Benoit Bruneau, PhD

Professor
Department of Pediatrics
+1 415 734-2708
Research Description: 

The main focus of our lab is to understand how a heart becomes a heart: what cell lineage decisions take place to direct cardiac differentiation, and what morphogenetic and patterning processes occur to assemble all of the heart's components into a functional organ. We are primarily interested in regulation of these processes by transcriptional regulatory mechanisms that include DNA-binding transcription factors, chromatin remodeling complexes, and histone modifications. We have used this knowledge to understand disease mechanisms, but also to devise strategies for cardiac regeneration.

Why study heart development? We believe that primary defects in patterning in early heart development are at the root of congenital heart defects, which affect approximately 1% of live-born children, and we want to understand how these defects occur, to perhaps be able to uncover new and improved diagnostic or even therapeutic options. Also, by understanding how cardiac lineage specification occurs, we can better design stem cell-based interventions of cardiac repair, based on the knowledge of what drives an uncommitted cell towards a specific cardiac fate. We have recently focused our efforts on cardiac chromatin remodeling and modification factors, enzymes that unwind DNA or modify histones to turn genes on or off. We are particularly interested in how these factors control cardiac cell lineage decisions. These chromatin remodeling factors may also be key to pushing a stem cell into becoming a heart cell, perhaps opening up new avenues for cardiac regenerative medicine.

Primary Thematic Area: 
Developmental & Stem Cell Biology
Secondary Thematic Area: 
Vascular & Cardiac Biology
Research Summary: 
Transcriptional regulation of cardiac morphogenesis and differentiation
Publications: 

Heart tube morphogenesis is regulated by segment-specific gene regulatory networks controlled by MEF2C.

bioRxiv : the preprint server for biology

Muncie-Vasic JM, Sinha T, Clark AP, Brower EF, Saucerman JJ, Black BL, Bruneau BG

TBXT dose sensitivity and the decoupling of nascent mesoderm specification from EMT progression in 2D human gastruloids.

Development (Cambridge, England)

Bulger EA, Muncie-Vasic I, Libby ARG, McDevitt TC, Bruneau BG

A TBX5-dependent compartment boundary patterns the cardiac interventricular septum.

bioRxiv : the preprint server for biology

Kathiriya IS, Dominguez MH, Rao KS, Muncie-Vasic JM, Patrick Devine W, Hu KM, Hota SK, Garay BI, Quintero D, Goyal P, Matthews MN, Thomas R, Sukonnik T, Miguel-Perez D, Winchester S, Brower EF, Forjaz A, Wu PH, Wirtz D, Kiemen AL, Bruneau BG

CDX2 dose-dependently influences the gene regulatory network underlying human extraembryonic mesoderm development.

bioRxiv : the preprint server for biology

Bulger EA, McDevitt TC, Bruneau BG