Rescue of cardiac α-actin-deficient mice by enteric smooth muscle γ-actin

Kumar, Ajit; Crawford, Kelly; Close, L.; Madison, Marisa N.; Lorenz, John N.; Doetschman, Tom; Pawlowski, Sharon A.; Duffy, John; Neumann, Jonathan; Robbins, Jeffrey; Boivin, Gregory P.; O’Toole, Barbara A.; Lessard, James L.

doi:10.1073/pnas.94.9.4406

Cited by 175 publications

(175 citation statements)

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“…This gene encodes cardiac a-actin, and the Actc1 knockout mouse showed a similar phenotype to that of the Itpa À/À mouse. 31 As the Actc1 gene is located near the Itpa gene on mouse chromosome 2, we determined whether Itpa gene disruption affected Actc1 gene expression. Semiquantitative RT-PCR analysis showed that the amount of Actc1 mRNA was not affected by Itpa gene disruption in the heart (Figure 7).…”

Section: Resultsmentioning

confidence: 99%

ITPase-deficient mice show growth retardation and die before weaning

et al. 2009

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Inosine triphosphate pyrophosphatase (ITPase), the enzyme that hydrolyzes ITP and other deaminated purine nucleoside triphosphates to the corresponding purine nucleoside monophosphate and pyrophosphate, is encoded by the Itpa gene. In this study, we established Itpa knockout (KO) mice and used them to show that ITPase is required for the normal organization of sarcomeres in the heart. Itpa À/À mice died about 2 weeks after birth with features of growth retardation and cardiac myofiber disarray, similar to the phenotype of the cardiac a-actin KO mouse. Inosine nucleotides were found to accumulate in both the nucleotide pool and RNA of Itpa À/À mice. These data suggest that the role of ITPase in mice is to exclude ITP from the ATP pool, and the main target substrate of this enzyme is rITP. Our data also suggest that cardiomyopathy, which is mainly caused by mutations in sarcomeric protein-encoding genes, is also caused by a defect in maintaining the quality of the ATP pool, which is an essential requirement for sarcomere function.

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Section: Resultsmentioning

confidence: 99%

ITPase-deficient mice show growth retardation and die before weaning

et al. 2009

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“…Mouse knockouts of cell migration components or other proteins with direct effects on cell migration Protein Function Type Phenotype Reference α skeletal muscle actin Actin Cytoskeleton Total Postnatal death at P1-9, marked loss of body weight; upregulation of other actin isoforms (Crawford et al, 2002) α smooth muscle actin Actin Cytoskeleton Total Viable; impaired vascular contractility and blood pressure homeostasis; upregulation of other actin isoforms (Schildmeyer et al, 2000) α cardiac actin Actin Cytoskeleton Total Perinathal lethality; cardiac hypertrophy and heart muscle abnormalities; upregulation of other actin isoforms (Kumar et al, 1997) β non-muscle actin Actin Cytoskeleton Total Death after E9.5 (Shawlot et al, 1998) γ non-muscle actin Actin Cytoskeleton Skeletal muscle-specific Muscle weakness, necrosis and degeneration (Sonnemann et al, 2006) Tropomyosin Actin Cytoskeleton Total Death before morula stage (Hook et al, 2004) Mena Actin Cytoskeleton Total Viable, with misrouted axons and defects in the nervous system (Lanier et al, 1999) Mena, VASP, Evl triple null Actin Cytoskeleton Total Defects in brain development, neuritogenesis, and neural tube closure Filamin-B Actin Cytoskeleton Total Skeletal malformations and impaired microvascular development (Zhou et al, 2007) Gelsolin (or ADF) Actin Cytoskeleton Total Defects in fibroblast and platelet motility and lamellar responses (Witke et al, 1995) Nonmuscle myosin II-B Actin Cytoskeleton Total Embryonic and perinatal lethality with severe heart defects (Tullio et al, 1997) Myosin heavy chain II-A Actin Cytoskeleton Total Failure in embryonic patterning, embryonic lethality by E7.5 (Conti et al, 2004) Cardiac alpha myosin, heavy chain Actin Cytoskeleton Total Embryonic lethality between E11 and 12 with gross heart defects (Jones, 1996) (Imamoto and Soriano, 1993;Nada et al, 1993) Ephrin B1 Transmembrane signaling Total Neural crest cell misguidance (cranial and cardiac, but not trunk) (Davy et al, 2004) Angiomotin Transmembrane signaling Total Death between E11-E11.5, severe vascular insufficiency in intersomitic regions, dilated vessels in the brain (Aase et al, 2007) Birth Defects Res C Embryo Today. Author manuscript; available in PMC 2009 June 1.…”

