Nucleic Acids - 2024/2025 Biochemistry I - University of Babylon PDF

Summary

These notes cover nucleic acid biochemistry for 3rd year Pharmacy students at the University of Babylon during the 2024/2025 academic year. The document contains information about the structure and function of nucleic acids including DNA, RNA and aspects of replication, transcription, and translation

Full Transcript

Republic of Iraq
Ministry of Higher Education and Scientific Research
University of Babylon
College of Pharmacy
Department of Laboratory and Clinical Sciences

Biochemistry I
For
3rd Year Pharmacy Students/ Semester I-2024/2025

Nucleic acid
By

Lec. Dr. Zeyad H. Nafaee 1
 Course Information

 Title of the course: Biochemistry I
 Course number: 314
 Level: 3rd Class, 1st Semester
 Credit hours/week : Theory (Lectures) 3 credits, Practical (Laboratory) 1 credit
 Reference text book : Harper’s Illustrated Biochemistry, 26th Edition
 University of Babylon /College of Pharmacy
 Name of the lecturer: Lecturer Dr. Zeyad Hasan A. Nafaee
 Name of the Lecture: Nucleic acids

Objectives
 To integrate key concepts describing the traditional core topics of Biochemistry: structure and metabolism.
 At the end of the semester, the students should be able to understand;
 Chemical structure, function of all biomolecules present in the living organisms. 2
University of Babylon /College of Pharmacy Nucleic Acid 2024-2025/ Semester I/ 3rd year

Introduction

 Nucleic Acids is polynucleotide molecules
 Polymeric molecule composed of only four types of monomeric units called nucleotide,
 Genetic information(the genetic code) is coded along the length of this polymeric molecule.
 Nucleic acid is Deoxyribonucleic acid (DNA), ribonucleic acid (RNA).
 Basic information pathway is that DNA directs the synthesis of RNA, which in turn directs protein
synthesis.
 DNA Transcription mRNA Translation Protein
 Genes do not function autonomously; their replication and function are controlled by various gene.
products, often in collaboration with components of various signal transduction pathways.

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University of Babylon /College of Pharmacy Nucleic Acid 2024-2025/ Semester I/ 3rd year

 Chemical Properties
 Structures
 Functions
 Building blocks
 Replication
 Transcription
 Translation

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Nucleic Acid
Importance

 Knowledge of the structure and function of nucleic acids is essential in understanding genetics, many aspects of
pathophysiology and the genetic basis of disease.
 In many cases, the resulting double-stranded DNA transcript is integrated into the host genome and subsequently
serves as a template for gene expression and from which new viral RNA genomes can be transcribed.
 Genetic material for some animal and plant viruses is RNA rather than DNA. Although some RNA viruses never
have their information transcribed into a DNA molecule, many animal RNA viruses specifically, the retroviruses (e.g
HIV virus) are transcribed by an RNA-dependent DNA polymerase, the so-called reverse transcriptase, to produce a
double- stranded DNA copy of their RNA genome.
 Synthetic purine and pyrimidine analogs that contain halogens, thiols, or additional nitrogen are employed for
chemotherapy of cancer either by inhibiting an enzyme of nucleotide biosynthesis or by being incorporated into DNA
or RNA and AIDS and as suppressors of the immune response during organ transplantation..

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University of Babylon /College of Pharmacy Nucleic Acid 2024-2025/ Semester I/ 3rd year

Antibiotic target sites

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Reference: Madigan and Martinko, 2006)
University of Babylon /College of Pharmacy Nucleic Acid 2024-2025/ Semester I/ 3rd year

History

 In 1871 Miescher isolated a phosphorous containing material from the cell nucleus.
 He supposed that this „nuclein” is needed for cell division process.
 He predicted that the knowledge of the interactions between the materials from the nucleus, proteins and
their direct metabolic products will gradually enlighten the internal processes of the cells.
 The attention of the researchers towards deoxyribonucleic acids (DNA) was postponed until 1944.
 In 1944 , Avery, MacLeod, and McCarty were first made a series of experiments demonstrating that DNA
contained the genetic information.
 Avery and coworkers discovered that this material (instead of proteins) is responsible for the heredity of
various properties in bacteria.

