SCANNING ELECTRON MICROSCOPY OF ANTHERIDIA AND ARCHEGONIA OF ANEMIA MEXICANA KLOTZSCH

Antheridia and archegonia of the fern Anemia mexicana were viewed with scanning electron microscopy (SEM). The mature antheridium is composed of a cap, ring, and basal cell with spermatozoids inside. The archegonium neck is composed of a neck canal cell surrounded by four rows of neck cells. The ventral canal cell and egg were not observed. The neck bends toward the notched meristem. The neck cells usually are uniform in shape and arrangement, but in some archegonia, shape and arrangement of neck cells was irregular. The apex of these archegonia often appeared swollen because of the random cell arrangement. In the presence of water, the antheridium cap is partially detached and the spermatozoids emerge. At this time, the neck cells open at the end of the archegonium in preparation for fertilization. The basic morphology of the antheridia and archegonia is similar to previous reports, although SEM provides more structural detail and a better three-dimensional visualization of these reproductive structures.     

Evidence for intergeneric incompatibility in ferns

The archegonial mucilage ofAthyrium filix-femina andA. distentifolium paralyses spermatozoids ofDryopteris filix-mas (and in one caseD. inaequalis) before they penetrate the archegonial venter. The archegonial mucilage ofDryopteris filix-mas has a weak positive chemotactic influence on the spermatozoids of the twoAthyrium species. The spermatozoids ofDryopteris were never observed in the archegonia ofAthyrium. Incompatibility was not observed within and between the twoAthyrium species, withinDryopteris filix-mas or betweenAthyrium filix-femina and twoAsplenium species.Contribution No. 327.     

Antheridia and Archegonia of the Apogamous Fern Pteris cretica

The external appearance of gametophytes and gametangia of Pteriscretica closely resembled those of sexually reproducing ferns.Antheridia were fully functional but archegonia were not. Despitethe formation of egg, ventral and neck canal cells, the flask-shapedarchegonia failed to open and Pteris spermatozoids failed toexhibit a chemotactic response to them. Cryo SEM revealed thatthe topmost cells of mature archegonia had collapsed, and thisis thought to account for the loss of archegonial function. Pteris cretica, fern, apogamy, antheridia, archegonia, cryo SEM     

樟子松受精作用和原胚的选择

樟子松发育成熟的雄配子体中的精子6月15日左右在颈卵器中上部与卵细胞结合,进行受精作用,其后,受精卵进行游离核分裂,形成8个子核时,开始形成细胞壁。它们再分裂1次,形成16个细胞的原胚。接着胚柄细胞层迅速生长、伸长,把下面的原胚送出颈卵器基部的细胞壁,进入胚乳中的溶蚀腔。原胚吸收溶蚀腔中的营养,生长发育。初期,胚的数目往往很多,但常常只有1个发育成熟。     

Ultrastructure and phylogeny of the spermatozoid ofChara vulgaris (Charophyceae)

At maturity, spermatozoids of the green algaChara vulgaris are biflagellated, contain little cytoplasm, and coil for approximately 2 1/2 gyres within the mother cell wall. The anterior of the cell contains an ovoid headpiece anchoring two slightly staggered basal bodies that are positioned above and directly in front of approximately 30 linearly arranged mitochondria. An elongated stellate pattern occupies the transition zone between the BBs and axonemes. Flagella emerge from the cell just in front of the nucleus and encircle the full length of the spermatozoid. The spline comprises a maximum of 38 microtubules surrounding the anterior mitochondria and gradually decreases posteriorly to a minimum of 11. The dense nucleus is narrow, cylindrical, and occupies the central revolution of the cell. Six starch-laden plastids and associated mitochondria are linearly arranged at the cell posterior. Phylogenetic analyses of charalean taxa and archegoniates based on spermatogenesis strongly support the orderCharales, withNitella as the sister group toChara. Diagnostic features ofChara spermatozoids include absence of a lamellar strip and axonemes embedded in the cell for almost the entire length of the anterior mitochondria. Potential relationships amongCharales, Coleochaetales and archegoniates are evaluated in regards to the probable course of evolution of streamlined biflagellated gametes.     

