Study on the Proteomics of Flyingfish (Cyselurus poecilopterus) Skeletal Muscle

Chang, Kuan-hsiang

18 August 2009

Flying fish has specialized pectoral fins. When they are activated, they will rush out of the water, expand their pectoral fins and flap their caudal fin to glide. The pectoral fins are controlled by two groups of muscles in which the external appearance is pink. No histological investigations have been made on their muscles to verify whether they are red muscles. The purposes of this study were to compare the pectoral fin muscle, trunk white muscle and trunk red muscle by histological and proteome methods so as to understand if the pectoral fin muscles is red muscles and to infer their function. Cyselurus poecilopteins was used for this study, Result show that the sizes for the cross section of the pectoral-fin-muscle-fibers were between the white and red muscles, and a large amount of connective tissue and fat tissues are present in the space among the muscle cells. It is interpreted the pectoral fin muscles of flying fish might not belong to white muscle and red muscle, and they probably utilize lipid metabolism to provide enough energy for the gliding activates. The proteomic pages for the three muscle types were compared and differences were found in the muscle proteins: actin, myosin regulatory light chain, myosin light polypeptide; enzymes: isocitrate dehydrogenase, malate synthase, queuosine biosynthesis protein¡Fstress proteins: heat shock protein (HSP70 and HSP60). Expressions of these proteins were high in the pectoral-fin muscles than in the white and red muscles. These results suggest that the flying fish¡¦ pectoral-fin muscles may involve in the oxidative and glycolysis pathways, and the muscle fibers type maybe belong to an intermediate type of muscle fiber.

skeletal muscles

proteomics

Cyselurus poecilopterus

flyingfish

Vasomotor responses of rat skeletal muscle arterioles to norepinephrine and adenosine /

Aaker, Aaron Paul,

January 2001

Thesis (Ph. D.)--University of Missouri--Columbia, 2001. / "May 2001." Typescript. Vita. Includes bibliographical references (leaves 122-137). Also available on the Internet.

Evidence-based clinical practice guidelines for care of skeletal pin sites in orthopaedic patients

Sin, Tak-nam., 冼德藍.

January 2010

published_or_final_version / Nursing Studies / Master / Master of Nursing

External skeletal fixation (Surgery)

Fractures - Treatment.

Investigation of the physiological and biochemical function of mitochondrial uncoupling protein 3

Kenaston, Monte Alexander

09 February 2011

Uncoupling proteins (UCPs) are highly conserved inner mitochondrial membrane proteins that have been found in plants, nematodes, flies, and vertebrates. UCPs dissipate the proton gradient formed by the electron transport chain in an energy-expending process that generates heat. In mammals, the brown fat-specific UCP1 is thought to be the dominant, if not the only significant mediator of thermogenic responses. However, adult humans express only negligible amounts of brown fat and UCP1, yet still show significant non-shivering thermogenic responses (e.g. amphetamine-induced hyperthermia, diet induced thermogenesis, fever). Thus, the fact that human thermogenic mechanisms haven't been identified is a huge gap in our understanding of human thermoregulation. UCP3 is primarily expressed in skeletal muscle, an established thermogenic organ which is a major target of amphetamine-induced pathology. UCP3 knockout mice have a near complete loss (~80%) of amphetamine-induced thermogenesis and are completely protected from amphetamine-induced death over a range of lethal doses. With regard to mechanisms of UCP3 activation, we observed that norepinephrine and free fatty acids are elevated in the bloodstream prior to peak amphetamine-induced hyperthermia. However, little is known about the anatomic location of UCP3-dependent thermogenesis or the mechanisms by which fatty acids regulate UCP function. Thus, we sought to investigate the physiology and biochemical activation of UCP3 to establish the thermogenic potential of skeletal muscle uncoupling and elucidate the mechanisms of UCP3 function. The overall goal of this research was to identify the tissue target(s) and mechanisms involved in amphetamine-induced UCP3-dependent thermogenesis. Herein, we show that in addition to a deficit in induced thermogenesis, UCP3-null mice also lack responses to other physiologically-relevant stimuli (i.e. catecholamines and bacterial pathogens). Conversely, UCP3 knockout mice, engineered to express UCP3 only in skeletal muscle have an augmented thermogenic response to amphetamines. In order to explore UCP3's mechanism of activation, we performed a modified yeast two-hybrid analysis and identified [Delta][superscript 3,5][Delta][superscript 2,4]dienoyl-CoA isomerase (DCI) as a UCP3 binding partner. DCI, an auxiliary fatty acid oxidation enzyme, protects cells from the accumulation of toxic lipid metabolites. Using immunoprecipitation and fatty acid oxidation (FAO) assays, we determined that UCP3 and DCI directly bind in the mitochondrial matrix in order to augment lipid metabolism. These findings support a novel model in which skeletal muscle UCP3 is responsible for inducible thermogenesis through cooperation with binding partners such as DCI which enhance oxidation of fatty acids. Together, these studies shed light on thermogenic pathways in rodents that are likely to be relevant to humans. / text