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University of Babylon /College of Pharmacy Nucleic Acid 2024-2025/ Semester I/ 3rd year

History

 Watson and Crick published the structure of the DNA double helix in 1953 (Nobel-prize in medicine, 1962)
 Rosalind Elsie Franklin was an English chemist and X-ray crystallographer.
 She made contributions to the understanding of the molecular structures of DNA (deoxyribonucleic acid), RNA
(ribonucleic acid), viruses, coal, and graphite.
 Consequently, DNA persists for considerable periods and has been detected even in fossils.

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University of Babylon /College of Pharmacy Nucleic Acid 2024-2025/ Semester I/ 3rd year

Single Strand DNA Single Strand RNA

Pyrimidines Pyrimidines

Purines
Purines

Sugar (ribose)
Sugar (ribose)
Phosphate
Phosphate 9
University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Purines and pyrimidines
 Purines and pyrimidines are nitrogen-containing heterocycles, cyclic compounds whose rings contain both
carbon and other elements (hetero atoms).
 Note that the smaller pyrimidine has the longer name and the larger purine the shorter name and that their
six-atom rings are numbered in opposite directions.
 Planar character of purines and pyrimidines facilitates their close association, or “stacking,” which stabilizes
double-stranded DNA.
 Oxo and amino groups of purines and pyrimidines exhibit keto-enol and amine-imine tautomerism but
physiologic conditions strongly favor the amino and oxo forms.

Tautomerism of the oxo and amino

Note: atoms are numbered according to the international system. 10
University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Purines and pyrimidines

(C) (U) (T)

(A) (G)

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Nucleosides & Nucleotides

 Nucleosides are derivatives of purines and pyrimidines that have a sugar linked to a ring nitrogen.
 Numerals with a prime (eg, 2′ or 3′) distinguish atoms of the sugar from those of the heterocyclic base.
 Sugar in ribonucleosides is D-ribose, and in deoxyribonucleosides it is 2-deoxy-D-ribose.
 Sugar is linked to the heterocyclic base via a -N-glycosidic bond, almost always to N-1 of a pyrimidine or to N-9
of a purine.

 Both syn or anti conformers occur in nature, anti conformers predominate
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University of Babylon /College of Pharmacy Nucleosides & Nucleotides 2024-2025/ Semester I/ 3rd year

 Mononucleotides are nucleosides with a phosphoryl group esterified to a hydroxyl group of the sugar. The 3′- and
5′-nucleotides are nucleosides with a phosphoryl group on the 3′- or 5′-hydroxyl group of the sugar, respectively.
 Nucleotides are the monomer units or building blocks of nucleic acids.
 Since most nucleotides are 5′-, the prefix “5′-” is usually omitted when naming them.
 UMP and dAMP thus represent nucleotides with a phosphoryl group on C-5 of the pentose.
 Additional phosphoryl groups linked by acid anhydride bonds to the phosphoryl group of a mononucleotide form
nucleoside diphosphates and triphosphates.
 Steric hindrance by the base restricts rotation about the β-N-glycosidic bond of nucleosides and nucleotides.

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University of Babylon /College of Pharmacy Nucleosides & Nucleotides 2024-2025/ Semester I/ 3rd year

 Single-letter abbreviations are used to identify adenine (A),
guanine (G), cytosine (C), thymine (T), and uracil (U), whether
free or present in nucleosides or nucleotides. The prefix “d”
(deoxy) indicates that the sugar is 2′-deoxy-D-ribose (eg, dGTP).

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Nucleic acids

 5′-phosphoryl group of a mononucleotide can esterify a second -OH group, forming a phosphodiester. Most
commonly, this second -OH group is the 3′-OH of the pentose of a second nucleotide.
 Most nucleosides contain D-ribose or 2-deoxy-Dribose linked to N-1 of a pyrimidine or to N-9 of a purine by
a β-glycosidic bond whose syn conformers predominate.
 This forms a dinucleotide in which the pentose moieties are linked by a 3′ → 5′ phosphodiester bond to form
the “backbone” of RNA and DNA.
 While formation of a dinucleotide may be represented as the elimination of water between two monomers,
the reaction in fact strongly favors phosphodiester hydrolysis.
 Phosphodiesterase bonds rapidly catalyze the hydrolysis of phosphodiester bonds whose spontaneous
hydrolysis is an extremely slow process.
 RNAs are far less stable than DNA since the 2′-hydroxyl group of RNA (absent from DNA) functions as a
nucleophile during hydrolysis of the 3′,5′-phosphodiester bond.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year

