Timo Strünker

The CatSper channel mediates progesterone-induced Ca2+ influx in human sperm

In the oviduct, cumulus cells that surround the oocyte release progesterone. In human sperm, progesterone stimulates a Ca2+ increase by a non-genomic mechanism. The Ca2+ signal has been proposed to control chemotaxis, hyperactivation and acrosomal exocytosis of sperm. However, the underlying signalling mechanism has remained mysterious. Here we show that progesterone activates the sperm-specific, pH-sensitive CatSper Ca2+ channel. We found that both progesterone and alkaline pH stimulate a rapid Ca2+ influx with almost no latency, incompatible with a signalling pathway involving metabotropic receptors and second messengers. The Ca2+ signals evoked by alkaline pH and progesterone are inhibited by the Cav channel blockers NNC 55-0396 and mibefradil. Patch-clamp recordings from sperm reveal an alkaline-activated current carried by mono- and divalent ions that exhibits all the hallmarks of sperm-specific CatSper Ca2+ channels. Progesterone substantially enhances the CatSper current. The alkaline- and progesterone-activated CatSper current is inhibited by both drugs. Our results resolve a long-standing controversy over the non-genomic progesterone signalling. In human sperm, either the CatSper channel itself or an associated protein serves as the non-genomic progesterone receptor. The identification of CatSper channel blockers will greatly facilitate the study of Ca2+ signalling in sperm and help to define further the physiological role of progesterone and CatSper.

Fast manipulation of cellular cAMP level by light in vivo

The flagellate Euglena gracilis contains a photoactivated adenylyl cyclase (PAC), consisting of the flavoproteins PACα and PACβ. Here we report functional expression of PACs in Xenopus laevis oocytes, HEK293 cells and in Drosophila melanogaster, where neuronal expression yields light-induced changes in behavior. The activity of PACs is strongly and reversibly enhanced by blue light, providing a powerful tool for light-induced manipulation of cAMP in animal cells.

Molecular and functional characterization of an octopamine receptor from honeybee (Apis mellifera) brain

Biogenic amines and their receptors regulate and modulate many physiological and behavioural processes in animals. In vertebrates, octopamine is only found in trace amounts and its function as a true neurotransmitter is unclear. In protostomes, however, octopamine can act as neurotransmitter, neuromodulator and neurohormone. In the honeybee, octopamine acts as a neuromodulator and is involved in learning and memory formation. The identification of potential octopamine receptors is decisive for an understanding of the cellular pathways involved in mediating the effects of octopamine. Here we report the cloning and functional characterization of the first octopamine receptor from the honeybee, Apis mellifera. The gene was isolated from a brain‐specific cDNA library. It encodes a protein most closely related to octopamine receptors from Drosophila melanogaster and Lymnea stagnalis. Signalling properties of the cloned receptor were studied in transiently transfected human embryonic kidney (HEK) 293 cells. Nanomolar to micromolar concentrations of octopamine induced oscillatory increases in the intracellular Ca2+ concentration. In contrast to octopamine, tyramine only elicited Ca2+ responses at micromolar concentrations. The gene is abundantly expressed in many somata of the honeybee brain, suggesting that this octopamine receptor is involved in the processing of sensory inputs, antennal motor outputs and higher‐order brain functions.

A family of octapamine receptors that specifically induce cyclic AMP production or Ca2+ release in Drosophila melanogaster

In invertebrates, the biogenic‐amine octopamine is an important physiological regulator. It controls and modulates neuronal development, circadian rhythm, locomotion, ‘fight or flight’ responses, as well as learning and memory. Octopamine mediates its effects by activation of different GTP‐binding protein (G protein)‐coupled receptor types, which induce either cAMP production or Ca2+ release. Here we describe the functional characterization of two genes from Drosophila melanogaster that encode three octopamine receptors. The first gene (Dmoa1) codes for two polypeptides that are generated by alternative splicing. When heterologously expressed, both receptors cause oscillatory increases of the intracellular Ca2+ concentration in response to applying nanomolar concentrations of octopamine. The second gene (Dmoa2) codes for a receptor that specifically activates adenylate cyclase and causes a rise of intracellular cAMP with an EC50 of ∼3 × 10−8 m octopamine. Tyramine, the precursor of octopamine biosynthesis, activates all three receptors at ≥ 100‐fold higher concentrations, whereas dopamine and serotonin are non‐effective. Developmental expression of Dmoa genes was assessed by RT–PCR. Overlapping but not identical expression patterns were observed for the individual transcripts. The genes characterized in this report encode unique receptors that display signature properties of native octopamine receptors.

