Principles of Molecular Genetics PDF

Summary

This document outlines principles of molecular genetics, including DNA structure, DNA replication, and gene function. It explains the roles of DNA and RNA in storing and transmitting genetic information.

Full Transcript

Principles of molecular genetics

DNA (= deoxyribonucleic acid):
- the carrier of genetic information
- discoverer of DNA: Miescher (1869)
- the first model of DNA was built by Watson and Crick (1953)

The structure of DNA:
- nucleotide - the basic building block of DNA; is an organic compound
- the nucleotide consists of:
1. a nucleobase (= nitrogenous base):
a) DNA – adenine (A), guanine (G), cytosine (C), thymine (T)
b) RNA – adenine (A), guanine (G), cytosine (C), uracil (U)
2. a sugar (pentose)
a) DNA – deoxyribose
b) RNA - ribose
3. a phosphate group (H3PO4)

Polynucleotide chain:
- a chain of many nucleotides
- nitrogenous bases are held together by hydrogen bonds
- the 2 strands of DNA (= polynucleotide chains) are held together by weak hydrogen
bonds between the nitrogenous bases according to the principle of complementarity
- complementary base pairing: (DNA – (C-G), (A-T) and vice versa, RNA – (C-G),
(A-U), (T-A – only from DNA)

Function of DNA:
- to store and transmit genetic information

Function of RNA:
- to convert the information stored in DNA into proteins

The transmission of genetic information:
- involves:
1. replication – the process of making copies of DNA molecules in the cell nucleus
2. transcription (mRNA synthesis) - a process that involves transcribing genetic
information from DNA to mRNA = messenger RNA (DNA is transcribed or re-
written into RNA)
3. translation (protein biosynthesis):
– happens on the ribosomes in the cytoplasm and in the endoplasmic reticulum
– the synthesis of protein from RNA
– the coded information from mRNA (nucleotide sequence) is translated into chains
of amino acids
 DNA REPLICATION (SYNTHESIS):

- before a cell enters the process of mitosis, its DNA replicates itself
- DNA replication occurs during the S phase of the cell cycle
- equal copies of the DNA pass into the daughter cells at the end of mitosis
- in human cells, this means that 46 chromosomes (or molecules of DNA) replicate to
form 92 chromosomes

Mechanism of DNA replication:
- the double helix opens and a complementary strand of DNA is synthesized along
each strand
- DNA replication begins with the "unzipping" of the parent molecule
- specialized enzymes unzip the DNA double helix (the hydrogen bonds between the
base pairs are broken) = the two strands separate
- the sequence of bases on each of the separated strands serves as a template (= a
pattern) to guide the insertion of a complementary set of bases on the strand being
synthesized
- the enzyme DNA polymerase joins all the nucleotide components to one another,
forming a long strand of nucleotides
- the old strand of DNA directs the synthesis of a new strand of DNA through
complementary base pairing
- the nucleotides are assembled in the order of bases on the strand serving as the
template
- the old strand then unites with the new strand to reform a double helix

The genetic code:
- the sequence of nucleotides in DNA and RNA that serve as instructions for
synthesizing proteins
- the set of rules by which information encoded within genetic material (DNA or mRNA
sequences) is translated into proteins (amino acid sequences) by living cells

Properties of the genetic code:
1. the genetic code is a three-letter (triplet) code:
- triplet – a series of three nucleotides (eg. CCA, TGG) = codon
- codon – specifies the insertion of an amino acid in a specific structural position in a
polypeptide chain during the synthesis of proteins
2. the genetic code is degenerate:
- 20 main amino acids can be coded for by 64 different triplet combinations – codons
- one amino acid is coded by more than one codon
- 61 codons encode amino acids and 3 codons are nonsense = stop codons (do not
code for any amino acids)
- start and stop codons:
1. start codon – AUG (the first codon of mRNA; always codes for
methionine)
2. stop codons – UAA, UAG, UGA (signal a termination of translation, or
punctuation)
3. the genetic code is non-overlapping:
- each nucleotide is part of only one triplet codon
4. the genetic code is almost universal:
- almost all organisms in nature (from bacteria to humans) use exactly the same genetic
code

The function of genes at a molecular level

1. structural genes:
- genes that specify the amino acid sequence of a polypeptide chain (of a specific
protein)
2. genes for RNA:
- genes for RNA are transcribed into the nucleotide sequence of tRNA and rRNA
3. regulator(y) genes:
- genes which determine whether or not genes will be expressed
- genes which regulate the activity of other genes