The Embryogeny of Cryptomeria fortunei

The embryogeny of Cryptomeria fortunei was observed. By the middle of March the nucleus of functioning megaspore divides twelve times to form about 3000–4000 free nuclear female gametophyte. Wall formation is centripetal. By the end of May the archegonial complex containing 12–16 archegonia surrounded by jacket layer is present at the micropylar end of the gametophyte. The pollen grains are shed at the uninucleate stage. After pollination the pollen grains swell. The microspore nucleus moves to one side and divides to form a large generative nucleus and a small tube nucleus, The generative cell then divides to form a body cell and a stalk cell. When the pollen tube passed through the nucellus and reached the archegonial complex the nucleus of the body cell divides to form two male cells, generally only one of which enters the arehegonium and the fertilization takes place in the upper part of an egg cell. A number of eggs in an archegonial complex may be fertilized. After the fusion of the male nucleus with the egg nucleus, the zygote divides three times to form eight nuclei, which become organized into primary embryo cells and the open tier. The former are only two or three cells, while the latter has five or six cells open towards the top and divides to form the prosuspensor tier and the upper tier. Thus, the pro-embryo of Cryptomeria belongs to the standard type, according to Doyle (1963). Excepting the simple polyembryony, the cleavage polyembryony is a common character in the embryogeny of Cryptomeria. The mature embryo consists of the radicle, the hypocotyl, the plumule and three cotyledons. When the embryogeny of Cryptomeria fortunei is compared with that of C. japonica, there are many differences obtained. The number of archegonia in the archegonial complex of C. fortunei is less than that of C. japonica. The former does not form the archegonial chamber and the chalazal and lateral archegonia, while the latter does.     

樟子松大孢子的发生和雌配子体的形成过程

樟子松大孢子母细胞经一系列变化,发育成雌配子体。在哈尔滨地区樟子松大孢子母细胞于每年6月8～14日形成,接着进行减数分裂,于6月16～20日形成大孢子。随着大孢子核的分裂,进入游离核时期,并于次年5月28日～6月4日形成细胞壁,幼雌配子体中出现颈卵器原始细胞,它分裂一次形成颈细胞和中央细胞。6月7～9日中央细胞分裂成卵细胞和腹沟细胞,6月13～15日颈卵器发育成熟。成熟的颈卵器含有颈细胞、腹沟细胞和卵细胞,但颈细胞和腹沟细胞已经退化。     

Intergeneric pollen – megagametophyte relationships of conifers in vitro

 Germinating pollen from larch (Larix occidentalis), Sitka spruce (Picea sitchensis) and white pine (Pinus monticola) were co-cultured with megagametophytes dissected from cones of other genera (Pseudotsuga menziesii, Larix×eurolepis and Pinus monticola). Pollen was presented to megagametophytes possessing archegonia which were either alive, degenerating or dead. In addition, pollen was presented to fertilized megagametophytes and to megagametophytes that had been cut in half. Megagametophyte penetration by pollen tubes and male gamete release into archegonia were verified by serial sections of glycomethacrylate-embedded specimens. Pollen tubes penetrated through any part of the apex of the megagametophyte. Division of the body cell into the two gametes was regularly observed. Delivery of gametes was confirmed between spruce and larch. Pollen tubes also penetrated fertilized megagametophytes, dead or degenerating archegonia as well as wounded and/or cut surfaces. This demonstrates the inability of the male gametophyte to optimize its mating efforts, since it is unable to differentiate between healthy and unhealthy archegonia. The megagametophyte cells are unable to optimize male selection. They may produce secretions of a generally attractive nature, as pollen is attracted to the apex of the megagametophyte, but archegonia themselves do not produce pollen-specific signals of either a promotive or inhibitory nature. These results open new avenues for the development of novel breeding strategies where natural breeding barriers may be bypassed. Received: 19 March 1998 / Accepted: 29 April 1998     

Ultrastructural studies of spermatogenesis inAnthocerotophyta V. Nuclear metamorphosis and the posterior mitochondrion ofNotothylas orbicularis andPhaeoceros laevis

