1.5: Nucleic acids and their functions
ATP is a nucleotide.
ATP stands for adeninosine triphosphate, as it contains the base adenine, the sugar ribose and three phosphate groups.
When ATP is required in the bond, the enzyme ATPase hydrolyses the bond between the second and third phosphate groups, making adeninosine disulphate (ADP) and one inorganic phosphate ion.
Every mole of ATP releases 30.6 kJ of energy, making it an exergonic reaction (releases energy).
This reaction is reversible. This is done through a condensation reaction, with the enzyme ATP synthetase, ADP and an inorganic phosphate ion. It results in ATP and a water molecule.
This reaction, the addition of phosphate to ADP is known as phosphorylation and is a endergonic reaction, as it takes in energy from it's surroundings.
ATP transfers energy from energy-rich compounds such as glucose to where they are needed in cellular reactions.
These transfers are inefficient and produce heat energy, which would destroy cells if uncontrolled.
Therefore energy is released gradually in a series of small steps called respiration, which produces ATP.
ATP only needs one reaction to produce energy, where glucose requires many intermediates and takes longer.
ATP needs one enzyme, while glucose requires many.
ATP releases small amount of energy where and when it is needed, glucose releases it in large amounts.
ATP is a common source of energy of energy for many chemical reactions, increasing cell control and efficiency.
Metabolic processes.
Active transport.
Movement.
Nerve transmissions.
Secretion.
The structure was discovered by Watson and Crick, although they used Franklinās work without credit.
DNA stands for Deoxyribose Nucleic Acid, as it contains deoxyribose as itās pentose sugar.
DNA is a polymer, built up of nucleotide monomers. Each nucleotide consists of one phosphate, one sugar and one organic base. This makes it a polynucleotide.
There are four different bases, and two complementary base pairings; adenine and thymine, and cytosine and guanine.
The complementary bases are held together by weak hydrogen bonds, which therefore hold the two polynucleotide strands together.
Adenine and thymine have two hydrogen bonds, guanine and cytosine three.
The largest bases, adenine and guanine, are described as purines. This is because they have two nitrogen containing rings.
The smallest bases, thymine and cytosine, are described as pyrimidines. This is because they have a single nitrogen containing ring.
Nucleotides form strong covalent bonds with the phosphate of one nucleotide and the phosphate of another.
The chains run in opposite directions to each other, known as antiparallel strands.
The distance between the two backbones doesnāt vary along the length of the whole molecule, which perfectly accommodates the space needed for a purine-pyrimidine pair.
The strands are coiled into a double helix.
DNA codes for proteins, by copying to DNA and using to sequence to decide the amino acids.
There is 20 amino acids, and each ones have different codes.
It is also known as a degenerate code, as amino acids can be coded for by more than one triplet code.
The codes are made of three letters, with 64 different possibilities. One of these triplet is known as a codon.
There is a start code that is the same for each protein, known as met. There are also three end codes.
This code was discovered by Crick and colleagues.
DNA replicates in order to perform meiosis and mitosis, which are needed for growth, repair and reproduction.
DNA uses a semi-conservative replication, known as this as half of the two new strands are built up of the old strand.
There are three enzymes used during the replication.
The enzyme DNA helicase attaches to the DNA molecule and moves along its length.
This separates the hydrogen bonds holding together the strand, and splits it apart.
Free nucleotides are attracted to the exposed strand, with ATP activating their movement.
Nucleotides are attracted to the complementary base pairing, so A to T and C to G.
DNA ligase is used to help match and lay down nucleotides to build the new daughter strand.
DNA polymerase binds the DNA fragments together by forming phosphate bridges.
This process was proven by Meselson and Stahl.
They used e-coli bacteria and created parent DNA molecules of N15, which is a heavy isotope of nitrogen. This was created by growing e-coli on a N15 medium for many generations.
They then placed it in a growing medium where only N14 nitrogen existed.
Between each generation, they used a density gradient centrifugation. This is when the tubes are spun in a centrifuge, and observed under only UV light. During the process, the DNA molecules move to where their density corresponds with caesium chloride solution.
They looked at four generations:
Parent generation - contained only N15 only DNA.
F1 - contained hybrid N15 and N14 DNA.
F2 - contained half hybrid N14 and N15 DNA and half N14 only DNA.
F3 - contained 25% hybrid N15 DNA and 75% N14 DNA.
This was done as there were three main theories of DNA replication at the time:
Conservative - the old strand remains as a completely identical strand is made.
Dispersive - DNA strands are made from fragments of new and old strands.
Semi-conservative - one old strand remains, and one is completely new.
This proved semi-conservative, as there was new DNA created and the DNA didnāt remain hybrid.
DNA is extremely stable and information asses virtually unchanged.
It is a large molecule as it carries a large amount of genetic information.
