Yellow-bellied Marmots (Marmota flaviventris) preserve bone strength and microstructure during hibernation

Wojda, Samantha J.; McGee‐Lawrence, Meghan E.; Gridley, Richard A.; Auger, Janene; Black, Hal L.; Donahue, Seth W.

doi:10.1016/j.bone.2011.10.013

Cited by 26 publications

(34 citation statements)

References 37 publications

(61 reference statements)

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“…Hibernators face the risk of losing bone strength during prolonged periods of inactivity. Recent studies in thirteen-lined and golden-mantled ground squirrels, marmots, and woodchucks have shown that some microstructural bone loss occurs during hibernation but macrostructural strength is maintained (24,55,92,100). During hibernation, the osteocyte lacunar porosity increases, indicating a decrease in cell number.…”

Section: Discussionmentioning

confidence: 99%

Effects of hibernation on bone marrow transcriptome in thirteen-lined ground squirrels

Cooper

Sell

Fahrenkrog

et al. 2016

Physiological Genomics

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M. Effects of hibernation on bone marrow transcriptome in thirteen-lined ground squirrels. Physiol Genomics 48: 513-525, 2016. First published May 20, 2016 doi:10.1152/physiolgenomics.00120.2015.-Mammalian hibernators adapt to prolonged periods of immobility, hypometabolism, hypothermia, and oxidative stress, each capable of reducing bone marrow activity. In this study bone marrow transcriptomes were compared among thirteen-lined ground squirrels collected in July, winter torpor, and winter interbout arousal (IBA). The results were consistent with a suppression of acquired immune responses, and a shift to innate immune responses during hibernation through higher complement expression. Consistent with the increase in adipocytes found in bone marrow of hibernators, expression of genes associated with white adipose tissue are higher during hibernation. Genes that should strengthen the bone by increasing extracellular matrix were higher during hibernation, especially the collagen genes. Finally, expression of heat shock proteins were lower, and cold-response genes were higher, during hibernation. No differential expression of hematopoietic genes involved in erythrocyte or megakaryocyte production was observed. This global view of the changes in the bone marrow transcriptome over both short term (torpor vs. IBA) and long term (torpor vs. July) hypothermia can explain several observations made about circulating blood cells and the structure and strength of the bone during hibernation. erythrocyte; leukocyte; megakaryocyte; osteoblast; adipose BONE MARROW IS A COMPLEX ORGAN consisting of many different cell types and stem cell pools. These cells express both unique and common sets of genes and likely influence each other's activities. Hematopoietic stem cells can differentiate into lymphoid progenitor cells that produce natural killer cells and lymphocytes, or into myeloid progenitor cells that give rise to erythrocytes, the remaining leukocytes, and megakaryocytes. Megakaryocytes in turn shed anucleated platelets involved in blood clotting and inflammation. Bone marrow resident mesenchymal stem cells can differentiate to produce resident bone cells including osteoblasts, adipocytes, and chondrocytes (64). Osteoblasts can terminally differentiate into osteocytes and are involved in maintaining bone strength and extracellular matrix production. Bone marrow adipose composition is affected by age, diet, and disease states. Bone marrow may also contain skeletal muscle and hepatocyte stem cell pools. Because of the rapid rate of mitosis by multiple resident stem cell pools, bone marrow is sensitive to damage by radiation and chemotherapy, leaving patients immunocompromised and anemic (25). Bone mineral density and collagen are decreased by prolonged disuse such as bed rest or immobilization (45,86). Recent studies have also demonstrated an increase in neutrophils, natural killer cells, and lymphocytes and a decrease in monocytes in patients subjected to 60 days of bed rest (38). Finally, bone marrow adipocytes increase in ...

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Section: Discussionmentioning

confidence: 99%

Effects of hibernation on bone marrow transcriptome in thirteen-lined ground squirrels

Cooper

Sell

Fahrenkrog

et al. 2016

Physiological Genomics

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“…This applies to many species, such as bears, squirrels, woodchucks, bats, hamsters, prairie dogs and marmots (Cotton, 2016;Cotton and Harlow, 2010;Doherty et al, 2012;James et al, 2011;McGee-Lawrence et al, 2015Utz et al, 2009;Wojda et al, 2012). However, some small hibernators, such as the 13-lined ground squirrel (Ictidomys tridecemlineatus) have been reported to exhibit microstructural bone loss (osteocytic osteolysis) during hibernation bouts, which has not been observed in larger hibernating animals (McGeeLawrence et al, 2011).…”

Section: Maintenance Of Musculoskeletal Properties In Hibernators Andmentioning

confidence: 99%

“…Although these studies lacked thorough quantification of a wide array of bone properties, for small mammalian hibernators there is still conflicting evidence as to whether bone loss regularly occurs during dormancy. Whereas both arctic and golden-mantled ground squirrels retain cortical bone properties and strength following hibernation (Utz et al, 2009;Wojda et al, 2012), data indicate that hibernating I. tridecemlineatus might be unable to avoid microstructural losses of cortical and trabecular bone (McGee-Lawrence et al, 2011). Nevertheless, because bone geometrical and mechanical properties do not differ significantly between hibernating and active squirrels, these animals can still perhaps activate the appropriate physiological mechanisms to maintain bone macrostructure and strength throughout hibernation in preparation for normal skeletal function during arousal.…”

