New Observations on Gametogenesis,Fertilization, and Zygote Transformation in Plasmodium gallinaceum1

The ultrastructure of the sexual stages of Plasmodium gallinaceum during gametogenesis, fertilization, and early zygote transformation is described. New observations are made regarding the parasitophorous vacuole (PV) of gametocytes and the process of emergence in male and female gametocytes. Whereas female gametocytes readily disrupted both the PV membrane and host cell plasmalemma during emergence, male gametocytes frequently failed to break down the plasmalemma of the host cell. New observations and hypotheses are presented on the behavior of the male gamete nucleus. Following fertilization, the male nucleus appears to travel through a channel of endoplasmic reticulum in the female gamete before fusing with the female nucleus at a region in which the nuclear envelope is thrown into extensive convoluted folds. Polarization of the zygote nucleus, in association with the appearance of a perinuclear spindle of cytoplasmic microtubules, preceded all other changes in the developing zygote. After nuclear polarization becomes apparent, electron-dense material is deposited beneath the zygote pellicle, and a canopy is formed which eventually extends over the entire apical end of the developing ookinete. As the apical end begins to extend outward, polar rings, micronemes, and subpellicular microtubules become visible in this portion and a “virus-like” inclusion known as a crystalloid is formed in the posterior portion of the zygote. When female gametes are prevented from being fertilized, the cytoplasm at 24 h after gametogenesis is devoid of most of those organelles found in the developing zygote or the mature ookinete. The cell is surrounded only by a single membrane. Although at various points beneath the membrane there are deposits of electron-dense material reminiscent of those deposited in the zygote, no further development of ookinete structures takes place in the unfertilized female gamete.     

Photographs of Fertilization in Trichonympha grandis

SYNOPSIS. The gametes of Trichonympha grandis fuse quite differently from those of all the other species of Trichonympha in Cryptocercus; fusion is partial and temporary instead of complete and permanent as in other species. In this species, as in the others, fusion brings about the disintegration of all the extranuclear organelles of the male gamete, but none of those of the female; these persist to become the organelles of the zygote. Gametic union accomplishes two things: loss of extranuclear organelles of male and fusion of pronuclei. Unlike that of the other species of Trichonympha , the cytoplasm of the male gamete of T. grandis contributes slightly, if at all, to the formation of the zygote.     

Photographs of Fertilization in the Smaller Species of Trichonympha

SYNOPSIS. The photographs illustrate male and female gametes before fertilization, several progressive stages in the entrance of the male gamete into the cytoplasm of the female, cytoplasmic fusion of gametes, loss of extranuclear organelles of male gamete, retention of extranuclear organelles of female gamete, movement of pronucleus of male gamete to that of female, progressive stages in fusion of pronuclei, and the formation of the zygote which possesses the extranuclear organelles of the female gamete. Some abortive attempts at fertilization, resulting from failure of gametes to differentiate, are shown.     

Observations on Gametogenesis in Plasmodium falciparum from Continuous Culture*

Synopsis. Gametocytes of Plasmodium falciparum were produced in continuous cultures but eventually declined in numbers after 3–4 months in vitro. Their development progressed in a consistent pattern, from small rounded, through triangular, to ellipsoidal, and finally after 8 days to crescentic forms. Morphologic maturity occurred at 8–9 days, but the gametocytes would not exflagellate in vitro, even after 14–18 days of development. Thus, current culture methods cannot produce a continuous supply of functional gametes for further studies.     

