Remodelamento das proteínas contráteis cardíacas na transição da hipertrofia compensada para falência cardíaca / Remodeling of cardiac contractile proteins in the transition from compensated hypertrophy to heart failure

Amorin, Vanessa Almeida

06 April 2017

A sobrecarga crônica de pressão causa hipertrofia, disfunção e insuficiência cardíaca (IC). O mecanismo envolvido na transição da hipertrofia cardíaca compensada para descompensada ainda não é totalmente entendido. Evidências sugerem que modificações nas proteínas contráteis poderiam contribuir para disfunção contrátil e evolução para IC. Neste sentido, estudos mostraram mudanças na expressão das proteínas da maquinaria contrátil durante o desenvolvimento da doença cardíaca como um mecanismo inicialmente benéfico. Porém, na insuficiência cardíaca, ocorrem alterações estruturais que prejudicam a contratilidade. Contudo, não se sabe ao certo quais proteínas estariam contribuindo para a transição da hipertrofia compensada para a insuficiência cardíaca. Este estudo teve como objetivo investigar as alterações das proteínas da maquinaria contrátil na transição da hipertrofia cardíaca compensada para descompensada e correlacionar essas alterações com a função cardíaca. Ratos Wistar machos foram submetidos a estenose da aorta abdominal. Após 90d da cirurgia, foram realizados ecocardiograma, análise da pressão sanguínea e os corações foram coletados para realização do Western blot e imunofluorescência para miosina de cadeia pesada, actina sarcomérica, troponina T e troponina I. Os dados foram considerados significantes quando p<0,05. Aos 90d, 70,0±5,35% dos animais apresentaram hipertrofia cardíaca (HH) e 30,3±4,79% corações hipertrofiados+dilatados (HD). A pressão arterial média aumentou 58,2% no HH e 55,0% no HD. As? expressões? de? ?-actina sarcomérica, miosina de cadeia pesada, troponina T e I aumentaram no grupo HH. No grupo HD, a miosina de cadeia pesada e a troponina T reduziram significantemente. A função sistólica manteve-se preservada nos grupos controle e HH, porém reduzida no HD. A perda estrutural da miosina de cadeia pesada e da troponina T poderia contribuir para a insuficiência cardíaca observada nesse modelo experimental. / Hypertension causes hypertrophy, cardiac dysfunction and heart failure (HF). The mechanisms implicated in the transition from compensated to decompensated cardiac hypertrophy are not fully understood. There is considerable evidence that changes in the contractile proteins may contribute to the contractile dysfunction and progression to HF. Studies have shown changes in the expression of contractile proteins during the development of heart disease as a mechanism that is initially beneficial. However, in heart failure there is an intrinsic reduction of cross-bridges that contributes to impaired contractility. It is not known which proteins are contributing to the transition from compensated hypertrophy to heart failure. We investigated ?-sarcomeric actin, heavy chain myosin and troponins T and I in the transition from compensated to decompensated cardiac hypertrophy and correlate these alterations with cardiac function. Male Wistar rats were submitted to abdominal aorta constriction and killed at 90 days post-surgery (dps). The hearts were collected; Western blot and immunofluorescence were performed to investigate ?-sarcomeric actin, heavy chain myosin and troponins T and I. Blood pressure and cardiac systolic function were evaluated. Data were considered significant when p<0.05. At 90 dps, 70,0±5,35% presented hypertrophic hearts (HH) and 30,3±4,79% hypertrophic+dilated hearts (HD). Mean blood pressure increased 58.19% in HH and 54.96% in HD. Heavy chain myosin, troponin T, troponin I and ?-sarcomeric actin expression increased in HH. In HD, only heavy chain myosin and troponin T reduced significantly. The systolic function was the same in control and HH animals and reduced in HD. The structural loss of heavy chain myosin and troponin T could contribute to heart failure observed in this experimental model of abdominal aorta constriction.

Cardiac hypertrophy

Contractile proteins

Heart failure

Hipertrofia cardíaca

Insuficiência cardíaca

Maquinaria contrátil

Proteínas contráteis

Remodelamento das proteínas contráteis cardíacas na transição da hipertrofia compensada para falência cardíaca / Remodeling of cardiac contractile proteins in the transition from compensated hypertrophy to heart failure

