Characterization of the thrombospondin (TSP)-II gene in Penaeus monodon and a novel role of TSP-like proteins in an induction of shrimp sperm acrosome reaction

We have recently shown that water-soluble materials from the egg extracellular cortical rods (wsCRs) exert the ability to induce the sperm acrosome reaction in Penaeus monodon. In this study, we further demonstrated that the thrombospondin protein family (TSP) existed in wsCRs, and that their mRNA transcripts were detected in developing oocytes as early as stage I. Full sequence analysis revealed that our pmTSP sequence was considerably different from the recently reported pmTSP in the 5' nonconserved region and in many TSP signature domains, hence, the name pmTSP-II was given to our variant. The transcripts of pmTSP-II were detected only in early developing oocytes (stage-I and -II) while TSP-like proteins were detected in all developing oocytes, particularly at the outer rim of cortical rods situated in the extracellular crypts of the mature, stage-IV oocytes. In addition, wsCRs contained anti-TSP-reactive proteins, suggesting that TSP-like proteins are dissolved in and are part of the egg water during spawning. The functional importance of TSP-like proteins was evident by the interference of a wsCR-induced acrosome reaction response with anti-TSP in a concentration-dependent manner. In summary, we found that pmTSP-II transcripts were present in the developing oocytes and pmTSP-II protein accumulated in cortical rods, which are partly secreted and thus solubilized to produce dissolved TSP-like proteins that participate in induction of the sperm acrosome reaction-a novel reproductive role for TSP protein family.

Acrosome reaction of sperm in the mud crab Scylla serrata as a sensitive toxicity test for metal exposures

In order to test the sensitivity of the sperm cell of the mud crab Scylla serrata to heavy metals, the toxic effects of Ag+, Cd2+, Cu2+, and Zn2+ on the acrosome reaction (AR) were studied by artificially inducing the AR of sperm exposed to heavy metals, counting the AR rates by light microscopy, and observing structural changes in sperm by transmission electron microscopy. The AR in S. serrata occurs at two stages. The first stage (ARI) is the eversion of the subacrosomal material. The second stage (ARII) is the ejection of the acrosomal filament. The results showed the EC50 values of the AR based on (ARI + ARII)% for Ag+, Cd2+, Cu2+, and Zn2+ were 10.02, 2.14, 13.69, and 2.21 microg/L, and the EC50 values based on ARII % of Ag+, Cd2+, Cu2+, and Zn2+ were 1.96, 0.20, 1.46, and 0.34 microg/L. The order of toxicity is Cd2+ > Zn2+ > Cu2+ > Ag+ based on the percentage of reacted sperm at the second stage. Sperm cells exposed to heavy metals showed an increased rate of swelling, shape irregularities, and the acrosomal filament of some sperm cells was, crooked, ruptured, and even dissolved. The AR of the sperm cell from S. serrata is more sensitive to the tested heavy metals compared to sea urchin sperm cell toxicity tests.

Morphological and biochemical alterations of abalone testicular germ cells and spawned sperm and their fertilizing ability

In this study, we aimed to detect morphological and biochemical changes in developing germ cells (Gc), testicular sperm (Tsp), and spawned sperm (Ssp) using capacitation-associated characteristics. Gradual changes in the profiles of two membrane proteins, namely NaCl- and detergent-extractable proteins, were observed as compared Gc with Tsp and Tsp with Ssp. These membrane modifications were accomplished mostly through the introduction of new protein sets, both peripheral and integral, into Tsp and Ssp membranes. Activation of serine proteases, particularly in Ssp detergent-extracted proteins with the molecular masses of 38-130 kDa was evident and marked a major difference between Ssp and Tsp. An increase in the level of tyrosine phosphorylation of the proteins ranging from 15 to 20 kDa was noted in Tsp and remained constant in Ssp. Specifically, these three capacitation-associated characteristics could be detected in Ssp, possessing full fertilizing capacity. The lack of an activated proteolytic activity in Tsp resulted in a delayed fertilization, but not affected fertilizing ability. We believe that these characteristics should be advantageous in predicting abalone sperm fertilizing capability, particularly in cases when isolated germ cells or purified Tsp are used in place of spawned sperm in abalone aquaculture.

Egg coats of the rock shrimp Rhynchocinetes typus: ultrastructural characterization and their function during fertilization

The aim of the present work was to characterize structurally and ultrastructurally the egg coats of the rock shrimp, Rhynchocinetes typus, and to describe their functional roles during fertilization. Oocytes fixed directly from the ovary, have a total diameter of 549 microm and are covered by a 10- microm-thick transparent envelope. Electron microscope sections (dehydrated) of the egg envelope revealed an electron-dense external coat of 0.4 microm covered by filamentous processes, and a granular inner coat of 4- microm thickness. Oocytes placed for 5 min in seawater had a significantly larger diameter (573 microm), because of the increase in the thickness of the egg coats (32 microm) and the formation of a 16- microm perivitelline space. The diameter of the egg proper was reduced by the same extent as the size of the perivitelline space. All these changes were associated to the loss of the egg fertilizability. SDS-PAGE of isolated and solubilized egg coats with 20% beta-mercaptoethanol or 25 mM dithiothreitol (DTT) showed bands between 58 and 105 kDa and between 44 and 103 kDa, respectively. During normal fertilization, the sperm undergoes a drastic change in shape after first contact with the egg. We observed a similar change when solubilized egg coats were placed with vas deferens sperms. When the solubilized egg coat proteins were ultrafiltrated with a membrane of 10,000 MWCO (pore size) and then assayed for their effect on fertilization, an inhibitory effect of 30%, 41%, and 59% was found when oocytes were incubated with spermatozoa pre-treated with 30, 60, and 120 microg/ml of proteins solubilized with beta-mercaptoethanol. A similar inhibitory effect was found when egg coat proteins solubilized with 25 mM DTT were used. Our results suggest that, in the shrimp, the egg coats play an active role during the morphological changes of the sperm during their passage through them.

