POLYGONAL ASPECTS OF CELL FACES. III. CELL SIZE,CELL DIVISION,AND CELL FACE DISTRIBUTIONS

Wheeler , George E. (Brooklyn Coll., Brooklyn, New York.) Polygonal aspects of cell faces. III. Cell size, cell division, and cell face distributions. Amer. Jour. Bot. 50(8): 747–754. Illus. 1963.—The effects of cell size differences on cell face (polygon type) distributions, and the relationship of cell division to these effects were investigated, using published and original data. Only “relative” size was considered, i.e., the size of a body compared with the sizes of contiguous bodies. A preliminary study of mixtures including 2 sizes of nonliving bodies (bubbles or shot) showed that, with increase in number of smaller bodies relative to larger, 4- and 5-gons decrease and 6-gons increase on both large and small bodies (except for 5-gons on small bubbles). Since the cited papers on cells generally include no volume measurements, cell size was assumed to be proportional to number of faces; therefore, the cells from each sample were pooled in 3 groups of different ranges as to number of faces per cell. This device made evident the 4- and 5-gon decreases and the 6-gon increases with increasing size, but only in certain samples;- marked exceptions occurred among others. New data from 2 original samples showed, in general, the correlations described above, but again then; were exceptions. Discrepancies were found to arise from variable division patterns which affect face types both directly, and indirectly through division effects on cell size. It was concluded that relative size is generally less important in determining cell face distributions than are the more direct cell division events, and that size difference effects can be detected only if the other events operate minimally.     

POLYGONAL ASPECTS OF CELL FACES. II. QUADRILATERALS AS THE PREVAILING TYPE

Wheeler , George E. (Brooklyn Coll., Brooklyn, New York.) Polygonal aspects of cell faces. II. Quadrilaterals as the prevailing type. Amer. Jour. Bot. 49(4): 355–362. Illus. 1962.—Quadrilateral faces are abundant and even predominant among the faces of certain types of cells. Data taken from the literature and several original samples were studied to define the conditions which foster large numbers of quadrilaterals. The presence of free faces (cells on air spaces) profoundly affects cell-face distributions. There is a great excess of quadrilaterals on cells with 2 free faces on opposite sides (cells of single layers). Among cells with 1 free face (cells of epidermises), pentagonal faces usually surpass quadrilateral faces, although they are just about equal in a few samples. Intermediate ratios of the 2 face types occur in samples which include cells having faces touching 1 free face, mixed with cells having faces between 2 free faces. The “competition” for numerical superiority shifts to pentagons vs. hexagons, among cells comprising internal tissues (cells in contact on all sides with other cells). With respect to epidermises, the relative size of epidermal and of subepidermal cells strongly influences the relative numbers of quadrilaterals and pentagons. A marked trend toward quadrilaterals may also be found in connection with a quite different set of cell relationships: if 2 layers of elongated cells occur together, and if their long axes are mutually perpendicular, then a “checkerboard” pattern may result. This arrangement favors large numbers of quadrilateral faces; in some samples, they may even dominate. It is suggested that certain modifications of this pattern may generate large numbers of triangular and of lenticular (lens-shaped) faces. Varying patterns of cell division are considered to be primarily responsible for changes in cell-face distributions and for changes in predominating face types.     

Genetic control of cell-type-specific levels of mouse beta-galactosidase.

Tissue analyses of mouse β-galactosidase (BGS) activity indicate previously unobserved genetic complexities. The existing genotypic classification of Bgs^h (high-activity) vs Bgs^d (diminished-activity) alleles has been based exclusively on strain differences in brain [Felton, J., Meisler, M., and Paigen, K. (1974). J. Biol. Chem.249, 3267–3272]. However, it now appears that other tissues in a strain with “high BGS” in brain can be relatively low in activity, or that tissues in a “low-BGS” strain can be relatively high. In addition, different cell types within a tissue (e.g., exocrine vs endocrine pancreas) can vary in BGS activity independently of each other. A given tissue ranges, among strains tested here, between 1.8- and 3.6-fold over the activity of the lowest strain. These new results suggest that complex mechanisms may be involved in tissue- and cell type-specific control of BGS activity. The hypothesis is proposed that there may be “controlling genes” determining specific enzyme levels by causing a limited somatic amplification of the structural gene and by controlling the degree of amplification in a given cell type and strain.     

