Genetics is the study of heredity and genetic variation. Key terms include:
- Genotype is the genetic makeup of an organism, phenotype is observable traits.
- Genes hold information to build cells and pass traits to offspring. The human genome contains 25,000-35,000 genes located on 23 chromosome pairs in the nucleus.
- DNA is transcribed to RNA and translated to proteins, which determine an organism's traits. Variations in genes and chromosomes can result in genetic disorders. Common methods to study genetics include karyotyping, analyzing pedigrees, and identifying alleles and mutations. Understanding genetics provides insight into inheritance patterns and human health.
2. WHAT IS GENETICS?????
The branch of biology that deals with heredity,
especially the mechanisms of hereditary transmission
and the variation of inherited characteristics among
similar or related organisms
3. Important Terminology
Genotype is the genetic constitution of an organism
or a cell.
Phenotype is the observable physical or biochemical
characteristics of an organism.
4. GENE
Biological unit of heredity.
Gene hold the information to build and maintain
their cells and pass genetic traits to offsprings
In cells, a gene is portion of
DNA
5. Genome
Genome – a term used to refer to all the
genes carried by an individual or cell.
Human genome contains 25000 to 35000
genes.
6. Chromosomes:
Chromatin: DNA, RNA &
proteins that make up
chromosome
Chromatids: one of the two
identical parts of the
chromosome.
Centromere: the point where
two chromatids attach
46 chromosomes. 22 pairs
Autosomes and 1 pair Sex
chromosomes.
7. NUCLEOTIDE: group of molecules that when linked
together, form the building blocks of DNA and RNA;
composed of phosphate group, the bases:
adenosine,cytosine,guanine and thymine and a
pentose sugar. In case of RNA,thymine base is
replaced by uracil.
CODON: series of three adjacent bases in one
polynucleotide chain of a DNA or RNA molecule
which codes for a specific amino acid.
8. Locus
A locus is the specific location of a gene or a DNA sequence
on a chromosome.
eg: Gene at position “11q 23".
Chromosome 11
q- long arm
2- second region
3- 3rd
band
9. Examples:
TNF alpha -308 : (-) Upstream/ Promoter region
IL-1 beta: + 3954 : (+) Downstream/ Coding region
10. Gene is transcribed to RNA
Poly(A) tail added and splicing away intron sequences
RNA transcription product is processed inron functional mRNA
mRNA is transported to cytoplasm
Ribosomes associate with mRNA, mRNA is read and translated into amino acid
sequence of encoded protein which is added to a growing polypeptide chain
The newly synthesized polypeptide chain undergoes posttranslational
modification(folds into a 3d structure and sugar residues or other chemical
groups are added as needed)
Completed protein molecules are then transported to destination sites by specific
targetting amino acid sequences
11.
12. DNA, RNA and protein
synthesis
The process by which DNA is copied to RNA is
called transcription, and that by which RNA is used to
produce proteins is called translation.
13. DNA replication
Each time a cell divides, each of its double strands of
DNA splits into two single strands.
Each of these single strands acts as a template for a
new strand of complementary DNA.
As a result, each new cell has its own complete
genome. This process is known as DNA replication.
Replication is controlled by the Watson-Crick pairing
of the bases in the template strand with incoming
deoxynucleotide triphosphates, and is directed by
DNA polymerase enzymes
14. DNA biosynthesis proceeds in the 5 - to 3 -direction.′ ′
This makes it impossible for DNA polymerases to
synthesize both strands simultaneously. A portion of
the double helix must first unwind, and this is
mediated by helicase enzymes
15. TRANSCRIPTION
Transcription is the process by which DNA is copied
(transcribed) to mRNA, which carries the information
needed for protein synthesis.
Transcription takes place in two broad steps. First, pre-
messenger RNA is formed, with the involvement of RNA
polymerase enzymes.
The process relies on Watson-Crick base pairing, and the
resultant single strand of RNA is the reverse-complement
of the original DNA sequence.
The pre-messenger RNA is then "edited" to produce the
desired mRNA molecule in a process calledRNA splicing
16. Formation of pre-messenger RNA
partial unwinding of the double helix must occur
before transcription can take place, and it is the RNA
polymerase enzymes that catalyze this process
only one strand is transcribed.
The strand that contains the gene is called
the sense strand, while the complementary strand is
the antisense strand.
