Lecture 5 Nucleic Acid BIOL 158 PDF

Summary

This lecture provides an overview of nucleic acids and their components, such as DNA and RNA. It details the structure of nucleotides, bases, and the roles of these molecules. Key concepts and questions are highlighted.

Full Transcript

NUCLEIC ACIDS
 The central dogma of biosciences

DNA RNA Protein
Genetic Transmitter of genetic Biocatalyst
Information information Molecular machine
 Nucleotides and Nucleic acids
NUCLEIC ACIDS
Deoxyribonucleic acid (DNA)
Ribonucleic acid (RNA)

Linear polymers of nucleotides

NUCLEOTIDES

Ribose/Deoxyribose sugar
Heterocyclic nitrogenous bases (pyrimidines & purines)
Phosphate group
 Things to learn from the lecture

What are the structures of the nucleotides?

How are nucleotides joined together to form nucleic acids?

How is information stored in nucleic acids?

What are the biological functions of nucleotides and nucleic
acids?
What are the structures of the nucleotides?

Nitrogenous bases: derivatives of pyrimidine or purine
Three pyrimidines and two purines are commonly found in cells

Purine derivatives
Ribose

5 OH
HOCH2 O OH HOCH2 O
4 1
2 2
3 OH H
OH OH
Ribose Deoxyribose
β-D-Ribofuranose β-D-2-Deoxyribofuranose
Nucleosides (ribose + base)
β-N-glycosidic bond
Syn and anti conformations of nucleosides

NH2 NH2
1N N N
N 1
N N N N
9 9
HOCH2 O HOCH2 O

OH OH OH OH
Syn-conformation
syn Anti-conformation
anti

The anti conformations predominate in nucleic acids, the
polymers of nucleotides.
Nucleosides are more water soluble than free bases

Both kinds of nucleosides are stable in alkali
Pyrimidine nucleosides are resistant to acid hydrolysis than purine
 O
NH N NH O
2 N HN
RNA

N N 2 HN
N NH2 N N
N O N O N
HOCH2 O HOCH2 O HOCH2 O HOCH2
O

OH OH OH OH OH OH
OH OH
A Adenosine G Guanosine C Cytidine U Uridine
NH2 O NH2 O
DNA

CH3
N HN N
N N HN
N N NH2 N N O N O N
HOCH2 O HOCH2 O HOCH2
HOCH2 O O

OH H OH H OH H
A OH H
G C T
Deoxyadenosine Deoxyguanosine Deoxycytidine Deoxythymidine
Nucleotides (phosphated nucleosides )

NH2 NH2

Phosphate ester N N N
- N N N O
O
O- P O OCH2 O P OCH2 O

O
OH H
OH OH
Adenosine monophosphate Deoxycytidine
P AMP monophosphate
Phosphoryl group dCMP
Structures of common ribonucleotides
— AMP, GMP, CMP, and UMP

uncommon
 Nucleoside diphosphates and triphosphates are nucleotides
with two or three phosphate groups

Nucleoside 5’-diphosphates/triphosphates (NDPs/NTPs):
strong polyprotic acids
Form stable complexes with divalent cations: Mg2+, Ca2+
What are the structures and functions of the NA?
Nucleic acids are polynucleotides: linear polymers of nucleotides
linked by 3’,5’-phosphodiester bridge
The base sequence of a nucleic acid is its distinctive characteristic

Pi-
Sugar-phosphate Side chains: bases
backbone
DNA: A, G, C, T
Two termini of RNA: A, G, C, U
Polynucleotides:
5’-Pi (5’- )
3’- OH (3’- ) Direction of the
5’-end: pTpGpCpAp polynucleotide
3’-end: ApCpGpTp chain
-OH
5’-TGCA…… From 5’- to 3’-
The different classes of a nucleic acid: DNA and RNA
What is the different between structures of DNA and RNA?

DNA: quite large
only a single molecular (chromosome DNA) in simple life
Escherichia coli: 2.9 × 109 D (> million nucleotides)
Many chromosomes in eukaryotic cells, in two copies
principally; also occurs in mitochondria and in chloroplasts.

