Mammalian hibernation: cellular and molecular responses to depressed metabolism and low temperature HV Carey, MT Andrews, SL Martin Physiological reviews 83 (4), 1153-1181, 2003 | 1347 | 2003 |
Low-temperature carbon utilization is regulated by novel gene activity in the heart of a hibernating mammal MT Andrews, TL Squire, CM Bowen, MB Rollins Proceedings of the National Academy of Sciences 95 (14), 8392-8397, 1998 | 206 | 1998 |
Advances in molecular biology of hibernation in mammals MT Andrews Bioessays 29 (5), 431-440, 2007 | 201 | 2007 |
Coordinate expression of the PDK4 gene: a means of regulating fuel selection in a hibernating mammal MJ Buck, TL Squire, MT Andrews Physiological genomics 8 (1), 5-13, 2002 | 196 | 2002 |
Torpor induction in mammals: recent discoveries fueling new ideas RG Melvin, MT Andrews Trends in Endocrinology & Metabolism 20 (10), 490-498, 2009 | 194 | 2009 |
Adaptive mechanisms regulate preferred utilization of ketones in the heart and brain of a hibernating mammal during arousal from torpor MT Andrews, KP Russeth, LR Drewes, PG Henry American Journal of Physiology-Regulatory, Integrative and Comparative …, 2009 | 145 | 2009 |
Seasonal and regional differences in gene expression in the brain of a hibernating mammal C Schwartz, M Hampton, MT Andrews PloS one 8 (3), e58427, 2013 | 140 | 2013 |
Elements essential for processing intronic U14 snoRNA are located at the termini of the mature snoRNA sequence and include conserved nucleotide boxes C and D. NJ Watkins, RD Leverette, L Xia, MT Andrews, ES Maxwell Rna 2 (2), 118-133, 1996 | 113 | 1996 |
Mouse U14 snRNA is a processed intron of the cognate hsc70 heat shock pre-messenger RNA RD Leverette, MT Andrews, ES Maxwell Cell 71 (7), 1215-1221, 1992 | 113 | 1992 |
Deep sequencing the transcriptome reveals seasonal adaptive mechanisms in a hibernating mammal M Hampton, RG Melvin, AH Kendall, BR Kirkpatrick, N Peterson, ... PloS one 6 (10), e27021, 2011 | 110 | 2011 |
Digital transcriptome analysis indicates adaptive mechanisms in the heart of a hibernating mammal KM Brauch, ND Dhruv, EA Hanse, MT Andrews Physiological genomics 23 (2), 227-234, 2005 | 96 | 2005 |
Transcriptomic analysis of brown adipose tissue across the physiological extremes of natural hibernation M Hampton, RG Melvin, MT Andrews PloS one 8 (12), e85157, 2013 | 91 | 2013 |
Transient activation of oocyte 5S RNA genes in Xenopus embryos by raising the level of the trans-acting factor TFIIIA MT Andrews, DD Brown Cell 51 (3), 445-453, 1987 | 91 | 1987 |
Molecular interactions underpinning the phenotype of hibernation in mammals MT Andrews Journal of Experimental Biology 222 (2), jeb160606, 2019 | 80 | 2019 |
Genes controlling the metabolic switch in hibernating mammals MT Andrews Biochemical Society Transactions 32 (6), 1021-1024, 2004 | 78 | 2004 |
Gene expression changes controlling distinct adaptations in the heart and skeletal muscle of a hibernating mammal KL Vermillion, KJ Anderson, M Hampton, MT Andrews Physiological Genomics 47 (3), 58-74, 2015 | 64 | 2015 |
Nature's fat-burning machine: brown adipose tissue in a hibernating mammal MA Ballinger, MT Andrews Journal of Experimental Biology 221 (Suppl_1), jeb162586, 2018 | 63 | 2018 |
Circulation and metabolic rates in a natural hibernator: an integrative physiological model M Hampton, BT Nelson, MT Andrews American Journal of Physiology-Regulatory, Integrative and Comparative …, 2010 | 63 | 2010 |
Brain energy metabolism and neurotransmission at near‐freezing temperatures: in vivo1H MRS study of a hibernating mammal PG Henry, KP Russeth, I Tkac, LR Drewes, MT Andrews, R Gruetter Journal of neurochemistry 101 (6), 1505-1515, 2007 | 62 | 2007 |
Expression of a chimeric retroviral-lipase mRNA confers enhanced lipolysis in a hibernating mammal VW Bauer, TL Squire, ME Lowe, MT Andrews American Journal of Physiology-Regulatory, Integrative and Comparative …, 2001 | 61 | 2001 |