HLTH 103 Biological Determinants of Health Genes & Genetics PDF

Summary

This document is a presentation on genes and genetics, covering topics like Gregor Mendel's experiments, patterns of inheritance (including Punnett squares), and inheritance beyond Mendel. It also touches on the role of environment in gene expression. The presentation appears to be part of a university-level health sciences course.

Full Transcript

HLTH 103 – Biological Determinants of
Health
Genes & Genetics

Health Sciences

PART
B
Genes & Genetics
 PART A:
 Case Study: Sickle Cell Anemia & Malaria
 Part B:
 Gregor Mendel & Mendelian Genetics
 Patterns of Inheritance Beyond Mendel
 Part C:
 Genes, Genetics, and Genomics
 Nucleic Acids (Cellular Building Blocks)
 Processing of Genetic Content

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Gregor Mendel
Gregor Mendel, 1822-1884
Considered the father of genetics
Entered monastery and became a priest
He was interested in patterns of inheritance and began
some experiments at the monastery where he resided in
Austria
Conducted historic experiments with pea plants
Pea plants were ideal due to there multiple
characteristics that could be clearly and easily observed
His paper was ignored at the time, but his findings were
independently rediscovered years later

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Gregor Mendel: Pea Plant (Pisum sativum)
 Pea Plants have several advantageous properties
making them ideal to use in these studies:
 Several different and variable TRAITS that
 self-fertilizing: Female gamete fertilized by male Stamen Stigma
gamete from same plant
 Easy to breed true-breeding lines (exhibit the same
trait)
 Large flowers make crosses easy when desired
 Cross-fertilization or hybridization Ovule

Ovary

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Gregor Mendel: TRAITS of Pea Plants
 Seed Shape: round vs wrinkled
 See Color: yellow vs green
 Flower Color: purple vs white
 Pod Shape: smooth (inflated) vs constricted
 Pod Color: yellow vs green
 Flower Pattern: axial vs terminal
 Stem Height: tall vs short (dwarf)

Source:
Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
https://opentextbc.ca/biology/wp-content/uploads/sites/96/2015/02/Figure_08_01_03.jpgcal
Gregor Mendel: Cross Fertilization of Pea Plants

Stamens

Stigma

1Remove stamens 2Transfer pollen from
from purple flower. stamens of white
flower to the stigma
of a purple flower.

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Gregor Mendel’s
Experiments
Experimental Results & Patterns of Inheritance
1. Mendel focused on one trait at a time.
2. Mendel followed the cross for more than one generation.
3. Mendel collected quantitative data and kept detailed records.
4. Mendel’s research revealed some basic rules of inheritance.
 Genes can come in more than one form, or allele.
 Alleles of a particular gene sort individually into gametes during meiosis.
 Certain traits are dominant, while others are recessive.
 The dominant trait is the one that is seen even when only one allele is
present.
 The recessive trait is the one that is not seen when only one allele is
present.

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance
 Punnett square analysis
 used to predict patterns of inheritance
 alleles will be indicated as upper and lower case
letters

 In a Punnett square:
 the possible alleles of one parent are placed on
one axis Example: In a Punnett square, the possible
combinations of male and female gametes
 the possible alleles of the other parent are placed are placed on two axes, and then the possible
combinations of the offspring are plotted in
on the other axis the enclosed squares. This square shows that
in a cross between two hetero-zygotes only
 possible combinations of parental alleles are half the offspring will be heterozygotes.

written in the squares within the grid

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
 P
Patterns of Genetic Inheritance generatio
n PP X pp
purple X
Experimental Results & Patterns of Inheritance white
P-generation: true-pure breeding parents
Sperm from P-Parent (pp)
homozygous dominant X homozygous recessive F1 plant

generatio
mating results in F1-generation
n
Eggs Pp
Pp
from P-
Parent
Pp Results: all
F1-generation: offspring of P-mating cross (PP) Pp (purple)
plant
Pp
all heterozygous dominant Pp

mating results in F2-generation
Sperm from F1 (Pp) plant
F2
generatio
F2 generation: offspring of F1-cross-fertilization
n Results:
(heterozygous dominant X heterozygous dominant)Eggs 1: PP
from F1
results: 1: 2: 1 genotype; 3: 1 phenotype (Pp) (purple)
plant
2: Pp
recessive
Adapted From: Bozzone, trait
Biology for the re-appears
Informed Citizen, © 2014 by Oxford University Press (purple)
Testcross
 Cross the unknown individual to a homozygous recessive
individual
 If some offspring display the recessive phenotype, unknown
individual must have been heterozygous dominant
 If all offspring display the dominant phenotype, unknown
individual was homozygous dominant