The mRNA produced in transcription is a copy of the
sense strand
17. Ribonucleotide triphosphates (NTPs) align along the antisense DNA
strand, with Watson-Crick base pairing (A pairs with U). RNA
polymerase joins the ribonucleotides together to form a pre-
messenger RNA molecule that is complementary to a region of the
antisense DNA strand. Transcription ends when the RNA polymerase
enzyme reaches a triplet of bases that is read as a "stop" signal. The
DNA molecule re-winds to re-form the double helix
18. RNA splicing
The pre-messenger RNA thus formed contains
introns which are not required for protein synthesis.
The pre-messenger RNA is chopped up to remove the
introns and create messenger RNA (mRNA) in a
process called RNA splicing
19. Alternative splicing
In alternative splicing, individual exons are either
spliced or included, giving rise to several different
possible mRNA products.
Each mRNA product codes for a different protein
isoform; these protein isoforms differ in their peptide
sequence and therefore their biological activity
Alternative splicing contributes to protein diversity −
a single gene transcript (RNA) can have thousands of
different splicing patterns, and will therefore code for
thousands of different proteins: a diverse proteome is
generated from a relatively limited genome.
20.
21. Reverse transcription
In reverse transcription, RNA is "reverse transcribed"
into DNA.
This process, catalyzed by reverse transcriptase
enzymes, allows retroviruses, including the human
immunodeficiency virus (HIV), to use RNA as their
genetic material.
Reverse transcriptase enzymes have also found
applications in biotechnology, allowing scientists to
convert RNA to DNA for techniques such as PCR.
22. TRANSLATION
The mRNA formed in transcription is transported out
of the nucleus, into the cytoplasm, to the ribosome
(the cell's protein synthesis factory). Here, it directs
protein synthesis
The process by which mRNA directs protein synthesis
with the assistance of tRNA is called translation.
The ribosome is a very large complex of RNA and
protein molecules.
Each three-base stretch of mRNA (triplet) is known
as a codon, and one codon contains the information
for a specific amino acid.
23. As the mRNA passes through the ribosome, each codon
interacts with the anticodon of a specific transfer RNA
(tRNA) molecule by Watson-Crick base pairing.
This tRNA molecule carries an amino acid at its 3 -′
terminus, which is incorporated into the growing protein
chain. The tRNA is then expelled from the ribosome
25. Each amino acid has its own special tRNA (or set of
tRNAs).
Each amino acid is attached to its tRNA through the 3 -′
OH group to form an ester which reacts with the α-amino
group of the terminal amino-acid of the growing protein
chain to form a new amide bond (peptide bond) during
protein synthesis
The reaction of esters with amines is generally favourable
but the rate of reaction is increased greatly in the
ribosome.
Each transfer RNA molecule has a well defined tertiary
structure that is recognized by the enzyme aminoacyl
tRNA synthetase, which adds the correct amino acid to the
3 -end of the uncharged tRNA. The presence of modified′
nucleosides is important in stabilizing the tRNA structure
26. THE GENETIC CODE
It is the basis of the transmission of hereditary
information by nucleic acids in all organisms.
There are four bases in RNA (A,G,C and U), so there are
64 possible triplet codes (43
= 64).
In theory only 22 codes are required: one for each of the
20 naturally occurring amino acids, with the addition of a
start codon and a stop codon (to indicate the beginning
and end of a protein sequence).
Many amino acids have several codes (degeneracy), so that
all 64 possible triplet codes are used
No two amino acids have the same code but amino acids
whose side-chains have similar physical or chemical
properties tend to have similar codon sequences
27.
28. ALLELE
A variant of the DNA sequence at a given locus is
called an allele
Homozygous-an organism in which 2 copies of genes are
identical i.e. have same alleles [AA/ aa]
Heterozygous-an organism which has different alleles of
the gene [Aa]
Do minant alleles are represented with a capitalcapital letter
Recessive alleles are represented with a lo wer caselo wer case letter
Mutation can cause variation in alleles.
29.
30.
31. Definition:
Permanent changes in the
DNA. Those that affect germ cells are
transmitted to the progeny. Mutations
in the somatic cells are not transferred
to the progeny but are important in
the causation of cancer and some
congenital diseases.
33. X – rays & ultraviolet light
Certain viruses such as bacterial virus
34.
35. • Point Mutation:
Substitution of a single
nucleotide base by a
different base.
• Categorized as:
• Transition
• transversion
Missense Mutations.
Nonsense Mutations.
37. Trinucleotide
Repeat Mutations:
set of genetic
disorder caused by
trinucleotide repeat
in certain genes
exceeding
normal,stable
threshold e.g.
Fragile X Syndrome.
38. Classification Of Genetic Diseases:
Single Gene Defects/Mendelian Disorders.
Disorders with Multifactorial or Polygenic
inheritance.
