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CHAPTER 16 Heredity Chapter 16 Heredity 16.1 Heredity 16.2 Basic Knowledge for Studying Heredity 16.3 Determining Genotypes 16.4 Discontinuous and Continuous Variations 16.5 Mutation Why do Animals look the same? 16.1 Heredity Learning Outcome After this section, you should be able to: • understand genetics and monohybrid inheritance. 16.1 Heredity Hereditary traits • A hereditary trait is a characteristic that can be passed on from one generation to another. • Examples include: - Hair type Shape of earlobe Eye colour Face shape Chin shape Ability to roll tongue Skin colour Blood type 16.1 Heredity What is Genetics? Genetics is the study of the inheritance of characteristics by transmission of genetic materials from one generation to another. Gregor Mendel, the founding father of modern genetics studied monohybrid inheritance in peas. 16.1 Heredity What is monohybrid inheritance? • Monohybrid inheritance refers to the inheritance of one characteristic that has TWO contrasting forms. • Each characteristic is controlled by a single gene. gene • Each gene consists of a pair of alleles. alleles • Alleles can be dominant or recessive. homologous chromosomes 16.1 Heredity Mendel’s monohybrid experiment Mendel crossed pure-bred tall pea plants with pure-bred dwarf plants. He planted the seeds from the cross and observed that the resulting F1 generation hybrids are all tall plants. tall dwarf tall tall tall tall dwarf He allowed the F1 offspring to self-fertilise and produce seeds. The seeds from the F1 offspring gave rise to the F2 generation, which produced a ratio of three tall plants to one dwarf plant. 16.1 Heredity Mendel’s monohybrid experiment Mendel named the trait that always appeared in the F1 hybrids (tall) dominant and the other (dwarf) recessive. dominant trait recessive trait 16.1 Heredity Mendel’s model of heredity • Hereditary factors (genes) are responsible for the transmission of characteristics. • Each characteristic is controlled by a pair of factors in the cells. • If the two factors are different, only the dominant factor will show its effect. • The two factors separate (segregate) during gamete formation. Each gamete will only contain one factor (Law of Segregation). • The random fusion of gametes formed contains two factors. ensures that the zygote 16.1 Heredity Mendel’s Law of Segregation Chapter 16 Heredity 16.1 Heredity 16.2 Basic Knowledge for Studying Heredity 16.3 Determining Genotypes 16.4 Discontinuous and Continuous Variations 16.5 Mutation 16.2 Heredity Learning Outcomes After this section, you should be able to: • understand the terms gene, allele, dominant, recessive, homozygous, heterozygous, phenotype and genotype; • use genetic diagrams to explain monohybrid inheritance. 19.2 Basic Knowledge for Studying Heredity Chromosome A chromosome is a rod-like structure visible in the nucleus during cell division. It is made up of the molecule deoxyribonucleic acid (DNA). 19.2 Basic Knowledge for Studying Heredity Gene A gene is a unit of inheritance, born on a particular locus (position) of a chromosome. It is a small segment of DNA in a chromosome that controls a particular characteristic or protein in an organism. gene locus chromosome 19.2 Basic Knowledge for Studying Heredity Alleles Alleles are different forms of the same gene. They occupy the same relative positions on a pair of homologous chromosomes. Letters are usually used to represent alleles. T t 19.2 Basic Knowledge for Studying Heredity Homologous Chromosomes gene locus Homologous chromosomes exist in pairs. One chromosome in the pair comes from the male parent and the other from the female parent. They have exactly the same sequence of gene loci. paternal chromosome maternal chromosome 16.2 Basic Knowledge for Studying Heredity Introduction to terms nucleus chromatin gene different gene loci cell homologous chromosomes 16.2 Basic Knowledge for Studying Heredity Introduction to terms: Phenotype • The phenotype of an organism refers to its observable traits. • The phenotype of an organism is influenced by: – its genotype – the environment URL 16.2 Basic Knowledge for Studying Heredity Introduction to terms: Genotype • The genotype is the genetic make-up of an organism which is inherited from its parents. • An organism is homozygous for a trait if the two alleles controlling the trait are the same. The possible homozygous combinations are: – homozygous dominant (e.g. TT) – homozygous recessive (e.g. tt) • An organism is heterozygous for a trait if the two alleles controlling the trait are different (e.g. Tt). 