 (A) nucleotides equals that of thymidine (T) nucleotides (A = T), while the concentration of deoxyguanosine (G)
nucleotides equals that of deoxycytidine (C) nucleotides (G = C), led Watson, Crick, and Wilkins to propose in
the early 1950s a model of a double- stranded DNA molecule.
 Two strands of this double-stranded helix are held in register by hydrogen bonds between the purine and
pyrimidine bases of the respective linear molecules.
 Pairings between the purine and pyrimidine nucleotides on the opposite strands are very specific and are
dependent upon hydrogen bonding of A with T and G with C.
 Phosphodiester bond is represented by P or p, bases by a single letter, and pentoses by a vertical line.
 Where all the phosphodiester bonds are 5′ → 3′, a more compact notation is possible: pGpGpApTpCpA
 Representation indicates that the 5′-hydroxyl— but not the 3′-hydroxyl—is phosphorylated.
 Most compact representation shows only the base sequence with the 5′- end on the left and the 3′- end on the
right. The phosphoryl groups are assumed but not shown: GGATCA

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University of Babylon /College of Pharmacy DNA 2024-2025/ Semester I/ 3rd year

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Chemical structure of Nucleic acids

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Exercise

Q/ Give the complement strand of the following DNA strands?
1/ 5′ AGTTCTGTTCCAGGCC 3′
2/ 3′ TTTTTTGCGGCAT 5′
3/ 3′ ATACACTATTCTCAG 5′

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
DNA
 DNA consists of four bases A, G, C, and T which are held in linear array by phosphodiester bonds through the 3′
and 5′ positions of adjacent deoxyribose moieties.
 These strands form a double helix around a central axis.
 The 3 × 109 base pairs of DNA in humans are organized into the haploid complement of 23 chromosomes.
 The exact sequence of these 3 billion nucleotides defines the uniqueness of each individual.
 DNA provides a template for its own replication and thus maintenance of the genotype and for the transcription of
the 30,000–50,000 genes into a variety of RNA molecules.
 If a distance between two nucleotides was 1 mm, then the length of the entire human genome would be ~ 3200
kms.
 Length of an average gene would be ~300 m, while that of the coding sequence ~ 1 m.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Nucleic Acid

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
DNA Conformations

 Common form of DNA is right handed because as one looks down the double helix the base residues form a spiral
in a clockwise direction.
 Two strands of the double-helical molecule, each of which possesses a polarity, are antiparallel; ie, one strand runs
in the 5′ to 3′ direction and the other in the 3′ to 5′ direction.
 Opposite strand is considered the coding strand because it matches the RNA transcript that encodes the protein.
 The two strands, in which opposing bases are held together by hydrogen bonds, wind around a central axis in the
form of a double helix.
 Double-stranded DNA exists in at least six forms (A–E and Z).
 B form is usually found under physiologic conditions (low salt, high degree of hydration). A single turn of B-DNA
about the axis of the molecule contains ten base pairs.
 Distance spanned by one turn of B-DNA is 3.4 nm.
 Width (helical diameter) of the double helix in B-DNA is 2 nm.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
DNA Conformations
 B-DNA double helix is built up from two antiparallel, complementary strands by Watson-Crick type base pairing.
Further DNA structures, such as the A- or Z-DNA are also known.
 Base pairing (hybridization): A-T, two hydrogen bonds G-C, three hydrogen bonds

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University of Babylon /College of Pharmacy DNA 2024-2025/ Semester I/ 3rd year

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University of Babylon /College of Pharmacy RNA 2024-2025/ Semester I/ 3rd year

 Ribonucleic acid (RNA) is a polymer of purine and pyrimidine ribonucleotides linked together by 3′,5′-
phosphodiester bridges analogous to those in DNA.
 Information within the single strand of RNA is contained in its sequence (“primary structure”) of purine and
pyrimidine nucleotides within the polymer.
 Sequence is complementary to the template strand of the gene from which it was transcribed.
 Because of this complementarity, an RNA molecule can bind specifically via the base-pairing rules to its template
DNA strand; it will not bind (“hybridize”) with the other (coding) strand of its gene.
 The sequence of the RNA molecule (except for U replacing T) is the same as that of the coding strand of the gene.
 Nearly all of the several species of RNA are involved in some aspect of protein synthesis.
 In eukaryotic cells, including mammalian cells, is degraded within the nucleus, and it never serves as either a
structural or an informational entity within the cellular cytoplasm.

