Cytogenetics Lecture Notes PDF

Summary

These lecture notes are an introduction to cytogenetics and cover topics like clinical pathology, genetics, and the Big Bang Theory. The notes also discuss the creation story and evolution, as well as specific historical figures in the field.

Full Transcript

CYTOGENETICS
LECTURE: Introduction to Cytogenetics

DR. SARAH DY HINOGUIN-CASIO
PRELIM 1ST SEMESTER – A.Y 2022-2023

INTRODUCTION TO CYTOGENETICS The Big Bang Theory proposes the following:
- The universe began as an extremely hot
Branches of Clinical Pathology and dense dot only a few millimeters
1. Hematology – study of blood wide.
2. Blood Bank – blood transfusion - It since grew over 13.7 billion years into
3. Serology / Immunology – deals with the vast and cooler expanding cosmos
antigen, antibody reactions
4. Microbiology – bacteriology etc. THE CREATION STORY
5. Clinical Microscopy – study of parasites
and the rest of the cells 1st day heaven, Earth, light
6. Clinical Chemistry – chemical testing of all 2nd day firmament
the fluids
3rd day water, dry land, grass,
7. Special Chemistry (CYTOGENETICS)
herb-yielding seed, fruit
Science was confirming that everything in the bible tree
is really true. 4th day sun and moon (two great
lights), stars
GENETICS 5th day water and flying
Genetics creatures
- comes from the word genesis or beginning 6th day land creatures, male and
- From Ancient Greek genetikos (genitive) & female
genesis (origin) 7th day ended and rested. God
- A discipline in biology blessed the seventh day
- The science of heredity and variation in living and sanctified it.
organisms.
Origin & Significance THE EVOLUTION HYPOTHESIS
 An explanation of how the genes came into
being. 1. The fossil known as Java Man, discovered
 Not uncommon to hear people responding in 1891, and that given the name Pekin
to this question with false explanations Man, discovered in 1923, have both been
which have roots in evolution and other non- exposed as false intermediate forms
scientific teaching. 2. A single tooth discovered in 1922 and given
 How it produced different races maybe the name Nebraska Man was
puzzling… subsequently, in 1927, determined to have
belonged to a wild boar
CLINICAL LABORATORY MEDICINE 3. The skull discovered in 1912 and known as
Focused on 2 subspecialties of Genetics: Piltdown Man was exposed as hoax in
 Human Genetics – the study of heredity in 1953, have been placed on display for the
man previous 40 years. Smith Wood
 Medical Genetics – the study of human reconstructed the skull fragments and
genetic variation of medical significance hypothesized that they belonged to a
THE BIG BANG THEORY human.
Georges Lemaitre 4. fossil referred to as Zinjanthropus,
- A Belgian priest who first suggested the Big Bang discovered in 1956, was realized to have
Theory in the 1920s when he theorized that the been just an ordinary ape
universe began from a single primordial atom 5. Ramapithecus discovered in the 1930s
The and exhibited as an intermediate form

ALYSSA JENNIFER S. EGAR
 for the next 50 years, was declassified with  In 1910, Thomas Hunt Morgan, argued
the realization in 1981 that it was just an that genes are on chromosomes based on
ordinary species of baboon observations of a sex-linked white eye
6. Research conducted in 1999-2000 showed mutation in fruit flies.
that Lucy, discovered in Africa in 1974, was  In 1913, his student Alfred Sturtevant used
also invalid the phenomenon in genetic linkage to show
7. When it was realized that the fossil skull that genes are arranged linearly on the
known as the Taung Child, discovered in chromosome
1924, was that of a young gorilla, this was
similarly removed from the list in 1954 CYTOGENETICS

COMPARISON OF THE EVOLUTIONARY  The science that combines the methods
AND CREATIONARY ORIGIN THEORIES and findings of cytology and genetics to
allow the investigation of heredity at the
Creation Hypothesis Evolution Hypothesis cellular level, through careful evaluation of
Intelligent design Ape-like creature the chromosomes.
The cell, in its complexity Darwin himself said that  Mendel established Genetics as a new field
discloses a well-planed, “if the cell were more of science, around 16 years before the
and well-programmed complex that it appears, discovery of chromosomes (1866),
individual & collaborative then, his whole theory is making cytogenetics as one of the oldest
system wrong” fields of genetics.
Consistent in its With missing links
 After the turn of 19th century, the
developmental theory
importance of sex chromosomes was
Death has to be Denies origin in order to
overcome deny death established.
Creator of life takes over Uses genetic studies to  1959 - Cytogenetic studies were first utilized
creature’s sad fate avoid death in clinical laboratory studies, making a
Assigned billions of years instead of days major advancement in clinical diagnosis:
1. The ability to detect changes in
Francisco Ayala chromosome structure,
- “On the basis of only 6.7% heterosity, the 2. Direct correlation of these changes to
average human couple could have 10 children disease & phenotypic anomalies in
before they would have to have one child identical individuals.
to another  Many of tests have become the “gold
standard” for diagnosis
MEDICAL GENETICS
Clinical Fields  There is a growing number of
disease genes being cloned. There
- Clinical Genetics
is increasing emphasis on
- Genetic Counseling
developing molecular direct mutation
analyses.
Laboratory Sciences
- Cytogenetics  These analytical studies work well
- Molecular Genetics when a diagnosis is known or
- Biochemical Genetics suspected.
 In the absence of a known disorder,
MODERN SCIENCE OF GENETICS cytogenetics retains its position as
the only clinical laboratory test to be
 Seeks to understand the process of able to survey genetic cellular
inheritance. constitution of an individual with a
 Began with the work of Gregor Johann single assay.
Mendel, a German-Czech Augustinian  Clinical applications for cytogenetic
monk & scientist (mid-nineteenth century). analysis = range from prenatal
 Mendel “observed that organisms inherit diagnosis to cancer evaluation
traits via discrete units of inheritance, which
are now called genes.”

ALYSSA JENNIFER S.EGAR
 CYTOGENETICS
LECTURE: Cell and Cell Division

DR. SARAH DY HINOGUIN-CASIO
PRELIM 1ST SEMESTER – A.Y 2022-2023

THE CELL

Protoplasm
– the living substance of the cell
- subdivided into 2 compartments:
a) cytoplasm b) karyoplasm
Cytoplasm
– the bulk is water
- suspended & or dissolved therein are
various inorganic & organic chemicals
Cytosol
– the fluid suspension or undissolved
portion in the cytoplasm
- contains organelles
Cytoskeleton
a) microtubules b) microfilaments
- this system maintains the:
a) shapes of cells
b) ability to move
c) intracellular pathways within cell
Organelles
CELLS – basic functional unit of any living thing. - metabolically active cellular structures that
TISSUES - similar cells that are grouped together, execute or perform specific & distinctive
and function to serve a common purpose. functions
Inclusions
Four Basic Tissues: - by-products of metabolism
a) Epithelium c) Muscle - storage forms of:
b) Connective Tissues d) Nervous a) various nutrients
b) inert crystals
These four basic tissues are assembled to form c) pigments
ORGANS. Membranes
- serves as boundary of the cell (cell
Organs are collected into ORGAN SYSTEMS, to membrane)
perform specific task, performing a collection of - partitions the cell into compartments:
associated a) nucleus b) organelles
functions: digestion, reproduction, respiration - made up of phospholipid bilayer
- provides large surface areas for
human body composed of >200 different types biochemical
of cells - reactions essential for maintenance of
life
All cells possess certain unifying & common
characteristics: every cell FUNCTIONS
A. Surrounded by a bilipid plasma membrane CELL MEMBRANE
B. Possesses functioning organelles - also called plasma membrane or
C. Synthesizes macromolecules for its own plasmalemma
use or for export Cell Membrane Functions:
D. Produces energy a) maintaining structural integrity of cell
E. Capable of communicating with other cells.

