高等植物受精过程中雌-雄相互作用的分子调控机制

从广义上讲,被子植物的受精过程是指花粉粒落到柱头上萌发形成花粉管,花粉管穿过柱头沿着引导组织生长进入子房内,最终在胚囊中实现精细胞与卵细胞以及中央细胞分别融合从而起始胚胎和胚乳的发育．被子植物的精细胞由于不具有鞭毛而无法自由移动,因此在受精过程中需要借助于花粉管来将精细胞运送到胚囊中．花粉管通过与雌性的孢子体组织之间的相互作用和识别将精细胞准确地运送到胚珠附近,而最终将精细胞准确地运送到胚囊内的过程则是受到了雌配子体细胞的控制．可以说,受精的成功实现有赖于雌性和雄性细胞之间的持续的识别和相互作用,这种互作具有多样性和阶段特异性．本文将主要综述被子植物受精过程中花粉粒以及花粉管与多种雌性孢子体组织以及雌配子体之间的信号互作研究．     

Embryonal carcinoma cells transfected with ZP3 genes differentially glycosylate similar polypeptides and secrete active mouse sperm receptor

Mouse and hamster sperm receptors, called mZP3 (approximately 83,000 Mr) and hZP3 (approximately 56,000 Mr), respectively, are glycoproteins located in the ovulated egg zona pellucida. Certain of the glycoprotein O-linked oligosaccharides are essential for sperm receptor activity. Here, we transfected mouse embryonal carcinoma (EC) cells with mZP3 and hZP3 genes placed under control of a constitutive promoter. Transfected cells synthesized and secreted large amounts of the glycoproteins, called EC-mZP3 and EC-hZP3. Although the primary structures of mZP3 and hZP3 polypeptides (44,000 Mr) are very similar to one another, EC-mZP3 (approximately 83,000 Mr) and EC-hZP3 (approximately 49,000 Mr) were glycosylated to very different extents, such that they resembled their egg counterparts. Like egg mZP3, EC-mZP3 inhibited binding of sperm to ovulated eggs and induced sperm to acrosome-react in vitro. In addition, large numbers of sperm bound to aggregates of mZP3-transfected EC cells in vitro. On the other hand, unlike egg hZP3, EC-hZP3 did not exhibit either sperm receptor or acrosome reaction-inducing activity, and sperm failed to bind to aggregates of hZP3-transfected EC cells. Thus, transfected EC cells not only express sperm receptor genes, but also discriminate between very similar polypeptides with respect to glycosylation and, in the case of mZP3, add specific oligosaccharides essential for biological activity. In addition, the results demonstrate that EC cells can serve as a source for large amounts of functional mouse sperm receptor.     

Mammalian fertilization: the strange case of sperm protein 56

During mammalian fertilization sperm bind to the egg's zona pellucida (ZP) after undergoing capacitation. Capacitated mouse sperm bind to mZP3 (one of three ZP glycoproteins), undergo the acrosome reaction, penetrate the ZP, and fuse with egg plasma membrane. Sperm protein 56 (sp56), a member of the C3/C4 superfamily of binding proteins, was identified nearly 20 years ago as a binding partner for mZP3 by photoaffinity cross‐linking of acrosome‐intact sperm. However, subsequent research revealed that sp56 is a component of the sperm's acrosomal matrix and, for sperm with an intact acrosome, should be unavailable for binding to mZP3. Recently, this dilemma was resolved when it was recognized that some acrosomal matrix (AM) proteins, including sp56, are released to the sperm surface during capacitation. This may explain why uncapacitated mammalian sperm are unable to bind to the unfertilized egg ZP.     