The CatSper channel: a polymodal chemosensor in human sperm

The sperm‐specific CatSper channel controls the intracellular Ca2+ concentration ([Ca2+]i) and, thereby, the swimming behaviour of sperm. In humans, CatSper is directly activated by progesterone and prostaglandins—female factors that stimulate Ca2+ influx. Other factors including neurotransmitters, chemokines, and odorants also affect sperm function by changing [Ca2+]i. Several ligands, notably odorants, have been proposed to control Ca2+ entry and motility via G protein‐coupled receptors (GPCRs) and cAMP‐signalling pathways. Here, we show that odorants directly activate CatSper without involving GPCRs and cAMP. Moreover, membrane‐permeable analogues of cyclic nucleotides that have been frequently used to study cAMP‐mediated Ca2+ signalling also activate CatSper directly via an extracellular site. Thus, CatSper or associated protein(s) harbour promiscuous binding sites that can host various ligands. These results contest current concepts of Ca2+ signalling by GPCR and cAMP in mammalian sperm: ligands thought to activate metabotropic pathways, in fact, act via a common ionotropic mechanism. We propose that the CatSper channel complex serves as a polymodal sensor for multiple chemical cues that assist sperm during their voyage across the female genital tract.

Direct action of endocrine disrupting chemicals on human sperm

Synthetic endocrine disrupting chemicals (EDCs), omnipresent in food, household, and personal care products, have been implicated in adverse trends in human reproduction, including infertility and increasing demand for assisted reproduction. Here, we study the action of 96 ubiquitous EDCs on human sperm. We show that structurally diverse EDCs activate the sperm‐specific CatSper channel and, thereby, evoke an intracellular Ca2+ increase, a motility response, and acrosomal exocytosis. Moreover, EDCs desensitize sperm for physiological CatSper ligands and cooperate in low‐dose mixtures to elevate Ca2+ levels in sperm. We conclude that EDCs interfere with various sperm functions and, thereby, might impair human fertilization.

An Atypical CNG Channel Activated by a Single cGMP Molecule Controls Sperm Chemotaxis

The ability of a single molecule of cGMP to activate the K+-selective cyclic nucleotide–gated channel allows sea urchin sperm to find an egg. Finding an Egg in an Ocean Sperm of the sea urchin Arbacia punctulata, which are released into the ocean and must find their way to an egg before fertilization can take place, can sense and respond to a single molecule of the egg-derived chemoattractant resact. This response depends on the production of guanosine 3′,5′-monophosphate (cGMP) and the consequent activation of K+-selective cyclic nucleotide–gated (CNGK) channels, which leads to production of an intracellular calcium signal that regulates movement of the sperm flagellum and thereby the direction in which the sperm cell swims. After cloning the A. punctulata CNGK, Bönigk et al. combined mutational analysis with optical analysis and electrophysiology to explore the mechanisms responsible for this sensitivity. They found that, although CNGK contains four repeating regions, each of which resembles a cyclic nucleotide–gated (CNG) channel subunit and contains a cyclic nucleotide–binding domain, it is activated through binding of only a single molecule of cGMP. Using a compound that cages cGMP and becomes fluorescent after its release, they were able to calibrate the system and determine that fewer than 50 molecules of cGMP were required to mediate the Ca2+ response to a single molecule of resact. Sperm of the sea urchin Arbacia punctulata can respond to a single molecule of chemoattractant released by an egg. The mechanism underlying this extreme sensitivity is unknown. Crucial signaling events in the response of A. punctulata sperm to chemoattractant include the rapid synthesis of the intracellular messenger guanosine 3′,5′-monophosphate (cGMP) and the ensuing membrane hyperpolarization that results from the opening of potassium–selective cyclic nucleotide–gated (CNGK) channels. Here, we use calibrated photolysis of caged cGMP to show that ~45 cGMP molecules are generated during the response to a single molecule of chemoattractant. The CNGK channel can respond to such small cGMP changes because it is exquisitely sensitive to cGMP and activated in a noncooperative fashion. Like voltage-activated Cav and Nav channels, the CNGK polypeptide consists of four homologous repeat sequences. Disabling each of the four cyclic nucleotide–binding sites through mutagenesis revealed that binding of a single cGMP molecule to repeat 3 is necessary and sufficient to activate the CNGK channel. Thus, CNGK has developed a mechanism of activation that is different from the activation of other CNG channels, which requires the cooperative binding of several ligands and operates in the micromolar rather than the nanomolar range.

