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1

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Nuclear cytoplasmic domains, microtubules and organelles in microsporocytes of the slipper orchid Cypripedium californicum A. Gray dividing by simultaneous cytokinesis (1996)

Brown, Roy C. ; Lemmon, Betty E. ; Brown, R. C. ; [et al.]

Springer

Sexual plant reproduction 9 (1996), S. 145-152

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ISSN: 1432-2145

Keywords: Cytokinesis ; Microtubules ; Microsporogenesis ; Orchids ; Phragmoplast ; Pollen

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Microsporocytes of the slipper orchidCypripedium californicum A. Gray divide simultaneously after second meiosis. The organization and apportionment of the cytoplasm throughout meiosis are functions of nuclear-based radial microtubule systems (RMSs) that define domains of cytoplasm - a single sporocyte domain before meiosis, dyad domains within the undivided cytoplasm after first meiosis, and four spore domains after second meiosis. Organelles migrate to the interface of dyad domains in the undivided cytoplasm after first meiotic division, and second meiotic division takes place simultaneously on both sides of the equatorial organelle band. Microtubules emanating from the telophase II nuclei interact to form columnar arrrays that interconnect all four nuclei, non-sister as well as sister. Cell plates are initiated in these columns of microtubules and expand centrifugally along the interface of opposing RMSs, coalescing in the center of the sporocyte and joining with the original sporocyte wall at the periphery to form the tetrad of microspores. Organelles are distributed into the spore domains in conjunction with RMSs. These data, demonstrating that cytokinesis in microsporogenesis can occur in the absence of both components of the typical cytokinetic apparatus (the preprophase band of microtubules which predicts the division site and the phragmoplast which controls cell-plate deposition), suggest that plant nuclei have an inherent ability to establish a domain of cytoplasm via radial microtubule systems and to regulate wall deposition independently of the more complex cytokinetic apparatus of vegetative cells.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02221394

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2

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Ultrastructure of meiosis in the mossRhynchostegium serrulatum I. Prophasic microtubules and spindle dynamics (1982)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 110 (1982), S. 23-33

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ISSN: 1615-6102

Keywords: Meiosis ; Microtubules ; Polarity ; Ultrastructure ; Mosses

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary An extensive system of microtubules develops during meiotic prophase in the mossRhynchostegium serrulatum (Hedw.)Jaeg. &Sauerb. Development of the cytoskeleton can be traced to early prophase when the nucleus is acentric and the single plastid divides into four plastids. The cytoskeletal microtubules are associated with equidistant positioning of the four plastids at the distal tetrad poles and with migration of the nucleus to a central position in the sporocyte. The cytoskeleton, which interconnects plastids and encloses the nucleus, contributes to the establishment of moss sporocyte polarity. Just prior to metaphase I evidence of the prophase cytoskeleton is lost as the bipolar metaphase I spindle develops in association with discrete polar organizers located in opposite cleavage furrows between plastids.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01314678

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3

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A cytoskeletal system predicts division plane in meiosis ofSelaginella (1985)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 127 (1985), S. 101-109

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ISSN: 1615-6102

Keywords: Division polarity ; Microtubules ; Meiosis ; Selaginella ; Sporogenesis

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary An ultrastructural investigation of the monoplastidic microsporocytes ofSelaginella arenicola revealed a unique cytoskeletal array that predicts the future division plane before nuclear division takes place. By midprophase of the first meiotic division, the single plastid has divided once and the two plastids lie on opposite sides of the nucleus which is elongated in the plane of the incipient metaphase I spindle. A cytoplasmic structure, the procytokinetic plate (PCP), predicts the division plane of of both plastid and cytoplasm. The PCP consists of a distinct concentration of vesicles lying in the future division plane and an elaborate system of microtubules aligned parallel to the long axis of plastids and nucleus. Microtubules of the axially aligned system appear to terminate in clusters of vesicles in the central zone of the PCP. The PCP with axially aligned microtubules is as predictive of the division plane in these meiotic cells as is the girdling preprophase band of microtubules in mitotic cells.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01273706

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4

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Division polarity, development and configuration of microtubule arrays in bryophyte meiosis (1987)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 138 (1987), S. 1-10