SPERM COMPETITION AND THE EVOLUTION OF NONFERTILIZING SPERM IN MAMMALS

Nonfertilizing sperm with special morphologies have long been known to exist in invertebrates. Until recently, abnormal sperm in mammals were considered errors in production. Now, however, Baker and Bellis (1988, 1989) have proposed that mammalian sperm, like some invertebrate sperm, are polymorphic and adapted to a variety of nonfertilizing roles in sperm competition, including prevention of passage of sperm inseminated by another male. More specifically, their “kamikaze” sperm hypothesis proposes that deformed mammalian sperm are adapted to facilitate the formation and functioning of copulatory plugs (Baker and Bellis, 1988). Here I argue that most, maybe all, mammals are unlikely to produce nonfertilizing sperm. First, mammals might not be able to afford to evolve nonfertilizing sperm, given that a) fertilization is often unlikely despite the huge numbers of sperm produced; b) production of larger numbers of sperm is constrained, presumably because of metabolic costs, evidence for which includes the fact that in species in which sperm morphology and anatomy of the female reproductive tract increase the probability of fertilization, the numbers of sperm produced is lower than in others; and c) selection appears to act against the production of deformed sperm. Second, some of the evidence advanced for the existence of nonfertilizing sperm does not in fact support the idea. Third, accessory gland secretions are sufficient on their own to coagulate semen and produce fully functioning plugs; thus the male that used accessory gland secretions would be at a clear advantage over the male that diluted his fertilizing sperm with “kamikaze” sperm; and indeed, current evidence indicates selection on accessory glands, not sperm morphology, to enhance coagulation of semen. Fourth, predictions made on the basis of the “kamikaze” sperm hypothesis are not supported by quantitative comparisons of data from polyandrous and monandrous primates (i.e., those in which several males mate with a fertile female, and therefore in which sperm competition should be operating, and those in which only one male mates). Although sperm competition is almost certainly more intense in polyandrous genera than in monandrous genera (as indicated by, e.g., more frequent copulations and the production of more sperm per ejaculate from larger spermatogenic organs), polyandrous genera do not produce a greater proportion of deformed (i.e., nonfertilizing) sperm than do monandrous genera, or even necessarily a greater number of deformed sperm; nor a greater variety of sperm sizes—indeed they might produce fewer; nor fewer motile sperm (as might be expected if sperm are selected to stay behind and compete with sperm from subsequent males); and nor larger sperm (as might be expected if sperm are produced for functions other than to reach the egg). In sum, currently available evidence suggests that the function of all mammalian sperm is to fertilize, and that sperm competition in mammals occurs through scramble competition, not contest competition.     

Complexin I is required for mammalian sperm acrosomal exocytosis

Regulated exocytosis in many cells is controlled by the SNARE complex, whose core includes three proteins that promote membrane fusion. Complexins I and II are highly related cytosolic proteins that bind tightly to the assembled SNARE complex and regulate neuronal exocytosis. Like somatic cells, sperm undergo regulated exocytosis; however, sperm release a single large vesicle, the acrosome, whose release has different characteristics than neuronal exocytosis. Acrosomal release is triggered upon sperm adhesion to the mammalian egg extracellular matrix (zona pellucida) to allow penetration of the egg coat. Membrane fusion occurs at multiple points within the acrosome but how fusion is activated and the formation and progression of fusion points is synchronized is unclear. We show that complexins I and II are found in acrosome-intact mature sperm, bind to SNARE complex proteins, and are not detected in sperm after acrosomal exocytosis (acrosome reaction). Although complexin-I-deficient sperm acrosome-react in response to calcium ionophore, they do not acrosome-react in response to egg zona pellucida proteins and have reduced fertilizing ability, in vitro. Complexin II is present in the complexin-I-deficient sperm and its expression is increased in complexin-I-deficient testes. Therefore, complexin I functions in exocytosis in two related but morphologically distinct secretory processes. Sperm are unusual because they express both complexins I and II but have a unique and specific requirement for complexin I.     

Male contributions to egg production: the role of accessory gland products and sperm in Drosophila melanogaster

Drosophila melanogatser seminal fluid components, accessory gland proteins (Acps) and sperm, induce females to deposit high numbers of fertilized eggs for about 11 days. This high and sustained level of egg deposition requires that oogenesis be stimulated to provide the necessary mature oocytes. To investigate the relative timing and contributions of Acps and sperm in the egg-production process, we examined the rates of oogenic progression and egg deposition in females mated to genetically altered males that have seminal fluid deficient in Acps and/or sperm, and subjected these data to path analysis. We found that Acps and sperm are complementary stimuli necessary for inducing high rates of oogenic progression and rapid egg deposition. While egg deposition and oogenic progression can be induced by Acps alone, both Acps and sperm are required for maximum stimulation of oogenic progression and egg deposition immediately after mating.     

