Embryological Studies on Apomixis in Pennisetum squamulatum

Studies on the formation and development of the embryo sac of the apomictic material of Pennisetum squamulatum Fresen indicated that normal archesporial cell did form with consequent development of a megaspore mother cell and later meiotic division to give rise to a triad. But invariably the megaspore mother cell and the triad underwent degeneration after formation. During the period of formation or degeneration of the megaspore or the triad a number of nucellar cells around the degenerated sexual cell became much enlarged. Frequently, one of the enlarging nucellar cells near the micropylar end became vacuolated and then developed into an aposporous uninucleate embryo sac, which underwent two further mitotic divisions to form an aposporous four-nucleate embryo sac, where the four nuclei remained in the micropylar end. Thus in the mature aposporous embryo sac there were one egg cell, one synergid and one central cell (containing two polar nuclei). Antipodal cells were completely lacking. The pattern of development of the aposporous embryo sac resembles the panicum type. There were two types of embryo formed during apomictic development namely ( 1 ) The pre-genesis embryo--embryo formed without fertilization, 1 to 2 days before anthesis, and (2) The late-genesis embryo--derived from the unfertilized egg cells, 3 to 4 days after anthesis. In the late-genesis embryo type, the egg cell divided after the secondary nucleus has undergone division to form the endosperm nuclei. All egg cells developed vacuoles before they differentiated into embryos. The development of the aposporous embryo followed the sequence of the formation of globular, pearshaped embryo and full stages of differentiation. The unfertilized secondary nucleus divides to form free endosperm nuclei after being stimulated by pollination. The development of the endosperm belongs to the nuclear-type.     

Origin of Megagametophytes with Supernumerary Egg Cells Occurring in Oryza sativa

Cytoembryological observations were attempted to reveal the cytological origin of megagametophyte with supernumerary egg cells. It was shown that all ovules underwent a normal megasporogenesis. The meiosis of megasporocyte consisted of two successive divisions, which gave rise to four haploid megaspores. It was the chalazal spore that developed to form the megagametophyte while the three micropylar megaspores degenerated quickly. After first mitosis in the functional megaspore the two nuclei were separated to the micropylar and chalazal poles by a large central vacuole, meanwhile a differential enlargement of the two-nucleate embryo sac was visualized. The micropylar side enlarged quickly and in contrast, the chalazal side remains almost unchanged. Immediately afterward, the second mitosis took place forming four-nucleate embryo sac. During the second mitosis, nucleus located in the narrow area of chalazal side divided transversely, with its upper sister nucleus migrating to the central or micropylar part of the embryo sac, while the nucleus in the micropylar side divided at an angle of about 45° against the micropylar-chalazal axis. Through the third mitosis, two patterns of nuclear arrangement deviating from polygonum were observed. (i) One nuclear distribution pattern was two, two, four respectively in chalazal, central and micropylar parts. And during maturation the four micropylar nuclei differentiated as egg apparatus consisting of two egg cells and two synergids. The two central nuclei, which presumably suppressed the movement of nucleus toward centre part from both micropylar and chalazal sides developed into central cell with two polar nuclei. And the two chalazal nuclei organized into antipodal cells. Rarely indeed, one nucleus of either chalazal or micropyle side did migrate to join the formation of central cell. (ii) The other nuclei arrangement pattern was two and six respectively positioned in chalazal and micropylar sides. During maturation, five micropylar nuclei differentiated into egg apparatus consisted of three egg cells and two synergids. The sixth one migrated to form the upper polar nucleus. The lower nucleus of the chalazal side developed into antipodal cell which divided quickly, and the upper nucleus became the lower polar nucleus.     