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confidence: 99%

Cell biology of embryonic migration

Kurosaka¹,

Kashina²

2008

Birth Defects Research Pt C

111

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Cell migration is an evolutionarily conserved mechanism that underlies the development and functioning of uni-and multicellular organisms and takes place in normal and pathogenic processes, including various events of embryogenesis, wound healing, immune response, cancer metastases, and angiogenesis. Despite the differences in the cell types that take part in different migratory events, it is believed that all of these migrations occur by similar molecular mechanisms, whose major components have been functionally conserved in evolution and whose perturbation leads to severe developmental defects. These mechanisms involve intricate cytoskeleton-based molecular machines that can sense the environment, respond to signals, and modulate the entire cell behavior. A big question that has concerned the researchers for decades relates to the coordination of cell migration in situ and its relation to the intracellular aspects of the cell migratory mechanisms. Traditionally, this question has been addressed by researchers that considered the intra-and extracellular mechanisms driving migration in separate sets of studies. As more data accumulate researchers are now able to integrate all of the available information and consider the intracellular mechanisms of cell migration in the context of the developing organisms that contain additional levels of complexity provided by extracellular regulation. This review provides a broad summary of the existing and emerging data in the cell and developmental biology fields regarding cell migration during development.

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“…aSMA and aCAA are found in primary tumors, whereas aSKA is expressed in the more differentiated state of the rhabdomyosarcomas, consistent with the developmental steps of skeletal muscle differentiation Clement et al, 2003;Moll et al, 2006]. The majority of aCAA KO mice do not survive until birth, and those that survive, die within 2 weeks after birth [Kumar et al, 1997]. Apart from occasional delay, the development of the embryonic aCAA deficient hearts is normal up to E14.0 [Abdelwahid et al, 2004].…”

Section: Mutations In Aska Cause Various Congenital Myopathiesmentioning

confidence: 75%

“…But the total actin content in the heart is still reduced by about 50%. Increase of the total actin content to normal levels was achieved by ectopic expression of gSMA under the control of the cardiac a-myosin heavy chain promoter in these aCAA deficient mice [Kumar et al, 1997]. These transgenic mice can reach adulthood, but their hearts are hypodynamic, enlarged and hypertrophied [Kumar et al, 1997].…”

Section: Mutations In Aska Cause Various Congenital Myopathiesmentioning

confidence: 99%

“…It has been suggested that different degrees of contractility in the subregions of the heart are generated by different ratios of aSKA and aCAA expression [Suurmeijer et al, 2003]. Moreover, ectopic expression of gSMA in wild type mice and heterozygous aCAA deficient mice reduces cardiac contractility, whereas the heart of BALB/c mice, which contains increased amounts of aSKA, is hyperdynamic [Hewett et al, 1994;Kumar et al, 1997].…”

Section: Mutations In Ccya Cause Deafnessmentioning

confidence: 99%

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Actin isoform expression patterns during mammalian development and in pathology: Insights from mouse models

Tondeleir

Vandamme

Vandekerckhove

et al. 2009

Cell Motil. Cytoskeleton

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The dynamic actin cytoskeleton, consisting of six actin isoforms in mammals and a variety of actin binding proteins is essential for all developmental processes and for the viability of the adult organism. Actin isoform specific functions have been proposed for muscle contraction, cell migration, endo-and exocytosis and maintaining cell shape. However, these specific functions for each of the actin isoforms during development are not well understood. Based on transgenic mouse models, we will discuss the expression patterns of the six conventional actin isoforms in mammals during development and adult life. Ablation of actin genes usually leads to lethality and affects expression of other actin isoforms at the cell or tissue level. A good knowledge of their expression and functions will contribute to fully understand severe phenotypes or diseases caused by mutations in actin isoforms. Cell Motil. Cytoskeleton 66: 798-815, 2009. '

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Rescue of cardiac α-actin-deficient mice by enteric smooth muscle γ-actin

Cited by 175 publications

References 42 publications

ITPase-deficient mice show growth retardation and die before weaning

ITPase-deficient mice show growth retardation and die before weaning

Cell biology of embryonic migration

Actin isoform expression patterns during mammalian development and in pathology: Insights from mouse models

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