Prof. Christopher B Burge
Uncas (1923) and Helen Whitaker Professor of Biology and Biological Engineering
Associate Member, Broad Institute
Primary DLC
Department of Biology
MIT Room:
68-271A
Areas of Interest and Expertise
Mechanisms and Regulation of Pre-mRNA Splicing
MicroRNAs: Genomics, Expression, and Role in Gene Regulation
Identification and Modeling of Genes and Cis-Regulatory Nucleic Acid Motifs
Prediction of Genes, Splicing Patterns, and Splicing Phenotypes of Genetic Variations
Biochemistry and Biophysics
Bioengineering
Computational and Systems Biology
MicroRNAs: Genomics, Expression, and Role in Gene Regulation
Identification and Modeling of Genes and Cis-Regulatory Nucleic Acid Motifs
Prediction of Genes, Splicing Patterns, and Splicing Phenotypes of Genetic Variations
Biochemistry and Biophysics
Bioengineering
Computational and Systems Biology
Research Summary
The interests of the Burge lab revolve around the mechanisms of gene expression and regulation in higher organisms. In the course of reading out the human genome instructions, very long pre-mRNA molecules are transcribed, and then long non-coding segments (introns) are removed and the remaining segments (exons) are ligated together in the process of RNA splicing to produce the correct messenger RNA (mRNA) that will direct protein synthesis. The Burge lab integrates computational modeling and experimental methods to investigate the rules of RNA splicing that are used by the cellular splicing machinery to identify the precise locations of exons and splice sites. Their research includes studying the mechanisms of splicing regulation, developing improved algorithms to identify genes in genomic sequences, and investigating the regulation of protein expression by the recently discovered class of small non-coding RNAs known as microRNAs.
Expression of most eukaryotic genes requires removal of one or more introns. The process of intron splicing must be extremely accurate considering that a typical human transcript from one gene is over 30,000 bases long and contains 8-10 introns which must be removed with single-base precision in order to produce the correct mRNA and protein product. Inaccurate RNA splicing due to mutations in splicing signals results in altered or truncated proteins, and mutations causing aberrant splicing are involved in about 15% of all human genetic diseases. Therefore, understanding RNA splicing rules and regulation will help in predicting disease-causing mutations. RNA splicing is also frequently regulated – about half of all human genes are alternatively spliced, producing multiple distinct mRNAs and proteins from a single gene locus.
Expression of most eukaryotic genes requires removal of one or more introns. The process of intron splicing must be extremely accurate considering that a typical human transcript from one gene is over 30,000 bases long and contains 8-10 introns which must be removed with single-base precision in order to produce the correct mRNA and protein product. Inaccurate RNA splicing due to mutations in splicing signals results in altered or truncated proteins, and mutations causing aberrant splicing are involved in about 15% of all human genetic diseases. Therefore, understanding RNA splicing rules and regulation will help in predicting disease-causing mutations. RNA splicing is also frequently regulated – about half of all human genes are alternatively spliced, producing multiple distinct mRNAs and proteins from a single gene locus.
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Projects
March 18, 2016Department of Biology
Regulation and Function of Alternative mRNA Isoform Expression in Mammals
Principal Investigator Christopher Burge
October 9, 2012Department of BiologyFunction of Sequence-Specific Regulators of RNA Splicing
Principal Investigator Christopher Burge
December 20, 2006Department of BiologyComputational Biology of Gene Expression
Principal Investigator Christopher Burge
December 20, 2006Department of BiologySplicing Regulatory Elements and Interactions
Principal Investigator Christopher Burge
December 11, 2006Department of BiologyComputational and Systems Biology Ph.D. Program (CSB)
Principal Investigator Christopher Burge