Contributions to the cytology of endosperm in angiosperms-XII.Pisum sativum L.

A study of the cytology of endosperm ofPisum sativum, pea, fixed at different stages of development reveals that it remains free nuclear throughout its entire life. The nuclei are extremely polymorphic and differ in size from each other. The nuclei increase proportionately in size with the advancement in endosperm age.The haploid chromosome number of the taxon was verified asn=7. The endosperm nuclei were normally triploid with 3n=21 chromosomes, but higher polyploidy (6n and 12n) and aneuploidy were also recorded in small proportions. Nuclear fusions and aberrations such as irregular separation of chromosomes, sticky bridges and laggards are believed to be responsible for the origin of polyploid nuclei.Accumulation of mitotic aberrations including bridges and laggards are considered to result in reduced divisional activity thereby leading to endosperm breakdown with the consequent low seed set in some cases.     

An electron microscope study of nuclear and cell division in a dinoflagellate

Summary Light microscopical observations on the cell division of the small dinoflagellate Woloszynskia micra are correlated for the first time with an electron microscopical study. In prophase, whilst the nucleus enlarges and becomes pearshaped, the chromosomes divide to give pairs of chromatids. This process starts at one end and works to the other giving Y- and V-shaped chromosomes as it occurs. Cytoplasmic invaginations pass through the nucleus and by the end of prophase these are seen to contain a number of microtubules of about 180 Å diameter. There is no connection between the microtubules in the nuclear in vagination and either the flagellar bases or the chromosomes. At anaphase the nucleus expands laterally and the sister chromatids move towards opposite ends. The cell hypocone is now partially divided and the two longitudinal flagella well separate. The nucleus completes its division into two daughter nuclei and for a time portions of the cytoplasmic invaginations remain visible. Cell cleavage is completed by the division of the epicone. The nuclear membrane remains intact throughout division and the nucleolus does not break down.The mitotic division in this organism, which is unusual in comparison with the mitosis of higher organisms, is discussed in the light of other types of mitosis which have been reported and of earlier light microscopical observations on dinoflagellates.     

VEGETATIVE NUCLEAR DIVISION IN NEUROSPORA

A re-examination of the mode of vegetative nuclear division in Neurospora crassa was facilitated by the availability of the mutant “clock” which produces definite growth bands. Since the growth rhythm is correlated with nuclear divisions, stained mycelial mats of this mutant prepared at intervals from the beginning of a growth period provided a sequence of stages of division. In a 28-hour period the following broad features of nuclear behavior were observed: In the early part of the period during rapid mycelial growth, dividing elongated nuclei predominated. At the end of the period the mycelium contained mostly rounded resting nuclei. In the middle of a growth period nuclear forms of various degrees of annularity occurred along with elongated and rounded nuclei. Elongated and rounded nuclei completed division cycles without change in form, although the corresponding stages of the two types were similar. Elongated nuclei assumed a spiral form at the beginning of division. As division proceeded, relaxation of the nuclear gyres was accompanied by a visible duplication of the chromatin thread and the appearance of chromomere-like bodies on the daughter threads. One of the chromomere-like bodies became displaced and was interpreted to be a chromosome or a segment of a chromosome that acts as a mitotic center. All the chromosomes were found to be interconnected and to act as a unit throughout the division cycle. Only after the separation of the daughter chromatin threads could seven chromosomes be counted. Electron microscopic studies complemented the observations with the light microscope. On the basis of the evidence it was concluded that the vegetative nuclear division in Neurospora differs from the classical mitotic pattern in the following respects: (1) absence of visible centrioles, (2) the presence of interconnected chromosomes, (3) the comparatively late appearance of countable chromosomes, and (4) the frequent presence of interzonal connections between separating chromatin threads.     

