<i>C3orf58</i>
            , a Novel Paracrine Protein, Stimulates Cardiomyocyte Cell-Cycle Progression Through the PI3K–AKT–CDK7 Pathway

Beigi, Farideh; Schmeckpeper, Jeffrey; Pow-anpongkul, Pete; Payne, James Alan; Zhang, Lunan; Zhang, Zhiping; Huang, Jing; Mirotsou, Maria; Dzau, Victor J.

doi:10.1161/circresaha.113.301075

Cited by 83 publications

(58 citation statements)

References 31 publications

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“…ExPASy ProtParam online analysis showed that the LOC339524 protein instability index was so large that it could be classified as an unstable protein, suggesting that the protein is active and important. Transmembrane prediction software indicated that at residues 47-68, the protein may have a transmembrane helix, which is consistent with the results reported by Ota et al (2004), suggesting that the protein is a single transmembrane protein without a putative signal peptide, just like hypoxia and Akt-induced stem cell factor (HASF) (Beigi et al, 2013). Further analysis showed that the functional domain of the LOC339524 protein is located at residues 138-236, a region that is likely to induce and regulate cytokine production (Boissanet al, 2014;Turnquistet al, 2014), thereby regulating the immune system.…”

Section: Discussionsupporting

confidence: 87%

Cloning and sequence analysis of the LOC339524 gene in Sprague-Dawley rats

Zh¹,

H²,

Chen³

et al. 2015

Genet. Mol. Res.

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ABSTRACT. We cloned the LOC339524 gene in Sprague-Dawley (SD) rats and analyzed the structure and function of the protein encoded by it. Based on the known human LOC339524 gene sequences, the full-length coding sequence of the LOC339524 gene in SD rats was cloned and amplified by the polymerase chain reaction using the complementary DNA of SD rats as a template. Bioinformatics analysis showed that the length of the cloned LOC339524 gene (GenBank accession No. KM224520) was 831 bp and it encoded a deduced protein of 276 amino acids. Sequence analysis revealed that the coded protein was identical to that produced in humans and its functional domain was located in the 138-236 amino acid fragments, a proline-rich region. Our results suggest that the encoded protein may be a significant regulator of the inflammatory response and may provide sufficient information to justify an in-depth investigation of the role of the LOC339524 gene.

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Section: Discussionsupporting

confidence: 87%

Cloning and sequence analysis of the LOC339524 gene in Sprague-Dawley rats

Zh¹,

H²,

Chen³

et al. 2015

Genet. Mol. Res.

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“…Importantly, evidence of cytokinesis was observed in a murine model 73 . The proliferative effects of HASF were found to be mediated by PI3K and the cell-cycle regulator cyclin-dependent kinase 7 (CDK7) 73 . We are currently investigating in more detail the molecular pathways by which HASF promotes cardiomyocyte proliferation.…”

Section: Effects Of the Paracrine Factorsmentioning

confidence: 96%

“…As noted in a recent editorial HASF has a number of novel features as a cytoprotective factor 136 . Over-expression of PKCε promotes cardiac hypertrophy 137 , whereas that of HASF does not 73 . Moreover, pharmacological inhibition of PKCε did not affect HASF mediated activation of Akt and it is curious feature of HASF that high levels of Akt activity are not important for the cytoprotective effects of this paracrine factor 136 .…”

Section: Emerging Concepts In Paracrine Mechanisms: Temporal and Spatmentioning

confidence: 99%

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Emerging Concepts in Paracrine Mechanisms in Regenerative Cardiovascular Medicine and Biology

Hodgkinson

Bareja

Gómez

et al. 2016

Circulation Research

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242

191

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In the past decade, substantial evidence supports the paradigm that stem cells exert their reparative and regenerative effects, in large part, through the release of biologically active molecules acting in a paracrine fashion on resident cells. The data suggest the existence of a tissue microenvironment where stem cell factors influence cell survival, inflammation, angiogenesis, repair and regeneration in a temporal and spatial manner.

