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Bursting may result from the stochastic nature of biochemical events superimposed upon a two or more step fluctuation. In its most simple form, the gene can exist in two states, one where activity is negligible and one where there is a certain probability of activation.<ref>{{cite journal | pmid=18957198 |year=2008 |last1=Raj |first1=A |last2=Van Oudenaarden |first2=A |title=Stochastic gene expression and its consequences |volume=135 |issue=2 |pages=216–26 |doi=10.1016/j.cell.2008.09.050 |journal=Cell | pmc=3118044}}</ref> Only in the second state does transcription readily occur. Whilst the nuclear and signaling landscapes of complex [[eukaryotic]] nuclei are likely to favour more than two simple states- for example, there are over twenty post-translational modifications of nucleosomes known, this simple two step model perhaps provides a reasonable intellectual framework for understanding the changing probabilities affecting transcription. It seems likely that some rudimentary eukaryotes have genes which do not show bursting. The genes are always in the permissive state, with a simple probability describing the numbers of RNAs generated.<ref>{{cite journal |pmid=19011635 |year=2008 |last1=Zenklusen |first1=D |last2=Larson |first2=DR |last3=Singer |first3=RH |title=Single-RNA counting reveals alternative modes of gene expression in yeast |volume=15 |issue=12 |pages=1263–71 |doi=10.1038/nsmb.1514 |journal=Nature structural & molecular biology |pmc=3154325}}</ref>
Bursting may result from the stochastic nature of biochemical events superimposed upon a two or more step fluctuation. In its most simple form, the gene can exist in two states, one where activity is negligible and one where there is a certain probability of activation.<ref>{{cite journal | pmid=18957198 |year=2008 |last1=Raj |first1=A |last2=Van Oudenaarden |first2=A |title=Stochastic gene expression and its consequences |volume=135 |issue=2 |pages=216–26 |doi=10.1016/j.cell.2008.09.050 |journal=Cell | pmc=3118044}}</ref> Only in the second state does transcription readily occur. Whilst the nuclear and signaling landscapes of complex [[eukaryotic]] nuclei are likely to favour more than two simple states- for example, there are over twenty post-translational modifications of nucleosomes known, this simple two step model perhaps provides a reasonable intellectual framework for understanding the changing probabilities affecting transcription. It seems likely that some rudimentary eukaryotes have genes which do not show bursting. The genes are always in the permissive state, with a simple probability describing the numbers of RNAs generated.<ref>{{cite journal |pmid=19011635 |year=2008 |last1=Zenklusen |first1=D |last2=Larson |first2=DR |last3=Singer |first3=RH |title=Single-RNA counting reveals alternative modes of gene expression in yeast |volume=15 |issue=12 |pages=1263–71 |doi=10.1038/nsmb.1514 |journal=Nature structural & molecular biology |pmc=3154325}}</ref>


What do the repressive and permissive states represent? An attractive idea is that the repressed state is a closed [[chromatin]] conformation whilst the permissive state is an open one. Another hypothesis is that the fluctuations reflect transition between bound pre-initiation complexes (permissive) and dissociated ones (restrictive). Bursts may also result from bursty signalling, cell cycle effects or movement of chromatin to and from [[transcription factories]]. Recent data suggests different degrees of supercoiling distinguish the permissive and inactive states<ref>{{cite pmid|25036631}}</ref>.
What do the repressive and permissive states represent? An attractive idea is that the repressed state is a closed [[chromatin]] conformation whilst the permissive state is an open one. Another hypothesis is that the fluctuations reflect transition between bound pre-initiation complexes (permissive) and dissociated ones (restrictive). Bursts may also result from bursty signalling, cell cycle effects or movement of chromatin to and from [[transcription factories]]. Recent data suggest different degrees of supercoiling distinguish the permissive and inactive states<ref>{{cite pmid|25036631}}</ref>.


The bursting phenomenon, as opposed to simple probabilistic models of transcription, can account for the high variability (see [[transcriptional noise]]) in gene expression occurring between cells in isogenic populations. This variability in turn can have tremendous consequences on cell behaviour, and must be mitigated or integrated. In certain contexts, such as the survival of microbes in rapidly changing stressful environments, or several types of scattered differentiation, the variability may be essential<ref>{{cite pmid|18388284}}</ref>. Variability also impacts upon the effectiveness of clinical treatment, with resistance of bacteria to [[antibiotics]] demonstrably caused by non-genetic differences.<ref>{{cite pmid|6348026}}</ref><ref>{{cite pmid|20528688}}</ref> Variability in gene expression may also contribute to resistance of sub-populations of cancer cells to chemotherapy.<ref>{{cite pmid|20371346}}</ref>
The bursting phenomenon, as opposed to simple probabilistic models of transcription, can account for the high variability (see [[transcriptional noise]]) in gene expression occurring between cells in isogenic populations. This variability in turn can have tremendous consequences on cell behaviour, and must be mitigated or integrated. In certain contexts, such as the survival of microbes in rapidly changing stressful environments, or several types of scattered differentiation, the variability may be essential<ref>{{cite pmid|18388284}}</ref>. Variability also impacts upon the effectiveness of clinical treatment, with resistance of bacteria to [[antibiotics]] demonstrably caused by non-genetic differences.<ref>{{cite pmid|6348026}}</ref><ref>{{cite pmid|20528688}}</ref> Variability in gene expression may also contribute to resistance of sub-populations of cancer cells to chemotherapy.<ref>{{cite pmid|20371346}}</ref>

