Membrane recycling occurs during asymmetric tip growth and cell plate formation inFucus distichus zygotes

Summary Zygotes of the brown algaFucus distichus undergo a series of intracellular changes resulting in the establishment of a polar growth axis prior to the first embryonic cell division. In order to examine the dynamics of membrane recycling which occur in the zygote during polar growth of the rhizoid, we probed living Fucus zygotes with the vital stain FM4-64, N-(3-triethylammoniumpropyl)-4-(6-(4-(diethylammo)phenyl)hexatrienyl)pyridinium dibromide. In newly fertilized, spherical zygotes, FM4-64 staining is symmetric and predominantly in the perinuclear region which is rich in endoplasmic reticulum, Golgi, and vacuolar membranes. As rhizoid or tip growth is initiated, this population of stained membranes becomes asymmetrically redistributed, concentrating at the rhizoid tip and extending centrally to the perinuclear region. This asymmetric localization is maintained in the zygote throughout polar growth of the rhizoid and during karyokinesis. Subsequently, FM4-64 staining also begins to accumulate in a central location between the daughter nuclei. As cytokinesis proceeds, this region of stain expands laterally from this central location, perpendicular to the plane of polar rhizoid outgrowth. The staining pattern thus delineates the formation of a cell plate, similar spatially to the accumulation of nascent plate membranes of higher plants. Treatment of Fucus zygotes with brefeldin-A inhibits both asymmetric growth of the rhizoid and formation of a new cell plate. These data suggest that inF. distichus FM4-64 is labeling a Golgi-derived membrane fraction that appears to be recycling between the site of tip growth, perinuclear region, and new cell plate.Abbreviations AF after fertilization - ASW artificial seawater - BFA brefeldin A - ER endoplasmic reticulum - FM4-64 N-(3-triethylam-moniumpropyl)-4-(6-(4-(diethylamino)phenyl)hexatrienyl)pyridinium dibromide     

Effects of caffeine on germination and differentiation in spores of the fern, Onoclea sensibilis

During spore germination in the fern, Onoclea sensibilis L., the nucleus moves from a central position to one end, and an asymmetrical cell division partitions the spore into two cells of greatly unequal size. The smaller cell differentiates directly into a rhizoid, whereas the larger cell and its derivatives give rise to the prothallus. In the presence of 5 mM caffeine, the nuclei of most of the spores undergo mitotic replication, whereas cell wall formation is blocked. Multinucleate single cells are produced, which are capable of growth, but no rhizoid differentiation occurs. In some cases a partial cell wall is produced, but the nucleus moves through the discontinuity back to the center of the spore, and the enucleate, incompletely partitioned small “cell” fails to differentiate into a rhizoid. In less than 1% of the spores a broad protuberance, whose wall is yellow-brown, is formed in a multinucleate single cell. The color, staining reaction to ruthenium red, and ultrastructural appearance of the protuberance resemble that of the rhizoid wall. It appears that infrequently in the caffeine-treated spores, a feature which is characteristic of rhizoids is expressed, in the absence of asymmetric cell division, in a cell which otherwise is unable to produce a rhizoid. The results are interpreted to mean that the spore has a highly localized, persistent differentiated region. For rhizoid differentiation to occur, a nucleus must be confined in that region – a confinement which normally is accomplished by the geometrically asymmetric first cell division of germination.     