Cytogenetic Disorders.
Disorders showing atypical patterns of inheritance.
39. Mendelian Disorders
A genetic disease caused by a single mutation in the
structure of DNA, which causes a single basic defect
with pathologic consequences
42. Manifested in heterozygous states.
Individuals with these diseases usually have one affected
parent .*
Variable to late onset.
These disorders usually involve non-enzymatic proteins;
• Proteins involved in metabolic pathway regulation.
• Structural Proteins.
43. Inheritance Pattern:
• Typical mating pattern is a
heterozygous affected
individual with a
homozygous unaffected
individual.
•Every child has one chance
in two of having the disease
• Both sexes are affected
equally..
46. Marfan’s Syndrome:
Mutation in the fibrillin gene.
Fibrillin important
component of microfibrils in
Elastin.
Tissues affected are Skeleton,
Eyes and the CVS.
C/F include tall stature, long
fingers, pigeon breast
deformity, hyper-extensible
joints,high arched palate, BL
subluxation of lens, floppy
Mitral valve, Aortic aneurysm
and dissection, defects in
skin,lungs.
47. Ehler-Danlos Syndrome(Cutis Hyperelastica):
Characterized by defects in collagen synthesis.
.Clinical Features include fragile, hyper-extensible skin,
hyper-mobile joints, grotesque contortions, rupture of
internal organs like the colon, cornea and large arteries,
poor wound healing.
48.
49. Defects in metabolic pathway proteins:
Familial Hypercholesterolemia:
• One of the most common mendelian disorders.
• Mutation in the LDL receptor gene.
• Hypercholesterolemia due to impaired LDL transport
into cells.
• Increased risk of atherosclerosis and coronary artery
disease.
• Increases Cholesterol leads to formation of Xanthomas.
50.
51. Largest group of Mendelian Disorders
Affected individuals usually have unaffected (carrier)
parents.
Uniform, early age of onset.
These disorders usually involve Enzymatic Proteins.
52. Pattern Of
Inheritance:
Typical mating pattern is two
heterozygous unaffected (carrier)
individuals.
The trait doesnot usually affect the
parent, but siblings may show the
disease
Siblings have one chance in four of
being affected
Both sexes affected equally.
54. Glycogen Storage Diseases.
Category Disease Enzyme
Hepatic Type. Von Gierke’s
Disease type 1.
Glucose-6-
phosphotase.
Myopathic Type. McArdle Syndrome. Muscle
Phosphorylase.
Miscellaneous Type. Pompe’s Disease
type II
Lysosomal
Glucosidase.
55.
56. Most common X-linked disorders.
Usually expressed only in males.
Rarely, due to random X-inactivation, a female will express
disease, called manifesting heterozygotes.
57. Pattern Of Inheritance:
• Disease usually passed on from
carrier mother.
• Expressed in male offspring,
females are carriers.
• Skipped generations are
commonly seen.
• In this case, Recurrence risk is
half of sons are affected, half of
the daughters are carriers.
58. • Recurrence risk:
• All the daughters
are heterozygous
carriers and all the
sons are homozygous
normal.
60. DISORDERS WITH
MULTIFACTORIAL
(POLYGENIC)INHERITANCE
Involved in many physiologic characteristics of
humans e.g. height, weight, hair color
Defined as one governed by additive effect of two or
more genes of small effect but conditioned by
environmental, non genetic influences
61. The disorder becomes manifested only when a certain
number of effector genes, as well as conditioning
environmental influences are involved
Rate of recurrence is 2 to 7%
65. KARYOTYPING
Basic tool of cytogeneticist
Karyotype is a photographic representation in which
chromosomes are arranged in order of decreasing
length
Giemsa stain (G banding) technique—each
chromosome can be seen to possess a distinctive
pattern of alternating light and dark bands of variable
widths
66. Shorthand of Cytogenetics:
Short arm denoted as p,
long arm denoted q.
Each arm divided into
numbered regions from the
centromere onwards.
Each region numerically
arranged into bands.
For e.g., 5p24 would denote
chromosome 5, short arm,
region 2 and band 4.
67. Cytogenetic disorders may result from
structural or numeric abnormalities of
chromosomes
It may affect autosomes or sex
chromosomes
68. Numeric Abnormalities:
Normal Chromosomal number is 46. (2n=46).
This is called euploid state. (Exact multiple of
haploid number).
Polyploidy: posession of more than two sets of
homologous chromosomes. Chromosomal
numbers like 3n or 4n. (Incompatible with life);
generally results in spontaneous abortion
Aneuploidy: Any Chromosomal number that is
not an exact multiple of haploid number . E.g 47
or 45.
