Phosphatidylinositol 4,5-bisphosphate and calcium at ER-PM junctions - Complex interplay of simple messengers

A molecular systems perspective on calcium oscillations beyond ion fluxes

Calcium (Ca2+) oscillations, marked by periodic fluctuations in cytosolic Ca2+ levels, are a universal feature of both excitable and non-excitable cells, regulating key functions like immune responses, neuronal activity and oocyte activation. Despite significant progress over the past few decades in identifying the molecular toolkits involved in Ca2+ mobilization, fundamental questions remain unresolved: How do Ca2+oscillations arise? In dynamical systems, oscillations arise as closed-loop trajectories in phase space, known as limit cycles. In this framework, [Ca2+] is the variable that oscillates along the limit cycle. Is [Ca2+] also the control parameter that defines the system's stability? Understanding how oscillations arise and how instability is controlled are essential for determining what these oscillations encode. This review revisits classic categorizations of Ca2+ oscillation models, focusing on the minimal mathematical models, their assumptions and gaps linking models with experimental data. We examine historical arguments in light of recent discoveries of plasma membrane lipid oscillations in non-excitable cells. While growing evidence support the pivotal role of lipid signaling in regulating Ca2+ dynamics, they mostly focused on the upstream role of signaling in Ca2+ mobilization, rather than viewing membrane-dependent signal transduction as the core control loop that is responsible for oscillatory Ca2+ dynamics. Here we summarize recent molecular studies of phosphoinositide signaling in modulating Ca2+ dynamics, by considering a broader chemical perspective as essential for understanding Ca2+ oscillations beyond ion fluxes.

Ion channels and transporters involved in calcium flux regulation in mammalian sperm

After ejaculation, mammalian spermatozoa are not capable of fertilizing a metaphase II-arrested egg. They require to undergo a series of biochemical and physiological processes collectively known as capacitation. In all these processes, the regulation of calcium ions fluxes plays essential roles and involves participation of many channels and transporters localized in the plasma membrane as well as in the membrane of intracellular organelles. In mammalian sperm, a fraction of these molecules has been proposed to contribute to mature sperm function. However, in many cases, the evidence for the presence of a given protein is based on the use of agonists and antagonists with more than one target. In this review, we will critically analyze the published evidence supporting the presence of these molecules in mammalian sperm with special emphasis to methods involving tandem mass spectrometry identification, electrophysiological evidence and controlled immunoassays.

Dual regulation of IP3 receptors by IP3 and PIP2 controls the transition from local to global Ca2+ signals

The spatial organization of inositol 1,4,5-trisphosphate (IP3)-evoked Ca2+ signals underlies their versatility. Low stimulus intensities evoke Ca2+ puffs, localized Ca2+ signals arising from a few IP3 receptors (IP3Rs) within a cluster tethered beneath the plasma membrane. More intense stimulation evokes global Ca2+ signals. Ca2+ signals propagate regeneratively as the Ca2+ released stimulates more IP3Rs. How is this potentially explosive mechanism constrained to allow local Ca2+ signaling? We developed methods that allow IP3 produced after G-protein coupled receptor (GPCR) activation to be intercepted and replaced by flash photolysis of a caged analog of IP3. We find that phosphatidylinositol 4,5-bisphosphate (PIP2) primes IP3Rs to respond by partially occupying their IP3-binding sites. As GPCRs stimulate IP3 formation, they also deplete PIP2, relieving the priming stimulus. Loss of PIP2 resets IP3R sensitivity and delays the transition from local to global Ca2+ signals. Dual regulation of IP3Rs by PIP2 and IP3 through GPCRs controls the transition from local to global Ca2+ signals.

Regulatory mechanisms controlling store-operated calcium entry

Calcium influx through plasma membrane ion channels is crucial for many events in cellular physiology. Cell surface stimuli lead to the production of inositol 1,4,5-trisphosphate (IP3), which binds to IP3 receptors (IP3R) in the endoplasmic reticulum (ER) to release calcium pools from the ER lumen. This leads to the depletion of ER calcium pools, which has been termed store depletion. Store depletion leads to the dissociation of calcium ions from the EF-hand motif of the ER calcium sensor Stromal Interaction Molecule 1 (STIM1). This leads to a conformational change in STIM1, which helps it to interact with the plasma membrane (PM) at ER:PM junctions. At these ER:PM junctions, STIM1 binds to and activates a calcium channel known as Orai1 to form calcium release-activated calcium (CRAC) channels. Activation of Orai1 leads to calcium influx, known as store-operated calcium entry (SOCE). In addition to Orai1 and STIM1, the homologs of Orai1 and STIM1, such as Orai2/3 and STIM2, also play a crucial role in calcium homeostasis. The influx of calcium through the Orai channel activates a calcium current that has been termed the CRAC current. CRAC channels form multimers and cluster together in large macromolecular assemblies termed "puncta". How CRAC channels form puncta has been contentious since their discovery. In this review, we will outline the history of SOCE, the molecular players involved in this process, as well as the models that have been proposed to explain this critical mechanism in cellular physiology.