1. C HAPT E R 2
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2. INTRODUCTION
• Some of the basic ideas of heredity have been known
since antiquity, but a scientific understanding of how
traits are passed from parent to offspring began with
the Austrian monk Gregor Mendel (1822–84) and his
famous experiments on garden peas. In the early
twentieth century, the importance of Mendel’s work
was realized and chromosomes were first seen with the
microscope. Cytogenetics now uses techniques of
cytology and microscopy to study chromosomes and
their relationship to hereditary traits. Molecular
genetics uses the techniques of biochemistry to study
the structure and function of DNA.
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3. Genes
Genes -located in the nuclei of all cells of the body.
Control heredity from parents to children, control day-
today function of all the body’s cells by determining type
of substances synthesized within the cell.
Gene nucleic acid called deoxyribonucleic acid (DNA).
It controls the formation of another nucleic acid,
ribonucleic acid (RNA).
RNA then spreads throughout the cell to control the
formation of a specific protein.
As there are more than 30,000 different genes in each
cell, it is theoretically possible to form a very large
number of different cellular proteins
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5. Basic Building Blocks of DNA
• Genes/ DNA is a polymer of nucleotides composing:
1. Sugar (deoxyribose),
2. Phosphoric acid,and
3. Four nitrogenous bases
Nitrogenous bases- are grouped into 2 categories.
i. Pyrimidines
- Have a single carbon-nitrogen ring
- Composes three bases: Cytosine (C), Thymine
(T), and Uracil (U).
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6. Cont…
ii. Purines
- Have double carbon-nitrogen rings
- Composes adenine (A) and guanine (G)
• The bases of DNA are C, T, A, and G, whereas the bases of
RNA are C, U, A, and G.
The first stage in the formation of DNA is to combine one
molecule of phosphoric acid, one molecule of deoxyribose,
and one of the four bases to form an acidic nucleotide.
• Four separate nucleotides are thus formed, one for each of
the four bases:
a. Deoxyadenylic,
b. Deoxythymidylic,
c. Deoxyguanylic, and
d. Deoxycytidylic acids.
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7. Cont…
Fig. 2.1 The basic building blocks of DNA.
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8. Cont…
Figure 2–2: Deoxyadenylic acid, one of the nucleotides that make up DNA
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9. Cont…
• The outer covering of the DNA strand is formed
of phosphoric acid & deoxyribose sugar.
• The interior of the strand of DNA is composed
of the bases which connect two strands by
hydrogen bond.
• Each purine base adenine of one strand always
bonds with a pyrimidine base thymine of the
other strand, and
• Each purine base guanine always bonds with a
pyrimidine base cytosine.
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10. Cont…
Figure 2.3- DNA Structure
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11. Cont…
In the above figure , the sequence of complementary pairs
of bases is CG,CG,GC,TA,CG,TA,GC,AT, and AT.
Because of the looseness of the hydrogen bonds, the two
strands can pull apart with ease, and they do so many times
during the course of their function in the cell.
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12. GENETIC CODE
The importance of DNA lies in its ability to
control the formation of proteins in the cell.
It does this by means of the so-called genetic code.
When the two strands of a DNA molecule are split
apart, this exposes the purine and pyrimidine bases
projecting to the side of each DNA strand.
• These projecting bases form the genetic code, that
control the sequence of amino acids in a protein
molecule which is to be synthesized in the cell.
• The spilled DNA strand carries the genetic code.
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13. GENETIC CODE cont…
The spilled DNA template strand will be copied to
RNA.
DNA controls cytoplasmic chemicals through the
process of transferring its code to RNA.
This process of transforming DNA code to RNA
code is called transcription.
The RNA, in turn diffuses from nucleus through
the nuclear pores in to the cytoplasmic
compartment, where it controls protein synthesis.
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15. GENETIC CODE cont…
G G C A G A C T T
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16. SYNTHESIS OF RNA
During synthesis of RNA:
The two strands of the DNA molecule separate
temporarily
One of these strands is used as a template for
synthesis of an RNA molecule
The code triplets in the DNA cause formation of
complementary code triplets called codons in the
RNA;
Codons control the sequence of amino acids in a
protein synthesis in the cell cytoplasm.
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17. Basic Building Blocks of RNA
RNA is a nucleic acid which formed from the polymer
of nucleotide.
The basic building blocks of RNA are almost the same
as those of DNA, except for two differences.
1st – no deoxyribose sugar instead ribose sugar
2nd thymine is replaced by another pyrimidine, uracil.
– Thus RNA nucleotide composed of:
a. Phosphoric acid
b. Ribose sugar &
c. 4 nitrogenous bases ( uracil replaces thymine)
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18. “Activation” of the RNA Nucleotides
• The next step in the synthesis of RNA is
“activation” of the RNA nucleotides by an
enzyme, RNA polymerase.
