MEIOSIS IN THE OOMYCETES: I. A MICROSPECTROPHOTOMETRIC ANALYSIS OF NUCLEAR DEOXYRIBONUCLEIC ACID IN SAPROLEGNIA TERRESTRIS

A cytological and cytochemical examination of Saprolegnia terrestris Cookson was undertaken to resolve the conflict of opinion regarding the life cycle of fungi in the Saprolegniaceae, i.e., whether meiosis is zygotic or gametic. Microspectrophotometric analysis reveals that pre-divisional oogonial and antheridial nuclei are 4C; a subsequent reduction division in the sex organs produces 1C male and female gametes. These division products coexist in the developing oospore and presumably fuse to produce the diploid zygote. Analysis of the somatic hyphal nuclei shows a 2C DNA content, with the characteristic skew and bimodal character indicative of predominantly G1, and some S-period and G2 types. The evidence is completely consistent with gametic meiosis, i.e., a predominant diploid vegetative phase and short haploid phase, and refutes the notion of zygotic meiosis. Further ramifications of the work are discussed along with preliminary results of related work in progress.     

THE NUCLEAR CELL CYCLE IN CHLAMYDOMONAS (CHLOROPHYCEAE)1

The timing of replication and division of the Chlamydomonas Ehrenberg nucleus in the vegetative cell cycle and at gametogenesis was examined, using fluorescence microspectrophotometry with two fluorochromes, mithramycin and 4′,6-diamidino-2-phenylindole (DAPI). Under appropriate conditions, these bind specifically to DNA, and the fluorescence of the DNA fluorochrome complex is a quantitative measure of the DNA content. The alga is a haplont, which produces 2ⁿ daughter cells at the time of vegetative reproduction; cytokinesis and daughter cell release lag behind karyokinesis. No nucleus was found to contain more than the 2c quantity of DNA. Hence daughter cell production proceeds by doubling of the nuclear DNA followed by karyokinesis, in a repetitive sequence. As reported previously for C. reinhardtii Dangeard, the gametes of C. moewusii Gerloff contain the 1c amount of nuclear DNA. Several conflicting interpretations of the cell cycle sequence proposed in the literature were resolved.     

Elucidation of fertilization and development in a red alga by quantitative DNA microspectrofluorometry

Crucial nuclear events throughout the life histories of red algae have eluded researchers. Use of the DNA fluorochrome 4′,6-diamidino-2-phenylindole (DAPI) and microspectrofluorometry has now resolved the problems. In the parasitic red alga Choreocolax polysiphoniae (= Leachiella pacifica), the amounts of nuclear DNA during the processes of meiosis and fertilization are documented as well as the transfer of the newly formed zygote nucleus to the adjacent accessory cell. In this organism, the G₂ period predominates in the cell cycle of vegetative and reproductive cells; many nondividing vegetative cells become highly polyploid. The results indicate that the use of various fluorochromes combined with microspectrofluorometric measurements of individual nuclei is valuable for study of many developmental problems in lower eukaryotes where the relatively small nuclear DNA content has made study with conventional dyes impossible.     

SEXUAL REPRODUCTION OF PERIDINIUM WILLEI (DINOPHYCEAE)1

Sexual reproduction was induced in the dinoflagellate Peridinium willei Huitfeld-Kass when exponentially growing cells were inoculated into nitrogen deficient medium. Small, naked vegetative cells produced by division of thecate cells acted as gametes. The zygote remained motile 13–14 days, during which time it enlarged and the theca formed became warty. Fourteen to 15 days following plasmogamy the zygote was nonmotile with the protoplast contracted. A large red oil droplet appeared and the wall thickened, becoming chitinized. Hypnozygotes with 4 nuclei were observed 7–8 wk following formation. Meiosis was inferred. The hypnozygote germinated, within 8 wk producing one post-zygotic cell retaining the red oil droplet. This cell divided within 24 h into 2 daughter cells each with a prominent red oil droplet. These daughter cells divided after 2 to 3 days into ordinary vegetative cells. Attempts to induce sexual reproduction by inoculation of cells into media deficient in a number of basic elements were unsuccessful.     