Observations on Fertilization in Sugar Beet

The whole process of double fertilization in sugar beet has been observed, the main results are as follows: About 2 hours after pollination, the pollen grains germinate, the sperms in the pollen tube are long-oval. 15 hours after pollination, the pollen tube destroys a synergid and releases two sperms on one side or at the chalazal end of the egg cell. The sperms are spherical each having a cytoplasmic sheath. 17 hours after pollination, one sperm enters the egg cell, and the sperm nucleus fuses with the egg nucleus rapidly. 21 hours after pollination, the zygote is formed. In the meantime, the primary endosperm nucleus has divided into two free endosperm nuclei. 25 hours after pollination, the zygote begins to divide, forming a two-celled proembryo. The dormancy stage of the zygote is about 4 hours. In the meantime the endosperm is at the stage of four free nuclei. 17 hours after pollination, the sperm nucleus comes into contact and fuses with the secondary nucleus. The sperm nucleus fuses with the secondary nucleus, faster than the sperm with the egg. he first division of the primary endosperm nucleus is earlier than that of the zygote, it takes place about 20 hours after pollination, the dormancy stage of the primary endosperm is about 2 hours. The endosperm is free nuclear. The fertilization of sugar beet belongs to premitotic type of syngamy. From the stage of zygote to the two-celled proembryo, it can be seen that addition- al sperms enter the embryo sac, but polyspermy has not been observed yet.     

Cytologic Observations on the Double Fertilization in Maize

1.The double fertilization is the type of the premitotic syngamy. 2. In 21 to 24 hours after pollination, most of the female nuclei fuse with the male nuclei. When the female nucleus fuses with the male nucleus, there are two situations in the appearance of the male nucleolus: one is that while the chromatin of the sperm nucleus relaxes gradually, a male nucleolus appears; the other is that after the chromatin of the sperm nucleus relaxes gradually, the male nucleus just appears in about 2 to 4 hours. 3. Generally, the fusion of the female nucleolus with the male nucleolus takes place before the division of the nygote. The nygote enters the stage of division when it has a jarge nucieojus; the zygote, in which the female nucleoius does not fuse with the male nucleolus, also can enter the stage of division. In 30 to 33 hours after pollination, the first division of the zygote occurs. The resting period of the zygote is about 9 hours 4. In the primary endosperm nucleus, the female nucleolus does not fuse with the male nucleolus. 24 to 26 hours after pollination, the primary endosperm nucleus begins the first division. The resting period of the primary endosperm nucleus is 2 to 4 hours. 5. Under the condition of artificial pollination, the fertilization of the fruit ears of maize proceeds sequencely, i.e. from the upper of the fruit ears to the lower the fertilization is fulfilled gradually.     

Light and Electron Microscopic Observations of Gametogenesis in Hastigerina pelagica (Foraminifera)*

SYNOPSIS. During gametogenesis mother individuals of Hastigerina pelagica (d'Orbigny) undergo significant morphological changes. Thirty h before gamete release, the cytoplasm changes from pale orange to bright red, possibly due to transport of stored lipids from the inner region to more peripheral parts of the cytoplasm. During the next 10 to 15 h the bubble capsule which surounds the calcareous shell is discarded. After all bubbles have disappeared, the individual sheds its spines by resorbing the spine bases close to the shell surface. A single mother nucleus divides into some hundreds of thousands of gamete nuclei within a span of ～ 20 h. A bulge of cytoplasm is extruded from the aperture and increases in size during the next 5 to 10 h. This bulge consists of cytoplasmic strands in which gametes and spherical bodies are embedded. The gametes and spherical bodies mature and are released during the afternoon and early evening. The gametes have 2 unequal acronematic flagella. A previously undescribed structure in foraminiferal reproduction is the spherical body which consists of a large vacuole surrounded by a thin cytoplasmic layer in which several nuclei, various typical cell organelles and multiple flagella are present. The spherical bodies are believed to play a role as receptacles of waste material, possibly including residual digestive enzymes, thereby protecting the gametes from lysis during the reproductive process. Fusion of gametes and further development into the next generation have not been observed.     