Summary Ultrastructural observations reveal that the spermatozoids of the hornwortsNotothylas andPhaeoceros contain two mitochondria and not one as described previously. Mitochondrial ontogeny and nuclear metamorphosis during spermiogenesis in these plants differ from all other archegoniates. The discovery that the posterior region of the coiled nucleus (when viewed from the anterior aspect) lies to the left of the anterior, in striking contrast to the dextral coiling of the nucleus of spermatozoids of other embryophytes, underlines the isolated nature of the hornworts among land plants. As the blepharoplast develops, the numerous ovoid mitochondria initially present in the nascent spermatid fuse to form a single elongated organelle which is positioned subjacent to the MLS and extends down between the nucleus and plastid. At the onset of nuclear metamorphosis, the solitary mitochondrion has separated into a larger anterior mitochondrion (AM) associated with the MLS and a much smaller posterior mitochondrion (PM) adjacent to the plastid. The PM retains its association with the plastid and both organelles migrate around the periphery of the cell as the spline MTs elongate. By contrast, in moss spermatids, where mitochondria undergo similar fusion and division, the AM is approximately the same size as the PM and the latter is never associated with the spline. As in other archegoniates, except mosses, spline elongation precedes nuclear metamorphosis in hornworts. Irregular strands of condensed chromatin compact basipetally to produce an elongated cylindrical nucleus which is narrower in its mid-region. During this process excess nucleoplasm moves rearward. It eventually overarches the inner surface of the plastid and entirely covers the PM.Abbreviations ABB anterior basal body - AM anterior mitochondrion - LS lamellar strip - MLS multilayered structure - MT microtubule - PBB posterior basal body - PM posterior mitochondrion     

Paternal cytoplasmic transmission in Chinese pine (Pinus tabulaeformis)

Summary. In this paper, the stages of normal sexual reproduction between pollen tube penetration of the archegonium and early embryo formation in Pinus tabulaeformis are described, emphasizing the transmission of parental cytoplasm, especially the DNA-containing organelles – plastids and mitochondria. The pollen tube growing in the nucellus contained an irregular tube nucleus followed by a pair of sperm cells. The tube cytoplasm contained abundant organelles, including starch-containing plastids and mitochondria. The two sperm cells differed in their volume of cytoplasm. The leading sperm, with more cytoplasm, contained abundant plastids and mitochondria, while the trailing one, with a thin layer of cytoplasm, had very few organelles. The mature egg cell contained a great number of mitochondria, whereas it lacked normal plastids. At fertilization, the pollen tube penetrated into the egg cell at the micropylar end and released all of its contents, including the two sperms. One of the sperm nuclei fused with the egg nucleus, whereas the other one was retained by the receptive vacuole. Very few plastids and mitochondria of male origin were observed around the fusing sperm and egg nuclei, while the retained sperm nucleus was surrounded by a large amount of male cytoplasm. The discharged tube cytoplasm occupied a large micropylar area in the egg cell. In the free nuclear proembryo, organelles of maternal and paternal origins intermingled in the neocytoplasm around the free nuclei. Most of the mitochondria had the same features as those of the egg cell, but some appeared to be from sperm cells and tube cytoplasm. Plastids were obviously of male origin, with an appearance similar to those of the sperm or tube cells. After cellularization of the proembryo, maternal mitochondria became more abundant than the paternal ones and the plastids enlarged and began to accumulate starch. The results reveal the cytological mechanism for paternal inheritance of plastids and biparental inheritance of mitochondria in Chinese pine. Correspondence and reprints: State Key Laboratory of Plant Physiology and Biochemistry, College of Biological Science, China Agricultural University, Beijing 100094, People’s Republic of China.     

An unusual archegonium with persistent ventral canal cell in Physcomitrium cyathicarpum Mitt. — an ultrastructural study

Abstract

An unusually persistent ventral canal cell has been observed in a few archegonia of Physcomitrium cyathicarpum Mitt. Ultrastructural investigations revealed a close similarity between the ventral canal cell and the egg. The similarity in fine structure of these cells provides support for the idea that the ventral canal cell is an abortive egg.     

