Abstract
Congenital vertebral malformations (CVMs) comprise a group of spinal abnormalities that include alterations in vertebral shape or number. Evidence suggests CVMs have a genetic link, possibly resulting from mutations in multiple genes. One candidate gene is T. T protein, a transcription factor found in a variety of animals including humans, is essential for correct embryonic development and guides the development of bone and cartilage from embryonic mesodermal tissue. T protein accumulates in the nuclei of notochord cells, interacts with DNA at specific genes, and acts as a genetic switch to activate the genes. T protein binds to the major and minor grooves of DNA as a dimer. Mutations in T (turning “off” the T protein switch) are hypothesized to result in defects in spinal development. The Cedarburg SMART (Students Modeling A Research Topic) Team has designed a partial model of T protein using 3D printing technology to investigate its structure‐function relationship, focusing primarily on the residues important for dimerization of T (Pro125, Asp126, and Pro128) and for binding DNA (Arg67). A 3D model could indicate how the location of the mutations may impact the function of T. T could consequently be a potential target for the development of treatment or prevention options. Program supported by a grant from NIH‐CTSA.
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