Ultrastructural Changes of the "Truncated Cone" during the Acrosome Reaction in Japanese Abalone Spermatozoa

An electron-dense structure termed the "truncated cone" covers the apical surface of the acrosomal contents except for the trigger region in Haliotis discus spermatozoa. The truncated cone, having a slant height of 0.3 μm and diameters of circular top and base of 0.3 and 0.6 μm, shows striations with a periodicity of 6.6 to 8.0 nm. During the acrosome reaction, the truncated cone elongates simultaneously with the protrusion of the acrosomal process through the truncated cone. As the growth of the acrosomal process further proceeds, the truncated cone transforms into a cylindrical shape and eventually reaches 1 μm in length and 0.2 μm in diameter. The elongated truncated cone is characterized by regularlly helical striations with a periodicity of 19 to 21 nm with an inclination of 40° to 46°. These results may suggest that the truncated cone is composed of coiled filaments, which coil up further during the acrosome reaction causing the truncated cone to slenderize and elongate. The elongation is also achieved by stretching of the coil. In H. discus hannai Ino, structural changes in the truncated cone show close homology to those in H. discus. No such morphologically unique organelle has been found in other species thus far.     

Fine Structural Changes in the Acrosome Reaction of the Japanese Abalone, Haliotis disus

The spermatozoon of the Japanese abalone, Haliotis discus , and its structural changes during the acrosome reaction were observed by electron microscopy. The spermatozoon has a huge acrosome in the shape of a hanging bell or a forefinger with a deep fossa at the posterior end being filled with a bundle of microfilaments. The membranes of the acrosomal apex, the so-called trigger region, are structurally discernible from those of other acrosomal regions. Following the trigger region, a unique structure under the acrosomal membrane covers the surface of the acrosomal content in the form of a truncated cone.
The acrosome reaction occurs in the jelly layer very close to the egg envelope. First, the membranes at the apex of the acrosome are vesiculated, followed by the formation of a narrow gap between the outer acrosomal membrane and the acrosomal content. Next, the bundle of micro-filaments elongates, running through the center of the acrosome, reaching the trigger region and protruding out of the acrosomal top. Then release of the acrosomal content occurs in two steps, disclosing the "membrane undercoating structure" that comprises globular particles with a fuzzy material connecting them. This resembles the undercoat network found in erythrocytes.     

Phospholipase A of Guinea Pig Spermatozoa: Its Preliminary Characterization and Possible Involvement in the Acrosome Reaction

Phospholipase A activity was demonstrated in guinea pig spermatozoa using [U-¹⁴C] phosphatidyl choline as a substrate. The activity had a neutral pH optimum, was stimulated by Ca²⁺ and low concentrations of detergent, and. was inhibited by EDTA, mepacrine and p-bromophenacyl bromide. Appropriate concentrations of mepacrine and p-bromophenacyl bromide inhibited the acrosome reactions of capacitated spermatozoa without interfering with their motility. These results support the notion that phospholipase A is involved in the acrosome reaction of mammalian spermatozoa.     

Induction of the Acrosome Reaction of Sea Urchin Spermatozoa by Means of Urea

Urea is an effective reagent for inducing the acrosome reaction of spermatozoa in sea urchins. Urea-treated spermatozoa are capable of fertilizing eggs in Ca-deficient sea water. The pH of the urea solution is an important factor affecting the induction of the acrosome reaction. The reaction occurs at a high percentage in urea Solution at pH's higher than 7.8, while the reaction is almost completely suppressed at pH 7.2. Ca⁺⁺ is also an important factor for the induction of the reaction, although the minimum concentration required is very low.
The acrosomal filament formed in urea solution is similar in shape to that formed in egg-water, when fixed after 10 seconds' urea-treatment. The acrosome granule material is found around the basal portion of the acrosomal filament.     

Effects of Cations and Other Medium Components on the Zona-induced Acrosome Reaction of Hamster Spermatozoa

Although the acrosome reaction in lively motile hamster spermatozoa can occur independently of the egg or its investments ("spontaneous" acrosome reaction), it appears to be the egg investments, particularly the zona pellucida, that induces the acrosome reaction in fertilizing spermatozoa of many mammalian species. The latter is referred to as "zona-induced" acrosome reaction. Experiments were conducted to determine if the zona-induced acrosome reaction has different ion requirements from the spontaneous reaction. Like the spontaneous acrosome reaction, the zona-induced acrosome reaction required extracellular Na⁺, K⁺ and Ca²⁺. The absence of Cl⁻ and albumin in the medium inhibited the reaction. The zona-induced acrosome reaction could occur in a HCO₃⁻-free medium, but far less efficiently than in medium containing this ion. Proteinase inhibitors, benzamidine and TLCK, inhibited the zona-induced acrosome reaction. These results suggest that the chemical reactions involved in the spontaneous and zona-induced acrosome reactions are similar although the reaction-triggering mechanism is probably different.     