Ovule,Female and Male Gametophyte and Fertilization of Kingdonia uniflora Balfour F. et W. W. Smith

The structure of ovule, female and male gametophyte, double fertilization and the distrubution of starch grains during the fertilization have been studied. The main results are as follows: ( 1 ) Ovule The ovule is anatropous, unitegmic and tenuinucellate. The nucetlus appears cylindric, since megaspores and embryo sac development, its internal cells of nucellus become disorganized, so that only a single layer of epidermal cells remains toward the side of the micropyle, On the other hand, the integument is not as long as nucellus, as a result micropyle is not formed. And no vascular bundle is found in the integument. (2) Female gametophyte The mature embryo sac is slender and is composed of an egg cell, two synergids, a central cell and three antipodal cells. The egg cell is situated slightly away from the tip of embryo sac. Some of them contain starch grains. Synergids occupy the tip of embryo sac. Its wall at micropylar region appears irregular in thickenes and irregular in ingrowths to form the filiform apparatus. The centrateell is very large, and strongly vacuolated Two polar nuclei come to contact closely with each other, but not fuse, or to fuse into a large secondary nucleus before fertilization. The polar nuclei or the secondary nucleus are usually situated at the middle-lower position of the central cell or nearer to the chalazal end above the antipodal cell. It is different from egg cell, no starch grains are found here. In most embryo sacs three antipodal cells are found. They are not as large as those in other plants of Ranunculaceae. But six antipodal cells or the antipodal cell with two nuclei may rarely be found. Like synergid, the wall of them appears not only irregularly thickened, but clearly with irregular ingrowths. In a few antipodal cells the starch garins are usually found near the nucleus. By the end of fertilization, antipodal cells become disintegrated. (3) Male gametophyte Most pollen grains are two-celled when shedding, and rich in starch grains. A few of them contain single nucleus or three-celled. (4) The double fertilization The fertilization of Kingdonia unifiora Balfour f. et W, W. Smith is wholly similar to some plants of Ranunculaceae studied. First, the pollen tube penetrates a degenerating synergid. And the pollen tube discharges its contents with two sperm nuclei into the degenerating synergid cell. One of the two sperms fuses with the nucleus of the egg, and the other fuses with two polar nuclei or the secondary nucleus of the central cell. If one sperm nucleus at first fuses with one of the polar nuclei, and then the fertilized polar nuclei again fuses with other polar nucleus. Secondly, the fertilization of the polar nuclei or the secondary nuclei completes earlier than that of the egg. The primary endosperm nucleus begins to divide earlier than the zygote. It seems that one of the sperm nuclei come to contact with egg nucleus, the other has already fused with polar nuclei or the secondary nucleus. The zygote with a single nucleolus appears until the endosperm with 16–20 cell. Thirdly, before and after fertilization there are one to some small nucleoli in egg nucleus and polar nuclei or secondary nucleus. However they increase in quantity from the beginning of the fusion of male nucleis. These nucleoli quite differ from male nucleoli by their small size, and most of them disappear at the end of fertilization. It may be concluded that the small nucleoli increase in quantity is related to the fusion of male and female nuclei. In the duration of fertilization, in ovule starch distribution is in the basal region of integument. But in embryo sac, onlysome egg cells, or zygotes contain starch grains, a part of which was brought in by pollen tube. Sometimes the starch grains are found in some synergids and antipodal cells. No starch grains are found in the central cell.     

Fertilization and Histochemical Investigation on Pulsatilla chinensis (Bung) Regel

