Roberta Ferretti

Cardiac Overexpression of Melusin Protects From Dilated Cardiomyopathy Due to Long-Standing Pressure Overload

We have previously shown that genetic ablation of melusin, a muscle specific &bgr; 1 integrin interacting protein, accelerates left ventricle (LV) dilation and heart failure in response to pressure overload. Here we show that melusin expression was increased during compensated cardiac hypertrophy in mice subjected to 1 week pressure overload, but returned to basal levels in LV that have undergone dilation after 12 weeks of pressure overload. To better understand the role of melusin in cardiac remodeling, we overexpressed melusin in heart of transgenic mice. Echocardiography analysis indicated that melusin over-expression induced a mild cardiac hypertrophy in basal conditions (30% increase in interventricular septum thickness) with no obvious structural and functional alterations. After prolonged pressure overload (12 weeks), melusin overexpressing hearts underwent further hypertrophy retaining concentric LV remodeling and full contractile function, whereas wild-type LV showed pronounced chamber dilation with an impaired contractility. Analysis of signaling pathways indicated that melusin overexpression induced increased basal phosphorylation of GSK3&bgr; and ERK1/2. Moreover, AKT, GSK3&bgr; and ERK1/2 were hyper-phosphorylated on pressure overload in melusin overexpressing compared with wild-type mice. In addition, after 12 weeks of pressure overload LV of melusin overexpressing mice showed a very low level of cardiomyocyte apoptosis and stromal tissue deposition, as well as increased capillary density compared with wild-type. These results demonstrate that melusin overexpression allows prolonged concentric compensatory hypertrophy and protects against the transition toward cardiac dilation and failure in response to long-standing pressure overload.

The mammalian CHORD-containing protein melusin is a stress response protein interacting with Hsp90 and Sgt1

MINT‐6538515:melusin (Q9R000)physically interacts (MI:0218) with Hsp90 (P07901) by anti bait co-immunoprecipitation (MI:0006) MINT‐6538566, MINT‐6538556:Hsp90 (P07901) physically interacts (MI:0218) with melusin (Q9R000) by cross-linking studies (MI:0030) MINT‐6538524:melusin (Q9R000) physically interacts (MI:0218) with Sgt1 (Q9CS74) by anti tag co-immunoprecipitation (MI:0007) MINT‐6538595:Hsp90 (P07901) physically interacts (MI:0218) with melusin (Q9R000) by enzyme linked immunosorbent assay (MI:0411) MINT‐6538543:melusin (Q9R000) physically interacts (MI:0218) with Sgt1 (Q9CS74) by anti bait co-immunoprecipitation (MI:0006) MINT‐6538580: melusin (Q9R000) physically interacts (MI:0218) with Hsp90 (P07901) by surface plasmon resonance (MI:0107)

Morgana/chp-1, a ROCK Inhibitor Involved in Centrosome Duplication and Tumorigenesis

Centrosome abnormalities lead to genomic instability and are a common feature of many cancer cells. Here we show that mutations in morgana/chp-1 result in centrosome amplification and lethality in both Drosophila and mouse, and that the fly centrosome phenotype is fully rescued by the human ortholog of morgana. In mouse cells, morgana forms a complex with Hsp90 and ROCK I and II, and directly binds ROCK II. Morgana downregulation promotes the interaction between ROCK II and nucleophosmin (NPM), leading to an increased ROCK II kinase activity, which results in centrosome amplification. Morgana(+/-) primary cells and mice display an increased susceptibility to neoplastic transformation. In addition, tumor tissue array histochemical analysis revealed that morgana is underexpressed in a large fraction of breast and lung human cancers. Thus, morgana/chp-1 appears to prevent both centrosome amplification and tumorigenesis.

Chp-1 and melusin, two CHORD containing proteins in vertebrates.

Melusin is a muscle specific protein required for heart hypertrophy in response to mechanical overload. Here we describe a protein 63% homologous to melusin, named chp‐1, expressed in all tissues tested, including muscles, and highly conserved from invertebrates to human. Both proteins are characterized in their N‐terminal half by a tandemly repeated zinc binding 60 amino acid domain with a motif of uniquely spaced cysteine and histidine residues. These motives are highly conserved from plants to mammals and have been recently named CHORD (for cysteine and histidine rich domain) domains. At the C‐terminal end melusin contains a calcium binding stretch of 30 acidic amino acid residues which is absent in chp‐1. While invertebrate genome contains only one gene coding for a chp‐1 homolog, two genes coding for CHORD containing proteins (chp‐1 and melusin) are present in vertebrates. Sequence analysis suggests that the muscle specific CHORD containing protein melusin originated by a gene duplication event during early chordate evolution.

