Masakatsu Fujinoki

Serotonin-enhanced hyperactivation of hamster sperm

The effects of serotonin on reproductive function were examined using hamster spermatozoa. When serotonin at concentrations from 1 fmol/l to 1 μmol/l was added to modified Tyrodes albumin lactate pyruvate (mTALP) medium, hyperactivation was significantly enhanced. Agonists and antagonists of 5-hydroxytryptamine hydrochloride (5-HT) receptors (5-HT(2) and 5-HT(4) receptors) were added to the medium. Both 5-HT(2) and 5-HT(4) receptor agonists significantly enhanced hyperactivation, although the effect was greater than the former. However, both 5-HT(2) and 5-HT(4) receptor antagonists significantly suppressed serotonin-enhanced hyperactivation, with the former suppressing stimulation by a lower concentration of serotonin than the latter. These results indicate that serotonin enhances hyperactivation via 5-HT(2) and/or 5-HT(4) receptors in a dose-dependent manner.

Suppression of progesterone-enhanced hyperactivation in hamster spermatozoa by estrogen

In this study, I examined whether sperm hyperactivation in hamster is regulated by steroid hormones such as estrogen (estradiol, E(2)) and progesterone. Although sperm hyperactivation was enhanced by progesterone, 17beta-estradiol (17betaE(2)) itself did not affect sperm hyperactivation. However, 17betaE(2) suppressed progesterone-enhanced hyperactivation in a concentration-dependent manner through non-genomic pathways when spermatozoa were exposed to 17betaE(2) at the same time or before exposure to progesterone. When spermatozoa were exposed to 17betaE(2) after exposure to progesterone, 17betaE(2) did not suppress progesterone-enhanced hyperactivation. Moreover, 17alpha-estradiol, an inactive isomer of E(2), did not suppress progesterone-enhanced hyperactivation. Observations using a FITC-conjugated 17betaE(2) showed that it binds to the acrosome region of the sperm head. Binding of 17betaE(2) to spermatozoa was not inhibited by progesterone, although 17betaE(2) did not suppress progesterone-enhanced hyperactivation when spermatozoa were exposed to 17betaE(2) after exposure to progesterone. On the other hand, binding of progesterone to spermatozoa was also not inhibited by 17betaE(2) even if progesterone-enhanced hyperactivation was suppressed by 17betaE(2). Although tyrosine phosphorylations of sperm proteins were enhanced by progesterone, enhancement of tyrosine phosphorylations by progesterone was suppressed by 17betaE(2). Moreover, tyrosine phosphorylations were inhibited by 17betaE(2) when only 17betaE(2) was added to the medium. From these results, it is likely that 17betaE(2) competitively suppresses progesterone-enhanced hyperactivation through the inhibition of tyrosine phosphorylations via non-genomic pathways.

Regulation of hyperactivation of hamster spermatozoa by progesterone

AimAlthough it is accepted that progesterone (P) induces acrosome reaction through non-genomic regulation, it is not well known if P also affects hyperactivation of sperm.MethodsHamster spermatozoa were hyperactivated by incubation for 4 h on modified Tyrode’s albumin lactate pyruvate medium and recorded on a DVD via a charge-coupled device camera attached to a microscope with phase-contrast illumination and a small CO2 incubator. Phosphorylation of proteins was detected by western blotting using antiphosphotyrosine antibodies.ResultsSperm hyperactivation was significantly increased and accelerated by a non-genomic signal of P. Although acceleration of motility of hyperactivated sperm occurred with 10, 20 and 40 ng/mL P, the most effective concentration was 20 ng/mL. Progesterone also significantly increased 80-kDa tyrosine phosphorylation of sperm proteins. Both extracellular Ca2+ and albumin were essential for sperm hyperactivation, and the former was also essential for maintaining sperm flagellar movement. Moreover, phospholipase C (PLC) was associated with the regulation of hyperactivation by P.ConclusionIt is likely that P regulates sperm hyperactivation by a non-genomic signal in relation to tyrosine phosphorylation and PLC.

Non-genomic regulation of mammalian sperm hyperactivation

Although it has been suggested that the acrosome reaction is induced through non-genomic regulation in a ligand-dependent manner, it is not known whether hyperactivation is similarly regulated. Progesterone and melatonin have been identified as ligands that regulate hyperactivation, the former through non-genomic regulation with phospholipase C and the latter most likely through a reactive oxygen species-mitogen activated protein kinase cascade. Both may be involved in spontaneous regulation of hyperactivation via tyrosine phosphorylation. The concentration of many hormones changes according to environmental conditions and biological rhythms, which will modulate ligand-dependent regulation of hyperactivation.