Fertilization and variation of protein and starch grains in Pulsatilla chinensis (Bung) Regel have been studied at light microscopic level with histochemical test. Based upon the observations, the main conclusions are summarized as follows: The mature pollen grains are two-celled in which the generative cell shows the stronger protein staining than the vegetative cell. And vegetative cells are full of starch garins. When the pollen tube enters into the embryo sac, one synergid is destroyed, or in a few cases synergids are intact. Occasionally two synergids are disorganized as pollen tube penetrates. However, most of the remaining syuergids break down during fertilization, only in a few cases it remains till early stage of embryo development. The contents discharged by the pollen tube consist of two sperms, which stain intensely blue with protein dyes, a great amount of protein and starch grains. Mature female gametophyte (embryo sac) consists of an egg apparatus, central cell, which has a huge secondary nucleus, and antipodal apparatus which retain in course of fertilization. A few of embryo sac contain two sets of egg apparatus, a central cell with two huge secondary nuclei and two sets of antipodal apparatus. In some nucleoli of the central cell the comb-like structure pattern may be detected clearly. There are 1–2 small nucleoli in some egg cells and central cells. All the cells in embryo sac show protein positive reaction. According to the different shades of the color in cells, its may be arranged in the following order: antipodal cells, synergids, central cell and egg cell. Only a few small starch grains are present near nuclei of central cell and egg cell before fertilization, but no starch grains remain in most of the central cell, the synergids and antipodal cells. The fertilization is of the premitotic type. The fusion of the sexual nuclei progresses in the following order: 1, sperms approach and lie on the egg nucleus and secondary nucleus; 2, sperm chromatin sinks themselves into female nucleus, and male nucleolus emerges with the sperm chromosome; and 3, male nucleoli fuse with the nucleoli of egg nucleus and central cell nucleus, and finally forming the zygote and the primary endosperm cells respectively. Nevertheless, as it is well known, the fertilization completes in central cell obviously earlier than that in egg cell. Though it has been explained in cereals and cotton, in Pulsatilla chinensis the main reason is that nucleolar fusion of the male and female nucleoli in egg nucleus is slower than that in secondary nucleus. And the dormancy of the primary endosperm nucleus is shorter than that of the zygote. In the process of fertilization, histochemical changes are considerably obvious in the following three parts: 1, from the begining of fusion of male and female nuclei to form zygote and primary endosperm cell, Protein staining around female nucleus appears to increase gradually; 2, no starch grains are detected in embryo sac. Though only starch grains are carried in by pollen tube, they are completely exhausted during this period; and 3, near completion of fertilization starch grains appear again in zygote, however, not yet in primary endosperm nucleus till its dividing for the first time. The present study reveals that antipodal cells and synergids seem to play a significant role in nutrition of the embryo sac during the fertilization.     

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.     

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.     

云南油杉受精过程中新细胞质及蛋白泡的动态观察

云南油杉(Keteleeria evelyniana Mast)在受精前,精核与卵核周围的细胞质鞘不明显。受精后,合子核周围出现细密的新细胞质。应用孚尔根核染色法,可以较清晰地将新细胞质染出,呈现较弱的正反应,而合子的核质及受精前的精核与卵核染色极弱。卵细胞质及其中的蛋白泡均为负反应。原胚形成后,除上层外,其余几层细胞质内开始积累淀粉粒。此时胚原细胞核的孚尔根染色深度有所增加。幼胚形成后,在顶端的胚原细胞群中核的孚尔根染色反应已恢复正常。在原胚及幼胚胚原细胞质中也呈现很弱的正反应。在电镜下,胚原层细胞质及新细胞质中均含有核样电子致密小体或称作染色质小体,而原胚莲座层细胞质及四周套细胞质中的线粒体则不含这种核样小体。因此,大蛋白泡在卵核形成的早期数量不多,当合子形成时含量最高,而随着游离核的分裂进程,蛋白泡以及原卵质均逐渐地解体,在原胚形成后全部消解。     

甜菜无融合生殖单体附加系M14 成熟胚囊的超微结构特征

以甜菜无融合生殖单体附加系M14(Beta vulgaris, 2n=18+1)为实验材料, 利用电子显微镜技术对成熟胚囊及其超微结构进行研究。结果表明: M14成熟胚囊包括1个卵细胞、2个退化的助细胞、1个具有次生核的中央细胞和3-6个反足细胞。其卵细胞具有3种不同的形态: (1)极性正常的卵细胞, 细胞核位于合点端, 细胞质含有大量核糖体、线粒体、内质网等细胞器; (2)细胞核位于细胞中央; (3)细胞核位于珠孔端, 且后2种形态细胞器的种类与数量少。大多数胚囊中的2个助细胞在开花前已退化。中央细胞的次生核位于反足细胞附近; 未经受精自发分裂前的卵细胞与中央细胞的细胞核大、核仁明显, 细胞器的种类与数量多, 呈现旺盛代谢活动特征, 成为二倍体孢子无融合生殖过程中, 卵细胞与次生核自发分裂的细胞学标志。     