Uncoupling protein

Thermogenesis

Amphetamine

Skeletal muscle

Chromium chloride increases insulin-stimulated glucose uptake in the perfused rat hindlimb

Doerner, Phillip Gene

16 February 2011

Chromium has been reported to increase glucose clearance in insulin resistant and diabetic populations. Skeletal muscle is the tissue primarily responsible for glucose clearance. We therefore tested the effect of chromium chloride (CrCl3) on skeletal muscle glucose uptake both in the absence and presence of a submaximal level of insulin via the rat hindlimb perfusion technique. 0.096 μM CrCl3 was used with and without 200 μU/ml insulin. Our testing showed that insulin significantly increased [H3]-2 deoxyglucose (2-DG) uptake in both the gastrocnemius and quadriceps muscles. Additionally, the combination of CrCl3 and insulin (Cr-sIns) led to greater amounts of 2-DG uptake than insulin alone (sIns) in both the gastrocnemius (Cr-sIns 6.49±0.75 μmol/g/h, sIns 4.83±0.42 μmol/g/h) and quadriceps (Cr-sIns 6.74±0.62 μmol/g/h, sIns 4.54±0.43 μmol/g/h). However, CrCl3 without insulin (Cr) had no affect on 2-DG uptake above basal (Bas) in both the gastrocnemius (Cr 1.45±0.14 μmol/g/h, Bas 1.61±30 μmol/g/h) and the quadriceps (Cr 1.35±0.15 μmol/g/h, Bas 1.27±0.13 μmol/g/h). It has been speculated that chromium works to increase glucose uptake by increasing insulin signaling. To examine this, we used western blotting analysis to test both Akt and AS160 phosphorylation in the mixed gastrocnemius. We found that insulin increased Akt and AS160 phosphorylation, but chromium had no affect on Akt (Cr-sIns 25%±2%, sIns 22%±4%) or AS160 (Cr-sIns 35%±5%, sIns 36%±4%) phosphorylation in the absence or presence of insulin. Our results suggest that supplementation with CrCl3 can lead to an increase in glucose uptake in skeletal muscle, but only in the presence of insulin. However, this effect of CrCl3 does not appear to be a result of enhanced insulin signaling. / text

Insulin signaling

Trace minerals

Skeletal muscle

Alutiiq Engineering: The Mechanics and Design of Skeletal Technologies in Alaska's Kodiak Archipelago

Margaris, Amy Vlassia

January 2006

This dissertation expands current theoretical and practical knowledge of variability in the technological strategies practiced by past forager societies. Specifically, it examines the interplay between raw material innate and working properties, and tool design as they relate to skeletal media and technologies. Data were synthesized from existing biomedical literature on the structure and mechanical properties of technologically-relevant osseous media, including bird and cetacean bone, and antler. Original laboratory tests were then conducted to determine the mechanical properties of Young's modulus (intrinsic stiffness), intrinsic strength, and fracture resistance of the compact tissue of reindeer antler, cervid long bones, and the limb bones of the California sea lion. Cervid compact limb tissue is stiff, strong, and brittle, while reindeer antler is flexible and highly fracture-resistant (tough). Air-drying hardens all skeletal tissues, and greatly increases investment times for creating tool blanks of both antler and cervid limb bone. Water -soaking can soften dry antler, but may have little effect on the workability of previously-dried land mammal limb bone. Finally, data on the mechanical and working properties of osseous tissues were applied to an analysis of the raw material selection and tool design strategies practiced by protohistoric Alutiiq foragers of Alaska's Kodiak region. Drawing on a sample of over 300 osseous tools and tool blanks, the engineering designs of five tool types were investigated: unbarbed arrows, barbed sea mammal harpoons, fishing harpoon tips, woodworking wedges, and awls. By employing multiple analytical scales, the study points to multiple design pathways toward a generalized goal of maximizing tool longevity, or circulation time. Tool fracture potential can be reduced through raw material selection and stress-reducing structural design. Alutiiq designs for longevity include nested fish harpoon valves, and the off-set line holes on unilaterally barbed harpoons. Also, both tool types were created most frequently from tough but non-local antler. Tool recycling and conservation to avoid drying and fracture can likewise increase tool use-lives. For osseous tools, maximizing longevity might offset high initial tool production investments. The results are applicable to processes of technology transfer in many protohistoric contexts and the Upper Paleolithic of Eurasia.