ALYSSA JENNIFER S.EGAR
b) acts as interface between cytoplasm & external observed only during interphase
milieu because itdissipates during cell
b) controlling movements of substances in & out of division.
the cell (selective permeability) - no more than 2-3 nucleoli in each cell
c) regulating cell-cell interactions - contains only small amount of DNA,
d) recognition (via receptors) of antigens, and which is also inactive
foreign cells as well as altered cells - become hypertrophic in malignancy
- located in the pale-staining fibrillar
Protein Synthetic and Packaging Machinery of center:
the cell: - tips of chromosomes 13, 14, 15, 21, 22
a) ribosomes (in humans), containing the nucleolar-
b) rough endoplasmic reticulum (RER) organizing regions (NORs), where gene
c) Golgi apparatus loci that encode rRNA are located
Smooth Endoplasmic Reticulum:
- abundant only in cells whose active THE CELL CYCLE
functions are: - series of events that prepare the cell for
a) synthesis of steroids dividing into 2 daughter cells
b) synthesis of cholesterol & triglycerides  2 major events:
c) detoxification of toxic materials (alcohol a) interphase = occupies most of the cell’s
&barbiturates) “life”; a longer period of time during which
Lysosomes the cell:
- have an acidic pH & contain hydrolytic b.1) increases its size & content
enzymes b.2) replicates its genetic material
Mitochondria b) mitosis - the short period of time during
- possess their own DNA and perform which the cell divides its nucleus &
oxidative phosphorylation and lipid cytoplasm may last only 10 - 20 hours
synthesis
Cytoskeleton
3 major components:
a) filaments:
thin - cellular movement
intermediate - maintenance of
3-dimensional framework of cell
b) microtubules - act as intracellular pathways
Centrioles
- small cylindrical structures
- composed of 9 microtubule triplets
- usually paired, arranged perpendicular
to each other
- located in the microtubule organizing
center,
known as centrosome
Nucleus Interphase
- largest organelle of the cell - subdivided into 3 phases:
- houses 3 major components: a. G1 (gap) phase
a) chromatin, the genetic material of the - when synthesis of macromolecules
cell essential for DNA duplication begins.
b) nucleolus, center for ribosomal RNA - time when the cells are performing their
(rRNA) synthesis assigned tasks, metabolizing,
c) Nucleoplasm synthesizing, etc.
Nucleolus triggers the cell to begin a cell division event:
- deeply staining a) To replace dead or dying cells,
- non-membrane bound structure b) To produce more cells to enlarge the
organism (growth and development)

ALYSSA JENNIFER S.EGAR
c) Reproduction, i.e., to increase the number
of unicellular organisms.
b. S (synthetic) phase
- when the DNA is duplicated
- therefore, from single stranded DNA in
G1 phase to double stranded DNA in
G2.
c. G2 phase Pro Metaphase
- preparations for mitosis - begins when nuclear envelope
- e.g., tubulin is synthesized, the protein disappear
used to manufacture & microtubules of - microtubules attached to kinetochore,
the spindle apparatus in prophase of called mitotic spindle microtubules
mitosis. - microtubules that do not become
incorporated into spindle apparatus, the
Cells that become highly differentiated after the polar microtubules.
last mitotic event, may cease to undergo - mitotic spindle microtubules assist in
mitosis, leave the cycle to enter the G0 phase migration of the chromosomes so that
(resting stage / outside or stable phase) either: they become oriented into an alignment
a) permanently – neurons, muscles with the mitotic spindle.
b) temporarily – peripheral lymphocytes Metaphase
- begins when newly duplicated
Mitosis (M) chromosomes align themselves on the
- occurs at the conclusion of G2 phase equator of the mitotic spindle –
and thus completes the cell cycle. metaphase plate configuration.
1. Karyokinesis - nuclear division - chromosomes become maximally
2. Cytokinesis - cytoplasmic division condensed
- spindle microtubules attached to the
Mitosis 5 distinct stages: kinetochores
a) prophase d) anaphase
b) prometaphase e) telophase
c) metaphase

Prophase
- chromosomes condensed to become
visible microscopically.
- chromosome consists of 2 parallel
sister chromatids, joined together at 1 Anaphase
point (centromere) - begins when sister chromatids separate
- as chromosomes condense, nucleolus & begin to migrate to opposite poles
disappears spindle – kinetochore attachment site
- centrosome divides, each contains a leads the way with arms of
pair of centrioles & a microtubule- chromosome simple trailing,
organizing center (MTOC) contributing nothing to the migration or
- from each MOTC, the following its pathway.
develop: - as result of shortening of microtubules
a) astral rays – assist in orienting the via depolymerization at the kinetochore
MOTC at the pole end.
b) spindle fibers – assist in directing - Late anaphase – cleavage furrow
the chromosome migration to the pole. begins to form at the plasmalemma.
- at the centromere region of each
chromatid, new MOTC develops,
“kinetochore”
- spindle fibers attach to kinetochore in
preparation for migration

ALYSSA JENNIFER S.EGAR
Telophase - lasts a long time & subdivided into:
- terminal phase of mitosis 1) Leptotene – individual chromosomes,
- characterized by: composed of 2 chromatids joined at
a) cytokinesis – division of cytoplasm into 2 centromere, begin to condense, forming
equal parts long strands in nucleus.
b) reconstitution of the nucleus & nuclear 2) Zygotene – homologous pairs of
envelope chromosomes approximate each other,
c) disappearance of mitotic spindle lining up in register (gene locus to gene
d) unwinding of chromosomes into locus), and make synapses via
chromatin synaptonemal complex, forming a tetrad
e) nucleolus developed from the NORs
(nucleolar organizing region) on each of
the five pairs of chromosomes. 3) Pachytene - chromosomes continue to
condense, becoming thicker and shorter,
chiasmata (crossing over sites) are formed
as random exchange of genetic material
occurs between homologous chromosomes.
4) Diplotene – chromosomes continue to
condense and then begin to separate,
revealing chiasmata.
5) Diakinesis – chromosomes condensed
maximally; nucleolus & nuclear envelope
disappears, freeing the chromosomes.
MEIOSIS
- special type of cell division resulting in the Metaphase I
formation of gametes or germ cells – ova & - homologous chromosomes align as pairs,
spermatozoa. on the equatorial plate of the spindle
- 2 crucial results: apparatus in random order, ensuring a
a) Reduction of chromosomal number from the subsequent reshuffling of maternal &
diploid (2n) to the haploid (1n) number; paternal chromosomes.
ensuring that each gamete carries the Anaphase I
haploid amount of DNA - homologous pairs of chromosomes begin to
& Chromosomes pull apart, & migrate to opposite poles.
b) recombination of genes, ensuring genetic - each chromosome still consists of 2
variability & diversity of the gene pool. chromatids
Telophase I
Two separate events / steps in Meiosis: - similar to Telophase of Mitosis.
a) Meiosis I (Reductional Division)
1) homologous pairs of chromosomes
line up
2) members of each pair separate and
go to opposite poles
3) cell divides
4) daughter cell receives half the
number of chromosomes

