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[[File:T--Paris_Saclay--fig1.png|650px|center|]] | [[File:T--Paris_Saclay--fig1.png|650px|center|]] | ||
− | <center>'''Fig 1''' : DNA transcription by RNA polymerase</center> | + | <center>'''Fig 1''' : DNA transcription by RNA polymerase.</center> |
<center>a. Binding of RNA polymerase on a promoter, a specific sequence on the DNA. b. Transcription of the DNA template into a RNA molecule</center> | <center>a. Binding of RNA polymerase on a promoter, a specific sequence on the DNA. b. Transcription of the DNA template into a RNA molecule</center> | ||
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[[File:T--Paris_Saclay--fig2_overview.png|650px|center|]] | [[File:T--Paris_Saclay--fig2_overview.png|650px|center|]] | ||
− | <center>'''Fig 2''' : Transcriptional regulation</center> | + | <center>'''Fig 2''' : Transcriptional regulation.</center> |
<center>Several mechanisms play a role in transcriptional regulation. Transcription factors (blue circles) can inhibit or enhance transcription rate.</center> | <center>Several mechanisms play a role in transcriptional regulation. Transcription factors (blue circles) can inhibit or enhance transcription rate.</center> | ||
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[[File:T--Paris_Saclay--fig4_overview.png|650px|center|]] | [[File:T--Paris_Saclay--fig4_overview.png|650px|center|]] | ||
− | <center>'''Figure 3''' : Four mechanisms allow DNA-binding proteins to find target sequences </center> | + | <center>'''Figure 3''' : Four mechanisms allow DNA-binding proteins to find target sequences.</center> |
<center>a. Sliding of RNA polymerase on DNA. b. Hopping of a DNA-binding protein from a site to an other. c. Intersegment transfer of two DNA binding proteins (dark blue circles) linked by another protein (blue circle) from a DNA segment to an other. d. Looping of DNA allowed by a DNA binding protein </center> | <center>a. Sliding of RNA polymerase on DNA. b. Hopping of a DNA-binding protein from a site to an other. c. Intersegment transfer of two DNA binding proteins (dark blue circles) linked by another protein (blue circle) from a DNA segment to an other. d. Looping of DNA allowed by a DNA binding protein </center> | ||
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==Transcription initiation== | ==Transcription initiation== | ||
− | + | Transcriptional regulation can occur at every step on the pathway to gene expression, but transcription initiation is probably the most frequently regulated step (Haugen 2008). It is the result of: | |
# The recognition of a promoter by a σ-factor; | # The recognition of a promoter by a σ-factor; | ||
# The recruitment of the other parts of the RNA polymerase; | # The recruitment of the other parts of the RNA polymerase; | ||
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# The release of the σ-factor (Browning 2002) '''[Fig. 4]'''. | # The release of the σ-factor (Browning 2002) '''[Fig. 4]'''. | ||
− | The first step, in which the σ-factor binds to the promoter, can limit the transcription rate. Moreover one σ-factor can lead to the beginning of transcription of a gene, be released and lead to the beginning of the transcription of an other one. As a result, we think that spatially close promoters can act on each others, for example by doubling the number of sequences which can recruit a σ-factor in a certain area. A strong promoter could recruit a σ-factor and after its release, this σ-factor would have a better probability of being recruited to a weaker promoter. Conversely, a strong promoter could have a better chance of recruiting a σ-factor leading to “starving” of the weaker promoters within the same area. | + | The first step, in which the σ-factor binds to the promoter, can limit the transcription rate. Moreover one σ-factor can lead to the beginning of transcription of a gene, be released and lead to the beginning of the transcription of an other one. As a result, we think that spatially close promoters can act on each others, for example by doubling the number of sequences which can recruit a σ-factor in a certain area. A strong promoter could recruit a σ-factor and after its release, this σ-factor would have a better probability of being recruited to a weaker promoter. Conversely, a strong promoter could have a better chance of recruiting a σ-factor leading to “starving” of the weaker promoters within the same area. This could be an other unstudied link between topology and transcriptional regulation. |
[[File:T--Paris_Saclay--fig3_overview.png|650px|center|]] | [[File:T--Paris_Saclay--fig3_overview.png|650px|center|]] | ||
− | <center>'''Figure 4''' : | + | <center>'''Figure 4''' : Transcription initiation mechanism.</center> |
