Purification and characterization of cardiac and skeletal muscle calsequestrin using phenyl-sepharose

Cala, Steven Edward

January 1983

This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu).

Glycoproteins

Calsequestrin

Sepharose

Sarcoplasmic Reticulum Calcium Handling in Maturing Skeletal Muscle From Two Models of Dystrophic Mice

Rittler, Matthew Robert

03 December 2002

Duchenne's muscular dystrophy (DMD) is a debilitating disease that affects approximately 1 in 3500 boys, with many DMD patients dying before the age of 20 due to cardio-respiratory complications. DMD is the result of defects in the gene that encodes dystrophin, an integral muscle membrane protein. Although the genetic defect has been identified, the relation between the absence of expressed dystrophin and the mechanisms leading to its onset are still unclear. One possibility is that disrupted calcium (Ca²⁺) handling by the sarcoplasmic reticulum (SR) leads to an increased cytosolic Ca²⁺ concentration that activates proteolytic and apoptotic pathways that initiate muscle fiber death. However, little is known about the role of disrupted SR function in the onset of DMD. The purpose of this study was to test the hypothesis that altered calcium cycling by the SR could contribute to elevated cytosolic Ca²⁺ levels in the early stages of DMD, and thereby account for the onset of disease pathogenesis. Rates of SR Ca²⁺ uptake and release were determined in quadriceps muscles obtained from maturing dystrophic and control mice prior to the overt signs of the disease at ages ~9 and 21 days. In addition, the content of several key Ca²⁺ handling proteins, including two isoforms of the sarco(endo)plasmic reticulum ATPase pump (SERCA 1 & 2), ryanodine receptor type 1 (RyR1), parvalbumin, and calsequestrin were determined by Western analysis. Two dystrophic mouse models were used, the mdx mouse which lacks dystrophin, and the mdx:utrophin-deficient (mdx:utrn^-/-) mouse which also lacks utrophin, a protein homolog of dystrophin. The rate of SR Ca²⁺ uptake in quadriceps muscles of mdx/utrn^-/- mice aged 21 days was 73.1% and 61.3% higher than age-matched control and mdx muscles, respectively (p < 0.05). There was no difference in SR Ca²⁺ release rates between the genotypes at either age. There were significant increases in the content of each of the calcium handling proteins with age (p < 0.05), but no significant differences were detected between genotypes at either age. These data demonstrate the Ca²⁺ release rates of dystrophic SR are not compromised, but suggest the increased uptake rates of mdx:utrn^-/- SR may be an adaptation to increased cytosolic calcium levels, and/or be due to changes in intrinsic SERCA function and/or regulation. The role of increased SR Ca²⁺ uptakes rates in onset of DMD pathogenesis can not be directly determined from the present data; therefore it is suggested that future studies directly assess cytosolic Ca²⁺ concentration and examine the role of SERCA regulatory proteins in intact fibers obtained from mdx:utrn^-/- muscles at age 21 days. / Master of Science

Parvalbumin

Ryanodine

Duchenne

Calsequestrin

SERCA

Changes in Skeletal Muscle Sarcoplasmic Reticulum Calcium Handling and Regulatory Protein Content in Congestive Heart Failure

Allen, Emily E.

