Project Details
Description
PROJECT SUMMARY/ABSTRACT
Epigenetic memory is a phenomenon of trans-generational, altered trait inheritance without changes to DNA
sequence. Our present ability to predict or direct epigenomic behavior is extremely limited, even though
epigenetic factors participate in nearly all aspects of multicellular development, environmental stress response,
and disease development. There are critical gaps in our current knowledge of DNA methylation patterning, stable
epiallele formation, and the relationship of genome-wide epigenomic behavior to gene expression and phenotype
in both plant and animal systems. We have developed a system that will directly address these questions. Our
long-term goals are to decode the heritable epigenome, and its relationship to organismal phenotype, particularly
in response to stress.
What distinguishes our proposed research is the availability of robust biologicals in the model plant Arabidopsis
to impose artificial stress, recurrent heritable epigenetic memory, and methylome repatterning. These resources
emanate from discovery of the MSH1 gene, disruption of which leads to epigenomic reprogramming. Recent data
from this system lead to the overarching hypothesis that stress-induced gene expression recruits methylation
machinery to gene networks in a non-stochastic manner. To address this hypothesis, we have developed novel
genome-wide methylome analysis procedures for high-resolution identification of gene-associated methylation
repatterning. These analyses reveal gene networks that are strikingly consistent with phenotype changes, and
display repatterning that is intragenic and often subtle, yet reproducible. We have also identified epigenetic
components of the DNA methylation and RdDM pathways that are essential to reprogramming based on msh1
double mutant analysis. Building upon strong preliminary data, we propose to pursue three specific aims to
characterize trans-generational epigenomic behavior: (1) To delineate stable, de novo epialleles in the
Arabidopsis msh1 model system, exploiting a five-generation memory lineage, (2) to develop a mechanistic
understanding of stable epiallele formation in response to stress, implementing machine learning and mutant
screening, and (3) to test locus-specific mechanics of epiallele establishment, capitalizing on gene relocation to
delimit germane local chromatin features.
The proposed research will broadly impact the field by providing the first example of inducible epigenomic
reprogramming in a non-stochastic pattern that permits machine learning-based predictive modeling and
identification of cis-acting sequence features. The results will be pertinent to mammalian systems and, possibly,
to diagnostic strategies for diseases with a strong GxE component.
Status | Finished |
---|---|
Effective start/end date | 8/1/19 → 6/30/23 |
Funding
- National Institute of General Medical Sciences: $319,720.00
- National Institute of General Medical Sciences: $319,720.00
- National Institute of General Medical Sciences: $319,720.00
- National Institute of General Medical Sciences: $319,720.00
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