Maitotoxin, A Presumed Calcium Channel Activator, Induces the Acrosome Reaction in Mussel Spermatozoa

Maitotoxin, a presumed activator of the voltage-sensitive calcium channel, induced the acrosome reaction in the mussel, Mytilus edulis at physiological pH and in the starfish, Asterias amurensis at pH 9.5. The induction of acrosome reaction by maitotoxin depended upon external Ca²⁺ and was inhibited by two types of calcium channel blockers; verapamil and diltiazem. These results suggest that the activation of the voltage-sensitive calcium channel takes an important part in the initiation of acrosome reaction in Mytilus and other animals.     

Changes of Con A Receptor Sites on Mammalian Sperms during Capacitation and Acrosome Reaction

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Intracellular pH Changes of Starfish Sperm Upon the Acrosome Reaction

The acrosome reaction is accompanied by ionic changes such as increases in intracellular Ca²⁺ and intracellular pH (pH_i). Since the two jelly components essential for inducing the acrosome reaction, ARIS and Co-ARIS, were shown to activate Ca-channels (accompanying paper), we examined the jelly components to determine which was responsible for the pH_i-increase using 9-aminoacridine as a probe of pH_i. This paper presents evidence that an oligopeptide(s) is responsible for the pH_i-increase. The pH_i of swimming sperm is 7.4-7.5. Within 20 sec after the addition of jelly, their pH_i increased rapidly by 0.06 pH unit, then decreased by 0.2–0.3 pH unit, and reached a plateau level within 3 min. Similar changes in pH_i were observed on addition of a Pronase digest of ARIS (P-ARIS) and a diffusible fraction of jelly (Fraction M₈) together. Fraction M₈, but not ARIS or Co-ARIS increased the pH_i, and activated sperm respiration in sea water at pH 6.5. The two activities of Fraction M₈ depended upon Na⁺ but not Ca²⁺, and were susceptible to Pronase digestion. Fraction M₈ is also known to enhance induction of the acrosome reaction by the Ca-ionophore A23187. These results suggest that the egg jelly contains a peptide(s) that is not obligatory for the acrosome reaction but facilitates the reaction by increasing the pH_i of the sperm. The significance of the pH_i-increase upon the acrosome reaction is discussed.     

中国对虾精子顶体反应的超微结构和蛋白成分变化的研究

用卵水 (eggwater)对中国对虾纳精囊内精子进行人工诱导顶体反应 ,并分别用透射电镜和SDS—PAGE及复性单向电泳对顶体反应的超微结构变化和蛋白成分的变化进行了研究。结果表明 ,中国对虾精子在人工诱导条件下 3 0min内有 5 0 %以上完成反应。电镜观察证明 ,中国对虾精子的顶体反应可分为两个阶段 :(1 )棘突的收缩 ;(2 )顶体颗粒的释放和顶体帽的消失。在反应过程中许多蛋白被降解 ,且反应开始后精子本身释放出一些水解酶类 ,主要有 2 0 0kDa、1 3 0kDa、66kDa、5 3kDa、48kDa和 41kDa 6种。在对卵水成分的初步分析中发现两种分子量约 2 0 0kDa的蛋白。     

A Simple Staining Procedure for Detecting the true Acrosome Reaction in Buffalo (Bubalus bubalis) Spermatozoa

A simple dual staining procedure for detecting the true acrosome reaction in dried smears of buffalo spermatozoa is described. Trypan blue is used first to differentiate live from dead spermatozoa and the dried smears which have been prepared are stained with Giemsa for acrosome evaluation. Four categories of spermatozoa were recognized: A) live, intact acrosome (acrosome pink, postnuclear cap clear); B) dead, intact acrosome (acrosome pink, postnuclear cap blue); C) live, detached acrosome (acrosome clear, postnuclear cap clear); and D) dead, detached acrosome (acrosome clear, postnuclear cap blue). The procedure is simple, rapid and convenient for assessing true acrosome reaction in buffalo spermatozoa. Simultaneous assessment of sperm viability and its acrosomal status in dried smears makes this procedure attractive because the true acrosome reaction can be studied thoroughly at a later state after the incubation period.     

A Naphthol Yellow S and Erythrosin B Staining Procedure for Use in Studies of the Acrosome Reaction of Rabbit Spermatozoa

Rabbit spermatozoa suspended in Krebs-Ringer-phosphate containing 0.25% glucose were smeared on polylysine-coated slides and dried in air at room temperature for 2 hr to overnight. Smears were stained in 0.1% naphthol yellow S in 1.0% acetic acid for 30 min at room temperature, blotted, rinsed in 1.0% aqueous acetic acid for 10-15 sec, drained and stained for 7 min in a mixture of equal parts of aqueous naphthol yellow S and erythrosin B (final concentration of each dye 0.1% w/v) at pH 4.6-5.0 (pH adjusted with acetic acid). Stained slides were well rinsed in distilled water adjusted to pH 4.65.0 with acetic acid, blotted, allowed to dry completely, rinsed in xylene and mounted in synthetic resin. Acrosomal caps were stained cherry-red (apical ridge) to pink (dorsal and ventral aspects); postnuclear caps stained pale pink; nuclei were either unstained or stained a very faint yellowish-pink. The mid-piece and flagellum were stained different shades of pink. The procedure is simple, rapid, and gives highly reproducible results. When present, acrosomes are easily detected regardless of the density of the smear.     

