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Genetics

Chapter 2 Science 30. Genetics. What is genetics?. Genetics is the study of how traits are passed from parent to offspring Nucleus of cells contain genetic material organized into chromosomes. Chromosomes carry genes, units of hereditary. Each chromosome contains many different genes.

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Genetics

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  1. Chapter 2 Science 30 Genetics

  2. What is genetics? • Genetics is the study of how traits are passed from parent to offspring • Nucleus of cells contain genetic material organized into chromosomes. • Chromosomes carry genes, units of hereditary. • Each chromosome contains many different genes. • Humans have 23 pairs of chromosomes (46 total). • 1 set from each parent.

  3. Chromosomes • Long, thin coiled strands of DNA • Seen during cell division. • X shape is created when copies attach at one point (centromere). BrainPop - DNA

  4. Genes • A segment of DNA that codes for a specific protein. • The order of the bases codes for a specific trait (e.g.. Tongue rolling). • Some genes are dominant and some are recessive. Free ear lobe a.) is dominant to attached ear lobe b.).

  5. Role of proteins • Each gene makes a protein…these are used for/as: • Enzymes (amylase- digestion). • Structural (Keratin/ collagen). • Transport ( cell membranes). • Hormones (insulin). • Defense (antibodies). • Energy (Casein). • Muscle contraction (Actin and myosin). BrainPop - RNA

  6. Human karyotype • All 23 chromosomes matched to their pair is a called a karyotype. • 3 features are used to identify pairs: • Length of chromosome (longest = #1) • Pattern of dark bands on chromosome. • Position of centre connection (centromere). • The last 2 chromosomes are the sex chromosomes: • XX = female. • XY= male

  7. Amniocentesis • Prenatal test done to determine karyotype fetus • Taken during week 15 – 16 of pregnancy • Used to diagnose genetic abnormalities such as a trisomy (3 copies of a single chromosome)

  8. Trisomy • Trisomy 21 – Down Syndrome • Trisomy 18 – Edward’s Syndrome • Trisomy 13 – Patau Syndrome • XXY – Klinefelter Syndrome

  9. Down Syndrome (21) • Results in: • Delayed physical growth • Lowered cognitive ability • Congenital heart disease in 50% of individuals • Most common autosomal trisomy

  10. Edward’s Syndrome (18) • Results in : • Kidney and heart malformations • Developmental delays • Cleft lip and palate • Protruding intestines • Second most common autosomal trisomy

  11. Patau Syndrome (13) • Results in: • Developmental delays • Heart and kidney defects • Polydactalism • Cleft lip and palate • Malformed genitalia

  12. Klinefelter Syndrome (XXY) • Small children may have reduced muscular development and strength • Symptoms may not be visible until the on-set of puberty • Individuals may have breast development due to reduced levels of testosterone.

  13. Chromosome Replication • The 2 ways that an exact copy of the DNA from the chromosome is created are: • Mitosis: • occurs in somatic/ autosomal (body cells) • Asexual reproduction • Meiosis: • Occurs in germ cells (in ovaries and testes) • Produces gametes (egg and sperm) for sexual reproduction

  14. Mitosis • Body cells (autosomal cells) divide by replicating all the parts and dividing into 2 identical cells • 1 parent cell = 2 identical daughter cells • A copy of the DNA must be made before replication; each strand replicates and attaches at a centre point (centromere). • Parent cell is diploid; 2n(2 copies of each chromosome • Daughter cells are diploid; 2n (2 copies of each chromosome)

  15. Summary of Mitosis: BrainPop - Mitosis

  16. Meiosis • Occurs in germ cells to produce gametes (egg or sperm) • Germ cell replicates DNA and divides twice • 1 parent cell = 4 sex cells • Parent cell is diploid; 2n (2 copies of each chromosome) • Sex cell is haploid; 1n (1 copy of each chromosome)

  17. Summary of Meiosis:

  18. Fertilization • The sperm and the egg (gametes) are each haploid, the fertilized egg (zygote) is diploid and can reproduce through mitosis. • This increases variation and allows for more than 70 trillion gene combinations. • Crossing over improves the variation possible in the gametes; explains why 2 siblings look so different. BrainPop - Gender Determination

  19. Inheritance ideas • Charles Darwin had produced the theory of evolution through natural selection during the 19th century • Darwin understood that traits were passed from parent to offspring but did not understand how…

  20. Gregor Mendel • The “father of genetics” • (1822-1884) Gregor Mendel’s work with garden peas provided missing piece in theory of evolution by natural selection. • Noticed that traits were not blended but instead one was dominant. BrainPop - Heredity

  21. Crosspollination • Transferring pollen between genetically different plants. • Mendel discovered that some traits were easy to recognize and studied these.