In gametogenesis, when the germ cells are in the S
phase of the cell cycle preceding meiosis,
- the amount of DNA is doubled to 4n, and
the chromosome number is also doubled
to 4n.
Prophase I
- the commencement of meiosis, begins after
DNA has been doubled to 4n Two separate events / steps in Meiosis:

ALYSSA JENNIFER S.EGAR
b) Meiosis II (Equatorial Division)
- occurs without DNA synthesis
- proceeds rapidly through four phases &
cytokinesis, to form 4 daughter cells, each
with the haploid chromosome number.

COMPLETE CYCLE

ALYSSA JENNIFER S.EGAR
 CYTOGENETICS
LECTURE: Inheritance

DR. SARAH DY HINOGUIN-CASIO
PRELIM 1ST SEMESTER – A.Y 2022-2023

INHERITANCE d. The two genes for each character segregate
- The patterns governing how genetic during gamete production
information is transmitted from generation to
generation are collectively known as the 3. Law of Independent Assortment
principles of inheritance - Alleles of different genes pass randomly to
- Inheritance is not subtyping offspring
- In the gametes , alleles of one gene
Austrian Monk, creationist Gregor Mendel (father separate independently of those another
of Cytogenetics) gene , and thus all possible combinations of
- Mendel’s Laws (1865) went unnoticed until alleles are equally probable.
35 years later , when they were - The emergence of one trait will not affect
simultaneously and independently the emergence of another
discovered by Hugo De Vries in the - Mendel concluded that each organism
Netherlands , Erich Von Tschermak in carries two copies of its expressed
Austria , and Carl Correns in Germany phenotype. If one differs from the other on
the same phenotype one will inevitably
Mendel’s three laws or Basic Principles of dominate the other.
Heredity: This law was later found to have important
1. Law of Dominance (Unit Inheritance) exceptions: If two genes are very close to each
- Each trait is determined by two factors other on a chromosome, they tend to be passed
(alleles), inherited one from each parent. down together.
Each of these factors exhibit a characteristic
dominant, that are dominant will mask the GENOTYPE
expression of those that are recessive - The genetic make-up of an organism
2. Law of Segregation
- The two alleles of a gene are never PHENOTYPE
transmitted together from one parent to - The external appearance of an organism
an offspring. This means that , in humans , caused by genotype
an individual egg or sperm is form with only
one allele of each gene GENE POOL
- Each of the two inherited factors (alleles) - All of the genes and their alleles present in
possessed by the parent will segregate a population
and pass during meiosis into separate
gamete (eggs or sperm), which will carry GENOME
only one of the factors. - Entire genetic material of an organism

This specific law has four parts, which are: HYBRID
a. Alternative versions of genes, or alleles - Receive different alleles for a trait from each
account for variations in inherited parent
characteristics
b. For each characteristic or trait an organism GENES
inherits two alternative forms of that gene, - Composed of DNA (deoxyribonucleic acid),
one from each parent whose building blocks , the nucleotides ,
c. If the two alleles differ , then one , the code for the multitude of proteins in the
dominant allele , is fully expressed in the human body , including enzymes and
organism’s appearance. The other , the structural proteins
recessive allele has no noticeable effect on
the organism’s appearance.

ALYSSA JENNIFER S.EGAR
 - In 2001 , estimates place the number of
human protein-coding genes between
25,000 and 35,000

GENOTYPE
- Subset of alleles of an individual

PHENOTYPE
- Characteristics of an individual
Female reproductive cell or ovum bringing the
haploid then the other cell comes from the Male
reproductive cell or the father forming a zygote
making an individual who has a mixture of two
alternative alleles

ALLELES
- Different forms of a trait; one form of a gene
- Example of traits: eye color, skin color,
height, hair texture
(most traits are determined by multiple
genes with multiple alleles)
- Examples of alleles: brown or blue , albino In figuring out what the offspring “look-like”
or pigmented , tall or short, curly or straight
1. Dominant
Why are genes and how are they passed along? - the fully expressed gene, has
- Coiled until they become “sausage-like” control on the phenotype
structures called chromosomes - denoted by a capital letter

2. Recessive
- gene is completely masked in the
phenotype
- Locus: location of a specific gene on a - denoted by a lower-case letter
chromosome
- Allele: alternative version of a gene An easier way to figure out what the offspring
“look-like”

1. Punnett Square

ALYSSA JENNIFER S.EGAR
 75% - attached earlobes
25% - unattached earlobes
Proportion: 3:1

Example:
- Mother (Aa) x Father (Aa)
1. What are the genotypes of the a. Genotype
offspring? - Two of the same is called
2. If the dominant gene is attached homozygous
earlobes and the recessive gene - Different is called heterozygous
is unattached earlobes , what
are the phenotype/s of the APPLICATION TO BLOOD TYPES
offspring?
Antigen on surface – gives the person his blood
phenotype
Floating around – antibodies

Group A Group B Group AB Group O
Red Blood A B AB O
Cell Type
Antigens A antigen B antigen A and AB None
in Red antigen
Blood Cell
Antibodies Anti-B Anti-A None Anti-A
in Plasma and
Anti- B

ABO BLOODTYPES:
- O – Recessive
- A, B – dominant
- AB – co-dominant
Genotype Phenotype Antigen Anti-bodies
AO Type A A Anti-B
(Heterozygous A)
AA(Homozygous Type A A Anti-B
A)
BO(Heterozygous Type B B Anti-A
B)
BB(Homozygous Type B B Anti-A
B)
OO Type O - Anti-A &
Anti-B
AB Type AB A&B -

Additional concepts about inheritance that need
to be added to cover other traits:
- A gene on one of the 22 pairs of
autosomes that is, the non-sex-
determining chromosomes – is
called an autosomal gene