Reorganisation du Type Endomixique chez les Loxodidae et chez les Centrophorella

New investigations of the nuclear cycle in the gymnostome ciliate Loxodes rostrum verify the long-neglected hypothesis proposed by Bütschli that in this multinucleated ciliate the macronuclei never divide. The consequences of this "caryosterose" are compensated for by a process of endomixis, that is, by the transformation of a certain number of the micronuclei, during vegetative multiplication, into new macronuclei.
The nuclear cycle in the gymnostome Centrophorella fistulosa does not show any aspect of nuclear division. Interpretation of this supposes the existence of polyenergid nuclei which fragment, during the interdivisional period, into subnuclei; among these some evolve in the somatic and macronuclear direction, before disappearance by karyolysis; others, corresponding to the micronuclei, grow by endomitosis, and reconstitute the polyploid and polyenergid nuclei. Thus the very particular nuclear cycle of C. fistulosa is believed to exhibit a new aspect in the endomictic process of nuclear reorganization.     

Meiotic division and fusion of nuclei in multinucleate cells from the induced fusion of meiotic protoplasts of liliaceous plants

Multinucleate protoplasts were produced from meiotic cells at the zygotene and pachytene stages in a lily andTrillium, and their meiotic divisions were followed during subsequent culture. In each multinucleate, a complete synchrony of nuclear division was maintained throughout the meiotic process, and chromosome behavior appeared normal up to the metaphase stage. In most dinucleates, chromosome segregation movement was organized in a common spindle, and the daughter nuclei at the telophase appeared to envelope each other in the newly formed nuclear membrane. The cell was divided into two daughter cells by a common cell plate. Trinucleates were similarly converted to two cells with a hexaploid number of chromosomes. Some of the di- and trinucleates subsequently completed the second meiotic division with the formation of typical tetrad configurations. In giant cells with more than several nuclei, chromosomes separated at random but reaggregated into one giant resting nucleus, with no later cytokinesis. The rate of meiotic development in multinucleates was relatively slower in cells which contained greater numbers of nuclei.     

Vegetative nuclear structures and their mode of division inCyathus species

Vegetative nuclear division in the homokaryotic and dikaryotic hyphae ofCyathus olla Brodie,C. setosus Brodie andC. bulleri Brodie was investigated. In the homokaryotic hyphae a nucleolus develops within a globular condensed nucleus consisting of a folded up filament. As the nucleolus increases in size, the nucleus unfolds and can assume a ring, horseshoe or filament configuration. The filament duplicates and (usually when unwound from the nucleolus) divides longitudinally. Occasionally, strand separation occurs while the filament is wrapped in the form of a ring around the nucleolus. The daughter nuclei may condense before the next division. In the dikaryotic hyphae the same nuclear cycle occurs as in the homokaryons except that an extra nuclear condensation to the globular form can occur in both the clamp and tube nuclei. The division of these two nuclei is not always synchronous and, moreover, the stage of karyokinesis of the clamp nucleus is not closely synchronized with the formation of the clamp connection. A deeply stained granule is associated with the nucleus. Some granules can be observed to be connected to the nucleus by a faintly Feulgen positive thread-like structure but other granules are sessile. The granule or centriole-like body is thought to direct the nuclear unfolding process. It may divide prior to, or after nuclear division.     

Nuclear division cycle in Neurospora crassa hyphae under different growth conditions.

Treatment with picolinic acid blocked Neurospora crassa nuclei in G1, and recovery from the treatment allowed a synchronous wave of deoxyribonucleic acid synthesis to occur. Nuclei, which appeared as compact globular bodies during the period of blockage, assumed a ring shape during the following S phase, which was also maintained in the G2 phase. The proportion of compact globular nuclei was much higher in hyphae growing at lower rates, whereas that of ring nuclei increased when the hyphae were growing at higher rates. Horseshoe nuclei (probably mitotic nuclei) and double ring nuclei were also observed in growing hyphae, but their frequencies were low and fairly independent of the rate of growth. The length of the S phase of the Neurospora nuclear division cycle was determined to be about 30 min. From the frequencies of the phase-specific nuclear shapes, the durations of the G1 phase and the combined S plus G2 phases were calculated. The results showed that variations in the growth rates of the mycelia were mainly coupled with variations in the G1 phase of the nuclear division cycle. For mycelia growing in minimal sucrose, the lengths of all of the phases of the nuclear division cycle were estimated.     