16.2 Basic Knowledge for Studying Heredity Introduction to terms: Dominant and recessive alleles • Alleles can exist in dominant or recessive forms. Dominant allele is represented with an upper case letter. Recessive allele is represented with the corresponding lower case letter. • A dominant allele expresses itself in both homozygous dominant and heterozygous conditions. • A recessive allele will only express itself in a homozygous recessive genotype. Basic Knowledge for Studying Heredity 16.2 Introduction to terms: Dominant and reccessive alleles P a a Q R Phenotype: physical characteristic of the organism A A A a Genotype: genetic make-up of the organism homozygous (pure-breeding) heterozygous (hybrid) Why do plants Q and R look the same when they have different genes? 16.2 Basic Knowledge for Studying Heredity Modelling genetic crosses • Genetic models can be used to: - explain how alleles are passed on to an offspring - predict the traits that will be displayed by an offspring • The next slide uses the genetic model to explain Mendel’s monohybrid experiment on tall and dwarf plants. 16.2 Basic Knowledge for Studying Heredity Genetic diagram Basic Knowledge for Studying Heredity 16.2 The Punnett square • The Punnett square is a simpler method to determine or explain genetic crosses. • The Punnett squares for Mendel’s monohybrid experiment: Parents TT F1 hybrid self-cross tt Tt Tt Gametes t t Gametes T t T Tt (tall) Tt (tall) T TT (tall) Tt (tall) T Tt (tall) Tt (tall) t Tt (tall) tt (dwarf) Chapter 16 Heredity 16.1 Heredity 16.2 Basic Knowledge for Studying Heredity 16.3 Determining Genotypes 16.4 Discontinuous and Continuous Variations 16.5 Mutation 16.3 Determining Genotypes Learning Outcomes After this section, you should be able to: • use a test cross to predict an unknown phenotype; • describe sex determination in humans. 16.3 Determining Genotypes Determining genotypes • When an organism displays the recessive trait, the organism is a homozygous recessive. • However, when organisms display the dominant trait, the organism could be a heterozygous or a homozygous dominant. • Breeding experiments are used to identify the genotype of an organism. 16.3 Determining Genotypes Test cross A test cross is used to determine the genotype of an organism with dominant trait by crossing the organism with a homozygous recessive organism. • If the organism is homozygous dominant, all the offspring should show the dominant trait. Phenotypes and genotypes of parents Gametes Phenotype and genotype of offspring homozygous dominant tall TT homozygous recessive T tt t Tt all tall dwarf 16.3 Determining Genotypes Test cross • If the organism is heterozygous, half the number of offspring should show the dominant trait. The remaining half should show the recessive trait. Phenotypes and genotypes of parents heterozygous homozygous recessive Tt tt Gametes T t t Genotypes of offspring Tt Ratio of phenotypes tall tt 1 tall : 1 dwarf dwarf 16.3 Determining Genotypes Sex determination • Sex chromosomes are chromosomes that determine the sex of an organism. • Autosomes are chromosomes in cells other than the sex chromosome. • There are two types of sex chromosome: – X chromosome – Y chromosome • Cells that produce gametes by meiosis are known as sex cells. The other cells in the body are known as somatic cells. 16.3 Determining Genotypes Sex determination • Humans have 22 pairs of autosomes and one pair of sex chromosomes (XY - male or XX - female) in each cell. • Male gametes (sperms) contain either the X chromosome or Y chromosome. • Female gamete (eggs) contain only the X chromosome. • Whether an X-carrying sperm or a Y-carrying sperm fertilises the ovum determines the sex of the zygote. URL 16.3 Determining Genotypes Sex determination When male and female gametes fuse during fertilisation, there is an equal chance that the offspring could be a male or a female. male female X XY Parents XX Gametes X Y X X Offspring XX XX XY XY females males 3.6 What are gametes haploid? • Differences in cell division • Somatic cells (growth, repair) – Mitosis – Produces 2 identical diploid cells – Daughter cells have the same number and kinds of chromosome as parent cell • Gametes (Ovaries + Testes) – Meiosis – Produces 4 haploid daughter cells – Each daughter cell has ½ number of chromosomes as the parent cell 3.6.1 Relationship between mitosis, meiosis and fertilization 3.5.1 Think about this • Is this a haploid/diploid cell? • Is this a male or female? 