A cell-free system for light-dependent nuclear import of phytochrome.

Translocation from the cytosol to the nucleus is an essential step in phytochrome (phy) signal transduction. In the case of phytochrome A (phyA), this step occurs with the help of FHY1 (far-red-elongated hypocotyl 1), a specific transport protein. To investigate the components involved in phyA transport, we used a cell-free system that facilitates the controlled addition of transport factors. For this purpose, we isolated nuclei from the unicellular green algae Acetabularia acetabulum. These nuclei are up to 100 mum in diameter and allow easy detection of imported proteins. Experiments with isolated nuclei of Acetabularia showed that FHY1 is sufficient for phyA transport. The reconstituted system demonstrates all the characteristics of phytochrome transport in Arabidopsis thaliana. In addition, FHY1 was also actively exported from the nucleus, consistent with its role as a shuttle protein in plants. Therefore, we believe that isolated Acetabularia nuclei may be used as a general tool to study nuclear transport of plant proteins.

Involvement of bristle coat structures in surface membrane formations and membrane interactions during coenocytotomic cleavage in caps of Acetabularia mediterranea.

In the multinucleate cap rays of the green alga Acetabularia mediterranea the cell surface increases dramatically within a short time period during the final stages of coenocytotomic cleavage. In early stages of cyst formation the cytoplast is traversed by numerous large and prolate cleavage vesicles which are characterized by typical columellar or spinous coat structures. The cleavage vesicles are closely associated with the surface of plastids and, to a lesser degree, of mitochondria. This intimate association seems to be mediated by regularly spaced, densely stained intermembranous cross-bridge structures and is maintained throughout cleavage. These cleavage vesicles contain a finely fibrillar material structurally similar to the hyaline layer of mucilage that fills the space between the plasma membrane and cell wall. They line up with invaginations of the plasmalemma and vacuole membranes and, together with smaller vesicles interspersed, constitute preformed "perforation lines" for the final separation of the coenoblast portions. Equidistantly spaced plaques of attachment of such vesicles with surface membrane are described. We hypothesize (a) that the cleavage vesicle membrane is the immediate precursor to the new postcoenocytotomic surface membrane, (b) that the cleavage vesicle coat structures are integrated into the subsurface coat of the plasma membrane, (c) that growth of the laterally attached cleavage vesicles by intussusception of small fuzzy-coated vesicles is confined to their "free ends," (d) that the intermembranous cross-bridge elements are related to bristle coat structures and play a role in the establishment of the cleavage lines, and (e) that the coenocytotomic cleavage process is organized so that adjacent plastids are separated in a way that guarantees the inclusion of several plastids in each cyst.

Use of the fluorochrome 4'6-diamidino-2-phenylindole in genetic and developmental studies of chloroplast DNA.

Use of the DNA-specific fluorochrome 4'6-diamidino-2-phenylindole (DAPI) makes it possible to examine in situ the structure of chloroplast DNA (chDNA) with the fluorescence microscope. This simplifies the study of genetic and developmental changes in chloroplast DNA. Three examples are presented. (a) Wild-type Euglena gracilis B contains several chloroplast DNA nucleoids per chloroplast. A yellow mutant lacking functional chloroplasts is similar, but such nucleoids are absent in an aplastidic mutant strain known from biochemical studies to have lost its chDNA. (b) In vegetative cells of the giant-celled marine algae Acetabularia and Batophora, only about a quarter of the chloroplasts have even one discernible chloroplast DNA particle, and such particles vary in size, showing a 30-fold variation in the amount of DNA-bound DAPI fluorescence detected per chloroplast. By contrast, 98% of chloroplasts in developing Acetabularia cysts contain chDNA, with as many as nine nucleoids per chloroplast. (c) DAPI-stained chloroplasts of chromophyte algae display the peripheral ring of DNA expected from electron microscope studies. However, these rings are not uniform in thickness, but are necklace-like, with the appearance of beads on a string. Since the multiple nucleoids in plastids of chlorophyte algae also appear to be interconnected throughout the chloroplast, a common structural plan may underlie chDNA morphology in both groups of algae.

Growth of the nuclear envelope in the vegetative phase of the green alga Acetabularia. Evidence for assembly from membrane components synthesized in the cytoplasm.

