News Release

Researchers speed identification of DNA regions that regulate gene expression

St. Jude Children's Research Hospital scientists have developed a highly efficient method to address a major challenge in biology--identifying the genetic 'switches' that regulate gene expression.

Peer-Reviewed Publication

St. Jude Children's Research Hospital

Yong Cheng, Ph.D.,

image: Corresponding author Yong Cheng, Ph.D., of the St. Jude Departments of Hematology and Computational Biology, helped develop a highly efficient method in identifying the genetic switches that regulate gene expression. view more 

Credit: St. Jude Children's Research Hospital

St. Jude Children's Research Hospital scientists have developed an integrated, high-throughput system to better understand and possibly manipulate gene expression for treatment of disorders such as sickle cell disease and beta thalassemia. The research appears today in the journal Nature Genetics.

Researchers used the system to identify dozens of DNA regulatory elements that act together to orchestrate the switch from fetal to adult hemoglobin expression. The method can also be used to study other diseases that involve gene regulation.

Regulatory elements, also called genetic switches, are scattered throughout non-coding regions of DNA. These regions do not encode genes and make up about 98% of the genome. The elements have a variety of names--enhancer, repressor, insulator and more--but the specific genes they regulate, how the regulatory elements act together, and answers to other questions have been unclear.

"Without the high-throughput system, identifying key regulatory elements is often extremely slow," said corresponding author Yong Cheng, Ph.D., of the St. Jude Departments of Hematology and Computational Biology. Mitchell Weiss, M.D., Ph.D., Hematology chair, is co-corresponding author.

"For example, despite decades of research, fewer than half of regulatory elements and the associated genetic variants that account for fetal hemoglobin levels have been identified," Cheng said.

Precision editing provides key details about regulation of gene expression

The new system combines bioinformatic prediction algorithms and an adenine base editing tool with tests to measure how base gene editing affects gene expression. Base editing works more precisely than conventional gene-editing tools such as CRISPR/Cas9, by changing a single letter in the four-letter DNA alphabet at high efficiency without creating larger insertions or deletions.

Researchers used the base editor ABEmax to make 10,156 specific edits in 307 regulatory elements that were predicted to affect fetal hemoglobin expression. The expression can modify the severity of hemoglobin disorders such as sickle cell disease. The edits changed the DNA bases adenine and thymine to guanine and cytosine. The study focused on regulatory elements in the genes BCL11A, MYB-HBS1L, KLF1 and beta-like globin genes.

Using this approach, the scientists validated the few known regulatory elements of fetal hemoglobin expression and identified many new ones.

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