Section: Mechanisms Underpinning the Inhibition Of Osteoporosismentioning

confidence: 99%

Prevention of muscle wasting and osteoporosis: the value of examining novel animal models

Reilly

Franklin

2016

Journal of Experimental Biology

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Bone mass and skeletal muscle mass are controlled by factors such as genetics, diet and nutrition, growth factors and mechanical stimuli. Whereas increased mechanical loading of the musculoskeletal system stimulates an increase in the mass and strength of skeletal muscle and bone, reduced mechanical loading and disuse rapidly promote a decrease in musculoskeletal mass, strength and ultimately performance (i.e. muscle atrophy and osteoporosis). In stark contrast to artificially immobilised laboratory mammals, animals that experience natural, prolonged bouts of disuse and reduced mechanical loading, such as hibernating mammals and aestivating frogs, consistently exhibit limited or no change in musculoskeletal performance. What factors modulate skeletal muscle and bone mass, and what physiological and molecular mechanisms protect against losses of muscle and bone during dormancy and following arousal? Understanding the events that occur in different organisms that undergo natural periods of prolonged disuse and suffer negligible musculoskeletal deterioration could not only reveal novel regulatory factors but also might lead to new therapeutic options. Here, we review recent work from a diverse array of species that has revealed novel information regarding physiological and molecular mechanisms that dormant animals may use to conserve musculoskeletal mass despite prolonged inactivity. By highlighting some of the differences and similarities in musculoskeletal biology between vertebrates that experience disparate modes of dormancy, it is hoped that this Review will stimulate new insights and ideas for future studies regarding the regulation of atrophy and osteoporosis in both natural and clinical models of muscle and bone disuse.

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“…Like bears, marmots do not lose bone mass and strength during hibernation periods lasting 5-6 mo (Wojda et al 2012). Marmots decrease their basal metabolic rate during hibernation to 5.5% of the levels observed during periods of physical activity (Hock 1969).…”

Section: Physiological and Biochemical Zoologymentioning

confidence: 99%

“…Animals that hibernate (e.g., marmots and bears) are naturally physically inactive for extended periods (6 mo or longer) annually. However, bears, marmots, woodchucks, and ground squirrels maintain bone properties, despite these long bouts of physical inactivity (McGee et al 2007bMcGee-Lawrence et al 2009aUtz et al 2009;Doherty et al 2012;Wojda et al 2012). Hibernating mammals demonstrate remarkable resilience by having evolved physiological mechanisms that allow them to survive extreme physiological and environmental conditions for prolonged periods of time (Carey et al 2003).…”

Section: Introductionmentioning

confidence: 99%

Exploring the Bone Proteome to Help Explain Altered Bone Remodeling and Preservation of Bone Architecture and Strength in Hibernating Marmots

Doherty

Roteliuk

Gookin

et al. 2016

Physiological and Biochemical Zoology

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Periods of physical inactivity increase bone resorption and cause bone loss and increased fracture risk. However, hibernating bears, marmots, and woodchucks maintain bone structure and strength, despite being physically inactive for prolonged periods annually. We tested the hypothesis that bone turnover rates would decrease and bone structural and mechanical properties would be preserved in hibernating marmots (Marmota flaviventris). Femurs and tibias were collected from marmots during hibernation and in the summer following hibernation. Bone remodeling was significantly altered in cortical and trabecular bone during hibernation with suppressed formation and no change in resorption, unlike the increased bone resorption that occurs during disuse in humans and other animals. Trabecular bone architecture and cortical bone geometrical and mechanical properties were not different between hibernating and active marmots, but bone marrow adiposity was significantly greater in hibernators. Of the 506 proteins identified in marmot bone, 40 were significantly different in abundance between active and hibernating marmots. Monoaglycerol lipase, which plays an important role in fatty acid metabolism and the endocannabinoid system, was 98-fold higher in hibernating marmots compared with summer marmots and may play a role in regulating the changes in bone and fat metabolism that occur during hibernation.

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Yellow-bellied Marmots (Marmota flaviventris) preserve bone strength and microstructure during hibernation

Cited by 26 publications

References 37 publications

Effects of hibernation on bone marrow transcriptome in thirteen-lined ground squirrels

Effects of hibernation on bone marrow transcriptome in thirteen-lined ground squirrels

Prevention of muscle wasting and osteoporosis: the value of examining novel animal models

Exploring the Bone Proteome to Help Explain Altered Bone Remodeling and Preservation of Bone Architecture and Strength in Hibernating Marmots

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