. Codon: triplet sequence on mRNA Anticodon sequence on tRNA DNAmRNAtRNA ATGATG UACUAC AUGAUG

52. END