Non-genomic regulation and disruption of spermatozoal in vitro hyperactivation by oviductal hormones

During capacitation, motility of mammalian spermatozoon is changed from a state of “activation” to “hyperactivation.” Recently, it has been suggested that some hormones present in the oviduct are involved in the regulation of this hyperactivation in vitro. Progesterone, melatonin, and serotonin enhance hyperactivation through specific membrane receptors, and 17β-estradiol suppresses this enhancement by progesterone and melatonin via a membrane estrogen receptor. Moreover, γ-aminobutyric acid suppresses progesterone-enhanced hyperactivation through the γ-aminobutyric acid receptor. These hormones dose-dependently affect hyperactivation. Although the complete signaling pathway is not clear, progesterone activates phospholipase C and protein kinases and enhances tyrosine phosphorylation. Moreover, tyrosine phosphorylation is suppressed by 17β-estradiol. This regulation of spermatozoal hyperactivation by steroids is also disrupted by diethylstilbestrol. The in vitro experiments reviewed here suggest that mammalian spermatozoa are able to respond to effects of oviductal hormones. We therefore assume that the enhancement of spermatozoal hyperactivation is also regulated by oviductal hormones in vivo.

Suppression of progesterone-enhanced hyperactivation in hamster spermatozoa by γ-aminobutyric acid.

It has been recently shown that mammalian spermatozoa were hyperactivated by steroids, amines and amino acids. In the present study, we investigated whether hyperactivation of hamster sperm is regulated by progesterone (P) and γ-aminobutyric acid (GABA). Although sperm hyperactivation was enhanced by P, GABA significantly suppressed P-enhanced hyperactivation in a dose-dependent manner. Suppression of P-enhanced hyperactivation by GABA was significantly inhibited by an antagonist of the GABAA receptor (bicuculline). Moreover, P bound to the sperm head, and this binding was decreased by GABA. Because the concentrations of GABA and P change in association with the estrous cycle, these results suggest that GABA and P competitively regulate the enhancement of hyperactivation through the GABAA receptor.

Estrogen suppresses melatonin-enhanced hyperactivation of hamster spermatozoa.

Hamster sperm hyperactivation is enhanced by progesterone, and this progesterone-enhanced hyperactivation is suppressed by 17β-estradiol (17βE2) and γ-aminobutyric acid (GABA). Although it has been indicated that melatonin also enhances hyperactivation, it is unknown whether melatonin-enhanced hyperactivation is also suppressed by 17βE2 and GABA. In the present study, melatonin-enhanced hyperactivation was significantly suppressed by 17βE2 but not by GABA. Moreover, suppression of melatonin-enhanced hyperactivation by 17βE2 occurred through non-genomic regulation via the estrogen receptor (ER). These results suggest that enhancement of hyperactivation is regulated by melatonin and 17βE2 through non-genomic regulation.

Regulation and disruption of hamster sperm hyperactivation by progesterone, 17β-estradiol and diethylstilbestrol

PurposeHyperactivation of hamster sperm is dose-dependently enhanced by progesterone (P) and 17β-estradiol (E). In the first part of the present study, enhancement of hyperactivation in response to the concentrations of P and E was examined in detail and in the second part, it was examined whether enhancement of hyperactivation by P and E was disrupted by diethylstilbestrol (DES).MethodsHamster spermatozoa were hyperactivated by incubation in modified Tyrode’s albumin lactate pyruvate medium with P, E and/or DES. After spermatozoa were recorded using a video-microscope, observations were quantified by manually counting the numbers of total, motile and hyperactivated spermatozoa.ResultsHyperactivation was enhanced in response to the concentrations of P and E. When spermatozoa were exposed to DES with E, moreover, DES significantly and strongly suppressed P-enhanced hyperactivation by accelerating the effect of E, but DES itself only weakly suppressed P-enhanced hyperactivation.ConclusionsEnhancement of hyperactivation was regulated by the concentrations of P and E, suggesting that in vivo hamster spermatozoa are hyperactivated through “monitoring” these concentrations in the oviduct. DES in combination with E suppressed P-enhanced hyperactivation, suggesting that DES significantly disrupts hyperactivation by acting as an accelerator of the effect of E.