甜菜无融合生殖单体附加系M14成熟胚囊的超微结构特征

以甜菜无融合生殖单体附加系M14（Betavulgaris,2n=18＋1）为实验材料,利用电子显微镜技术对成熟胚囊及其超微结构进行研究。结果表明：M14成熟胚囊包括1个卵细胞、2个退化的助细胞、1个具有次生核的中央细胞和3-6个反足细胞。其卵细胞具有3种不同的形态：（1）极性正常的卵细胞,细胞核位于合点端,细胞质含有大量核糖体、线粒体、内质网等细胞器;（2）细胞核位于细胞中央;（3）细胞核位于珠孔端,且后2种形态细胞器的种类与数量少。大多数胚囊中的2个助细胞在开花前已退化。中央细胞的次生核位于反足细胞附近;未经受精自发分裂前的卵细胞与中央细胞的细胞核大、核仁明显,细胞器的种类与数量多,呈现旺盛代谢活动特征,成为二倍体孢子无融合生殖过程中,卵细胞与次生核自发分裂的细胞学标志。     

水稻胚囊超微结构的研究

水稻(Oryza sativa L.)胚囊成熟时,卵细胞的合点端无细胞壁,核居细胞中部,细胞器集中在核周围,液泡分散于细胞周边区域。助细胞珠孔端有丝状器,合点端无壁,核位于细胞中部贴壁处,细胞器主要分布在珠孔端,液泡主要分布在合点端。开花前不久,一个助细胞退化。中央细胞为大液泡所占,两个极核靠近卵器而部分融合,细胞器集中在极核周围和靠近卵器处,与珠心相接的胚囊壁上有发达的内突。反足细胞多个形成群体,其增殖主要依靠无丝分裂与壁的自由生长,反足细胞含丰富活跃的细胞器,与珠心相接的壁上有发达的内突。开花后6小时双受精已完成,合子和两个助细胞合点端均形成完整壁。合子中开始形成多聚核糖体、液泡减小。退化助细胞含花粉管释放的物质,其合点端迴抱合子。极核已分裂成数个胚乳游离核,中央细胞中细胞器呈活化状态。反足细胞仍在继续增殖。讨论了卵细胞的极性、助细胞的退化、卵器与中央细胞间界壁的变化、反足细胞的分裂特点等问题。     

Initiation of DNA replication in nuclei from quiescent cells requires permeabilization of the nuclear membrane

We have investigated the replication capacity of intact nuclei from quiescent cells using Xenopus egg extract. Nuclei, with intact nuclear membranes, were isolated from both exponentially growing and contact- inhibited BALB/c 3T3 fibroblasts by treatment of the cells with streptolysin-O. Flow cytometry showed that > 90% of all contact- inhibited cells and approximately 50% of the exponential cells were in G0/G1-phase at the time of nuclear isolation. Intact nuclei were assayed for replication in the extract by incorporation of [alpha- 32P]dATP or biotin-dUTP into nascent DNA. Most nuclei from exponential cells replicated in the egg extract, consistent with previous results showing that intact G1 nuclei from HeLa cells replicate in this system. In contrast, few nuclei from quiescent cells replicated in parallel incubations. However, when the nuclear membranes of these intact quiescent nuclei were permeabilized with lysophosphatidylcholine prior to addition to the extract, nearly all the nuclei replicated under complete cell cycle control in a subsequent incubation. The ability of LPC-treated quiescent nuclei to undergo DNA replication was reversed by resealing permeable nuclear membranes with Xenopus egg membranes prior to extract incubation demonstrating that the effect of LPC treatment is at the level of the nuclear membrane. These results indicate that nuclei from G1-phase cells lose their capacity to initiate DNA replication following density-dependent growth arrest and suggest that changes in nuclear membrane permeability may be required for the initiation of replication upon re-entry of the quiescent cell into the cell cycle.     

