Inheritabce.pdf

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Patterns of Inheritance and Genetic Concepts
(00:00:25 - 00:02:26)

Genotypes and Phenotypes
Genotype is the genetic code an organism has, including both alleles from each parent
Phenotype is the actual physical appearance or expression of the genotype

Homozygous vs. Heterozygous
Homozygous means having two alleles of the same type
Heterozygous means having two different alleles, typically inherited from different parents

Penetrance and Expressivity
Penetrance is the proportion of individuals who have the phenotype associated with a genotype
Incomplete penetrance is when some individuals with the genotype do not express the phenotype
Expressivity is the extent or intensity to which a given genotype is expressed as the phenotype

Incomplete Dominance vs. Codominance
Incomplete dominance is when two alleles blend together, producing an intermediate phenotype
Codominance is when multiple alleles are expressed independently, without one being dominant

Epistasis
Epistasis is when one gene can suppress the expression of another gene

Pleiotropy vs. Polygenic Inheritance
Pleiotropy is when one gene affects multiple traits
Polygenic inheritance is when multiple genes affect one trait, like height

Proto-oncogenes vs. Tumor Suppressor Genes
Proto-oncogenes are genes that can become cancer-causing oncogenes with a mutation
Tumor suppressor genes have a different mechanism for causing cancer when mutated

Mendel's Laws and Genetic Crosses
(00:00:13 - 00:00:41)

Lesson Overview
1. Patterns of inheritance
2. Mendel's laws and genetic crosses
3. Linked genes
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Mendel's Laws
Mendel's laws describe how traits are passed from parents to offspring

Linked Genes
(00:00:41 - 00:01:21)

Linkage and Crossing Over
Linked genes are genes that are physically close together on the same chromosome
Crossing over during meiosis can separate linked genes into different gametes

Oncogenes and Tumor Suppressors
(00:05:03 - 00:05:24)
RSS is a protein that causes cells to divide
Each person has two copies of the RSS gene, one from each parent
If one of the RSS genes is overactive, it can cause all the cells to start dividing uncontrollably

(00:05:24 - 00:05:34)
Tumor suppressors are things that slow down cell division or induce apoptosis (programmed cell death)
Typically, you need mutations in both copies of a tumor suppressor gene to induce cancer

(00:05:34 - 00:05:52)
If you lose one copy of a tumor suppressor gene, the other copy can still suppress cell division and prevent
tumor formation
But if you lose the other copy, you'll start to have uncontrolled growth

(00:06:07 - 00:06:21)
Haploinsufficiency means that one copy of the wild-type gene is insufficient
Haplosufficency means that one copy of the wild-type gene is sufficient

Mendel's Laws
(00:06:36 - 00:06:46)Mendel's First Law: The Law of Dominance
A dominant allele will mask a recessive allele

(00:06:46 - 00:07:12)
In a heterozygote, the dominant allele will mask the recessive allele
If two heterozygotes are crossed, you can get the recessive phenotype in the offspring

(00:07:12 - 00:07:23)Mendel's Second Law: The Law of Segregation
During gamete formation, homologous gene copies will separate

(00:07:23 - 00:07:52)
Each parent contributes one copy of each gene to the offspring
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The offspring only receives one allele for each trait from the assortment of alleles the parents had

(00:08:02 - 00:08:34)Mendel's Third Law: The Law of Independent Assortment
Alleles of different genes get sorted into gametes independently of each other
This is complicated by the concept of linkage, where genes that are close together on a chromosome are more
likely to be inherited together

(00:08:46 - 00:09:01)Summary of Mendel's Laws:
Law of Dominance: Dominant alleles mask recessive alleles
Law of Segregation: Homologous gene copies segregate during gamete formation
Law of Independent Assortment: Alleles of different genes sort independently into gametes

Non-Disjunction
(00:09:22 - 00:09:35)
Non-disjunction occurs when two chromosomes fail to separate properly during cell division (anaphase)
This can lead to cells with the wrong number of chromosomes

Non-Disjunction and Genetic Disorders
(00:09:45 - 00:09:55)
Normally, chromosomes would separate and form two complete, different nuclei.
In the case of non-disjunction, something fails, such as the spindle or the chromosomes failing to break apart.
This results in a cell ending up with two copies of the same chromosome.

(00:09:55 - 00:10:09)
Non-disjunction can occur in two different places: during meiosis I and meiosis II.
Both result in errors, but the outcomes are different.

(00:10:09 - 00:10:21)
In non-disjunction during meiosis I, the sister chromatids will separate normally, but the chromosomes (copies)
go together and split.
This results in more errors because it's happening earlier in the process.

(00:10:21 - 00:10:36)
In non-disjunction during meiosis II, the sister chromatids don't separate, leading to two copies of the same
allele.
This is different from meiosis I, where the copies could be of different alleles.

(00:10:36 - 00:10:54)
Most questions will just require knowing that non-disjunction can occur during meiosis and usually results in
multiple copies of the same chromosome.
There are some rare cases, like chromosome fragments or fusions, that can also lead to abnormal chromosome
numbers.

(00:10:54 - 00:11:21)
Triploid chromosomes can occur due to non-disjunction or the fusion of a chromosome onto another.
Down syndrome is a result of non-disjunction, typically during meiosis, leading to trisomy 21.
Turner syndrome is caused by having only one X chromosome.
Kleinfelter syndrome is caused by having two X chromosomes and a Y chromosome.
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(00:11:21 - 00:12:00)
Genetic disorders like Down syndrome, Turner syndrome, and Kleinfelter syndrome are caused by having an
abnormal number of chromosomes.
Down syndrome is trisomy 21, Turner syndrome is monosomy X, and Kleinfelter syndrome is XXY.