25 April 2002

Fatigue and skeletal muscle weakness are problems associated with congestive heart failure. Research does not support the theory that the affected cardiac function is responsible for the fatigue. During skeletal muscle fatigue, calcium handling is altered. Thus, the fatigue associated with congestive heart failure could be attributed to altered calcium handling. The main proteins involved in calcium release are the ryanodine receptor (RyR) and the dihydropyridine receptor (DHPR). The main proteins involved in calcium uptake are the fast and slow isoforms of sarco(endo)plasmic reticulum calcium ATPase (SERCA 1 and SERCA 2 respectively). Calsequestrin (Csq) and calmodulin (CaM) play regulatory roles in calcium handling. Changes in the levels of these proteins could explain alterations in calcium handling and subsequent muscle function. The purpose of this study was to use a genetic model of heart failure, the SHHF rat, to examine the levels of regulatory calcium handling proteins to determine if changes in the amounts of RyR, DHPR, SERCA1, SERCA2, Csq and CaM are altered in congestive heart failure. A significant decrease was found in the amounts of RyR, DHPR, and SERCA 1 of the SHHF gastrocnemius and diaphragm samples in comparison to the control. There was no significant difference found in the amounts of CaM or SERCA 2 between the two groups. Csq was not found to be statistically different between the two groups of the gastrocnemius samples. However, there was an increase in Csq in the SHHF diaphragm samples in comparison to the control. In conclusion, the calcium handling proteins are affected in the genetic model of heart failure. These changes could explain previous reports of altered calcium handling within the skeletal muscles of congestive heart failure animals. / Master of Science

calsequestrin

dihydropyridine

ryanodine

SERCA

calmodulin

Skeletal Muscle as a Mechanism for Peripheral Regulation of Voluntary Physical Activity

Ferguson, David Paul

16 December 2013

Physical activity can prevent cardiovascular disease, obesity, type II diabetes and some types of cancer. With only 3.5% of adults meeting the recommended physical activity guidelines, research has focused on the regulatory factors that influence physical activity level. Genetic influence accounts for the majority of physical activity regulation. However, there is limited information on the mechanisms that affect physical activity, in part, because of a lack of reliable methods to silence genes in vivo. The purpose of this dissertation was to identify mechanisms in skeletal muscle that influence physical activity. The methods used to accomplish the purpose of this dissertation were the evaluation of Vivo-morpholinos as a gene silencing tool in skeletal muscle and brain, identification of proteins in skeletal muscle associated with increased physical activity level, and the use Vivo-morpholinos to transiently knockdown the identified skeletal muscle proteins as a means to elucidate mechanisms for the peripheral regulation of physical activity. Overall, this study showed that Vivo-morpholinos effectively silenced genes in skeletal muscle yet required the use of a pharmacological aid to achieve gene silencing in the brain. Additionally proteins associated with calcium regulation (Annexin A6 and Calsequestrin 1) and the Kreb’s (TCA) cycle were found to be over expressed in the high active animals. The knockdown of Annexin A6 and Calsequestrin 1 resulted in a significant decrease in physical activity, thus showing that calcium regulation could influence the physical activity response. While these results provide a potential mechanism for the peripheral regulation of physical activity, a side effect observed was that Vivo-morpholinos can hybridize resulting in increased mortality rates of the treatment animals. Therefore, we developed methods to alleviate the toxic effects of Vivo-morpholinos. Thus, this dissertation refined a technique for determining a gene’s effect in an in vivo model and identified two candidate proteins (Annexin A6 and Calsequestrin 1) that play a role in regulating daily physical activity.

Wheel running

voluntary physical activity

2D-DIGE

Vivo-moprholino

Vmat2

Drd1

Glut4

Calsequestrin 1

Annexin A6

Early growth factor response 1 (Egr-1) negatively regulates expression of calsequestrin (CSQ) on cardiomyocytes in vitro

Kasneci, Amanda.

January 2008

Heart failure represents an important cause of death in Western Countries. The pathophysiology of heart failure is mainly associated with abnormalities in intracellular calcium control. We previously showed that Egr-1 negatively regulates expression of sodium-calcium exchanger (NCX) in vivo and in vitro. Here we tested the hypothesis that Egr-1 regulates expression of calcium storage proteins in the sarco-endoplasmic reticulum (SER), calsequestrin (CSQ) and/or ER, calreticulin (CRT) directly or indirectly via Egr-1:NFAT (nuclear factor of activated T-cells) formation. Secondarily, we hypothesized that this will reduce calcium mobilization. We found that undifferentiated 1293F cells, overexpressing Egr-1, have reduced CSQ compared to control H9c2 cells. We demonstrated that Egr-1 negatively regulates CSQ but not CRT expression. The Egr-1 mediated decrease in CSQ is linked to decreased calcium availability. Repression is by a novel NAB-independent (NGFI-A binding protein) activity localized to a.a. region 1-307. We conclude that Egr-1-mediated reductions in calcium storage protein expression alter calcium availability for cardiac contraction/relaxation.