The Ultracytochemical Localzation of Acid Phosphatase Activity in Wheat During Fertilization

No acid phosphatase activity was observed in the mature embryo sac of wheat (Triticum aestivum) except the chalazal cytoplasm Of the central cell before fertilization. During fertilization, acid phosphataseactivity was observed in the following loci: part of chromatin of the egg nucleus and most of the mitochondria in the egg cytoplasm; the perinuclear spaces of the egg and sperm nuclei at the fusion of the egg and sperm nuclei; the chalazal cytoplasm and some vacuoles of the degenerated synergid; two sperm nuclei within the cytoplasm of female cells; the cell wall of each cell of the embryo sac and that of the nucellar cells surrounding the embryo sac. No acid phosphatase was observed in the two-celled proembryo. Dense enzyme reaction product was localized in the chromatin of the free nuclei at early stage of the endosperm. The characteristic of acid phosphatase distribution during fertilization may be associated with the physiological change of the egg Cell, the reorganization of mitochondria in the egg cell cytoplasm, the degeneration of one of the two synergids, the physiological state of the sperm nuclei and the nuclear membrane fusion of the egg and sperm nuclei.     

SEXUAL REPRODUCTION IN EPHEDRA NEVADENSIS (EPHEDRACEAE): FURTHER EVIDENCE OF DOUBLE FERTILIZATION IN A NONFLOWERING SEED PLANT

Since the initial discovery of double fertilization in angiosperms in 1898, a number of reports of double fertilization-like events in the genus Ephedra have appeared. Until recently, convincing documentation of double fertilization in Ephedra had not been presented. In Ephedra nevadensis, following entry of a single binucleate sperm cell into the egg cell, one sperm nucleus migrates in a chalazal direction to fuse with the egg nucleus. Contemporaneous with this first fertilization event, the ventral canal nucleus regularly migrates from its initially apical position within the egg cell to a more central position within the egg cytoplasm, where it fuses with a second sperm nucleus. Based on quantitative microspectrofluorometric analysis, occasional supernumerary nuclei within the egg cell (derived by migration through pores in the cell walls between jacket cells and the central cell or egg cell) can be ruled out as participating in the second fertilization event. The evolutionary establishment of double fertilization in Ephedra (or its ancestors) was dependent on a number of specific developmental preconditions: 1) persistence of the ventral canal nucleus (which is degenerate in many groups of nonflowering seed plants) through the time of normal fertilization; 2) regular displacement of the ventral canal nucleus from its initially apical position within the egg cell to a position within the egg cytoplasm where fusion of the egg nucleus with the first sperm nucleus earlier occurred; 3) acquisition of egg-like features by the ventral canal nucleus that allow it to attract and fuse with a sperm nucleus; and 4) consistent entry of a second sperm nucleus into the archegonial cavity to participate in a second fertilization event. Although it cannot be determined definitively whether double fertilization in Ephedra is evolutionarily homologous with double fertilization in flowering plants, comparative evidence is consistent with the hypothesis that double fertilization arose in a common ancestor of the Gnetales and angiosperms.     

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。     

Early post-pollination events in hexaploid wheat × maize crosses

Summary Cytological events in the first 12 h after pollination were studied in crosses between the hexaploid wheat genotype Chinese Spring and the maize genotype Seneca 60. A pollen tube was first observed in the embryo sac 4 h after pollination, and maize sperm nuclei were first observed in the embryo sac after 5 h. On 29 occasions two, and on 1 occasion three, pollen tubes penetrated the embryo sac. Four categories of aberration limiting the frequency of fertilization were identified: (1) in 20% of florets no pollen tube reached the embryo sac; (2) in at least 1.9% the pollen tube severely damaged the wheat egg cell and polar nuclei; (3) in 33% the maize sperm nuclei were not released from the pollen tube; and (4) in 16% the sperm nuclei were released into the embryo sac but failed to move to either of the wheat gametes. In the remaining 29% sperm nuclei were more often found in the egg cell than at the polar nuclei. The results suggest that karyogamy occurs with very high efficiency when a sperm nucleus reaches the egg cell, but with only about 50% efficiency when a sperm nucleus reaches the polar nuclei.     