A microaliquoting technique for precise histological annotation and optimization of cell content in frozen tissue specimens

Knowledge of the exact cell content of frozen tissue samples is of growing importance in genomic research. We developed a microaliquoting technique to measure and optimize the cell composition of frozen tumor specimens for molecular studies. Frozen samples of 31 mesothelioma cases were cut in alternating thin and thick sections. Thin sections were stained and evaluated visually. Thick sections, i.e., microaliquots, were annotated using bordering stained sections. A range of cellular heterogeneity was observed among and within samples. Precise annotation of samples was obtained by integration and compared to conventional single face and “front and back” section estimates of cell content. Front and back estimates were more highly correlated with block annotation by microaliquoting than were single face estimates. Both methods yielded discrepant estimates, however, and for some studies may not adequately account for the heterogeneity of mesothelioma or other malignancies with variable cellular composition. High yield and quality RNA was extracted from precision annotated, tumor-enriched subsamples prepared by combining individual microaliquots with the highest tumor cellularity estimates. Microaliquoting provides accurate cell content annotation and permits genomic analysis of enriched subpopulations of cells without fixation or amplification.     

No enhanced recognition memory,but better source memory for faces of cheaters

Previous studies sought to test for the existence of a “cheater-detection module” by testing for enhanced memory for the faces of cheaters, but past results have been inconclusive. Here, we present four experiments showing that old–new discrimination was not affected by whether a face was associated with a history of cheating, trustworthy or irrelevant behavior. In contrast, source memory for faces associated with a history of cheating (i.e., memory for the cheating context in which the face was encountered) was consistently better than source memory for other types of faces. This pattern held under a variety of conditions, including different types of judgments participants made about the stimulus persons (attractiveness in Experiment 1; likeability in Experiments 2–4), different retention intervals (a few minutes in Experiments 1, 2 and 4; 1 week in Experiment 3), whether the behaviors were exceptional or ordinary (Experiments 1–3) and whether the social status of the characters was low or high (Experiment 4). Given no differences in old–new discrimination, enhanced source memory for faces of cheaters may be useful for avoiding cheaters in future interactions.     

Premature cytokinesis in pollen mother cells of transgenic tobacco plants (<Emphasis Type="Italic">Nicotiana tabacum</Emphasis> L.)

For the majority of dicotyledonous plants, cytokinesis in PMC is staged only once, i.e., after the completion of two cycles of caryokinesis. In the article, a cytological picture and the frequency characteristics of anomalies are shown, in which the cytokinesis in the PMCs of transgenic tobacco plants was already initiated after the first meiotic division. It is shown that, in such cells, the basic processes of cytoskeletal reorganization, which is typical for the simultaneous type of cytokinesis, remained unmodified. However, in most cases, premature division of cytoplasm took place with abnormalities, e.g., with the formation of a membranous “tunnel” or “gash.” It has been detected that the initialization of an additional round of cytokinesis is not an obstacle to the performance of the nuclear cycle or cytokinesis after the second meiotic division. Thus, in the presence of this anomaly, there is a change in the type of cytoplasm division, i.e., of simultaneous to successive.     

STUDIES ON SARGASSUM. I. A LIGHT MICROSCOPIC EXAMINATION OF THE WOUND REGENERATION PROCESS IN MATURE STIPES OF S. FILIPENDULA

Regrowth from wounded stipe explants of Sargassum can be divided into four stages based on cytological changes. The first stage involves changes associated with the wound reactions and the formation of a wound epidermis. The second stage includes the formation of a well defined medullary pit with meristematically active cells around its periphery. Several “bud primordia” are also formed which begin to grow by cell division towards the wound surface. The third stage involves a period of internal tissue differentiation in the “bud primordia” such that mitotic activity is localized in the bud tip and the basal cells grow by cell elongation. The fourth stage marks a major change in the morphology of the regeneration branch from a tubular structure to that of a flattened blade. This change in morphology is preceded by the formation of an apical pit around which the flattened growth appears to be organized.     