A profile of fertilization in mammals

Fertilization is defined as the process of union of two gametes, eggs and sperm. When mammalian eggs and sperm come into contact in the female oviduct, a series of steps is set in motion that can lead to fertilization and ultimately to development of new individuals. The pathway begins with species-specific binding of sperm to eggs and ends a relatively short time later with fusion of a single sperm with each egg. Although this process has been investigated extensively, only recently have the molecular components of egg and sperm that participate in the mammalian fertilization pathway been identified. Some of these components may participate in gamete adhesion and exocytosis, whereas others may be involved in gamete fusion. Here we describe selected aspects of mammalian fertilization and address some of the latest experimental evidence that bears on this important area of research.     

Molecules on the sperm's route to fertilization.

In eutherian mammals billions of sperm are deposited at ejaculation in the female reproductive tract, but only a few thousand enter the oviduct. A few reach the ampulla at the time of fertilization and only one sperm fertilizes the egg. In most mammalian species the lower isthmus of the fallopian tubes has taken over the function of a reservoir in which sperm are stored under conditions that save sperm energy by suppressing motility and increase viability. Close to the time when the egg is ovulated into the ampulla, the sperm undergo a complex sequence of processes, named capacitation. Capacitation is a prerequisite for fertilization, enabling the sperm to recognize the egg and to respond to the egg signals in the appropriate manner. Sperm bind to the egg extracellular matrix, the zona pellucida, and upon binding undergo the acrosome reaction, followed by the passage of the zona pellucida and binding to and fusion with the egg oolemma, thus triggering the embryonic developmental program. The oviduct and the egg itself appear to coordinate sperm function to ensure that two functional competent gametes will meet, leading to fertilization. For the communication between sperm and somatic cells as well as between both gametes the information potential of carbohydrates is utilized, and this event probably prepares the next level of interactions, e.g., capacitation, acrosome reaction, egg binding, and fusion. The current perspective focuses on the role of molecules possibly implicated in sperm-oviduct and sperm-egg interactions. J. Exp. Zool. (Mol. Dev. Evol.) 285:259-266, 1999.     

THE PRODUCTION OF PARTHENOGENETIC MAMMALIAN EMBRYOS AND THEIR USE IN BIOLOGICAL RESEARCH

1. The eggs of many mammalian species show signs of early parthenogenetic development as they age after ovulation and oocytes may form transplantable terato-carcinomas. These cases of apparently spontaneous parthenogenetic development suggest that the cells of the female germ line have an inherent tendency to divide and differentiate. 2. The ovulated eggs of virgin female mammals may be stimulated to start parthenogenetic development by a wide variety of treatments. Most of these damage the egg so that it does not develop beyond the 4 cell stage. However if the eggs are exposed to electrical activation, hyaluronidase treatment, or temperature shock then in many cases they will develop into blastocysts. 3. These blastocysts may be either haploid or diploid. Haploid blastocysts may be formed either by the egg extruding the nucleus of the second polar body or by the egg dividing in half, so that the female pronucleus is in one cell and the nucleus of the second polar body is in another cell. Diploid blastocysts are formed by the retention of the nucleus of the second polar body within the egg. The way in which the egg develops may be controlled by altering the osmolarity of the culture medium, the age of the egg at the time of activation, or the strain of animal used. 4. The action of the sperm on the egg can be defined by comparing the events of normal fertilization and parthenogenetic activation. Both these stimuli cause the egg to expose binding sites for Concanavalin A to synthesize DNA and to divide. However, the release of cortical granules, which occurs after fertilization, does not appear to be induced by parthenogenetic activation, and it is significant that parthenogenones lack the sperm nucleus and mitochondria. 5. The majority of parthenogenones die soon after implantation. Death at this time occurs with parthenogenones obtained from the activated eggs of both inbred and outbred stocks. Death might be caused by recessive lethal mutations or by extra-genetic effects of the maternal chromosomes. 6. Parthenogenones contain endogenous A-type particles which shows that these bodies are inherited through the female germ line. 7. Parthenogenones may in the future provide both a method for chromosome mapping and a source of haploid cells. At present the use of mammalian parthenogenones in biological research is restricted by the heavy embryonic losses which occur around the time of implantation. This means that the role of the sperm, gene activity and virus expression must be studied during a very limited period. Part of the mortality before implantation is the consequence of the damage which the egg suffers during activation and it should be possible to reduce this loss by improving the techniques for activation. It may also be possible to increase the quantity of cells derived from haploid and diploid mammalian embryos by deriving teratocarcinomas from them.     