ALYSSA JENNIFER S.EGAR
 - Similarly, a trait or disease
associated with that gene is an
autosomal trait
- Autosomal conditions are the most
common and are equally likely to
occur in males or females.
Autosomal traits are further
classified as either dominant or
recessive.
1. Autosomal Dominant Inheritance
- Autosomal Dominant Traits are 5. X-linked recessive inheritance
those in which a single copy of an - Expressed in
allele is enough for the trait to be a. Males (who are necessarily
expressed or shown in the hemizygous for the one gene
phenotype of the animal mutation because they have
- Dominant conditions are those that only one X chromosome ;
are expressed in heterozygotes b. Females who are homozygous
2. Autosomal Recessive Inheritance for the mutation
- Autosomal recessive traits require - Carrier females do not usually
that individual have 2 copies of express phenotype
the trait to express the phenotype 6. Mitochondrial Inheritance
- The genes for autosomal-recessive - Refers to the additional genes in
traits are also located on the cell’s mitochondria
autosomes , but mutant , disease- - Mitochondria are almost exclusively
causing alleles are recessive to the passed from parent to child in the
normal alleles; thus, if one normal egg and not in the sperm , a
allele is present , it is usually hallmark of mitochondrial
sufficient to prevent any expression inheritance is transmission from an
of the disease affected woman to all of her children
3. X-Linked Inheritance
- Females have two X chromosomes
and males have an X and Y (XY)
- Smaller Y chromosomes has only a
very few genes as compared to the
larger X
- Often referred as sex-linked-
inheritance
- A distinguishing feature is the lack
of male-to-male transmission,
because a father transmits only
his Y chromosome, and not his X
to his sons
4. X-linked Dominant Inheritance
- Works differently depending upon
whether the mother or father is the
carrier of a gene that causes
disease or disorder
- All daughters of an affected
father will also be affected but
none of his sons will be affected
(unless the mother is also affected)
- In addition , the mother of an
affected son is also affected (but not
necessarily the other way around)

ALYSSA JENNIFER S.EGAR
 CYTOGENETICS
LECTURE: DNA-RNA

DR. SARAH DY HINOGUIN-CASIO
PRELIM 1ST SEMESTER – A.Y 2022-2023

DNA-RNA the right place, another to get rid of the
protein when it’s done its job, and the list
DEOXYRIBONUCLEICACID (ACID) goes on and on.
Contained in the nucleus - Proteins to be packaged are synthesized on
- Found in every cell of our body and contains the RER surface, whereas proteins
all the information that makes you, “you”. destined for the cytosol are manufactured
- If extracted and stretched out, a person’s within the cytosol.
entire DNA would be enough to get to the - The information for the primary structure of
moon and back 13 times a protein (sequence of amino acids) is
- In each cell there are 46 chromosomes housed in the DNA of the nucleus.
- Tightly coiled DNA form chromosomes
NUCLEUS
- they like to hang around in pairs – you get
half from your mother and half from your
- Contains nearly all of the DNA possessed
by the cell, as well as the mechanisms for
father.
RNA synthesis.
- Chromosomes can be divided into sections
known as genes.
CHROMATIN
- DNA is made up of two (2) strands that stick
- Complex of DNA and proteins
together to make a double helix.
- Represents the relaxed, uncoiled
- The information coming from the DNA is chromosomes of the interphase nucleus.
transcribed into a strand of mRNA
- The sequence of codons of the mRNA Types of Chromatins:
represents the chain of amino acids, in 1) Heterochromatin
which each codon is composed of 3 - Condensed inactive form; visible with light
consecutive nucleotides. microscope
- Periphery of the nucleus
2) Euchromatin
- Lighter, non-visible portions of the nucleus
- Represents the active area, where the
genetic material of the DNA molecules is
being transcribed into RNA
- When euchromatin is examined under the
electron microscope, if unwound, looks like
beads on a string of pearls on a necklace
✓ Beads – nucleosomes
✓ String – DNA molecule: filament with
GENES 2nm in diameter
- are like recipes for the cell (they tell it how
to make proteins)

PROTEIN
- you have a protein to do everything in your
body
- for example, one to make a colored pigment
for your eyes, another to protect that protein
so that it can do its job, another to direct it

ALYSSA JENNIFER S.EGAR
DNA  Each represents a specific segment of the
- Acts as a template for RNA transcription DNA molecule that codes for the synthesis
- Double-stranded polynucleotide chain of a particular protein.
wound into a double helix  The sequential arrangement of bases
- A double helix is established by the constituting the gene represents the
formation of hydrogen bonds between sequence of amino acids of the protein.
complimentary bases on each strand of
DNA molecule GENETIC CODE
- Is designed in such a manner that a triplet
NUCLEOTIDE of consecutive bases – codon – denotes a
- Are linked to one another by particular amino acid.
phosphodiester bonds (a type of covalent - Each amino acid is represented by a
bond) formed between the sugar molecules. different codon
- More or less 100,000 genes & 3 billion
Each nucleotide is composed of: nucleotide bases.
a) A nitrogenous base
b) A deoxyribose sugar [pentose (5 C sugar)]; DEOXYRIBONUCLEIC ACID (ACID)
and - Contained in the nucleus
c) A phosphate molecule - Single-stranded

NITROGENOUS BASES
- The sequence of the 5 – nitrogenous bases,
determines unique structure of DNA and
RNA.
- Nitrogenous base sticks out of the strand
- N-bases connect with another sugar-
phosphate backbone strand
Two (2) types of Bases:
Pyrimidines (6-member ring)
- A pyrimidine always connects to a purine
- Adenine with thymine (A – T) [2 bonds] - they are complementary to each other (5’
end – 3’ end)
- Guanine with cytosine (G – C) [3 hydrogen
bonds]
✓ Cytosine
✓ Thymine (DNA only)
✓ Uracil (RNA only)

Purines (6-member ring + 5 ring)
- Adenine
- Guanine
POLYNUCLEOTIDE
- Formed by bonds between sugar and
phosphate (sugar-phosphate backbone)
GENES
-Biological information that is passed from
one cell generation to the next “units of RIBONUCLEIC ACID (RNA)
heredity” - Like DNA: polynucleotide with nitrogenous
bases sticking out of sugar-phosphate
 Located in specific loci (locus for singular)
backbone strand.
 Located at specific regions on DNA
- RNA exists as a single sugar phosphate
molecule
backbone strand.

ALYSSA JENNIFER S.EGAR
 - Uracil, replaces thymine, and is - A 5s rRNA molecule – synthesized in the
complimentary to adenine nucleus + ribosomal proteins, synthesized
- Sugar is ribose instead of deoxyribose. in the cytoplasm
a. Transported into the nucleolus
b. Associate with 45s rRNA molecule,
Synthesis of the 3 types of RNA is catalyzed by forming a very large ribonucleoprotein
3 different RNA polymerases: particle.
a. Messenger RNA (mRNA) by RNA
polymerase II
b. Transfer RNA (tRNA) by RNA DNA
polymerase III - Acts as template for RNA transcription
c. Ribosomal RNA (rRNA) by RNA
polymerase I

Note: mechanism of transcription is generally
the same for all 3 types of RNA.

Messenger RNA (mRNA)
- Carries the genetic code from the nucleus to
the cytoplasm to act as a template for
protein synthesis
- Each mRNA is a complimentary copy the
region of the DNA molecule that constitute 1
gene
- Consists of a series of codons
- Also has:
a) Start codon (AUG)
b) Stop codons (UAA, UAG, UGA)
- Once formed, transported to cytoplasm and
translated to protein.
Transfer RNA (tRNA)
- Ferries activated amino acids to the
ribosome/mRNA complex, resulting in the
formation of protein
- About 80 nucleotides in length
- Folded upon itself to resemble a cloverleaf
with base pairing between some
nucleotides.
Two (2) significant regions in the tRNA:
a) Anticodon – recognizes the codon of mRNA
b) Amino acid-bearing region – 3’ end of
molecule

RIBOSOMAL RNA (Rrna)
- Forms associations with proteins and
enzymes in the nucleus to form ribosomes
- Synthesized in the fibrillar (pars fibrosa)
region of the nucleolus
- The primary transcript is called 45S rRNA
(pre-RNA), a huge molecule of about
13,000 nucleotides.

