Hofmeister effect underlying the quiescence of sperm motility in the vas deferens of the viviparous guppy Poecilia reticulata

Guppy sperm are immotile in the fluid (seminal plasma) of the vas deferens. We previously reported that the initiation of sperm motility is regulated by "Hofmeister solutes" in the isotonic medium. This indicates that chaotropes in solution activate the guppy sperm, whereas counteracting kosmotropes negate this activational effect and keep the sperm immotile. Here we show that seminal plasma has a strong inhibitory effect on sperm activation in response to chaotropes and multivalent ions, and that this inhibitory effect is due to kosmotropicity of the seminal plasma. These findings suggest a novel system of regulation of sperm motility in the guppy, a viviparious fish, in which the sperm are kept immotile in the vas deferens by a physicochemical effect (the Hofmeister effect) of the seminal plasma.     

DNA G-quadruplexes are uniquely stable in the presence of denaturants and monovalent cations

Ions in the Hofmeister series exhibit varied effects on biopolymers. Those classed as kosmotropes generally stabilize secondary structure, and those classed as chaotropes generally destabilize secondary structure. Here, we report that several anionic chaotropes exhibit unique effects on one DNA secondary structure - a G quadruplex. These chaotropes exhibit the expected behaviour (destabilization of secondary structure) in two other structural contexts: a DNA duplex and i-Motifs. Uniquely among secondary structures, we observe that G quadruplexes are comparatively insensitive to the presence of anionic chaotropes, but not other denaturants. Further, the presence of equimolar NaCl provided greater mitigation of the destabilization caused by other non-anionic denaturants. These results are consistent with the presence of monovalent cations providing an especially pronounced stabilizing effect to G quadruplexes when studied in denaturing solution conditions.     

Sperm motility in fishes. (II) Effects of ions and osmolality: a review

The spermatozoa of most fish species are immotile in the testis and seminal plasma. Therefore, motility is induced after the spermatozoa are released into the aqueous environment during natural reproduction or into the diluent during artificial reproduction. There are clear relationships between seminal plasma composition and osmolality and the duration of fish sperm motility. Various parameters such as ion concentrations (K+, Na+, and Ca2+), osmotic pressure, pH, temperature and dilution rate affect motility. In the present paper, we review the roles of these ions on sperm motility in Salmonidae, Cyprinidae, Acipenseridae and marine fishes, and their relationship with seminal plasma composition. Results in the literature show that: 1. K+ is a key ion controlling sperm motility in Salmonidae and Acipenseridae in combination with osmotic pressure; this control is more simple in other fish species: sperm motility is prevented when the osmotic pressure is high (Cyprinidae) or low (marine fishes) compared to that of the seminal fluid. 2. Cations (mostly divalent, such as Ca2+) are antagonistic with the inhibitory effect of K+ on sperm motility. 3. In many species, Ca2+ influx and K+ or Na+ efflux through specific ionic channels change the membrane potential and eventually lead to an increase in cAMP concentration in the cell, which constitutes the initiation signal for sperm motility in Salmonidae. 4. Media that are hyper- and hypo-osmotic relative to seminal fluid trigger sperm motility in marine and freshwater fishes, respectively. 5. The motility of fish spermatozoa is controlled through their sensitivity to osmolality and ion concentrations. This phenomenon is related to ionic channel activities in the membrane and governs the motility mechanisms of axonemes.     

The systematic characterization by aqueous column chromatography of solutes which affect protein stability

We have systematically characterized, by aqueous column chromatography on a size exclusion cross-linked dextran gel (Sephadex G-10), 12 solutes, 11 of which are known to affect protein stability. Six are chaotropes (water structure breakers) and destabilize proteins, while five are polar kosmotropes (polar water structure makers) and stabilize proteins. Analysis of the chromatographic behavior of these neutral (ethylene glycol, urea), positively charged (Tris, guanidine, as the hydrochloride salts) and negatively charged (SO2-4, HPO2-4, F-, Cl-, Br-, Cl3CCO-2, I-, SCN-, as the sodium salts, in order of elution) solutes at pH 7 as a function of sample concentration (up to 0.6 M), supporting electrolyte, and temperature yields four conclusions, based largely on the behavior of the anions. Chaotropes adsorb to the gel according to their position in the Hofmeister series, with the most chaotropic species adsorbing most strongly. ++Chaotropes adsorb to the gel less strongly in the presence of chaotropes (a salting in effect) and more strongly in the presence of polar kosmotropes (a salting out effect). Polar kosmotropes do not adsorb to the gel, and are sieved through the gel according to their position in the Hofmeister series, with the most kosmotropic species having the largest relative hydrodynamic radii. The hydrodynamic radii of polar kosmotropes is increased by chaotropes and decreased by polar kosmotropes. These results suggest that a chaotrope interacts with the first layer of immediately adjacent water molecules somewhat less strongly than would bulk water in its place; a polar kosmotrope, more strongly.     