The two strands can easily separate due to weak hydrogen bonds, allowing for easier replication.
The base pairs are protected by the deoxyribose-phosphate backbones.
RNA stands for ribonucleic acid.
It is a single stranded polynucleotide, resembling a singular DNA strand.
It uses the pentose sugar ribose.
It uses adenine and guanine as purine bases and cytosine and uracil as pyrimidine bases, excluding thymine.
The main role of RNA is protein synthesis.
There are three types:
It is synthesised in the nucleus and carries the genetic code from the DNA to the ribosomes in the cytoplasm.
These strands are different lengths based on the lengths of the genes they are transcribed from.
Found in the cytoplasm and comprises large, complex molecules.
They make up ribosomes, along with protein. They are the site of translation of the genetic code into protein.
A small molecule, made up of 75-90 nucleotides and forms a āclover-leafā shape.
It folds so that in certain places there are complementary base pairings.
It has an anticodon, which allows it to interact with molecules of mRNA.
At the opposite end of the molecule is an amino acid binding site, which are carried and eventually form polypeptide chains during protein synthesis.
This is done as the tRNA transfers them to ribosomes during protein synthesis.
There are two stages:
Transcription - a strand of DNA acts as a template for mRNA production, this occurs in the nucleus.
Translation - the mRNA strand moves to a ribosome and acts as a template for complementary tRNA molecules to deposit amino acids, which are linked to form a polypeptide.
Transcription rewrites DNA as a new strand in order to transport it out of the cell, as DNA is too large and valuable to leave the nucleus.
This happens in 4 steps:
DNA helicase splits hydrogen bonds between the bases, unwinding the strands and exposing the bases.
RNA polymerase binds to the template strand of DNA to copy it. Free ribonucleotides align with the bases in complementary pairs, with uracil bonding to adenine instead of thymine.
RNA polymerase forms bonds to add bases to the RNA strand, synthesising a molecule of mRNA along the DNA behind the RNA polymerase, the DNA strands reform the double helix.
Once a stop codon is reached, the RNA polymerase separates from the template strand. Production of mRNA is complete and it moves out of the nuclear pores towards a ribosome.
In eukaryotes, RNA must be processed before synthesising a polypeptide.
Before it is processed, it is known as pre-mRNA, and is much longer than the final strand.
Some parts, known as introns, do not code for any polypeptides. It is also known as junk DNA, and is suspected to be evolutionary leftovers. Around 97% of DNA is introns.
These parts are removed by RNA polymerase using endonucleases.
The parts that are left behind do code for polypeptides and are known as exons.
These are spliced together using ligases.
Translation begins once the mRNA has reached a ribosome. It occurs using the sequence of codons to organise the amino acids, which forms a polypeptide.
Also used in this process is tRNA.
The ribosome has two subunits, one larger as it has two sites for tRNA attachment and one smaller which binds to the mRNA strand.
The ribosome moves along the mRNA and adds one amino acid at a time, holding the codon-anticodon complex together until they bind. This occurs in three stages.
Initiation:
The ribosome attaches to the start codon on the mRNA.
A tRNA with a complementary anti-codon to the first mRNA codon attaches to the ribosome. The bases bond together using hydrogen bonds, creating a codon-anticodon complex.
A second tRNA attaches at the other attachment site, which is complementary to the second mRNA codon.
Elongation:
The two amino acids are close enough for a ribosomal enzyme to catalyse a peptide bond between them.
The first tRNA leaves the ribosome and therefore itās attachment site vacant. It returns to the cytoplasm and binds to another copy of its specific amino acid.
This requires ATP, and is a process known as amino acid activation.
The ribosome then moves one codon along the mRNA strand and the next tRNA binds to the attachment site.
Termination:
The first two processes repeat until a stop codon is reached.
The ribosome-mRNA-polypeptide complex separates.
Usually several ribosomes are attached to one mRNA strand, all reading the information at the same time. This is called a polysome.
Each ribosome produces a separate polypeptide.
The polypeptide chain is only a primary structure protein, and while usually functional, must be chemically modified or folded into secondary, tertiary and quaternary structures in order to fit itās purpose.
It is chemically modified in the golgi body and folded in the ER.
It can be modified to combine with non-proteins, such as carbohydrates to make glycoproteins, lipids to make lipoproteins and phosphate to make phospho-proteins.
In the 1940s research began into how DNA encoded information. Experiments on fungi showed that radiation damage to DNA prevented a single enzyme from being made, leading to the one gene-one enzyme hypothesis.
As enzymes are a type of protein, this was expanded to become the one gene one-protein hypothesis.
However, as some proteins require multiple polypeptides, this became the one gene one-polypeptide hypothesis.
This defines a gene biochemically: a sequence of DNA bases that codes for a polypeptide.