<center>1. Binding of a σ-factor on a promoter. 2. Recruitment of RNA polymerase subunits on the σ-factor. 3. Open complex formation and beginning of transcription. 4. Release of the σ-factor and elongation</center> | <center>1. Binding of a σ-factor on a promoter. 2. Recruitment of RNA polymerase subunits on the σ-factor. 3. Open complex formation and beginning of transcription. 4. Release of the σ-factor and elongation</center> | ||
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[[File:T--Paris_Saclay--fig6.png|650px|center|]] | [[File:T--Paris_Saclay--fig6.png|650px|center|]] | ||
− | <center>'''Figure 5''': Possible chromosome conformation and conformational dynamism, From Wright ''et al.'' 2007</center> | + | <center>'''Figure 5''': Possible chromosome conformation and conformational dynamism, From Wright ''et al.'' 2007.</center> |
<center>« Curves represent genomic DNA that is compacted 21-fold and may consist of substructures including topological domains. The dimensions of the helices are 2.5 µm high with a radius of 0.3 µm, compatible with an average ''E. coli'' cell. Consecutive dots along the helices represent 1 kb of compacted genomic DNA. In this configuration the chromosome would be coiled into a single stack of 117-kb loops, with the origin and terminus at midcell. Note that several configurations are possible because of dynamical changes. The gene pair density is indicated by increasing dot size.» </center> | <center>« Curves represent genomic DNA that is compacted 21-fold and may consist of substructures including topological domains. The dimensions of the helices are 2.5 µm high with a radius of 0.3 µm, compatible with an average ''E. coli'' cell. Consecutive dots along the helices represent 1 kb of compacted genomic DNA. In this configuration the chromosome would be coiled into a single stack of 117-kb loops, with the origin and terminus at midcell. Note that several configurations are possible because of dynamical changes. The gene pair density is indicated by increasing dot size.» </center> | ||
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− | Because of this periodicity, regulation could be effective in particular area of the chromosome, leading to a fine, but integral, tuning of the genes involved in the same pathway. That | + | Because of this periodicity, regulation could be effective in particular area of the chromosome, leading to a fine, but integral, tuning of the genes involved in the same pathway. That's why concepts such as regulons (genes that are usually geographically scattered but under the control of the same regulatory factor), who were initially described with a 2D vision of the bacterial chromosomes, could be specified with the incorporation of new researches. Theories behind these concepts focused on protein-protein interactions after translation, which occurs at the same time as transcription in bacteria. Indeed, products of gene-coding-protein are synthesized near their gene and a pairing of genes can results in an increasing probability for the two proteins to interact with each others '''[Fig.6]''' (Dorman 2013). |
[[File:T--Paris_Saclay--fig7.png|650px|center|]] | [[File:T--Paris_Saclay--fig7.png|650px|center|]] | ||
− | <center>'''Figure 6''' : Nucleoid folding and gene regulation, From Dorman 2013</center> | + | <center>'''Figure 6''' : Nucleoid folding and gene regulation, From Dorman 2013.</center> |
− | <center>« A simple regulon consisting of a regulatory gene and two structural operons, A and B, is | + | <center>« A simple regulon consisting of a regulatory gene and two structural operons, A and B, is illustrated in various conformations. |
− | + | ||
− | + | ||
When the chromosome is represented in a one‐dimensional, linear form, the three genetic loci are separated by large distances in space. However, when the chromosome is reorganized as a solenoid (left) or as a plectoneme (right), the periodicity of these structures brings the three genes close together, between the regulatory gene and its two target operons. Moreover, the products of the A and B operons are produced in close proximity, favouring their interaction.»</center> | When the chromosome is represented in a one‐dimensional, linear form, the three genetic loci are separated by large distances in space. However, when the chromosome is reorganized as a solenoid (left) or as a plectoneme (right), the periodicity of these structures brings the three genes close together, between the regulatory gene and its two target operons. Moreover, the products of the A and B operons are produced in close proximity, favouring their interaction.»</center> | ||
− | + | ||
