Abstract
Calcium is one of the most important signaling factors in mammalian cells. Specific temporal and spatial calcium signals underlie fundamental processes such as cell growth, development, circadian rhythms, neurotransmission, hormonal actions and apoptosis. In order to translate calcium signals into cellular processes a vast number of proteins bind this ion with affinities from the nanomolar to millimolar range. Using classical biochemical methods an impressing number of calcium binding proteins (CBPs) have been discovered since the late 1960s, some of which are expressed ubiquitously, others are more restricted to specific cell types. In the nervous system expression patterns of different CBPs have been used to discern different neuronal cell populations, especially before advanced methods like single-cell transcriptomics and activity recording were available to define neuronal identity. However, understanding CBPs and their interacting proteins is still of central interest. The post-genomic era has coined the term “calciomics,” to describe a whole new research field, that engages in the identification and characterization of CBPs and their interactome. Secretagogin is a CBP, that was discovered 20 years ago in the pancreas. Consecutively it was found also in other organs including the nervous system, with characteristic expression patterns mostly forming cell clusters. Its regional expression and subcellular location together with the identification of protein interaction partners implicated, that secretagogin has a central role in hormone secretion. Meanwhile, with the help of modern proteomics a large number of actual and putative interacting proteins has been identified, that allow to anticipate a much more complex role of secretagogin in developing and adult neuronal cells. Here, we review recent findings that appear like puzzle stones of a greater picture.
Highlights
Calcium ions (Ca2+) are one of the major messengers used by cells to regulate their metabolism, drive gene expression and activate specific cellular functions like exo- and endocytosis or contraction
Activation of Ca2+-dependent signaling pathways can be initiated by membrane depolarization or extracellular signaling molecules that activate voltage- or ligand-activated calcium channels in the plasma membrane or via intracellular messengers that cause the release of Ca2+ from intracellular stores, mainly via the 1, 4, 5- triphosphate receptor (IP3R) or the ryanodine receptor (RyR) from the endoplasmatic reticulum (ER) or sarcoplasmic reticulum (SR) (Supnet and Bezprozvanny, 2010)
The amplitude and duration of the signal is shaped by cytosolic Ca2+ buffers like parvalbumin, calbindin-D28K and calretinin that transiently take up Ca2+ and contribute to the spatial restriction of the signal
Summary
Secretagogin’s expression pattern is not conserved from rodents to humans and significant differences exist between mice and rats (Garas et al, 2016; Raju et al, 2018). The data presented by Romanov et al (2015) and Alpár et al (2018) define a critical role of secretagogin in the molecular axis of stress responsiveness Their results let the study of Gyengesi et al (2013) appear in a new light: the bed nucleus of the stria terminalis functions as a regulator of the HPA-axis and many of the SCGN-positive neurons identified in this area are CRH-positive. It has been shown, that CBPs like parvalbumin, calbindin-D28K and calretinin (i.e., Ca2+ buffers) protect neurons from detrimental Ca2+ overload as it occurs for instance in ischemic conditions (Turovsky et al, 2018). Future studies will have to pave the way for translation of novel diagnostics and to investigate, if SCGN can serve as a biomarker especially in neuro-psychiatric onsets
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