The Chlamydomonas Hatching Enzyme, Sporangin, is Expressed in Specific Phases of the Cell Cycle and is Localized to the Flagella of Daughter Cells Within the Sporangial Cell Wall

Chlamydomonas reinhardii divides by multiple fission to produce 2n daughter cells per division burst, where n is an integer. By separating predivision cells from synchronous cultures into fractions of differing mean cell volumes, and electronically measuring the numbers and volume distributions of the daughter cells produced by the subsequent division burst, we have shown that n is determined by the volume of the parent cell. Control of n can occur simply, if after every cell division the daughter cells monitor their volume and divide again if, and only if, their volume is greater than a fixed minimum value. In cultures synchronized by 12-h light/12-h dark cycles, the larger parent cells divide earlier in the dark period than do smaller cells. This has been shown by two independent methods: (1) by separating cells into different size fractions by Percoll density-gradient centrifugation and using the light microscope to see when they divide; and (2) by studying changes in the cell volume distribution of unfractioned cultures. Since daughter cells remain within the mother-cell wall for some hours after cell division, and cell division causes an overall swelling of the mother-cell wall, the timing of division can be determined electronically by measuring this increase in cell volume that occurs in the dark period in the absence of growth; we find that cells at the large end of the size distribution range undergo this swelling first, and are then followed by successively smaller size fractions. A simple model embodying a sizer followed by a timer gives a good quantitative fit to these data for 12-h light/12-h dark cycles if cell division occurs 12-h after attaining a critical volume of approximately 140 μm3. However, this simple model is called into question by our finding that alterations in the length of the light period alter the rate of progress towards division even of cells that have attained their critical volume. We discuss the relative roles of light and cell volume in the control of division timing in the Chlamydomonas cell cycle.

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Bcl-2 protein localizes to the chromosomes of mitotic nuclei and is correlated with the cell cycle in cultured epithelial cell lines

Journal of Cell Science ◽

10.1242/jcs.107.2.363 ◽

1994 ◽

Vol 107 (2) ◽

pp. 363-371

Author(s):

Q.L. Lu ◽

A.M. Hanby ◽

M.A. Nasser Hajibagheri ◽

S.E. Gschmeissner ◽

P.J. Lu ◽

...

Keyword(s):

Gene Expression ◽

Cell Cycle ◽

Epithelial Cell ◽

Cell Lines ◽

Cytoplasmic Localization ◽

Human Epithelial Cell ◽

Daughter Cells ◽

Epithelial Cell Lines ◽

Cell Immortalization

bcl-2 gene expression confers a survival advantage by preventing cells from entering apoptosis. In contrast to the previously described cytoplasmic localization of Bcl-2 in epithelial cells in vivo, in this study we have demonstrated, in a series of human epithelial cell lines, that Bcl-2 also localizes to mitotic nuclei. Both immunocytochemical and immunoelectron microscopical examinations localize this protein to nuclei and in particular to chromosomes. Nuclear Bcl-2 expression in these cell lines is correlated with the cell cycle. There is relatively strong expression during mitosis, most intense during prophase and metaphase, declining in telophase and then the protein becomes undetectable soon after separation of the two daughter cells. The expression and distribution of Bcl-2 is influenced by treatment with excessive thymidine. These results indicate that Bcl-2 may protect the cells from apoptosis occurring during mitosis and suggest a possible role for the protein in cell immortalization.

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Generation of asymmetry during development. Segregation of type-specific proteins in Caulobacter.

The Journal of Cell Biology ◽

10.1083/jcb.81.1.123 ◽

1979 ◽

Vol 81 (1) ◽

pp. 123-136 ◽

Cited By ~ 18

Author(s):

N Agabian ◽

M Evinger ◽

G Parker

Keyword(s):