RNA: small
Occurs in multiple copies and various forms in cells
As biological functions, they are categorized into 3 major types:
messenger RNA, transfer RNA, ribosomal RNA (in all lives),
and another kind, small nuclear RNA ( only in eukaryotic cells).
mRNA, tRNA, rRNA and snRNA (see table 10.2--p.319)
The fundamental structure of DNA is a double helix

Chargaff’s rules: in late 1940s, Amounts of the four bases: (p.320)
Vary from species to species
A = T ; G = C (in each X-ray diffraction studies (R
Purine (A+G) = pyrimidine (T+C) Franklin and M Wilkins):
Helix with two different loops
in outside
James Watson and Francis
Crick at Cambrige University in
1953:
DNA was a complementary
double helix;
Two strands of DNA are
held together by the
bonding interactions
between unique base pairs.
Size of DNA: ~bp; ~kb
The genetic information in DNA is encoded in digital form
Base paring: interaction between bases—H bonds

Replication of DNA: two identical progeny molecules by base paring
DNA is in the form of enormously long, threadlike molecules

E. coli are
partially
digested
and diluted
with water
DNA in cells occurs in the form of chromosomes

Prokaryotic cell:
circular form, bind
proteins,
chromosomes are no
ordered structure

Eukaryotic cell:
Basic unit--nucleosome

Histones,
a class of Arg- and Lys-rich basic
protein,
interact ionically with the anionic
phosphate groups of DNA backbone
nucleosome
Various forms of RNA serve different roles in cells
mRNA, tRNA, rRNA, and small nuclear (sn) RNA
1. Messenger RNA carries the sequence information for synthesis of a
protein

Transcription : synthesis of RNA from DNA by RNA polymerase
Prokaryotes

Gene expression

Translation : synthesis of protein from RNA by ribosome
Eukaryotes

Heterogeneous heavy nuclear RNA,
hnRNA
Gene expression
2. Ribosomal RNA provides the structural and
functional foundation for ribosomes
3. Transfer RNAs carry amino acids to ribosomes for use in
protein synthesis

73~94 residues (bases)
4. Small nuclear RNAs mediate the splicing of Eukaryotic gene
transcripts (hnRNA) into mRNA
Contain 100~200 nucleotides, found in stable complexes with
specific proteins forming small nuclear ribonucleoprotein
particles, or snRNPs, are important in the processing of
hnRNA.
5. Small RNAs serve a number of roles, including post-
transcriptional gene silencing
Only 21~28 nucleotides, can target DNA or RNA through
complementary base pairing—direct readout.
Small interfering RNA (siRNA): disrupt gene expression by
binding mRNA complementally to form double-stranded
RNA, which is easily degraded and eliminating the mRNA.
Are nucleic acids susceptible to hydrolysis?

RNA is susceptible to hydrolysis by base, but DNA is susceptible to
hydrolysis by acid
DNA: HCl—hydrolyzing purine
glycosidic bond (apurinic acid)

RNA: NaOH—randomly hydrolyzing glycosidic bond

The enzymes that hydrolyze nucleic acids are phosphodiesterases
 Nucleases differ in their specificity for different forms of
nucleic acid
DNase, RNase only act on DNA or RNA respectively

Restriction enzymes are nucleases that cleave double-stranded
DNA molecules
There are types I, II and III restriction endonucleases
Type I and III require ATP to hydrolyze DNA, Type I cleave DNA
randomly, Type III cut DNA in specific sequence.
Type II restriction enzymes: no need for ATP, specific
recognition sequences are typically 4 or 6 nucleotides in length
and have a two fold axis of symmetry
 Type II restriction endonuclease

EcoRI
5’—N–N–N–N–N–N–G A–A–T–T–C–N–N–N–N–N–N—3’
: : : : : : : : : : : : : : : : : :
3’—N–N–N–N–N–N–C–T–T–A–A G–N–N–N–N–N–N—5’

“sticky” ends—cohesive ends

Restriction endonucleases can be used to map the structure of a
DNA fragment
 Peptide nucleic acids (PNAs) are synthetic mimics of DNA and RNA
The sugar phosphate backbone is replaced by a peptide backbone

Stable probe

PNAs are resistant to nucleases and also are poor substrates for protease
Key points:
Structures of purine and pyrimidine bases, nucleosides and
nucleotides.
Structure of polynucleotide strand.
Difference between DNA and RNA (structure and function).