technology theory

foragers

Kodiak

skeletal technologies

Alaska

The role of glutathione depletion in skeletal muscle apoptotic signalling in young and old rats

Lalonde, Crystal

January 2010

There is substantial evidence that oxidative stress causes negative outcomes in many cell and tissue types. This is especially true of skeletal muscle, as it is continually subjected to various sources of reactive oxygen species (ROS). Oxidative stress in muscle has been linked to several disease states as well as to the normal aging process. Oxidative stress has also been associated with increased apoptotic signalling. Furthermore, elevated apoptosis is consistently observed in aged skeletal muscle and is thought to be one of the mechanisms of age-related muscle atrophy. Due to its post-mitotic nature, skeletal muscle may be more susceptible to the harmful effects of oxidative stress in light of its limited regenerative capacity. As a protective measure, a sophisticated antioxidant system exists in muscle consisting of both enzymatic (superoxide dismutases (SOD’s), catalase, glutathione peroxidase) and non-enzymatic elements (glutathione: GSH). GSH is a ubiquitously expressed tripeptide essential to maintenance of the redox status of the cell. Its role in skeletal muscle apoptosis, especially in different muscle types, is currently unclear. To elucidate the potential role of GSH in skeletal muscle apoptosis and oxidative stress, L-buthionine-[S,R]-sulfoximine (BSO) was used to deplete GSH in young (34.85 ± 0.68 wks) and old (69.11 ± 3.61 wks) male Sprague-Dawley rats. Thiol levels (GSH, GSSG), ROS production, 4-hydroxy-2-nonenal (4HNE) levels, DNA fragmentation and apoptosis-related protein expression were examined in soleus (SOL) and white gastrocnemius (WG) muscle. BSO led to significant GSH depletion (89% in SOL, 96% in WG) compared to age-matched controls. Catalase upregulation, in the absence of change in SOD levels, was evident as a result of BSO treatment and advancing age in both muscle tissues. BSO treatment also resulted in increased DNA fragmentation in WG and SOL, with elevated ROS production in SOL only; both of these effects were independent of age. Advancing age resulted in elevated caspase activity and Hsp70 protein content, with a concomitant decrease in anti-apoptotic ARC in SOL but not WG. Additionally, ROS production, 4HNE content, DNA fragmentation and ARC levels were all significantly elevated in SOL compared to WG. These data indicate that SOL may be subjected to a state of elevated cellular stress. There is also some evidence that GSH depletion increases DNA fragmentation while age contributes to a degradative loss of glycolytic muscle.

apoptosis

skeletal muscle

BSO

glutathione

aging

Kinesiology

An investigation of the Coxsackie and Adenovirus Receptor in striated muscle /

Shaw, Christian A.