Trypsin-like enzymes during fertilization in the shrimp Rhynchocinetes typus

The spermatozoon of Rhynchocinetes typus is atypical because it is nonmotile and lacks head and tail. The body has a rigid spike. Neither an acrosome-like structure nor changes during gamete interaction which could be interpreted as an acrosome reaction have been observed in this species. Nevertheless, the spermatozoon exerts a lytic effect on the extracellular envelope of the egg, and in this way it penetrates through egg-coats, forming a channel. In this research we found that crude spermatozoa extracts analyzed by gelatin SDS-PAGE developed one band of protease activity that was completely inhibited by SBTI (soybean trypsin inhibitor) and pAB (p-aminobenzamidine). In sperm extracts an enzymatic activity was determined, using BAEE (N-benzoil-L-arginine ethyl ester), but not ATEE, as substrate. This activity was inhibited by SBTI and pAB. We observed that in vitro fertilization was inhibited by spermatozoon incubation with the trypsin inhibitors SBTI, PMSF (phenylmethanesulphonyl fluoride), and pAB. Additionally, we observed that when whole isolated egg-coats were incubated with sperm extract and then analyzed by SDS--PAGE, one band of the egg-coats disappeared. These results have been interpreted as sperm trypsinlike enzyme participation in R. typus sperm passage through the egg-coats.

Video microscopic analysis of ionophore induced acrosome reactions of lobster (Homarus americanus) sperm

Sperm from the American lobster (Homarus americanus) are normally nonmotile. However, during fertilization, the sperm undergo a calcium-dependent acrosome reaction that propels them forward about 18 microns. The reaction occurs in two phases, eversion and ejection, which take place too quickly to permit analysis by direct observation. The purposes of this study were to examine the structural changes occurring in sperm during the normal acrosome reaction and to determine the rate of the reaction using video microscopy. The reaction was induced in vitro by ionophore A23187 and recorded using a video system attached to a Nikon Nomarski interference microscope. Videotapes were played back frame by frame (30 frames/sec), and images of reactions from 10 sperm were analyzed. The acrosome reaction, including the eversion of the acrosomal vesicle and ejection of the subacrosomal material and nucleus, can be divided into 4 steps: (1) expansion of the apical cap followed by expansion of the remainder of the acrosomal cylinder; expansion of the cylinder begins at its apical end and proceeds toward its base, (2) eversion of the apical half of the acrosomal vesicle and initial contraction of the apical cap, (3) eversion of the basal half of the acrosomal vesicle, continued contraction of the apical cap, and ejection of the subacrosomal material and nucleus, and (4) final contraction of the apical cap and ejection of the acrosomal filament. During steps 2, 3, and 4, the mean forward movement of sperm is 12.7, 3.9, and 1.1 microns, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural changes in sperm from the fiddler crab, Uca tangeri (Crustacea, Brachyura), during the acrosome reaction

The acrosome reaction (AR) was induced in sperm from the brachyuran crustacean Uca tangeri either by mixing male and female gametes in filtered seawater or by treating the spermatozoa with the divalent cation ionophore A23187. This latter method provided a sufficient number of reacted spermatozoa to allow a detailed ultrastructural study of the AR. The process consists of two separate phases: a) initial release of the acrosomal vesicle contents, and b) further elongation of the acrosomal filament, which causes reversal of the rigid capsule limiting the acrosomal vesicle contents. The elongate acrosomal filament consists of an apical perforatorium and a basal columnar structure called here the proximal piece. The former derives from the perforatorium of the uninduced sperm stage with only small ultrastructural changes. The proximal piece forms from myelin-like membrane layers which are initially distributed all around the subacrosomal region and then accumulate in a column at the perforatorial base, thus promoting a sudden forward projection of the perforatorium. The AR in brachyurans is thought to be a passive mechanism that utilizes the negative pressure exerted on the nucleus--caused by emptying of the acrosomal vesicle--for an organized accumulation of membrane-rich material immediately behind the perforatorium, with the final result of the raising of a 3 microns long acrosomal filament.

Preloading of micromolar intracellular Ca2+ during capacitation of Sicyonia ingentis sperm, and the role of the pHi decrease during the acrosome reaction

In studying the mechanism controlling the sperm acrosome reaction (AR) in the marine shrimp Sicyonia ingentis, intracellular Ca2+ and pH were measured using the fluorescent indicators Fura-2 and Fluo-3 for Ca2+, and SNARF-1 for pH. Capacitated sperm possessed an apparent resting Ca2+ concentration of 1-2 microM which remained constant upon induction of the AR with egg water. Uncapacitated sperm had extremely low Ca2+ levels and did not respond to egg water. These results suggest that, while in other species the Ca2+ is elevated to micromolar levels during initiation of the AR, S. ingentis sperm are preloaded with Ca2+ during capacitation and the trigger for the AR is downstream of the Ca2+ increase. The notion that Ca2+ influx is not involved at the actual time of the AR in capacitated S. ingentis sperm is supported by the inability of Ca2+ ionophore A23187 to induce the AR and the ineffectiveness of Ca2+ channel antagonists to block egg water-induced AR. Measurements of capacitated sperm pH showed a significant decrease during the first 10-15 min of the AR, which did not correlate temporally to either acrosomal exocytosis (at 5 min post-induction) or filament formation (after 45 min). Inhibition of egg protease activity required for induction of filament formation did not inhibit the pH drop, indicating that intracellular acidification is not the final trigger for filament formation, although it may be required prior to action of the protease.