The Studies on Embryology in Fritillaria ussuriensis Maxim

The development of the anther wall follows Basic-type. The cytokinesis at the time of pollen mother cell meiosis conforms to successive type. The arrangement of the microspores in the tetrad is referred to isobilateral. The primary wall between the generative cell and the vegetative cell is callose. The callose wall is easily detected under the fluorescence microscope. The mature pollen grain is 2-celled type. The ovule is bitegminous, tenui-nucellar and anatropous. The development of the female gametophyte follows Fritillaria-type. The mature embryo sac. consists of the six cells including the seven nuclei. The fertilization is referred to the premitotic syngamy type. The fusion of the female and male nucleoli is not observed at the end of the fertilization. The division of the primary endosperm nucleus is earlier than that of the zygote. The development of the endosperm is referred to nuclear type. The division of the zygote is transverse of longitudinal, the development of the embryo conforms to Onagradtype. When the seed is mature, the embryo is at the proembryo stage without differentiation and the endosperm cells are not absorbed.     

玉米双受精过程的细胞学观察

1.玉米双受精属于有丝分裂前配子融合的类型。2.授粉后21至24小时,大部分雌、雄性核发生融合。雌、雄性核融合时,雄性核仁的出现存在两种情况,其一是精核染色质逐渐分散的同时出现雄性核仁,其二是精核染色质逐渐分散后,约经2至4小时才出现雄性核仁。3.合子内的雌、雄性核仁若发生融合,一般在合子分裂前进行。合子以一个大核仁的形式进入分裂期;雌、雄性核仁不融合的合子同样可以进入分裂期。授粉后30至33小时,合子进行第一次分裂。合子静止期大约为9小时左右。4.初生胚乳核内的雌、雄性核仁不发生融合。授粉后24至26小时,初生胚乳核进行第一次分裂。初生胚乳核的静止期为2—4小时。5.人工授粉条件下,玉米果穗受精过程的进行有一定的顺序;即自果穗上部逐渐向下部完成受精作用。     

SEXUAL REPRODUCTION OF PERIDINUM CINCTUM F. OVOPLANUM (DINOPHYCEAE)1,2

Sexual reproduction is induced in the dinoflagelate Peridinium cinctum f. ovoplanum Lindemann when exponentially growing cells are inoculated into nitrogen deficient medium. Small, naked vegetative cells, produced by division of the thecate cells, then act as gametes. The zygote remains motile for 12–13 days during which time it enlarges and the theca which it forms becomes warty. Thirteen to 14 day s following plasmogamy the zygote is nonmotile, the protoplast contracts, a large red oil droplet appears, the wall thickens and becomes chitinized. This hypnozygote germinates within 7–8 weeks at 20 c producing 1 post-zygotic cell retaining the large red oil droplet. The presence of 4 nuclei in these post-zygotic cells may be demonstrated by staining them with acetocarmine. Two of these nuclei are smaller than the other two and probably abort. One may infer that meiosis occurs immediately prior to or at the germinartion of the hypnozygote. This post-zygotic cell divides within 24 h into 2 daughter cells each with a promment red oil droplet. These daughter cells divide after 2–3 days into ordinary vegetative cells. Attempts to induce sexual reproduction by changes in temperature or light and by inoculation of cells into media deficient in a number of basic elements were unsuccessful.     

MICROSPECTROPHOTOMETRIC ANALYSIS OF NUCLEAR DNA IN CHARA ZEYLANICA

Microspectrophotometric analysis of the DNA content of nuclei in various parts of Chara zeylanica Willd. revealed that the amount of DNA in the nucleus of an internodal cell equals twice the amount of DNA in the nucleus of a sperm, while the half-anaphase stage of the same nodal cells contains the same amount of DNA as the nuclei of the male gametes. The DNA content of the nuclei of internodal cells may rise as much as 50 times higher than that of the gametes. However, in the oldest (most basal) internodal cells, the DNA content of the minute nuclei falls again to the basic (1 C) amount. Measurements of sister nuclei derived by amitosis indicated that both nuclei have equal amounts of DNA; this was interpreted as further evidence that amitosis is not a disorganized process or manifestation of degeneration. The bearing of these analyses on the question of the site of meiosis in these plants is discussed.     

Nuclear DNA synthesis during the induction of embryogenesis in cultured microspores and pollen of Brassica napus L.