Myocytes, Cardiac -- metabolism.

Sarcoplasmic Reticulum -- metabolism.

Calcium Signaling.

Calsequestrin -- metabolism.

Musculos laringeos distroficos : proteção a mionecrose, expressao de SERCA1 e calsequestrina / Protection from myonecrosis, and expression of SERCA1 and calsequestrin in dystrophic laryngeal muscles

Ferretti, Renato, 1982-

18 December 2007

Orientador: Humberto Santo Neto / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-10T05:09:51Z (GMT). No. of bitstreams: 1 Ferretti_Renato_M.pdf: 2564906 bytes, checksum: ad6eec170e1a021892d4ba5f418fe910 (MD5) Previous issue date: 2007 / Resumo: A Distrofia Muscular de Duchenne (DMD) e o camundongo mdx, modelo experimental da doença, caracterizam-se pela ausência de distrofina e pela necrose das fibras musculares. Alguns músculos são protegidos da mionecrose e admite-se que nestes a expressão das proteínas reguladoras de cálcio está aumentada. Os músculos intrínsecos da laringe (ILMs) apresentam características anatômicas e fisiológicas semelhantes aos músculos extra-oculares (EOMs), que são protegidos da mionecrose em pacientes portadores de DMD e camundongos mdx. Assim levantamos a hipótese de que os ILMs são protegidos da necrose de suas fibras e apresentam expressão diferenciada de proteínas reguladoras do cálcio. Foram avaliados os ILMs e músculos apendiculares de camundongos C57Bl/10 (controles) e mdx, adultos e idosos. Foi analisado a porcentagem de núcleos centrais, como um sinal de fibras lesionadas e em reparação e foi utilizado o azul de Evans, como marcador de lesão miofibrilar. Após a caracterização desses músculos, foi estudado por imunohistoquímica e imunobloting, o nível da expressão de proteínas reguladoras do cálcio, calsequestrina e Ca2+-ATPase do retículo sarcoplasmático (SERCA1). Observou-se que, exceto o músculo cricotireóideo (CT), nenhum ILMs dos camundongos mdx adultos ou idosos apresentaram sinais de miopatia, entretanto núcleos centrais foram visíveis no músculo tibial anterior do mesmo animal. Houve aumento significativo da porcentagem de núcleos centrais no músculo CT comparado com outros ILMs, o qual piorou com envelhecimento. A expressão de SERCA1 e calsequestrina está aumentada nos ILMs distróficos em relação aos controles, distintamente do que ocorre nos músculos apendiculares. Assim, conclui-se que os ILMs dos camundongos mdx são protegidos da mionecrose e mostram níveis elevados de SERCA1 e calsequestrina, sugerindo que a manutenção da homeostase do cálcio pode estar envolvida na proteção desses músculos / Abstract: Duchenne muscular dystrophy (DMD) and mdx mice, a model for DMD, is characterized by the lack of dystrophin expression and muscle fiber necrosis. Some muscle are enigmatically protected and admitted that an elevated expression of calcium-binding proteins. The intrinsic laryngeal muscles (ILMs) share many anatomical and physiological properties with extra-ocular muscles, which are unaffected in both Duchenne muscular dystrophy and mdx mice. We hypothesized that ILMs are spared from myonecrosis in the mdx and investigated whether this possible protection is related to an increased expression of calcium-binding proteins, SERCA1 and calsequestrin, which may be protective against the elevated calcium levels seen in dystrophic fibers. ILMs and limb muscles of adult and aged control C57Bl/10 and mdx mice were used. The percentage of central nucleated fibers, as a sign of muscle fibers that had experienced injury and regeneration, and myofibers labeling with Evans blue dye, as a marker of myofiber damage, were studied. After this characterization, the expression of Sarco-endoplasmic-reticulum Ca2+-ATPase (SERCA1) and calsequestrin was examined using immunofluorescence and immunoblotting. Except for the cricothyroid muscle (CT), none of the ILMs from adult and old mdx mice showed signs of myofiber damage. Central nucleation was readily visible in tibialis anterior of the same mdx mice. A significant increase in the percentage of central nucleated fibers was observed in adult CT compared to the other ILMs, which was worsened by age. Dystrophic ILMs presented a significant increase in the proteins studied, in comparison to controls. These proteins were reduced in the non-spared mdx muscles. Thus we show that the ILMs are spared from the lack of dystrophin and the increase of SERCA1 and calsequestrin may permit a better maintenance of calcium homeostasis with the consequent absence of myonecrosis / Mestrado / Anatomia / Mestre em Biologia Celular e Estrutural