Vanessa Almeida Amorin

06 April 2017

A sobrecarga crônica de pressão causa hipertrofia, disfunção e insuficiência cardíaca (IC). O mecanismo envolvido na transição da hipertrofia cardíaca compensada para descompensada ainda não é totalmente entendido. Evidências sugerem que modificações nas proteínas contráteis poderiam contribuir para disfunção contrátil e evolução para IC. Neste sentido, estudos mostraram mudanças na expressão das proteínas da maquinaria contrátil durante o desenvolvimento da doença cardíaca como um mecanismo inicialmente benéfico. Porém, na insuficiência cardíaca, ocorrem alterações estruturais que prejudicam a contratilidade. Contudo, não se sabe ao certo quais proteínas estariam contribuindo para a transição da hipertrofia compensada para a insuficiência cardíaca. Este estudo teve como objetivo investigar as alterações das proteínas da maquinaria contrátil na transição da hipertrofia cardíaca compensada para descompensada e correlacionar essas alterações com a função cardíaca. Ratos Wistar machos foram submetidos a estenose da aorta abdominal. Após 90d da cirurgia, foram realizados ecocardiograma, análise da pressão sanguínea e os corações foram coletados para realização do Western blot e imunofluorescência para miosina de cadeia pesada, actina sarcomérica, troponina T e troponina I. Os dados foram considerados significantes quando p<0,05. Aos 90d, 70,0±5,35% dos animais apresentaram hipertrofia cardíaca (HH) e 30,3±4,79% corações hipertrofiados+dilatados (HD). A pressão arterial média aumentou 58,2% no HH e 55,0% no HD. As? expressões? de? ?-actina sarcomérica, miosina de cadeia pesada, troponina T e I aumentaram no grupo HH. No grupo HD, a miosina de cadeia pesada e a troponina T reduziram significantemente. A função sistólica manteve-se preservada nos grupos controle e HH, porém reduzida no HD. A perda estrutural da miosina de cadeia pesada e da troponina T poderia contribuir para a insuficiência cardíaca observada nesse modelo experimental. / Hypertension causes hypertrophy, cardiac dysfunction and heart failure (HF). The mechanisms implicated in the transition from compensated to decompensated cardiac hypertrophy are not fully understood. There is considerable evidence that changes in the contractile proteins may contribute to the contractile dysfunction and progression to HF. Studies have shown changes in the expression of contractile proteins during the development of heart disease as a mechanism that is initially beneficial. However, in heart failure there is an intrinsic reduction of cross-bridges that contributes to impaired contractility. It is not known which proteins are contributing to the transition from compensated hypertrophy to heart failure. We investigated ?-sarcomeric actin, heavy chain myosin and troponins T and I in the transition from compensated to decompensated cardiac hypertrophy and correlate these alterations with cardiac function. Male Wistar rats were submitted to abdominal aorta constriction and killed at 90 days post-surgery (dps). The hearts were collected; Western blot and immunofluorescence were performed to investigate ?-sarcomeric actin, heavy chain myosin and troponins T and I. Blood pressure and cardiac systolic function were evaluated. Data were considered significant when p<0.05. At 90 dps, 70,0±5,35% presented hypertrophic hearts (HH) and 30,3±4,79% hypertrophic+dilated hearts (HD). Mean blood pressure increased 58.19% in HH and 54.96% in HD. Heavy chain myosin, troponin T, troponin I and ?-sarcomeric actin expression increased in HH. In HD, only heavy chain myosin and troponin T reduced significantly. The systolic function was the same in control and HH animals and reduced in HD. The structural loss of heavy chain myosin and troponin T could contribute to heart failure observed in this experimental model of abdominal aorta constriction.

Hipertrofia cardíaca

Insuficiência cardíaca

Maquinaria contrátil

Proteínas contráteis

Cardiac hypertrophy

Contractile proteins

Heart failure

The characterization of the cytoskeleton and associated proteins in the formation of wound-induced contractile arrays /

Stromme, Adrianna.

January 2008

The cytoskeleton is an intrinsic aspect of all cells, and is essential for many cellular events including cell motility, endocytosis, cell division and wound healing. Remodeling of the cytoskeleton in response to these cellular activities leads to significant alterations in the morphology of the cell. One such alteration is the formation of an actomyosin contractile array required for cytokinesis, wound healing and embryonic development. / Cellular structure and shape depends upon tensional prestress brought about by the organization of cytoskeletal components. Using the Xenopus laevis oocyte wound healing model, it is first described how diminished cellular tension affects the balance of the Rho family of GTPases, and subsequently prevents the formation of actomyosin contractile arrays. This suggests that cellular tension in the cell is not created at the level of the cytoskeletal elements but rather via the upstream signaling molecules: RhoA and Cdc42. / The role of N-WASP (Neural-Wiscott Aldrich Syndrome Protein), a mediator of Arp2/3 based actin polymerization, is next examined for its putative role in cellular wound healing. Xenopus laevis oocytes injected with mutant N-WASP constructs reveals in vivo evidence that functional N-WASP is required for appropriate contractile array formation and wound closure. / Lastly, it is revealed that the cellular structures involved with single cell wound healing in other model systems are also important for the initial repair of severed muscle cells. Actin, non-muscle myosin-II, microtubules, sarcomeric myosin and Cdc42 are all recruited and reorganized at the edge of damaged C2C12 myotubes. This data promotes the possibility that an actomyosin array may be established in injured muscle cells as well.

Actomyosin -- physiology.

Contractile Proteins -- physiology.

Wound Healing -- physiology.

cdc42 GTP-Binding Protein -- metabolism.

rhoA GTP-Binding Protein -- metabolism.

Oocytes -- physiology.

Xenopus laevis.

The characterization of the cytoskeleton and associated proteins in the formation of wound-induced contractile arrays /

Stromme, Adrianna.

January 2008

No description available.

rhoA GTP-Binding Protein -- metabolism.

cdc42 GTP-Binding Protein -- metabolism.

Oocytes -- physiology.

Wound Healing -- physiology.

Xenopus laevis.

Contractile Proteins -- physiology.

Actomyosin -- physiology.