MECHANICAL BEHAVIOR OF PLANT TISSUES AS INFERRED FROM THE THEORY OF PRESSURIZED CELLULAR SOLIDS

The mechanical behavior of plant tissues and its dependency on tissue geometry and turgor pressure are analytically dealt with in terms of the theory of cellular solids. A cellular solid is any material whose matter is distributed in the form of beamlike struts or complete “cell” walls. Therefore, its relative density is less than one and typically less than 0.3. Relative density is the ratio of the density of the cellular solid to the density of its constitutive (“cell wall”) material. Relative density depends upon cell shape and the density of cell wall material. It largely influences the mechanical behavior of cellular solids. Additional important parameters to mechanical behavior are the elastic modulus of “cell walls” and the magnitude of internal “cell” pressure. Analyses indicate that two “stiffening” agents operate in natural cellular solids (plant tissues): 1) cell wall infrastructure and 2) the hydrostatic influence of the protoplasm within each cellular compartment. The elastic modulus measured from a living tissue sample is the consequence of both agents. Therefore, the mechanical properties of living tissues are dependent upon the magnitude of turgor pressure. High turgor pressure places cell walls into axial tension, reduces the magnitude of cell wall deformations under an applied stress, and hence increases the apparent elastic modulus of the tissue. In the absence of turgid protoplasts or in the case of dead tissues, the cell wall infrastructure will respond as a linear elastic, nonlinear elastic, or “densifying” material (under compression) dependent upon the magnitude of externally applied stress. Accordingly, it is proposed that no single tangent (elastic) modulus from a stress-strain curve of a plant tissue is sufficient to characterize the material properties of a sample. It is also suggested that when a modulus is calculated that it be referred to as the tissue composite modulus to distinguish it from the elastic modulus of a noncellular solid material.     

THE ORIGIN OF AN ORGAN: PHYLOGENETIC ANALYSIS OF EVOLUTIONARY INNOVATION IN THE DIGESTIVE TRACT OF FLIES (INSECTA: DIPTERA)

The cardia, a prominent digestive tract organ consisting of several specialized cell types, occurs throughout the “higher” or muscoid flies, division Schizophora of order Diptera. Phylogenetic analysis of cellular organization in 65 insect species from 36 families indicates that this organ originated within the order Diptera from ancestrally undifferentiated tissues. “Lower” flies, suborder “Nematocera,” display little or no epithelial cell specialization at the corresponding site. Scorpionflies of the outgroup order Mecoptera are similarly unspecialized. Intermediate levels of cellular specialization occur in Tabanomorpha, Asilomorpha and Aschiza, dipteran taxa that diverge between “Nematocera” and Schizophora. The distribution of epithelial characteristics suggests that the cardia evolved through a sequence of simple tissue transformations, combining changes in epithelial configuration with local differentiation of cell structure and function. The evolution of locally specialized cell types implies the emergence of structural genes and regulatory mechanisms through the modification of an ancestral genome that had not supported such extensive differentiation. Comparison of localized gene expression in Drosophila melanogaster with that in other fly species having greater or lesser degrees of cell specialization may provide a practical model system for studying specific patterns of mutation associated with such evolutionary innovation.     

On the structural and functional components of coated vesicles.

Despite the diversity of their known functions, coated vesicles from different tissues contain a rather similar spectrum of proteins, in addition to their major coat protein, clathrin. In particular, each coated vesicle preparation shows a doublet of polypeptide species, on sodium dodecyl sulphate-containing gel electrophoresis, of apparent molecular weight in the region 30,000 to 36,000. Using bullock brain as a source, these molecules are found in association with possible trimers or higher multiples of clathrin, obtained by dissolving coated vesicles in cholate. They may play a structural role relating to the vertices or edges of the lattices of pentagons and hexagons of the polyhedral coats.Purified coated vesicles (e.g. from chicken oocytes) seem to contain relatively small amounts of specific proteins in terms of “contents”. This suggests that the bulk of the isolated particles, especially those in the small size range (500 to 800 Å diam.), may be “empty” of contents, although many still retain a lipid vesicle. These empty structures could represent a pool of recycling coated vesicle components formed after release (possibly from larger vesicles (800 to 1500 Å diam.)) of the specific contents, at their particular destination.     

GROWTH AND CELL CYCLE OF TWO CLOSELY RELATED RED TIDE-FORMING DINOFLAGELLATES: GYMNODINIUM NAGASAKIENSE AND G. CF. NAGASAKIENSE1

Small-sized vegetative cells were found to co-occur with normal-sized cells in populations of the European bloom-forming dinoflagellate Gymnodinium cf. nagasakiense Takayama et Adachi, currently known as Gyrodinium aureolum Hulburt, but not in populations of the closely related Japanese species Gymnodiniumn agasakiense. We examined how cell size differentiation may influence growth and cell cycle progression under a 12:12-h light: dark cycle in the European taxon, as compared to the Japanese one. Cell number and volume and chlorophyll red fluorescence in both species varied widely during the photocycle. These variations generally appeared to be related lo the division period, which occurred at night, as indicated by the variations of the fraction of binucleated cells (mitotic index) as well as the distribution of cellular DNA content. “Small” cells of G. cf. nagasakiense divided mainly during the first part of the dark period, although a second minor peak of dividing cells could occur shortly before light onset. In contrast, “large” cells displayed a sharp division peak that occurred 9 h after the beginning of the dark period. The lower degree of synchrony of “small” cells could be a consequence of their faster growth. Alternatively, these data may suggest that cell division is lightly controlled by an endogenous clock in “large” cells and much more loosely controlled in “small” cells. Cells of the Japanese species, which were morphologically similar to “large” cells of the European taxon, displayed an intermediate growth pattern between the two cell types of G. cf. nagasakiense, with a division period that extended to most of the dark period.     

