Mendelian Genetics: Patterns of Inheritance PDF

Summary

This document covers Mendelian genetics, inheritance patterns, and single-gene disorders. It discusses the laws of inheritance and explores various aspects of genetic diseases. Key terms include co-dominance, incomplete dominance, and the different types of single-gene disorders.

Full Transcript

Titu Maiorescu University
Faculty of Dental Medicine
Specialization: Dental Medicine
Genetics, year 2

Mendelian Genetics:

Patterns of Inheritance and Single-Gene Disorders Inheritance Patterns

 Many diseases are caused or influenced by genetics.

 Genes, through the proteins they encode, determine how efficiently foods and chemicals are
metabolized, how effectively toxins are detoxified, and how vigorously infections are targeted.

 Genetic diseases can be categorized into three major groups: single-gene, chromosomal, and
multifactorial.

 Changes in the DNA sequence of single genes, also known as mutations, cause thousands of
diseases.

 A gene can mutate in many ways, resulting in: an altered protein product that is unable to
perform its normal function. The altered protein product may still retain some reduced normal
function, or the protein may be totally disabled by the mutation or gain an entirely new, but
damaging, function.

 The outcome of a particular mutation depends not only on how it alters a protein’s function,
but also on how vital that particular protein is to survival.

 Other mutations, called polymorphisms, are natural variations in DNA sequence that have no
adverse effects and are simply differences among individuals.
 The basic laws of inheritance are useful in understanding patterns of disease transmission.
Titu Maiorescu University
Faculty of Dental Medicine
Specialization: Dental Medicine
Genetics, year 2

 Single-gene diseases are usually inherited in one of several patterns, depending on the location
of the gene (e.g., chromosomes 1-22 or X and Y) and whether one or two normal copies of the
gene are needed for normal protein activity.
 Six basic modes of inheritance for single-gene diseases exist: autosomal dominant, autosomal
recessive, X-linked dominant, X-linked recessive, Y-linked and mitochondrial.
 The way in which traits are passed from one generation to the next-and sometimes skip
generations-was first explained by Gregor Mendel.
 By experimenting with pea plant breeding (Pisum sativum), Mendel developed three principles
of inheritance that described the transmission of genetic traits, before anyone knew genes
existed.

Mendel`s laws of inheritance

1. LAW OF SEGREGATION – alleles segregate, offsprings acquire one allele from each parent;
2. LAW OF DOMINANCE – alleles can be dominant/ recessive;

Domninat traits appear when ≥ one dominant allele is present.

3. LAW OF INDEPENDENT ASSORTMENT – separate genes assort independently.
Les gènes situés sur des chromosomes di érents sont hérités indépendamment les uns des autres. En d’autres termes, la
transmission d’un certain caractère (comme la couleur des yeux) n’in uence pas la transmission d’un autre caractère (comme
Glossary of Terms la taille) si ces caractères sont contrôlés par des gènes situés sur des chromosomes di érents.

HYBRID = offsprings that are the result of mating between two genetically different kind of
parents;

F1 GENERATION = the first offspring (or filial) generation.

MONOHYBRID CROSS = cross between parents differing in only one trait or in which only one
trait is being considered;

DIHYBRID CROSS = cross between parents in which two pairs of contrasting characters are
studied simultaneousley for the inheritance pattern.

LAW OF DOMINANCE

In a cross of parents that are pure for contrasting traits, only one form of the trait will appear in F1
generation. All offsprings will be hybrid for a trait and will have only the dominant trait express the
phenotype. The phenotype trait which is not expressed in the hybrid is called recessive.

LAW OF SEGREGATION

According to this principle, the "particles" (or alleles as we now know them) that determine traits
are separated into gametes during meiosis and meiosis produce equal numbers of egg or sperm cells
that contain each allele.
Titu Maiorescu University
Faculty of Dental Medicine
Specialization: Dental Medicine
Genetics, year 2

Fenotipic ratio: 3:1

Genotipic ratio: 1:2:1

Limitations of Mendel’s Law of Dominance

1. CO-DOMINANCE = the mechanism of dominance seen in some alleles where both alleles of
a gene in a heterozygote lack the dominant and recessive relationship and each allele is capable
of some degree of phenotypic expression (the phenotype will be a blend of the two alleles);

2. INCOMPLETE DOMINANCE = the dominant allele does not entirely overcome the
phenotypic expression of the recessive allele and there occurs an intermediate phenotype in the
Co-dominance : Les deux allèles s’expriment pleinement et séparément
heterozygote.
dans le phénotype, sans mélange.
Dominance incomplète : Les deux allèles contribuent au phénotype,
mais de manière partielle, créant un résultat intermédiaire ou « fusionné ».

