CHEM 43: Biochemistry I: Nucleic Acids PDF

Summary

This document provides information about nucleic acids, including their structure and function. It includes details on the various types of nucleic acids, their components, and the central dogma of molecular biology. The text contains extensive diagrams and tables to aid understanding.

Full Transcript

CHEM 43: Biochemistry I

NUCLEIC ACIDS

I. Structure of Nucleotides
Genetics inherited phenotypes, focused
on genes and functions.
Nucleotide: basic unit of NA’s, arranged in two
Biochem chemistry of living organisms long strands (spiraled, double helix).
Consists of 3 covalently-linked units:
Molec. Bio molecular basis of bio. activity

Genomics study of genomes Nitrogenous Purine: A, G
Bases
Pyrimidine: C, T, U
A genome is an organism’s complete
set of genetic information (blueprint!). Pentose Ribose: has OH at at C2
Sugar
This includes all hereditary instructions Deoxyribose: no O at C2
for creating (reproduction) and maintaining life.
Phosphate Monophosphate
○ 23 pairs (22 autosome, 1 sex chromosome)
Diphosphate

Triphosphate

Chromosome: long strand of DNA, packed
together with proteins and other molecules.

DNA: long polymers of nucleotides. Purine two hydrogen-carbon rings
pyrimidine ring fused
with imidazole ring.
and four nitrogen atoms.
DNA info. is encoded in four chemical bases:
adenine (A), guanine (G), cytosine (C), and Pyrimidine one hydrogen-carbon ring
thymine (T). and two nitrogen atoms.

pair up as A+T and C+G to form base pairs.
each base connects to a sugar & phosphate
molecule, forming the DNA backbone.

Base + Sugar + Phosphate = Nucleotide

★ Nucleoside = Nitrogenous base + Sugar
★ Nucleotide = Nucleoside + Phosphate

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 CHEM 43: Biochemistry I

NUCLEIC ACIDS

Researchers Year Process Findings Signif.

Oswald Avery, 1944 Mixed heat-killed S strain with live R Only when Established
Colin Macleod, strain; destroyed components with DNA was DNA as the
Maclyn McCarty enzymes. destroyed did genetic
transformatio material
1. S strain (virulent) was heat-killed, n stop.
making it non-virulent.
2. The heat-killed S strain was mixed DNA is the
with live R strain (non-virulent). transforming
3. Transformation occurred, creating substance
live S strain.
4. Extracted and purified the
transforming factor (DNA).
5. Used enzymes to destroy proteins,
RNA, and DNA separately.

Martha Chase & 1952 Used labeled bacteriophages to infect Only the DNA, not
Alfred Hershey bacteria; separated components. phosphorus- the protein,
labeled DNA, is the
1. Labeled phages were allowed to not protein genetic
infect E. coli. (sulfur), material
2. Phages were separated from the entered the responsible
bacteria. bacteria for heredity.
3. Measurements were taken to see during
which component entered bacteria. infection.

James Watson & 1953 Built models using X-ray diffraction Proposed the Discover
Francis Crick data (images from Rosalind Franklin double helix DNA
and Maurice Wilkins). structure with structure
base pairing

Erwin Chargaff 1950s Analyzed DNA from various organisms: Discovered Provided key
base pairing evidence for
[A] = [T] and [C] ≡ [G] rules in all DNA
organisms structure.

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 CHEM 43: Biochemistry I

NUCLEIC ACIDS

1. B DNA (right-handed double helix)
most common
Anti-parallel
BP’s are parallel to the axis of the helix
Axis passes through the center of BP’s

2. A DNA (right-handed)
○ found in solutions with higher salt
DNA Forms concentration or with alcohol added

3. Z DNA (left-handed)
○ its bases seems to zigzag (hence, Z!)
○ found in DNA molecules w/ alternating
G-C sequences in alcohol or high salt
solution.

