Presentation is loading. Please wait.

Presentation is loading. Please wait.

dCIN5 and Wildtype Transcription Factor Mapping in Cold Shock

Published byGervase Matthews Modified over 6 years ago

Similar presentations

Presentation on theme: "dCIN5 and Wildtype Transcription Factor Mapping in Cold Shock"— Presentation transcript:

1 dCIN5 and Wildtype Transcription Factor Mapping in Cold Shock
William Gendron and Jeffrey Crosson

2 Outline Background: Yeast, Transcription Factors and Cold Shock
Results GO Terms GRN Weighting+Production GRN Mapping Comparison between our respective networks Discussion and future plans

3 Background Saccharomyces cerevisae is the eukaryotic model organism
Chemostat models have been used to limit the stress to one variable Cold shock has not been as analyzed as other stressors (Tai et al, 2007)

4 Novel Cold Shock Analysis with mutant dCIN5 and wildtype
Received microarray data Purpose: to create a novel model of yeast under cold shock focusing on interactions in combination with dCIN5

5 GO Terms GO: fungal-type cell wall organization: This showed an increase in expression of the cell wall construction genes. This is a known response, probably to rebuild damage. GO: nucleoplasm: This is involved with regulating the genome and RNA, which is to be expected when the cell is reacting to new conditions. GO: mRNA catabolic process: Similar to the one above, this is involved in the breakdown of RNA molecules. GO: organic cyclic compound catabolic process: This would break down organic cyclic compounds and therefore could be related to the RNA.

6 Wil’s Weight Comparison

7 Jeff’s Weight Comparison

8 Wil’s Production Rate Comparison

9 Jeff’s Production Rate Comparison

10 Fixed B Weight Comparison

11 Estimated B Comparison

12 Fixed B Production Rate Comparison

13 Compared Production: Estimated

14 Wil’s Fixed B GRNsight Map

15 Wil’s Estimated B GRNsight Map

16 Jeff’s Fixed B GRNsight Map

17 Jeff’s Estimated B GRNsight Map

18 CIN5 Graph Comparison Fixed B Estimated B Wil

19 HMO1 Graph Comparison Fixed B Estimated B

20 STB5 Graph Comparison Fixed B Estimated B Wil

21 Wil’s Estimated-b GRNmap

22 MIG2 Graph Comparison Fixed B Estimated B

23 Wil’s Estimated-b GRNmap

24 CYC8 Graph Comparison Fixed B Estimated B Wil

25 Concluding thoughts Discrepancies between our weights
Even slight changes to the network composition will alter the genes expected effect Can visualize alterations that result from deletion. Can be seen in maps and plots. Wil

26 Overview Background: Yeast, Transcription Factors and Cold Shock
Results GO Terms GRN Weighting+Production GRN Mapping Comparison between our respective networks Discussion and future plans

27 Ideas for the future Larger maps
Is this possible? Will this create the most representative/accurate values? Find which gene is temperature sensitive? Can we use these networks to find genes that are the first to react to the temperature change? Wil

28 Acknowledgements and References
Dr. Kam Dahlquist Dr. Ben Fitzpatrick The class: MATH : Survey of Biomathematics 2014, Gene Ontology Consortation, 7 April 2015 Tai, Siwe L. "Acclimation of Saccharomyces Cerevisiae to Low Temperature: A Chemostat-based Transcriptome Analysis." The American Society for Cell Biology, 1 Dec Web. 1 May <http%3A%2F%2Fwww.molbiolcell.org%2Fcontent%2F18%2F12%2F5100.full> Coller, John. Sample Microarray. Digital image. Microarray.org. The Board of Trustees of Leland Stanford Junior University, Web. 1 May <

29 QUESTIONS? ?

Download ppt "dCIN5 and Wildtype Transcription Factor Mapping in Cold Shock"

Similar presentations

The Effects of an Increasing Dilution Rate on Biomass Growth and Nitrogen Metabolism of Saccharomyces cerevisiae Kasey O’Connor Ashley Rhoades Department.

The Effects of an Increasing Dilution Rate on Biomass Growth and Nitrogen Metabolism of Saccharomyces cerevisiae Kasey O’Connor Ashley Rhoades Department.
Modeling the Gene Expression of Saccharomyces cerevisiae Δcin5 Under Cold Shock Conditions Kevin McKay Laura Terada Department of Biology Loyola Marymount.

Modeling the Gene Expression of Saccharomyces cerevisiae Δcin5 Under Cold Shock Conditions Kevin McKay Laura Terada Department of Biology Loyola Marymount.
Software Refactoring and Usability Enhancement for GRNmap, a Gene Regulatory Network Modeling Application Mathematical Model Equation 2. Equation 3. Future.

Software Refactoring and Usability Enhancement for GRNmap, a Gene Regulatory Network Modeling Application Mathematical Model Equation 2. Equation 3. Future.
Determining the Identity and Dynamics of the Gene Regulatory Network Controlling the Response to Cold Shock in Saccharomyces cerevisiae June 24, 2015.

Determining the Identity and Dynamics of the Gene Regulatory Network Controlling the Response to Cold Shock in Saccharomyces cerevisiae June 24, 2015.
Sarah Carratt and Carmen Castaneda Department of Biology Loyola Marymount University BIOL 398/MATH 388 March 24, 2011 Cold Adaption in Budding Yeast Babette.