pH gradients and cell polarity inPelvetia embryos

Summary Endogenous pH profiles were measured around single fertilized eggs of the brown algaPelvetia during the earliest stages of development. Profiles were constructed by measuring the pH near the cell surface at several positions using a pH sensitive microelectrode. Transcellular pH differences in the medium surrounding zygotes were detected soon after fertilization, as the developmental axis was being formed. The future rhizoid end of the cell was relatively alkaline and the presumptive thallus was acidic. At germination and throughout the first 5 d of embryogenesis, the apex of the elongating rhizoid was alkaline with respect to more distal regions. However, conditions that dissipated or reversed this extracellular pH gradient had little or no effect on polarization or growth, indicating that the gradient was not essential for early development.Inhibition of respiratory electron transport by cyanide and antimycin A eliminated the pH gradient, while uncouplers of oxidative phosphorylation [2,4-dinitrophenol (DNP) and carbonylcyanide m-chlorophenylhydrazone (CCCP)] stimulated acidification of the thallus regions. Proton ATPase inhibitors had no effect. Acidification, therefore, is not generated by ATP-dependent proton pumps in the plasma membrane, and instead probably reflects secretion of metabolic acids. Localized metabolism may establish an internal pH gradient that controls regional differentiation, and we are presently investigating this possibility.Abbreviations ASW artificial seawater - CCCP carbonylcyanide m-chlorophenylhydrazone - CD cytochalasin D - DNP 2,4-dinitrophenol     

The pulse current pattern generated by developing fucoid eggs

Using a newly developed extracellular vibrating electrode, we have made the first study of the spatial distribution of the growth currents around a single developing egg. This pattern was studied during the current pulses wihic traverse two-celled Pelvetia embryos. These pulses can be stimulated to occur with a periodicity of 70 min by mild acidification of the dea water medium. Current enters only at the growing rhizoid's tip while leaving both the base of the rhizoid cell and the whole outer membrane of the thallus cell. The field in front of the rhizoid cell falls off as the inverse cube of the distance from the rhizoid cell's center in the manner of a dipole field. The total inward and outward currents are equal, agreeing with theory. The current density at the rhizoid cell's base is twice that at the top of the thallus cell and this probably represents a change in the outer membrane's properties. There are no significant differences in the durrent density over the thallus cell. These results suggest a model in which the pulse current leaks in through newly opened channels in the growing tip and leaks out elsewhere due to the resultant fall in the membrane potential.     

Localization of Actin mRNA during the Establishment of Cell Polarity and Early Cell Divisions in Fucus Embryos

Localization of mRNA is a well-described mechanism to account for the asymmetric distribution of proteins in polarized somatic cells and embryos of animals. In zygotes of the brown alga Fucus, F-actin is localized at the site of polar growth and accumulates at the cell plates of the first two divisions of the embryo. We used a nonradioactive, whole-mount in situ hybridization protocol to show the pattern of actin mRNA localization. Until the first cell division, the pattern of actin mRNA localization is identical to that of total poly(A)+ RNA, that is, a symmetrical distribution in the zygote followed by an actin-dependent accumulation at the thallus pole at the time of polar axis fixation. At the end of the first division, actin mRNA specifically is redistributed from the thallus pole to the cell plates of the first two divisions in the rhizoid. This specific pattern of localization in the zygote and embryo involves the redistribution of previously synthesized actin mRNA. The initial asymmetry of actin mRNA at the thallus pole of the zygote requires polar axis fixation and microfilaments but not microtubules, cell division, or polar growth. However, redistribution of actin mRNA from the thallus pole to the first cell plate is insensitive to cytoskeletal inhibitors but is dependent on cell plate formation. The F-actin that accumulates at the rhizoid tip is not accompanied by the localization of actin mRNA. However, maintenance of an accumulation of actin protein at the cell plates of the rhizoid could be explained, at least partially, by a mechanism involving localization of actin mRNA at these sites. The pattern and requirements for actin mRNA localization in the Fucus embryo may be relevant to polarization of the embryo and asymmetric cell divisions in higher plants as well as in other tip-growing plant cells.     

