To date, developmental biology and tissue engineering studies on human muscle tissue use early-stage muscle cells derived from embryonic, foetal, or inducible pluripotent stem cell sources where the primary comparator is adult tissue. Human foetal skeletal & cardiac tissue, cell, and myosin functional research is very limited, with few publications and little knowledge of the structure and function with early stage isoforms of muscle sarcomere contractile and regulatory proteins. Until the fellow’s 2013 publication on foetal tissue, there was no significant work on human muscle of similar developmental stage. Dr. Geeves, collaborating with Dr. Leinwand, was able to express & isolate the motor domain of human embryonic & perinatal myosins in mouse cell lines for detailed kinetic studies, which confirmed the results in this project regarding the speed and function of the developing skeletal muscle myosin. Our data are the first biochemical and biophysical studies to date on the whole myosin protein isolated from tissue, and thus, offer validation for studies on myosin from mouse cell lines and highlight post- translational modifications of the protein. Visits to the laboratory of Poggesi & Tesi (Florence, Italy) for studies on foetal myofibrils, allowed the fellow to examine myosin function under high-strain situations, important because myosin's enzymatic functions vary more than 10-fold under strain. Together this work has established a novel framework for studying foetal muscle from the molecular to
the tissue level. With our top-to bottom, molecule to muscle tissue, thorough functional assessment in developing muscles, engineered muscle tissue can be compared to human muscle of similar developmental stage and limitations in the engineered tissue better understood through such a comparison. As the tissue engineering field grows, a better understanding of the native developmental biophysical attributes offers insights into the potentials and limitations of such projects, and how to overcome barriers in function.