Ultrastructural characterization and three-dimensional reconstruction of isolated maize (Zea mays L.) egg cell protoplasts

Summary Isolated egg cell protoplasts ofZea mays L., inbred line A 188, have been studied at the transmission electron microscope level. Their preparation for electron microscopy has been performed by embedding in ultra-low gelling agarose as a preliminary step. Five isolated egg cell protoplasts were serially ultrathin sectioned and studied in detail. One of these protoplasts was reconstructed in three dimensions to provide additional information on its structure. After enzymatic digestion and microdissection, isolated egg cells are true, highly vacuolized protoplasts. The structure of their organelles agrees with in situ observations, indicating an ultrastructural intactness after isolation: the mitochondria are polymorphic, form reticulate networks, and have well developed cristae; the plastids contain starch grains; and the spherical nucleus is euchromatic. As in situ, the organelles of the isolated egg cell protoplasts are aggregated near the nucleus. The complete picture provided by this work should serve as a comparative base for studies on in vitro fertilization products.     

Secretions from the female gametophyte and their role in spermatozoid induction in Cycas revoluta

In cycads, spermatozoids are released from pollen tubes and swim in fluid toward the archegonia. The source of this fluid was examined using Cycas revoluta Thunb. ovules placed in culture. Dissected female gametophytes just before fertilization produced copious fluid on their upper surface. The fluid first appeared around the archegonial chamber and then on the inside of the archegonial chamber. When this fluid was applied to dry turgid pollen tubes, they discharged spermatozoids 12 h later. The archegonial neck appeared as two semi-spherical swellings, whereas the four neck cells later became visible and they separated in a schizogenous manner. Many globose particles appear on the top of the archegonial neck cells when the fluid is present. The contents of pollen tubes, spermatozoids and surrounding liquid intermingle with the secreted fluid. The female gametophyte differs in ultrastructure during the stages before and after fluid secretion, the latter showing changes suggestive of fluid secretion from the female gametophyte.     