Revision as of 12:32, 26 June 2015

Transcriptional bursting, also known as transcriptional pulsing, is a fundamental property of genes in which transcription from DNA to RNA can occur in "bursts" or "pulses", which has been observed in diverse organism from bacteria to humans.[1][2][3][4] This phenomenon has recently come to light with the advent of new technologies, such as MS2 tagging, to detect RNA production in single cells, allowing precise measurements of RNA number or RNA appearance at the gene. Other, more widespread techniques, such as Northern blotting, microarrays, RT-PCR and RNA-Seq, measure bulk RNA levels from homogenous population extracts. These techniques lose dynamic information from individual cells and give the impression that transcription is a continuous smooth process. Observed at an individual cell level, transcription is irregular, with strong periods of activity interspersed by long periods of inactivity.

Bursting may result from the stochastic nature of biochemical events superimposed upon a two or more step fluctuation. In its most simple form, the gene can exist in two states, one where activity is negligible and one where there is a certain probability of activation.[5] Only in the second state does transcription readily occur. Whilst the nuclear and signaling landscapes of complex eukaryotic nuclei are likely to favour more than two simple states- for example, there are over twenty post-translational modifications of nucleosomes known, this simple two step model perhaps provides a reasonable intellectual framework for understanding the changing probabilities affecting transcription. It seems likely that some rudimentary eukaryotes have genes which do not show bursting. The genes are always in the permissive state, with a simple probability describing the numbers of RNAs generated.[6]

What do the repressive and permissive states represent? An attractive idea is that the repressed state is a closed chromatin conformation whilst the permissive state is an open one. Another hypothesis is that the fluctuations reflect transition between bound pre-initiation complexes (permissive) and dissociated ones (restrictive). Bursts may also result from bursty signalling, cell cycle effects or movement of chromatin to and from transcription factories. Recent data suggest different degrees of supercoiling distinguish the permissive and inactive states[7].

The bursting phenomenon, as opposed to simple probabilistic models of transcription, can account for the high variability (see transcriptional noise) in gene expression occurring between cells in isogenic populations. This variability in turn can have tremendous consequences on cell behaviour, and must be mitigated or integrated. In certain contexts, such as the survival of microbes in rapidly changing stressful environments, or several types of scattered differentiation, the variability may be essential[8]. Variability also impacts upon the effectiveness of clinical treatment, with resistance of bacteria to antibiotics demonstrably caused by non-genetic differences.[9][10] Variability in gene expression may also contribute to resistance of sub-populations of cancer cells to chemotherapy.[11]

Notes

  1. ^ Golding, I; Paulsson, J; Zawilski, SM; Cox, EC (2005). "Real-time kinetics of gene activity in individual bacteria". Cell. 123 (6): 1025–36. doi:10.1016/j.cell.2005.09.031. PMID 16360033.
  2. ^ Chubb, JR; Trcek, T; Shenoy, SM; Singer, RH (2006). "Transcriptional pulsing of a developmental gene". Current biology : CB. 16 (10): 1018–25. doi:10.1016/j.cub.2006.03.092. PMID 16713960.
  3. ^ Raj, A; Peskin, CS; Tranchina, D; Vargas, DY; Tyagi, S (2006). "Stochastic mRNA Synthesis in Mammalian Cells". PLoS Biology. 4 (10): e309. doi:10.1371/journal.pbio.0040309. PMC 1563489. PMID 17048983.{{cite journal}}: CS1 maint: unflagged free DOI (link)
  4. ^ Attention: This template ({{cite pmid}}) is deprecated. To cite the publication identified by PMID 25728770, please use {{cite journal}} with |pmid=25728770 instead.
  5. ^ Raj, A; Van Oudenaarden, A (2008). "Stochastic gene expression and its consequences". Cell. 135 (2): 216–26. doi:10.1016/j.cell.2008.09.050. PMC 3118044. PMID 18957198.
  6. ^ Zenklusen, D; Larson, DR; Singer, RH (2008). "Single-RNA counting reveals alternative modes of gene expression in yeast". Nature structural & molecular biology. 15 (12): 1263–71. doi:10.1038/nsmb.1514. PMC 3154325. PMID 19011635.
  7. ^ Attention: This template ({{cite pmid}}) is deprecated. To cite the publication identified by PMID 25036631, please use {{cite journal}} with |pmid=25036631 instead.
  8. ^ Attention: This template ({{cite pmid}}) is deprecated. To cite the publication identified by PMID 18388284, please use {{cite journal}} with |pmid=18388284 instead.
  9. ^ Attention: This template ({{cite pmid}}) is deprecated. To cite the publication identified by PMID 6348026, please use {{cite journal}} with |pmid=6348026 instead.
  10. ^ Attention: This template ({{cite pmid}}) is deprecated. To cite the publication identified by PMID 20528688, please use {{cite journal}} with |pmid=20528688 instead.
  11. ^ Attention: This template ({{cite pmid}}) is deprecated. To cite the publication identified by PMID 20371346, please use {{cite journal}} with |pmid=20371346 instead.
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