Cell Cycle ◽

Cell Division ◽

Messenger Rna ◽

Cell Types ◽

Specific Protein ◽

Soluble Proteins ◽

Specific Cell ◽

Daughter Cells ◽

Specific Proteins ◽

Entire Cell

An essential event in developmental processes is the introduction of asymmetry into an otherwise undifferentiated cell population. Cell division in Caulobacter is asymmetric; the progeny cells are structurally different and follow different sequences of development, thus providing a useful model system for the study of differentiation. Because the progeny cells are different from one another, there must be a segregation of morphogenetic and informational components at some time in the cell cycle. We have examined the pattern of specific protein segregation between Caulobacter stalked and swarmer daughter cells, with the rationale that such a progeny analysis would identify both structurally and developmentally important proteins. To complement the study, we have also examined the pattern of protein synthesis during synchronous growth and in various cellular fractions. We show here, for the first time, that the association of proteins with a specific cell type may result not only from their periodicity of synthesis, but also from their pattern of distribution at the time of cell division. Several membrane-associated and soluble proteins are segregated asymmetrically between progeny stalked and swarmer cells. The data further show that a subclass of soluble proteins becomes associated with the membrane of the progeny stalked cells. Therefore, although the principal differentiated cell types possess different synthetic capabilities and characteristic proteins, the asymmetry between progeny stalked and swarmer cells is generated primarily by the preferential association of specific soluble proteins with the membrane of only one daughter cell. The majority of the proteins which exhibit this segregation behavior are synthesized during the entire cell cycle and exhibit relatively long, functional messenger RNA half-lives.

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The ER Stress Surveillance (ERSU) pathway regulates daughter cell ER protein aggregate inheritance

eLife ◽

10.7554/elife.06970 ◽

2015 ◽

Vol 4 ◽

Cited By ~ 8

Author(s):

Francisco J Piña ◽

Maho Niwa

Keyword(s):

Cell Cycle ◽

Endoplasmic Reticulum ◽

Er Stress ◽

Mother Cell ◽

Daughter Cell ◽

Protein Aggregates ◽

Cytoplasmic Protein ◽

Protein Aggregate ◽

Daughter Cells ◽

Simultaneous Visualization

Stress induced by cytoplasmic protein aggregates can have deleterious consequences for the cell, contributing to neurodegeneration and other diseases. Protein aggregates are also formed within the endoplasmic reticulum (ER), although the fate of ER protein aggregates, specifically during cell division, is not well understood. By simultaneous visualization of both the ER itself and ER protein aggregates, we found that ER protein aggregates that induce ER stress are retained in the mother cell by activation of the ER Stress Surveillance (ERSU) pathway, which prevents inheritance of stressed ER. In contrast, under conditions of normal ER inheritance, ER protein aggregates can enter the daughter cell. Thus, whereas cytoplasmic protein aggregates are retained in the mother cell to protect the functional capacity of daughter cells, the fate of ER protein aggregates is determined by whether or not they activate the ERSU pathway to impede transmission of the cortical ER during the cell cycle.

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Nucleolus behaviour during the cell cycle of a primitive dinoflagellate eukaryote, Prorocentrum micans Ehr., seen by light microscopy and electron microscopy

Journal of Cell Science ◽

10.1242/jcs.102.3.475 ◽

1992 ◽

Vol 102 (3) ◽

pp. 475-485 ◽

Cited By ~ 1

Author(s):

MARIE-ODILE SOYER-GOBILLARD ◽

MARIE-LINE GERAUD

Keyword(s):

Cell Cycle ◽

Light Microscopy ◽

Early Prophase ◽

Microscopy Observation ◽

Prorocentrum Micans ◽

Late Prophase ◽

Daughter Cells ◽

Nucleolar Material ◽

Freeze Fixation ◽

Higher Eukaryotes

Light-microscopy observation of the dinoflagellate Prorocentrum micans after silver-staining of the argyrophilic proteins of the nucleolar organizing region (Ag-NOR staining) showed the presence of nucleolar material throughout the vegetative cell cycle, and in particular during all the mitotic stages. This contrasts with the case in most higher eukaryotes, in which nucleoli disappear at the end of prophase and are reconstituted in daughter cells during telophase. Electron-microscope (EM) observations after conventional or fast-freeze fixation revealed that during interphase several functional nucleoli with three compartments (NORs, the fibrillogranular and the preribosomal granular compartments) are present in a nucleus in which the envelope is persistent and the chromosomes are always compact. During early prophase, when chromosomes are beginning to split, the nucleoli remain functional, whereas in late prophase they contain only a NOR and the granular component, and the chromosomes are surrounded by many protein masses. In early telophase, the nucleolar material coating the chromosomes migrates along with the chromosomes. Nucleologenesis occurs through the formation of prenucleolar bodies around lateral or telomeric nucleofilaments extruding from the chromosomes. Several chromosomes can contribute to the formation of one nucleolus. The behaviour of these ‘persistent nucleoli’ in a closed-nucleus model such as that of the dinoflagellates is discussed with regard to the higher eukaryotes.