CYTOLOGICAL AND CYTOCHEMICAL STUDIES OF GREEN MONKEY KIDNEY CELLS INFECTED IN VITRO WITH SIMIAN VIRUS 40

Cytological and cytochemical studies of green monkey kidney cells infected with SV40 virus indicated that the type of lesion produced was influenced by the multiplicity of infection and that the lesions appeared later and progressed more slowly when the inoculum was diluted. The earliest change consisted of enlargement of ribonucleoprotein-containing spherules in the nucleolus (nucleolini). This was followed by rarefaction, with or without condensation, of the chromatin and the appearance of one or more homogeneous masses of inclusion material containing DNA, RNA, and non-histone protein which eventually filled the nucleus. In some instances the chromatin appeared to be directly transformed into inclusion material. In the later stages of infection, the ribonucleoprotein of the nucleolini was no longer stainable and material resembling the nucleoprotein of the intranuclear inclusions was found in the nucleolar vacuoles and in the cytoplasm. The nucleic acids in the inclusions were stained by toluidine blue, toluidine blue-molybdate, the Feulgen stain, and by methyl green. The stainable material was extractable by nuclease digestion or by hot trichloroacetic acid. Green or yellowish green staining by acridine orange was apparently due to binding of dye by protein and not by nucleic acids since the staining reaction was not reduced by extraction of nucleic acids by hot trichloroacetic acid. Extraction with pepsin in combination with ribonuclease or deoxyribonuclease removed practically all the inclusions from the cells; consequently they could not be stained with acridine orange. The cytochemical studies suggest that the use of pepsin together with nuclease is not a meaningful technique.     

Effects of microtubule-inhibitors on nuclear migration and rhizoid differentiation in germinating fern spores (Onoclea sensibilis)

Summary Germinating spores of the sensitive fern,Onoclea sensibilis L., undergo premitotic nuclear migration before a highly asymmetric cell division partitions each spore into a large protonemal cell and a small rhizoid initial. Nuclear movement and subsequent rhizoid formation were inhibited by the microtubule (MT) inhibitors, colchicine, isopropyl-N-3-chlorophenyl carbamate (CIPC) and griseofulvin. Colchicine prevented polar nuclear movement and cell division so that spores developed into enlarged, uninucleate single cells. CIPC and griseofulvin prevented nuclear migration, but not cell division, so that spores divided into daughter cells of approximately equal size. In colchicine-treated spores, MT were not observed at any time during germination. CIPC prevented MT formation at a time coincident with nuclear movement in the control and caused a disorientation of the spindle MT. Both colchicine and CIPC appeared to act at a time prior to the onset of normal nuclear movement. The effects of colchicine were reversible but those of CIPC were not. Cytochalasin b had no effect upon nuclear movement or rhizoid differentiation. These results suggests that MT mediate nuclear movement and that a highly asymmetric cell division is essential for rhizoid differentiation.     

Metal-binding sites in germinating fern spores (Onoclea sensibilis)

Summary During germination of the spore of the sensitive fernOnoclea sensibilis L. the nucleus migrates from a central position to the proximal face and then to one end of the ellipsoidal spore. An asymmetric cell division follows giving rise to a small cell which differentiates immediately into a rhizoid, and a large cell which divides further to give rise to the prothallus. The proximal face of the spore coat is differentiated from the remainder of the spore by its ability to bind nickel ions under certain conditions and by its staining with a sulfide-silver procedure which localizes heavy metals. The inner portion of the exine at the proximal face is differentiated from the outer part by its ability to stain with sulfide-silver at specific periods during germination. The exine at the proximal face also contains pore-like structures 50 nm in diameter which extend from the inner layer of the exine to the outer surface. Sulfide-silver staining material appears to be extruded through the pores at specific periods during germination. The percentage of spores showing nickel-binding and sulfide-silver stainability increases sharply during the first two to four hours of imbibition, then decreases sharply during the following two hours. This is followed by a second rise in staining at 8 to 12 hours of imbibition.The role of the ion-binding sites in the exine is discussed in relation to the stable polarity of the spore.Publishing prior to 1984 asAlix R. Bassel     

Division patterns in the thallus ofPelvetia compressa embryos and the effects of gravity

