RNA: Difference between revisions
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- DNA is transcribed into mRNA, therefore the mRNA and the DNA are complementary | - DNA is transcribed into mRNA, therefore the mRNA and the DNA are complementary | ||
- mRNA carries the [[Genetic code|genetic code]] from the DNA in the nucleus to the [[Ribosomes|ribosomes]] in the [[ | - mRNA carries the [[Genetic code|genetic code]] from the DNA in the nucleus to the [[Ribosomes|ribosomes]] in the [[Cytoplasm|cytoplasm]]<br> - This mRNA is then used as a template for [[Translation|translation]] into a functional protein<br> - mRNA is also used to make copy DNA ([[CDNA|cDNA]]) | ||
<br>2. [[TRNA|tRNA]] – transfer RNA <ref>Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 120</ref> | <br>2. [[TRNA|tRNA]] – transfer RNA <ref>Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 120</ref> | ||
- Single polynucleotide strand which is folded into a clover shape, held together by [[Hydrogen bonds|hydrogen bonds]]<br> - Consists of a specific sequence of three unpaired bases bound to a complementary [[ | - Single polynucleotide strand which is folded into a clover shape, held together by [[Hydrogen bonds|hydrogen bonds]]<br> - Consists of a specific sequence of three unpaired bases bound to a complementary [[Codon|codon]] ([[Anticodon|anticodon]]) and an [[Amino acid|amino acid]] binding site | ||
- Found in the [[ | - Found in the [[Cytoplasm|cytoplasm]], where it is involved in translation | ||
- This [[Molecule|molecule]] carries amino acids to the ribosomes where a [[Polypeptide|polypeptide]] is formed, the sequence of which was determined by the [[MRNA|mRNA]]. | - This [[Molecule|molecule]] carries amino acids to the ribosomes where a [[Polypeptide|polypeptide]] is formed, the sequence of which was determined by the [[MRNA|mRNA]]. | ||
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<br>3. [[RRNA|rRNA]] – ribosomal RNA <ref>Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 120</ref><br> - This is the RNA which forms [[Ribosomes|ribosomes]]<br> - It acts as a catalyst for [[Proteins|protein]] synthesis | <br>3. [[RRNA|rRNA]] – ribosomal RNA <ref>Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 120</ref><br> - This is the RNA which forms [[Ribosomes|ribosomes]]<br> - It acts as a catalyst for [[Proteins|protein]] synthesis | ||
- It is synthesised in the [[Nucleolus|nucleolus]] | - It is synthesised in the [[Nucleolus|nucleolus]] | ||
- rRNA molecules do not code for protein | - rRNA molecules do not code for protein | ||
The three RNAs all work together to convert the initial DNA molecule into a protein. All three of these types of RNA are synthesised by RNA Polymerase. | |||
<br> | |||
4. snRNA -- small nuclear RNA | |||
- commonly known as U-RNA | |||
- function in various nuclear processes | |||
- function in the splicing of pre-mRNA | |||
- transcribed by either RNA polymerase II or RNA polymerase III | |||
<br> | |||
5. snoRNA -- small nucleolar RNA | |||
- used to process and modify rRNA chemically | |||
| |||
6. scaRNA -- small cajal RNA | |||
- a class of snoRNAs | |||
- locate at the Cajal body | |||
- to modify snoRNA and snRNA | |||
<br> | |||
7. miRNA -- microRNA | |||
- non-coding RNA molecule | |||
- containing approximately 22 nucleotides | |||
- regulate gene expression by blocking translation of selective mRNA | |||
<br> | |||
8. siRNA -- small interfering RNA | |||
- also known as silencing RNA | |||
- double stranded RNA molecules | |||
- turn off gene expression by directing degradation of selective mRNA and the establishment of compact chromatin structures | |||
| |||
| | ||
<br> | |||
RNA can also exist in non coding forms. These non-coding RNAs have many applications but many revolve around regulation of [[ | RNA can also exist in non coding forms. These non-coding RNAs function in diverse cell processes, such as telomere synthesis, transport of proteins intot the endoplasmic recticulum and X-chromosome inactivation. Beasides, non-coding RNAs also have many applications but many revolve around regulation of [[Gene|gene]] expression, such as [[Riboswitches|riboswitches]] in bacteria and miRNAs involved in [[RNAi]] (RNA interference) in animals <ref>Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Walter P,2008, Molecular Biology of the Cell,5th Edition, New York, Garland Science, pg 493</ref>. | ||
== References == | == References == | ||
<references /> | <references /> | ||
Revision as of 18:32, 27 November 2014
RNA stands for ribonucleic acid. It is made up of a series of nucleotides joined by 3'-5' phosphodiester bonds. RNA forms a polynucleotide strand with a sugar-phosphate backbone. Unlike DNA, RNA has a ribose sugar, which means that it has a 2` hydroxyl group.