Polyspermic mouse eggs can dispose of supernumerary sperm

Zona-free mouse eggs inseminated with capacitated epididymal sperm in a modified Krebs-Ringer bicarbonate medium exhibited unusual kinetics of sperm incorporation. At a sperm concentration of 10⁵ cells/ml or higher, the mean number of sperm per egg reached a maximum and then decreased with time. This decrease was correlated with the abstriction of sperm in cytoplasmic blebs which formed during or slightly after second polar body abstriction, 1.5–2.5 hr postinsemination. A correlation was apparent between the degree of polyspermy and the total number of sperm lost by this mechanism. Of 82 dispermic eggs studied, 36 underwent sperm loss by blebbing, a process that restored the monospermic condition. The sequential steps in the abstriction process are depicted in micrographs of whole mounts of fixed eggs. A sperm head or male pronucleus could be seen in isolated blebs. The prevention of bleb formation by exposure of penetrated eggs to cytochalasin B largely eliminated any difference in sperm number when the mean number of sperm per egg was compared at 2, 4, and 6 hr postinsemination. Sperm abstriction may be a novel sperm exclusion mechanism employed by mammalian eggs. Evidence is also presented that an unknown mechanism of sperm exclusion is operative in mouse eggs, since sperm loss by abstriction did not account for all sperm loss.     

A hyaluronidase activity of the sperm plasma membrane protein PH-20 enables sperm to penetrate the cumulus cell layer surrounding the egg

A typical mammalian egg is surrounded by an outer layer of about 3,000 cumulus cells embedded in an extracellular matrix rich in hyaluronic acid. A current, widely proposed model is that the fertilizing sperm, while it is acrosome intact, passes through the cumulus cell layer and binds to the egg zona pellucida. This current model lacks a well- supported explanation for how sperm penetrate the cumulus layer. We report that the sperm protein PH-20 has a hyaluronidase activity and is present on the plasma membrane of mouse and human sperm. Brief treatment with purified, recombinant PH-20 can release all the cumulus cells surrounding mouse eggs. Acrosome intact mouse sperm incubated with anti-PH-20 antibodies can not pass through the cumulus layer and thus can not reach the zona pellucida. These results, indicating that PH-20 enables acrosome intact sperm to penetrate the cumulus barrier, reveal a mechanism for cumulus penetration, and thus provide the missing element in the current model.     

Mammalian sperm contain a Ca(2+)-sensitive phospholipase C activity that can generate InsP(3) from PIP(2) associated with intracellular organelles

We have previously described a phospholipase C (PLC) activity in mammalian sperm cytosolic extracts. Here we have examined the Ca(2+) dependency of the enzyme, whether there is enough in a single sperm to account for Ca(2+) release at fertilization, and finally where in the egg is the phosphatidyl 4,5-bisphosphate, the substrate for the enzyme. As for all PLCs examined so far in vitro, we found that the boar sperm PLC activity was Ca(2+) dependent. Specific activity increased when free Ca(2+) levels were micromolar. However, even at nanomolar free Ca(2+) concentration the boar sperm PLC activity was considerable, being two orders of magnitude greater than PLC activities in other tissues. We calculated that PLC activity of a single boar sperm in a mammalian egg is enough to generate 400 nM inositol 1,4,5-trisphosphate (InsP(3)) in 1 min, which may be sufficient to account for the observed Ca(2+) changes in an egg at fertilization. We fractionated sea urchin egg homogenate and examined the ability of boar sperm extract to generate InsP(3) from these fractions. The sperm PLC activity triggered InsP(3) production from a PIP(2)-enriched nonmicrosomal egg compartment that contained yolk platelets. We propose that this sperm PLC activity, which is active at nanomolar Ca(2+) levels and hydrolyzes PIP(2) from intracellular membranes, could be involved in the Ca(2+) changes observed at fertilization.     