ALYSSA JENNIFER S.EGAR
 CYTOGENETICS
LECTURE: DNA Replication

DR. SARAH CASIO
PRELIM 1ST SEMESTER – A.Y 2022-2023

DNA REPLICATION chains, each of them with parts of both
- One major question for the human mind is parent and daughter molecules
how does life continues
- One of the most important mechanisms for  The correct model is the
all life cells to give off springs is semiconservative DNA Replication
undoubtedly the DNA which was proved by the experiment
- Prior to cell division, the DNA material in the of Meselson-Stahl.
original cell must be duplicated so that after
cell division, each new cell contains the full RECAP
amount of DNA material 1. Nucleotides are monomers that are made
- The process of DNA duplication is usually of a phosphate, a sugar (deoxyribose)
called replication and a heterocyclic base (Thymine,
- DNA Replication answers to the question: Cytosine – pyrimidines – Adenine,
“When a cell divides, where does the Guanine-purine)
extra DNA come from?” 2. The combination of a sugar and a
- DNA Replication is the process whereby an heterocyclic base gives a nucleoside.
entire double-stranded DNA is copied to When a phosphate is added to the
produce a second, identical DNA double molecule, a nucleotide is created.
helix 3. The phosphate of a nucleotide binds both
- This is how DNA Replication or DNA to the “5 carbon of one deoxyribose and
Synthesis succeeds. the 3 carbon of next deoxyribose. This is
- Replication of DNA begins at a replication how the nucleotides create the strand.
origin 4. The strands of a DNA double helix are
- Bacterial and viral DNA have only one antiparallel which means that one chain
replication origin, whereas eukaryotic DNA runs in 5’-3’ and the other runs 3’-5’
has many sited where DNA synthesis 5. The two strands are complementary
begins simultaneously  Connection happens between the
- Replication origins are spaced between adenines and thymine (2 hydrogen
30,000 to 300,000 nucleotides from each bond) and between cytosines and
other. guanines (3 hydrogen bond)
6. And thus, each of them can be a matrix
There are three possible models that describe for the creation of a new complementary
the accurate creation of the daughter chains: and antiparallel strand
7. The DNA Double Helix makes a
1. Semiconservative Replication complete turn in over 10 nucleotide
- DNA replication would create two pairs.
molecules. Each of them would be a 8. About 25 hydrogen bonds are created
complex of an old (parental and a daughter in this complete turn.
strand) 9. The power of these 25 bonds is equal to
2. Conservative Replication 1 covalent bond (bond between carbon
- According to this model, the DNA and oxygen)
Replication process would create a brand
new DNA double helix made of two DNA REPLICATION
daughter strands while the parental chains - The original polynucleotide strand of DNA
would stay together. serves as a temple to guide the synthesis of
3. Dispersive Replication the new complementary polynucleotide of
- According to this model the replication DNA
process would create two DNA double-

ALYSSA JENNIFER S.EGAR
 - DNA replication is an intricate process
requiring the concerted action of many
different proteins & several enzymes
- The replication proteins are clustered
together in particular locations in the cell

Enzymes of DNA Replication
1. Helicase – Unwound a portion of the
DNA Double Helix
2. RNA Primase – Attaches RNA primers 2. One of the most important steps of DNA
to the replicating strands Replication is the binding of RNA Primase
3. DNA Polymerase delta (ä) – Binds to in the initiation point of the 3’-5’ parent
the 5’ and 3’ strand in order to bring chain.
nucleotides and create the daughter  RNA Primase can attract RNA
leading strand nucleotides which bind to the DNA
4. DNA Polymerase epsilon (å) – Binds nucleotides of the 3’-5’ strand due to the
to the 3’-5’ strand in order to create hydrogen bonds between the bases
discontinuous segments starting from  RNA nucleotides are the primers for
different RNA primers binding DNA nucleotides
5. Exonuclease (DNA Polymerase I) -
Finds and removes the RNA Primers
6. DNA Ligase – adds phosphate in the
remaining gaps of the phosphate-sugar
backbone
7. Nucleases – remove wrong nucleotides
from the daughter strand

Steps in DNA Replication

3. The elongation process is different for the
5’-3’ and 3’-5’ template
 5’3 template: The 3’-5’ proceeding
daughter strand that uses a 5’-3’
template is called leading strand

Because DNA Polymerase ä can
“read” the template and continuously
adds nucleotides complementary to
the nucleotides of the template

1. The first major step in DNA Synthesis is
the breaking of hydrogen bonds between
bases of the two antiparallel strands
 The splitting happens in places of the
chains which are rich in A-T, because
there are only two hydrogen bonds
 Helicase is the enzyme that splits the
two strands
 The initiation points where the splitting
starts is called “origin of replication”.  3’-5’ template: The 3’-5’ template
The structure that is created is known as cannot be “read” by DNA Polymerase ä
“Replication Fork”  The new strand is called lagging
strand

ALYSSA JENNIFER S.egAR
  In the lagging strand the RNA  So, the end of the parental strand
Primase adds more RNA Primers where the last primer binds isn’t
 DNA Polymerase å reads the replicated.
template and lengthens the bursts.  These ends of linear (chromosomal)
The gap between two RNA DNA consists of noncoding DNA that
primers is call “Okazaki Fragments” contains repeat sequences and are
 The RNA Primers are necessary called telomeres
for DNA Polymerase å to bind  As a result , a part of the telomere is
nucleotides to the 3’ end of them removed in every cycle of DNA
 The daughter strand is elongated Replication
with the binding of more DNA
nucleotides 6. The DNA Replication is not completed
before a mechanism of repair fixes
possible errors caused during
replication
 Enzymes like nucleases remove the
wrong nucleotides and the DNA
Polymerase fills the gaps

4. In the lagging strand, the DNA Pol I –
exonuclease – reads the fragments and
removes the RNA Primers.
 The gaps are closed with the action of
DNA Polymerase (adds complementary
nucleotides to the gaps) and DNA
Ligase (adds phosphate in the Speed of DNA Replication
remaining gaps of the phosphate -sugar
backbone) - The genome of complex eukaryotes is
 Each new double helix is consisted of huge and the process of DNA Replication
one old and one new chain. This is what should be incredibly fast
we call semiconservative replication. - A chromosome of 250 million pair of bases
can be replicated in several hours
- The speed of DNA replication for the
humans is about 50 nucleotides per
second per replication fork
- The human genome can be copied only in a
few hours because many replication forks
take place at the same time (multiple
initiation sites)
- But the speed of DNA replication in bacteria
is much longer (about 1000 nucleotides per
5. The last step of DNA Replication is the second)
Termination - That is a reason why during the process of
 This process happens when the DNA bacterial replication the rate of errors is
Polymerase reaches to an end of the much higher
strand
 In the last section of the lagging
strand, when the RNA Primer is
removed, it is not possible for DNA
Polymerase to seal the gap (because
there is no primer)