Studies in Fertilization of Fokienia

Material of Fokienia hodginsii was collected in 1964 from Fengyangshan (alt. 1000–1400 M) in Lungchuan county, Chekiang province. This paper deals with the fertilization in Fokienia. It includs the structure of male and female gametes as wed1 as the process of fusion of their nuclei and cytoplasm respectively. The division of the spermatogenous cell of Fokienia occurred by the end of June (1964) and two sperms similar in shape and size were formed when pollen tube reached the top of archegonia. Two equalsperms look like two hemispherical bodies conjoined togather. The sperm possesses cell wall and is about 65 μ in diameter. Its nucleus is rather large and about 45–50 μ in diameter. There is a nucleolus in the nucleus. Outside the nucleus the dense cytoplasm forms the deep colored zone, some 10 μ in thickness. This zone is separated from the nucleus by a narrow perinuclear zone, and from the plasmalemma by a marginal zone. The perinuclear zone is about 2 μ thick, and the mariginal zone is from 3 to 4 μ thick. Both zones have transparent cytoplasm. When the archegonium is formed, the central cell has a small nucleus which is located below the neck ceils. At the middle of June (1964), the central cell divides to form the ventral nucleus and the egg nucleus. The egg nucleus sites primarily at the upper part of archegoninm and has only one nucleolus. Then the egg nucleus increases gradually in sim and moves to the central part of the archegoninm. In mature archegonium there are usually 4–5, rarely 6–7 nucleoli in the egg nucleus, each of them is about 15 μ in diameter. The egg cell in Fokienia hodginsii is about 500 in length. The female nucleus is larger than the male one. After egg cell matures, its cytoplasm increases gradually, while the central vacuole decreases gradually and almost disappears completely after fertilization. It is interesting to note that there are 1–2 dense cytoplasm masses at the upper or lower part of egg nucleus. The shape of the mass is similar to that of the egg nucleus but no membrane is formed. These cytoplasm masses are about 50–70 μ in diameter in some cases. The fertilization of Fokienia took place at the end of June when the growing tip of pollen tube had reached the top of the archegoninm. Then the neck cells become disorganized and degenerated. It is possible that all the cytoplasmic contents of pollen tubes are released into the archegoninm. Before fertilization, the cytoplasm around the sperms and sterile cell and tube nucleus are in front of these two sperms. Then the sperms separate from each other and come down into the cytoplasm of the egg. When the mede nucleus contacts with the egg nucleus, both become flattened along their contact surface. Then the nuclear membranes of both sperm and egg nuclei become ultimately disintegrated. Thus the fusion process is complete. However, it is nia, though the opposite is the case in an exceptional example. When the sperm nucleus passes into the cytoplasm of egg cell, its cytopasm is released inside the archegonium along with it. During the course of fusion of the male and female nuclei, tile fertilized nucleus is surrounded by both female and male cytoplasm. Thus the male cytoplasm along with the peripheral cytoplasm of the egg cell invests the two nuclei lying in contact and forms a dense neocytoplasm. When the zygote divides, the neoeytoplasm is full of the starch grains and a dense cytoplasm sheath is formed. After fertilization, the fused nucleus moves toward the base of the egg cell. It seems that the movement of the fused nucleus is not a simple mechanical movement but turned over repeatedly toward the base of the arehegonium. Sometimes the position of the sperm and egg nuclei makes a turn of 180. At the same time the track of the fertilized egg nucleus with vacuoles in the archegonium may be traced. After zygote moves into basal part of the archegonium, first intranuclear mitosis occurs. The nuclear envelop of zygote disappears gradually at the telophase of the first mitosis. Then division of the free nuclei of proembryo follows. From fertilization to the stage of proembryo formation, the second sperm may sometimes enter into the cytoplasm of the egg cell. Mitosis of the second sperm nucleus may take place in the upper part of the archegonium. In addition, there are often several supernmnerary nuclei (as many as 7–8 in number) in the same egg cell. These nuclei are also surrounded by dense cytoplasm. They may persist for some time and be recognizable at somewhat later stages of the proembryo or even after the elongated suspensors are formed. In some cases, there are some cell groups above the upper tier of proembryo. These cell groups are also surrounded by dense cytoplasm. Either the supernumerary nuclei or cells are surrounded by the dense cytoplasm. Probably they are derived from the mitosis or amitosis of the second sperm. Investigations on submicroscopic structures of sperm and egg in relation to the fertilization of Cupressaceae have been carried out extensively during the last decade. The fate of male cytoplasm has been debated for a long time and this problem attracted attention again in the nineteen seventies. At last the concept of neocytoplasm has been established soundly based upon the information from observation of electron microphotographs. The neocytoplasm is also visible under the light microscope though the components are not recognizable. The sperms of Fokienia are similar to those of Cupressus funebris, Juniperus communis, Sabina virginiana, Tetraclinis articulata, Chamaecyparis pisifera as well as the genus Thujopsis and others. Two sperms are all effective in fertilization and this is the common phenomenon of the family Gupressaceae.     

THE OCCURRENCE AND PHYLOGENETIC SIGNIFICANCE OF A MULTILAYERED STRUCTURE IN COLEOCHAETE SPERMATOZOIDS

Spermatozoid-forming cells of Coleochaete scutata were found in packets of four arranged in concentric internal bands. Spermatozoids, which occur singly in antheridial cells, are spherical to ovoid, approximately 7 μm long by about 3.9 μm wide. As compared to relatively unspecialized zoospores, male gametes undergo a number of specialized cellular changes during development. The spherical nuclei and cytoplasm of mature spermatozoids are increased in density. Posterior plastids are reduced and contain large starch grains. Many small mitochondria are clustered near the cell anterior. The plasmalemma is covered with a layer of flattened, diamond-shaped scales, while body scales of zoospores are pyramidal. The two flagella of both zoospores and spermatozoids are covered with flattened, diamond-shaped scales and hairs. The spermatozoids contain an anterior multilayered structure (MLS) structurally similar to, though smaller than, the MLS observed in zoospores. An asymmetrical cytoskeleton consisting of a band of 30–45 microtubules extends from the MLS down one side of the spermatozoid close to the plasmalemma. An immature MLS was observed in an early stage of spermatozoid development. The finding of an MLS and asymmetrical cytoskeleton in specialized male gametes as well as relatively unspecialized zoospores of Coleochaete strengthens assumptions of homology between MLSs of green algal reproductive cells and those found in flagellated spermatozoids of archegoniate plants. The structure of the spermatozoid of Coleochaete supports the hypothesis that this alga may be relatively close to the phylogenetic line which led directly to archegoniates.     

