Biology:miR-33
miR-33a | |
---|---|
Conserved secondary structure of miR-33a microRNA precursor | |
Identifiers | |
Symbol | miR-33a |
Alt. Symbols | mir33a |
Rfam | RF00667 |
miRBase | MI0000091 |
miRBase family | MIPF0000070 |
NCBI Gene | 407039 |
HGNC | 31634 |
Other data | |
RNA type | miRNA |
Domain(s) | Metazoa |
GO | 0035195 |
SO | 0001244 |
Locus | Chr. 22 q13.2 |
PDB structures | PDBe |
miR-33b | |
---|---|
Identifiers | |
Symbol | miR-33b |
Alt. Symbols | mir33b |
Rfam | RF00667 |
miRBase | MI0003646 |
miRBase family | MIPF0000070 |
NCBI Gene | 693120 |
HGNC | 32791 |
Other data | |
RNA type | miRNA |
Domain(s) | Metazoa |
GO | 0035195 |
SO | 0001244 |
Locus | Chr. 17 13.2 |
PDB structures | PDBe |
miR-33 is a family of microRNA precursors, which are processed by the Dicer enzyme to give mature microRNAs.[1] miR-33 is found in several animal species, including humans. In some species there is a single member of this family which gives the mature product mir-33. In humans there are two members of this family called mir-33a and mir-33b, which are located in intronic regions within two protein-coding genes for Sterol regulatory element-binding proteins (SREBP-2 and SREBP-1) respectively.[2]
Function
miR-33 plays a role in lipid metabolism; it downregulates a number of ABC transporters, including ABCA1 and ABCG1, which in turn regulate cholesterol and HDL generation.[3][4] Further related roles of miR-33 have been proposed in fatty acid degradation and in macrophage response to low-density lipoprotein.[2] It has been suggested that miR-33a and miR-33b regulates genes Involved in fatty acid metabolism and insulin signalling.[5]
Potential binding sites for mir-33 have been identified in the cDNA of tumour suppressor p53.[6] Further, study has shown that miR-33 is able to repress p53 expression and p53-induced apoptosis. This function is thought to be related to hematopoietic stem cell renewal.[7]
Applications
miR-33, along with miR-122, could be used to diagnose or treat conditions related to metabolic disorders and cardiovascular disease.[2][8]
References
- ↑ Ambros, V (2001). "microRNAs: tiny regulators with great potential". Cell 107 (7): 823–826. doi:10.1016/S0092-8674(01)00616-X. PMID 11779458.
- ↑ 2.0 2.1 2.2 Najafi-Shoushtari, SH (Jun 2011). "MicroRNAs in cardiometabolic disease.". Current Atherosclerosis Reports 13 (3): 202–7. doi:10.1007/s11883-011-0179-y. PMID 21461683.
- ↑ Fernández-Hernando, C; Suárez, Y; Rayner, KJ; Moore, KJ (Apr 2011). "MicroRNAs in lipid metabolism.". Current Opinion in Lipidology 22 (2): 86–92. doi:10.1097/MOL.0b013e3283428d9d. PMID 21178770.
- ↑ Moore, KJ; Rayner, KJ; Suárez, Y; Fernández-Hernando, C (Dec 2010). "microRNAs and cholesterol metabolism.". Trends in Endocrinology and Metabolism 21 (12): 699–706. doi:10.1016/j.tem.2010.08.008. PMID 20880716.
- ↑ "miR-33a/b contribute to the regulation of fatty acid metabolism and insulin signaling". Proc. Natl. Acad. Sci. U.S.A. 108 (22): 9232–7. May 2011. doi:10.1073/pnas.1102281108. PMID 21576456. Bibcode: 2011PNAS..108.9232D.
- ↑ Herrera-Merchan, A; Cerrato, C; Luengo, G; Dominguez, O; Piris, MA; Serrano, M; Gonzalez, S (Aug 15, 2010). "miR-33-mediated downregulation of p53 controls hematopoietic stem cell self-renewal.". Cell Cycle 9 (16): 3277–85. doi:10.4161/cc.9.16.12598. PMID 20703086.
- ↑ Fuster, JJ; Andrés, V (Sep 1, 2010). "A role for miR-33 in p53 regulation: New perspectives for hematopoietic stem cell research.". Cell Cycle 9 (17): 3397–8. doi:10.4161/cc.9.17.13070. PMID 20861665.
- ↑ Najafi-Shoushtari, SH; Kristo, F; Li, Y; Shioda, T; Cohen, DE; Gerszten, RE; Näär, AM (Jun 18, 2010). "MicroRNA-33 and the SREBP host genes cooperate to control cholesterol homeostasis.". Science 328 (5985): 1566–9. doi:10.1126/science.1189123. PMID 20466882. Bibcode: 2010Sci...328.1566N.
External links
Original source: https://en.wikipedia.org/wiki/MiR-33.
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