ATP is a nucleotide.
ATP stands for adeninosine triphosphate, as it contains the base adenine, the sugar ribose and three phosphate groups.
When ATP is required in the bond, the enzyme ATPase hydrolyses the bond between the second and third phosphate groups, making adeninosine disulphate (ADP) and one inorganic phosphate ion.
Every mole of ATP releases 30.6 kJ of energy, making it an exergonic reaction (releases energy).
This reaction is reversible. This is done through a condensation reaction, with the enzyme ATP synthetase, ADP and an inorganic phosphate ion. It results in ATP and a water molecule.
This reaction, the addition of phosphate to ADP is known as phosphorylation and is a endergonic reaction, as it takes in energy from it's surroundings.
ATP transfers energy from energy-rich compounds such as glucose to where they are needed in cellular reactions.
These transfers are inefficient and produce heat energy, which would destroy cells if uncontrolled.
Therefore energy is released gradually in a series of small steps called respiration, which produces ATP.
ATP only needs one reaction to produce energy, where glucose requires many intermediates and takes longer.
ATP needs one enzyme, while glucose requires many.
ATP releases small amount of energy where and when it is needed, glucose releases it in large amounts.
ATP is a common source of energy of energy for many chemical reactions, increasing cell control and efficiency.
Metabolic processes.
Active transport.
Movement.
Nerve transmissions.
Secretion.
The structure was discovered by Watson and Crick, although they used Franklinās work without credit.
DNA stands for Deoxyribose Nucleic Acid, as it contains deoxyribose as itās pentose sugar.
DNA is a polymer, built up of nucleotide monomers. Each nucleotide consists of one phosphate, one sugar and one organic base. This makes it a polynucleotide.
There are four different bases, and two complementary base pairings; adenine and thymine, and cytosine and guanine.
The complementary bases are held together by weak hydrogen bonds, which therefore hold the two polynucleotide strands together.
Adenine and thymine have two hydrogen bonds, guanine and cytosine three.
The largest bases, adenine and guanine, are described as purines. This is because they have two nitrogen containing rings.
The smallest bases, thymine and cytosine, are described as pyrimidines. This is because they have a single nitrogen containing ring.
Nucleotides form strong covalent bonds with the phosphate of one nucleotide and the phosphate of another.
The chains run in opposite directions to each other, known as antiparallel strands.
The distance between the two backbones doesnāt vary along the length of the whole molecule, which perfectly accommodates the space needed for a purine-pyrimidine pair.
The strands are coiled into a double helix.
DNA codes for proteins, by copying to DNA and using to sequence to decide the amino acids.
There is 20 amino acids, and each ones have different codes.
It is also known as a degenerate code, as amino acids can be coded for by more than one triplet code.
The codes are made of three letters, with 64 different possibilities. One of these triplet is known as a codon.
There is a start code that is the same for each protein, known as met. There are also three end codes.
This code was discovered by Crick and colleagues.
DNA replicates in order to perform meiosis and mitosis, which are needed for growth, repair and reproduction.
DNA uses a semi-conservative replication, known as this as half of the two new strands are built up of the old strand.
There are three enzymes used during the replication.
The enzyme DNA helicase attaches to the DNA molecule and moves along its length.
This separates the hydrogen bonds holding together the strand, and splits it apart.
Free nucleotides are attracted to the exposed strand, with ATP activating their movement.
Nucleotides are attracted to the complementary base pairing, so A to T and C to G.
DNA ligase is used to help match and lay down nucleotides to build the new daughter strand.
DNA polymerase binds the DNA fragments together by forming phosphate bridges.
This process was proven by Meselson and Stahl.
They used e-coli bacteria and created parent DNA molecules of N15, which is a heavy isotope of nitrogen. This was created by growing e-coli on a N15 medium for many generations.
They then placed it in a growing medium where only N14 nitrogen existed.
Between each generation, they used a density gradient centrifugation. This is when the tubes are spun in a centrifuge, and observed under only UV light. During the process, the DNA molecules move to where their density corresponds with caesium chloride solution.
They looked at four generations:
Parent generation - contained only N15 only DNA.
F1 - contained hybrid N15 and N14 DNA.
F2 - contained half hybrid N14 and N15 DNA and half N14 only DNA.
F3 - contained 25% hybrid N15 DNA and 75% N14 DNA.
This was done as there were three main theories of DNA replication at the time:
Conservative - the old strand remains as a completely identical strand is made.
Dispersive - DNA strands are made from fragments of new and old strands.
Semi-conservative - one old strand remains, and one is completely new.
This proved semi-conservative, as there was new DNA created and the DNA didnāt remain hybrid.
DNA is extremely stable and information asses virtually unchanged.
It is a large molecule as it carries a large amount of genetic information.