• This occurs by adding to each nucleotide two
extra phosphate radicals to form triphosphates
• These last two phosphates are combined with
the nucleotide by high-energy phosphate bonds
derived from ATP in the cell.
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20. Types of RNA
There are three different types of RNA.
Each of them plays an independent and entirely different
role in protein formation.
1. Messenger RNA (mRNA)
It carries the genetic code to the cytoplasm for controlling
the type of protein formed.
Their molecules are long, single RNA strands that are
suspended in the cytoplasm.
Composed of several hundred to several thousand RNA
nucleotides in unpaired strands
They contain codons that are exactly complementary to the
code triplets of the DNA genes
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21. Types of RNA cont…
E.g. codons those carried by mRNA are CCG,UCU,
and GAA.
These three are the codons for the amino acids
proline, serine, and glutamic acid respectively.
Codons
mRNA Molecule
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22. Types of RNA cont…
2. Transfer RNA
It transports activated amino acids to the ribosomes
to be used in assembling the protein molecule.
Contains only about 80nucleotides, is a relatively
small molecule in comparison with messenger RNA.
Each type of transfer RNA combines specifically with
1 of the 20 amino acids that are to be incorporated into
proteins.
Each type of transfer RNA combines specifically with
1 of the 20 amino acids that are to be incorporated into
proteins.
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23. Types of RNA cont (tRNA)…
Each specific type of tRNA recognizes a particular
codon on the messenger RNA, in the ribosomes.
This specific code is known as anticodon, which is
again triplet of nucleotides.
Each type of transfer RNA have specificity for a
particular codon in the messenger RNA.
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24. Types of RNA cont (tRNA)…
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25. Types of RNA cont…
3. Ribosomal RNA
Forms ribosomes the physical and chemical
structures on which protein molecules are actually
assembled.
It constitutes about 60 per cent of the ribosome.
The remainder of the ribosome is protein, containing
about 75 types of proteins that are both structural
proteins and enzymes needed in the manufacture of
protein molecules.
The ribosome is the physical structure on which
protein molecules are actually synthesized
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26. Protein Synthesis
When a molecule of messenger RNA comes in
contact with a ribosome, it travels through the
ribosome.
While mRNA travels through the ribosome, a
protein molecule is formed by the process called
Translation.
Translation starting from the sequence of RNA bases
called the “initiation chain” codon.
The formation of protein end (stop) by signal of
chain terminating codons.
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27. Chemical steps of protein synthesis
1. Activation of free amino acid--each amino acid is
activated by a chemical process in which ATP
combines with the amino acid to form an AMP
complex with the amino acid, giving up two
high-energy phosphate bonds in the process.
AA + ATP AA-AMP+2P+
AA-
AMP
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28. Chemical steps cont…
2. Combination of AA with tRNA--The activated
amino acid, having an excess of energy, then
combines with its specific transfer RNA to form
an amino acid–tRNA complex and, at the same
time, releases the adenosine monophosphate.
tRNA
Anticodons
AA-AMP + tRNA AA-tRNA + AMP
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29. Chemical steps cont…
3. Temporary bond b/n tRNA & mRNA-the transfer RNA
carrying the amino acid complex then comes in
contact with the messenger RNA molecule in the
ribosome, where the anticodon of the transfer RNA
attaches temporarily to its specific codon of the
messenger RNA, thus lining up the amino acid in
appropriate sequence to form a protein molecule
Under the influence of the enzyme peptidyl
transferase peptide bonds are formed between the
successive amino acids.
Peptidyl transferase is one of the proteins in the
ribosome.
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30. Chemical steps cont…
Thus peptidyl transferase adding progressively to
the protein chain.
These chemical events require energy from two
additional high-energy phosphate bonds, making
a total of four high-energy bonds used for each
amino acid added to the protein chain.
Thus, the synthesis of proteins is one of the most
energy-consuming processes of the cell.
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31. ….
…
.
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32. 12/3/2012 physiology Note series for midwifes 32
33. Summery of Chemical steps of protein synthesis
1. mRNA leaves the nucleus.
2. Ribosome binds mRNA.
3. tRNA binds an amino acid; binding consumes 1 ATP.
4. tRNA anticodon binds to complementary mRNA codon.
5. The preceding tRNA hands off the growing peptide to the
new tRNA, and the ribosome links the new amino acid to
the peptide.
6. tRNA is released from the ribosome and is available to
pick up a new amino acid and repeat the process.
7. After translating the entire mRNA, ribosome dissociates
into its two subunits.
8. Ribosomal subunits rejoin to repeat the process with the
same or another mRNA.
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35. 12/3/2012 physiology Note series for midwifes 35
36. Control of Gene Function and
Biochemical Activity in Cells
The genes control both the physical and the chemical
functions of the cells.