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“…Thus, we successfully used this model to identify Meis1, one of the key regulators of neonatal cardiac regeneration, and report that Meis1 inhibits cardiomyocyte proliferation through transcriptional activation of CDKIs p15, p16, and p21 . Meis1 knockout 9 (pH3 + CMs, Aurora B + CMs) GSK-3 inhibition (BIO) 5 (pH3 + CMs) (Tseng et al, 2006) Foxo1 dominant negative 2.5 (pH3 + CMs) (Evans-Anderson et al, 2008) miR-133a knockout 2.5 (pH3 + CMs) (Liu et al, 2008) Jumonji knockout 2.2 (pH3 + CMs) (Jung et al, 2005) p27 KIP1 knockout 2-3 (troponin I + CMs) (Poolman et al, 1999) Constitutively active ERBB2 >12 (Ki67 + CMs, pH3 + CMs, Aurora B+ CMs) (D'Uva et al, 2015) Nrg1 (or FGF1, periostin) treatment >4 (BrdU + CMs, Aurora B + CMs, pH3 + CMs,) (Bersell et al, 2009) Activated Yap1 >7 (Ki67 + CMs, pH3 + CMs, Aurora B+ CMs) (von Gise et al, 2012) Salv knockout >4 (pH3 + CMs) (Heallen et al, 2011) IL13 (or IL3, CTGF, Nrg1) treatment >1.5 (3H Thymidine CMs, Ki67 + CMs, BrdU + CMs) Oncostatin M treatment >2 (EdU + CMs) (Kubin et al, 2011) TWEAK treatment 6.2 (BrdU + CMs) (Novoyatleva et al, 2010) C3orf58 treatment >2 (Ki67 + CMs, BrdU + CMs, Aurora B + CMs) (Beigi et al, 2013) Periostin treatment >5 (BrdU + CMs, pH3 + CMs, Aurora B+ CMs) (Kühn et al, 2007) FGF10 treatment 2 (Ki67 + CMs, pH3 + CMs,) (Rochais et al, 2014) Cyclin D2 overexpression >5 (MHC-nLAC + CMs) (Pasumarthi et al, 2005) Cyclin B1-CDC2 or cyclin a2 overexpression >1.4 (CMs) (Bicknell et al, 2004) (Cheng et al, 2007) Activated notch >7 (Ki67 + CMs, BrdU + CMs, Aurora B + CMs) (Campa et al, 2008) c-myc or E1A overexpression 2 (CMs) (Jackson et al, 1990) (Liu and Kitsis, 1996) CM: cardiomyocytes.…”

Section: Kip2mentioning

confidence: 99%

Underlying mechanisms and prospects of heart regeneration

Aslan¹,

Misir²,

Kocabaş³

2016

Turk J Biol

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Using electron microscopy in 1974, Oberpriler et al. (1974 demonstrated the prospect of cardiac regeneration in newts. Later, Witman et al. (2011) reported that the adult newt is able to completely regenerate its heart after a basal resection (Witman et al., 2011). Zebrafish (Danio rerio) is a tropical freshwater fish Abstract: Findings in the last decade suggest that there is a considerable amount of cardiomyocyte turnover in the human heart throughout life, albeit not sufficient for heart regeneration following myocardial infarctions. Only a few species are known to be remarkably efficient in cardiac regeneration. They restore lost cardiomyocytes via a process of cardiomyocyte dedifferentiation, which is followed by robust proliferation of cardiomyocytes and incorporation into the myocardium. Similarly, neonatal mice have been recently shown to regenerate their heart following myocardial injuries. Studies with a neonatal cardiac regeneration mouse model suggest that the major source of new cardiomyocytes is likely to be of cardiomyocyte origin, with the possibility of involvement of cardiac stem cells. To this end, numerous studies have been conducted on the induction of cardiac regeneration to shed light on the underlying mechanisms. This review covers studies on the renewal of cardiomyocytes, the utilization of stem cells in myocardial therapies, and their future applications.

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C3orf58 , a Novel Paracrine Protein, Stimulates Cardiomyocyte Cell-Cycle Progression Through the PI3K–AKT–CDK7 Pathway

Cited by 83 publications

References 31 publications

Cloning and sequence analysis of the LOC339524 gene in Sprague-Dawley rats

Cloning and sequence analysis of the LOC339524 gene in Sprague-Dawley rats

Emerging Concepts in Paracrine Mechanisms in Regenerative Cardiovascular Medicine and Biology

Underlying mechanisms and prospects of heart regeneration

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