小麦受精过程中酸性磷酸酶的超微细胞化学定位

小麦（Ｔｒｉｔｉｃｕｍ ａｅｓｔｉｖｕｍ ）受精前成熟胚囊,除胚囊中央细胞的合点端细胞质中有酸性磷酸酶外,其余部位均未发现酸性磷酸酶。受精时期,以下部位存在酸性磷酸酶活性：卵细胞的细胞核内一部分染色质和细胞质中大部分线粒体;精、卵核融合时两核的核周腔内;退化助细胞合点端细胞质和一些液泡内;进入雌性细胞中的两个精核;胚囊各成员细胞的细胞壁及胚囊周围珠心细胞的细胞壁。二细胞原胚中未见有酸性磷酸酶。早期胚乳游离核染色质上有酸性磷酸酶。小麦受精过程酸性磷酸酶的分布特点可能与卵细胞生理状态的变化和细胞质中线粒体的改组、助细胞的退化、精核的生理状态以及精核与卵核的核膜融合等有关。     

Cell-cycle dependency of radiosensitivity and mutagenesis in fertilized egg cells of rice,Oryza sativa L.

Summary To determine the time and duration of the first and second DNA synthetic phases in fertilized egg cells and central cells of rice, a total of 753 ovules were sampled at 2 h intervals during the first 30 h after pollination and exposed to ³H-thymidine for 2 h at 25 °C. Autoradiographic observation of labeled nuclei was made for fertilized egg cells, as well as for central and antipodal cells. The first and second DNA synthetic phases in fertilized egg cells were found 8–12 h and 21–25 h after pollination, respectively. The durations of each cell-cycle phase in the egg cell were estimated to be 4–6 h for G₁, 4 h vor S and for G₂, and 2 h for M. In the central cell, the first DNA synthesis took place at 3–4 h after pollination, i.e., immediately after fertilization, followed by the formation of the primary endosperm nucleus. Antipodal cells also showed labeled nuclei in the early stages after fertilization. The first divisions of fertilized egg cell and primary endosperm nucleus were observed at 16–18h and at 4–6 h after pollination, respectively. The present observations suggest that sperm and egg nuclei participate in fertilization with haploid amount (1C) of DNA and fertilized egg cell originates thus in 2C state.     

Polarity of nuclear and organellar DNA during megasporogenesis and megagametogenesis in Plumbago zeylanica

Summary Megasporogenesis and megagametogenesis of Plumbago zeylanica were studied using isolated megasporocytes, megaspores, and embryo sacs labeled with Hoechst 33258 for nuclear and organellar (presumably plastid) DNA. Megasporogenesis conforms to the tetrasporic Plumbago type, producing a coenomegaspore with four megaspore nuclei. Organeller DNA is polarized in the micropylar end of the coenomegaspore and embryo sac, reflecting the site of egg cell formation. The three remaining nuclei are somewhat displaced to the chalazal pole, producing a variable number of accessory cells and a 4N secondary central cell nucleus. Ultimately, the mature embryo sac consists of two to five cells including an egg cell, a central cell, zero to two lateral cells, and zero to one antipodal cell depending on the degeneration of the lateral or chalazal nuclei during megagametogenesis.     

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.     

Occurrence of Mitochondria in the Nuclei of Tobacco Sperm Cells

Tobacco sperm cells contain intact mitochondria within their nuclei with a frequency of 0.35 [plusmn] 0.13 per cell. These inclusions appear to originate from mitochondria found among chromatids in the highly elongated metaphase plate of the dividing generative cell. These organelles are apparently captured during the reconstitution of the nuclear envelope. Only sperm cells were observed to contain these nuclear mitochondria; generative cells, vegetative pollen cells, transmitting tissue cells, unfertilized egg cells, and central cells lacked them. Nuclear mitochondria were also seen in the nuclei of the egg and central cell after fusion with sperm nuclei, suggesting that nuclear mitochondria are transmitted into the zygote and primary endosperm cells during double fertilization. Organellar inclusions in the sperm nucleus provide a potential mechanism for transmitting organellar DNA into the next generation and could potentially facilitate the transfer of genetic material between the nucleus and other organelles.