Germ cell cluster formation in insect ovaries

Three different ovariole types exist in insects: panoistic, polytrophic- and telotrophic-meroistic. Their ontogenetic development is comparable to all insect orders. Each ovariole is composed of somatic tissues and germ cells.Panoistic ovarioles can be developed: (1) by totally blocking germ cell cluster division (e.g. in “primitive” insect orders; and (2) after germ cell cluster formation by final cleavage of cystocytes, which develop as oocytes (e.g. in stoneflies or thrips).Polytrophic-meroistic ovaries, showing a set of identical characters, are found among hemirnetabolous and holometabolous insects, indicating a “basic type” of common origin. One characteristic feature is the differentiation of only one oocyte, which is derived from one central cell of the cluster, whereas all other siblings are transformed into nurse cells.Telotrophic ovaries differ from polytrophic ovaries by retention of all nurse cells in the anterior trophic chamber. In addition, oocyte-nurse cell determination can be shifted towards more oocytes in a cluster, and clusters or subclusters can fuse by cell membrane reduction among nurse cells. This type of ovary developed independently 3 times from polytrophic ancestors and once in mayflies directly from panoistic ancestors.     

Rapid electroelution of nucleic acids from agarose and acrylamide gels

The alkaline/filter DNA elution technique measures single-strand DNA breaks in mammalian cells based on the DNA molecular weight dependent retention of the macromolecule on 2-μm-pore-size filters. Described here is a modification of the technique which uses [³H]thymidine-labeled DNA of γ-irradiated cells as an internal reference. Thus, an increased precision is obtained in the assessment of this type of DNA damage at biologically significant radiation doses (i.e., where cell survival occurs). The measure of DNA damage is based on the actual initial DNA elution rate, i.e., arithmetic ratio of the elution of “test” DNA (i.e., ¹⁴C-labeled DNA) relative to the elution of “reference” DNA (i.e., ³H-labeled DNA). The repair of this damage on postirradiation incubation of the cells is detected as a decrease in the rate of “test” DNA cluted relative to “reference” DNA from unincubated cells. For Chinese hamster V79–171 cells irradiated with 5 Gy (500 rads), repair can be resolved into two first-order processes having rate constants (at 24°C) of ～0.190 and ～0.017 min^?1.     

Baboons (Papio papio) spontaneously process the first-order but not second-order configural properties of faces

A two-alternative forced-choice discrimination task was used to assess whether baboons (N=7) spontaneously process qualitative (i.e., first-order) or quantitative (i.e., second-order) variations in the configural arrangement of facial features. Experiment 1 used as test stimuli second-order pictorial faces of humans or baboons in which the mouth and the eyes were rotated upside down relative to the normal face. Baboons readily discriminated two different normal faces but did not discriminate a normal face from its second-order modified version. Experiment 2 used human or baboon faces for which the first-order configural properties had been distorted by reversing the location of the eyes and mouth within the face. Discrimination was prompt with these stimuli. Experiment 3 replicated some of the conditions and the results of experiment 1, thus ruling out possible effects of learning. It is concluded that baboons are more adept at spontaneously processing first- than second-order configural facial properties, similar to what is known in the human developmental literature.     

A ‘simple clock’ approach of circadian rhythms: An easy way to predict the clock's singularity

A graphical method is presented which allows the prediction of phase resetting curves of circadian rhythms for both type 1 and type 0 resetting, starting from one experimentally determined phase resetting curve. Calculations were based on literature data for the pupal eclosion rhythm of Drosophila pseudoobscura. The method is based on the assumption that for all practical purposes the rhythm may be approached as a “simple clock”, i.e. an oscillator with only one state variable, namely its phase or circadian time, CT. Besides predicting both “types” of phase resetting the method is capable to locate the “position” of the phase singularity and thus the transition from type 1 to type 0 resetting. This graphical method is an elaboration of the “transformation method”, developed in 1972 by A. Johnsson and H. G. Karlsson, which was effective in predicting phase resetting by “strong” stimuli, but failed in the case of “weak” stimuli. Predictions made using the extended transformation method are in good agreement with experimental results obtained with Drosophila. Also for the flesh fly, Sarcophaga argyrostoma, a prediction is made of the position of the phase singularity of the eclosion rhythm and compared with experimental results.     

