- Ribonuclease
Ribonuclease, abbreviated commonly as RNase, is a
nuclease that catalyzes the degradation ofRNA into smaller components. Ribonucleases can be divided intoendoribonuclease s andexoribonuclease s, and comprise several sub-classes within the EC 2.7 (for the phosphorolytic enzymes) and 3.1 (for the hydrolytic enzymes) classes of enzymes.Function
All organisms studied contain many RNases of many different classes, showing that RNA degradation is a very ancient and important process. As well as cleaning of cellular RNA that is no longer required, RNases play key roles in the maturation of all RNA molecules, both messenger RNAs that carry genetic material for making proteins, and non-coding RNAs that function in varied cellular processes. In addition, active RNA degradation systems are a first defence against RNA viruses, and provide the underlying machinary for more advanced cellular immune strategies such as RNAi.
Some cells also secrete copious quantities of non-specific RNases such as A and T1. RNases are therefore extremely common, resulting in very short lifespans for any RNA that is not in a protected environment. It is worth noting that all intracellular RNAs are protected from RNase activity by a number of strategies including 5' end capping, 3' end
polyadenylation , and folding within an RNA protein complex (ribonucleoprotein particle or RNP).Another mechanism of protection is
ribonuclease inhibitor (RI), which comprises a relatively large fraction of cellular protein (~0.1%) in some cell types, and which binds to certain ribonucleases with the highest affinity of anyprotein-protein interaction ; thedissociation constant for the RI-RNase A complex is ~20 fM under physiological conditions. RI is used in most laboratories that study RNA to protect their samples against degradation from environmental RNases.Similar to
restriction enzyme s, which cleave highly specific sequences of double-strandedDNA , a variety ofendoribonuclease s have been recently classified which recognize and cleave specific sequences of single-stranded RNA.RNases play a critical role in many biological processes, including
angiogenesis andself-incompatibility inflowering plant s (angiosperms). Additionally, RNases in prokaryotic toxin-antitoxin systems are proposed to function asplasmid stability loci, and as stress-response elements when present on the chromosome.Classification
Major types of endoribonucleases
*: RNase A is an RNase that is commonly used in research. RNase A (e.g., bovine pancreatic ribonuclease A: PDB|2AAS) is one of the hardiest enzymes in common laboratory usage; one method of isolating it is to boil a crude cellular extract until all enzymes other than RNase A are denatured. It is sequence specific for single stranded RNAs. It cleaves 3'end of unpaired C and U residues, leaving a 3'-phosphorylated product, via a 2',3'-cyclic monophosphate.
*:
RNase H is a ribonuclease that cleaves the RNA in a DNA/RNA duplex to produce ssDNA. RNase H is a non-specific endonuclease and catalyzes the cleavage of RNA via a hydrolytic mechanism, aided by an enzyme-bound divalent metal ion. RNase H leaves a 5'-phosphorylated product.*
EC number 3.1.??:RNase I cleaves 3'-end of ssRNA at all dinucleotide bonds leaving a 5' hydroxyl, and 3' phosphate, via a 2',3'-cyclic monophosphate intermediate.*:
RNase III is a type of ribonuclease that cleaves rRNA (16s rRNA and 23s rRNA) from transcribed polycistronic RNA operon in prokaryotes. It also digests double strands RNA (dsRNS)-Dicer family of RNAse, cutting pre-miRNA (60-70bp long) at a specific site and transforming it in miRNA (22-30bp), that is actively involved in the regulation of transcription and mRNA life-time.*
EC number 3.1.??:RNase L is an interferon-induced nuclease which, upon activation, destroys all RNA within the cell*:
RNase P is a type of ribonuclease and is currently under heavy research. RNase P is unique from other RNases in that it is aribozyme – a ribonucleic acid that acts as a catalyst in the same way that aprotein based enzyme would. Its function is to cleave off an extra, or precursor, sequence of RNA ontRNA molecules. Further RNase P is one of two known multiple turnover ribozymes in nature (the other being theribosome ).*
EC number 3.1.??:RNase PhyM is sequence specific for single stranded RNAs. It cleaves 3'-end of unpaired A and U residues.*:
RNase T1 is sequence specific for single stranded RNAs. It cleaves 3'-end of unpaired G residues.*:
RNase T2 is sequence specific for single stranded RNAs. It cleaves 3'-end of all 4 residues, but preferentially 3'-end of As.*:
RNase U2 is sequence specific for single stranded RNAs. It cleaves 3'-end of unpaired A residues.*:
RNase V1 is non-sequence specific for double stranded RNAs. It cleaves base-paired nucleotide residues.*:
RNase V Major types of exoribonucleases
*
EC number EC number|2.7.7.8:Polynucleotide Phosphorylase (PNPase) functions both as anexonuclease as well as anucleotidyltransferase .*
EC number EC number|2.7.7.56:RNase PH functions both as anexonuclease as well as anucleotidyltransferase .*
EC number 3.1.??:RNase II is responsible for the processive 3'-to-5' degradation of single-strandedRNA .*
EC number 3.1.??:RNase R is a close homolog of RNase II, but it can, unlike RNase II, degrade RNA with secondary structures without help of accessory factors.*
EC number EC number|3.1.13.5:RNase D is involved in the 3'-to-5' processing of pre-tRNAs.*
EC number 3.1.??:RNase T is the major contributor for the 3'-to-5' maturation of many stable RNAs.*:
Oligoribonuclease degrades short oligonucleotides to mononucleotides.*:
Exoribonuclease I degrades single-stranded RNA from 5'-to-3', exists only in eukaryotes.*:
Exoribonuclease II is a close homolog of Exoribonuclease I.External links
* [http://www.chem.qmul.ac.uk/iubmb/enzyme/EC3/1/ IUBMB Enzyme Database for EC 3.1]
* [http://www.ebi.ac.uk/intenz/query?cmd=SearchEC&ec=3.1 Integrated Enzyme Database for EC 3.1]
References
* D'Alessio G and Riordan JF, eds. (1997) "Ribonucleases: Structures and Functions", Academic Press.
* Gerdes K, Christensen SK and Lobner-Olesen A (2005). "Prokaryotic toxin-antitoxin stress response loci". Nat. Rev. Microbiol. (3): 371-382.
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