scholarly journals Cell division and cell shape patterns during migration of the embryonic chick neural crest revealed by in vivo time-lapse microscopy

2010 ◽  
Vol 344 (1) ◽  
pp. 473
Author(s):  
Dennis A. Ridenour ◽  
Katherine W. Prather ◽  
Rebecca McLennan ◽  
Zachary Warren ◽  
Paul M. Kulesa
Keyword(s):  
Cell Division ◽  
Neural Crest ◽  
Cell Shape ◽  
Time Lapse ◽  
Embryonic Chick ◽  
Time Lapse Microscopy

scholarly journals Two-Step Assembly Dynamics of the Bacillussubtilis Divisome

2009 ◽  
Vol 191 (13) ◽  
pp. 4186-4194 ◽  
Author(s):  
Pamela Gamba ◽  
Jan-Willem Veening ◽  
Nigel J. Saunders ◽  
Leendert W. Hamoen ◽  
Richard A. Daniel
Keyword(s):  
Cell Cycle ◽  
Cell Division ◽  
Fluorescent Protein ◽  
Time Lapse ◽  
Localization Pattern ◽  
Ftsz Ring ◽  
Time Lapse Microscopy ◽  
Green Fluorescent ◽  
Posttranscriptional Level

ABSTRACT Cell division in bacteria is carried out by about a dozen proteins which assemble at midcell and form a complex known as the divisome. To study the dynamics and temporal hierarchy of divisome assembly in Bacillus subtilis, we have examined the in vivo localization pattern of a set of division proteins fused to green fluorescent protein in germinating spores and vegetative cells. Using time series and time-lapse microscopy, we show that the FtsZ ring assembles early and concomitantly with FtsA, ZapA, and EzrA. After a time delay of at least 20% of the cell cycle, a second set of division proteins, including GpsB, FtsL, DivIB, FtsW, Pbp2B, and DivIVA, are recruited to midcell. Together, our data provide in vivo evidence for two-step assembly of the divisome. Interestingly, overproduction of FtsZ advances the temporal assembly of EzrA but not of DivIVA, suggesting that a signal different from that of FtsZ polymerization drives the assembly of late divisome proteins. Microarray analysis shows that FtsZ depletion or overexpression does not significantly alter the transcription of division genes, supporting the hypothesis that cell division in B. subtilis is mainly regulated at the posttranscriptional level.

scholarly journals MICROTUBULE BIOGENESIS AND CELL SHAPE IN OCHROMONAS

1973 ◽  
Vol 56 (2) ◽  
pp. 340-359 ◽  
Author(s):  
G. Benjamin Bouck ◽  
David L. Brown
Keyword(s):  
Cell Division ◽  
Cell Shape ◽  
Spindle Pole ◽  
Vegetative Cells ◽  
External Wall ◽  
Cell Form ◽  
Attachment Sites ◽  
Spindle Microtubules ◽  
Mitotic Cells

In the first of two companion papers which attempt to correlate microtubules and their nucleating sites with developmental and cell division patterns in the unicellular flagellate, Ochromonas, the distribution of cytoplasmic and mitotic microtubules and various kinetosome-related fibers are detailed. Of the five kinetosome-related fibers, which have been found in Ochromonas, two, the kineto-beak fibers and the rhizoplast fibers are utilized as attachment sites for distinct groups of microtubules. The set of microtubules attached to the kineto-beak fibers apparently shape the anterior beak region of the cell whereas the rhizoplast microtubules appear to extend into and shape the tail in vegetative cells. In mitotic cells a rhizoplast is found at each spindle pole apparently serving as foci for the spindle microtubules. These findings are discussed in relation to the less well defined attachment sites for vegetative and mitotic microtubules in other kinds of cells. It is noted that the effects of depolymerizing microtubules in vivo might be easily quantitated in whole populations since no external wall or pellicle contributes to the maintenance or the biogenesis of the characteristic cell form of Ochromonas.

scholarly journals The zebrafish as a novel model for the in vivo study of Toxoplasma gondii replication and interaction with macrophages