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Punnett
Squares

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
 KEY:
Patterns of Genetic Inheritance Y = yellow
peas
y = green
P Generation F1 Generation peas
Cross cross
Yellow pea Yellow pea
YY Yy

Green pea Yellow pea
yy Yy

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance
Sperm (Father) gametes
Bb
♂ B b

♀ BB Bb
B Summary of
Offspring/Progeny:
Eggs 50% = Bb = Heterozygous
Gametes
Bb Bb bb Dominant
b
25% = BB = Homozygous
Dominant
25% = bb = Homozygous
Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Punnett Square
Practice
Sperm (Father) gametes
_____
♂
♀

Egg (Mother)
Gametes
____

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Mendel’s
Results
Characteris Contrasting P0 F1 Offspri F2 Offspring F2 Trait
tic Traits ng Traits Traits Ratios
100%
Flower color Violet vs. white 705 violet: 224 white 3.15:1
violet
Flower
Axial vs. terminal 100% axial 651 axial: 207 terminal 3.14:1
position
Plant height Tall vs. dwarf 100% tall 787 tall: 277 dwarf 2.84:1
100% 5,474 round: 1,850
Seed texture Round vs. wrinkled 2.96:1
round wrinkled
100% 6,022 yellow: 2,001
Seed color Yellow vs. green 3.01:1
yellow green
Pea pod Inflated vs. 100% 882 inflated: 299
2.95:1
texture constricted inflated constricted
Pea pod 100%
Green vs. yellow 428 green: 152 yellow 2.82:1
color green
Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Mendel’s Laws

Mendel’s Law of Segregation
The two copies of each gene segregate, or
separate, during gamete formation and end up
in different gametes.

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Mendel’s Laws

Law of Independent
Assortment
Alleles of different genes assort
independently
of each other during gamete formation
(meiosis).

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Mendel’s Laws
Mendel developed two “laws” of inheritance based on analysis of his experimental data
 Law of segregation: two alleles of each gene separate during gamete formation and end up in
different gametes
 Law of independent assortment: genes for different traits are separated from each other
independently during meiosis (applies in most cases)
 Certain traits are dominant, while others are recessive.
 Dominant allele
 The dominant trait is the one that is seen even when only one allele is present.

 Masks or suppresses the expression of its complementary allele

 Always expressed, even if heterozygous

 Recessive allele
 Will not be expressed if paired with a dominant allele (heterozygous)

 Will only be expressed if individual is homozygous for the recessive allele

 The recessive trait is the one that is not seen (masked) when only one allele is present.

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Dominant
Alleles
 Dominant refers to how the allele behaves in
combination with a recessive allele in a heterozygote
 Dominant does not refer to the frequency of the
allele in the population or to whether the allele
encodes a “normal” phenotype
 Some dominant alleles encode an abnormal or
disease phenotype while the recessive counterparts
encode the normal phenotype
 Polydactyly (extra finger/toe): dominant allele
(P)
▪ The vast majority of people are pp
(homozygous recessive) with five digits on
each hand/foot
 Achondroplasia (dwarfism): Presence of one
Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Freckles
Examples of Traits Influenced by Dominant and Recessive Alleles
 Freckles: determined by the MC1R gene
 Dominant allele (F): produces freckles
 Recessive allele (f): no freckles
 Genotypes FF and Ff will have freckles
 Genotype ff will not have freckles

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: PTC
(phenylthiocarbamide)
Examples of Traits Influenced by Dominant and Recessive Alleles
 Taster: gene determines ability to taste the chemical PTC
(phenylthiocarbamide)
 Dominant allele (T): taster, PTC is bitter
 Recessive allele (t): non-taster, can’t taste PTC
 Genotypes TT and Tt: can taste PTC, bitter sensation
 Genotype tt: non-taster phenotype

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Genetic Inheritance: Cystic Fibrosis
(CFTR)
 Cystic fibrosis: results from inheriting a recessive allele of the CFTR gene
from each parent
 CFTR (cystic fibrosis transmembrane conductance regulator gene):
encodes a protein that transports chloride across the plasma membrane
 Individuals with two copies of the defective recessive allele (homozygous
recessive): functional CFTR protein is not produced
▪ Impaired chloride transport—very thick mucus accumulates in the lungs
▪ Interferes with breathing, frequent pulmonary infections
 Heterozygotes (have one normal allele and one defective allele) produce
the transport protein and have a normal phenotype

