Lecture 3 DNA RNA Gen Structure Ade FKUI 2012
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Transcript of Lecture 3 DNA RNA Gen Structure Ade FKUI 2012
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Lecture 3Nucleic acid and Gene Structure
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Biomolecules
Many biomolecules are synthesized from smallermolecules. Such molecules are called polymers.
They include:• DNA and RNA both polymers of nucleotides• Proteins are polymers of amino acids• Polysaccharides are polymers of sugars.
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Polymers and Monomers
monomer polymercategory of
biomolecules
monosaccharides polysaccharides carbohydrates
amino acids polypeptides proteins
nucleotides polynucleic acids RNA & DNA
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Hyd
roly
sis–
Pol
ymer
Bre
akdo
wn
+ Energy
Enzymes are employed in biological systems to effect most hydrolysis reactions
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R
D
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In 1860, F. Meischer a Swiss physician isolated a precipitate substance obtained by treatment of white blood cells nuclei, with alkaline solution. The chemical analysis has showed that this precipitate contained Carbon, Nitrogen, Hydrogen, Oxygen and Phosphorus. Meischer called this substance Nuclein.
In 1930 A. Kossel and P. Levene proved that Nuclein was a deoxyribonucleic acid.
In the late 1940's, E. Chargaff discovered the "equimolarity" of bases ([A]=[T], [G]=[C]) and established the coefficient of specificity ((G+C)/(A+T)), which characterise each DNA molecule.
In 1952, Hershey & Chase demonstrated that DNA molecules are the universal support of heridity.
In 1953 J. Watson & S. Crick determined the double helix structure of DNA, owing to the important Xray diffraction works made by R. Franklin. In 1962 Watson, Crick & M. Wilkins were awarded the Nobel Prize for their discovery.
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Nitrogen Bases
The nitrogen bases in nucleic acids consist of the:
• Pyrimidines: C U T
• purines : G A
CHCH
Uracil (in RNA)U
CN
NC
OH
NH2
CHCH
OC
NH
CH
HNC
O
CCH3
N
HNC
C
HO
O
CytosineC
Thymine (in DNA)T
NHC
N C
CN
C
CH
N
NH2 O
NHC
NHH
C
C
C
N
NH
C NH2
AdenineA
GuanineG
Purines
Nitrogenous bases Pyrimidines
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Pentose Sugars
The pentose (five-carbon) sugar:• In RNA is ribose.• In DNA is deoxyribose. • Has carbon atoms numbered with primes to
distinguish them from the nitrogen bases.
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HO
Nucleosides
A nucleoside: • Has a nitrogen base
linked by a glycosidic bond to C1’ of a ribose or deoxyribose.
• Is named by changing the nitrogen base ending to -osine for purines and –idine for pyrimidines
N Base
N-glycosidic linkage
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HO
Adenin
DeoxyriboseDeoxyadenosine
NUCLEOSIDE
OHH
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glycosidic bond
phosphoester bond
Nucleoside
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Names of Nucleosides and Nucleotides
sugar base sugar base phosphate
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AMP, ADP, and ATP
• Adding phosphate groups to AMP forms the diphosphate ADP and the triphosphate ATP.
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TTT RNARNADNAPURINES TT T
PIRIMIDINES
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Primary Structure of Nucleic Acids
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DNA Secondary structure
sugar - phosphate
Sugar – phosphate bone causes each DNA chain to coil around the outside of the attached bases
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DNA Tertiary structureHydrogen bonding occurs between purines and pirimidines. This causes two DNA strands to bond together. Resulted in a double helix structure.
pentose
pentose
pentose
pentose
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The DNA double helix
Nucleotide sequence specifies the amino acid sequence of
proteins
Space-filling model
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The double helix structure is mainly stabilized by hydrogen bonds between bases pairs. Since the hydrophobic bases are stacked inside and the hydrophilic ribose-phosphate chains are on the outside, Van der Waals forces and hydrophobic interactions are also deeply involved in the stabilization of the double helix.
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In this major or minor grooves, the bases are exposed to solvent and to other molecules. By this way, some chemical and biochemical substances may have interactions with specific bases without disrupting the double helix structure.