ALYSSA JENNIFER S.egAR
ALYSSA JENNIFER S.egAR
 CYTOGENETICS
LECTURE: DNA Transcription

DR. SARAH DY HINOGUIN-CASIO
MIDTERM 1ST SEMESTER – A.Y 2022-2023

DNA TRANSCRIPTION

Proteins are important molecules in
During transcription, a DNA sequence is
organisms because they carry out so many
read by RNA polymerase, which
different jobs, including the production of
produces a complementary, antiparallel
the other molecules.
RNA strand. As opposed to DNA
The information for making proteins is
Replication, transcription results in an
carried in each cell’s DNA, where the
RNA complement that includes uracil(U)
sequence of bases in a gene encodes what
instead of thymine(T).
sequence of amino acids should be joined
to make a protein
The sequence of amino acids joined
together folds into a specific shape, which
allows the protein to carry out its specific - although RNA polymerase performs
job. transcription, the enzyme needs assisting
Protein Synthesis is a two-step process: proteins to help initiate and produces
the transcript
1. Transcription: a temporary copy of - These factors either associate directly with
information in RNA is made using DNA as RNA Polymerase or add in building the
a template actual transcription complex apparatus to
2. Translation: the base sequence of mRNA is help regulate the appropriate transcript
decoded to make a sequence of amino - The general term for such associated
acids proteins are Transcription Factors
 To save energy, transcription and - The stretch of DNA transcribed into an
translation of a particular gene (information RNA molecule is called a transcription
for a protein in DNA) are only carried out unit and encodes at least one gene
when a particular protein is needed. - If the gene transcribed encodes for a
protein, the result of transcription is
messenger RNA (mRNA) which will then
be used to create that protein via the
process of translation
- Alternatively, the transcribed gene may
encode for either ribosomal RNA (rRNA)
or transfer RNA (tRNA) , other
components of the protein-assembly
process, or other ribosomes.
- A DNA Transcription unit encoding for a
protein contains not only the sequence that
will eventually be directly translated into the
protein ( the coding sequence)
TRANSCRIPTION - But also regulatory sequences that
- The synthesis of RNA from a DNA template directly and regulate the synthesis of that
- The process of creating an equivalent RNA protein
copy of a sequence of DNA - The regulatory sequence before
- The first step leading to gene expression (upstream) the coding sequence is called
the coding sequence is called the five
prime untranslated region (5’UTR)

Alyssa Jennifer Egar | MEDICAL LABORATORY SCIENCE
 - The sequence following (downstream) the - RNA polymerase is able to bind to core
coding sequence is called the three prime promoters in the presence of various
untranslated region (3’UTR) specific transcription factors
- As in DNA Replication , DNA is read from - The most common type of core promoter:
3’-5’ during transcription, while the TATA box (short DNA sequence), found -
complementary RNA is created from the 30 base pairs from the start site of
5’-3’ direction transcription
- Although DNA is arranged as two - The TATA box, as a core promoter, is the
antiparallel strands in a double helix , only binding site for a transcription factor known
one of the two DNA Strands, called the as TATA Binding Protein (TBP), which is
template strand , is used for itself a subunit of another transcription
transcription factor, called Transcription Factor IID
- The other DNA strand is called the coding (TFIID).
strand, because its sequence is the same - After TFIID binds to the TATA Box via
as the newly created RNA transcript the TBP, five more transcription factors
(except for the substitution of uracil for and RNS polymerase combine around the
thymine) TATA box in a series of stages to form a
- The use of only the 3’-5’ strand eliminates pre-initiation complex
the need for the Okazaki fragments seen in - One transcription factor, DNA Helicase, is
DNA replication involved in the separation of opposing
strands of double-stranded DNA to provide
Transcription is divided into five stages: access to a single-stranded DNA template.
1. Pre-initiation - However, only a low, or basal, rate of
2. Initiation transcription is driven by the pre-initiation
3. Promoter clearance complex alone
4. Elongation - Other proteins known as activators and
5. Termination repressors, along with any associated
coactivators or corepressors, are
responsible for modulating transcription
rate.