Sarah Carratt and Carmen Castaneda Department of Biology Loyola Marymount University BIOL 398/MATH 388 March 24, 2011 Cold Adaption in Budding Yeast Babette.
Deletion of ZAP1 as a transcriptional factor has minor effects on S. cerevisiae regulatory network in cold shock KARA DISMUKE AND KRISTEN HORSTMANN MAY.

Deletion of ZAP1 as a transcriptional factor has minor effects on S. cerevisiae regulatory network in cold shock KARA DISMUKE AND KRISTEN HORSTMANN MAY.
A COMPREHENSIVE GENE REGULATORY NETWORK FOR THE DIAUXIC SHIFT IN SACCHAROMYCES CEREVISIAE GEISTLINGER, L., CSABA, G., DIRMEIER, S., KÜFFNER, R., AND ZIMMER,

A COMPREHENSIVE GENE REGULATORY NETWORK FOR THE DIAUXIC SHIFT IN SACCHAROMYCES CEREVISIAE GEISTLINGER, L., CSABA, G., DIRMEIER, S., KÜFFNER, R., AND ZIMMER,
GRNmap Testing Analysis Grace Johnson and Natalie Williams June 10, 2015.

GRNmap Testing Analysis Grace Johnson and Natalie Williams June 10, 2015.
GRNmap Testing Grace Johnson and Natalie Williams June 3, 2015.

GRNmap Testing Grace Johnson and Natalie Williams June 3, 2015.
Open Source Projects for Undergraduate Research Experiences

Open Source Projects for Undergraduate Research Experiences
Changes in Gene Regulation in Δ Zap1 Strain of Saccharomyces cerevisiae due to Cold Shock Jim McDonald and Paul Magnano.

Changes in Gene Regulation in Δ Zap1 Strain of Saccharomyces cerevisiae due to Cold Shock Jim McDonald and Paul Magnano.
Physiological and Transcriptional Responses to Anaerobic Chemostat Cultures of Saccharomyces cerevisiae Subjected to Diurnal Temperature Cycle Kevin Wyllie.

Physiological and Transcriptional Responses to Anaerobic Chemostat Cultures of Saccharomyces cerevisiae Subjected to Diurnal Temperature Cycle Kevin Wyllie.
Data Analysis and GRNmap Testing Grace Johnson and Natalie Williams June 24, 2015.

Data Analysis and GRNmap Testing Grace Johnson and Natalie Williams June 24, 2015.
Creating a Gene Regulatory Network Comparing a Wild Type Strain with a Mutant ΔGLN3 Deletion in S. cerevisiae Showed that ΔGLN3 Exhibits No Meaningful.

Creating a Gene Regulatory Network Comparing a Wild Type Strain with a Mutant ΔGLN3 Deletion in S. cerevisiae Showed that ΔGLN3 Exhibits No Meaningful.
Nonlinear differential equation model for quantification of transcriptional regulation applied to microarray data of Saccharomyces cerevisiae Vu, T. T.,

Nonlinear differential equation model for quantification of transcriptional regulation applied to microarray data of Saccharomyces cerevisiae Vu, T. T.,
Comparing the Dynamics of the Cold Shock Gene Regulatory Network in Yeast with a Random Network K. Grace Johnson 1, Natalie E. Williams 2, Kam D. Dahlquist.

Comparing the Dynamics of the Cold Shock Gene Regulatory Network in Yeast with a Random Network K. Grace Johnson 1, Natalie E. Williams 2, Kam D. Dahlquist.
Student: Trixie Anne M. Roque, Tessa A. Morris Faculty Mentors: Dr. Kam D. Dahlquist, Dr. Ben G. Fitzpatrick, & Dr. John David N. Dionisio SURP 2015 Final.

Student: Trixie Anne M. Roque, Tessa A. Morris Faculty Mentors: Dr. Kam D. Dahlquist, Dr. Ben G. Fitzpatrick, & Dr. John David N. Dionisio SURP 2015 Final.
Comparison of the wild type of S. cerevisiae and S. paradoxus Karina Alvarez and Natalie Williams.

Comparison of the wild type of S. cerevisiae and S. paradoxus Karina Alvarez and Natalie Williams.
PROTEIN INTERACTION NETWORK – INFERENCE TOOL DIVYA RAO CANDIDATE FOR MASTER OF SCIENCE IN BIOINFORMATICS ADVISOR: Dr. FILIPPO MENCZER CAPSTONE PROJECT.

PROTEIN INTERACTION NETWORK – INFERENCE TOOL DIVYA RAO CANDIDATE FOR MASTER OF SCIENCE IN BIOINFORMATICS ADVISOR: Dr. FILIPPO MENCZER CAPSTONE PROJECT.
Outline S. cerevisiae, a eukaryote known for cold-shock adaption, used in cold-shock experiments Deletion strand HMO1 and the comparison of microarray.

Outline S. cerevisiae, a eukaryote known for cold-shock adaption, used in cold-shock experiments Deletion strand HMO1 and the comparison of microarray.

Similar presentations

Ads by Google