红松配子体的发育过程

红松是我国主要用材树种,材质优良。我国主要分布在长白山和小兴安岭,随着森林工业的发展,大面积的原始森林迅速减少,人工更新日趋重要。在生产中采用种子育苗,因此对红松种子的发育规律应全面掌握,以便为种子园建立、良种选育采取有效措施提供理论依据。根据国内外有关报导,红松雌雄配子的形成、受精作用已有一定的研究^[14、15],但这些研究只侧重在小孢子母细胞的减数分裂和受精作用。故对雌雄配子体的发育过程仍需深入研究,尤其是授粉后的雄配子体发育和精子进入颈卵器的过程,均未见详细报导。     

FERTILIZATION IN OEDOGONIUM. III. KARYOGAMY

Karyogamy is described in Oedogonium cardiacum from ultrastructural studies. Close proximity of the two gamete nuclei in the fusion cell is established by plasmogamy, whereas karyogamy appears to be initiated by multiple contacts formed between the outer membranes of the adjoining nuclear envelopes. Blebs of endoplasmic reticulum (ER) originate from the outer membrane of each nuclear envelope; these ER blebs presumably contact and fuse with the outer membrane of the nuclear envelope of the opposing nucleus. This is followed by the fusion of the inner membranes of the opposing nuclear envelopes, thereby resulting in a series of small connective bridges between the two gamete nuclei. It is estimated that in this manner 30–50 bridges are formed, perhaps many more. Several of these bridges enlarge relative to the others; one presumably becomes the major connection between the fusing nuclei. As it continues to enlarge, any organelles positioned between the fusing nuclei are pushed aside. There is also evidence, particularly in later stages of karyogamy, that the smaller connective bridges fuse to form larger ones. Temporary cytoplasmic channels often result at the juncture of fusion. In other instances, isolated inclusions of cytoplasm may be delimited by remnants of nuclear envelope deep within the developing zygote nucleus; these inclusions disappear with subsequent development. Throughout karyogamy the contribution of the male gamete nucleus is readily recognized by the characteristic appearance of its highly condensed chromatin. Ultimately, however, this distinction is lost and the content of the mature zygote nucleus assumes a more uniform appearance very similar to that of an egg nucleus. The complete process of fertilization in Oedogonium may occur within 15 min of mixing the spermatozoids with eggs.     

FERTILIZATION IN OEDOGONIUM. I. PLASMOGAMY12

Events prior to, during, and immediately following plasmogamy have been investigated in Oedogonium cardiacum using combined techniques of light and electron microscopy. Maturation of the oogonium involves the formation of an oogonial pore and the differentiation of the single egg from the larger oogonial protoplast from which it is formed. The fine structure of the sperm cell at the time of plasmogamy is described as well as the nature of its entrance into the oogonium. Cinematographic films were used to analyze the movements of the spermatozoids prior to plasmogamy and, similarly, 26 complete acts of gametic fusion were recorded and analyzed. Prior to plasmogamy the flagella-bearing anterior extremity of the spermatozoid typically becomes elongate and is thereafter capable of flexible movements and rapid changes in shape which appear more or less independent of the rest of the cell. The sperm cell always makes initial contact with the egg surface by means of this agile, proboscis-like, anterior end. Contact results through a combination of thrusting movements of the entire sperm cell and rapid, lateral sweeping movements of its flagellated anterior extremity against the egg surface. Gametic fusion is initiated with violent, vibrational movements of the sperm cell accompanied by loss of its flagella. Apparent fusion of the gamete membranes unites their protoplasts by a narrow cytoplasmic bridge which gradually increases in size as the sperm cell cytoplasm flows into the egg. An average time of 30.5 sec was required for complete fusion as determined from 25 typical sequences of plasmogamy recorded cinematographically. Fusion occurs even more rapidly when diploid oogonia are substituted for daploid oogonia. The entire sperm cell, with the exception of the flagella, fuses with the egg during plasmogamy. The dissimilar gamete nuclei are clearly distinguished ultrastructurally in the binucleate fusion cell. Concentrations of sperm cell mitochondria and remains of the flagellar apparatus (but no flagella) are readily recognized in the fusion cell. The fate of these and other cytoplasmic constituents of the sperm cell is discussed. Immediately after plasmogamy, and prior to karyogamy, a thin, finely fibrous layer is formed us an investment exterior to the fusion cell. Karyogamy follows shortly after plasmogamy, and both events may take place within 15 min after mixing eggs and spermatozoids.     