INITIATION

- Binding of the RNA polymerase (RNAP)
and association of the initiation complex to
promoter and enhancer regions on double-
MAJOR STEPS stranded DNA
- RNA polymerase does not directly
PRE-INITIATION recognize the core promoter sequences
- RNA polymerase requires the presence of - Transcription factors mediate the binding
a core promoter sequence in the DNA for of RNA polymerase and the initiation of
the initiation of transcription transcription
- Promoters are found at -30,-75, and -90 - Only after certain transcription factors are
base pairs upstream from the start site of attached to the promoter does the RNA
transcription polymerase bind to it. The completed
- core promoters = sequences within the assembly form the transcription initiation
promoter essential for transcription complex
initiation
 PROMOTER CLEARANCE appropriate RNA editing factors to bind;
- After the first bond is synthesized , the may intrinsic to the RNA polymerase or due
RNA polymerase must clear the promoter to chromatin structure.
- During this time there is a tendency to TERMINATION
release the RNA transcript and produce - Recognition of the transcription
truncated transcripts , abortive initiation. termination sequence and the release of
- Abortive initiation continues to occur until RNA polymerase and the newly formed
the sigma factor rearranges, resulting in RNA polymer.
the transcription elongation
complex(which gives 35 base pairs
moving footprint)
- The sigma factor is released before 80
nucleotides of mRNA are synthesized.
- Once the transcript reaches approximately - Bacteria use two different strategies for
23 nucleotides, it no longer slips and transcription termination
elongation can occur. - In Rho-independent transcription
- This , like most of the remainder of termination, RNA transcription stops when
transcription , is an energy-dependent the newly synthesized RNA molecule forms
process, consuming adenosine a G-C rich hairpin loop followed by a run
triphosphate (ATP) of US, which makes it detach from the DNA
- Process coincides with phosphorylation by template.
TFIIH of serine 5 on the carboxy terminal - In the “RHO-dependent” type of
domain of RNAP. termination, a protein factor called “RHO”
destabilizes the interaction between the
ELONGATION template and the mRNA, thus releasing the
- Covalent addition of ribonucleic bases to newly synthesized mRNA from the
the 3’ end of a growing chain pairing with a elongation complex.
single stranded DNA template. The transcription termination in
- eukaryotes is less understood
but involves cleavage of the
new transcript followed by
template-independent addition
- of As at its new 3’ end, in
- process called
- Using the template strand (or noncoding polyadenylation.
strand) as a template, RNA molecule is
produced from 5’ to 3’, an exact copy of the
coding strand MEASURING AND DETECTING
- Difference: Thymine is replaced with TRANSCRIPTION
Uracil, and the nucleotides are composed - electron micrograph of the ribosomal
of a ribose(5-carbon) sugar where DNA transcription process
has deoxyribose (one less oxygen atom in - the forming of mRNA strands are visible as
its sugar-phosphate backbone) branches from the main DNA strand
- Unlike DNA replication, mRNA transcription
can involve multiple RNA polymerases Transcription can be measured and detected in
on a single DNA template and multiple s variety of ways:
rounds of transcription (amplification of 1. Nuclear Run-on Essay: measures the
particular mRNA), so many mRNA relative abundance of newly formed
molecules can be rapidly produced from a transcripts
single copy of a gene 2. RNase protection assay & Chip-Chip of
- Elongation also involves a proofreading RNAP: detective active transcription sites
mechanism that can replace incorrectly 3. RT-PCR: measures the absolute
incorporated bases – short pause; allow abundance of total or nuclear RNA levels,
 which may however differ from transcription - An associated enzyme, ribonuclease H,
rates digests the RNA strand, and reverse
4. DNA microarrays: measures the relative transcriptase synthesizes a complementary
abundance of the global total or nuclear strand of DNA to form a double helix DNA
RNA levels; however, these may differ from structure
transcription rates - This cDNA is integrated into the host cell’s
5. In Situ Hybridization: detects the genome via another enzyme (integrase)
presence of a transcript causing the host cell to generate viral
6. MS2 tagging: by incorporating RNA stem proteins which reassemble into new viral
loops, such as MS2, into a gene, these particles
become incorporated into newly - Subsequently, the host cell undergoes
synthesized RNA. The stem loops can programmed cell death, apoptosis.
then be detected using a fusion of GFP and - Some eukaryotic cells contain an enzyme
the MS2 coat protein, which has a high with reverse transcription activity called
affinity, sequence specific interaction with telomerase
the MS2 stem loops. The recruitment of - Telomerase is a reverse is a transcriptase
GFP to the site of transcription is visualized that lengthens the ends of a linear
as a single fluorescent spot. chromosomes, and carries and RNA
7. Northern blot: the traditional method, and template from which it synthesizes DNA
until the advent of RNA-sequence, the repeating sequence , or “junk” DNA
most quantitative - This repeated sequence of DNA is
8. RNA-sequence: applies next-generation important because every time a linear
sequencing techniques to sequence whole chromosome is duplicated it is shortened in
transcriptomes, which allows the length.
measurement of relative abundance of - With “junk” DNA at the ends of
RNA , as well as the detection of additional chromosomes, the shortening eliminates
variations such as fusion genes, post- some of the non-essential, repeated
translational edits and novel splice sites sequence rather than the protein-coding
REVERSE TRANSCRIPTION DNA sequence farther away from the
chromosome end.
- Telomerase is often activated in cancer
cells to enable cancer cells to duplicate
their genomes indefinitely without losing
important protein-coding DNA sequence
- Activation of telomerase could be part of
the process that allows cancer cells to
become technically immortal. However, the
true in vivo significance of telomerase has
Scheme of Reverse Transcription still not been empirically proven.
- Some viruses (such as HIV, the cause of
AIDS), have the ability to transcribe RNA
into DNA; main enzyme responsible for
synthesis: reverse transcriptase
- HIV has an RNA genome that is duplicated
into DNA
- The resulting DNA can be merged with the
DNA genome of the host cell
- In the case of HIV, reverse transcriptase is
responsible for synthesizing a
complementary DNA strand (cDNA) to
the viral RNA genome
 CYTOGENETICS
LECTURE: DNA Translation

DR. SARAH DY HINOGUIN-CASIO
MIDTERM 1ST SEMESTER – A.Y 2022-2023

DNA TRANSLATION and it also carries an anticodon. The
- DNA provides the roadmap for making anticodon is the complementary
proteins. The DNA is translated to nucleotides sequence to a given codon.
messenger RNA (mRNA) which in turn - The tRNA will pick up the appropriate
directs the building of the protein, one amino acid the cytoplasm that is coded for
amino acid at a time. by the mRNA codon and to which its
anticodon matches.

In translation the mRNA will run through the
- Translation occurs when the mRNA rRNA from the 5’ end (with A U G) to the
strand moves out of the nucleus and termination codon at the 3’ end.
into the cytoplasm. - The first codon, A U G, will start in the A
- At this point mRNA, rRNA and tRNA all site.
come together. - There, the tRNA with the appropriate
- The rRNA is the factory of translation, while anticodon, U A C, will meet up with the
the tRNA becomes the worker start codon bringing with it the appropriate
amino acid, methionine.

- The rRNA consists of two parts, the large
ribosomal unit and the small ribosomal unit.
On the large ribosomal unit are two sites-
the A site and the P site.
- These will be the sites of polypeptide
synthesis and elongation.

- The tRNA molecules have an amino acid
(the monomer of proteins) attachment site
 Once this is complete, the complex will An example of an mRNA codon chart used to
move over to the P site. determine amino acids.
- The next codon will move in, connect with
its tRNA and appropriate amino acid. The
two amino acids in the rRNA will then form
a peptide bond.
- At this point, the first tRNA will disconnect
from its U A C amino acid and go back into
the cytoplasm.
- The second tRNA with the smell,
elongating polypeptide attached will move
into the P site.
- The third codon will enter the rRNA and the
process will happen again as before.
- This will continue in assembly-line fashion
with the polypeptide chain elongating all
the time until a stop or termination codon
enters the A site.

- At this point the translation will stop and the
completed polypeptide chain will
disconnect to be folded into a complete
protein.
- The rRNA will float off to be used in other
translations and the mRNA in other
transcriptions.

Each amino acid is specified by a sequence of
3 nucleotides, a word in the vocabulary of the
genome:

Amide
Asparagine (Asn, N) = MW: 114.11
Glutamine (Gln, Q) = MW: 128.14
 CYTOGENETICS
LECTURE: Chromosomes

DR. SARAH DY HINOGUIN-CASIO

CHROMOSOMES
- Chromosomes – first observed in tumor cells by
Walther Fleming in 1882, 16 years after
establishment of genetics.
Why in tumor cells?
- Because in tumor the cells here are fast divide
and the mass or tumor is fast growing it’s
because of the multiplying cells. If the cells is
actively dividing it means we could see a lot
active nuclei.
Compare and contrast prokaryotic and
eukaryotic chromosomes.
Eukaryotic chromosomes
EUKARYOTIC CHROMOSOMES
 More than one
- human chromosomes: 46 (44 autosomes; 2
 Linear rather than circular
sex chromosomes)
 Sequestered within a nucleus
 other eukaryotes:
 Composed of DNA and globular
- fruit fly (2x: 8)
proteins (histones)
- kingfisher (2x: 132)
 Nucleosomes (10 nm diameter beads)
- tobacco (4x: 48)
 Chromatic (30 nm diameter). A very thin
- adder’s tongue fern (2x: 1260)
material.
Extranuclear DNA: Eukaryotes
 Active genes- EUCHROMATIN
- Mitochondria, chloroplasts
 Inactive DNA – HETEROCHOMATIN
- DNAs are circular
- Codes for 5% RNA and polypeptides
(nonfunctional) required for the organelle
replication and function
Plasmids
 Fungi and protozoa
- S. cerevisiae – contains 70 copies of a
plasmid (2μm circle)