LAW OF INDEPENDENT ASSORTMENT

 Mendel observed that, when peas with more than one trait were crossed, the F1 generation did
not always match the parents.

 This is because different traits are inherited independently – this is the principle of independent
assortment.

 He cross-bred pea plants with round, yellow seeds and plants with wrinkled, green seeds. Only
the dominant traits (yellow and round) appeared in the F1 progeny, but all combinations of trait
were seen in the self-pollinated F2 generation.
Titu Maiorescu University
Faculty of Dental Medicine
Specialization: Dental Medicine
Genetics, year 2

 The traits were present in a 9:3:3:1 ratio (round, yellow: round, green: wrinkled, yellow:
wrinkled, green).

Observable Human Characteristics

o Earlobe attachment
o Dimples
o Freckles
o Hairline shape

Autosomal Dominant Single-Gene Diseases

 Examples: Huntington`s disease - a progressive neurodegenerative disorder, myotonic
dystrophy - a progressive muscle atrophy and weakness, familial hypercholesterolemia - it
causes LDL (bad) cholesterol level to be very high, neurofibromatosis - increased risk of
developing tumors, polycystic kidney disease - clusters of cysts grow in the body, mainly in the
kidneys etc.

Autosomal Recessive Single-Gene Diseases

 Examples: phenylketonuria - mutations in the gene that encodes the enzyme phenylalanine
hydroxylase (PAH) - unable to break down the amino acid phenylalanine, cystic fibrosis- causes
severe damage to the lungs, digestive system and other organs in the body - it affects the cells
that produce mucus, sweat and digestive juices, sickle-cell anemia - it affects the shape of red
blood cells - an abnormality in the oxygen-carrying protein haemoglobin found in red blood
cells, occulocutaneous albinism - reduction or complete lack of melanin pigment in the skin,
hair and eyes etc.

X Chromosome–Linked Dominant Single-Gene Diseases

 Examples of X chromosome-linked dominant diseases are rare, but several do exist:
hypophosphatemic rickets - a disorder of bone mineralization, Rett syndrome - a
neurodevelopmental disease; symptoms include impairments in language and coordination, and
repetitive movements. Those affected often have slower growth, difficulty walking, and a
smaller head size.

X Chromosome–Linked Recessive Single-Gene Diseases

 Examples: hemophilia A - hemorrhagic disorder resulting from a congenital deficit of factor
VIII that manifests as protracted and excessive bleeding either spontaneously or secondary to
trauma, Duchenne muscular dystrophy - progressive muscle fiber degeneration and weakness,
red/green colorblindness (daltonism) - the decreased ability to see color or differences in color.
Titu Maiorescu University
Faculty of Dental Medicine
Specialization: Dental Medicine
Genetics, year 2

Y Chromosome–Linked Single-Gene Disease

 It makes no difference whether the Y chromosome-linked mutation is dominant or recessive,
because only one copy of the mutated gene is ever present; thus, the disease-associated
phenotype always shows.

 Examples: hairy ear (auricular hypertrichosis) - excessive hair growth on or in your outer ear,
the part of your ear you can see.

Mitochondrial Single-Gene Disease

 Mitochondrial disorders impair the function of mitochondria; depending on which cells have
fewer or lower-functioning mitochondria, different symptoms may occur.

 Examples: Leber hereditary optic neuropathy (LHON) - form of vision loss (blurring and
clouding of vision), MELAS syndrome - = Mitochondrial Encephalomyopathy with Lactic
Acidosis and Stroke-like episodes - predominantly affects the nervous system and muscles.

CONCLUSIONS

 Gregor Mendel, through his work on pea plants, discovered the fundamental laws of
inheritance.

 He deduced that genes come in pairs and are inherited as distinct units, one from each parent.

 Mendel tracked the segregation of parental genes and their appearance in the offspring as
dominant or recessive traits.