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ISSN: 1615-6102

Keywords: Meiosis ; Microtubules ; Cytokinesis ; Immunofluorescence ; Bryophytes

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary First and second division spindles and the three cell plates of moss meiosis are oriented in accordance with polarity established during meiotic prophase. Plastids are located at the second division poles and cytoplasmic infurrowing marks the planes along which the cytoplasm will cleave into four spores. Anaphase I spindles that terminate in two focal points of microtubules straddling opposite cleavage furrows reflect the unusual tetrahedral origin of the functionally bipolar spindle. The organelles (except for the plastids which remain in the four cytoplasmic lobes) are polarized in the first division equatorial region at the time of phragmoplast microtubule assembly and remain in a distinct band after microtubule disassembly. Prophasic spindles appear to be directly transformed into metaphase II spindles in the predetermined axes between mutually perpendicular pairs of plastids. Cell plates form by vesicle coalescence in the equatorial regions of the two sets of second division phragmoplasts at approximately the same time as a cell plate belatedly forms in the organelle band. The cytoplasmic markers (plastid migration, cytoplasmic lobing and infurrowing) that predict poles and cleavage planes in free cells lacking a preprophase band strongly strengthens the concept that division sites are capable of preserving preprogrammed signals that can be triggered later in the process of cell division.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01281179

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5

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Preprophasic microtubule systems and development of the mitotic spindle in hornworts (Bryophyta) (1988)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 143 (1988), S. 11-21

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ISSN: 1615-6102

Keywords: Bryophytes ; Immunofluorescence ; Microtubules ; Mitotic apparatus ; Monoplastidy ; Preprophase band

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Studies of monoplastidic mitosis in hornworts (Bryophyta) using transmission electron microscopy and indirect immunofluorescence staining of microtubules have revealed that two mutually perpendicular microtubule systems predict division polarity in preprophase. Events of cytoplasmic reorganization in preparation for division occur in the following order: migration of the single plastid to a position perpendicular to the division site, constriction of the plastid where its midpoint intersects the division site, development of an axial system of microtubules parallel to the elongating plastid isthmus, and appearance of an atypical preprophase band of microtubules (PPB). The PPB is asymmetrical with a tight band of microtubules on the side over the plastid isthmus and a broad band of widely spaced microtubules over the nucleus. The axial system contributes directly to development of the spindle. In prometaphase, the axial system separates at the equator and additional microtubule bundles project from polar regions, creating two opposing halfspindles. The PPB is still present during asymmetrical organization of the spindle and microtubules extending from the broad portion of the PPB to poles appear to be incorporated into the developing spindle. Dynamic changes in the microtubular cytoskeleton demonstrate (1) intimate relationship of plastid and nuclear division, (2) contribution of preprophase/prophase microtubule systems to spindle development in monoplastidic cells, and (3) dynamic reorientation of microtubules from one system to another.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01282954

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6

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Aperture development in spores of the moss,Trematodon longicollis Mx. (1981)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 106 (1981), S. 273-287

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ISSN: 1615-6102

Keywords: Microtubules ; Polarity ; Spore development ; Trematodon

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Young spores of the mossTrematodon longicollis Mx. are highly polar. Immediately after meiotic cytokinesis an extensive system of microtubules associated with the single plastid develops under the entire distal face. Following exine initiation on the distal surface a microtubule system is elaborated at the site of aperture development on the proximal surface. Both plastid and nucleus move from distal to proximal pole and are attached to microtubules of the proximal system. Microtubules underlie the plasma membrane as it withdraws from the exine in the initiation of both the surrounding annulus and central aperture pore. The central pore enlarges to form a bowl-shaped concavity in which a fibrillar plug develops basipetally. The annulus expands into a fibrillar-filled protrusion surrounding the central pore. The mature aperture consists of a central pore plug covered by a thin roof of exine and separated from the surrounding annulus by exine lamellae. The aperture of the mature spore is obscured by development of the ornate exine and is not a prominent feature of the mature spore surface.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01275558

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7

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Pollen development in orchids (1991)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 165 (1991), S. 155-166

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ISSN: 1615-6102

Keywords: Cytokinesis ; F-actin ; Microsporogenesis ; Microtubules ; Orchids ; Phragmoplast

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Cytokinesis in microsporocytes of moth orchids is unusual in that it occurs simultaneously after meiosis, the cytoplasm does not infurrow in the division planes, and cell plates are deposited in association with centrifugal expansion of phragmoplasts. Microtubules radiating from the nuclear envelopes appear to be of fundamental importance in establishment of division planes. Primary interzonal spindles develop between sister nuclei and interaction of radial microtubules triggers development of secondary interzonal spindles between non-sister nuclei. From three to six or more phragmoplasts, depending upon the arrangement of nuclei in the coenocyte, develop from these postmeiotic arrays. The phragmoplasts consist of co-aligned microtubules and F-actin organized into bundles that are broad proximal to the mid-plane and taper distally. Ultrastructure of the phragmoplast/cell plate reveals that abundant ER is associated with vesicle aggregation and coalescence. Cell plates are deposited in association with phragmoplasts as they expand centrifugally to join the parental wall and/or fuse with one another in the interior of the cell.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01322286