PROKARYOTIC CHROMOSOMES
- A prokaryotic chromosome consists of a
single molecule of DNA in the form of a
closed loop
E.g.
1. agrobacterium tumefaciens = 1 linear, 1
circular
2. Vibrio cholerae = 2 circular
3. Bacterial – circular molecule of DNA
associated with proteins and RNA
- Located in NUCLEOID
- Folded into loops that are 50,000 – 100,000
bp
 The parts of a chromosomes:
 Telomere – the ends of the chromosomes
 Centromere – the primary constriction of
the chromosomes; it also divides the
chromosome into a short arm (p) and a
long arm (q)
 Chromatid – a single molecule of DNA

PLASMIDS Classification of Chromosomes:
- Small, circular molecules of DNA
- By size and position of centromere.
- Few thousand bp to million bp
- Carries information required for replication, Metacentric – centromere in the
cellular traits middle of the chromosome
Submetacentric – centromere divides
the chromosome into 1/3 and 2/3
Acrocentric – centromere near the end
of the chromosome

 Scientists called cytogeneticists can
Types of Plasmids
recognize and identify many of these gross
1. Fertility (F) factors – chromosomal abnormalities by examining
conjugation, transfer of genes chromosomes through a microscope.
2. Resistance (R) factors – carry
Cytogeneticists use three things to tell
genes for resistance to one or
more antimicrobial drugs, heavy chromosomes apart:
metals or toxins. 1. Chromosome size
3. Bacteriocin factors – carry 2. The position of the centromere
genes for proteinaceous toxins 3. Characteristic banding patterns of
(bacteriocin). alternating light and dark bands (caused by
4. Virulence plasmids staining the chromosomes with dyes).
 combination, allowing the visualization of
the individually colored chromosomes.

DETECTION
In the “classic” (depicted) karyotype, a dye, 3. Digital karyotyping
often Giemsa (G-banding), less frequently - Digital karyotyping is a technique used
Quinacrine, is used to stain bands on the to quantify the DNA copy number on a
chromosomes. genomic scale.
- Giemsa is specific for the phosphate - Short sequences of DNA from specific
groups of DNA. Quinacrine binds to the loci all over the genome are isolated
adenine-thymine rich regions. and enumerated.
- Each chromosome has a characteristic - This is also known as virtual
banding pattern that helps to identify them; karyotyping.
both chromosomes in a pair will have the
same banding pattern.
- Karyotypes are arranged with the short arm
of the chromosome on top, and the long
arm on the bottom.
- The short and long arms are called p and
q, respectively.
- In addition, the differently stained regions
and sub-regions are given numerical
designations from proximal to distal on
the chromosome arms.
- Spectral karyotyping is a molecular
cytogenetic technique used to
simultaneously visualize all the pairs of
chromosomes in an organism in different
colors.
- Fluorescently labeled probes of each
chromosome are made by labeling
chromosome-specific DNA with different
fluorophores.
- Because there are a limited number of
spectrally-distinct fluorophores, a
combinatorial labeling method is used to
generate many different colors.
- Spectral differences generated by
combinatorial labeling are captured and
analyzed by using an interferometer
attached to a fluorescence microscope.
- Image processing software then assigns a
pseudo color to each spectrally different
 CYTOGENETICS
LECTURE: Chromosomes

DR. SARAH DY HINOGUIN-CASIO
SEMI-FINALS

CHROMOSOMES
- Chromosomes – first observed in tumor cells by
Walther Fleming in 1882, 16 years after
establishment of genetics.
Why in tumor cells?
- Because in tumor the cells here are fast divide
and the mass or tumor is fast growing it’s
because of the multiplying cells. If the cells is
actively dividing it means we could see a lot
active nuclei.
Compare and contrast prokaryotic and
eukaryotic chromosomes.
Eukaryotic chromosomes
EUKARYOTIC CHROMOSOMES
 More than one
- human chromosomes: 46 (44 autosomes; 2
 Linear rather than circular
sex chromosomes)
 Sequestered within a nucleus
 other eukaryotes:
 Composed of DNA and globular
- fruit fly (2x: 8)
proteins (histones)
- kingfisher (2x: 132)
 Nucleosomes (10 nm diameter beads)
- tobacco (4x: 48)
 Chromatic (30 nm diameter). A very thin
- adder’s tongue fern (2x: 1260)
material.
Extranuclear DNA: Eukaryotes
 Active genes- EUCHROMATIN
- Mitochondria, chloroplasts
 Inactive DNA – HETEROCHOMATIN
- DNAs are circular
- Codes for 5% RNA and polypeptides
(nonfunctional) required for the organelle
replication and function
Plasmids
 Fungi and protozoa
- S. cerevisiae – contains 70 copies of a
plasmid (2μm circle)

PROKARYOTIC CHROMOSOMES
- A prokaryotic chromosome consists of a
single molecule of DNA in the form of a
closed loop
E.g.
1. agrobacterium tumefaciens = 1 linear, 1
circular
2. Vibrio cholerae = 2 circular
3. Bacterial – circular molecule of DNA
associated with proteins and RNA
- Located in NUCLEOID
- Folded into loops that are 50,000 – 100,000
bp

AJSE
 The parts of a chromosomes:
 Telomere – the ends of the chromosomes
 Centromere – the primary constriction of
the chromosomes; it also divides the
chromosome into a short arm (p) and a
long arm (q)
 Chromatid – a single molecule of DNA

PLASMIDS Classification of Chromosomes:
- Small, circular molecules of DNA
- By size and position of centromere.
- Few thousand bp to million bp
- Carries information required for replication, Metacentric – centromere in the
cellular traits middle of the chromosome
Submetacentric – centromere divides
the chromosome into 1/3 and 2/3
Acrocentric – centromere near the end
of the chromosome

 Scientists called cytogeneticists can
Types of Plasmids
recognize and identify many of these gross
1. Fertility (F) factors – chromosomal abnormalities by examining
conjugation, transfer of genes chromosomes through a microscope.
2. Resistance (R) factors – carry
Cytogeneticists use three things to tell
genes for resistance to one or
more antimicrobial drugs, heavy chromosomes apart:
metals or toxins. 1. Chromosome size
3. Bacteriocin factors – carry 2. The position of the centromere
genes for proteinaceous toxins 3. Characteristic banding patterns of
(bacteriocin). alternating light and dark bands (caused by
4. Virulence plasmids staining the chromosomes with dyes).
 combination, allowing the visualization of
the individually colored chromosomes.

DETECTION
In the “classic” (depicted) karyotype, a dye, 3. Digital karyotyping
often Giemsa (G-banding), less frequently - Digital karyotyping is a technique used
Quinacrine, is used to stain bands on the to quantify the DNA copy number on a
chromosomes. genomic scale.
- Giemsa is specific for the phosphate - Short sequences of DNA from specific
groups of DNA. Quinacrine binds to the loci all over the genome are isolated
adenine-thymine rich regions. and enumerated.
- Each chromosome has a characteristic - This is also known as virtual
banding pattern that helps to identify them; karyotyping.
both chromosomes