Intracellular Ca 2C stores play a central role in the regulation of cellular [Ca 2C ] i and the generation of complex [Ca 2C ] signals such as oscillations and waves. Ca 2C signalling is of particular significance in sperm cells, where it is a central regulator in many key activities (including capacitation, hyperactivation, chemotaxis and acrosome reaction) yet mature sperm lack endoplasmic reticulum and several other organelles that serve as Ca 2C stores in somatic cells. Here, we review i) the evidence for the expression in sperm of the molecular components (pumps and channels) which are functionally significant in the activity of Ca 2C stores of somatic cells and ii) the evidence for the existence of functional Ca 2C stores in sperm. This evidence supports the existence of at least two storage organelles in mammalian sperm, one in the acrosomal region and another in the region of the sperm neck and midpiece. We then go on to discuss the probable identity of these organelles and their discrete functions: regulation by the acrosome of its own secretion and regulation by membranous organelles at the sperm neck (and possibly by the mitochondria) of flagellar activity and hyperactivation. Finally, we consider the ability of the sperm discretely to control mobilisation of these stores and the functional interaction of stored Ca 2C at the sperm neck/midpiece with CatSper channels in the principal piece in regulation of the activities of mammalian sperm.Reproduction (
Background: Ca2+ signals, elicited by cues from the oocyte and female tract, regulate human sperm behavior.Results: CatSper channel activation (flagellum) and Ca2+ store mobilization (neck) caused similar [Ca2+]i elevation but induced functionally different behaviors.Conclusion: Sperm motility pattern is determined by the site of Ca2+ mobilization.Significance: Selection of Ca2+ signaling components and/or regulation of their availability for activation controls human sperm behavior.
Ca2+i signalling is pivotal to sperm function. Progesterone, the best-characterized agonist of human sperm Ca2+i signalling, stimulates a biphasic [Ca2+]i rise, comprising a transient and subsequent sustained phase. In accordance with recent reports that progesterone directly activates CatSper, the [Ca2+]i transient was detectable in the anterior flagellum (where CatSper is expressed) 1–2 s before responses in the head and neck. Pre-treatment with 5 μM 2-APB (2-aminoethoxydiphenyl borate), which enhances activity of store-operated channel proteins (Orai) by facilitating interaction with their activator [STIM (stromal interaction molecule)] ‘amplified’ progesterone-induced [Ca2+]i transients at the sperm neck/midpiece without modifying kinetics. The flagellar [Ca2+]i response was unchanged. 2-APB (5 μM) also enhanced the sustained response in the midpiece, possibly reflecting mitochondrial Ca2+ accumulation downstream of the potentiated [Ca2+]i transient. Pre-treatment with 50–100 μM 2-APB failed to potentiate the transient and suppressed sustained [Ca2+]i elevation. When applied during the [Ca2+]i plateau, 50–100 μM 2-APB caused a transient fall in [Ca2+]i, which then recovered despite the continued presence of 2-APB. Loperamide (a chemically different store-operated channel agonist) enhanced the progesterone-induced [Ca2+]i signal and potentiated progesterone-induced hyperactivated motility. Neither 2-APB nor loperamide raised pHi (which would activate CatSper) and both compounds inhibited CatSper currents. STIM and Orai were detected and localized primarily to the neck/midpiece and acrosome where Ca2+ stores are present and the effects of 2-APB are focussed, but store-operated currents could not be detected in human sperm. We propose that 2-APB-sensitive channels amplify [Ca2+]i elevation induced by progesterone (and other CatSper agonists), amplifying, propagating and providing spatio-temporal complexity in [Ca2+]i signals of human sperm.