Musculos laringeos

Músculo esquelético

Distrofia muscular

Calsequestrina

SERCA1

Laryngeal muscles

Skeletal muscle

Muscular dystrophy

Calsequestrin

Early growth factor response 1 (Egr-1) negatively regulates expression of calsequestrin (CSQ) on cardiomyocytes in vitro

Kasneci, Amanda.

January 2008

No description available.

Sarcoplasmic Reticulum -- metabolism.

Calsequestrin -- metabolism.

Calcium Signaling.

Myocytes, Cardiac -- metabolism.

Transcriptional control of muscle cell excitation-contraction coupling:the role of activity and mitochondrial function

Hänninen, S. L. (Sandra Lynn)

04 June 2019

Abstract Cardiac and skeletal muscle cell contraction is a result of excitation-contraction coupling (ECC), where an electrical signal leads to a rise in intracellular calcium levels and contraction. This process is carefully regulated to meet physiological demand and heavily dependent on an adequate energy supply. Disturbed ECC can have severe consequences on muscle cell function and underlies many cardiac and skeletal muscle pathologies. Cell stress, changing intracellular Ca2+ concentrations, and calcium signal dynamics can all play a role in the transcriptional regulation of genes involved in myocyte Ca2+-handling. In this thesis project, the transcriptional control of ECC was studied in skeletal and cardiac myocytes. Skeletal myocyte calsequestrin (CASQ1) was downregulated in a mouse model of mitochondrial myopathy and it contributed to the decreased SR Ca2+ load and impaired Ca2+ handling in Tfam-/- skeletal myocytes. In cultured neonatal cardiomyocytes, mitochondrial uncoupler FCCP-induced mitochondrial dysfunction led to downregulation of cardiac calsequestrin (CASQ2) and similarly impaired Ca2+ handling. Whereas there was no increase in reactive oxygen species (ROS) levels in Tfam-/- myocytes, cultured cells exposed to FCCP did display increased ROS, an effect that was counteracted by coexposure with the ROS scavenger (NAC). NAC attenuated FCCP-induced CASQ2 downregulation and restored Ca2+ handling. Therefore, mitochondrial dysfunction led to CASQ1/2 downregulation and impaired Ca2+ handling in these two cell types, but by different mechanisms. This project also looked at the role of Ca2+ dynamics on the transcriptional regulation of Ca2+ handling genes. Increased intracellular Ca2+ levels and &#946;-adrenergic stimulation of cardiomyocytes activate Ca2+-calmodulin kinase II (CaMKII) and can trigger hypertrophic remodeling. It was found that CaMKII downregulated expression of the L-type Ca2+ channel &#945;1c-subunit (Cacna1c) in cultured cardiomyocytes. Analysis of the Cacna1c promoter revealed that the transcriptional repressor DREAM bound to a putative downstream regulatory element. The results shed light on the complex