The primary nucleus of the green alga Acetabularia grows about 25,000-fold in volume while it is separated from the endoplasmic reticulum and the whole cytoplasm by a special paranuclear cisterna of a vacuolar labyrinthum system which shows only very few (two to six per square micrometer) and small (ca. 40-120 nm in diamter) fenestrations. The nuclear envelope does not bear polyribosomes, nor do they occur in the entire zone intermediate between the nuclear envelope and the paranuclear cisterna. It is suggested that this special form of nuclear envelope growth takes place by assembly from cytoplasmically synthesized proteins that are translocated across the paranuclear cisterna in a nonmembrane-structured form.

Chloroplast membranes of the green alga Acetabularia mediterranea. II. Topography of the chloroplast membrane.

The localization of the chlorophyll-protein complexes inside the thylakoid membrane of Acetabularia mediterranea was determined by fractionating the chloroplast membrane with EDTA and Triton X-100, by using pronase treatment, and by labeling the surface-exposed proteins with 125I. The effects of the various treatments were established by electrophoresis of the solubilized membrane fractions and electron microscopy. After EDTA and pronase treatment, the membrane structure was still intact. Only the two chlorophyll-protein complexes of 67,000 and 152,000 daltons and an additional polypeptides were found in the membrane before the EDTA and pronase treatment. The 125,000 dalton complex seems to be buried inside the lipid layer. The 23,000 dalton subunit of the 67,000 dalton complex is largely exposed to the surface of the EDTA-insoluble membrane and only the chlorophyll-binding subunit of 21,500 daltons is buried inside the lipid layer.

Dynamics and pharmacological perturbations of the endoplasmic reticulum in the unicellular green alga Acetabularia.

The giant unicellular green alga Acetabularia was labeled with the lipophilic fluorochrome DiOC6 (3,3'-dihexyloxacarbocyanine) and examined by confocal laser scanning microscopy to study the distribution of the endoplasmic reticulum (ER) and its dynamic changes after the application of inhibitors. In control cells, a two-dimensional polygonal network of ER sheets and tubulus is suspended between parallel, longitudinally oriented bands. These bands coincide with the main physical tracks of organelle transport. All treatments that inhibited organelle motility caused a transformation of the polygonal network into confluent large patches of lamellar ER sheets. The shape of the lamellar sheets and residual activities of the ER were dependent on the inhibitors used. The largest ER lamellae were obtained after cytochalasin D (CD) treatment which effectively stopped cytoplasmic streaming. CD also caused the formation of a network of fine tubules overlapping with the lamellar sheets. Okadaic acid, a specific inhibitor of serine/threonine-protein phosphatases, also caused inhibition of organelle movement and enlargement of lamellar areas. Tension in the cytoplasm appeared to be reduced, as judged from the convexly curved lamellar rims and wavy connecting ER tubules. In contrast, N-ethylmaleimide, a sulfhydryl group blocking reagent, rapidly stopped streaming and halted all activities of the ER in a rigor-like state. These effects are interpreted in the context of actin-based motility phenomena prevalent in Acetabularia, and regulatory principles are discussed that might underlie ER dynamics.

Accumulation of peroxidase in the cap rays of Acetabularia during the development of gametangia.

Accumulation of peroxidase was demonstrated by light and electron microscopy to occur in Acetabularia in certain regions of the cap rays in relation to the development of the gametangia (cysts). Peroxidase was found to be incorporated into special, cell wall-like obstructions that separate the cap rays from the stalk when the secondary nuclei have settled in the cap rays. It is assumed that peroxidase acts as an anti-microbial protectant of the gametangia.

Temporal morphology and cap formation in Acetabularia--I. Light-dark cycle perturbations.

Cap formation, a major developmental process in the alga Acetabularia, is influenced by a single perturbation of the entraining light-dark schedule and thus, presumably, of the circadian rhythms. This perturbation is brought about several weeks before cap formation, the most conspicuous expression of morphogenesis in Acetabularia. The effect is more pronounced on cap formation than on growth. It varies in importance with the circadian time at which the perturbation was brought about. The effect is dependent on the developmental state of the alga: transfer carried out during the logarithmic phase of growth produces a delay whose importance decreases with time. When carried out during the phase of slow terminal growth, the transfer induces a transitory acceleration of cap formation. When the algae approach their final length, no effect is elicited. Photoperiodism seems to be involved.

Temporal morphology and cap formation in Acetabularia--II. Effects of morphactin and auxin.