January 2006

Since its identification in 1997 as the common receptor for Coxsackie and adenovirus (CAR) multiple lines of evidence argue in favor of CAR contributing to aspects of cell adhesion in addition to serving as a viral receptor. Nevertheless, a precise biological role for CAR remains to be identified suggesting the receptor may participate in a variety of cellular functions that reflect its tissue specific and developmentally regulated expression. This thesis elucidates aspects of CAR biology in mature striated muscle by providing studies that encompass (i) its physiological cellular/subcellular localization and expression in mature striated muscle (ii) its expression profile in human diseased skeletal muscle and (iii) the potential consequences of its sustained expression in mature striated muscle where its levels would otherwise be highly attenuated. / In non-diseased, mature striated muscle despite low and barely detectable levels of the CAR transcript (cardiac and skeletal muscle respectively), we identified CAR as a novel component of the neuromuscular junction and showed its expression to be isoform-specific in contrast to the intercalated discs, where both predominant CAR isoforms are detected. We then investigated the expression of CAR at the level of human skeletal muscle disease. From these studies we observed that in diseases characterized by active necrosis and regeneration, extrasynaptic CAR expression is detectable in regenerating fibers and co-expressed with other previously described markers of regeneration at a high degree of coincidence. Moreover, extrasynaptic CAR expression appears to be a highly reliable indicator of the regenerative process offering potential use at the diagnostic level. Following these investigations, our final studies involved assessing whether sustained CAR expression might affect the normal homeostasis in skeletal and cardiac muscle using a transgenic mouse model. We discovered that transgenic mice expressing sustained high levels of CAR (as seen in the CAR+/+ transgenics) develop a lethal necrotizing myopathy characterized by dual deficiencies in dystrophin and dysferlin, two proteins pivotal in maintaining plasmalemmal integrity, raising the possibility for a previously unrecognized cause of skeletal muscle dysfunction. / Collectively these findings argue that in non-diseased mature skeletal and cardiac muscle, CAR expression is restricted to the neuromuscular junction and cardiac intercalated discs but in diseases of skeletal muscle characterized by active necrosis and regeneration, extrasynaptic CAR expression is reexpressed at these sites of injury/repair. In addition they raise the possibility that sustained CAR expression in mature skeletal muscle may be associated with altered muscle homeostasis.

Muscle, Skeletal.

Receptors, Virus.

Enterovirus.

Adenoviridae.

The Role of Sarcolipin in Calcium Handling and Obesity

Bombardier, Eric

January 2010

Sarcolipin (SLN), a small molecular weight, hydrophobic protein found in skeletal muscle, is a known regulator of sarco(endo)plasmic reticulum Ca2+ ATPase (SERCA) pumps. Earlier in vitro reconstitution experiments have shown that SLN uncouples ATP hydrolysis from Ca2+ transport by the SERCA pumps and increases the amount of heat released per mol of ATP hydrolyzed by inducing an increased rate of ???slippage??? during the reaction cycle of SERCA pumps. In order to determine whether SLN causes slippage of SERCA activity by uncoupling ATP hydrolysis from Ca2+ transport under more physiological conditions, comparisons were made between skeletal muscle Ca2+ ATPase activity and Ca2+ uptake in homogenates from soleus muscle of wild-type (WT) and Sln-null (KO) mice under conditions in which a Ca2+ gradient was preserved across the sarcoplasmic reticulum (SR) vesicles. Ca2+ ATPase activity, measured in the absence of the Ca2+ ionophore, A23187, was 15-25% lower in KO muscles, compared with WT, consistent with the proposal that SLN increases ???slippage??? and reduces the extent of back-inhibition of the Ca2+ ATPase. Ca2+ uptake, measured in homogenates without oxalate, was not different (p>0.05) in SR vesicles from WT and KO mice, indicating that the calculated Ca2+ transport efficiency (coupling ratio) in KO mice was increased by about 20% (P<0.04). The basal oxygen consumption (VO2) of soleus muscles isolated from WT and KO mice and the contribution of energy utilized by SERCA was also compared. Surprisingly, basal VO2 was not lower in the soleus of KO mice, but the contribution of energy utilized by SERCA pumps was about 7% lower (P<0.0001). It was also found that uncoupling protein 3 (UCP-3) was expressed at a higher (P<0.03) concentration in soleus muscle of KO compared to WT. Thus UCP-3 could, potentially, provide compensation, resulting in higher basal VO2 in KO mice than expected. These data show that at physiological SLN:SERCA ratios, SLN uncouples ATP hydrolysis from SR Ca2+ uptake in skeletal muscle, resulting in a lower contribution of Ca2+ handling to basal VO2. Thus, SLN is a key regulator of both ATP utilization in Ca2+ handling and of overall energy metabolism in skeletal muscle. To further examine the role of SLN in adaptive thermogenesis, obesity and glucose intolerance, KO and WT mice were placed on a high fat diet (HFD; 42% of kcal derived from fat) for an eight week period. Whole body metabolism, weight gain, glucose tolerance and insulin tolerance were measured before and after the HFD. Fat pads, liver, pancreas, hindlimb muscles and plasma samples were collected from standard chow fed control and HFD WT and KO mice. KO mice gained more weight (P<0.05) and became more obese (P<0.05) than WT mice after consuming the HFD. The comprehensive laboratory animal monitoring system (CLAMS) revealed no differences in whole body metabolic rate (ml O??2/kg/hr) between KO and WT mice pre diet; however, daily metabolic rate was lower (P<0.05) in KO mice compared with WT mice after the HFD which may explain the increased obesity in KO mice. Western blotting analyses revealed SLN protein content to be 3.8 fold higher (P<0.05) in WT soleus post HFD compared to control. Phospholamban (PLN), a homologue of SLN, was found to be 2.1 fold higher (P<0.05) in brown adipose tissue (BAT) in both WT and KO mice post HFD. Protein contents of other Ca2+ handling proteins (SERCA1a, SERCA2a, PLN and calsequestrin) within fast (white gastrocnemius) and slow (soleus) twitch muscle were not different between KO and WT mice following the HFD. Collectively, these results suggest that PLN and SLN could play a role in adaptive diet-induced thermogenesis. On the other hand, compared with chow fed control mice, the metabolic cost of Ca2+ handling in soleus muscle was significantly reduced post HFD in both WT and KO mice, although to a greater extent (P<0.05) in KO mice than WT mice. Moreover, there were no differences in resting energy expenditure of soleus muscles between WT and KO mice following the HFD. These observations can be accounted for by diet-induced increases in sympathetic nervous system activity in KO mice and other adaptive responses leading to increased energy expenditure of soleus in both WT and KO mice. Therefore, differences in whole body metabolic rate and obesity between high fat fed WT and KO mice do not appear to be due to adaptive thermogenesis mechanisms in skeletal muscle involving SLN. Interestingly, soleus and EDL muscle weights increased proportionately to body weight in high fat fed WT mice but not KO mice. Therefore, lower lean body tissue mass may explain the lower whole body metabolic rate and increased susceptibility to obesity in KO mice compared with WT mice. With increased obesity, KO mice became extremely glucose intolerant (P<0.05) post HFD compared to WT mice who also demonstrated glucose intolerance (P<0.05) compared to the pre-HFD values. Surprisingly, the insulin tolerance test responses were not different between KO and WT mice post HFD suggesting that KO mice did not develop greater whole body insulin resistance despite being more obese than WT mice. Blood serum analysis showed that non-esterified fatty acids (NEFA) and LDL cholesterol levels were also increased more (P<0.05) in KO mice compared to the WT mice post HFD. Overall, it is concluded that SLNs impact on Ca2+ handling influences not only ATP consumption by SERCA pumps in resting soleus muscle via uncoupling of ATP hydrolysis from SR Ca2+ uptake but also blunts the negative effect of high fat feeding by increasing resistance to diet-induced obesity and glucose intolerance in mice through mechanisms which are currently unidentified.

