Flashcards in 2.3 - Nucleic Acids Deck (28):
Describe the structure of DNA.
Double helix, polynucleotide, macromolecule.
How is DNA organised in cells?
In eukaryotes - in the nucleus, wound around histone proteins, held as chromosomes.
Mitochondria and chloroplasts have prokaryote like plasmids, single, double stranded loop of DNA.
In prokaryotes - free in the cytoplasm, single, double stranded loop, no histones, naked DNA.
Plasmids free in cytoplasm.
What are nucleotides?
Monomers of DNA and RNA.
State the roles of nucleotides.
Phosphorylated nucleotides contain more than one phosphate group, e.g. adenosine di/triphosphate - the universal energy currency.
Regulation of biochemical pathways, e.g. cAMP.
Component of coenzymes, e.g. NAD - electron/proton carrier in respiration.
What components make up a nucleotide?
Deoxyribose (DNA), ribose (RNA).
Pentose sugar and phosphate group joined by a phosphodiester bond in a condensation reaction.
An organic nitrogenous base joined to the pentose sugar by a covalent bond formed in a condensation reaction.
What are the nitrogenous bases?
Adenine, Thymine, Uracil, Cytosine, Guanine.
Name the purines and describe their structure.
Guanine and adenine. Double nitrogenous ring.
Name the pyrimidines and describe their structure.
Cytosine, thymine and uracil (uracil replaces thymine in RNA). Single nitrogenous ring.
What is the base pair rule?
A pyrimidine always pairs with a purine.
A always pairs with T (or U in RNA).
C always pairs with G.
A and T form two hydrogen bonds.
C and G form three hydrogen bonds.
DNA strands are antiparallel - what does this mean?
The sugar phosphate backbones of each strand in DNA run in opposite directions.
The 5th carbon of the pentose is attached to the phosphate group This is the 5’ end of the molecule.
The third carbon on the pentose ring is free to bond with the 5th carbon of the next nucleotide.
This is the 3’ end of the molecule.
Nucleotides are added 5’ to 3’.
How is DNA structure related to its function, storing genetic information?
Long - can hold lots of information.
Coiled - compact so can store a lot of information in a small space.
Sugar phosphate backbone - strong bonds make DNA stable.
Many hydrogen bonds between complementary bases - give stability but easily broken to allow enzymes access for replication and transcription.
Code is universal.
Why is DNA described as universal?
DNA is the same in all living organisms.
What is the structure of mRNA?
Ribose sugar and phosphate backbone.
Organic nitrogenous bases, U replaces T.
What are the 3 main types of RNA?
Messenger RNA (mRNA), ribosomal RNA (rRNA) and transfer RNA (tRNA).
Compare and contrast DNA and mRNA.
DNA: long molecule; found in the nucleus; pentose sugar is deoxyribose; adenine, thymine, cytosine and guanine; double stranded, replicates to produce two identical molecules - semiconservative replication.
mRNA: shorter molecule; found in the nucleus and cytoplasm; pentose sugar is ribose; adenine, cytosine and guanine, uracil replaces thymine; single stranded; does not replicate, exists only for polypeptide synthesis then destroyed.
When does DNA replication occur?
During interphase, before cell division. DNA in mitochondria and chloroplasts also replicates.
Describe the steps of DNA replication.
Gyrase untwists the double helix. Helicase breaks the hydrogen bonds between nitrogenous bases. DNA nucleotide nitrogenous are exposed. Free phosphorylated nucleotides, present in the nucleus, form complementary base pairs with the exposed nucleotides. DNA polymerase catalyses the formation of the phosphodiester bonds in a 5' to 3' direction. Energy to form this bonds comes from the hydrolysis of the extra phosphate group on the activated nucleotides. The leading strand is synthesised continuously in the 5' to 3' direction. The lagging strand is synthesised in smaller 5' to 3' fragments called Okazaki fragments. Ligase joins the fragments together. Two identical strands are formed. Each strand contains one strand from the parent molecule and one new strand. This is semiconservative replication.
Describe the nature of the genetic code.
Universal - present in almost all living things; the same triplet bases of DNA code for the same amino acid in almost all living things.
Degenerate - there is more than one base triplet code for all amino acids except methionine and tryptophan.
Non-overlapping - read in sequence, starting from a fixed point.
What is a gene?
A stretch of DNA that carries the code to make a polypeptide.
What is the triplet code?
3 DNA nucleotide bases = 1 DNA base triplet.
3 mRNA nucleotides = 1 mRNA base triplet = 1 codon.
Each tRNA base triplet = 1 anticodon = 1 specific amino acid.
What is transcription?
The production of mRNA from DNA using RNA polymerase.
Takes place in the nucleus.
Gene unwinds and unzips.
Hydrogen bonds between nitrogenous bases break, exposing DNA nucleotide nitrogenous bases.
Free RNA nucleotides in nucleus form complementary base pairs with exposed DNA nucleotides - C with G, A with U.
RNA polymerase catalyses formation of phosphodiester bond in 5' to 3' direction on one strand only forming mRNA, the transcript.
This DNA strand is the template strand.
mRNA passes out of the nucleus into the cytoplasm, via a nuclear pore.
The opposite DNA strand is the coding strand; this does not produce mRNA.
Where are ribosomes made?
rRNA is synthesised in nucleus. Single stranded rRNA folded to form rRNA in nucleus. 2 subunits, one larger, one smaller. Subunits move through nuclear pore into cytoplasm.
Where is tRNA made?
tRNA is synthesis in nucleus. Single stranded tRNA folded to form tRNA in nucleolus. tRNA moves through nuclear pore into cytoplasm.
Describe the structure of tRNA.
tRNA is folded into cloverleaf shape held together with hydrogen bonds between complementary bases. tRNA contains an anticodon at one end of the hairpin. tRNA has three unpaired bases at the other end of the hairpin, an amino acid binding site.
What is translation?
The production of polypeptides from the sequence of codons carried by mRNA.
mRNA attaches to ribosome at the start codon, AUG, and moves along the mRNA to next codon.
tRNA, carrying a specific amino acid, forms temporary hydrogen bonds between mRNA codon and tRNA RNA codon.
First and second tRNA anticodon attaches to complementary mRNA.
The two amino acids attached to tRNA are joined together by a peptide bond, this requires energy in the form of ATP.
tRNA leaves the ribosome.
Ribosome moves along and cycle repeats with next tRNA.
Polypeptide produced until stop codon reached.
Polypeptide chain folded into 3D shape using chaperon proteins.