Cell Division without Chromatin in Trichonympha and Barbulanympha

SUMMARY. Oxygen concentrations of 70–80 per cent of an atmosphere destroy all chromosomes of the flagellate Trichonympha provided the oxygen treatment is carried out during the early stages of gametogenesis at which time the chromosomes are in the process of duplicating themselves. This treatment does no damage to the cytoplasm and its organelles. Following the loss of chromosomes, the centrioles function in the production of the achromatic figure, the flagella, and'parabasal bodies. Then the cytoplasm divides, thus producing two anucleate gametes which make some progress in the cytoplasmic differentiations characteristic of normal male and female gametes of Trichonympha.
It is also possible, with somewhat higher concentrations of oxygen, with temperatures slightly above the freezing point and a longer period of treatment, to destroy the chromosomes of resting asexual nuclei in several genera of the flagellates that live in the roach Cryptocercus. So far as one can determine by observing organisms so treated, their cytoplasm and organelles are not injured.     

星星草受精作用及其胚与胚乳早期发育的观察

利用常规石蜡切片法对星星草[Puccinellia tenuiflora(Griseb．)Scribn．et Merr．]受精过程及胚与胚乳的早期发育进行了观察,主要结论如下：(1)开花后2h,花粉管破坏1个助细胞,释放2个精子,精子呈逗点状。(2)开花后2～3h,2个精子分别移向卵细胞与极核。(3)开花后3～5h,精核分别贴附于卵细胞与极核的核膜上。(4)开花后5～10h,精核与卵核融合,雄性核仁出现,合子形成。(5)开花后5～6h,精核与极核融合,并出现雄性核仁,形成初生胚乳核,精核与极核的融合比与卵核融合要快。(6)开花后20h左右,合子分裂。(7)开花后8h,初生胚乳核。     

Cytoplasmic Membranes and the Nuclear Membrane in the Flagellate Trichonympha

The structure of the nuclear and cytoplasmic membranes of Trichonympha, a complex flagellate, has been studied in the electron microscope. The nuclear membrane consists of two 70 A membranes, penetrated by numerous pores. Small (100 A) granules occur on the outer surface, around the rims of the pores. Granule-bearing membranes, only 30 to 40 A thick, form long, ribbon-shaped sacs, with 100 A granules on their outer surface. They apparently form close to the nucleus, from which they probably derive their granules. Smooth membranes occur in the parabasal bodies, which consist of stacks of 70 A membranes, joined at their edges in pairs to form flattened sacs. These can inflate and form cytoplasmic vesicles. A protein fibre is applied laterally to the pile of sacs. New sacs, replacing those lost by inflation, appear to form by a process involving the granular membranes, and there may be a transformation of one into the other. Starving eliminates granular membranes and results in a failure in the formation of new parabasal sacs. Refeeding reverses these effects. A parabasal body is a steady-state system, in which the rates of loss and gain of sacs are normally approximately equal. Parabasal bodies resemble the Golgi apparatus.     

Current Topics in Organogenesis and Gametogenesis

At the 49th Annual Drosophila Research Conference from April 3-8, 2008 in San Diego there were eight talks and over ninety posters in the section on Organogenesis and Gametogenesis. These covered a wide range of topics within the two broad categories of organ-specific stem cells (including germ cells) and organ-specific developmental programs. Here we discuss eleven of these presentations describing current research into the formation of the gonad, intestine, trachea, muscle and leg joint. The new insights presented advance our understanding of the molecular events that underlie interactions between stem cells and their niches as well as mechanisms underlying tissue-specific differentiation programs.     

Gametogenesis in Fundulus heteroclitus

Our present understanding of the structure of the gonads andof gametogenesis in Fundulus helerodilus is briefly reviewed. The testes contain spermatogenic tubules which distally arecomposed of linearly arranged germinal cysts with clones ofsynchronously developing germ cells, and proximally of efferentducts with mature sperm. Within the tubules, those cysts containingspermatogonia are found close to the testicular periphery, whereascysts with mature sperm are contiguous with the efferent ducts.Cytological details of the three principal stages of spermatogenesis,namely spermatocytogenesis, meiosis, and spermiogenesis, arepresented along with examples of the various somatic cells ofthe testis. The ovary consists of numerous ovigerous lamellae which containrandomly arranged follicles in various stages of development.Since follicular growth is asynchronous, follicles of all sizesare present in the ovary during the breeding season and eggsare continuously ovulated into the ovarian lumen. Oocyte growthis divided into five distinct stages: Primary growth (substagesA and B), cortical alveolus formation, vitellogenesis, oocytematuration (substages A and B), and the ovulated egg. This seriesof stages is based both on cytological observations and physiologicalevents.     