Electron microscopic studies on the foraminiferAllogromia laticollaris arnold mitosis in agamonts

Summary During mitosis in multinucleated agamonts ofAllogromia laticollaris the nucleolar substance cannot be demonstrated in the nuclei, but only in the cytoplasm as large opaque bodies, some of which are surrounded by two membranes. Only a few smaller bodies are still present within vacuoles of young agamonts formed subsequent to the dividing state. Since the nuclear envelope persists during karyokinesis, the division spindle is localized intranuclearly. The component continuous microtubules, which prefer the nuclear periphery, are mostly visible as bundles, whereas the microtubules running to the chromosomes appear single and less numerous. Centrosomes can be noticed not only at elongated but also at ovoid or irregularly shaped nuclei. These centrosomes represent round or elliptic bodies surrounded by a membrane and consist of granular and fibrillar material. They occur within the perinuclear space and are restricted to the state of karyokinesis.     

NUCLEAR DIVISION IN ALTERNARIA TENUIS

A study of the hyphal and conidial nuclei of Alternaria tenuis with the Feulgen nuclear reaction indicates that division is mitotic. Five chromosomes and a spindle apparatus are formed during nuclear division.     

Chromosome cycles of the basidiomycete Cyathus stercoreus (Schw.) De Toni

Summary Chromosome cycles of the basidiomycete Cyathus stercoreus (meiosis and mitosis) are described. The fusion of two nuclei of compatible mating type takes place in the developing basidium at the end of telophase of the presynaptic mitosis. Synapsis follows immediately after nuclear fusion. During synapsis the chromosomes elongate, facilitating pairing. Meiosis and mitosis are essentially similar to those processes in higher organisms. Details of divisional stages are described and illustrated with photomicrographs. The presence of centrioles and spindles is demonstrated. The presence of quadrivalents as well as secondary associations of like chromosomes suggests that Cyathus stercoreus may be a tetraploid species.     

MITOSIS AND CYTOKINESIS IN THE CHLOROMONADOPHYCEAN ALGA GONYOSTOMUM SEMEN1

Mitosis and cytokinesis in Gonyostomum semen (Ehrenberg) Diesing have been investigated with the light microscope. During prophase nucleoli disappear and the chromatid structure of the chromosomes becomes apparent. Separation of chromatids at anaphase is accompanied by progressive fusion of the progeny chromosomes. This process continues into telophase by which stage the progeny nuclei consist of dense masses of chromatin with occasional chromosomes extending from their equatorial surfaces. By the end of telophase, nucleoli are reforming and the interphase nuclear morphology is reestablished. Mitosis is followed by cytokinesis, which is a relatively lengthy phase. In early cytokinesis the 2 interphase nuclei are present, and there is no indication of the forthcoming division of the cytoplasm. Later in cytokinesis a membrane is formed between the 2 nuclei. Final separation of the progeny individuals is accomplished by vigorous movements of swimming cells or, in the case of palmelloid cells, by the deposition of a mucilaginous layer.     

Studies on the arrangement of nucleoprotein in elongate sperm heads

Sperm from Nucella lapillus and Gallus domesticus were treated with the enzymes pronase and trypsin and 8M urea to break down the nuclei. Preparations were dried by the critical point method and rotary shadowed with platinum/ carbon prior to examination with the electron microscope. The patterns of breakdown in the nuclei seen after experimental treatment show a close correlation with the patterns of nuclear condensation which occurs during spermiogenesis. No evidence was found to indicate boundaries between chromosomes. The arrangement of chromosomes within sperm nuclei and condensation patterns in spermiogenesis are discussed.Work supported in part by NSF University Science Development Award GU-1154.     