The Gametophytes and Fertilization in Pseudotaxus

The development of the gametophytes and fertilization of Pseudotaxus chienii Cheng has been investigated. Pollination first occurred on April 17 (1964). The pollen grains shed at the uninucleate stage and germination on the nucellus is almost immediate. The pollen tubes approached the freenucleate female gametophyte about May 5. The spermatogenous cell is continuously enlarging with the growth of the pollen tube and two unequal sperms are formed after its division. Occasionally the small sperm may divide further into two smaller ones. During pollination the megaspore mother cell is in meiosis and 3 or 4 megaspores are formed. Generally 2 or 3 megaspores at the micropylar end are going to degenerate while the chalaza] megaspore is rapidly enlarging. After 8 successive simultaneous divisions of the functional megaspore 256 free nuclei are resulted and they are evenly distributed at the bulge of the famale gametophyte. Then the wall formation follows. Sometimes there are more than two, even as many as 5–6 gametophytes developed within a single ovule. The archegonial initials become differentiated at the apical end of the female gametophyte. They are usually single and apical, rarely lateral in position. The number of the archegonia vary from 3 to 7, usually 4–6. There are 2–8 neck cells in each archegonium which is surrounded by a layer of jacket cells. The central cell divided about May 20–26 (1964) and the division of the central cell gives rise to the egg and the ventral canal nucleus, the latter being degenerated soon. There are many proteid vacuoles near the nucleus of the matured egg. The fertilization took place about May 23–26 (1964). At first, the pollen tube discharges its contents into the egg, then the larger sperm fuses with the egg nucleus in the middle part of the archegonium. At the same time the male cytoplasm also fuses with the female cytoplasm and a layer of densely-staining neocytoplasm is formed around the fused nucleus. The smaller sperm, tube nucleus and sterile cell usually remain in the cytoplasm above the egg nucleus for some time. Based upon the observations of the development of the gametophytes and fertilization the authors conclude that Pseudotaxus is more close related to Taxus than any other member of Taxaceae.     

CYTOLOGICAL BASIS FOR CYTOPLASMIC INHERITANCE IN PSEUDOTSUGA MENZIESII. II. FERTILIZATION AND PROEMBRYO DEVELOPMENT

Douglas fir (Pseudotsuga menziesii [Mirb.] Franco) ovules were used to study male gamete formation, insemination of the egg, and free nuclear and cellular proembryo development. Two male nuclei form as the pollen tube either reaches the megaspore wall or as it enters the archegonial chamber. No cell wall separates them. They are contained within the body-cell cytoplasm. A narrow extension of the pollen tube separates the neck cells and penetrates the ventral canal cell. The pollen tube then releases its contents into the egg cytoplasm. The two male gametes and a cluster of paternal organelles (plastids and mitochondria) migrate within the remains of the body-cell cytoplasm toward the egg nucleus. Microtubules are associated with this complex. The leading male gamete fuses with the egg nucleus. The zygote nucleus undergoes free nuclear division, but the cluster of paternal organelles remains discrete. Free nuclei, paternal and maternal nucleoplasm, maternal perinuclear cytoplasm, and the cluster of paternal organelles migrate en masse to the chalazal end of the archegonium. There, paternal and maternal organelles intermingle to form the neocytoplasm, the nuclei divide, and a 12-cell proembryo is formed. The importance of male nuclei or cells, the perinuclear zone, and large inclusions in cytoplasmic inheritance are discussed in the Pinaceae and in other conifer families. This completes a two-part study to determine the fate of paternal and maternal plastids and mitochondria during gamete formation, fertilization, and proembryo development in Douglas fir.