3.5.2 What happens if . . . . • Male : XXY – Klinefelter syndrome 3.5.3 What happens if . . . . • Male : XYY – Jacob's Syndrome, Supermale Syndrome • Signs and symptoms – learning problems at school – delayed emotional maturity – tall, thin, have acne, speech problems, and reading problems. 3.5.4 What happens if . . . . • Female : X – Turner syndrome Chapter 16 Heredity 16.1 Heredity 16.2 Basic Knowledge for Studying Heredity 16.3 Determining Genotypes 16.4 Discontinuous and Continuous Variations 16.5 Mutation 16.4 Discontinuous and Continuous Variations Learning Outcome After this section, you should be able to: • compare and provide examples for continuous and discontinuous variation. 16.4 Discontinuous and Continuous Variations Variations • Variations are differences in traits between individuals of the same species. • The traits of an individual is dependent on interactions between the genes and the environment. • Genetic variation is heritable, but variations due to the environment are not. 1.2.1 What is variation? • Differences observed among individuals within a species • Types of variations – Continuous variation – Discontinuous variation 1.2.2 What is continuous variation? • Characteristics that vary gradually from one extreme form to the other • No clearly defined groups ; with a large range of values • Examples of traits: – Human height, – Weight, – Intelligence • Controlled by several genes • Influenced by environment, lifestyle, diet, exercise Continuous Variation Length of feet Height 1.2.3 What is discontinuous variation? • Characteristics that show no intermediate forms • Clearly defined groups • Examples of traits : – – – – – attached earlobes or free earlobes, blood group, tongue rolling, colour blindness, ability to taste phenylthiourea (PTU) • Controlled by a single gene • Not influenced by environmental factors Discontinuous variation Cleft chin Attached or free earlobes Tongue roller Widow’s Peak Continuous variation vs Discontinuous variation Discontinuous variation Continuous variation Discontinuous and Continuous Variations 16.4 Variations • Discontinuous variation is brought about one or a few genes. • Continuous variation is brought about by the additive effect of many genes. double-eyelids single-eyelid Continuous variation Number of individuals in a population Number of individuals in a population Discontinuous variation Dark skin Fair skin 16.4 Discontinuous and Continuous Variations Comparing discontinuous and continuous variations Discontinuous variation Deals with a few clear-cut phenotypes Continuous variation Deals with a range of phenotypes Controlled by one or a few genes Controlled by many genes Genes do not show additive effect Not affected by environmental conditions Examples include eye colour and blood group Genes show additive effect Affected by environmental conditions Examples include height and skin colour Chapter 16 Heredity 16.1 Heredity 16.2 Basic Knowledge for Studying Heredity 16.3 Determining Genotypes 16.4 Discontinuous and Continuous Variations 16.5 Mutation 16.5 Mutation Learning Outcomes After this section, you should be able to: • explain mutation as a change in the structure of a gene such as in sickle-cell anaemia, or in the chromosome number, such as in Down’s syndrome; • understand that radiation and chemicals are factors which may increase the rate of mutation. 16.5 Mutation Types of mutation • Mutation occurs as a result of error during the replication of the gene or chromosome. • Somatic mutations that occur in normal body cells cannot be inherited. • Mutations may be inherited by the next generation if they occur in cells that give rise to gametes. • Dominant mutations are easily detected unlike recessive mutations, which may not be detectable for generations. 16.5 Mutation Types of mutation • Chromosome mutation – change in the structure or number of chromosomes – causes Down’s syndrome • Gene mutation – change in the structure of DNA – produces variation between individuals as it results in new alleles of genes – causes albinism and sickle-cell anaemia Mutation • Gene Mutation – Deletion – Addition – Substitution – Switching on/off genes expression • Chromosomal – Addition – Deletion 16.5 Mutation Chromosome mutation Down’s syndrome • Humans normally have 46 chromosomes in their body cells. • People with Down’s syndrome have 47 chromosomes. • They have an extra copy of chromosome 21. 