Post-transcriptional regulation Information & Post-transcriptional regulation Links at HealthHaven.com

This article is part of the series on: Gene expression a Molecular biology topic (portal) (Glossary)
Introduction to Genetics
General flow: DNA > RNA > Protein
special transfers (RNA > RNA, RNA > DNA, Protein > Protein)
Genetic code
Transcription
Transcription (Transcription factors, RNA Polymerase,promoter) Prokaryotic / Archaeal / Eukaryotic
post-transcriptional modification (hnRNA,Splicing)
Translation
Translation (Ribosome,tRNA) Prokaryotic / Archaeal / Eukaryotic
post-translational modification (functional groups, peptides, structural changes)
gene regulation
epigenetic regulation (Genomic imprinting)
transcriptional regulation
post-transcriptional regulation (sequestration, alternative splicing,miRNA)
translational regulation
post-translational regulation (reversible,irreversible)
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Post-transcriptional regulation is the control of gene expression at the RNA level, therefore between the transcription and the translation of the gene. ^[1]^[2]

[edit] Mechanism

The first instance of regulation is at transcription (transcriptional regulation) where due to the chromatin arrangement and due to the activity of transcription factors, genes are differentially transcribed. After being produced, the stability and distribution of the different transcripts is regulated (post-transcriptional regulation) by means of RNA binding protein (RBP) that control the various steps and rates of the transcripts: events such as alternative splicing, nuclear degradation (exosome), processing, nuclear export (three alternative pathways), sequestration in DCP2-bodies for storage or degradation, and ultimately translation. These proteins achieve these events thanks to a RNA recognition motif (RRM) that binds a specific sequence or secondary structure of the transcripts, typically at the 5’ and 3’ UTR of the transcript.

[edit] Significance

A prokaryotic example: Salmonella enterica (a pathogenic γ-proteobacterium) can express two alternative porins depending on the external environment (gut or murky water), this system involves EnvZ (osomotic sensor) which activates OmpR (transcription factor) which can bind to a high affinity promoter even at low concentrations and the low affinity promoter only at high concentrations (by definition): when the concentration of this transcription factor is high it activates OmpC and micF and inhibits OmpF, OmpF is further inhibited post-transcriptionally by micF RNA which binds to the OmpF transcript^[3]

This area of study has recently gained more importance due to the increasing evidence that post-transcriptional regulation plays a larger role than previously expected. Even though protein with DNA binding domains are more abundant than protein with RNA binding domains*, a recent study by Cheadle et al. (2005) showed that during T-cell activation 55% of significant changes at the steady-state level had no corresponding changes at the transcriptional level, meaning they were a result of stability regulation alone.^[4]

Furthermore RNA found in the nucleus is more complex than that found in the cytoplasm: more than 95% (bases) of the RNA synthesized by RNA polymerase II never reaches the cytoplasm. The main reason for this is due to the removal of introns which account for 80% of the total bases.^[5] Some studies have shown that even after processing the levels of mRNA between the cytoplasm and the nucleus differ greatly.^[6]

Developmental biology is a good source of models of regulation, but due to the technical difficulties it was easier to determine the transcription factor cascades than regulation at the RNA level. In fact several key genes such as nanos are known to bind RNA but often their targets are unknown.^[7] Although RNA binding proteins may regulate post transcriptionally large amount of the transcriptome, the targeting of a single gene is of interest to the scientific community for medical reasons, this is RNA interference and microRNAs which are both examples of posttranscriptional regulation, which regulate the destruction of RNA and change the chromatin structure. To study post-transcriptional regulation several techniques are used, such as RIP-Chip (RNA immunoprecipitation on chip).^[8]

