Following his Postdoctoral fellowship, Hood joined York University’s School of Kinesiology and Health Science, and the Department of Biology (Faculty of Graduate Studies) as an Assistant Professor in 1988. Hood became an Associate Professor in 1992, and Full Professor in 1999.[1]
Hood is the founding director, since 2009, of York University’s Muscle Health Research Centre (MHRC).[6]
Research
Hood has published over 180 full-paper academic publications in
peer-reviewed journals and book chapters as well as greater than 260 abstracts with his trainees. His research program is focused on the study of "Mitochondrial Turnover in Health and Disease”, with a focus on
mammalian skeletal muscle and the role of exercise and/or disuse and aging.[7] He has used a number of
in vivo and
cell culture experimental models to interrogate the mechanisms of both mitochondrial synthesis (
biogenesis), as well as degradation (
mitophagy) in muscle. In his research, he also employs multi-disciplinary approaches involving
physiological,
biochemical and
molecular biology techniques.[2]
In 1987, Hood examined
leucinemetabolism during steady-state conditions as a function of
leucine concentration and metabolic rate (VO2), and found out that leucine is metabolized by muscle but is not a major contributor to the energy cost of
muscle contractions.[4] His research also indicated that mitochondrial and
nuclear gene products are coordinately regulated during adaptations to contractile activity.[5]
In his work, Hood also provided an extensive description of mitochondrial and performance decrements during chronic muscle disuse.[8][9] He was the first to determine that
thyroid hormone modifies
mitochondria in heart and muscle during growth and development, and repairs mitochondrial defects in diseased cells, in part via increases in protein import.[10][11][12] He along with co-workers also discovered that contractile activity (i.e. exercise) induces calcium, AMP kinase and reactive oxygen species signaling to increase the transcription of nuclear genes, leading to mitochondrial biogenesis.[13] He also conducted a number of studies on muscle mitochondrial biogenesis, and found out that it occurs via the increased expression of fusion, compared to fission regulatory proteins,[14] and is accompanied by accelerated protein import into a growing mitochondrial reticulum as a result of exercise.[15][16]
In a series of papers published in 2007 and 2009, Hood discussed that mitochondrially-mediated cell death (
apoptosis) in muscle is increased with age and disuse, and attenuated with exercise.[17][18][19] He was also the pioneer in providing descriptions of how p53 controls mitochondrial content and function in muscle via exercise, in part via signaling and interaction with
mtDNA.[20][21] His research further indicated that exercise induces lysosomal biogenesis in skeletal muscle and overcomes lysosomal impairments leading to improved mitochondrial function.[22][23] Hood’s research contributed to define the role of mitochondria in terms of sending
retrograde signals to the nucleus to activate
gene expression in response to mitochondrial stress in muscle.[24][25] He also explored the role of
PGC-1α and claimed that it is not required to restore mitochondrial respiratory function as a result of exercise,[26] but it is required for the normal exercise-induced signaling of nuclear gene expression and the induction of
mitophagy.[27]
Hood gave the first definition of a role for parkin in exercising and aging skeletal muscle,[28] and demonstrated that exercise serves as “Mitochondrial Medicine” for muscle.[29][30] Furthermore, he discovered that exercise and
resveratrol synergistically increase mitochondria in muscles.[31]
^Oliveira, A. N.; Richards, B. J.; Slavin, M.; Hood, D. A. (2021). "Exercise Is Muscle Mitochondrial Medicine". Exercise and Sport Sciences Reviews. 49 (2): 67–76.
doi:
10.1249/JES.0000000000000250.
PMID33720909.