Effects of different surfactants on motility and DNA integrity of brown trout (Salmo trutta fario) and common carp (Cyprinus carpio) spermatozoa

In this study we evaluated effects of surfactants on motility parameters and DNA integrity of spermatozoa of freshwater teleost fish. Common carp (Cyprinus carpio) and brown trout (Salmo trutta fario) spermatozoa were exposed to either sodium dodecyl sulphate (SDS, anionic surfactant) or octoxynol 9 ( Triton X-100, nonionic surfactant). Both surfactants added at activation caused a decrease in sperm motility characteristics measured by computer-assisted sperm analysis (CASA). Intraspecific differences in speed and trajectory of movement were detected. Triton X-100 and SDS when added to non activated sperm were also effective in the decrease of sperm motility and caused an increase of DNA fragmentation. Our results suggest that not only sperm motility apparatus but also DNA are targets for surfactant action. Therefore any exposure of spermatozoa to surfactants, in aquaculture conditions or natural environment, would have a negative impact on fish reproduction.     

Transmembrane adenylyl cyclase regulates amphibian sperm motility through protein kinase A activation

Sperm motility is essential for achieving fertilization. In animals with external fertilization as amphibians, spermatozoa are stored in a quiescent state in the testis. Spermiation to hypotonic fertilization media triggers activation of sperm motility. Bufo arenarum sperm are immotile in artificial seminal plasma (ASP) but acquire in situ flagellar beating upon dilution. In addition to the effect of low osmolarity on sperm motility activation, we report that diffusible factors of the egg jelly coat (EW) regulate motility patterns, switching from in situ to progressive movement. The signal transduction pathway involved in amphibian sperm motility activation is mostly unknown. In the present study, we show a correlation between motility activation triggered by low osmotic pressure and activation of protein kinase A (PKA). Moreover, this is the first study to present strong evidences that point toward a role of a transmembrane adenyl-cyclase (tmAC) in the regulation of amphibian sperm motility through PKA activation.     

Sperm motility in the horseshoe crab,Limulus polyphemus L: II. Partial characterization of a motility initiating factor from eggs and the effects of inorganic cations on motility initiation

Egg extracts (obtained by washing intact Limulus eggs with either distilled water or artificial seawater, ASW) contain a sperm motility initiating factor (SMI). The SMI is heat stable (withstands boiling to dryness), passes through a dialysis membrane, and is retained by G-10 Sephadex (indicating a molecular weight of less than 700). Qualitative analysis (by X-ray fluorescence spectroscopy) and quantitative analysis (by atomic absorption spectroscopy) of SMI extracts revealed the presence of four divalent cations (Ca, Mg, Ni, and Cu) and one monovalent cation (K) that affect sperm motility. When assayed individually at high concentrations, all of the divalent cations initiate sperm motility and K⁺ inhibits motility initiation by the divalent cations. However, none of the divalent cations are present at concentrations high enough to produce the observed SMI activity, and since K⁺ is present when motility is initiated by SMI, K⁺ must not normally be an inhibitor. Therefore, if inorganic cations are involved in normal sperm motility initiation in Limulus, they are acting in conjunction with some other low molecular weight factor.     