  22. 1st Generation Breeding 2nd Generation Breeding

  23. Mendel’s laws • Inherited characteristics are controlled by genes that occur in pairs; each gamete receives 1 gene (law of segregation). • Principal of dominance- 1 gene masks the effect of the other. • Dominant trait = capital letter • Recessive trait = lowercase letter

  24. Individuals randomly inherit genes from parents. Independent inheritance of traits to offspring- not linked to other traits.

  25. Inheritance • Inherited traits: • passed from parent to offspring via genes • example: blood type, eye color, hair color • Acquired traits: • due to environment; not genes • cannot be passed from parent to offspring • example: scars

  26. Alleles • A form of a gene responsible for a trait (e.g. Tongue rolling). • Individuals have 2 alleles for every trait located on chromosomes. • When the chromosomes separate during meiosis, 1 allele is passed to each gamete.

  27. Dominance Theory • Alleles can be dominant or recessive. • A dominant allele masks a recessive allele • Recessive traits are coded only when an offspring receives 2 recessive alleles.

  28. Genetic terms • Homozygous: two identical copies of an allele • can be homozygous dominant or recessive • (ie. RR or Rr) • Heterozygous: two different copies of an allele • (ie. Rr) • Genotype: the genes that an individual has • (ie. the rose plant has the genotype Rr) • Phenotype: how the gene is expressed; the observed trait • (ie. the rose has red flowers)

  29. Punnett Squares • If alleles are known, a Punnett square is used to predict the probability of offspring genotype. • To Draw a Punnett Square: • Draw a square and label each row with alleles of the gamete. • Fill in the squares with the genotype. • Determine the probability of the offspring with each genotype; expressed as a percentage (%)

  30. Codominance • Not all traits are controlled by one gene or have only two alleles for a gene • Codominance is a condition where both allele products are expressed at the same time

  31. Codominance - Blood Types • Controlled by 3 alleles: • A, B, O. • Produce 4 genotypes: • A, AB, B, O. • O is recessive; individual needs to be homozygous for type. • A and B are codominant; both can be expressed at the same time.

  32. Codominance - Blood Types BrainPop – Blood Type

  33. Who’s the daddy? The Maury Povich Show needs your help in determining the father of a new born baby. The blood type of the mother, baby and potential fathers are known. • Based on the information in the table, which could not be the father of the baby? Use a Punnett square to justify your answer. • Explain why blood type information cannot be used to determine who the father of the baby is, and only who the father of the baby is not.

  34. Gender determination • Mother has only X chromosomes; all eggs have an X chromosome. • Father determines the gender of the baby; 50% chance for either gender.

  35. Sex linked traits • Autosomal trait: • controlled by genes on chromosomes 1-22 • Sex-linked trait: • controlled by genes located on sex chromosomes (X or Y). • ie. colorblindness, hemophilia

  36. Deoxyribonucleic Acid (DNA) • DNA: • double helix structure (twisted ladder) • Composed of nucleotides: • sugar and phosphate “backbone” • bases (adenine, thymine, cytosine, guanine)

  37. Nitrogen Bases • There are 4 Nitrogen bases: • adenine (A) • thymine (T) • cytosine (C) • guanine (G) • Hydrogen bonds hold bases together; base pair • Only certain bases bond together: • A and T • C and G

  38. Base Pairs Bonding • DNA molecule has 1 base strand and 1 complementary base strand. • adenine pairs with thymine • cytosine pairs with guanine • 2 strands form the ladder, with the bonded pairs becoming the ‘rungs’. • What is the complementary strand to: • ATTGCCGATGC

  39. DNA Replication • DNA is only molecule known to duplicate itself (replication) • DNA must replicate before 1 cell can divide into 2 cells • During replication: • weak H bonds are broken • 2 edges of the ladder "unzip" • each strand acts as a template to which free floating nucleotides in cell can attach • new DNA strand is made 47

  40. The Genetic Code and Protein Synthesis • mRNA copies the DNA sequence and transports it to ribosomes outside nucleus for protein synthesis • Order of bases in a gene code for a specific protein: • order of bases code for the production of amino acids • amino acids are assembled in ribosomes to make proteins • 3 bases (DNA triplet/ codon) codes for a specific amino acid • 64 possible DNA triplets/ codons code for 20 amino acids.

  41. mRNA takes DNA to ribosome and tells them what protein to make. • To start or stop amino acid assembly, a specific codon is used: • Start = Initiator codon (ATG) • Stop = terminator codon (TAA, TAG, TGA)

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