interplay between muscle cell energetics and transcriptional regulation of SR Ca2+ handling proteins. A unique pathway for Cacna1c transcriptional regulation by CaMKII and DREAM was also described. / Tiivistelmä Sydän- ja luustolihassolujen supistuminen on seurausta ärsytys-supistuskytkennästä (ECC), jossa sähköinen ärsytys kohottaa solunsisäistä kalsiumpitoisuutta ja aiheuttaa supistuksen. Tätä säädellään tarkasti fysiologisen tarpeen mukaan, ja se riippuu riittävästä energian saannista. Häiriintynyt ECC voi aiheuttaa vakavia seurauksia lihassolujen toiminnalle, ja se on mukana monien sydän- ja luustolihasten sairauksien synnyssä. Tässä tutkimuksessa ECC:n transkriptionaalista säätelyä tutkittiin luustolihasten ja sydämen lihassoluissa. Luustolihassolujen kalsekvestriinin (CASQ1) väheneminen pienensi SR:n Ca2+-määrää mitokondrioiden myopatian hiirimallissa ja heikensi Ca2+-tasapainon ylläpitoa Tfam-/--luustolihassoluissa. Viljellyissä vastasyntyneiden kammio-sydänlihassoluissa mitokondrio-irtikytkijän FCCP:n aiheuttama mitokondrioiden toimintahäiriö johti sydämen kalsekvestriinin (CASQ2) vähenemiseen ja heikensi samalla tavalla Ca2+-tasapainon ylläpitoa. Vaikka Tfam-/--myosyyteissä reaktiivisten happilajien (ROS) tasot eivät olleet koholla, FCCP:lle altistetuissa viljellyissä soluissa ROS kuitenkin lisääntyi. Vaikutusta esti ROS-puhdistaja NAC, joka heikensi FCCP:n aiheuttamaa CASQ2:n laskua ja palautti Ca2+-säätelyn normaaliksi. Mitokondrioiden toimintahäiriö siis johti CASQ1/2:n vähenemiseen ja Ca2+-säätelyn heikentymiseen molemmissa solutyypeissä, mutta eri mekanismeilla. Tässä tutkimuksessa tarkasteltiin myös Ca2+-dynamiikan osuutta Ca2+-tasapainoon osallistuvien geenien transkription säätelyssä. Lisääntynyt solunsisäinen Ca2+-taso ja sydänlihassolujen &#946;-adrenerginen stimulointi aktivoivat Ca2+-kalmoduliinikinaasi II:n (CaMKII), ja ne voivat laukaista sydämen hypertrofisen uudelleenmuovautumisen. Havaittiin, että CaMKII vähensi L-tyypin Ca2+-kanavan a1c-alayksikön (Cacna1c) ilmentymistä viljellyissä sydänlihassoluissa. Promoottorianalyysi osoitti tämän johtuvan transkription repressorin DREAM:n sitoutumisesta oletettuun DRE:hen (alavirrassa sijaitseva säätelyelementti). Nämä tulokset tuovat uutta tietoa lihassolujen energiatalouden ja SR:n Ca2+:n vaikuttavien proteiinien transkription säätelyn vuorovaikutuksesta. Lisäksi havaittiin ainutlaatuinen Cacna1c-transkription säätelyn reitti, johon osallistuvat CaMKII ja DREAM.

calcium

calcium handling

calsequestrin

cardiomyocytes

gene expression

mitochondria

mitochondrial cardiomyopathy

mitochondrial dysfunction

calsequestriini

geeniekspressio

kalsium

kalsiumkäsittely

kardiomyosyytit

mitokondriaalinen kardiomyopatia

mitokondrioiden toimintahäiriö

mitokondriot

CaMKII

Cacna1c