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Brief cytochalasin-induced disruption of microfilaments during a critical interval in 1-cell C. elegans embryos alters the partitioning of developmental instructions to the 2-cell embryo

Development ◽

10.1242/dev.108.1.159 ◽

1990 ◽

Vol 108 (1) ◽

pp. 159-172 ◽

Cited By ~ 15

Author(s):

D.P. Hill ◽

S. Strome

Keyword(s):

Cell Cycle ◽

Asymmetric Cell Division ◽

Critical Time ◽

Time Interval ◽

Critical Interval ◽

Cell Stage ◽

C Elegans ◽

Daughter Cells ◽

Correct Pattern ◽

Cell Embryo

We are investigating the involvement of the microfilament cytoskeleton in the development of early Caenorhabditis elegans embryos. We previously reported that several cytoplasmic movements in the zygote require that the microfilament cytoskeleton remain intact during a narrow time interval approximately three-quarters of the way through the first cell cycle. In this study, we analyze the developmental consequences of brief, cytochalasin D-induced microfilament disruption during the 1-cell stage. Our results indicate that during the first cell cycle microfilaments are important only during the critical time interval for the 2-cell embryo to undergo the correct pattern of subsequent divisions and to initiate the differentiation of at least 4 tissue types. Disruption of microfilaments during the critical interval results in aberrant division and P-granule segregation patterns, generating some embryos that we classify as ‘reverse polarity’, ‘anterior duplication’, and ‘posterior duplication’ embryos. These altered patterns suggest that microfilament disruption during the critical interval leads to the incorrect distribution of developmental instructions responsible for early pattern formation. The strict correlation between unequal division, unequal germ-granule partitioning, and the generation of daughter cells with different cell cycle periods observed in these embryos suggests that the three processes are coupled. We hypothesize that (1) an ‘asymmetry determinant’, normally located at the posterior end of the zygote, governs asymmetric cell division, germ-granule segregation, and the segregation of cell cycle timing elements during the first cell cycle, and (2) the integrity or placement of this asymmetry determinant is sensitive to microfilament disruption during the critical time interval.

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FmhA and FmhC of Staphylococcus aureus incorporate serine residues into peptidoglycan cross-bridges

Journal of Biological Chemistry ◽

10.1074/jbc.ra120.014371 ◽

2020 ◽

Vol 295 (39) ◽

pp. 13664-13676 ◽

Cited By ~ 1

Author(s):

Stephanie Willing ◽

Emma Dyer ◽

Olaf Schneewind ◽

Dominique Missiakas

Keyword(s):

Staphylococcus Aureus ◽

Cell Wall ◽

Binding Proteins ◽

Penicillin Binding Proteins ◽

Daughter Cells ◽

Cross Bridge ◽

Resistant Strains ◽

The Cross ◽

Cross Bridges ◽

Adjacent Wall

Staphylococcal peptidoglycan is characterized by pentaglycine cross-bridges that are cross-linked between adjacent wall peptides by penicillin-binding proteins to confer robustness and flexibility. In Staphylococcus aureus, pentaglycine cross-bridges are synthesized by three proteins: FemX adds the first glycine, and the homodimers FemA and FemB sequentially add two Gly-Gly dipeptides. Occasionally, serine residues are also incorporated into the cross-bridges by enzymes that have heretofore not been identified. Here, we show that the FemA/FemB homologues FmhA and FmhC pair with FemA and FemB to incorporate Gly-Ser dipeptides into cross-bridges and to confer resistance to lysostaphin, a secreted bacteriocin that cleaves the pentaglycine cross-bridge. FmhA incorporates serine residues at positions 3 and 5 of the cross-bridge. In contrast, FmhC incorporates a single serine at position 5. Serine incorporation also lowers resistance toward oxacillin, an antibiotic that targets penicillin-binding proteins, in both methicillin-sensitive and methicillin-resistant strains of S. aureus. FmhC is encoded by a gene immediately adjacent to lytN, which specifies a hydrolase that cleaves the bond between the fifth glycine of cross-bridges and the alanine of the adjacent stem peptide. In this manner, LytN facilitates the separation of daughter cells. Cell wall damage induced upon lytN overexpression can be alleviated by overexpression of fmhC. Together, these observations suggest that FmhA and FmhC generate peptidoglycan cross-bridges with unique serine patterns that provide protection from endogenous murein hydrolases governing cell division and from bacteriocins produced by microbial competitors.

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Cell cycle phases in the unequal mother/daughter cell cycles of Saccharomyces cerevisiae.