In order to support the hypothesis that circadian rhythms are implicated in cap formation, experiments were undertaken on the possible time-dependency of the effects of (a) a competitive inhibitor of auxins, morphactin and (b) of auxin (IAA). It was found that: (i) the inhibitory effect of morphactin varies dramatically with the time at which the several weeks' treatment was first begun; (ii) the maximum inhibition varies with development and decreases with time; (iii) IAA accelerates cap formation when the algae are submitted to IAA during the exponential growth phase; the effect is time dependent and decreases with time; (iv) IAA first applied on smaller algae has a transient inhibitory effect which is time dependent; (v) anucleate fragments also respond differentially to an IAA treatment begun at several times in the 24-hr cycle, most clearly when newly formed mRNA have been accumulated and (vi) the effect of iAA is not cumulative with that of a LD shift; that of morphactin is not, or only slightly, improved by a LD shift.

[Ultrathin structure of normally growing and regenerating cells of Acetabularia mediterranea]. / Ul'tratonkoe stroenie normal'no rastushchikh i regeneriruiushchikh kletok Acetabularia mediterranea

The ultrastructure of nucleus and cytoplasm in regenerating cells of Acetabularia mediterranea differs from that in normally growing ones: the nucleus of regenerating cells form numerous outgrowths; the cortical layer of nucleolus disintegrates markedly; the emission of nucleolar material in the nucleoplasm is observed. In the cytoplasm the portion of active chloroplasts increases and a great number of tubular fibrils appears. In the cytoplasm of regenerating cells the Golgi dictyosomes occur more frequently and the vesicles at their ends are larger than in that of normally growing cells. The changes of macromolecular organization of the nucleus and cytoplasm in question observed at the earlier stages of regeneration (2--12 hrs) suggest the increase of metabolic activity of cells.

[Morphogenesis of reconstructed enucleated Acetabularia cells]. / Morfogenez rekonstruirovannykh énukleirovannykh kletok Acetabularia

Survival and morphogenesis of the enucleated fragments of Acetabularia has been studied after their reconstruction from the cell membrane and the endoplasm. Membranes and endoplasms of different species as well as of the same species but from plants in different functional states and with different regenerative abilities were combined. It was shown that inability of plants for growth and morphogenesis was due to the membrane state. When reconstructing anuclear fragments from membranes and endoplasms of different species or the same species but from plants in different functional states, a phenomenon of membrane-endoplasm incompatibility was found.

[Effect of colchicine on the morphogenesis and ultrastruct of Acetabularia mediterranea]. / Vliianie kolkhitsina na morfogenez i ul'trastrukturu Acetabularia mediterranea.

The effect of colchicine on morphogenesis of the regenerating nuclear fragments of Acetabularia mediterranea has been studied. Colchicine was shown to inhibit the formation of caps. The algae are most sensitive to colchicine at the early stages of regeneration. The breakdown of microtubules in the perinuclear cytoplasm of regenerating algae under the effect of colchicine was found under the electron microscopy. The breakdown of microtubules in this zone appears not to disturb the transport of morphogenetical substances in the apical cell part. Colchicine inhibits the morphogenesis, apparently, at the expense of protein inactivation in the zone of growth.

Development and organization of the central vacuole of Acetabularia acetabulum.

* Here we analyzed the shape of the central vacuole of Acetabularia acetabulum by visualizing its development during diplophase (from juvenility through reproduction) and haplophase (from meiosis through mating). * Light microscopy and whole-organism applications of a pH-sensitive dye, neutral red, were used to visualize the anatomy of the central vacuole. We studied connectivity within the thallus by locally applying dye to morphologically distinct regions (rhizoid, stalk, apex, hairs) and observing dye movements. * In vegetative thalli most of the rhizoid, stalk and young hairs stained with dye. In reproductive structures (caps, gametangia) dye also stained the majority of the interiors. When applied to small areas, dye moved at different rates through each region of the thallus (e.g. within the stalk). Dye moved from younger hairs, but not from older hairs, into the stalk. Errors in incorporation of central vacuole into gametangia occurred at <10(-5). * These data indicate that the central vacuole of A. acetabulum is a ramified polar organelle with, potentially, a gel-like sap that actively remodels its morphology during development.

Lampbrush-type chromosomes in the primary nucleus of the green alga Acetabularia mediterranea.