[edit] See also

[edit] References

^ Bruce Alberts, Alexander Johnson, Julian Lewis, Martin Raff, Keith Roberts, Peter Walter (2007). Molecular Biology of the Cell (Fifth ed.). Garland Science. pp. 1268 pages. ISBN 0-8153-4105-9.
^ Weaver, Robert J. (2007). "Part V: Post-transcriptional events". Molecular Biology. Boston: McGraw Hill Higher Education. ISBN 0-07-110216-7.
^ Mims C, Nash A, Stephen J. Mims' pathogenesis of infectious disease. 2001. 5th. Academic press. ISBN 0-12-498264
^ Cheadle C, Fan J, Cho-Chung YS, Werner T, Ray J, Do L, Gorospe M, Becker KG (2005). "Control of gene expression during T cell activation: alternate regulation of mRNA transcription and mRNA stability". BMC Genomics 6 (1): 75. doi:10.1186/1471-2164-6-75. PMID 15907206.
^ Jackson DA, Pombo A, Iborra F (2000). "The balance sheet for transcription: an analysis of nuclear RNA metabolism in mammalian cells". Faseb J. 14 (2): 242–54. PMID 10657981. http://www.fasebj.org/cgi/content/abstract/14/2/242.
^ Schwanekamp JA, Sartor MA, Karyala S, Halbleib D, Medvedovic M, Tomlinson CR (2006). "Genome-wide analyses show that nuclear and cytoplasmic RNA levels are differentially affected by dioxin". Biochim. Biophys. Acta 1759 (8-9): 388–402. doi:10.1016/j.bbaexp.2006.07.005. PMID 16962184.
^ Scott F. Gilbert. Developmental Biology. Sinauer, 2003. ISBN 0-87893-258-5.
^ Keene JD, Komisarow JM, Friedersdorf MB (2006). "RIP-Chip: the isolation and identification of mRNAs, microRNAs and protein components of ribonucleoprotein complexes from cell extracts". Nat Protoc 1 (1): 302–7. doi:10.1038/nprot.2006.47. PMID 17406249.

[isbn0-8153-4105-9-0] Bruce Alberts, Alexander Johnson, Julian Lewis, Martin Raff, Keith Roberts, Peter Walter (2007). Molecular Biology of the Cell (Fifth ed.). Garland Science. pp. 1268 pages. ISBN 0-8153-4105-9.

[isbn0-07-110216-7-1] Weaver, Robert J. (2007). "Part V: Post-transcriptional events". Molecular Biology. Boston: McGraw Hill Higher Education. ISBN 0-07-110216-7.

[2] Mims C, Nash A, Stephen J. Mims' pathogenesis of infectious disease. 2001. 5th. Academic press. ISBN 0-12-498264

[pmid15907206-3] Cheadle C, Fan J, Cho-Chung YS, Werner T, Ray J, Do L, Gorospe M, Becker KG (2005). "Control of gene expression during T cell activation: alternate regulation of mRNA transcription and mRNA stability". BMC Genomics 6 (1): 75. doi:10.1186/1471-2164-6-75. PMID 15907206.

[pmid10657981-4] Jackson DA, Pombo A, Iborra F (2000). "The balance sheet for transcription: an analysis of nuclear RNA metabolism in mammalian cells". Faseb J. 14 (2): 242–54. PMID 10657981. http://www.fasebj.org/cgi/content/abstract/14/2/242.

[pmid16962184-5] Schwanekamp JA, Sartor MA, Karyala S, Halbleib D, Medvedovic M, Tomlinson CR (2006). "Genome-wide analyses show that nuclear and cytoplasmic RNA levels are differentially affected by dioxin". Biochim. Biophys. Acta 1759 (8-9): 388–402. doi:10.1016/j.bbaexp.2006.07.005. PMID 16962184.

[6] Scott F. Gilbert. Developmental Biology. Sinauer, 2003. ISBN 0-87893-258-5.

[pmid17406249-7] Keene JD, Komisarow JM, Friedersdorf MB (2006). "RIP-Chip: the isolation and identification of mRNAs, microRNAs and protein components of ribonucleoprotein complexes from cell extracts". Nat Protoc 1 (1): 302–7. doi:10.1038/nprot.2006.47. PMID 17406249.

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Contents

[edit] Mechanism

[edit] Significance

[edit] See also

[edit] References