Preventing polyspermy in mammalian eggs—Contributions of the membrane block and other mechanisms

The egg's blocks to polyspermy (fertilization of an egg by more than one sperm) were originally identified in marine and aquatic species with external fertilization, but polyspermy matters in mammalian reproduction too. Embryonic triploidy is a noteworthy event associated with pregnancy complications and loss. Polyspermy is a major cause of triploidy with up to 80% of triploid conceptuses being the result of dispermic fertilization. The mammalian female reproductive tract regulates the number of sperm that reach the site of fertilization, but mammals also utilize egg‐based blocks to polyspermy. The egg‐based blocks occur on the mammalian egg coat (the zona pellucida) and the egg plasma membrane, with apparent variation between different mammalian species regarding the extent to which one or both are used. The zona pellucida block to polyspermy has some similarities to the slow block in water‐dwelling species, but the mammalian membrane block to polyspermy differs substantially from the fast electrical block that has been characterized in marine and aquatic species. This review discusses what is known about the incidence of polyspermy in mammals and about the mammalian membrane block to polyspermy, as well as notes some lesser‐characterized potential mechanisms contributing to polyspermy prevention in mammals.     

Assessment of sperm functional competence and sperm-egg interaction

A precise understanding in the functional competence of mammalian sperm is essential to generate clinical advances for the treatment of infertility and novel contraceptive strategies. The fundamental knowledge on the controlling parameters for spermatozoal activation process will help in the identifying the causes in fertilization failure due to male factor as well as in developing male contraceptive methodologies. The defects in the sperm-egg interaction seem to be one of the controlling mechanisms, however, none of the presently available methods for the evaluation of the fertilizing ability of sperm precisely indicates the reason for the failure or the success of sperm entry into egg. Adequate number of motile spermatozoa with normal morphology and timely occurrence of acrosome reaction are presumably the major prerequisites for the penetration through the egg investments. The present communication briefly reviews some of the main features of mammalian sperm which control the success or the failure of fertilization and existing clinical methods indicating the lack of fundamental knowledge on the sub-cellular and molecular aspects of this unique and species-specific cell-cell interaction.     

Mammalian sperm molecules that are potentially important in interaction with female genital tract and egg vestments

Fertilisation is a highly programmed process by which two radically different cells, sperm and egg, unite to form a zygote, a cell with somatic chromosome numbers. Development of the zygote begins immediately after sperm and egg haploid pronuclei come together, pooling their chromosomes to form a single diploid nucleus with the parental genes. Mammalian fertilisation is the net result of a complex set of molecular events which allow the capacitated spermatozoa to recognise and bind to the egg's extracellular coat, the zona pellucida (ZP), undergo the acrosome reaction, and fuse with the egg plasma membrane. Sperm-zona (egg) interaction leading to fertilisation is a species-specific carbohydrate-mediated event which depends on glycan-recognising proteins (glycosyltransferases/glycosidases/lectin-like molecules) on sperm plasma membrane (receptors) and their complementary glycan units (ligands) on ZP. The receptor-ligand interaction event initiates a signal transduction pathway resulting in the exocytosis of acrosomal contents. The hydrolytic action of the sperm glycohydrolases and proteases released at the site of sperm-egg interaction, along with the enhanced thrust generated by the hyperactivated beat pattern of the bound spermatozoon, are important factors regulating the penetration of egg investments. This review focuses on sperm molecules believed to be important for the interaction with the female genital tract, passage through cumulus oophorus and attachment to ZP, induction of the acrosome reaction, secondary binding events, and passage through the ZP. An understanding of the expression and modifications of molecules thought to be important in multiple events leading to fertilisation will allow new strategies to block these modifications and alter sperm function.     