Pattern of DNA synthesis in nuclei of feeding and starving Amoeba proteus : A cytofluorometric study

The DNA content in isolated nuclei of Amoeba proteus was determined for each of the three groups of synchronized amoebae over different intervals after division. Several nuclei of each amoeba group were fixed 1 h after division, before the amoebae were fed. About h after division, some amoebae in each group were given food (Tetrahymena pyriformis), while the rest were left starving. Samples of the nuclei of fed and starved amoebae were fixed 24 h and (in different groups) 42–55 h after division. In each group from 22 to 48% of the fed amoebae had divided prior to the last nuclei fixation. Starved amoebae did not undergo division. In all three amoeba groups the nuclear DNA content of fed cells by the end of interphase had increased to 280–300% the value for 1 h amoebae. The nuclear DNA content of starved amoebae of all three groups was also increased, and in two groups it exceeded the initial level more than two-fold. However, in all three groups, it was lower than that of fed amoebae. In all the groups the nuclear DNA content in fed amoebae grew after 24 h, i.e. during the second half of interphase, the increase accounting for from 11 to 48% of the total increase. The hypothesis is put forward that the increase in the nuclear DNA content during the cell cycle of Amoeba proteus is the result of two processes: (1) one-time replication of the DNA of the whole genome; and (2) repeated replication of some part of the DNA. In amoebae the relation of the pattern of nuclear DNA synthesis to the diet is considered.     

NUCLEAR BEHAVIOR IN THE VEGETATIVE HYPHAE OF CERATOCYSTIS FAGACEARUM

Vegetative nuclear division in Ceratocystis fagacearum (Bretz) Hunt was found to differ from classical mitosis in that: (1) division always occurs perpendicular to the longitudinal axis of the cell, (2) anaphase movement is unilateral and unsynchronized, (3) a spindle occurs only between separating chromatids. Interphase and prophase nuclei and nucleoli are morphologically similar to those in higher plants. At metaphase the associated chromosomes form a bar of chromatin and lie against the hyphal wall. Spindle fibers appear between separating chromatids, perhaps pushing them apart. When nuclear division is complete the nuclei become attenuated and migrate. Vegetative nuclear division in C. fagacearum may be an evolutionary form of classical mitosis.     

Cytological studies on degenerative nuclei at pollen development ofCarex ciliato-marginata

Chromosomes in degenerative and functional nuclei ofCarex ciliato-marginata Nakai were investigated during meiotic and primary pollen nuclear division. The nuclear DNA content of these nuclei was also measured using Feulgen microspectrophotometry. At metaphase of the primary pollen nuclear division, the chromosomes of degenerative nuclei were the same length as those of the functional nucleus, but only half their width. The functional nucleus divided into two, each of which moved to a pole, but the degenerative nuclei did not divide. The nuclear DNA content of the degenerative nucleus was half that of the functional nucleus and equal to that of one of the tetrads of a meiotic division. It is concluded that DNA replication was carried out in only one nucleus of the tetrad and that the other three nuclei were composed of unreplicated chromosomes at metaphase of the primary pollen nuclear division.     

Cell division in Hymenomonas carterae (Braarud et Fagerland) Braarud (Prymnesiophyceae)

The cell division cycle of Hymenomonas carterae (Braarud et Fagerland) Braarud was investigated at the ultrastructural level. DNA synthesis and cytokinesis occurred during the 8-hour dark period. All organelles, including the flagellar bases were replicated prior to nuclear division. Prophase consisted of a clustering of the chromosomes into distinct groups and the disappearance of the nucleolus. During metaphase there was complete dissociation of the nuclear envelope resulting in the formation of an open spindle containing no major organelles. The metaphase plate formed at right angles to an imaginary line joining the two pairs of flagellar bases. Elongation of the cell and separation of the chromosomes occurred at anaphase. During early telophase the nuclear envelope veformed and was closely associated with the chromosome masses, resulting in the nuclear possessing convoluted profiles. Telophase was characterized by complete break down of spindle fibres, rounding off of the nuclear profiles, reappearance of the nucleolus, emergence of the flagella and the final separation of the two daughter cells.     

