A maternal requirement for glutamine synthetase I for the mitotic cycles of syncytial Drosophila embryos

We describe the maternal effect phenotype of a hypomorphic mutation in the Drosophila gene for glutamine synthetase I (GSI). The extent of development of embryos derived from homozygous mutant females is variable, although most mutant embryos fail to survive past germband elongation and none develop into larvae. These embryos are characterised by an increase in the number of yolk-like nuclei following nuclear migration to the cortex. These nuclei appear to fall into the interior of the embryo from the cortex at blastoderm. As they do so, the majority continue to show association with PCNA in synchrony with nuclei at the cortex, suggesting some continuity of the synchrony of DNA replication. However, the occurrence of nuclei that have lost cell cycle synchrony with their neighbours is not uncommon. Immunostaining of mutant embryos revealed a range of mitotic defects, ultimately resulting in nuclear fusion events, division failure or other mitotic abnormalities. A high proportion of these mitotic figures show chromatin bridging at anaphase and telophase consistent with progression through mitosis in the presence of incompletely replicated DNA. GSI is responsible for the ATP-dependent amination of glutamate to produce glutamine, which is required in the formation of amino acids, purines and pyrimidines. We discuss how the loss of glutamine could depress both protein and DNA synthesis and lead to a variety of mitotic defects in this embryonic system that lacks certain checkpoint controls.

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Self-Organized Nuclear Positioning Synchronizes the Cell Cycle in Drosophila Embryos

Cell ◽

10.1016/j.cell.2019.03.007 ◽

2019 ◽

Vol 177 (4) ◽

pp. 925-941.e17 ◽

Cited By ~ 30

Author(s):

Victoria E. Deneke ◽

Alberto Puliafito ◽

Daniel Krueger ◽

Avaneesh V. Narla ◽

Alessandro De Simone ◽

...

Keyword(s):

Cell Cycle ◽

Nuclear Positioning ◽

Self Organized ◽

Drosophila Embryos

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Morphology and behaviour of dinoflagellate chromosomes during the cell cycle and mitosis

Journal of Cell Science ◽

10.1242/jcs.113.7.1231 ◽

2000 ◽

Vol 113 (7) ◽

pp. 1231-1239 ◽

Cited By ~ 3

Author(s):

Y. Bhaud ◽

D. Guillebault ◽

J. Lennon ◽

H. Defacque ◽

M.O. Soyer-Gobillard ◽

...

Keyword(s):

Electron Microscopy ◽

Cell Cycle ◽

Confocal Microscopy ◽

Nuclear Envelope ◽

Chromosome Segregation ◽

Morphological Changes ◽

S Phase ◽

Chromosome Behaviour ◽

Double Number ◽

Do So

The morphology and behaviour of the chromosomes of dinoflagellates during the cell cycle appear to be unique among eukaryotes. We used synchronized and aphidicolin-blocked cultures of the dinoflagellate Crypthecodinium cohnii to describe the successive morphological changes that chromosomes undergo during the cell cycle. The chromosomes in early G(1) phase appeared to be loosely condensed with numerous structures protruding toward the nucleoplasm. They condensed in late G(1), before unwinding in S phase. The chromosomes in cells in G(2) phase were tightly condensed and had a double number of arches, as visualised by electron microscopy. During prophase, chromosomes elongated and split longitudinally, into characteristic V or Y shapes. We also used confocal microscopy to show a metaphase-like alignment of the chromosomes, which has never been described in dinoflagellates. The metaphase-like nucleus appeared flattened and enlarged, and continued to do so into anaphase. Chromosome segregation occurred via binding to the nuclear envelope surrounding the cytoplasmic channels and microtubule bundles. Our findings are summarized in a model of chromosome behaviour during the cell cycle.

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rough deal: a gene required for proper mitotic segregation in Drosophila.