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University of Babylon /College of Pharmacy RNA Structure 2024-2025/ Semester I/ 3rd year

 RNA exists in several different single-stranded structures, most of which are involved in protein synthesis.
 The linear array of nucleotides in RNA consists of A, G, C, and U, and the sugar moiety is ribose.
 RNA is organized in several unique structures
 Diagrammatic representation of the secondary structure of a single-stranded RNA molecule in which a stem loop,
or “hairpin,” has been formed and is dependent upon the intramolecular base pairing.
 Note that A forms hydrogen bonds with U in RNA.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Types of RNAs

 In all prokaryotic and eukaryotic organisms, three main classes of RNA molecules exist:
 messenger RNA (mRNA), transfer RNA (tRNA), and ribosomal RNA(rRNA).
 Each differs from the others by size, function, and general stability.
 ribosomal RNAs; rRNAs have structural roles wherein they con-tribute to the formation and function of ribosomes
(the organellar machinery for protein synthesis) or serve as adapter molecules
 transfer RNAs; tRNAs for the translation of RNA information into specific sequences of polymerized amino acids.
 Some RNA molecules have intrinsic catalytic activity.
 The activity of these ribozymes often involves the cleavage of a nucleic acid.
 Those cytoplasmic RNA molecules that serve as templates for protein synthesis (ie, that transfer genetic
information from DNA to the protein-synthesizing machinery) are designated messenger RNAs, or mRNAs.
 In all eukaryotic cells there are small nuclear RNA (snRNA) species that are not directly involved in protein
synthesis but play pivotal roles in RNA processing.These relatively small molecules vary in size from 90 to about
300 nucleotides.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year

Chemical Properties of Nucleic acids

 Nucleic acids depicted possesses a polarity; one end has a 5′-hydroxyl or phosphate terminal while the other has a
3′-phosphate or hydroxyl terminal.
 Nucleosides or free purine or pyrimidine bases are uncharged at physiologic pH. By contrast, the primary
phosphoryl groups (pK about 1.0) and secondary phosphoryl groups (pK about 6.2) of nucleotides ensure that they
bear a negative charge at physiologic pH.
 Nucleotides can act as proton donors or acceptors at pH values two or more units above or below neutrality.
 Conjugated double bonds of purine and pyrimidine derivatives absorb ultraviolet light.
 Mutagenic effect of ultraviolet light results from its absorption by nucleotides in DNA with accompanying chemical
changes.
 Abs. spectra are pH-dependent, at pH 7.0 all the common nucleotides absorb light at a wavelength close to 260
nm.
 The concentration of nucleotides and nucleic acids thus often is expressed in terms of “absorbance at 260 nm.”

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Exercise

Ex/ Draw the structures of the dTTP and the ADP from the bellow structures showing the bonds
between the new connected molecules.

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University of Babylon /College of Pharmacy Nucleosides & Nucleotides 2024-2025/ Semester I/ 3rd year

Nucleotides serve multiple additional functions

 They form a part of many coenzymes and serve as donors of phosphoryl groups (eg, ATP or GTP), of sugars (eg,
UDP- or GDP-sugars), or of lipid (eg, CDP-acylglycerol).
 Regulatory nucleotides include the second messengers cAMP and cGMP, the control by ADP of oxidative
phosphorylation, and allosteric regulation of enzyme activity by ATP, AMP, and CTP.
 Synthetic purine and pyrimidine analogs that contain halogens, thiols, or additional nitrogen are employed for
chemotherapy of cancer and AIDS and as suppressors of the immune response during organ transplantation.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Additional purines and pyrimidines

 Small quantities of additional purines and pyrimidines occur in DNA and RNAs.
 Examples include 5-methylcytosine of bacterial and human DNA, 5-hydroxymethylcytosine of bacterial and
viral nucleic acids, and mono- and di-N-methylated adenine and guanine of mammalian messenger RNAs
These atypical bases function in oligonucleotide recognition and in regulating the half-lives of RNAs.
 Free nucleotides include hypoxanthine, xanthine, and uric acid intermediates in the catabolism of adenine
and guanine.
 Methylated heterocyclic bases of plants include the xanthine derivatives caffeine of coffee, theophylline of tea,
and theobromine of cocoa.
 Posttranslational modification of preformed polynucleotides can generate additional bases such as
pseudouridine, in which D-ribose is linked to C-5 of uracil by a carbon-to-carbon bond rather than by a β-N-
glycosidic bond.
 Nucleotide pseudouridylic acid Ψ arises by rearrangement of UMP of a preformed tRNA.
 Similarly, methylation by S-adenosylmethionine of a UMP of preformed tRNA forms TMP (thymidine
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monophosphate), which contains ribose rather than deoxyribose.
University of Babylon /College of Pharmacy Nucleic Acid 2024-2025/ Semester I/ 3rd year