Gadolinium,a mechano-sensitive channel blocker,inhibits osmosis-initiated motility of sea- and freshwater fish sperm,but does not affect human or ascidian sperm motility

Exposure to hypo-osmotic or hyperosmotic environment triggers the initiation of fish sperm motility. In this article, we report that calcium and potassium channel blockers do not influence motility of puffer fish sperm but calmodulin antagonists reversibly decrease it, suggesting that calmodulin-Ca(2+) interactions are prerequisite for the initiation of sperm motility in this species. Gadolinium (a stretch activated ion channel blocker) decreased the motility of puffer fish sperm from 92 +/- 3% to 6 +/- 3% and that of carp sperm from 91 +/- 7% to 3.5 +/- 4.3% in a dose-dependent manner (10-40 micro M). The effect of gadolinium was reversible, suggesting that stretch activated ion channels participate in the initiation of sperm motility of the two species. Gadolinium inhibits changes in the isoelectric point of certain proteins of puffer fish sperm, which occur when sperm motility is initiated in a hypertonic solution. Anisotropy measurements showed that hypo-osmotic treatment, which initiates carp sperm motility, increased membrane fluidity. When hypo-osmotic treatment was given in the presence of gadolinium, the sperm membrane remained as rigid as in quiescent cells, while motility was blocked. By contrast, gadolinium did not influence the motility parameters of Ciona or human sperm. Based on these lines of evidence, we suggest that conformational changes of mechanosensitive membrane proteins are involved in osmolality-dependent but not osmolality-independent sperm.     

Modulation of polyene antibiotics self-association by ions from the Hofmeister series

The toxicity of the antifungal polyene antibiotic amphotericin B (AMB) has been related to its low solubility, more specifically to a self-associated form termed toxic aggregate. In addition, AMB in aqueous medium gives rise to concentration, ionic strength, and time-dependent polydisperse systems. For this reason different approaches, including the use of several lipid aggregates, have been used in attempts to improve the drug's solubility and increase its therapeutic index. In this context, understanding AMB's self-association properties should help in the preparation of less toxic formulations. Ions from the Hofmeister series alter water properties: while kosmotropes (water structure makers-sulfate, citrate, phosphate) decrease solute solubility, chaotropes (water structure breakers-perchlorate, thiocyanate, trichloroacetate, and the neutral molecule urea) have opposite effects. This work reports a study of the effect of Hofmeister ions and urea on the self-aggregation of AMB and some of its derivatives. Optical absorption and circular dichroism spectra were used to monitor monomeric and aggregated antibiotic. While kosmotropes increased aggregation in a concentration-dependent manner, the opposite was observed for chaotropes. It is shown, for the first time, that thiocyanate and trichloroacetate can induce complete AMB monomerization. The understanding of these processes at the physicochemical and molecular levels and the possibility of modulating the aggregation state of AMB and its derivatives should contribute to elucidate the mechanisms of action and toxicity of this widely used antibiotic and to develop more efficient and less toxic preparations.     

Metabolism of motile zebrafish sperm

As metabolism of motile fish sperm is not well understood, the current study examined the metabolism of saline-activated zebrafish (Danio rerio) sperm. Activation of sperm with inhibitors of oxidative phosphorylation (potassium cyanide, 2,4 dinitrophenol or carbonyl cyanide 3-cholorophenylhydrazone) negatively impacted sperm motility by 60-90 s postactivation. Incubation of quiescent sperm with 2,4 dinitrophenol prior to activation resulted in a 67% decrease in the percent motile sperm assessed 15s postactivation. Thus, production of ATP in quiescent sperm is important for motility upon activation and nascent ATP production via oxidative phosphorylation by motile sperm appears important at 60-90 s postactivation. Exposure of sperm to iodoacetamide, an inhibitor of creatine kinase, at activation was without effect. However, incubation of quiescent sperm with iodoacetamide prior to activation resulted in a 77% reduction in percent motile sperm and decreased velocity and wobble at 15s postactivation. These results suggest that creatine kinase and phosphocreatine shuttle are physiologically important at, or shortly after the initiation of motility. Finally, sperm were exposed to lactate, pyruvate, or acetate as well as to several monosaccharides upon activation. The results provided no evidence supporting any metabolic role of exogenous organics (potentially from the female via ovarian fluid) in sperm once motility has begun.     