The Journal of Cell Biology ◽

10.1083/jcb.109.6.2951 ◽

1989 ◽

Vol 109 (6) ◽

pp. 2951-2961 ◽

Cited By ~ 48

Author(s):

R E Karess ◽

D M Glover

Keyword(s):

Cell Death ◽

Genetic Locus ◽

Motile Sperm ◽

High Frequencies ◽

Morphological Process ◽

Daughter Cells ◽

Chromosome Transmission ◽

Sister Chromatids ◽

Mitotic Abnormalities ◽

Homozygous Mutant

We describe a genetic locus rough deal (rod) in Drosophila melanogaster, identified by mutations that interfere with the faithful transmission of chromosomes to daughter cells during mitosis. Five mutant alleles were isolated, each associated with a similar set of mitotic abnormalities in the dividing neuroblasts of homozygous mutant larvae: high frequencies of aneuploid cells and abnormal anaphase figures, in which chromatids may lag, form bridges, or completely fail to separate. Surviving homozygous adults are sterile, and show cuticular defects associated with cell death, i.e., roughened eyes, sparse abdominal bristles, and notched wing margins. The morphological process of spermatogenesis is largely unaffected and motile sperm are produced, but meiocyte aneuploidy is common. The nature of the observed abnormalities in mitotic cells suggests that the reduced fidelity of chromosome transmission to the daughter cells is due to a failure in a mechanism involved in assuring the proper release of sister chromatids.

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Expression of the cell cycle control gene, cdc25, is constitutive in the segmental founder cells but is cell-cycle-regulated in the micromeres of leech embryos

Development ◽

10.1242/dev.121.9.3035 ◽

1995 ◽

Vol 121 (9) ◽

pp. 3035-3043 ◽

Cited By ~ 2

Author(s):

S.T. Bissen

Keyword(s):

Cell Cycle ◽

Cell Division ◽

Cell Cycle Control ◽

Control Gene ◽

Cdc25 Phosphatase ◽

Cell Cycles ◽

Cell Divisions ◽

Zygotic Transcription ◽

Founder Cells ◽

Drosophila Embryos

The identifiable cells of leech embryos exhibit characteristic differences in the timing of cell division. To elucidate the mechanisms underlying these cell-specific differences in cell cycle timing, the leech cdc25 gene was isolated because Cdc25 phosphatase regulates the asynchronous cell divisions of postblastoderm Drosophila embryos. Examination of the distribution of cdc25 RNA and the zygotic expression of cdc25 in identified cells of leech embryos revealed lineage-dependent mechanisms of regulation. The early blastomeres, macromeres and teloblasts have steady levels of maternal cdc25 RNA throughout their cell cycles. The levels of cdc25 RNA remain constant throughout the cell cycles of the segmental founder cells, but the majority of these transcripts are zygotically produced. Cdc25 RNA levels fluctuate during the cell cycles of the micromeres. The levels peak during early G2, due to a burst of zygotic transcription, and then decline as the cell cycles progress. These data suggest that cells of different lineages employ different strategies of cell cycle control.

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Positioning adjacent pair-rule stripes in the posterior Drosophila embryo

Development ◽

10.1242/dev.120.10.2945 ◽

1994 ◽

Vol 120 (10) ◽

pp. 2945-2955 ◽

Cited By ~ 4

Author(s):

J.A. Langeland ◽

S.F. Attai ◽

K. Vorwerk ◽

S.B. Carroll

Keyword(s):

Binding Sites ◽

Drosophila Embryo ◽

Regulatory Sequences ◽

Posterior Border ◽

Adjacent Pair ◽

Gap Gene ◽

Competitive Mechanism ◽

Pair Rule ◽

Drosophila Embryos ◽

Do So

We present a genetic and molecular analysis of two hairy (h) pair-rule stripes in order to determine how gradients of gap proteins position adjacent stripes of gene expression in the posterior of Drosophila embryos. We have delimited regulatory sequences critical for the expression of h stripes 5 and 6 to 302 bp and 526 bp fragments, respectively, and assayed the expression of stripe-specific reporter constructs in several gap mutant backgrounds. We demonstrate that posterior stripe boundaries are established by gap protein repressors unique to each stripe: h stripe 5 is repressed by the giant (gt) protein on its posterior border and h stripe 6 is repressed by the hunchback (hb) protein on its posterior border. Interestingly, Kruppel (Kr) limits the anterior expression limits of both stripes and is the only gap gene to do so, indicating that stripes 5 and 6 may be coordinately positioned by the Kr repressor. In contrast to these very similar cases of spatial repression, stripes 5 and 6 appear to be activated by different mechanisms. Stripe 6 is critically dependent upon knirps (kni) for activation, while stripe 5 likely requires a combination of activating proteins (gap and non-gap). To begin a mechanistic understanding of stripe formation, we locate binding sites for the Kr protein in both stripe enhancers. The stripe 6 enhancer contains higher affinity Kr-binding sites than the stripe 5 enhancer, which may allow for the two stripes to be repressed at different Kr protein concentration thresholds. We also demonstrate that the kni activator binds to the stripe 6 enhancer and present evidence for a competitive mechanism of Kr repression of stripe 6.