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8

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The specialized chalazal endosperm inArabidopsis thaliana andLepidium virginicum (Brassicaceae) (2000)

Nguyen, H. ; Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 212 (2000), S. 99-110

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ISSN: 1615-6102

Keywords: Arabidopsis thaliana ; Endosperm ; Lepidium irginicum ; Microtubules ; Seed development ; Seed loading

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Endosperm of the nuclear type initially develops into a large multinucleate syncytium that lines the central cell. This seemingly simple wall-less cytoplasm can, however, be highly differentiated. In developing seeds of members of the family Brassicaceae the curved postfertilization embryo sac comprises three chambers or developmental domains. The syncytium fills the micropylar chamber around the embryo, spreads as a thin peripheral layer surrounding a large central vacuole in the central chamber, and is organized into individual nodules and a large multinucleate cyst in the chalazal tip. Later in development, after the endosperm has cellularized in the micropylar and central chambers, the chalazal endosperm cyst remains syncytial and shows considerable internal differentiation. The chalazal endosperm cyst consists of a domelike apical region that is separated from the cellularized endosperm by a remnant of the central vacuole and a basal haustorial portion which penetrates the chalazal proliferative tissue atop the vascular supply. In the shallow chalazal depression ofArabidopsis thaliana, the cyst is mushroom-shaped with short tentacle-like processes penetrating the maternal tissues. The long narrow chalazal channel ofLepidium irginicum is filled by an elongate stalklike portion of the cyst. In both, the dome contains a labyrinth of endoplasmic reticulum, dictyosomes with associated vesicles, nuclei, and plastids. The basal portions, which lack the larger organelles, exhibit extensive wall ingrowths and contain parallel arrays of microtubules. The highly specialized ultrastructure of the chalazal endosperm cyst and its intimate association with degrading chalazal proliferative cells suggest an important role in loading of maternal resources into the developing seed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01279351

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9

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Division polarity and plasticity of the meiosis I spindle inCypripedium californicum (Orchidaceae) (1998)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 203 (1998), S. 168-174

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ISSN: 1615-6102

Keywords: Confocal laser scanning microscopy ; Cytoplasmic domains ; Meiosis ; Microtubules ; Organelle band ; Polarity

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Establishment of division polarity and meiotic spindle organization in the lady's slipper orchidCypripedium californicum A. Gray was studied by immunocytochemistry, confocal and transmission electron microscopy. Prior to organization of the spindle for meiosis I, the cytoplasmic domains of the future dyad and spindle polarity are marked by: (1) constriction of the prophase nucleus into an hourglass shape; (2) reorganization of nuclear-based radial microtubules into two arrays that intersect at the constriction; and (3) redistribution of organelles into a ring at the boundary of the newly defined dyad domains. It is not certain whether the opposing microtubule arrays contribute directly to the anastral spindle which is organized in the perinuclear areas of the two hemispheres. By late prophase each half-spindle consists of a spline-like structure from which depart the kinetochore fibers. This peculiar spindle closely resembles the spline-like spindle of generative-cell mitosis in certain plants where the spindle is distorted by physical constraints of the slender pollen tube. In the microsporocyte, the elongate spindle of late prophase/metaphase is curved within the cell so that the poles are not actually opposite each other and chromosomes do not form a plate at the equator. By late telophase the poles of the shortened halfspindles lie opposite each other. Plasticity of the physically constrained plant spindle appears to be due to its construction from multiple units terminating in minipoles. Cytokinesis does not follow the first meiosis. However, the dyad domains are clearly defined by radial microtubules emanating from the two daughter nuclei and the domains themselves are separated by a disc-like band of organelles.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01279473

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10

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Morphogenetic plastid migration and microtubule organization during megasporogenesis inIsoetes (1989)

Brown, R. C. ; Lemmon, B. E.

Springer

Protoplasma 152 (1989), S. 136-147

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ISSN: 1615-6102

Keywords: Isoetes ; Megasporogenesis ; Monoplastidy ; Meiosis ; Microtubules ; Mitotic apparatus

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary The large megasporocytes ofIsoetes provide an exceptional system for studying microtubule dynamics in monoplastidic meiosis where plastid polarity assures coordination of plastid and nuclear division by the intimate association of MTOCs with plastids. Division and migration of the plastid in prophase establishes the tetrahedrally arranged cytoplasmic domains of the future spore tetrad and the four plastid-MTOCs serve as focal points of a unique quadripolar microtubule system (QMS). The QMS is a dynamic structure which functions in plastid deployment and contributes directly to development of both first and second division spindles. The nucleation of microtubules at discrete plastid-MTOCs is compared with centrosomal nucleation of microtubules in animal cells where growth of microtubules involves dynamic instability.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01323073

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