Morgana and melusin: two fairies chaperoning signal transduction.

Chaperones and scaffold proteins are key elements involved in controlling the assembly of molecular complexes required for coordinated signal transduction. Here we describe morgana and melusin, two phylogenetically conserved chaperones that cooperate with Hsp90 and regulate signal transduction in important physiopathological processes. While morgana is ubiquitously expressed, melusin expression is restricted to striated muscles. Despite high sequence homology, the two chaperones have distinct functions. Morgana controls genomic stability by regulating the centrosome cycle via ROCKII kinase. Melusin, however, organizes ERK signal transduction in cardiomyocytes and regulates cardiac compensatory hypertrophy in response to different stress stimuli.

Morgana/CHP-1 is a novel chaperone able to protect cells from stress.

Morgana/CHP-1 (CHORD containing protein-1) has been recently shown to be necessary for proper cell divisions. However, the presence of the protein in postmitotic tissues such as brain and striated muscle suggests that morgana/CHP-1 has additional cellular functions. Here we show that morgana/CHP-1 behaves like an HSP90 co-chaperone and possesses an independent molecular chaperone activity towards denatured proteins. The expression time profile of morgana/Chp-1 in NIH3T3 cells in response to heat stress is similar to that of Hsp70, a classical effector of Heat Shock Factor-1 mediated stress response. Moreover, overexpression of morgana/CHP-1 in NIH3T3 cells leads to the increased stress resistance of the cells. Interestingly, morgana/Chp-1 upregulation in response to transient global brain ischemia lasts longer in ischemia-resistant regions of the gerbil hippocampus than in vulnerable ones, suggesting the involvement of morgana/CHP-1 in natural protective mechanisms in vivo.

Morgana acts as an oncosuppressor in chronic myeloid leukemia

We recently described morgana as an essential protein able to regulate centrosome duplication and genomic stability, by inhibiting ROCK. Here we show that morgana (+/-) mice spontaneously develop a lethal myeloproliferative disease resembling human atypical chronic myeloid leukemia (aCML), preceded by ROCK hyperactivation, centrosome amplification, and cytogenetic abnormalities in the bone marrow (BM). Moreover, we found that morgana is underexpressed in the BM of patients affected by atypical CML, a disorder of poorly understood molecular basis, characterized by nonrecurrent cytogenetic abnormalities. Morgana is also underexpressed in the BM of a portion of patients affected by Philadelphia-positive CML (Ph(+) CML) caused by the BCR-ABL oncogene, and in this condition, morgana underexpression predicts a worse response to imatinib, the standard treatment for Ph(+) CML. Thus, morgana acts as an oncosuppressor with different modalities: (1) Morgana underexpression induces centrosome amplification and cytogenetic abnormalities, and (2) in Ph(+) CML, it synergizes with BCR-ABL signaling, reducing the efficacy of imatinib treatment. Importantly, ROCK inhibition in the BM of patients underexpressing morgana restored the efficacy of imatinib to induce apoptosis, suggesting that ROCK inhibitors, combined with imatinib treatment, can overcome suboptimal responses in patients in which morgana is underexpressed.

Morgana acts as a proto‐oncogene through inhibition of a ROCK–PTEN pathway

Morgana/CHP‐1 is a ubiquitously expressed protein able to inhibit ROCK II kinase activity. We have previously demonstrated that morgana haploinsufficiency leads to multiple centrosomes, genomic instability, and higher susceptibility to tumour development. While a large fraction of human cancers has shown morgana down‐regulation, a small subset of tumours was shown to express high morgana levels. Here we demonstrate that high morgana expression in different breast cancer subtypes correlates with high tumour grade, mitosis number, and lymph node positivity. Moreover, morgana overexpression induces transformation in NIH‐3T3 cells and strongly protects them from various apoptotic stimuli. From a mechanistic point of view, we demonstrate that morgana causes PTEN destabilization, by inhibiting ROCK activity, hence triggering the PI3K/AKT survival pathway. In turn, morgana down‐regulation in breast cancer cells that express high morgana levels increases PTEN expression and leads to sensitization of cells to chemotherapy. Copyright

P11.46 Morgana overexpression confers resistance from apoptotic cell death

Resumen del poster presentado al 36th FEBS Congress celebrado en Torino (Italia) del 25 al 30 de Junio de 2011.-- et al.