Carp transferrin can protect spermatozoa against toxic effects of cadmium ions

Cadmium is a widespread heavy metal that enters the aquatic environment and affects many processes involved in fish reproduction such as sperm motility. Fish seminal plasma proteins can protect spermatozoa against toxic effects of heavy metals. The objective of this study was to demonstrate the ability of a major carp seminal plasma protein-transferrin (TF) to bind cadmium ions and to neutralize the toxic effect of cadmium on carp sperm motility. To obtain a high quantity of carp seminal plasma TF necessary for the experiment, immunoaffinity chromatography as a one-step isolation procedure was established. The titration of TF with cadmium ions spectrophotometrically at 247nm revealed that TF binds cadmium ions at only one spectrophotometrically-sensitive binding site, which suggests that TF is capable of neutralizing the cadmium toxic effect. Indeed, the addition of carp TF to carp semen incubated with 50ppm cadmium for 48h led to about a four-times higher percentage of sperm motility (30.3±1.1%) in comparison to samples incubated with only 50ppm cadmium (8.2±5.2%). Similarly, higher values of other parameters of sperm movement measured by a computer-assisted sperm motility analysis system (VSL, VCL and ALH) were observed at the presence of transferrin. In conclusion, our study provides the first evidence that transferrin from carp seminal plasma can protect sperm motility from cadmium toxicity.     

The role of hormones in the acquisition of sperm motility in salmonid fish.

In salmonid fish, spermatozoa taken from the testes are immotile, but acquire motility during their passage through the sperm duct. Using male masu salmon (Oncorhynchus masou), we found that gonadotropin-induced testicular production of 17 alpha, 20 beta-dihydroxy-4-pregnen-3-one (17 alpha, 20 beta-DP), the oocyte maturation-inducing hormone of salmonid fish, is responsible for the acquisition of sperm motility. However, neither testosterone (T) nor 11-ketotestosterone (11-KT), the two major androgens in teleost fish, were effective. We also present evidence that 17 alpha, 20 beta-DP action is mediated through an increase in sperm duct pH, which in turn increases the cAMP content of sperm allowing the acquisition of motility.     

Influence of osmolality and ions on the activation and characteristics of zebrafish sperm motility

Despite the prevalence of zebrafish as a model scientific organism, understanding sperm function in this species is essentially limited to observations that osmotic shock initiates motility. During natural spawning, sperm encounter a range of environmental salinities as well as freshwater mixed with egg-associated ovarian fluid (OF), thus sperm are likely to be exposed to saline prior to egg contact. Effects of saline on sperm function in this model species are unknown, but likely to be important. Using computer assisted sperm analysis, this study addressed the effects of osmolality of spawning media and ionic composition and pH on the proportion of sperm becoming motile at activation (motility), as well as sperm velocity and path. When activated with tap water, motility was maximal (80%) at 10 s (earliest time measured), declining to 5% by 87 s postactivation. With activation at moderate osmolalities (∼160-200 mmol/kg) initial motility was decreased relative to low osmolality, increased from 10 to 30 s, and subsequently declined less rapidly (motility in 80 mM NaCl was 35%, 80%, and 60% at 10, 30 and 147 s, respectively). Thus, moderate osmolality increased duration, but introduced a temporal lag in motility onset. With moderate osmolalities, the rate of velocity decay was less than that with tap water activation. Sodium chloride and sucrose similarly impacted both motility and velocity. Replacement of NaCl with KCl, pH values ranging from 6.8 to 8.4, or the presence of gadolinium were without effect. Motility, but not velocity, was slightly supressed by Ca²⁺. Therefore, whereas pH and concentrations of Ca²⁺ or K⁺ of OF are unlikely to impact fertility via sperm motility, the OF contribution to spawning media osmolality may have pronounced effects on motility and velocity of sperm, factors previously correlated with fertility in other species.     

Trout sperm motility. The transient movement of trout sperm is related to changes in the concentration of ATP following the activation of the flagellar movement