The dynamics of nuclear DNA synthesis were analysed in isolated microspores and pollen of Brassica napus that were induced to form embryos. DNA synthesis was visualized by the immunocytochemical labelling of incorporated Bromodeoxyuridine (BrdU), applied continuously or as a pulse during the first 24 h of culture under embryogenic (32 °C) and non-embryogenic (18 °C) conditions. Total DNA content of the nuclei was determined by microspectrophotometry. At the moment of isolation, microspore nuclei and nuclei of generative cells were at the G1, S or G2 phase. Vegetative nuclei of pollen were always in G1 at the onset of culture. When microspores were cultured at 18 °C, they followed the normal gametophytic development; when cultured at 32 °C, they divided symmetrically and became embryogenic or continued gametophytic development. Because the two nuclei of the symmetrically divided microspores were either both labelled with BrdU or not labelled at all, we concluded that microspores are inducible to form embryos from the G1 until the G2 phase. When bicellular pollen were cultured at 18 °C, they exhibited labelling exclusively in generative nuclei. This is comparable to the gametophytic development that occurs in vivo. Early bicellular pollen cultured at 32 °C, however, also exhibited replication in vegetative nuclei. The majority of vegetative nuclei re-entered the cell cycle after 12 h of culture. Replication in the vegetative cells preceded division of the vegetative cell, a prerequisite for pollen-derived embryogenesis.     

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.     

FERTILIZATION IN BARLEY

The mature embryo sac of barley consists of an egg, two synergids, a central cell, and up to 100 antipodal cells. At shedding the male gametophyte is 3-celled, consisting of a vegetative cell with a large amount of starch and two sperms having PAS+ boundaries. Before pollination the nucleus and cytoplasm of each synergid appear normal. After pollination the nucleus and cytoplasm of one synergid undergo degeneration. The pollen tube grows along the surface of the integument of the ovule, passes through the micropyle, and enters the degenerate synergid through the filiform apparatus. The pollen tube discharges the vegetative nucleus, two cellular sperms, and a variable amount of starch into the degenerate synergid. Soon after deposition the sperms migrate by an unknown mechanism to the chalazal end of the degenerate synergid. Sperm nuclei then enter the cytoplasm of the egg and central cell, ultimately resulting in the formation of the zygote and primary endosperm nucleus, respectively. Sperm boundaries do not enter egg or central cell, but it was not possible to determine the fate of other sperm components. Degenerate vegetative and synergid nuclei remain in the synergid after fertilization, constituting what are considered to be X-bodies in barley. The second synergid degenerates during early embryogeny.     

Mitosis and Amitosis of Generative Cell Nuclei in Artificially Germinated Pollen Tubes in Zephyranthes candida(Lindl.)Herb.

This paper deals with the comportmem of the vegetative nucleus and its spatial association with the generative cell and sperm cells in the artificially germinated pollen tubes of Zephyranthes candida (Lindl.) Herb. before and after generative cell mitosis with the use of DNA-specific fluochrome 4′,6-diamidino-2-phenylindole (DAPI). The induction of amitosis and abnormal mitosis of generative cell nuclei by cold-pretreatment of the pollen prior to germination was studied in particular. In normal case, the generative cell, after appressing to the vegetative nucleus for certain time, underwent mitosis to form two sperms, while the vegetative nucleus became markedly elongated, diffused, and exhibited blurring of its fluorescence. After division, a pair of sperms remained shortly in close connexion with the vegetative nucleus. Then the vegetative nucleus returned to its original state. In the pollen tubes germinated from cold-pretreated pollen, amitosis of some generative cell nuclei were frequently observed. Amitosis took place via either equal or unequal division with a mode of constriction. During amitosis, the dynamic change of vegetative nucleus and its intimate association with generative cell afore described did not occur. Sperm nuclei produced from amitosis could farther undergo amitisis resulting in micronnclei. Factors affecting the amitosic rate of generative cells, such as pollen developmental stage, temperature and duration of cold-pretreatment, were studied. Besides amitosis, cold-pretreatment also induced some abnormal mitotic behavior leading to the formation of micronuclei. Based on our observations and previously reported facts in other plant materials, it is inferred that the vegetative nucleus plays an important role in normal mitosis of generative cell and development of sperms.     