Summary The pattern of divisions in the thallus ofPelvetia compressa embryos was determined with respect to the embryonic growth axis. To detect all possible division planes, embryos were viewed from two vantages which permitted observations of (1) the thallus pole and (2) the longitudinal embryonic profile. Following formation of rhizoid and thallus cells by any asymmetrical division transverse to the embryonic axis that is established prior to any divisions, the thallus cell divided twice along the embryonic axis (axial divisions) in orthogonal planes, and then divided transverse to the growth axis. This division pattern produced an eight-cell thallus with four cells in each of two layers. The spatial relation between gravity and the first axial division was investigated, and gravity was found to have little effect on the alignment of this division. The reproducible pattern of divisions in the thallus indicates spatial control of spindle positioning.Abbreviations ASW artificial seawater - AF after fertilization     

SPORE GERMINATION AND DEVELOPMENT OF THE YOUNG GAMETOPHYTE OF THE OSTRICH FERN (MATTEUCCIA STRUTHIOPTERIS)

Light is required for the germination of spores of Matteuccia struthiopteris. Histochemical studies show that dormant spores contain no starch, but have an abundance of storage protein granules. Starch accumulates in the numerous chloroplasts of the spore on exposure to light and becomes gradually more extensive. Protein granules disappear as germination progresses. Following this, the centrally located nucleus migrates toward the proximal spore face. Concomitant with the nuclear migration, an increase of cytoplasmic RNA surrounding the nucleus occurs. An equal nuclear division and unequal cell division give rise to a 2-celled gametophyte consisting of a large prothallial cell and smaller rhizoidal cell. A new peripheral wall forms around the entire protoplast at the time of nuclear migration, while a transverse wall forms after nuclear division. The rhizoid emerges through the split raphe along the proximal spore face; it is rich in cytoplasmic RNA but contains very few chloroplasts and little starch. Electron microscopy of the 2-celled stage revealed a greater concentration of mitochondria, Golgi bodies, and a more extensive endoplasmic reticulum in the rhizoid than was found in the prothallial cell, which, however, was far richer in chloroplasts and lipid bodies. As the rhizoid elongates and becomes more vacuolated, cytoplasmic RNA decreases as cytoplasmic protein increases. The rhizoid undergoes no cell divisions, while the prothallial cell retains the potential for further cell division. The possible significance of the distribution of storage products, cell organelles, and other cell components were considered in relation to the non-equational cell division and differentiation of the 2 cells.     

Apical Structure of Actively Growing Fern Rhizoids Examined by DIC and Confocal Microscopy

The development and cytology of gametophyte primary rhizoidsof the fern Dryopteris affinis was examined using actively growingmaterial. During development an apical cytoplasmic ‘ accumulation’forms and is associated with active tip growth. This accumulationdeteriorates as terminal differentiation and cessation of growthapproaches. During early development the nucleus moves fromthe rhizoid cell base into the newly extending rhizoid. Later,during the active elongation phase, the nucleus takes up a relativelystable location approx. 100 µm behind the extending apex.Towards terminal differentiation the nucleus lags further behindthe tip. In actively growing rhizoids four distinct zones weredistinguished: a richly cytoplasmic ‘cap’; an apicalregion with tubular vacuolar intrusions; a region distinguishedby a peripheral sheath of cytoplasm and fine irregular cytoplasmicstrands connecting to the nucleus; and the main subapical vacuole.Confocal microscopy of gametophytes stained with fluorescentvital dyes, not previously used to examine fern rhizoid structure,confirmed that the tubular vacuolar system extends well intothe apical cytoplasm, and that the network of fine cytoplasmicstrands leads back from the apical cytoplasm to the nucleus.It also revealed that mitochondria are distributed throughoutthe rhizoid and are not excluded from the extreme apex. Membranestaining by FM 4-64 suggested a high density of membrane vesicleswithin the cytoplasm of the extreme apex. Uptake of this endocytosismarker into endomembranes also suggested rapid plasma membraneturnover in the rhizoid. This study highlights the similarityin the developmental stages and appearance of D. affinis rhizoidsto angiosperm root hairs and their much less distinct apicalzonation compared to pollen tubes. Copyright 2000 Annals ofBotany Company Rhizoid, root hair, confocal imaging, vital stains.     