For freshwater fish the motile period of sperm is extremely brief, even after a dilution in isotonic media. This result is in contrast to most other animals (ranging from invertebrates to mammals), in which sperm are generally motile for at least several hours. We have analyzed the reasons for the brevity of this movement by studying the relationships between the metabolism of trout sperm and the activation of their motility upon dilution. Sperm motility was not initiated when the dilution medium contained an elevated concentration of potassium (20-40 mM), but dilution in an isotonic solution of sodium chloride triggered an immediate activation of motility, and sperm swam vigorously. Motility of sperm decreased rapidly and 15 s after dilution sperm were moving slowly in small circles. Sperm became abruptly immotile at 20-30 s and flagella straightened. When millimolar concentrations of Ca2+ were also present in the dilution medium, movement did not stop abruptly, flagella kept beating and stopped only after 1-2 min. When sperm remained immotile they retained a high concentration of ATP. The activation of motility induced a rapid decrease of ATP. In the absence of calcium, and after the cessation of motility, ATP increased slowly back to its original concentration. In the presence of millimolar concentrations of calcium the concentration of ATP decreased to a very low level and remained low thereafter. The progressive decrease of the flagellar beat frequency, that had been observed during the period of trout sperm movement, might be related to the rapid exhaustion of intraflagellar ATP. Motility could be reinduced in sperm that had recovered high concentrations of ATP, demonstrating the functional integrity of the motile apparatus even after flagellar arrest. In conclusion we suggest that the maximum duration of trout sperm motility, at most 2 min (as a consequence of a depletion of ATP during the movement), is due to a low mitochondrial oxidative phosphorylation capacity.     

Sperm motility initiation and duration in a euryhaline fish, medaka (Oryzias latipes)

The medaka, Oryzias latipes, is a well-recognized fish model for biomedical research. An understanding of gamete characteristics is necessary for experimental manipulations such as artificial fertilization and sperm cryopreservation. The goal of this study was to investigate sperm characteristics of motility initiation, duration, and retention in medaka. First, motility was initiated by osmolality values ranging from 25 to 686 mOsm/kg, which included deionized water and hypotonic, isotonic, and hypertonic Hanks’ balanced salt solution. The percentage of motile sperm was >80% when osmolality was <315 mOsm/kg and decreased as osmolality increased. This is different from most fish with external fertilization in which sperm motility can be initiated by hypotonic (for freshwater fish) or hypertonic (for marine fish) solutions or by altering the concentration of specific ions such as potassium (e.g., in salmonids). Second, upon activation, the sperm remained continuously motile, with reserve capacity, for as long as 1 wk during storage at 4 °C. This was also different from other externally fertilizing fish, in which motility is typically maintained for seconds to several minutes. Third, after changing the osmolality to 46 to 68 mOsm/kg by adding deionized water, the motility of sperm held at 274 to 500 mOsm/kg was higher than the original motility (P ≤ 0.035) after 24, 48, and 72 h of storage at 4 °C. Fourth, the addition of glucose had no effect on maintaining sperm motility during refrigerated storage. To our knowledge, this combination of sperm motility characteristics is reported for the first time in fish and may be unique to medaka or may represent an undescribed modality of sperm behavior within euryhaline fish.     

Ion-specific Effects on Prion Nucleation and Strain Formation

Ordered, fibrous, self-seeding aggregates of misfolded proteins known as amyloids are associated with important diseases in mammals and control phenotypic traits in fungi. A given protein may adopt multiple amyloid conformations, known as variants or strains, each of which leads to a distinct disease pattern or phenotype. Here, we study the effect of Hofmeister ions on amyloid nucleation and strain generation by the prion domain-containing fragment (Sup35NM) of a yeast protein Sup35p. Strongly hydrated anions (kosmotropes) initiate nucleation quickly and cause rapid fiber elongation, whereas poorly hydrated anions (chaotropes) delay nucleation and mildly affect the elongation rate. For the first time, we demonstrate that kosmotropes favor formation of amyloid strains that are characterized by lower thermostability and higher frangibility in vitro and stronger phenotypic and proliferation patterns effectively in vivo as compared with amyloids formed in chaotropes. These phenomena point to inherent differences in the biochemistry of Hofmeister ions. Our work shows that the ionic composition of a solution not only influences the kinetics of amyloid nucleation but also determines the amyloid strain that is preferentially formed.     