濒危植物瑶山苣苔的大小孢子发生和雌雄配子体发育研究

利用石蜡切片技术对瑶山苣苔大小孢子发生、雌雄配子体发育及胚胎发育进行了细胞学观察,结果表明:瑶山苣苔胚珠倒生,单珠被,薄珠心,具珠被绒毡层。大孢子母细胞减数分裂形成的四分体呈直线排列,合点端的大孢子发育为功能大孢子,其余3个大孢子退化,胚囊为单孢子发生的蓼型胚囊发育方式。花药为四囊形,花药壁由外到内依次为表皮、药室内壁、中层和腺质绒毡层,小孢子形成时胞质分裂为修饰性同时型,小孢子四分体排列方式为四面体形,成熟花粉为2核细胞。胚乳发育为细胞型,在胚的发育过程中被吸收耗尽。瑶山苣苔大小孢子发生和雌雄配子体发育基本正常,不是导致其濒危的原因。但瑶山苣苔果实成熟时,胚仅发育至球形胚时期,需要经过一定时间休眠才能完成形态后熟,表明胚未发育完全可能是该物种天然更新困难的原因之一。     

Observations on the Neocytoplasm and Proteid Vacuoles During the Fertilization of Keteleeria evelyniana

Distributions and dynamics of the neocytoplasm and proteid vacuoles during the fertilization of Keteleeria evelyniana were studied by histochemical methods. Before fertilization cytoplasmic sheath surrounding the male and female gametes was indistinct. After fertilization, the dense neocytoplasm appeared around the zygote. Part of the neocytoplasm is invaded by mitochondria of maternal origin which had collected in large numbers in the perinuclear zone. The mitochondria contain electron compact little body which looks like a nucleus in the cytoplasm, but not observed in the rosette tier cell of proembryo and jacket cells. Hence, it was showed that the neocytoplasm participated in the development of embryo by all these observations. By using Feulgen reaction, the staining reaction of neocytoplasm was positive, the egg nucleus or zygote nucleus was weaker in positive reaction, while the proteid vacuoles were negative. When the proembryo developed, there were a few starch grains accumulated in the other three tiers except the upper tier. The Feulgen reaction was in- creased in intensity in the suspensor tier and embryonal cell tier nuclei. When the young embryo developed, Feulgen reaction became normal in the nuclei of the embryo initials. The embryo initials and Suspensor cells showed very weak Feulgen positive reaetion in the proembryo and young embryo. The development of the large proteid vacuoles was from plastid. During the early stage of egg nucleus, contents of large proteid vacuoles were less. When the zygote was formed, they reached the highest. However, after the zygote produced, the proteid vacuoles and egg cytoplasm were getting disintegrated following the course of fission of free nuclei. After the proembryo formed, the proteid vacuoles were wholly disintegrated.     

Gametogenesis in the Genus Hydra

This paper comments on the induction of gametogenesis, on microscopicaland electronmicroscopical aspects of spermatogenesis and oogenesisand on fertilization in the genus Hydra. Spermiogenesis doesnot present any peculiarities. The ripe sperm contains no detectableacrosoinc. Egg-formation involves phagocytosis of entire oogoniaby growing oocytes. Several oocytes merge to a single oocyte,in which one nucleus becomes the germinal vesicle. The egg shellis formed only when the egg is fertilized. Various factors suchas the synchronization of gametogenesis, the length of sexualperiods, continuous release of sperm and the long life spanof sperm are considered to guarantee the fertilization of theeggs.