+ | In the same way a single sigma factor, specific of a group of genes, could be recruited from a promoter to another easily because of the DNA topology. Thus, gene pair associations could provide the cell with another level of regulation of transcription. These genes associations could not only be significant for protein-protein interactions after translation but could also be significant to enhance or to inhibit transcription initiation. | ||
=Question= | =Question= | ||
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[[File:T--Paris_Saclay--soleno.png|700px|center|]] | [[File:T--Paris_Saclay--soleno.png|700px|center|]] | ||
− | <center>'''Figure | + | <center>'''Figure 7''': Gene pairs and transcriptional regulation.</center> |
− | + | <center>a. Binding of a sigma factor on gene A's promoter. b. Recruitment of the other parts of the RNA polymerase (red and yellow) on the sigma factor. c. Gene A's transcription begins, producing a RNA (orange) molecule. The sigma factor is released and binds an other close promoter on a pair gene, allowing the formation of an active RNA polymerase. d. Termination of gene A's transcription, an entire RNA molecule is released. Beginning of gene B's transcription, producing a RNA (dark green) molecule. The sigma factor is released. </center> | |
[[File:T--Paris_Saclay--solenolegende.png|550px|center|]] | [[File:T--Paris_Saclay--solenolegende.png|550px|center|]] | ||
=References= | =References= | ||
+ | |||
+ | Bondos, S.E., Swint-Kruse, L., and Matthews, K.S. (2015). Flexibility and Disorder in Gene Regulation: LacI/GalR and Hox Proteins. Journal of Biological Chemistry 290, 24669–24677. | ||
Browning, D.F., and Busby, S.J.W. (2004). The regulation of bacterial transcription initiation. Nature Reviews Microbiology 2, 57–65. | Browning, D.F., and Busby, S.J.W. (2004). The regulation of bacterial transcription initiation. Nature Reviews Microbiology 2, 57–65. | ||
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Dorman, C.J. (2013). Genome architecture and global gene regulation in bacteria: making progress towards a unified model? Nature Reviews Microbiology 11, 349–355. | Dorman, C.J. (2013). Genome architecture and global gene regulation in bacteria: making progress towards a unified model? Nature Reviews Microbiology 11, 349–355. | ||
+ | |||
+ | Elowitz, Levine, Siggia, and Swain (2002). Stochastic Gene Expression in a Single Cell. Science. | ||
Esvelt, K.M., Mali, P., Braff, J.L., Moosburner, M., Yaung, S.J., and Church, G.M. (2013). Orthogonal Cas9 proteins for RNA-guided gene regulation and editing. Nature Methods 10, 1116–1121. | Esvelt, K.M., Mali, P., Braff, J.L., Moosburner, M., Yaung, S.J., and Church, G.M. (2013). Orthogonal Cas9 proteins for RNA-guided gene regulation and editing. Nature Methods 10, 1116–1121. | ||
+ | |||
+ | Friedman, L.J., Mumm, J.P., and Gelles, J. (2013). RNA polymerase approaches its promoter without long-range sliding along DNA. Proceedings of the National Academy of Sciences 110, 9740–9745. | ||
+ | |||
+ | Haugen, S.P., Ross, W., and Gourse, R.L. (2008). Advances in bacterial promoter recognition and its control by factors that do not bind DNA. Nature Reviews Microbiology 6, 507–519. | ||
Ishihama, A. (2000). Functional modulation of Escherichia coli RNA polymerase. Annu. Rev. Microbiol. 54, 499–518. | Ishihama, A. (2000). Functional modulation of Escherichia coli RNA polymerase. Annu. Rev. Microbiol. 54, 499–518. | ||
+ | |||
Lagomarsino, M.C., Espéli, O., and Junier, I. (2015). From structure to function of bacterial chromosomes: Evolutionary perspectives and ideas for new experiments. FEBS Letters 589, 2996–3004. | Lagomarsino, M.C., Espéli, O., and Junier, I. (2015). From structure to function of bacterial chromosomes: Evolutionary perspectives and ideas for new experiments. FEBS Letters 589, 2996–3004. | ||
− | + | Rocha, E.P.C. (2008). The Organization of the Bacterial Genome. Annual Review of Genetics 42, 211–233. | |
Rud, I. (2006). A synthetic promoter library for constitutive gene expression in Lactobacillus plantarum. Microbiology 152, 1011–1019. | Rud, I. (2006). A synthetic promoter library for constitutive gene expression in Lactobacillus plantarum. Microbiology 152, 1011–1019. | ||
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Wright, M.A., Kharchenko, P., Church, G.M., and Segrè, D. (2007). Chromosomal periodicity of evolutionarily conserved gene pairs. Proceedings of the National Academy of Sciences 104, 10559–10564. | Wright, M.A., Kharchenko, P., Church, G.M., and Segrè, D. (2007). Chromosomal periodicity of evolutionarily conserved gene pairs. Proceedings of the National Academy of Sciences 104, 10559–10564. | ||
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{{Team:Paris_Saclay/project_footer}} | {{Team:Paris_Saclay/project_footer}} |
Latest revision as of 02:18, 20 October 2016