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Two-Trait Crosses:
Independent Assortment of Genes for Different Traits
 Outcome of two-trait crosses can be predicted by Punnett square analysis
 Law of independent assortment
 The alleles of different genes are distributed to gametes independently
during meiosis
 This law applies only if the two genes in question are on different
chromosomes
 Example of a two-trait cross:
 Cross FFTT (homozygous freckles/taster) with fftt (no freckles, non taster)
 All offspring are FfTt (heterozygous for both alleles)
 Next, cross FfTt with FfTt

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Two-Trait Crosses: Freckles and PTC
Independent Assortment
of Alleles for Different
Traits

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Two-Trait Crosses: Eggs

Sperm

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Inheritance beyond Mendel
 Mendel’s rules do not completely explain
inheritance
 Inheritance can be much more complicated:
 Alleles can interact, so can genes
 Genes do not always affect just one
characteristic
 Gene expression depends on the environment
 Example: Flowers of Hydrangea will vary
depending on the acidity of the soil
 Example: Carp are a slender fish if they
develop in the absence of predators. If
they are present, body shape changes.
Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Inheritance beyond Mendel
 Complete Dominance (1 genotype; 1 phenotype)
 Incomplete Dominance (both genotypes; blended phenotype)
 Co-dominance (both genotypes; both phenotype both)
 Sex-linked inheritance

Examples:
 Red-green color deficiency
 Hemophilia A & Hemophilia B
 Duchenne Muscular Dystrophy

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Inheritance beyond Mendel: CO-
DOMINANCE
CO-DOMINANCE: Human Blood Groups
 Codominance: heterozygotes express both inherited
alleles equally
 Example: Genes for ABO blood types
▪ A-allele and B-allele are co-dominant

An individual heterozygous for the
A and B alleles will be blood type
AB, expressing both A and B
antigens on red blood cells

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
 Patterns of Inheritance beyond Mendel
CO-DOMINANCE: Human Blood Groups
 Codominance: heterozygotes express both inherited alleles equally
 Example: AB blood type: A-allele and B-allele are co-dominant
 an individual heterozygous for the A and B alleles will be blood type AB, expressing
both A and B antigens on red blood cells
Type O Type A Type B Type AB
Antigen A Antigen B Antigen A Antigen B

RBC RBC RBC RBC
N-Acetyl- Galactose
galactosamine

Blood type: O A B AB
Genotype: ii IAIA or IAi IBIB or IBi IA IB
Surface antigen: Neither A nor B A B A and B
Antibodies: anti-A and anti-B Anti-B Anti-A None
Percentage: 45% 40% 10% 5%

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Inheritance beyond Mendel:
Biological SEX
Sex Determination:
 Sex determined by X & Y-chromosomes
 XX = female; XY = male
 Y-chromosome = 78 genes
 X-chromosome = 900-1200 genes

 X & Y chromosomes:
 homologous portions
 non-homologous portions
 Y-chromosome non-homologous portion contain holandric traits

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
 Patterns of Inheritance beyond Mendel:
Biological SEX Female

Sex-linked inheritance
 Sex-linked genes are located on sex chromosomes Carrier

 Recessive traits - X-linked inheritance

Examples: Male

 Red-green color blindness
Normal femaleCarrier female
 Hemophilia A & Hemophilia B
Normal
 Duchenne muscular dystrophy
Hemophil
Normal male iac
male

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Patterns of Inheritance beyond Mendel:
Biological SEX

© OpenStax Biology
Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Polygenic Inheritance: Phenotype Is Influenced
by Many Genes
 Inheritance of phenotypic traits that depend on many genes is called
polygenic inheritance
 Examples of polygenic traits:
 Eye color, skin color
 Height, body size, and body shape
 Polygenic traits are usually distributed within

a population as a continuous range of values

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Both Genotype and the Environment Affect
Phenotype
 Phenotype isn’t determined by genotype alone
 Environmental factors can profoundly influence phenotype
 Example:
▪ Nutrition affects height, body size
 Genes carry instructions for making proteins, but environment influences
how genes are expressed and how they contribute to one’s phenotype
 Environment may produce epigenetic changes in D N A

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
What Is Epigenetic Inheritance?
 Refers to the modification and transmission of traits in ways that do not
directly involve changes in the nucleotide sequence of a gene
 Environmental factors can modify D N A without changing the sequence
 Addition of methyl groups
 These changes affect the frequency with which these modified genes are
expressed, and in what cells they are expressed
 Different methylation patterns explain why identical twins become more
different as they age

Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press
Adapted From: Bozzone, Biology for the Informed Citizen, © 2014 by Oxford University Press