beyond mendels laws
TRANSCRIPT
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Human GeneticsConcepts and Applications
Ninth Edition
RICKI LEWIS
Copyright ©The McGraw-Hill Companies, Inc. Permission required for reproduction or display
PowerPoint® Lecture Outlines Prepared by Johnny El-Rady, University of South Florida
5 BeyondMendel’s Laws
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Exceptions to Mendel’s Law
Mendel’s traits showed two distinct forms Most genes do not exhibit simple inheritanceGenotypic ratios persist but phenotypic ratios
may vary due to “outside-the-gene” influences including - Multiple alleles- Other nuclear genes- Non-nuclear genes- Gene linkage- Environment
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Lethal Alleles
A lethal genotype causes death before the individual can reproduce
- This removes an expected progeny class following a specific cross
A double dose of a dominant allele may be lethal
- Examples:
- Achondroplastic dwarfism
- Mexican hairless dogs
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4Figure 5.1b
Figure 5.1
Lethal Alleles
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Multiple Alleles
An individual carries two alleles for each autosomal gene
However, a gene can have multiple alleles because its sequence can deviate in many ways
Different allele combinations can produce variations in the phenotype- PKU gene has hundreds of alleles resulting in four basic phenotypes- CF gene has over 1500 alleles
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NH2-terminal. COOH-terminal.
CF protein amino acid sequence
Allele 1
Allele 2
Allele 3
Allele 4
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Incomplete Dominance
The heterozygous phenotype is between those of the two homozygotes
Example: Familial hypercholesterolemia (FH)
- A heterozygote has approximately half the normal number of receptors in the liver for LDL cholesterol
- A homozygous for the mutant allele totally lacks the receptor, and so their serum cholesterol level is very high
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Incomplete Dominance
Figure 5.2
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Codominance
The heterozygous phenotype results from the expression of both alleles
The ABO gene encodes a cell surface protein
- IA allele produces A antigen
- IB allele produces B antigen
- i (IO) allele does not produce antigens
Alleles IA and IB are codominant, and both are completely dominant to i
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Figure 5.3
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11Figure 5.4
Offspring from Parents with Blood Type A and Blood Type B
Figure 5.4
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EpistasisThe phenomenon where one gene affects the
expression of a second geneExample: Bombay phenotype
- The H gene is epistatic to the I gene - H protein places a molecule at the cell surface
to which the A or B antigens are attached- hh genotype = no H protein
- Without H protein the A or B antigens can not be attached to the surface of the RBC
- All hh genotypes have the phenotype of type O, although the ABO blood group can be anything (A, B, AB, or O)
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epistasis
•which involves the interaction between two or more genes
•In fact, understanding epistatic interactions may be the key to understanding complex diseases, such as
•Alzheimer's disease,•diabetes, •cardiovascular disease, and •cancer.
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H antigen
ABO antigen
Red Blood Cell
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Penetrance and Expressivity
Penetrance refers to the all-or-none expression of a single gene
Expressivity refers to the severity or extent
A genotype is incompletely penetrant if some individuals do not express the phenotype
A phenotype is variably expressive is symptoms vary in intensity among different people
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Penetrance:
The likelihood a given gene will result in disease. For example, if half (50%) of the people with the neurofibromatosis (NF) gene have the disease NF, the penetrance of the NF gene is 0,5.