 Nucleic acids contain, in addition to A, G, C, T, and U, traces of 5-methylcytosine, 5-hydroxymethylcytosine,
pseudouridine (Ψ), or N-methylated bases.
 A primed numeral locates the position of the phosphate on the sugars of mononucleotides (eg, 3′- GMP, 5′-dCMP).
Additional phosphoryl groups linked to the first by acid anhydride bonds form nucleoside diphosphates and
triphosphates.
 Nucleoside triphosphates have high group transfer potential and participate in covalent bond syntheses.
 Mononucleotides linked by 3′ → 5′-phosphodiester bonds form polynucleotides, directional macromolecules with
distinct 3′- and 5′- ends.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year

Additional purines and pyrimidines

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year

Synthetic nucleotide analogs used in chemotherapy

 Synthetic analogs of purines, pyrimidines, nucleosides, and nucleotides altered in either the heterocyclic ring or
the sugar moiety have numerous applications in clinical medicine.
 Their toxic effects reflect either inhibition of enzymes essential for nucleic acid synthesis or their incorporation
into nucleic acids with resulting disruption of base-pairing.
 Oncologists employ 5-fluoro- or 5- iodouracil, 3-deoxyuridine, 6-thioguanine and 6-mercaptopurine, 5- or 6-
azauridine, 5- or 6-azacytidine, and 8-azaguanine which are incorporated into DNA prior to cell division.
 Purine analog allopurinol, used in treatment of hyperuricemia and gout, inhibits purine biosynthesis and xanthine
oxidase activity.
 Cytarabine is used in chemotherapy of cancer.
 Azathioprine, which is catabolized to 6-mercaptopurine, is employed during organ transplantation to suppress
immunologic rejection.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year

Synthetic nucleotide analogs used in chemotherapy

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Nucleotides Serve Diverse Physiologic Functions
 Nucleotides participate in reactions that fulfill physiologic functions as diverse as protein synthesis, nucleic acid
synthesis, regulatory cascades, and signal transduction pathways.
 Acid anhydrides, unlike phosphate esters, have high group transfer potential.
 ΔG for the hydrolysis of each of the terminal phosphates of nucleoside triphosphates is about −7 kcal/mol (−30
kJ/mol).
 High group transfer potential of purine and pyrimidine nucleoside triphosphates permits them to function as group
transfer reagents.
 Cleavage of an acid anhydride bond typically is coupled with a highly endergonic process such as covalent bond
synthesis eg, polymerization of nucleoside triphosphates to form a nucleic acid.
 In addition to their roles as precursors of nucleic acids, ATP, GTP, UTP, CTP, and their derivatives each serve unique
physiologic functions discussed in other chapters. For examples include:
i. Role of ATP as the principal biologic transducer of free energy.
ii. Second messenger cAMP.
iii. Adenosine 3′-phosphate-5′-phosphosulfate, sulfate donor for sulfated proteoglycans and for sulfate conjugates of
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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Denaturation (Melting) of DNA

 Double-stranded structure of DNA can be separated into two component strands (melted) in solution by
increasing the temperature or decreasing the salt concentration.
 Not only do the two stacks of bases pull apart but the bases themselves unstack while still connected in the
polymer by the phosphodiester backbone.
 Concomitant with this denaturation of the DNA molecule is an increase in the optical absorbance of the purine
and pyrimidine bases a phenomenon referred to as hyperchromicity of denaturation.
 Because of the stacking of the bases and the hydrogen bonding between the stacks, the double-stranded DNA
molecule exhibits properties of a rigid rod and in solution is a viscous material that loses its viscosity upon
denaturation.
 Strands of a given molecule of DNA separate over a temperature range. The midpoint is called the melting
temperature, or Tm. The Tm is influenced by the base composition of the DNA and by the salt concentration of
the solution.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Denaturation (Melting) of DNA

 DNA rich in G–C pairs, which have three hydrogen bonds, melts at a higher temperature than that rich in A–T
pairs, which have two hydrogen bonds. G–C bonds are much more resistant to denaturation, or “melting,” than
A–T-rich regions.
 A tenfold increase of monovalent cation concentration increases the Tm by 16.6 °C.
 Formamide, which is commonly used in recombinant DNA experiments, destabilizes hydrogen bonding between
bases, thereby lowering the Tm.
 This allows the strands of DNA or DNA-RNA hybrids to be separated at much lower temperatures and minimizes
the phosphodiester bond breakage that occurs at high temperatures.