Profile of a mammalian sperm receptor

Complementary molecules on the surface of eggs and sperm are responsible for species-specific interactions between gametes during fertilization in both plants and animals. In this essay, several aspects of current research on the mouse egg receptor for sperm, a zona pellucida glycoprotein called ZP3, are addressed. These include the structure, synthesis, and functions of the sperm receptor during oogenesis and fertilization in mice. Several conclusions are drawn from available information. These include (I) ZP3 is a member of a unique class of glycoproteins found exclusively in the extracellular coat (zona pellucida) of mammalian eggs. (II) ZP3 gene expression is an example of oocyte-specific and, therefore, sex-specific gene expression during mammalian development. (III) ZP3 is a structural glycoprotein involved in assembly of the egg extracellular coat during mammalian oogenesis. (IV) ZP3 is a sperm receptor involved in carbohydrate-mediated gamete recognition and adhesion during mammalian fertilization. (V) ZP3 is an inducer of sperm exocytosis (acrosome reaction) during mammalian fertilization. (VI) ZP3 participates in the secondary block to polyspermy following fertilization in mammals. (VII) The extracellular coat of other mammalian eggs contains a glycoprotein that is functionally analogous to mouse ZP3. The unique nature, highly restricted expression, and multiple roles of ZP3 during mammalian development make this glycoprotein a particularly attractive subject for investigation at both the cellular and molecular levels.     

Sperm Bind but Do not Unbind from the Fixed Sea Urchin Egg

In S. purpuratus sperm remained bound to aldehyde-fixed eggs and did not exhibit a detachment phase. Sperm bound in high numbers and the binding curve was similar to that for unfixed homologous gametes. Binding kinetics were analyzed using sequential still photographs of slightly flattened, fixed eggs under supported coverslips. In this way, a single egg could be observed. Alternatively, sperm remaining in the supernatant over settled eggs were counted at successive time points postmixing using spectrophotometry (340 nm) and hemocytometry. Additionally, aliquots of mixed gametes were fixed at successive time points and the numbers of bound sperm determined microscopically on egg perimeters. The maximum number of sperm bound by 2 min; this number remained at or near maximum for as long as 10 min when the experiments were terminated. When sperm were jelly-reacted before addition to eggs, fewer sperm bound, although binding curves were similar to the above experiments. It appears that the binding efficiency of sperm decreases with time after initiation of the acrosome reaction: (1) fewer prereacted sperm bound; and, (2) sperm did not continue to bind after 2 min even though the egg surface was not saturated. Whether these effects are related to motility or other factors is unclear. Furthermore, the above results indicate the importance of the cortical reaction to sperm unbinding. Such studies enable one to observe sperm behavior while precluding the effects of egg secretion during the initial stages of fertilization.     

The dynamics of calcium oscillations that activate mammalian eggs

It has been known for some time that mammalian eggs are activated by a series of intracellular calcium oscillations that occur shortly after sperm egg membrane fusion. Recent work has identified a novel sperm specific phospholipase C zeta as the likely agent that stimulates the calcium oscillations in eggs after sperm-egg membrane fusion. PLCzeta is stimulated by low intracellular calcium levels in a manner which suggests that there is a regenerative feedback of calcium release and PLCzeta induced inositol 1,4,5-trisphophate (InsP(3)) production in eggs. This implies calcium oscillations in fertilizing mammalian eggs are driven by underlying oscillations of InsP(3). This model of oscillations is supported by the response of mouse eggs to sudden increases in InsP(3). The cellular targets of calcium oscillations include calmodulin-dependent protein kinases, protein kinase C and mitochondria. There is evidence that eggs might be best activated by multiple calcium increases rather than a single calcium rise. As yet we do not fully understand how the target of calcium in a mammalian egg might decode the patterns of calcium changes that can occur during egg activation.     

CRISP1 as a novel CatSper regulator that modulates sperm motility and orientation during fertilization

Ca²⁺-dependent mechanisms are critical for successful completion of fertilization. Here, we demonstrate that CRISP1, a sperm protein involved in mammalian fertilization, is also present in the female gamete and capable of modulating key sperm Ca²⁺ channels. Specifically, we show that CRISP1 is expressed by the cumulus cells that surround the egg and that fertilization of cumulus–oocyte complexes from CRISP1 knockout females is impaired because of a failure of sperm to penetrate the cumulus. We provide evidence that CRISP1 stimulates sperm orientation by modulating sperm hyperactivation, a vigorous motility required for penetration of the egg vestments. Moreover, patch clamping of sperm revealed that CRISP1 has the ability to regulate CatSper, the principal sperm Ca²⁺ channel involved in hyperactivation and essential for fertility. Given the critical role of Ca²⁺ for sperm motility, we propose a novel CRISP1-mediated fine-tuning mechanism to regulate sperm hyperactivation and orientation for successful penetration of the cumulus during fertilization.