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Transcript
PowerPoint Lecture Outlines to accompany Hole’s Human Anatomy and Physiology Eleventh Edition Shier w Butler w Lewis Chapter 24 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1 Chapter 24 Genetics and Genomics Genetics – study of inheritance of characteristics Genome – complete set of genetic instructions Genomics – field in which the body is studied in terms of multiple, interacting genes 2 From Gene to Protein: Cystic Fibrosis • when the gene coding for CFTR protein is mutant, cystic fibrosis results • CFTR protein folds into a channel that regulates the flow of Cl- into and out of cells lining the respiratory tract, pancreas, and elsewhere 3 From Protein to Person: Cystic Fibrosis • when CFTR is abnormal, it traps Cl- in cells • water in cells forms very thick mucus 4 Chromosomes and Genes Come in Pairs 23 pairs of chromosomes • pairs 1-22 are autosomes • pair 23 are sex chromosomes Normal karyotype 5 Genotype and Phenotype Genotype • particular combination of genes • alleles are variant forms of the same gene • homozygous – identical alleles • heterozygous – different alleles • wild type allele – produces most common or normal phenotype Phenotype • way that genes are expressed • blue eyes, presence of a protein, etc 6 Dominant and Recessive Inheritance Dominant allele masks the phenotype of the recessive allele Recessive allele is expressed only if in a double dose (homozygous) Autosomal conditions are carried on a nonsex chromosome Sex-linked conditions are carried on a sex chromosome X-linked conditions are carried on the X chromosome Y-linked conditions are carried on the Y chromosome 7 Autosomal Recessive Disorder • cystic fibrosis is an example • sexes are affected with equal frequencies • offspring probabilities • 25% homozygous dominant • 50% heterozygous • 25% homozygous recessive • punnet square and a pedigree are useful ways to express genetic information 8 Autosomal Dominant Disorder • Huntington disease is an example • a person with one HD allele develops the disease • both sexes are equally affected 9 Different Dominance Relationships: Incomplete Dominance • heterozygote has a phenotype intermediate between homozygous dominant and homozygous recessive • familial hypercholesterolemia is an example 10 Different Dominance Relationships: Codominance • different alleles are both expressed • ABO blood type is an example • three alleles of ABO blood typing are IA, IB, I • a person with type A may have the genotype IA i or IA IA • a person with type B may have the genotype IB i or IB IB • a person with type AB must have the genotype IA IB • a person with type O blood must have the genotype ii 11 Gene Expression: Penetrance and Expressivity Complete penetrance • everyone who inherits the disease causing alleles has some symptoms Imcomplete penetrance • some individuals do not express the phenotype even though they inherit the alleles (example polydactyly) Variable expression • symptoms vary in intensity in different people • two extra digits versus three extra digits in polydactyly 12 Gene Expression: Pleiotrophy and Genetic Heterogeneity Pleiotropy • single genetic disorder producing several symptoms • Marfan syndrome is an example • people affected produce several symptoms that vary Genetic Heterogeneity • same phenotype resulting from the actions of different genes • hereditary deafness is an example 13 Complex Traits Most if not all characteristics and disorders considered “inherited” actually reflect input from the environment as well as genes. Polygenic traits • determined by more than one gene • height, skin color, eye color Multifactorial traits • traits molded by one or more genes plus environmental factors • height and skin color 14 Variations in Height 15 Variations in Skin Color Mid-range colors are more common 16 Variations in Eye Color 17 Sex Determination • an egg contributes an X chromosome • a sperm contributes either an X or a Y chromosome • A gene on the Y chromosome, SRY, determines sex 18 Sex Chromosomes and Their Genes X chromosome • has over 1,500 genes • most genes on the X chromosome do not have corresponding alleles on the Y chromosome Y chromosome • has only 231 protein-encoding genes • some genes are unique only to the Y chromosome 19 Sex-linked Genes • Y-linked genes are transmitted only from father to son • X-linked genes are transmitted from father to daughter or from mother to daughter or son • Hemophilia A is a sex-linked disorder 20 Hemophilia A • passed from mother (heterozygote) to son • each son has a 50% chance of receiving the recessive allele from the mother • each son with one recessive allele will have the disease • each son has no allele on the Y chromosome to mask the recessive allele • each daughter has a 50% chance of receiving the recessive allele from the mother • each daughter with one recessive allele will be a carrier • each daughter with one recessive allele does not develop the disease because she has another X chromosome with a dominant allele 21 Gender Effects on Phenotype Sex-limited trait • affects a structure or function of the body that is present in only males or only females • examples are beards or growth of breasts Sex-influenced inheritance • an allele is dominant in one sex and recessive in the other • baldness is an example • heterozygous males are bald but heterozygous females are not 22 Chromosomal Disorders Polyploidy • extra set of chromosomes • most embryos die Aneuploidy • missing a chromosome or having an extra chromosome • results from nondisjunction • trisomy is the condition of having an extra chromosome • monosomy is the condition of missing a chromosome Euploid is a normal chromosome number 23 Causes of Aneuploidy 24 Prenatal Tests 25 Prenatal Tests 26 Gene Therapy • group of experimental techniques that alter, replace, silence, or augment a gene’s function to improve, delay or prevent symptoms • heritable gene therapy • introduces the genetic change into a sperm, egg, or zygote • changes passed to future generations • common in plants; not done in humans • nonheritable gene therapy • targets only affected cells • changes not passed to future generations 27 Gene Therapy Targets 28 Clinical Application Down Syndrome • most common autosomal aneuploid • trisomy 21 • signs and symptoms include • short stature • mental retardation • protruding tongue • heart defects • kidney defects • suppressed immune systems • digestive disorders 29
