Visinin-like protein 1 regulates natriuretic peptide receptor B in the heart

Accumulating evidence indicates that Visinin-like protein-1 (VILIP-1), a member of the family of neuronal calcium sensor proteins (NCS), modulates a variety of processes in extra-neuronal tissues. In this study, we describe VILIP-1 expression in the human heart, rat cardiomyocytes, and H9c2 cells, and demonstrate that VILIP-1 regulates the cell surface localization of natriuretic peptide receptor B (NPR-B). In preparations from failing hearts, we observed VILIP-1 downregulation and reduced NPR-B signalling. In conclusion, VILIP-1 deficiency may be responsible for the reduced efficiency of the natriuretic peptide system in cardiac hypertrophy and heart failure and may therefore serve as pharmacological target

Correlation of visinin-like-protein-1 expression with clinicopathological features in squamous cell carcinoma of the esophagus

EF-hand Ca(2+)-sensor proteins are key molecules for transducing Ca(2+) signals into physiological answers and changes in cytosolic Ca(2+) concentration control a variety of cellular responses, including proliferation, migration, and differentiation, which are relevant for tumor progression. The Ca(2+)-sensor visinin-like protein-1 (VILIP-1) has recently attracted major interest due to its putative tumor suppressor function. Whereas VILIP-1 is expressed in normal skin, it is downregulated in skin tumors in a murine tumor model. The aim of this study was to investigate the expression of the Ca(2+)-sensor VILIP-1 in squamous cell carcinoma of the esophagus and to correlate expression levels with clinicopathological features of the tumor. We examined VILIP-1 expression in 54 specimens of esophageal squamous cell carcinomas and 24 normal esophagus tissues, with immunohistochemical staining and immunofluorescence co-staining techniques. VILIP-1 expression was completely lost or significantly reduced in esophageal tumor tissue compared with normal squamous epithelium. Correlation with clinicopathological features indicated that there was significantly less VILIP-1 expression in lymph node positive (N = 1) versus lymph node negative (N = 0) tumors (P = 0.002). Although there was no significant difference between highly (G(1)), moderately (G(2)) and poorly differentiated (G(3)) tumors (P = 0.177), VILIP-1 expression in tumors is significantly correlated with the depth of tumor invasion (P = 0.028 between T1, T2, T3, and T4). In contrast, co-staining with the proliferation marker Ki-67 indicated no significant correlation with proliferation rates in tumors (Ki-67 index of the tumor). In summary, the expression of the Ca(2+)-sensor VILIP-1 was found to be lost during development of squamous cell carcinoma of the esophagus. The protein expression level significantly correlates with invasive features, such as depth of tumor invasion and local lymph node metastasis, but not with proliferation rate of tumor cells. (c) 2006 Wiley-Liss, Inc

Volume transmission and wiring transmission from cellular to molecular networks: history and perspectives

The present paper deals with a fundamental issue in neuroscience: the inter-neuronal communication. The paper gives a brief account of our previous and more recent theoretical contributions to the subject and also reports new recent data that support some aspects of our proposal on two major modes of communication in the central nervous system: the wiring and the volume transmission. There exist two competing theories on inter-neuronal communication: the neuron doctrine and the theory of the diffuse nerve network, supported by Cajal and Golgi, respectively (see their respective Nobel Lectures). The present paper gives a brief account of a view on inter-neuronal communication in the brain, the volume and wiring transmission concept that to a great extent reconcile these two theories. Thus, the theory of volume and wiring transmission are summarized and its recent developments that allow to extend these two modes of communication from the cellular network to the molecular network level is also briefly illustrated. The explanatory value of this broadened view is further enhanced by our recent proposal on the existence of a Global Molecular Network enmeshing the entire central nervous system. It may be interesting to note that also the Global Molecular Network theory is reminiscent of the old reticular theory of Apathy. Finally, the so-called 'tide hypothesis' for diffusion of signals in the brain is briefly discussed and its possible extension to the molecular level is for the first time introduced. Early indirect evidence supporting volume transmission in the brain was the discovery of transmitter-receptor mismatches. Thus, as an experimental part of the present paper a new approach to evaluate transmitter-receptor mismatches is given and evidence for inter-relationships between temperature micro-gradients and mismatches is provided