γ-Aminobutyric acid suppresses enhancement of hamster sperm hyperactivation by 5-hydroxytryptamine

Sperm hyperactivation is regulated by hormones present in the oviduct. In hamsters, 5-hydroxytryptamine (5HT) enhances hyperactivation associated with the 5HT2 receptor and 5HT4 receptor, while 17β-estradiol (E2) and γ-aminobutyric acid (GABA) suppress the association of the estrogen receptor and GABAA receptor, respectively. In the present study, we examined the regulatory interactions among 5HT, GABA, and E2 in the regulation of hamster sperm hyperactivation. When sperm were exposed to E2 prior to 5HT exposure, E2 did not affect 5HT-enhanced hyperactivation. In contrast, GABA partially suppressed 5HT-enhanced hyperactivation when sperm were exposed to GABA prior to 5HT. GABA suppressed 5HT-enhanced hyperactivation associated with the 5HT2 receptor although it did not suppress 5HT-enhanced hyperactivation associated with the 5HT4 receptor. These results demonstrate that hamster sperm hyperactivation is regulated by an interaction between the 5HT2 receptor-mediated action of 5HT and GABA.

Regulatory mechanisms of sperm flagellar motility by metachronal and synchronous sliding of doublet microtubules

STUDY QUESTION What is the role of metachronal and synchronous sliding in sperm flagellar motility? SUMMARY ANSWER Both metachronal and oscillatory synchronous sliding are essential for sperm flagellar motility, while the change in mode of synchronous sliding between the non-oscillatory synchronous sliding of a specific pair of the doublet microtubules and the oscillatory synchronous sliding between most pairs of doublet microtubules modulates the sperm flagellar motility. WHAT IS KNOWN ALREADY Metachronal and synchronous sliding of doublet microtubules are involved in sperm flagellar motility and regulation of these sliding movements controls flagellar bend formation. STUDY DESIGN, SIZE, DURATION To study the regulatory mechanisms of metachronal and synchronous sliding in flagellar movement of golden hamster spermatozoa, changes in these sliding movements during hyperactivation were examined by measuring the angle of the tangent to the flagellar shaft with reference to the central axis of the sperm head (the shear angle) along the flagellum. Golden hamster spermatozoa were obtained from the caudal epididymis of five sexually mature golden hamsters. Results from three experiments were averaged. The number of spermatozoa analyzed is 15 activated sperm, 22 hyperactivated sperm and 20 acrosome-reacted sperm. PARTICIPANTS/MATERIALS, SETTING, METHODS For detailed field-by-field analysis, an individual flagellar image was tracked automatically using the Autotrace module of image analysis software. The coordinate values of the flagellar shaft were used to calculate the shear angle, which is proportional to the amount of microtubule sliding at any given position along the flagellum. The maximum shear angles of metachronal and synchronous sliding were obtained from the mean shear angles between the maximum shear angles of pro-hook bends and the absolute values of the minimum shear angles of anti-hook bends, which represent the amplitude of a set of successive shear angle curves, with 3-12 shear curves covering one beat cycle of sperm flagellar movement. Asymmetry of flagellar waves was expressed by the mean shear angle between the maximum shear angle of pro-hook bends and the minimum shear angle of anti-hook bends at 100 μm from the head-midpiece junction. MAIN RESULTS AND THE ROLE OF CHANCE The asymmetrical flagellar movements observed in the activated (non-hyperactivated) and hyperactivated spermatozoa were characterized by the non-oscillatory synchronous sliding of a specific pair of the doublets; the large asymmetrical flagellar movement in the hyperactivated spermatozoa was generated by the large non-oscillatory synchronous sliding. Both the metachronal and synchronous sliding increased during the hyperactivation; however, the large symmetrical flagellar movement of the acrosome-reacted spermatozoa was characterized by the oscillatory synchronous sliding between most pairs of doublets. These results demonstrated that the metachronal and synchronous sliding are involved in generation and modulation of sperm flagellar motility; however, two types of synchronous sliding, non-oscillatory and oscillatory sliding, modulate the sperm flagellar motility by enhancing the sliding of a specific pair of the doublets or the sliding between most pairs of the doublets. LARGE SCALE DATA None. LIMITATIONS, REASONS FOR CAUTION This is an indirect study of the metachronal and synchronous sliding of doublet microtubules. Studies based on the direct observation of behavior of dynein are needed to clarify the sliding microtubule theory of flagellar movement of spermatozoa. WIDER IMPLICATIONS OF THE FINDINGS Both the metachronal and oscillatory synchronous sliding of doublet microtubule generate and modulate sperm flagellar motility, while the change in mode of synchronous sliding between the non-oscillatory synchronous sliding and oscillatory synchronous sliding modulates the sperm flagellar motility. The coordination between these sliding leads to various types of flagellar and ciliary motility, including the asymmetrical beating in flagellar and ciliary movement and planar or helical beating in sea urchin spermatozoa. Moreover, the finding that the metachronal sliding and two types of synchronous sliding generate and modulate the flagellar motility will open a new avenue for quantitative analysis of flagellar and ciliary motility. STUDY FUNDING AND COMPETING INTEREST(S) The authors have no conflict of interest and no funding to declare.