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Pleiotropy
The phenomenon where one gene controls several functions or has more than one effect
Example: Porphyria variegata
- Affected several members of European Royal families, including King George III
- The varied illnesses & quirks appeared to be different unrelated disorders
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Photo © North Wind Picture Archives
Figure 5.5a
Figure 5.5b
Pleiotropy
Figure 5.5
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The Porphyrias
Diseases that result from deficiencies of any of several enzymes required to make heme
In each disease, an intermediate biochemical builds up
- It may be excreted in urine, or accumulate in tissues causing symptoms
- These symptoms, including reddish teeth and photosensitivity, may have inspired the vampire and werewolf legends
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myotonic dystrophy
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Genetic Heterogeneity
Different genes can produce identical phenotypes - Hearing loss – 132 autosomal recessive forms - Osteogenesis imperfecta – At least two different genes involved- Alzheimer disease – At least four different genes involved
Genes may encode enzymes that catalyze the same biochemical pathway, or different proteins that are part of the pathway
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Hearing loss
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Osteogenesis imperfecta
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Alzheimer disease
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Phenocopy
A trait that appears inherited but is caused by the environment
May have symptoms that resemble an inherited trait or occur within families
Examples:- Exposure to teratogens
- Thalidomide causes limb defects similar to inherited phocomelia- Infection
- AIDS virus can be passed from mother to child, looking like it is inherited
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Thalidomide causes limb defects
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The Human Genome Sequence Adds Perspective
The Human Genome Project has revealed that complications to Mendelian inheritance are more common than originally thought
Thus terms like epistasis and genetic heterogeneity are beginning to overlap and blur- Example: Marfan syndrome
Interactions between genes also underlie penetrance and expressivity- Example: Huntington disease
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Marfan syndrome
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32Table 5.3
Summary
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Mitochondrion
Organelle providing cellular energy
Contains small circular DNA called mtDNA - 37 genes without noncoding sequences
No crossing over and little DNA repair
High exposure to free radicals
Mutation rate is greater than nuclear DNA
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A cell typically has thousands of mitochondria, and each has numerous copies of its “mini-chromosome”
Figure 5.8
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Mitochondrion
Mitochondrial genes are transmitted from mother to all of her offspring
Figure 5.7
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36Table 5.4
Mitochondrial DNA
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Mitochondrial DisordersMitochondrial genes encode proteins that
participate in protein synthesis and energy production
Several diseases result from mutations in mtDNAExamples:
- Mitochondrial myopathies – Weak and flaccid muscles- Leber optical atrophy – Impaired vision
Ooplasmic transfer technique can enable woman to avoid transmitting a mitochondrial disorder
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Heteroplasmy
The condition where the mtDNA sequence is not the same in all copies of the genome - Thus, a mitochondrion will have different alleles for the same gene
At each cell division, the mitochondria are distributed at random into daughter cells
If an oocyte is heteroplasmic, differing number of copies of a mutant mtDNA may be transmitted- The phenotype reflects the proportion of mitochondria bearing the mutation
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Heteroplasmy
Figure 5.9
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Mitochondrial DNA Reveals Past
mtDNA provides a powerful forensic tool used to:- Link suspects to crimes- Identify war dead- Support or challenge historical records
- Example: Identification of the son of Marie Antoinette and Louis XVI
mtDNA is more likely to survive extensive damage and cells have many copies of it
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Linkage
Genes that are close on the same chromosome are said to be linked
Linked genes do not assort independently in meiosis- Rather, they are usually inherited together when the chromosome is packaged into a gamete- Therefore, they do not produce typical Mendelian ratios
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Linkage
Figure 5.10
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Linkage
Figure 5.11
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Recombination
Chromosomes recombine during crossing-over in prophase I of meiosis
New combinations of alleles are created
Parental chromosomes have the original configuration
Recombinant chromosomes have new combinations of alleles
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1) cis = Two dominant or two recessive alleles are on each chromosome
2) Trans = One dominant and one recessive allele are on each chromosome
Allele Configuration in a Dihybrid
Figure 5.13
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Crossing Over Disrupts Linkage
Figure 5.12
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47Figure 2.3
Crossing Over Animation
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Figure 5.15
Linkage versus Non-linkage
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Frequency of Recombination
Frequency of recombination is based on percentage of meiotic divisions that result in breakage of linkage between parental alleles
The frequency of recombination between two genes is proportional to the distance between them
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Frequency of Recombination
The correlation between crossover frequency and gene distance is used to construct linkage maps
Figure 5.14
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Linkage MapsA linkage map is a diagram indicating the relative distance
between genes1% recombination = 1 map unit = 1 centiMorgan (cM)Map distances are additive
Figure 5.17
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Linkage Disequilibrium (LD)
Is the non-random association between DNA sequences- Inherited together more often than would be predicted from their frequency
The human genome consists of many “LD” blocks where alleles stick together- These are interspersed with areas where crossing over is prevalent
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Solving Linkage Problems
The genes for Nail-patella syndrome (N) and the ABO blood type (I) are 10 map units apart on chromosome 9
Greg and Susan each have Nail-patella syndrome.
Greg has type A and Susan type B bloodWhat is the probability that their child has
normal nail and knees and type O blood?
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The ni sperm would have to fertilize the ni oocyte
Using the product rule, the probability of a child with nnii genotype is 0.45 x 0.05 = 0.0025 or 2.25%
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Genetic Markers
Are DNA sequences that serve as landmarks near genes of interest
These were used starting in 1980 in linkage mapping
Currently, they are used in genome-wide association studies
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Genetic Markers
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LOD Score
Indicates the “tightness” of linkage between a marker and a gene of interest
It is the likelihood that particular crossover frequency data suggests linkage rather than inheritance by chance
LOD scores of 3 or higher signifies linkage- Observed data are 1,000 times more likely to be due to linkage than chance
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Haplotype
Is the set of DNA sequences inherited on one chromosome due to linkage disequilibrium
Make it possible to track specific chromosome segments in pedigrees
- Disruptions of a marker sequence indicate crossover sites
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Haplotype
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