(00:12:00 - 00:12:37)
Kleinfelter syndrome results in a somewhat typical male, but they often have difficulty conceiving and may
develop breast tissue.
Kleinfelter syndrome is typically discovered when a male is having trouble conceiving with a partner.

(00:12:37 - 00:13:18)
The extra X chromosome in Kleinfelter syndrome significantly reduces the amount of sperm produced, making
it difficult for them to conceive.

(00:13:18 - 00:13:44)
Mnemonic for remembering genetic disorders:
Turner is X chromosome monosomy
Down syndrome is trisomy 21
Kleinfelter is sex chromosome trisomy XXY

(00:13:44 - 00:14:03)
Punnett squares and pedigrees are used to observe the patterns of inheritance for genetic disorders.

Mendel's Laws and Genetic Inheritance
Parental Generation and True Breeding
(00:14:03 - 00:14:23)
The parental generation is the first generation in a genetic cross
True breeding refers to organisms that always produce the same type of offspring, indicating they are
homozygous
True breeding organisms can be either dominant homozygous or recessive homozygous

F1 Generation and Heterozygotes
(00:14:23 - 00:14:50)
Crossing a homozygous dominant and a homozygous recessive true breeding organism results in an F1
generation of all heterozygotes
Heterozygotes have one dominant and one recessive allele

F2 Generation and Phenotypic Ratios
(00:14:50 - 00:15:57)
The F2 generation is the offspring of the F1 heterozygotes
The phenotypic ratio in the F2 generation is:
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1 homozygous dominant: 2 heterozygotes: 1 homozygous recessive

This 1:2:1 ratio is an important concept to memorize

Dihybrid Crosses
(00:16:07 - 00:17:25)
Dihybrid crosses involve the inheritance of two separate genes
The phenotypic ratio in the F2 generation of a dihybrid cross is:
9 with both dominant traits: 3 with one dominant, one recessive: 3 with one recessive, one dominant: 1
with both recessive traits

This 9:3:3:1 ratio should also be memorized

Pedigree Analysis
(00:17:36 - 00:18:18)
Pedigree analysis is used to track the inheritance of autosomal dominant traits
Squares represent males, circles represent females
Affected individuals are typically shown in red or another distinct color

Key Concepts:
True breeding and homozygosity
Phenotypic ratios in F1 (1:0) and F2 (1:2:1) generations
Dihybrid crosses and the 9:3:3:1 phenotypic ratio
Pedigree analysis and representation of affected individuals

(The notes above cover the key information presented in the given video transcript excerpts.)

Heredity and Genetic Inheritance
(00:18:34 - 00:18:58)
Importance of analyzing pedigrees to determine the mode of inheritance of a trait or disease
Genotyping can be used to identify carriers and determine genetic makeup, even without knowing family
history

(00:18:58 - 00:19:10)
This trait is not sex-linked, as both affected and unaffected males and females are present in the pedigree
Sex-linked traits typically only affect males or have a higher prevalence in males

(00:19:10 - 00:19:25)
In sex-linked inheritance, males would only have the disease, and females would be carriers or affected if they
inherited two copies of the disease allele
The presence of both affected and unaffected males and females suggests an autosomal mode of inheritance

(00:19:25 - 00:19:50)
Analyzing the pedigree can help determine the mechanism of inheritance, whether it is autosomal dominant,
autosomal recessive, or sex-linked
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Typically, autosomal dominant traits will have many affected individuals across multiple generations, while
autosomal recessive traits are less common in a pedigree with this many affected individuals

(00:19:50 - 00:20:04)
For an autosomal dominant trait, the affected male in the third generation could be either homozygous
dominant or heterozygous dominant

(00:20:04 - 00:20:32)
Since the father in the second generation is unaffected, he must be homozygous recessive
The mother in the second generation is likely heterozygous dominant, as she has an affected child but is not
affected herself
Therefore, the affected male in the third generation is most likely heterozygous dominant

(00:20:32 - 00:20:46)
The father in the second generation is homozygous recessive (little y, little y)
The mother in the second generation is likely heterozygous dominant (Little Y, little y)

(00:20:46 - 00:20:58)
Considering the genotypes of both parents, the affected male in the third generation is most likely heterozygous
dominant (Little Y, little y)

(00:20:58 - 00:21:14)
Linked genes are genes that are located close to each other on a chromosome
For autosomal dominant linked genes, all offspring with the affected allele will have the disorder

(00:21:14 - 00:21:28)
In the case of X-linked dominant inheritance, the affected allele on the X chromosome will cause the disorder
in both males and females
Individuals with the affected allele will have the disorder, regardless of sex

(00:21:28 - 00:21:54)
X-linked recessive inheritance typically only affects males, as they only have one X chromosome
Females would need to inherit two copies of the affected allele to have the disorder, which is rare in the
population

(00:21:54 - 00:22:15)
Y-linked inheritance is passed from father to son, as the father determines the sex of the offspring by providing
either an X or Y chromosome
Females cannot be affected by Y-linked traits, as they do not inherit the Y chromosome

(00:22:15 - 00:22:30)
The father determines the sex of the offspring by providing either an X or Y chromosome, while the mother
always provides an X chromosome
Mastering the concepts of heredity and genetic inheritance will be crucial for success on the upcoming test

(00:22:30 - 00:22:31)
Congratulations on your progress in understanding these important genetic principles!

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