Semen of Perca fluviatilis L.: sperm volume and density, seminal plasma indices and effects of dilution ratio, ions and osmolality on sperm motility

The objectives of the present study were to characterize sperm volume and density, seminal plasma indices (ionic contents and osmolality) and to study the effects of dilution ratio, ions and osmolality on sperm motility parameters (percentage of motile sperm and sperm velocity) in farmed European perch (Perca fluviatilis L.). The means of sperm volume (ml), sperm density (x10(9)spermml(-1)) and total number of sperm (volumexdensity) per fish were 2.75+/-0.51, 29.19+/-3.15 and 82.19+/-15.26. The seminal plasma osmolality (mOsmkg(-1)), sodium, chloride, potassium and calcium ions concentrations (mM) were measured to be 298.07+/-5.09, 130.97+/-2.19, 106.75+/-2.37, 10.70+/-0.61 and 2.41+/-0.09, respectively. At 15s post-activation of stripped sperm, the percentage of motile sperm (%) and sperm velocity (mums(-1)) were 91.90+/-1.27 and 115.54+/-1.25, respectively, and decreased significantly following sperm activation (P<0.05). The optimal sperm motility was observed when the sperm was prediluted in immobilizing solution (IS) at a ratio 1:50. Prediluted sperm showed the maximum velocity when activated in 2.5mM Ca(2+), 50mM K(+) and sucrose with osmolality 100mOsmkg(-1). Neither Ca(2+) nor K(+) showed a significant effect on the percentage of motile sperm at 15s post-activation. Osmolality higher than 200mOsmkg(-1) significantly decreased the percentage of motile sperm, while osmolality of 300mOsmkg(-1) or above totally suppressed sperm motility.     

Chilled storage of Asian seabass,Lates calcarifer Bloch semen: Effects of ions,extenders and storage periods on sperm quality and fertilization ability

The development of a chilled storage protocol of fish sperm requires an understanding of sperm biology and function as the activation/inhibition of fish sperm is greatly affected by several environmental factors. This study aimed to determine the effects of ionic and non-ionic solutions, extender types (Ringer's solution, Ca-F HBSS solution, HBSS solution, He and Wood solution, Saline solution, and Modified Cortland solution), and chilled-storage period on sperm quality and fertilization ability of Asian seabass, Lates calcarifer semen. Regulation of Asian seabass sperm motility was dependent on the osmolality of both ionic and non-ionic activation media. The threshold levels on the initiation of sperm motility were detected in KCl (>100 mM), NaCl (>50 mM), CaCl₂ (>50 mM), glucose (>300 mM), and mannitol (>100 mM) solutions. Relatively high percentages of sperm motility (>80%) were observed when activated with KCl, NaCl, CaCl₂, glucose, and mannitol solutions at above 700, 600, 350, 1,000, and 1,000 mM, respectively. Ringer's solution was the most optimal extender for chilled storage of Asian seabass semen at 2–4°C supported by the retention of sperm motility and viability for 6 days. Semen diluted in Ringer's solution and chilled-stored for 2 days exhibited acceptable fertilization (66.1% ± 6.2%) and hatching (56.4% ± 2.9%) rates. This report, for the first time, describes the ionicity and non-ionicity effects on the motility of Asian seabass sperm.     

Roles of osmolality, calcium - Potassium antagonist and calcium in activation and flagellar beating pattern of sturgeon sperm

The present study shows the roles of osmolality, calcium (Ca(2+))-potassium (K(+)) antagonist and Ca(2+) in sperm activation and flagellar beating of a sturgeon species, sterlet (Acipenser ruthenus). Sperm motility was activated at hypoosmolality relative to seminal plasma and suppressed at 175 mOsmol kg(-1). Sperm activation was totally suppressed by 0.35mM K(+), but Ca(2+) could fully reverse K(+) inhibitory effect at Ca(2+): K(+) ratio of 0.25. Neither EGTA (a chelator of Ca(2+) ions) nor nifedipine (a Ca(2+) channel blocker) prevented sperm activation. But, sperm motility and velocity were significantly decreased by EGTA, nifedipine and an inhibitor for Ca(2+)/calmodulin activated phosphodiesterase (w-7) that suggest role of Ca(2+) signaling after triggering sperm activation through hypoosmolality. Symmetric flagellar beating was also turned to asymmetric after activation in w-7, which is an evidence for modulation of Ca(2+)-binding proteins activity. Sturgeon sperm, similar to salmonids, is immotile in seminal plasma due to high K(+) concentrations, but the mechanism of sperm activation seems to be closer to other fish species where osmolality prohibits sperm activation in seminal plasma. In these species, hypoosmolality is the primary signal for sperm Ca(2+)-dependent signaling of axonemal beating.