Chemicals interaction
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Packaging In Prokaryotic cells (cells without nucleus), the two ends of the DNA molecule are joined to form a circular DNA. The circular DNA is coiled into a super helix and often organized in a compact structure containing various proteins and RNAs, named Nucleoid,
In Eukariotic cells, the DNA is packaged in Chromatin within the nucleus. The structure of chromatin is determined and stabilized through the interaction of the DNA with specific bindings proteins.
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Considering that human cell nucleus has a diameter of only 10 micrometers, whereas total DNA (genome) contained 46 chromosome, about 3x109 base pairs, and a length 1 m if streched end to end, so that DNA duplex must be highly compacted to fit into the nucleus.
This compaction is achieved by the double helix being folded around structure called nucleosome core. Each nucleosome is composed of 8 different protein called histones. The DNA duplex wraps around the nucleosome core to form a chain of nucleosome (about 150 – 200 base pairs per nucleosome).
An external ninth histone (H1 linker histone) is added which holds the nucleosome structure together. A nucleosome plus one H1-histone is termed a chromatosome.With the aid of histones H1, nucleosomes may be packed together and wound into a regular coil called solenoid. A solenoid contains six to eight nucleosomes per turn and forms the 30nm nucleoprotein fibers or chromatin fiber.
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= holds the nucleosome structure together
Chromatosome
H1 histone
nucleosome
20 – 200 nucleotides pairs
20 – 200 nucleotides pairs
20 – 200 nucleotides pairs
H1 histone
Tetrameric molecules: H2A, H2B, H3 and H4( 4 histone-subunits )
The DNA helix coils twice around the histone octamer
How DNA can be bound to the nucleosome core ?NH3
+ PO4-3
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Nucleosomes are separated one another by a linker segments of 20-200 nucleotides pairs. This gives unfolded chromatin a "beads-on-a-string" appearance.
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DNA Denaturation
1.Temperature
random coil conformation
2.Hyperchromiceffect
Increasing in UV absorbance
decrease interaction between bases
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RNA
To form RNA polymer, the ribonucleotide units are connected by a phosphodiester bond between the 3’ hydroxyl group (-OH) of one ribonucleotide and the 5’ hydroxyl group of another ribonucleotide.
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RNA types• transfer RNA (tRNA)• messenger RNA (mRNA)• ribosomal RNA (rRNA)• small interfering RNA (siRNA)• micro RNA (miRNA)• small nucleolar RNA (snoRNA)
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RNA Base Pairing tRNA
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Genes• Genes are the basic physical and functional units
of heredity. Each gene is located on a particular region of a chromosome and has a specific ordered sequence of nucleotides (the building blocks of DNA).
• The sequence of nitrogen bases along a DNA or mRNA polymer is unique for each gene.
• Genes are normally hundreds to thousands of nucleotides long.
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What is a locus?• A locus describes the region of
a chromosome where a gene is located. 11p15.5 is the locus for the human insulin gene. 11 is the chromosome number, p indicates the short arm of the chromosome, and 15.5 is the number assigned to a particular region on a chromosome. When chromosomes are stained in the lab, light and dark bands appear, and each band is numbered. The higher the number, the farther away the band is from the centromere.
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Exons vs Introns• Eukaryotic genes have introns and exons.
Exons contain nucleotides that are translated into amino acids of proteins. Exons are separated from one another by intervening segments of junk DNA called introns. Introns do not code for protein. They are removed when eukaryotic mRNA is processed. Exons make up those segments of mRNA that are spliced back together after the introns are removed; the intron-free mRNA is used as a template to make proteins.
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Splicing• Exons are sequences of DNA that are
expressed into protein.• Introns are intervening sequences that are not
translated into protein
DNA
Pre-mRNA
31
1 2 3
1 32
2Spliced mRNA
3
C
C
C
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• The flow of genetic information is from DNA -> RNA -> protein.– Protein synthesis occurs
in cellular structurescalled ribosomes.
– In eukaryotes, DNA is located in the nucleus, but most ribosomes are in the cytoplasm with mRNA as an intermediary.
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings
Fig. 5.28
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