Fluorescence microscopy of cells loaded with fluorescent, Ca 2+ -sensitive dyes is used for measurement of spatial and temporal aspects of Ca 2+ signaling in live cells. Here we describe the method used in our laboratories for loading suspensions of human sperm with Ca 2+-reporting dyes and measuring the fluorescence signal during physiological stimulation. Motile cells are isolated by direct swim-up and incubated under capacitating conditions for 0-24 h, depending upon the experiment. The cell-permeant AM (acetoxy methyl ester) ester form of the Ca 2+ -reporting dye is then added to a cell aliquot and a period of 1 h is allowed for loading of the dye into the cytoplasm. We use visible wavelength dyes to minimize photo-damage to the cells, but this means that ratiometric recording is not possible. Advantages and disadvantages of this approach are discussed. During the loading period cells are introduced into an imaging chamber and allowed to adhere to a poly-D-lysine coated coverslip. At the end of the loading period excess dye and loose cells are removed by connection of the chamber to the perfusion apparatus. The chamber is perfused continuously, stimuli and modified salines are then added to the perfusion header. Experiments are recorded by time-lapse acquisition of fluorescence images and analyzed in detail offline, by manually drawing regions of interest. Data are normalized to pre-stimulus levels such that, for each cell (or part of a cell), a graph showing the Ca 2+ response as % change in fluorescence is obtained. Video LinkThe video component of this article can be found at http://www.jove.com/video/1996/ ProtocolSperm from healthy fertile males, with a normal semen analysis, are normally prepared for imaging as follows. .8 Na lactate) supplemented with 0.3% charcoal de-lipidated/fatty acid free Fraction V BSA (quality of the BSA is crucial for successful capacitation of sperm). 1 ml of sEBBS is pipetted into each of a series of 5 ml tubes and gently underlayered with 0.3 ml of semen. After incubation for 1 hour (37°C; 6% CO 2 ) the top 0.7 ml is gently removed from each tube and pooled. 10 μl of the sperm suspension is diluted with 90 μl of 1% (v/v) formalin to immobilize the cells, then sperm are counted in a Neubauer chamber. Cell density in the suspension is then adjusted (with sEBSS) to 6 million cells/ml. 2. The sample is then divided into aliquots of 200 μl in loosely-capped tubes and incubated (37°C; 6% CO 2 ) in for 5-6 h to allow capacitation. 3. Coverslips (22x50 mm) have previously been treated with poly-D-lysine. 10 μl of poly-D-lysine solution (10% w/v) is applied as a number of small drops to the centre of the coverslip. The poly-D-lysine is then allowed to air dry. This can be on a heated stage and should be to complete dryness. A coverslip is attached with vacuum grease to an enclosed, purpose-built, perfusable, polycarbonate imaging chamber (dimensions 35 mm x 20 mm x 5 mm; capacity ≈ 180 μl) similar to the Warner RC20 chamber .The poly-D-lysine-coated coverslip forms the base ...
Previous work has provided evidence for involvement of store-operated channels (SOCs) in [Ca2+]i signalling of human sperm, including a contribution to the transient [Ca2+]i elevation that occurs upon activation of CatSper, a sperm-specific cation channel localized to the flagellum, by progesterone. To further investigate the potential involvement of SOCs in the generation of [Ca2+]i signals in human sperm, we have used cell-penetrating peptides containing the important basic sequence KIKKK, part of the STIM–Orai activating region/CRAC activating domain (SOAR/CAD) of the regulatory protein stromal interaction molecule 1. SOAR/CAD plays a key role in controlling the opening of SOCs, which occurs upon mobilization of stored Ca2+. Resting [Ca2+]i temporarily decreased upon application of KIKKK peptide (3–4 min), but scrambled KIKKK peptide had a similar effect, indicating that this action was not sequence-specific. However, in cells pretreated with KIKKK, the transient [Ca2+]i elevation induced by stimulation with progesterone decayed significantly more slowly than in parallel controls and in cells pretreated with scrambled KIKKK peptide. Examination of single-cell responses showed that this effect was due, at least in part, to an increase in the proportion of cells in which the initial transient was maintained for an extended period, lasting up to 10 min in a subpopulation of cells. We hypothesize that SOCs contribute to the progesterone-induced [Ca2+]i transient, and that interference with the regulatory mechanisms of SOC delays their closure, causing a prolongation of the [Ca2+]i transient.
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