Tünde Kovács

How many Ca2+ATPase isoforms are expressed in a cell type? A growing family of membrane proteins illustrated by studies in platelets

Ca2+ signaling plays a key role in normal and abnormal platelet functions. Understanding platelet Ca2+ signaling requires the knowledge of proteins involved in this process. Among these proteins are Ca2+ATPases or Ca2+ pumps that deplete the cytosol of Ca2+ ions. Here, we will particularly focus on two Ca2+ pump families: the plasma membrane Ca2+ATPases (PMCAs) that extrude cytosolic Ca2+ towards the extracellular medium and the sarco/endoplasmic reticulum Ca2+ATPases (SERCAs) that pump Ca2+ into the endoplasmic reticulum (ER). In the present review, we will summarize data on platelet Ca2+ATPases including their identification and biogenesis. First of all, we will present the Ca2+ATPase genes and their isoforms expressed in platelets. We will especially focus on a member of the SERCA family, SERCA3, recently found to give rise to a number of species-specific isoforms. Next, we will describe the differences in Ca2+ATPase patterns observed in human and rat platelets. Last, we will analyze how the expression of Ca2+ATPase isoforms changes during megakaryocytic maturation and show that megakaryocytopoiesis is associated with a profound reorganization of the expression and/or activity of Ca2+ATPases. Taken together, these data provide new aspects of investigations to better understand normal and abnormal platelet Ca2+ signaling.

Endoplasmic reticulum calcium pumps and cancer cell differentiation.

The endoplasmic reticulum (ER) is a major intracellular calcium storage pool and a multifunctional organelle that accomplishes several calcium-dependent functions involved in many homeostatic and signaling mechanisms. Calcium is accumulated in the ER by Sarco/Endoplasmic Reticulum Calcium ATPase (SERCA)-type calcium pumps. SERCA activity can determine ER calcium content available for intra-ER functions and for calcium release into the cytosol, and can shape the spatiotemporal characteristics of calcium signals. SERCA function therefore constitutes an important nodal point in the regulation of cellular calcium homeostasis and signaling, and can exert important effects on cell growth, differentiation and survival. In several cell types such as cells of hematopoietic origin, mammary, gastric and colonic epithelium, SERCA2 and SERCA3-type calcium pumps are simultaneously expressed, and SERCA3 expression levels undergo significant changes during cell differentiation, activation or immortalization. In addition, SERCA3 expression is decreased or lost in several tumor types when compared to the corresponding normal tissue. These observations indicate that ER calcium homeostasis is remodeled during cell differentiation, and may present defects due to decreased SERCA3 expression in tumors. Modulation of the state of differentiation of the ER reflected by SERCA3 expression constitutes an interesting new aspect of cell differentiation and tumor biology.

The platelet Ca2+ transport ATPase system

The Ca2+ signal accompanying cell function involves the activities of plasma membrane Ca2+ transport ATPases (PMCA) which transport Ca2+ ions out of the cell and those of sarco/endoplasmic reticulum Ca2+ transport ATPases (SERCA), which pump Ca2+ ions into intracellular Ca2+ pools. Although a platelet Ca2+ transport ATPase was described three decades ago, for a long time it remained poorly understood in terms of its cellular localization and identity. By integrating data obtained during recent years, including newly available information in the literature for the PMCAs and aspects of our work concerning the SERCAs, the present review will show how the overall view of the platelet Ca2+ATPase system has to be modified due to the presence of a number of Ca2+ATPases in these cells. These Ca2+ATPases include a typical 144 kDa PMCA protein, although its molecular identity still remains to be established, expressed together with a multi-SERCA system constituted by the ubiquitous 100 kDa SERCA 2b isoform, the 97 kDa SERCA 3 isoform and a new 97 kDa SERCA isoform recognized by the monoclonal antibody termed PL/IM 430 which also remains to be identified. The new paradigm of the platelet multi-Ca2+ATPase system will be discussed including: (i) the problems solved, as it has now become possible to reconciliate previous contradictory observations and (ii) those which still remain due to the fact that the platelet Ca2+ATPase system is more complex than previously assumed. Finally, to put this complexity of the platelet Ca2+ transport ATPase system into perspective, the biological significance of the multi-SERCA system in the context of Ca2+ signalling will be tentatively discussed in an attempt to produce a model of the organization of the intracellular Ca2+ pools in platelets.

interaction of antithrombin III and thrombinantithrombin III complex with cultured aortic endothelial cells

The binding of antithrombin III, thrombin, thrombin-antithrombin III complex to endothelial cells was investigated. While the rate of the binding of thrombin to these cells was very rapid, that of antithrombin III was relatively slow and the thrombin-antithrombin III complex was intermediate. Binding kinetics indicated that antithrombin III, like thrombin, showed high affinity to endothelial cells; with a Kd of 3 X 10(-8) M and with 5 X 10(4) binding sites per cell. The dissociation of the inhibitor molecule was also rapid, i.e., approximately 70% bound antithrombin III was released in 2 minutes. Heparin, in a 100-fold molar excess to antithrombin III, or the modification of lysine residues of the inhibitor involved in the interaction with heparin, did not influence the association of antithrombin III with endothelial cells. In addition, antithrombin III did not compete with thrombin blocked in its active center for binding to endothelial cells. It is suggested that the binding sites of endothelial cells are different for thrombin and antithrombin III, and antithrombin III does not bind to these cells through its heparin binding domain.