Molecular and Cellular Biology ◽

10.1128/mcb.4.11.2529 ◽

1984 ◽

Vol 4 (11) ◽

pp. 2529-2531 ◽

Cited By ~ 43

Author(s):

B J Brewer ◽

E Chlebowicz-Sledziewska ◽

W L Fangman

Keyword(s):

Saccharomyces Cerevisiae ◽

Cell Cycle ◽

Cycle Phase ◽

Cell Cycle Time ◽

Yeast Saccharomyces Cerevisiae ◽

Cell Cycles ◽

Daughter Cells ◽

Mother And Daughter ◽

Cell Cycle Phases ◽

Mother Cells

During cell division in the yeast Saccharomyces cerevisiae mother cells produce buds (daughter cells) which are smaller and have longer cell cycles. We performed experiments to compare the lengths of cell cycle phases in mothers and daughters. As anticipated from earlier indirect observations, the longer cell cycle time of daughter cells is accounted for by a longer G1 interval. The S-phase and the G2-phase are of the same duration in mother and daughter cells. An analysis of five isogenic strains shows that cell cycle phase lengths are independent of cell ploidy and mating type.

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The effects of 5α-dihydrotestosterone on the kinetics of cell proliferation in rat prostate

Biochemical Journal ◽

10.1042/bj1420483 ◽

1974 ◽

Vol 142 (3) ◽

pp. 483-489 ◽

Cited By ~ 9

Author(s):

Barry Lesser ◽

Nicholas Bruchovsky

Keyword(s):

Cell Cycle ◽

Cell Proliferation ◽

Cellular Growth ◽

Velocity Sedimentation ◽

Growth Fraction ◽

Subcutaneous Injections ◽

Daughter Cells ◽

A Cell ◽

Rat Prostate ◽

Kinetics Of

The regenerating rat prostate was used as an experimental model to determine the effects of 5α-dihydrotestosterone on certain parameters of cell proliferation, including the duration of the phases of the cell cycle and the size of the cellular growth fraction. Rats castrated 7 days previously were treated with daily subcutaneous injections of 5α-dihydrotestosterone for 14 days; 48h after the beginning of therapy, cells in the process of DNA synthesis were labelled with a single injection of radioactive thymidine and the progress of these cells through the division cycle was observed. Cell-cycle analysis was performed by fractionating prostatic nuclei according to their position in the cell cycle by using the technique of velocity sedimentation under unit gravity. The results indicate that during regeneration the cell population undergoes 1.8 doublings with a doubling time of 40h, and that the process involves almost four rounds of cell division with a cell-generation time of 20h. The growth fraction at any time is about 0.5, and about half the daughter cells produced do not re-enter the proliferative cycle. All cells present at the start of regeneration eventually undergo at least one division during the course of regeneration, although any given cell can divide from one to four times.

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E3 Ubiquitin Ligase TRIM Proteins, Cell Cycle and Mitosis

Cells ◽

10.3390/cells8050510 ◽

2019 ◽

Vol 8 (5) ◽

pp. 510 ◽

Cited By ~ 21

Author(s):

Santina Venuto ◽

Giuseppe Merla

Keyword(s):

Cell Cycle ◽

Cancer Progression ◽

Current Knowledge ◽

Ubiquitin Ligases ◽

Cell Protein ◽

E3 Ubiquitin Ligases ◽

Daughter Cells ◽

Protein Ubiquitination ◽

Functional Units ◽

Trim Proteins

The cell cycle is a series of events by which cellular components are accurately segregated into daughter cells, principally controlled by the oscillating activities of cyclin-dependent kinases (CDKs) and their co-activators. In eukaryotes, DNA replication is confined to a discrete synthesis phase while chromosome segregation occurs during mitosis. During mitosis, the chromosomes are pulled into each of the two daughter cells by the coordination of spindle microtubules, kinetochores, centromeres, and chromatin. These four functional units tie chromosomes to the microtubules, send signals to the cells when the attachment is completed and the division can proceed, and withstand the force generated by pulling the chromosomes to either daughter cell. Protein ubiquitination is a post-translational modification that plays a central role in cellular homeostasis. E3 ubiquitin ligases mediate the transfer of ubiquitin to substrate proteins determining their fate. One of the largest subfamilies of E3 ubiquitin ligases is the family of the tripartite motif (TRIM) proteins, whose dysregulation is associated with a variety of cellular processes and directly involved in human diseases and cancer. In this review we summarize the current knowledge and emerging concepts about TRIMs and their contribution to the correct regulation of cell cycle, describing how TRIMs control the cell cycle transition phases and their involvement in the different functional units of the mitotic process, along with implications in cancer progression.

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