Team:Virginia Commonwealth/Design

From 2009.igem.org

(Difference between revisions)
(UP-element design)
(UP-element design)
Line 18: Line 18:
[[Image:VCU 2009 UP-element variable regions.png|thumb|center|650px|UP-element consensus sequence and observed variable regions for selected sequences (that most closely matched the consensus sequence)]]
[[Image:VCU 2009 UP-element variable regions.png|thumb|center|650px|UP-element consensus sequence and observed variable regions for selected sequences (that most closely matched the consensus sequence)]]
-
We separated the UP-element sequence into regions of highly conserved and highly variable nucleotide frequency.  We hypothesized that variation of strength of the UP-element is attributed to the variable regions of the UP-element.  Upon further analysis of the nucleotide frequency in the variable regions we determined that changing a single base to the second most frequent nucleotide would allow us to quantify the relationship between nucleotide frequency and UP-element strength.
+
We separated the UP-element sequence into regions of highly conserved and highly variable nucleotide frequency.  We hypothesized that variation of strength of the UP-element is attributed to the variable regions within the sequence.  Upon further analysis of the nucleotide frequency in the variable regions we determined that changing a single base to the second most frequent nucleotide would allow us to quantify the relationship between nucleotide frequency and UP-element strength.
[[Image:VCU 2009 UP-element design sequences.png|thumb|center|930px|Sequences of designed UP-elements]]
[[Image:VCU 2009 UP-element design sequences.png|thumb|center|930px|Sequences of designed UP-elements]]

Revision as of 18:23, 21 October 2009


UP-element design

UP-elements are known to significantly increase the RNA polymerase-recruiting power of promoters by interacting with the alpha subunit of RNA polymerase. Work has been done to identify a consensus sequence for this transcriptional enhancer based on 31 natural E. coli promoters (Estrem ST, Gaal T, Ross W, Gourse RL, Identification of an UP element consensus sequence for bacterial promoters, PNAS, (1998), 95, 9761-9766.).

Figure 1: Tabulation of UP-elements in E. coli and nucleotide frequency at each position (adapted from Estrem ST, Gaal T, Ross W, Gourse RL, Identification of an UP element consensus sequence for bacterial promoters, PNAS, (1998), 95, 9761-9766.)


We are working on creating this UP element as a modular BioBrick part and characterizing its activity using the promoter characterization method that we develop. We will also manipulate this element using a bottom-up design approach to get UP elements of varying degree's of strength. Thus increasing the level of control we have over gene expression.

Tabulation of UP-element sequences in order of observed strengths and correlation with nucleotide frequency

Data showed direct correlation between the strength of naturally occurring UP elements and the frequency of each nucleotide at each respective position. Thirty one UP element sequences were analyzed for nucleotide frequency and the relative activity was tabulated for each sequence (Estrem, et. al). From this a consensus UP element sequence was identified which was composed of the most frequently occurring nucleotide at each position. This consensus sequence is theoretically the strongest UP element sequence.


UP-element consensus sequence and observed variable regions for selected sequences (that most closely matched the consensus sequence)

We separated the UP-element sequence into regions of highly conserved and highly variable nucleotide frequency. We hypothesized that variation of strength of the UP-element is attributed to the variable regions within the sequence. Upon further analysis of the nucleotide frequency in the variable regions we determined that changing a single base to the second most frequent nucleotide would allow us to quantify the relationship between nucleotide frequency and UP-element strength.

Sequences of designed UP-elements

Design strategies

Promoter design will be approached from the bottom up. First, a consensus promoter sequence will be studied and accepted by researching the work done by others on various promoters. This consensus will be our starting point as we identify which nucleotide and nucleotide sequences are most important to RNAP binding affinity. We will use direct synthesis to construct promoter sequences that we will test.

Future work

  • Constitutive promoters
    • There are several types of constitutive promoters that we can focus on. These promoters are separate in regard to their respective sigma binding domains. Constitutive promoters that interact with the sigma 70 domain of RNAP are most common most prevalent being as how sigma 70 RNAP is most common at normal cellular growth conditions. The alternatives would be sigma 54 and sigma 32 binding factors, these types of polymerases are more active when the cell is under certain strain, such as heat shock of nitrogen starvation.
    • There has already been considerable work done with sigma 70 RNAP including an established promoter library of varying promoter strengths available on the parts registry. We will develop and implement a method to fully characterize and standardize these promoters' activity and upload it to the registry.


  • T7 Promoters
    • T7 phage promoters have long been utilized as a way to create orthogonal gene expression. There is very little variation in the strength of T7 promoters available via the BioBrick registry. Our goal is to identify a consensus T7 promoter sequence and use our bottom-up design approach to create a library of T7 promoters which we will characterize and upload to the registry.