However, the degree of activation of respective genes
must be controlled as well; otherwise, some parts of the
cell might overgrow or some chemical reactions might
overact until they kill the cell.
Each cell has powerful internal feedback control
mechanisms that keep the various functional operations
of the cell in step with one another.
There are basically two methods by which the
biochemical activities in the cell are controlled.
1. Genetic Regulation &
2. Enzyme Regulation
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37. 1. Genetic Regulation
Synthesis of a cellular biochemical product usually
requires a series of reactions.
Each of these reactions is catalyzed by a special protein
enzyme.
Formation of all the enzymes controlled by a sequence
of genes located one after the other on the same
chromosomal DNA strand.
This area of the DNA strand is called an operon, and the
genes responsible for forming the respective enzymes
are called structural genes.
The control mechanism is required to prevent over or
under action of these enzymes in the process of
synthesis.
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38. Control of the Operon by a “Repressor Protein”
The segment on the DNA strand is called the promoter.
This is a group of nucleotides that has specific affinity
for RNA polymerase.
The promoter is an essential element for activating the
operon.
Additional band of nucleotides lying in the middle of
the promoter is called a repressor operator.
A “regulatory” protein bind to repressor operator and
prevent attachment of RNA polymerase to the promoter,
there by blocking transcription of the genes of this
operon.
Such a negative regulatory protein is called a repressor
protein
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39. Control of the Operon by an “Activator Protein”
Another operator , called the activator operator, that
lies adjacent to but ahead of the promoter.
When a regulatory protein binds to this operator, it
helps attract the RNA polymerase to the promoter, in
this way activates the operon.
Therefore, a regulatory protein of this type is called
an activator protein.
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40. In the above fig. , three respective structural genes are shown
in an operon, and it is demonstrated that they control the
formation of three respective enzymes that in turn cause
synthesis of a specific intracellular product.
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41. Negative Feedback Control of the Operon
The presence of a critical amount of a synthesized
product in the cell can cause negative feedback
inhibition of the operon that is responsible for its
synthesis.
It can do this either by causing :
1. Regulatory repressor protein to bind at the repressor
operator or
2. By causing a regulatory activator protein to break its
bond with the activator operator.
In either of two case, the operon becomes inhibited.
Therefore, once the required synthesized product has
become abundant enough for proper cell function, the
operon becomes dormant.
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42. 2. Enzyme Regulation
This is another means in which cellular biochemical
activities are controlled by intracellular inhibitors or
activators that act directly on specific intracellular
enzymes.
Thus, enzyme regulation represents a second
category of mechanisms by which cellular
biochemical functions can be controlled.
Some chemical substances formed in the cell have
direct feedback effects in the specific enzyme
systems either to inhibit or activate the enzyme.
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43. Cont….
1. Enzyme Inhibition
Enzyme inhibition is another example of negative
feedback control.
It is responsible for controlling intracellular
concentrations of multiple amino acids, purines,
pyrimidines, vitamins, and other substances.
2. Enzyme Activation
Enzymes that are normally inactive often can be
activated when needed.
• An example of this occurs when most of the ATP has
been depleted in a cell, a considerable amount of cyclic
adenosine monophosphate (cAMP) begins to be formed
as a breakdown product of the ATP
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44. Genetic Control of Cell Reproduction
Cell reproduction is another example of the ubiquitous
role that the DNA-genetic system plays in all life
processes.
The genes and their regulatory mechanisms determine
the growth characteristics of the cells and also when or
whether these cells will divide to form new cells.
The period from 1st cell reproduction to the next cell
reproduction is known as the life cycle of a cell.
Life cycle of the cell is terminated by a series of distinct
physical events called mitosis that cause division of the
cell into two new daughter cells.
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45. Cont…
As is true of almost all other important events in the
cell, reproduction begins in the nucleus itself.
The first step is replication (duplication) of all DNA
in the chromosomes.
Only after this has occurred can mitosis take place.
The DNA begins to be duplicated some 5 to 10
hours before mitosis, and this is completed in 4 to 8
hours.
The net result is two exact replicas of all DNA.
These replicas become the DNA in the two new
daughter cells that will be formed at mitosis
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46. Cont…
Cell division is occur in either of two forms:
1. Mitosis – is the actual process by which the cell splits
into two new cells.
- Involved in cell growth, differentiation and repair
- Duplication of chromosomes resulted in two cells
- Take place in all body cells except in sex cells
2. Meiosis
– Occurs only in reproductive cells
– Is process in which oocyte & sperm formed
– Reproduction in number of chromosomes/ the
daughter cells have half of parents cell/haploid/
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47. Stages of cell reproduction. A, B, and C, Prophase. D,
Prometaphase. E, Metaphase. F, Anaphase. G and H, Telophase.