2020 ◽  
Vol 13 (7) ◽  
pp. dmm043091 ◽  
Author(s):  
Nagisa Yoshida ◽  
Marie-Charlotte Domart ◽  
Christopher J. Peddie ◽  
Artur Yakimovich ◽  
Maria J. Mazon-Moya ◽  
...  
Keyword(s):  
High Resolution ◽  
Toxoplasma Gondii ◽  
Parasitophorous Vacuole ◽  
Time Lapse ◽  
Brain Cells ◽  
Type I ◽  
Murine Models ◽  
Time Lapse Microscopy ◽  
Novel Model

ABSTRACTToxoplasma gondii is an obligate intracellular parasite capable of invading any nucleated cell. Three main clonal lineages (type I, II, III) exist and murine models have driven the understanding of general and strain-specific immune mechanisms underlying Toxoplasma infection. However, murine models are limited for studying parasite-leukocyte interactions in vivo, and discrepancies exist between cellular immune responses observed in mouse versus human cells. Here, we developed a zebrafish infection model to study the innate immune response to Toxoplasma in vivo. By infecting the zebrafish hindbrain ventricle, and using high-resolution microscopy techniques coupled with computer vision-driven automated image analysis, we reveal that Toxoplasma invades brain cells and replicates inside a parasitophorous vacuole to which type I and III parasites recruit host cell mitochondria. We also show that type II and III strains maintain a higher infectious burden than type I strains. To understand how parasites are cleared in vivo, we further analyzed Toxoplasma-macrophage interactions using time-lapse microscopy and three-dimensional correlative light and electron microscopy (3D CLEM). Time-lapse microscopy revealed that macrophages are recruited to the infection site and play a key role in Toxoplasma control. High-resolution 3D CLEM revealed parasitophorous vacuole breakage in brain cells and macrophages in vivo, suggesting that cell-intrinsic mechanisms may be used to destroy the intracellular niche of tachyzoites. Together, our results demonstrate in vivo control of Toxoplasma by macrophages, and highlight the possibility that zebrafish may be further exploited as a novel model system for discoveries within the field of parasite immunity.This article has an associated First Person interview with the first author of the paper.

scholarly journals Partitioning and Exocytosis of Secretory Granules during Division of PC12 Cells

2012 ◽  
Vol 2012 ◽  
pp. 1-14 ◽  
Author(s):  
Nickolay Vassilev Bukoreshtliev ◽  
Erlend Hodneland ◽  
Tilo Wolf Eichler ◽  
Patricia Eifart ◽  
Amin Rustom ◽  
...  
Keyword(s):  
Cell Division ◽  
Pc12 Cells ◽  
Secretory Granules ◽  
Time Lapse ◽  
Intercellular Bridge ◽  
Time Lapse Microscopy ◽  
Interphase Cells ◽  
Molecular Machinery ◽  
Spindle Microtubules ◽  
Single Granule

The biogenesis, maturation, and exocytosis of secretory granules in interphase cells have been well documented, whereas the distribution and exocytosis of these hormone-storing organelles during cell division have received little attention. By combining ultrastructural analyses and time-lapse microscopy, we here show that, in dividing PC12 cells, the prominent peripheral localization of secretory granules is retained during prophase but clearly reduced during prometaphase, ending up with only few peripherally localized secretory granules in metaphase cells. During anaphase and telophase, secretory granules exhibited a pronounced movement towards the cell midzone and, evidently, their tracks colocalized with spindle microtubules. During cytokinesis, secretory granules were excluded from the midbody and accumulated at the bases of the intercellular bridge. Furthermore, by measuring exocytosis at the single granule level, we showed, that during all stages of cell division, secretory granules were competent for regulated exocytosis. In conclusion, our data shed new light on the complex molecular machinery of secretory granule redistribution during cell division, which facilitates their release from the F-actin-rich cortex and active transport along spindle microtubules.

Focal points for chromosome condensation and decondensation revealed by three-dimensional in vivo time-lapse microscopy

Nature ◽  
1989 ◽  
Vol 342 (6247) ◽  
pp. 293-296 ◽  
Author(s):  
Yasushi Hiraoka ◽  
Jonathan S. Minden ◽  
Jason R. Swedlow ◽  
John W. Sedat ◽  
David A. Agard
Keyword(s):  
Three Dimensional ◽  
Time Lapse ◽  
Chromosome Condensation ◽  
Focal Points ◽  
Time Lapse Microscopy
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