Attached to the backbone are 4 bases, in a similar way to DNA, in which cytosine (C) pairs with guanine (G) and thymine (T) pairs with adenine (A). However in RNA C pairs with G, but A pairs with uracil (U) instead of T [1]. RNA is typically single-stranded, although regions can form where the RNA loops back on itself, to produce "hairpin" secondary structures.[2]
RNA involved in gene expression
1. mRNA – messenger RNA [3]
- Single polynucleotide strand made in the nucleus during transcription
- DNA is transcribed into mRNA, therefore the mRNA and the DNA are complementary
- mRNA carries the genetic code from the DNA in the nucleus to the ribosomes in the cytoplasm
- This mRNA is then used as a template for translation into a functional protein
- mRNA is also used to make copy DNA (cDNA)
- Single polynucleotide strand which is folded into a clover shape, held together by hydrogen bonds
- Consists of a specific sequence of three unpaired bases bound to a complementary codon (anticodon) and an amino acid binding site
- Found in the cytoplasm, where it is involved in translation
- This molecule carries amino acids to the ribosomes where a polypeptide is formed, the sequence of which was determined by the mRNA.
3. rRNA – ribosomal RNA [5]
- This is the RNA which forms ribosomes
- It acts as a catalyst for protein synthesis
- It is synthesised in the nucleolus
- rRNA molecules do not code for protein
The three RNAs all work together to convert the initial DNA molecule into a protein. All three of these types of RNA are synthesised by RNA Polymerase.
4. snRNA -- small nuclear RNA
- commonly known as U-RNA
- function in various nuclear processes
- function in the splicing of pre-mRNA
- transcribed by either RNA polymerase II or RNA polymerase III
5. snoRNA -- small nucleolar RNA
- used to process and modify rRNA chemically
6. scaRNA -- small cajal RNA
- a class of snoRNAs
- locate at the Cajal body
- to modify snoRNA and snRNA
7. miRNA -- microRNA
- non-coding RNA molecule
- containing approximately 22 nucleotides
- regulate gene expression by blocking translation of selective mRNA
8. siRNA -- small interfering RNA
- also known as silencing RNA
- double stranded RNA molecules
- turn off gene expression by directing degradation of selective mRNA and the establishment of compact chromatin structures
RNA can also exist in non coding forms. These non-coding RNAs function in diverse cell processes, such as telomere synthesis, transport of proteins intot the endoplasmic recticulum and X-chromosome inactivation. Beasides, non-coding RNAs also have many applications but many revolve around regulation of gene expression, such as riboswitches in bacteria and miRNAs involved in RNAi (RNA interference) in animals [6].
References
- ↑ Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 109
- ↑ Lyons, I, 2011. Biomedical Science Lecture Notes. 1st ed. Oxford: Wiley-Blackwell, p21-23
- ↑ Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 119
- ↑ Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 120
- ↑ Berg JM, Tymoczko JL and Stryer L, 2007, Biochemistry 6th edition, NY, W. H Freeman and Company, page 120
- ↑ Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Walter P,2008, Molecular Biology of the Cell,5th Edition, New York, Garland Science, pg 493