Pattern of the plastid division in spore mother cells of the hornwortAnthoceros punctatus

Relative changes in plastid DNA content in each stage of plastid division were investigated in order to better understand the division cycle of plastids in spore mother cells in the horwortAnthoceros punctatus. Samples of cells stained with DAPI were observed with epifluorescence microscopy and CHIAS. In spore mother cells of this species, plastids duplicated their own DNA prior to the plastidkinesis of the first plastid division, but did not replicate plastid DNA prior to the plastidkinesis of the second plastid division. Therefore, the DNA content of those plastids in which division had been completed was reduced to half its initial value. This indicates that the DNA replication pattern of plastids in spore mother cells corresponds to that of cell nuclei during premeiosis and meiosis inA. punctatus.     

烟草雌、雄配子DNA含量变化

采用显微分光光度法测定了烟草（Nieotiana tabacum）精细胞和卵细胞的DNA含量。烟草是二胞花粉,花粉萌发后生殖细胞在花粉管中分裂形成精细胞。授粉后45h花粉管到达子房,在花粉管内的精细胞DNA含量为1C。当花粉管在退化助细胞中破裂,释放出的两个精细胞开始合成DNA。在与卵细胞融合前,两个精细胞DNA含量接近2C。随着精细胞的到达及合成DNA,卵细胞也开始合成DNA,融合前的卵细胞DNA含量也接近2C。精、卵细胞融合后,合子DNA含量为4C。烟草雌、雄配子是在细胞周期的G2期发生融合,属于G2型。     

COORDINATNE NUCLEAR AND CHLOROPLAST DIVISION IN UNILOCULAR SPORANGIA OF LAMINARIA ANGUSTATA (LAMINARIALES,PHAEOPHYCEAE)1

Changes in the number of nuclei and chloroplasts were examined during the process of unispore formation in unilocular sporangia of Laminaria angustata. Just before meiosis, eight chloroplasts were always present in unilocular sporangial mother cells. The number of chloroplasts remained constant through meiosis. After the resulting four nuclei divided again (third nuclear division), a close association between a nucleus and a chloroplast developed among each of the eight nuclei and eight chloroplasts. The eight chloroplasts divided ahost synchronously before the synchronous division of the eight nuclei. Following the 16 nucleate stage with 16 chloroplasts and the final 32 nucleate stage with 32 chloroplasts, 32 unispores, each with a nucleus and a chloroplast, were fomd in unilocular sporangza of L. angustata. Immunofluorescence microscopy using an anti-centrin antibody showed that two anticentrin-stained structures (as future mitotic poles) occurred adjacent to each of the premitotic four nuclei, and each spot was located near a chloroplast. Therefore, after the third division, each of the eight nuclei established close contact with a chloroplast presumably mediated by the centrosomes.     

Detection of changes in the nuclear phase and evaluation of male germ units by flow cytometry during in vitro pollen tube growth in <Emphasis Type="Italic">Alstroemeria aurea</Emphasis>

This study aimed to analyze male gamete behavior from mature pollen to pollen tube growth in the bicellular pollen species Alstroemeria aurea. For mature pollen, pollen protoplasts were examined using flow cytometry. The protoplasts showed two peaks of DNA content at 1C and 1.90C. Flow cytometry at different developmental stages of pollen tubes cultured in vitro revealed changes in the nuclear phase at 9 and 18 h after culture. Sperm cell formation occurred at 6–9 h after culture, indicating that the first change was due to the division of the generative cells into sperm cells. After sperm cell formation, the number of vegetative nucleus associations with sperm cells showed a tendency to increase. This association was suggested as the male germ unit (MGU). When sperm cells, vegetative nuclei, and partial MGUs were collected separately from pollen tubes cultured for 18 h and analyzed using a flow cytometer, the sperm cells and vegetative nuclei contained 1C DNA, while the DNA content of partial MGUs was counted as 2C. Therefore, the second change in the nuclear phase, which results in an increase in 2C nuclei, is possibly related to the formation of MGUs.     