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Zygotic expression of the pebble locus is required for cytokinesis during the postblastoderm mitoses of Drosophila

Development ◽

10.1242/dev.114.1.165 ◽

1992 ◽

Vol 114 (1) ◽

pp. 165-171 ◽

Cited By ~ 5

Author(s):

G. Hime ◽

R. Saint

Keyword(s):

Drosophila Melanogaster ◽

Developmental Regulation ◽

Single Cells ◽

Embryonic Cell ◽

Cell Cycles ◽

Drosophila Embryogenesis ◽

Zygotic Transcription ◽

Homozygous Mutant ◽

Mitotic Figures

Mutations at the pebble locus of Drosophila melanogaster result in embryonic lethality. Examination of homozygous mutant embryos at the end of embryogenesis revealed the presence of fewer and larger cells which contained enlarged nuclei. Characterization of the embryonic cell cycles using DAPI, propidium iodide, anti-tubulin and anti-spectrin staining showed that the first thirteen rapid syncytial nuclear divisions proceeded normally in pebble mutant embryos. Following cellularization, the postblastoderm nuclear divisions occurred (mitoses 14, 15 and 16), but cytokinesis was never observed. Multinucleate cells and duplicate mitotic figures were seen within single cells at the time of the cycle 15 mitoses. We conclude that zygotic expression of the pebble gene is required for cytokinesis following cellularization during Drosophila embryogenesis. We postulate that developmental regulation of zygotic transcription of the pebble gene is a consequence of the transition from syncytial to cellular mitoses during cycle 14 of embryogenesis.

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Genetic determinants of glutamine synthetase inDrosophila melanogaster: A gene for glutamine synthetase I resides in the 21B3-6 region

Biochemical Genetics ◽

10.1007/bf02399602 ◽

1988 ◽

Vol 26 (9-10) ◽

pp. 571-584 ◽

Cited By ~ 10

Author(s):

Corrado Caggese ◽

Ruggiero Caizzi ◽

Maria Pia Bozzetti ◽

Paolo Barsanti ◽

Ferruccio Ritossa

Keyword(s):

Glutamine Synthetase ◽

Genetic Determinants ◽

Glutamine Synthetase I

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SET8 prevents excessive DNA methylation by methylation-mediated degradation of UHRF1 and DNMT1

Nucleic Acids Research ◽

10.1093/nar/gkz626 ◽

2019 ◽

Author(s):

Huifang Zhang ◽

Qinqin Gao ◽

Shuo Tan ◽

Jia You ◽

Cong Lyu ◽

...

Keyword(s):

Cell Cycle ◽

Dna Methylation ◽

Cell Division ◽

Global Dna Methylation ◽

Protein Methylation ◽

Accessory Factor ◽

Protein Methyltransferase ◽

A Cell ◽

Do So

Abstract Faithful inheritance of DNA methylation across cell division requires DNMT1 and its accessory factor UHRF1. However, how this axis is regulated to ensure DNA methylation homeostasis remains poorly understood. Here we show that SET8, a cell-cycle-regulated protein methyltransferase, controls protein stability of both UHRF1 and DNMT1 through methylation-mediated, ubiquitin-dependent degradation and consequently prevents excessive DNA methylation. SET8 methylates UHRF1 at lysine 385 and this modification leads to ubiquitination and degradation of UHRF1. In contrast, LSD1 stabilizes both UHRF1 and DNMT1 by demethylation. Importantly, SET8 and LSD1 oppositely regulate global DNA methylation and do so most likely through regulating the level of UHRF1 than DNMT1. Finally, we show that UHRF1 downregulation in G2/M by SET8 has a role in suppressing DNMT1-mediated methylation on post-replicated DNA. Altogether, our study reveals a novel role of SET8 in promoting DNA methylation homeostasis and identifies UHRF1 as the hub for tuning DNA methylation through dynamic protein methylation.

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