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University of Babylon /College of Pharmacy Differences between DNA, and RNA 2024-2025/ Semester I/ 3rd year

 Sugar moiety to which the phosphates and purine and pyrimidine bases are attached, in RNA is ribose, while in
DNA is 2′-deoxyribose.
 Pyrimidine components of RNA differ from those of DNA; (i) RNA contains the ribonucleotides of A, G, C, and U,
while (ii) DNA contains the ribonucleotides of A, G, C, and T.
 RNA exists as a single strand, whereas DNA exists as a double-stranded helical molecule (complementary base
sequence with opposite polarity). However, single strand of RNA is capable of folding back on itself like a hairpin
and thus acquiring double stranded characteristics.
 Since the RNA molecule is a single strand complementary to only one of the two strands of a gene, its guanine
content does not necessarily equal its cytosine content, nor does its adenine content necessarily equal its uracil
content.
 RNA can be hydrolyzed by alkali to 2′,3′ cyclic diesters of the mononucleotides, compounds that cannot be
formed from alkali-treated DNA because of the absence of a 2′-hydroxyl group.
 Alkali lability of RNA is useful both diagnostically and analytically.

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University of Babylon /College of Pharmacy Replication 2024-2025/ Semester I/ 3rd year

 DNA replication is the process by which the genome's DNA
is copied in cells. Before a cell divides, it must first copy (or
replicate) its entire genome so that each resulting daughter
cell ends up with its own complete genome.
 These events are divided into four major stages: initiation,
unwinding, primer synthesis, and elongation.

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Replication

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University of Babylon /College of Pharmacy
PCR 2024-2025/ Semester I/ 3rd year

 Polymerase chain reaction (abbreviated PCR) is a laboratory technique for rapidly producing (amplifying) millions
to billions of copies of a specific segment of DNA, which can then be studied in greater detail.
 PCR involves using short synthetic DNA fragments called primers to select a segment of the genome to be
amplified, and then multiple rounds of DNA synthesis to amplify that segment.
 The reaction consists of cycles, each of which can be divided into three steps:
1. The separation of the two strands of the double stranded template dsDNA (denaturation, 94–97 °C).
2. The primers hybridize to the template strands at their complementary sequences (annealing, 50–70 °C), and by
this the multipliable section is determined.
3. The DNA polymerase builds up the new strands using the dNTP building blocks (extention, 72 °C).

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
PCR

Substances required for PCR:
 A double-stranded DNA template (e.g. from the studied cell).
 The synthetic oligonucleotide primers in excess amounts. By hybrdization to their complementary sequences,
they will determine the termini of the newly synthesized DNA section.
 DNA „building blocks” - dNTP-s (dCTP, dATP, dGTP and dTTP ) in equal amounts.
 A buffer and Mg(II) ions to ensure the optimal reaction conditions.
 Heat-stable DNA polymerase (the Taq polymerase DNA synthesizing enzyme originates from the Thermus
aquaticus bacteria that live in thermal water).
 There are about 37 types of PCR, The common PCR types are Real-Time PCR (Quantitative PCR (qPCR));
Repetitive sequence-based PCR; Reverse Transcriptase PCR (RT-PCR); Reverse-Transcriptase Real-Time PCR
(RT-qPCR)

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Transcription
 DNA transcription produces a single-stranded RNA molecule that is
complementary to one strand of DNA.
 Transcription is performed by enzymes called RNA polymerases,
which link nucleotides to form an RNA strand (using a DNA strand
as a template).

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 Transcription has three stages: initiation, elongation, and termination
University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Translation

 Translation is the way genetic code contained in mRNA is
decoded to produce a specific sequence of amino acids in a
polypeptide chain.
 In this process, the ribosome translates the mRNA produced
from DNA into a chain of specific amino acids.
 This chain of amino acids leads to protein synthesis

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Translation

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University of Babylon /College of Pharmacy 2024-2025/ Semester I/ 3rd year
Exercise

Q/ transcript and translate the following DNA strand using the table of the codon in the lecture?
1/ 5′ ATGTATTCTCCGCTCTGTCTCACCCAGGATTGA 3′
2/ 3′ TACTGCCACTTTTGGAGACTGTGTACGTCGAGGACC 5′

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