16.5 Mutation Chromosome mutation Down’s syndrome • Chromosome mutation in the gametes of a female parent can produce a child with Down’s syndrome. Male Female X Normal body cell has two copies of chromosome 21 One of the eggs has two copies of chromosome 21 mutation Zygote formed has three copies of chromosome 21 16.5 Mutation Gene mutation Albinism • Caused by mutation in a recessive allele • The absence of the pigment melanin results in reddish-white skin, white hair and pink eyes. • Albinos get sunburn easily as they are very sensitive to sunlight. 16.5 Mutation Gene mutation Sickle-cell anaemia • Caused by mutation in the gene controlling haemoglobin production • The mutated gene is recessive, hence only expressed in homozygous recessive condition. • Sickle-shaped red blood cells have low oxygen carrying capacity and tend to clump together. • This disease is fatal and sufferers usually die young. 16.5 Mutation Gene mutation Sickle-cell anaemia • Individuals who are heterozygous for the sickle-cell allele are more resistant to malaria. • Hence, heterozygous individuals are common in areas where malaria is prevalent such as West Africa. 16.5 Mutation Mutation and selection • Mutations can be harmful or beneficial. - Individuals with harmful mutation will be eliminated. - Individuals with beneficial mutation on the other hand may leave more offspring than normal individuals. • Nature ‘selects’ organisms with more favourable characteristics to survive and reproduce. 16.5 Mutation Natural selection • Natural selection is a process that ensures the best adapted organisms in a population survive to reproduce and pass on their genes to the next generation. • Nature selects varieties of organisms that are: – more resistant to diseases – better adapted to changes in the environment • The process by which present complex forms of living organisms have arisen from simpler ancestral forms is known as evolution. • • • • • Causes of Mutation Age of Cell (Wear & Tear of DNA replication machinery) Crossing over of genes between synapsis in Meiosis Mutagens (Cancer causing Agents) Radiation Virus 5.4.1 Dominant and recessive allele Characteristic PTC-tasting Tongue-rolling Earlobes Dominant allele T R E Recessive alle t r e • Let R represent dominant allele for tongue-roller • Homozygous Let r represent recessive allele dominant R Rfor non-tongue-roller Tongue-roller Heterozygous Rr Tongue-roller Homozygous recessive rr Non-roller Homozygous versus Heterozygous individuals • Find the probability of getting a child who is dark skin, has a unibrow and has myopia if he has the parents below. • Dominant genes : Dark skin, unattached eyebrows, good eyesight. • Father: Heterozygous skin colour, homozygous unattached eyebrow and myopic. • Mother: Fair skin, unibrow and heterozygous myopia. 5.5 What is genotype / phenotype? • Phenotype – Describes the observed trait / physical appearance – Eg: tallness and shortness of pea plants • Genotype – Genetic make-up of an organism – Eg: TT or tt or Tt 5.5.1 Phenotype vs Genotype • Let E represent dominant allele for unattached earlobes • Let e represent recessive allele for attached Homozygous earlobes Heterozygous person Homozygous recessive person EE Ee ee Unattached earlobes Unattached earlobes Attached earlobes dominant person Genotype Phenotype 5.5.2 Test yourself 1 • Let T represent dominant allele for PTC taster • Let t represent recessive allele for PTC non-taster Homozygous dominant person Heterozygou s person Homozygous recessive person Genotype TT Tt tt Phenotype PTC taster PTC taster PTC non-taster • Case study – Blood Group • • • • Man died after given wrong blood type Blood was mislabelled Why did he die? Why can O blood type be given to everyone? • Show YouTube video • White blood cells protect the human body • WBC’s do not have eyes, ear or a nose • Every cell has an antigen marker. It acts like an identity pass. • WBC’s attack anything that doesn’t have an antigen marker (identity pass) Blood Group • Antigens – RBC’s have special proteins Antigens on it’s surface (identity markers) – Antibodies will not attack our own RBC’s antigens – When it detects blood with different antigen, it will clump the blood. – 3 types of Antigen • A, B and O 78 79 • Codominance Q1: Identify the possibly blood types of a child if the parents are an O and a BO blood type. Q2: Billionaire Man X passes away and leaves no heir to his fortune. A lady makes a claim that her child’s father is Man X. Can you prove that the claim is false if the blood types of her child is AB, she is A while the Man X is O. • Q3: What if the man’s blood type is B? Can you prove that the claim is false? • Difficult thus thankfully we have DNA testing. Case Study – SARS Virus 86 SARS Virus Mutation • Case Study – Haemophilia Chapter 16 Heredity