Structures with a lampbruch-chromosome-like morphology are described in the nucleoplasm of primary nuclei of the green alga, Acetabularia mediterranea, by light and electron microscopy in sections of cells fixed in situ and in spread preparations of isolated nuclear components. These chromosomes reveal typical loops (up to 20 micronm long), chromomere-like nodules (1-2 micronm in diameter), and 2-4 micronm large axial globules. Associations of some of these chromosomes with nucleolar structures and with the nuclear envelope are also recognized. The light microscopically identified loops are correlated with distinct fibrillogranular structures observed in the thin sections and with the very long matrix units seen in the spread preparations. The similarity of these structures to the lampbrush chromosomes of various animal cell types, all exclusively stages of meiotic prophase, is discussed as well as the possible relation of the appearance of lampbrush chromosomes to a defined phase of the vegatative growth of this alga.

Magnetic resonance imaging approaching microscopic scale: maturation stages of Acetabularia mediterranea reproductive caps.

The reproductive cap of the giant single-celled alga Acetabularia mediterranea (or A. acetabulum) has rays tapering from a width of about 400 microns at the circumference of the cap to about 30 microns at their junction with the stalk of the cell. This is ideal geometry for testing the current limits of spatial resolution of proton magnetic resonance imaging. In this work, resolution of features down to 40 microns is achieved. Maturation of the cap rays involves a major cytoplasmic reorganization, from continuous cytoplasm and a central vacuole in each ray to bundles of cysts surrounded by aqueous solution. This work shows that an intermediate stage in the change can be highlighted in images by relaxation time (T1) contrasting.

Cytoplasmic induction of changes in the ultrastructure of the Acetabularia nucleus and perinuclear cytoplasm.

The ultrasturcture of the cell nucleus and perinuclear cytoplasm in Acetabularia is quite different in young and old cells. When a nucleus of an old cell was implanted into the cytoplasm of a young cell the nucleus assumed the morphology typical of a young cell within less than 10 days. The cytoplasm of an old cell was able to induce the reverse change in an implanted nucleus from a young cell. This cytoplasmic induction of nuclear ageing appeared to proceed more rapidly than rejuvenation.

Acetabulaira mediterranea: circadian rhythms of photosynthesis and associated changes in molecular structure of the thylakoid membranes.

Acetabularia mediterranea algae, grown in three different light-dark regimes, were frozen in liquid nitrogen at c.t.(1) 0 and c.t. 6 and a record made of 77 degrees K fluorescence emission spectra of their chloroplasts. Algae grown under LD cycles exhibited a clear circadian rhythm of oxygen production. The low temperature fluorescence emission spectrum at c.t.0 was different from that at c.t.6 and this difference was increased by submitting the algae to successive "freeze-thaw" treatment. Similar results were obtained in DD, and the photosynthesis rhythm remained fully expressed. Algae grown in LL, where no rhythm of photosynthesis could be detected in the samples because there is a great individual variability in period lenght under these conditions, exhibited a similar difference in their low temperature flourescence emission spectra between c.t.0 and c.t.6. We conclude that the circadian rhythm in low-temperature fluorescence emission of the chloroplasts in Acetabularia is related to the circadian rhythm in photosynthesis.

[The biological clock: circadian organization of the cell (author's transl)]. / Die biologische Uhr, zirkadiane Organisation der Zelle

Unicellular systems, and particularly individual cells, are advantageous in investigating the molecular mechanism of the circadian rhythm. The greeen alga Acetabularia has proven to be a uniquely suitable organism. Experiments are described which indicate that the circadian rhythm is due to a sequence of events which are casually interrelated. A model is presented which is based on a two-step mechanism, the first step of which is the synthesis of "essential polypeptides" on 80 S ribosomes. In a second step these polypeptides are consumed. The function of the "essential polypeptides" is to change a membrane component of the circadian clock. The membrane participates in a feed-back mechanism which produces a periodic alteration of the rate of synthesis of "essential polypeptides" and of photosynthesis. It is possible to draw parallels between this circadian rhythm model and other repetitive and non-repetitive types of temporal organization within the cell, e.g., the cell cycle; however, it must be stressed that in the case of the circadian rhythm, much stronger and more efficient mechanisms exist to keep the period constant. This is true particularly for temperature compensation. Such a conservatism is understandable if one recalls that during evolution, the circadian rhythm represents an adaptive advantage which permits the organism to adjust it activities in advance to periodic processes resulting from the earth's rotation.