Egg maturation and parthenogenetic recovery of diploidy in the scorpion Liocheles australasiae (Fabricius) (Scorpions, ischnuridae)

In the scorpion Liocheles australasiae, egg maturation and parthenogenetic recoveries of chromosome number and nuclear DNA content were examined by histological, karyological observations and quantitative measurements of DNA. The primary oocyte becomes mature through two successive maturation divisions. The first maturation division takes place in the primary oocyte to produce a secondary oocyte and a first polar body. The second maturation division soon occurs in the secondary oocyte, in which the nucleus is divided into a mature egg nucleus and a second polar body nucleus, not followed by cytoplasmic fission. The first polar body, in one case, was successively divided into two second polar bodies; in the other case it was not divided. In either case, these polar bodies remained attached to the early embryo. The fate of these polar bodies during further embryogenesis were studied. In the karyological analysis, the chromosome number was divided into two groups, one from 27-32, the other was 54-64. The former was presumably the metaphase chromosome number at the meiotic division; the latter was presumably the metaphase chromosome number at the mitotic division. DNA content in the diploid nucleus of the primary oocyte, doubled before the maturation divisions, was reduced through the maturation divisions by one-half in the nuclei of the secondary oocyte and the first polar body and by one-fourth in the nuclei of the egg and the second polar bodies. The first reduction of DNA content corresponded to halving the number of the chromosomes in the first maturation division and the second to the nuclear division in the secondary oocyte. These reductions represent a common process of egg maturation, except the final production of the mature egg with two haploid nuclei, an egg nucleus, and a second polar body nucleus. These two nuclei, which were formed apart in the mature egg, drew near to fuse into a zygote nucleus. The chromosome number and nuclear DNA content were doubled in the zygote and each blastomere in embryos, supporting the hypothesis that the egg nucleus fuses with the second polar body nucleus and this conjugation initiates subsequent embryonic development.     

鹤顶兰胚囊发育过程中微管变化的共焦显微镜观察

光镜的观察确定了鹤顶兰（Ｐｈａｉｕｓ ｔａｎｋｅｒｖｉｌｌｉａｅ （Ａｉｔｏｎ） Ｂｌ．）胚囊发育属单孢子蓼型。应用免疫荧光标记技术及共焦镜观察了胚囊发育过程中微管分布的变化。当孢原细胞初形成时,细胞内的微管呈网状分布。之后,孢原细胞体积增大发育为大孢子母细胞。大孢子母细胞延长,进入减数分裂Ⅰ。微管由分裂前的网状分布变为辐射状排列。二分体的两个细胞内的微管分布一样,呈辐射状。四分体的近珠孔端的３ 个大孢子解体,细胞内的微管消失。靠合点端的功能大孢子内有许多微管呈网状分布。当功能大孢子进入第一次有丝分裂时,细胞内的微管由网状变为辐射状,从核膜伸展至周质。再经两次有丝分裂形成八核胚囊。在核分裂之前微管一般是呈网状分布并紧包围着核。在分裂期间二核和四核胚囊都呈极性现象,微管系统也呈极性分布。微管在八核胚囊内的分布变化情形特别复杂。首先,八核分别作不同程度的移动,其中两个核移向胚囊中央,珠孔端和合点端的３ 个核分别互相靠拢,形成３ 个区,即中央区、反足区和卵器区。胚囊未形成区时,８ 个核都被网状分布的微管包围着。当胚囊明显分成区时,反足区内的微管仍作网状分布。中央区的微管分布则趋疏松,形成篮形结构,包围着液泡和两个极核。在     

NUCLEAR BEHAVIOR IN THE BASIDIOMYCETE,VOLVARIELLA VOLVACEA

The basidiospores of the straw mushroom are typically uninucleate and its vegetative hyphae are generally multinucleate. There is a marked reduction of nuclear number in the trama and subhymenium. Interphase nuclei exist in two forms, each of which undertakes a particular mode of division. The “diffused” nuclei divide by conventional mitosis while the “constricted” ones divide amitotically. In metaphase of mitosis nine chromosomes were seen both in polar and lateral view. This haploid number confirms the nine bivalents found in basidia during meiosis. A unique characteristic of this fungus is that the diploid nucleus, the two postkaryotic nuclei and the four postkaryotic nuclei may be enclosed by a well-defined nuclear envelope during division.     

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.