Since the completion of the Human Genome Project, there has been a natural surge in biomedical research aimed at gene discovery. Using genome-wide association studies (GWAS), bioinformatics, and other approaches, this process has focused largely on determining what genes are implicated in specific diseases.
While this process may shed light on what genes are involved in diseases, it has done little to help investigators understand why a gene or genomic region may be involved in a disease or a disease risk.
A new Research Affinity Group at CHOP Research aims to take the findings from various types of studies, including GWAS, a step further in order to understand entire networks underpinning disease susceptibility.
At the heart of the DNA-Protein Interaction Research Affinity Group is the analysis of data derived from chromatin immunoprecipitation coupled with high-throughput sequencing. More commonly referred to as ChIP-seq, the technique is used to look at how proteins like transcription factors interact with DNA, and to find the regions of the genome these transcription factors occupy to control gene expression.
The DNA-Protein Interaction research affinity group, co-led by Struan Grant, PhD, of the Department of Pediatrics and Genetics, and Andrew Wells, PhD, of the Department of Pathology, will deal with the processing and analyses of ChIP-seq and related data to gain insight into disease networks, identify vulnerabilities in given networks, and look for points amenable to therapeutic intervention.
“The new affinity group is a forum for investigators with diverse backgrounds and expertise to learn the downstream effect of transcription factors and related DNA binding proteins,” says Dr. Grant. “We can now work to analyze and translate the numerous findings made from GWAS and elsewhere — a natural step in discovering not only what causes disease but why.”
Also relevant to the goal of the affinity group is leveraging the data from the public research consortium ENCODE — the Encyclopedia Of DNA Elements — to better understand and integrate genome-wide data sets generated by investigators at CHOP. Launched by the National Human Genome Research Institute nearly a decade ago, the ENCODE project aims to ultimately identify all functional elements in the human genome sequence.
“The sequencing of genomic information is not the bottleneck — it’s the analysis,” says Dr. Wells. “The DNA-Protein Interaction affinity group creates a community that can benefit from what we can learn about disease networks through ChIP-seq and related techniques, and then develop a pipeline to find novel ways to understand and target those diseases.
The Research Affinity Group structure at the Research Institute builds upon areas of existing strength, identifies new and important research areas, and explores important, broad and interdisciplinary scientific questions that may have an impact on the health of children. Investigators collaborate across disciplines more easily to address issues of central importance to children’s health. This collaboration has the potential to link multi-talented investigators with common research interests who are widely dispersed through the Institute.
For more information on other Research Affinity Groups at CHOP Research, please visit the Institute’s website.