Egg release and germling development in Sargassum horneri (Fucales, Phaeophyceae)

The mature female conceptacle of Sargassum horneri (Turner) C. Agardh has an ostiole filled with a gelatinous plug. The oogonium in the conceptacle has cell walls that can be differentiated into a dense outer and a less dense inner microfibrillar layer. Just prior to egg release, stalk material is produced inside the outer layer and the inner layer disappears. At this stage the gelatinous plug is extruded and mucilage is released through the ostiole. The released eggs are retained on the receptacle by the stalk and are surrounded by a large amount of the mucilage. Three-celled germlings form a primary wall with a polylamellated structure of microfibril layers. In multicellular germlings that have differentiated into thallus and rhizoids, the peripheral thallus cells have an outer cell wall consisting of a microfibril layer under the primary wall, while the cell wall of the rhizoid tip has an amorphous structure. The germlings are released from the stalk and become attached to the substratum by an adhesive substance secreted from rhizoidal cells.     

纵胞藻切段再生的初步研究

作者将纵胞藻切成1.5—3mm长的切段,用PES培养液,室内漫射光进行培养,成功地得到大量纵胞藻再生植株。通过实验探讨,作者认为纵胞藻的切段再生现象可能是该种海藻营养繁殖的一种形式。     

Fixation and Staining of the Bacterial Nucleus

An examination of some early methods in bacterial cytology shows that technics for demonstrating the nucleus of the Eubacteriales were available for at least twenty years before the current era of investigation, which began in 1942. Although the bacterial nucleus reacts in many respects like the chromatin elements of higher plants, it shows certain peculiarities in its staining reactions. For example, hematoxylin, methyl green, and several preparations used to stain chromosomes, apparently do not exhibit the same affinity for the bacterial nucleus that they do for chromosomes in higher plants. Not only is the selection of a fixative important in nuclear studies, but also the manner in which the fixation is obtained. For example, when bacteria are fixed and processed in a completely wet state it is generally impossible to stain their nuclei. None of the special fixatives studied revealed any unusual organization in the bacterial cell or exhibited any advantage over the fixatives now in common use by bacteriologists. In view of the properties of osmium tetroxide vapor, particularly its relative lack of interference with positive nuclear staining, there can be little doubt of its superiority as a nuclear fixative. It appears that the basophilic material removed from the bacterial cell by hydrochloric acid is not only in the cytoplasm, but that a very significant amount of it is in close contact with the cell wall.     

纵胞藻切段再生的初步研究

作者将纵胞藻切成1.5—3mm长的切段,用PES培养液,室内漫射光进行培养,成功地得到大量纵胞藻再生植株。通过实验探讨,作者认为纵胞藻的切段再生现象可能是该种海藻营养繁殖的一种形式。     

GIBBERELLIC ACID-INDUCED GERMINATION OF SPORES OF ANEMIA PHYLLITIDIS: NUCLEIC ACID AND PROTEIN SYNTHESIS DURING GERMINATION

The distribution and synthesis of nucleic acids and proteins during gibberellic acid-induced germination of spores of Anemia phyllitidis were studied in order to relate biochemical activity with morphogenetic aspects of germination. Germination is accompanied by the hydrolysis of storage protein granules and the localized appearance of cytoplasmic RNA, protein, and insoluble carbohydrates in a small area adjoining the spore wall and surrounding the nucleus. The protoplast of the spore enlarges in this region, the spore wall breaks and a protonemal cell is formed which contains many chloroplasts. A second division in the spore at right angles to the first yields a rhizoid cell. Autoradiography of ³H-thymidine incorporation has shown that DNA is synthesized both in the nucleus and in the immediately surrounding cytoplasm of the germinating spore until some time after the first division, although a strictly nuclear DNA synthesis is observed later. Synthesis of RNA and proteins is limited to the presumptive regions of the germinating spore which become the protonema and rhizoid, shifting to specific sites in these cells as germination proceeds. The nucleus of the spore continues to be biosynthetically active long after it ceases to divide.     