Problems of structural and functional identification of biological tissues

Theoretical methods for identification of topological and functional parameters of biological tissues (e.g., myocardium) are considered. Unknown topological parameters include the network dimension and connectivity, while unknown functional parameters include the resistivity of the cellular membrane and cytoplasm. The cell size (length and diameter), the input resistance of the tissue, and the fundamental electric potential field formed by a “point” current source (intracellular microelectrode) are treated as experimentally known parameters.     

CELL SIZE DIFFERENTIATION IN THE BLOOM-FORMING DINOFLAGELLATE GYMNODINIUM CF. NAGASAKIENSE1

Two subpopulations differing essentially by their mean cell size were observed regularly in cultures and natural samples of the naked dinoflagellate Gymnodinium cf. nagasakiense Takayama et Adachi (currently known as Gyrodinium aureolum Hulburt), a species which frequently forms red tides in North European seas. “Large” cells represented the typical forms; they were morphologically similar to cells of the closely related Japanese species G. nagasakiense, which did not form any subpopulation of reduced size. “Small” and “large” cells of G. cf. nagasakiense had the same DNA content, but the nucleus of the former appeared to be much more condensed during interphase. Each cell type was able to divide and had its own growth dynamics; therefore, any intermediary between pure populations of “small” and of “large” cells were observed in culture. The “large” form generated a “small” cell by an atypical budding-like division, whereas the “small” form gave back a “large” form, once it ceased to divide, by simple enlargement of its cell body. Factory inducing cell size differentiation are yet unclear. Neither nitrogen nor phosphorus starvation induced a significant increase in the relative proportion of “small” and budding cells. Although cell size differentiation is associated with the formation of gametes in a variety of dinoflagellates, we demonstrated that “small” cells of G. cf. nagasakiense are able to divide asexually, in contrast to gametes of most other species. The high proliferative power of “small” cells as compared with normal cells suggests that they could play a significant role during red tides of G. cf. nagasakiense; in contrast, cells of the Japanese species G. Nagasakiense could sustain high growth rates with larger cell size because this species generally blooms in waters much warmer than those found in northern Europe.     

Zunahme von cytokinin und auxin in verwundetem speichergewebe von Solanum tuberosum

“Butanol-soluble” cytokinins increase in grated and in lighted cut potato tissue. In slices, an increase of “water soluble” cytokinins (darkness and of tRNA-cytokinins can be found. Together with auxin, the cytokinin factor stimulates cell division in wound tissue.     

Comparative development of the sporophyte–gametophyte junction in six moss species

Developmental anatomy of the sporophyte–gametophyte junction in six moss species is described with special reference to sporophyte penetration into the gametophytic tissue. The sporophyte–gametophyte junction in mosses is classified into two types based on vaginula morphology: in the “true vaginula” type, the junction involves only an epigonium derived from the archegonium, and in the other “shoot vaginula” type, it involves a shoot and an epigonium. In both of the types, the sporophyte penetrates into an epigonial tissue accompanied by degeneration of epigonium cells under the developing sporophyte. In the “shoot vaginula” type, the sporophyte further penetrates into the conducting strand or similar cells that seem to be induced by stimulation of fertilization. It is likely that the difference in growth rate between the epigonium and the capped sporophyte is a mechanical force for sporophyte penetration.     

PHLOEM OF PRIMITIVE ANGIOSPERMS. I. SIEVE-ELEMENT ONTOGENY IN THE PETIOLE OF LIRIODENDRON TULIPIFERA L. (MAGNOLIACEAE)

As part of a continuing study of sieve elements in primitive angiosperms, a study of this cell type was undertaken in Liriodendron tulipifera. A typical ontogenetic sequence was observed in which synthetic processes such as wall thickening are followed in time by cellular lysis of nucleus, ribosomes, microtubules, vacuoles, and dictyosomes. This lysis is selective in that certain cellular components (e.g., the plasmalemma) remain unaffected. Concomitant with lysis is the formation of sieve-area pores from plasmodesmata. Comparison of pore size on end and lateral walls indicates that the use of the term “sieve tube” rather than “sieve cell” to describe these elements is appropriate.