Induction of the Acrosome Reaction in Starfish

In the starfish, Asterias amurensis , at least two distinct components of the egg jelly are required for inducing the acrosome reaction: a sulfated glycoprotein named acrosome reaction-inducing substance (ARIS) and a diffusible organic substance(s) named Co-ARIS. The following evidence suggested that ARIS and Co-ARIS cooperatively activate CA-channels of the sperm plasma membrane and eventually induce dramatic changes in sperm morphology, the acrosome reaction. 1) Pronase digest of ARIS (P-ARIS) and Co-ARIS, either as a pure or a crude preparation (Fraction M₈), were fully effective in combination for induction of the acrosome reaction in normal sea water, although they were not effective individually. P- ARIS alone induced the acrosome reaction fully in high Ca²⁺ sea water and markedly at high pHs, whereas Fraction M₈ alone did not induce the reaction even in these conditions. The reaction was not induced by increase in either the Ca²⁺ concentration or the pH of sea water, but was markedly induced in the absence of jelly components by raising both the pH and Ca²⁺ concentration together. 2) The ionophore A23187 induced the acrosome reaction appreciably when present alone and fully in the presence of monensin or Fraction M₈. Monesin alone was ineffective. 3) The jelly or a combination of ARIS and Fraction M₈ caused abrupt Ca²⁺ -uptake by the sperm. The Ca-channel blockers verapamil and diltiazem inhibited the jelly-induced acrosome reaction.     

Induction of the Acrosome Reaction of Hemicentrotus pulcherrimus Spermatozoa by the Egg Jelly Molecules, Fucose-Rich Glycoconjugate and Spem-Activating Peptide I

A fucose-rich glycoconjugate (FRG) was isolated from egg jelly of the sea urchin Hemicentrotus pulcherrimus by gel filtration. FRG induced the acrosome reaction in H. pulcherrimus spermatozoa in a concentration-dependent manner, although it showed about half the activity of the original unfractionated jelly. Synthetic sperm-activating peptide I (SAP-I: Gly-Phe-Asp-Leu-Asn-Gly-Gly-Gly-Val-Gly) increased the rate of the acrosome reaction induced by FRG; the maximal rate of the acrosome reaction with FRG and SAP-I being that of the unfractionated jelly. The half-maximal increase in induction of the acrosome reaction by SAP-I with FRG occurred at 4 × 10⁻¹⁰ M SAP-I, which was almost the same concentration inducing half-maximal stimulation of sperm respiration. Pronase digestion of FRG resulted in an 50% decrease in induction of the acrosome reaction and also in the elevation of cAMP in sperm. Some reagents (monensin and 3-isobutyl-1-methylxanthine) which increase intracellular pH, Ca²⁺ and cyclic nucleotides also increased the rates of the acrosome reaction induced by FRG or pronase-digested FRG. However, the rates did not reach those with FRG or pronase-digested FRG with SAP-I. These results indicate that SAP-I promotes induction of the acrosome reaction by acting as a specific co-factor of FRG.     

Viability and Acrosome Staining of Bull, Boar and Rabbit Spermatozoa

A practical and reliable staining procedure was developed to distinguish the viability and acrosomal status of bull, boar and rabbit spermatozoa. The first stain with trypan blue or Congo red is rapid and avoids artifacts. This stain is precipitated by neutral red during the 2 min required for fixation. The precipitate gives a high contrast black color, resistant to the subsequent rinsings and persists during the time required for staining the acrosome with Giemsa. Ten classes of spermatozoa are distinguished (live or dead with intact acrosomes, loose acrosomes, damaged acrosomes, no acrosome, or with no acrosome and no postacrosomal ring). The intact acrosomes are purple, the loose acrosomes are dark lavender and the damaged acrosomes are pale lavender. The anterior part of the head of live spermatozoa with no acrosome is white or light pink and the same area of dead spermatozoa is white or pale gray. The postacrosomal ring is red. The postacrosomal area of the head of live spermatozoa is white or light pink and the same part of dead spermatozoa is black, dark violet or gray. The procedure did not give satisfactory results for stallion spermatozoa.     

Biochemical Studies on the Acrosome Reaction of the Starfish, Asterias Amurensis I. Factors Participating in the Acrosome Reaction

In contrast with the case in sea urchin sperm, in starfish the acrosome reaction is not spontaneously induced by simply increasing the extracellular Ca²⁺ concentration or pH. At higher pHs, starfish sperm undergo morphological changes accompanied by exocytosis of the acrosomal vacuole, but they do not form acrosomal filaments. Nomarski-microscopic observation confirmed that spermatozoa undergo the acrosome reaction within the jelly coat. Acrosome reaction-inducing substance, a glycoprotein from the egg jelly, required a diffusible cofactor(s) present in the egg jelly for full activity. Several lines of evidence showed that this diffusible factor(s) is not merely Ca²⁺.