The role of asymmetric cell division in pteridophyte cell differentiation. I. Localized metal accumulation and differentiation inVittaria gemmae andOnoclea prothallia

Summary In gemmae ofVittaria graminifolia and prothallia ofOnoclea sensibilis, cell differentiation is initiated by nuclear migration and geometrically asymmetric cell division. The small daughter cells inVittaria develop into antheridia in the presence of gibberellic acid or into rhizoids or new prothallia in its absence. Antheridial differentiation from asymmetric division is induced inOnoclea byPteridium antheridiogen, whereas rhizoid or vegetative cell formation occurs in its absence. Although asymmetric cytokinesis initiates differentiation, it does not in itself determine the developmental fate of the smaller cell. Several histochemical techniques demonstrate that prior to nuclear migration and cell division, Ca²⁺ accumulates in the cytoplasm and wall of the cell at the site where asymmetric division will occur, regardless of the developmental fate of the small cell. The cytoplasmic localization of Ca²⁺ appears to reflect a mobilization of Ca²⁺ from within the cell that eventually moves into the cell wall. We propose that this internal accumulation of Ca²⁺ leads to a localized decrease in cytosolic [Ca²⁺] which in turn may regulate developmental events such as nuclear migration.Publishing prior to 1984 as Alix R. Bassel.     

Autofluorescence of intact Equisetum arvense L. spores during their development

The autofluorescence of horsetail Equisetum arvense spores excited with UV-light of 360-380 nm was studied by microspectrofluorimetry during their development from an individual cell to the formation of a multicellular thallus with the generative organs. The investigation involved the registration of the fluorescence spectra of individual intact developing cells and the measurement of the ratio of cell fluorescence intensities in the blue and red regions of the spectrum. Dry blue-fluorescing microspores showed the maxima at 460 and 530 nm and a small maximum at 680 nm. Thirty minutes after moistening in water, red-fluorescing cells arose among blue-fluorescing microspores, indicating the onset of development. Red fluorescence with a maximum at 680 nm enhanced as cells put off their cover, which brightly fluoresced in the blue region of the spectrum with the main maximum at 460 nm. By estimating the ratio of autofluorescence intensities in the blue region of the spectrum to red lightening of microspores at the first stages of development up to 24 h (in particular, their first division, the formation of nonfluorescencing rhizoid, etc.), nonviable (only blue-lightening) cells were distinguished from viable cells, in which red fluorescence began to prevail. After 25-40 days of development, the gametophyte fluorescing mainly at 680 nm formed male organs, antheridia, with blue-green-fluorescing spermatozoids. Then female generative organs archegonia with the egg cell appeared, which fluoresced blue, whereas the surrounding cells fluoresced red. It was supposed that the lightening in the blue and green regions of the spectrum is due to the presence of phenols, terpenoids, and azulenes, whereas the emission in the red region is associated with the presence of chlorophyll and azulenes. The observation of autofluorescence makes it possible to easily distinguish generative cells without additional staining.     

浒苔(Enteromorpha prolifera)藻体发育的显微观察

通过显微镜观察以及石蜡切片法观察了浒苔属浒苔藻体的发育过程,阐述了浒苔从孢子释放到形成成熟藻体这一发育过程的显微特征。结果表明:浒苔孢子由成熟体细胞分化发育而成,每个成熟体细胞可形成10～30个孢子;孢子首先分裂为2细胞结构,2细胞具有明显的极性,基细胞发育成为假根,顶端细胞不断进行横分裂形成丝状体;丝状体顶端以下细胞通过纵分裂形成管状叶状体,顶端细胞始终保持横分裂;纵分裂分为切向分裂与径向分裂,切向分裂增加管状叶状体管周细胞数从而使管体增大,径向分裂形成管外壁突起细胞,最终发育为分枝;管状叶状体管腔内部有绒毛状的突起及糖蛋白成分的网架结构;当管状叶状体管周细胞达到30～50h,管腔内部突起消失,网架结构收缩拉紧,管壁细胞贴近形成片状叶状体;整个浒苔藻体始终保持极性发育。