69. Aneuploidy:
Most common cause is nondisjunction of
either a pair of homologous chromosomes
during meiosis I or failure of sister
chromatids to separate during meiosis II.
The resultant gamete will have either one
less chromosome or one extra
chromosome.
70. Fertilization of such gamete will result in
zygote being either trisomic ( 2n+1 ) or
monosomic ( 2n-1 ).
Monosomy in autosomes is incompatible
with life. Trisomy of certain autosomes and
monosomy of sex chromosomes is
compatible with life.
71. Mosaicism:
The presence of two or more types of cell populations in the
same individual.
Postzygotic mitotic nondisjunction will result in one
trisomic and one monosomic daughter cell.
The descendants of these cells will produce a mosaic.
72. Structural Abnormalities:
Usually result from chromosomal breakage, resulting in loss
or rearrangement of genetic material.
Patterns of breakage:
• Translocation.
• Isochromosomes.
• Deletion.
• Inversions.
• Ring Chromosomes.
73. TRANSLOCATION
Transfer of a part of one chromosome to another
chromosome
Translocations are indicated by t
E.g. 46,XX,t(2;5)(q31;p14)
Balanced reciprocal translocation is not harmful to
the carrier, however during gametogenesis, abnormal
gametes are formed, resulting in abnormal zygotes
74. Centric fusion type or robertsonian translocation:
The breaks occur close to the centromere, affecting
the short arms of both choromosomes
Transfer of the chromosome leads to one very large
and one extremely small chromosome
The short fragments are lost, and the carrier has 45
chromosomes
Such loss is compatible with survival
However, during gametogenesis difficulties arise
75.
76. ISOCHROMOSOMES
Result when one arm of a chromosome is lost and the
remaining arm is duplicated, resulting in a
chromosome consisting of two short arms only or of
two long arms.
DELETION
Loss of a portion of chromosome
This can be terminal (close to the end of the
chromosome on the long arm or the short arm), or it
can be interstitial (within the long arm or the short
arm).
A ring chromosome is a variant of deletion.It occurs
when break occurs at both the ends of chromosome
with fusion of the damaged ends.
77. INVERSIONS
Occur when there are two breaks within a single
chromosome with inverted reincorporation of the
segment.
Since there is no loss or gain of chromosomal
material, inversion carriers are normal.
An inversion is paracentric if the inverted segment is
on the long arm or the short arm .
The inversion is pericentric if breaks occur on both
the short arm and the long arm .
78.
79. General Features of Cytogenetic Disorders:
Associated with absence, excess, or
abnormal rearrangements of chromosomes.
Loss of genetic material produces more
severe defects than does gain.
Abormalities of sex chromosomes
generally tolerated better than those of
autosomes.
80. Sex chromosomal abnormalities are
usually subtle and are not detected at
birth.
Most cases are due to de novo
changes (i.e. parents are normal and
recurrence in siblings is low).
81.
82. Trisomy 21/Down’s Syndrome:
Most common chromosomal disorder.
Down syndrome is a chromosomal
abnormality characterized by the
presence of an extra copy of genetic
material on the 21st
chromosome
Trisomy 21 is caused by a meiotic
nondisjunction event.
83. With nondisjunction, a gamete (i.e., a sperm or egg
cell) is produced with an extra copy of chromosome 21;
the gamete thus has 24 chromosomes
When combined with a normal gamete from the other
parent, the embyo now has 47 chromosomes, with
three copies of chromosome 21.
About 4% of cases are due to Robertsonian
translocations.
Maternal age has a strong influence
87. Extreme karyotypic variations seen
frequently with Sex Chromosomes, with
females having 4-5 extra X Chromosomes.
Males with two to three Y chromosomes
have also been identified.
88. Klinefelter’s Syndrome:
Defined as Male Hypogonadism, develops
when there are at least two X
chromosomes and one or more Y
chromosomes.
Usual karyotype is 47,XXY. The extra X
may be maternal or paternal.
89. Results from nondisjunction of sex
chromosome during meiosis.
Risk factors include advanced
maternal age and a history of exposure
to radiation in either parent.
90. Clinical Manifestations:
Increase in body length between soles and pubis.
Reduced facial, body and pubic hair. Gynecomastia.
Testicular atrophy.
Infertility.
Mild mental retardation.
95. REFERENCES
Biology of the Periodontal connective tissues – P.
Mark Bartold A. Sampath Narayanan
Emery’s textbook of genetics
Genetics and molecular biology – Dr. Rober Scliff