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48. Cell Differentiation
Is special characteristic of cell growth and cell
division
It refers to changes in physical and functional
properties of cells as they proliferate in the embryo
to form the different bodily structures and organs.
Differentiation results not from loss of genes but
from selective repression of different genetic
operons.
The repressed genes never function again.
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49. Cell Death
The total number of cells is regulated not only by
controlling the rate of cell division but also by controlling
the rate of cell death.
Cell death occur either pathologically or naturally.
Pathological cell death called necrosis which is caused due
to occlusion of a blood supply/ or injury to the cell
become swell & rupture.
Natural cell death- when cells are no longer needed or
become a threat to the organism, they undergo a suicidal
programmed cell death, or apoptosis.
This process involves a specific proteolytic cascade that
causes the cell to shrink and condense, to disassemble its
cytoskeleton, and to alter its cell surface so that a
neighboring phagocytic cell, such as a macrophage, can
attach to the cell membrane and digest the cell
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50. Cell Death cont…
Apoptosis is initiated by activation of a family of proteases
called caspases.
These are enzymes that are synthesized and stored in the
cell as inactive procaspases.
A tremendous amount of apoptosis occurs in tissues that are
being remodeled during development.
Even in adult humans, billions of cells die each hour in
tissues such as the intestine and bone marrow and are
replaced by new cells.
Programmed cell death, however, is precisely balanced with
the formation of new cells in healthy adults.
Otherwise, the body’s tissues would shrink or grow
excessively.
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51. Cont…
Abnormalities of apoptosis may play a key role in
neurodegenerative diseases such as Alzheimer’s
disease, as well as in cancer and autoimmune
disorders.
Some drugs that have been used successfully for
chemotherapy appear to induce apoptosis in cancer
cells.
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52. Cancer
Is excessive uncontrolled proliferation of cell
Cancer is caused in all or almost all instances by
mutation or by some other abnormal activation of
cellular genes that control cell growth and cell mitosis.
Cancer refers to malignant type of neoplasm.
The abnormal genes are called oncogenes, as many as
100 different oncogenes have been discovered.
Also present in all cells are antioncogenes, which
suppress the activation of specific oncogenes.
Therefore, loss of or inactivation of antioncogenes can
allow activation of oncogenes that lead to cancer
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53. Cont…
So every body is an a risk to cancer, which result from
unlucky occurrence, even though the probability of
mutation increase due to exposure to certain.
However, the probability of mutations can be increased
many fold when a person is exposed to certain
chemical, physical, or biological factors, including the
following.
1. Ionizing radiation- such as x-rays, gamma rays, and
particle radiation from radioactive substances, and
even ultraviolet light can predispose individuals to
cancer
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54. Cont…
2. Chemical substances- Chemical substances that can
cause mutation are called carcinogens.
e.g. carcinogens from cigarette smokers
3. Physical irritants also can lead to cancer, such as
continued abrasion of the linings of the intestinal
tract by some types of food.
4. In many families, there is a strong hereditary
tendency to cancer
5. Certain type of virus cause some kinds of Ca
e.g. leukemia
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55. Cont…
The major differences between the cancer cell and the
normal cell are the following:
(1) The cancer cell does not respect usual cellular growth
limits; the reason for this is that these cells presumably
do not require all the same growth factors that are
necessary to cause growth of normal cells.
(2) Cancer cells often are far less adhesive to one another
than are normal cells. Therefore, they have a tendency
to wander through the tissues, to enter the blood stream,
and to be transported all through the body, where they
form nidi for numerous new cancerous growths.
(3) Some cancers also produce angiogenic factors that
cause many new blood vessels to grow into the cancer,
thus supplying the nutrients required for cancer growth.
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The genetic code consists of successive “triplets” of bases—that is, each three successive bases is a code word. The successive triplets eventually control the sequence of amino acids in a protein molecule that is to be synthesized in the cell. Note in Figure 3–6 that the top strand of DNA, reading from left to right, has the genetic code GGC, AGA, CTT, the triplets being separated from one another by the arrows. As we follow this genetic code through we see that these three respective triplets are responsible for successive placement of the three amino acids, proline, serine, and glutamic acid, in a newly formed molecule of protein.
DNA Base RNA Baseguanine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . cytosinecytosine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . guanineadenine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . uracilthymine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . adenineThree Different Types of RNA. There are three different types of RNA, each of which plays an independent and entirely different role in protein formation:1. Messenger RNA, which carries the genetic code to the cytoplasm for controlling the type of proteinformed.2. Transfer RNA, which transports activated amino acids to the ribosomes to be used in assembling the protein molecule.3. Ribosomal RNA, which, along with about 75 different proteins, forms ribosomes, the physical and chemical structures on which protein molecules are actually assembled.