Sarcolipin

SERCA

Calcium

Obesity

Diabetes

Skeletal Muscle

A morphometric analysis of parturition scarring on the human pelvic bone

Decrausaz, Sarah-Louise

04 June 2014

Osteological studies have identified scarring on the bone surface of the human pelvic bone as evidence of childbirth, termed parturition scarring. It remains unknown whether a single or multiple births cause parturition scarring. Such scarring has also been found on male pelvic bones. This study examines parturition scarring within the broader morphometric and musculoskeletal context of the pelves of both sexes. This project investigates the influence of body size (stature and body mass) and pelvic size (individual pelvic measurements and pelvic canal size) and shape (pelvic canal shape) on the presence of parturition scarring on the pelvic bones of females and males. Two skeletal collections of known-age and sex were chosen for this project on the basis of access to parity (childbirth) records: the Maxwell Museum Documented Skeletal Collection and the Christ Church, Spitalfields collection. The dimensions of articulated and disarticulated pelves, femoral measurements and scores for six types of parturition scarring were recorded for all individuals (n=292). Skeletal proxies for body mass and stature were calculated for all individuals. Univariate, bivariate and multivariate statistical analyses were used to identify significant differences in parturition scarring between sexes, correlation between body size variables, parity status, pelvic canal size and pelvic canal shape (as represented by principal components analysis) and parturition scarring. Parity status and pelvic canal shape do not associate with parturition scarring. Pubic tubercle variables associated variously with femoral head diameter and pelvic canal size in females or males only. Dorsal pitting correlates weakly with four pelvic dimensions in females. The results of this study suggest that the term parturition scarring should be revised to reflect its non-connection with parity status and that future investigations should examine musculoskeletal interactions based on body and pelvic size variation that affect the presence of such scarring in males. / Graduate / 0327 / 0287 / decrausa@uvic.ca

parturition scarring

pelvis

morphometric

skeletal size