Glycosidic Pentose Nitrogenous
Bonds Sugar Bases

Purine (A) C1 N9
distance between base pairs: 0.34 nm
Pyrimidine (B) C1 N1
distance covered by one full 3.4 nm
helical turn (pitch): (34 A)

base pairs per turn of helix 10.4 bp’s

base pair rotation relative to 35.4*
the adjacent base pair (360/10.4)

length of genome 3 x 10^9 bp’s

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 CHEM 43: Biochemistry I

NUCLEIC ACIDS

Naming Nucleotides
Hydrogen Bonds
For DNA (deoxy if deoxyribose)
A forms 2 hydrogen bonds with T
G forms 3 hydrogen bonds with C Deoxyadenosine monophosphate (dAMP)

Practice Problem: One strand found in Base Adenine Phosphate 1
the coding sequence of DNA fragment
isolated from E. coli reads 5’-GTAGCCTA-3’. Sugar Deoxyribose (basis if DNA or RNA)
How many H bonds are present between this
strand and its complementary strands? For RNA (no prefix for ribose)
Complementary sequence: 3’-CATCGGAT-5’ Uridine triphosphate (UTP)
Count the H-bonds: 20 hydrogen bonds! Base Uracil Phosphate 3
4 pairs of G ≡ C: 12 H bonds
4 pairs of A = T: 8 H bonds Sugar Ribose (basis if DNA or RNA)

DNA PACKAGING

Nucleosome – DNA
wrapped around histone
proteins.

Histones – Proteins that
help package DNA (H2A,
H2B, H3, H4, and H1).

Chromatin – DNA-protein
complex; euchromatin
(loose, active) &
heterochromatin (tight,
inactive).

Linker DNA – DNA
between nucleosomes,
bound by histone H1.

Chromosome – The most
condensed form of DNA
during cell division.

Topoisomerase – Enzyme
that prevents DNA tangling.

Condensins – Proteins
that compact chromosomes
during mitosis.

Scaffold proteins –
Structural proteins
supporting chromatin loops.

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 CHEM 43: Biochemistry I

NUCLEIC ACIDS

III. Central Dogma of Molecular Biology

The central dogma of molecular biology
outlines the flow of genetic information within a
biological system.

1. DNA: Stores genetic instructions. ‘
2. RNA: Acts as the messenger, carrying
instructions from DNA.
3. Protein: The functional molecule
responsible for most of the cellular
structure and processes

DNA → RNA → Protein

The Steps in the Central Dogma:

(1) Transcription DNA → Nucleus (in
RNA eukaryotes)

During transcription, a specific segment of DNA
is copied into messenger RNA (mRNA) by the
enzyme RNA polymerase.

(2) Translation RNA → Ribosome (in Codons and the Genetic Code
Protein cytoplasm)
Codons: Sequences of three nucleotides
In translation, the mRNA is used as a template on mRNA that correspond to specific
to synthesize proteins. Transfer RNA (tRNA) amino acids.
matches amino acids to the corresponding
codons on the mRNA. Type Start Stop

Sequence AUG UAA, UAG, UGA
(3) Post- Protein Cytoplasm or
Translation folding organelles
Function Initiates Terminates
protein translation
After synthesis, proteins fold into specific shapes synthesis
and may undergo modifications (e.g.,
glycosylation) to become fully functional. Amino Acid Methionine None (stop signal)

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 CHEM 43: Biochemistry I

NUCLEIC ACIDS

In prokaryotes, transcription and
translation happen quickly.
In DNA, need to process transcription
dahil sa labas ng nucleus ang
translation.
In eukaryotes, may introns and exons
(in prokaryotes, exons only).

REMAINING NOTES FROM FIRST MEETING

Length of genome = 3 x 10^9 base pairs

(3 x 10^9 bp) * 0.34 nm = 1 m length of
DNA na pinagsisiksikan in a 1 mm cell,
particularly sa nucleus

Nucleotides can only target the portion of
DNA na may histone linker, not yung
naka-wrap sa histone.
Genes in a genome do not have any effect on
cellular function until they are
expressed.

20k protein-coding genes.

Gene: Has a transcriptional and regulatory
region.

Transcriptional region: Part of DNA
that will be transcribed to mRNA.

Promoter (3’ to 5’)

transcription start site → mRNA
enzymes that help the promoter

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