The Ca2+-activated K+ current of human sperm is mediated by Slo3

Sperm are equipped with a unique set of ion channels that orchestrate fertilization. In mouse sperm, the principal K+ current (IKSper) is carried by the Slo3 channel, which sets the membrane potential (Vm) in a strongly pHi-dependent manner. Here, we show that IKSper in human sperm is activated weakly by pHi and more strongly by Ca2+. Correspondingly, Vm is strongly regulated by Ca2+ and less so by pHi. We find that inhibitors of Slo3 suppress human IKSper, and we identify the Slo3 protein in the flagellum of human sperm. Moreover, heterologously expressed human Slo3, but not mouse Slo3, is activated by Ca2+ rather than by alkaline pHi; current–voltage relations of human Slo3 and human IKSper are similar. We conclude that Slo3 represents the principal K+ channel in human sperm that carries the Ca2+-activated IKSper current. We propose that, in human sperm, the progesterone-evoked Ca2+ influx carried by voltage-gated CatSper channels is limited by Ca2+-controlled hyperpolarization via Slo3. DOI: http://dx.doi.org/10.7554/eLife.01438.001

The CatSper channel controls chemosensation in sea urchin sperm

Sperm guidance is controlled by chemical and physical cues. In many species, Ca2+ bursts in the flagellum govern navigation to the egg. In Arbacia punctulata, a model system of sperm chemotaxis, a cGMP signaling pathway controls these Ca2+ bursts. The underlying Ca2+ channel and its mechanisms of activation are unknown. Here, we identify CatSper Ca2+ channels in the flagellum of A. punctulata sperm. We show that CatSper mediates the chemoattractant‐evoked Ca2+ influx and controls chemotactic steering; a concomitant alkalization serves as a highly cooperative mechanism that enables CatSper to transduce periodic voltage changes into Ca2+ bursts. Our results reveal intriguing phylogenetic commonalities but also variations between marine invertebrates and mammals regarding the function and control of CatSper. The variations probably reflect functional and mechanistic adaptations that evolved during the transition from external to internal fertilization.

Controlling fertilization and cAMP signaling in sperm by optogenetics

Optogenetics is a powerful technique to control cellular activity by light. The light-gated Channelrhodopsin has been widely used to study and manipulate neuronal activity in vivo, whereas optogenetic control of second messengers in vivo has not been examined in depth. In this study, we present a transgenic mouse model expressing a photoactivated adenylyl cyclase (bPAC) in sperm. In transgenic sperm, bPAC mimics the action of the endogenous soluble adenylyl cyclase (SACY) that is required for motility and fertilization: light-stimulation rapidly elevates cAMP, accelerates the flagellar beat, and, thereby, changes swimming behavior of sperm. Furthermore, bPAC replaces endogenous adenylyl cyclase activity. In mutant sperm lacking the bicarbonate-stimulated SACY activity, bPAC restored motility after light-stimulation and, thereby, enabled sperm to fertilize oocytes in vitro. We show that optogenetic control of cAMP in vivo allows to non-invasively study cAMP signaling, to control behaviors of single cells, and to restore a fundamental biological process such as fertilization. DOI: http://dx.doi.org/10.7554/eLife.05161.001