The two strands can easily separate due to weak hydrogen bonds, allowing for easier replication.
The base pairs are protected by the deoxyribose-phosphate backbones.
RNA stands for ribonucleic acid.
It is a single stranded polynucleotide, resembling a singular DNA strand.
It uses the pentose sugar ribose.
It uses adenine and guanine as purine bases and cytosine and uracil as pyrimidine bases, excluding thymine.
The main role of RNA is protein synthesis.
There are three types:
It is synthesised in the nucleus and carries the genetic code from the DNA to the ribosomes in the cytoplasm.
These strands are different lengths based on the lengths of the genes they are transcribed from.
Found in the cytoplasm and comprises large, complex molecules.
They make up ribosomes, along with protein. They are the site of translation of the genetic code into protein.
A small molecule, made up of 75-90 nucleotides and forms a āclover-leafā shape.
It folds so that in certain places there are complementary base pairings.
It has an anticodon, which allows it to interact with molecules of mRNA.
At the opposite end of the molecule is an amino acid binding site, which are carried and eventually form polypeptide chains during protein synthesis.
This is done as the tRNA transfers them to ribosomes during protein synthesis.
There are two stages:
Transcription - a strand of DNA acts as a template for mRNA production, this occurs in the nucleus.
Translation - the mRNA strand moves to a ribosome and acts as a template for complementary tRNA molecules to deposit amino acids, which are linked to form a polypeptide.
Transcription rewrites DNA as a new strand in order to transport it out of the cell, as DNA is too large and valuable to leave the nucleus.
This happens in 4 steps:
DNA helicase splits hydrogen bonds between the bases, unwinding the strands and exposing the bases.
RNA polymerase binds to the template strand of DNA to copy it. Free ribonucleotides align with the bases in complementary pairs, with uracil bonding to adenine instead of thymine.
RNA polymerase forms bonds to add bases to the RNA strand, synthesising a molecule of mRNA along the DNA behind the RNA polymerase, the DNA strands reform the double helix.
Once a stop codon is reached, the RNA polymerase separates from the template strand. Production of mRNA is complete and it moves out of the nuclear pores towards a ribosome.
In eukaryotes, RNA must be processed before synthesising a polypeptide.
Before it is processed, it is known as pre-mRNA, and is much longer than the final strand.
Some parts, known as introns, do not code for any polypeptides. It is also known as junk DNA, and is suspected to be evolutionary leftovers. Around 97% of DNA is introns.
These parts are removed by RNA polymerase using endonucleases.
The parts that are left behind do code for polypeptides and are known as exons.
These are spliced together using ligases.
Translation begins once the mRNA has reached a ribosome. It occurs using the sequence of codons to organise the amino acids, which forms a polypeptide.
Also used in this process is tRNA.
The ribosome has two subunits, one larger as it has two sites for tRNA attachment and one smaller which binds to the mRNA strand.
The ribosome moves along the mRNA and adds one amino acid at a time, holding the codon-anticodon complex together until they bind. This occurs in three stages.
Initiation:
The ribosome attaches to the start codon on the mRNA.
A tRNA with a complementary anti-codon to the first mRNA codon attaches to the ribosome. The bases bond together using hydrogen bonds, creating a codon-anticodon complex.
A second tRNA attaches at the other attachment site, which is complementary to the second mRNA codon.
Elongation:
The two amino acids are close enough for a ribosomal enzyme to catalyse a peptide bond between them.
The first tRNA leaves the ribosome and therefore itās attachment site vacant. It returns to the cytoplasm and binds to another copy of its specific amino acid.
This requires ATP, and is a process known as amino acid activation.
The ribosome then moves one codon along the mRNA strand and the next tRNA binds to the attachment site.
Termination:
The first two processes repeat until a stop codon is reached.
The ribosome-mRNA-polypeptide complex separates.
Usually several ribosomes are attached to one mRNA strand, all reading the information at the same time. This is called a polysome.
Each ribosome produces a separate polypeptide.
The polypeptide chain is only a primary structure protein, and while usually functional, must be chemically modified or folded into secondary, tertiary and quaternary structures in order to fit itās purpose.
It is chemically modified in the golgi body and folded in the ER.
It can be modified to combine with non-proteins, such as carbohydrates to make glycoproteins, lipids to make lipoproteins and phosphate to make phospho-proteins.
In the 1940s research began into how DNA encoded information. Experiments on fungi showed that radiation damage to DNA prevented a single enzyme from being made, leading to the one gene-one enzyme hypothesis.
As enzymes are a type of protein, this was expanded to become the one gene one-protein hypothesis.
However, as some proteins require multiple polypeptides, this became the one gene one-polypeptide hypothesis.
This defines a gene biochemically: a sequence of DNA bases that codes for a polypeptide.