Ultrastructural Features of Mitosis in Anisonema sp. (Euglenida)1

The fine structure of stages in mitosis in a colorless euglenoid, Anisonema sp., reveals that chromosomes remain condensed throughout the life cycle and are attached to the nuclear envelope at interphase. The onset of mitosis is marked by the anterior migration of the nucleus towards the base of the reservoir and by elongation of the nucleolus. The nuclear envelope persists throughout mitosis. Microtubules are generated in the peripheral nucleoplasm adjacent to the envelope and attach to the chromosomes while they are still associated with the envelope. The region of microtubular contact develops into a distinct layered kinetochore as the developing spindle with attached chromosomes separates from the nuclear envelope and moves into the nucleoplasm. The mature spindle consists of a number of subspindles each containing about 8–10 microtubules and a few associated chromosomes. Both chromosomal and non-chromosomal microtubules are present in each subspindle and extend towards the envelope terminating at or near the nuclear pores. Chromosomal segregation is concomitant with nuclear elongation. By late division, an interzonal spindle develops in the dumbbell-shaped nucleus and nucleolar separation occurs. Continued invagination of the nuclear envelope in the region of the interzonal spindle eventually separates the daughter nuclei. A remnant of the interzonal spindle persists in the cytoplasm until cytokinesis.     

The chromosomes of Puschkinia libanotica during mitosis

The chromosome complement of Puschkinia libanotica is described. In addition to five pairs of A chromosomes plants may possess up to 7 B chromosomes. Part of the long arm of the B chromosome gives rise to a heterochromatic mass in interphase nuclei and this can be seen to be a double structure in G₁ nuclei and a quadruple structure in G₂ nuclei. It is believed that these configurations represent the pre- and post-replication forms of subchromatids in the heterochromatic segment of the B chromosome. Microdensitometry of metaphase chromosomes shows that the segment of the B chromosome that is heterochromatic during interphase has no more DNA per unit volume than any of the euchromatic A chromosomes.     

ULTRASTRUCTURE DURING DEVELOPMENT OF THE NUCLEUS OF BATOPHORA OERSTEDII (CHLOROPHYTA; DASYCLADACEAE)1

The primary nucleus of Batophora oerstedii J. Agardh like that of the related Acetabularia, undergoes a great increase in size throughout vegetative development. Formation of small secondary nuclei represents an irreversible stage in the development of reproductive structures in the gametangia. Changes observed in the course of the life cycle include: i) an increase from 3 to 200 μm diam, of the nucleus; ii) increase in number of nucleoli; iii) development of the perinuclear region; iv) increased pore density in the nuclear membrane; v) development of chromosomes in the nucleoplasm; vi) formation of secondary nuclei; and, vii) division of secondary nuclei.     

Unusual pattern of mitosis in the free-living flagellateDimastigella mimosa (Kinetoplastida)

Summary The three-dimensional ultrastructural organization of the mitotic apparatus ofDimastigella mimosa was studied by computer-aided, serial-section reconstruction. The nuclear envelope remains intact during nuclear division. During mitosis, chromosomes do not condense, whereas intranuclear microtubules are found in close association with six pairs of kinetochores. No discrete microtubule-organizing centers, except kinetochore pairs, could be found within the nucleus. The intranuclear microtubules form six separate bundles oriented at different angles to each other. Each bundle contains up to 8 tightly packed microtubules which push the daughter kinetochores apart. At late anaphase only, midzones of these bundles align along an extended interzonal spindle within the narrow isthmus between segregating progeny nuclei. The nuclear division inD. mimosa can be described as closed intranuclear mitosis with acentric and separate microtubular bundles and weakly condensed chromosomes.Abbreviation MTOC microtubule-organizing center