Your search keyword '"Yiqin Ma"' showing total 14 results

1. Chromatin organization changes during the establishment and maintenance of the postmitotic state

Author

Yiqin Ma and Laura Buttitta

Subjects

Drosophila, Cell cycle exit, E2F, Histone modifications, Heterochromatin binding proteins, Genetics, QH426-470

Abstract

Abstract Background Genome organization changes during development as cells differentiate. Chromatin motion becomes increasingly constrained and heterochromatin clusters as cells become restricted in their developmental potential. These changes coincide with slowing of the cell cycle, which can also influence chromatin organization and dynamics. Terminal differentiation is often coupled with permanent exit from the cell cycle, and existing data suggest a close relationship between a repressive chromatin structure and silencing of the cell cycle in postmitotic cells. Heterochromatin clustering could also contribute to stable gene repression to maintain terminal differentiation or cell cycle exit, but whether clustering is initiated by differentiation, cell cycle changes, or both is unclear. Here we examine the relationship between chromatin organization, terminal differentiation and cell cycle exit. Results We focused our studies on the Drosophila wing, where epithelial cells transition from active proliferation to a postmitotic state in a temporally controlled manner. We find there are two stages of G0 in this tissue, a flexible G0 period where cells can be induced to reenter the cell cycle under specific genetic manipulations and a state we call “robust,” where cells become strongly refractory to cell cycle reentry. Compromising the flexible G0 by driving ectopic expression of cell cycle activators causes a global disruption of the clustering of heterochromatin-associated histone modifications such as H3K27 trimethylation and H3K9 trimethylation, as well as their associated repressors, Polycomb and heterochromatin protein 1 (HP1). However, this disruption is reversible. When cells enter a robust G0 state, even in the presence of ectopic cell cycle activity, clustering of heterochromatin-associated modifications is restored. If cell cycle exit is bypassed, cells in the wing continue to terminally differentiate, but heterochromatin clustering is severely disrupted. Heterochromatin-dependent gene silencing does not appear to be required for cell cycle exit, as compromising the H3K27 methyltransferase Enhancer of zeste, and/or HP1 cannot prevent the robust cell cycle exit, even in the face of normally oncogenic cell cycle activities. Conclusions Heterochromatin clustering during terminal differentiation is a consequence of cell cycle exit, rather than differentiation. Compromising heterochromatin-dependent gene silencing does not disrupt cell cycle exit.

Published

2017

2. Changes in chromatin accessibility ensure robust cell cycle exit in terminally differentiated cells.

Author

Yiqin Ma, Daniel J McKay, and Laura Buttitta

Subjects

Biology (General), QH301-705.5

Abstract

During terminal differentiation, most cells exit the cell cycle and enter into a prolonged or permanent G0 in which they are refractory to mitogenic signals. Entry into G0 is usually initiated through the repression of cell cycle gene expression by formation of a transcriptional repressor complex called dimerization partner (DP), retinoblastoma (RB)-like, E2F and MuvB (DREAM). However, when DREAM repressive function is compromised during terminal differentiation, additional unknown mechanisms act to stably repress cycling and ensure robust cell cycle exit. Here, we provide evidence that developmentally programmed, temporal changes in chromatin accessibility at a small subset of critical cell cycle genes act to enforce cell cycle exit during terminal differentiation in the Drosophila melanogaster wing. We show that during terminal differentiation, chromatin closes at a set of pupal wing enhancers for the key rate-limiting cell cycle regulators Cyclin E (cycE), E2F transcription factor 1 (e2f1), and string (stg). This closing coincides with wing cells entering a robust postmitotic state that is strongly refractory to cell cycle reactivation, and the regions that close contain known binding sites for effectors of mitogenic signaling pathways such as Yorkie and Notch. When cell cycle exit is genetically disrupted, chromatin accessibility at cell cycle genes remains unaffected, and the closing of distal enhancers at cycE, e2f1, and stg proceeds independent of the cell cycling status. Instead, disruption of cell cycle exit leads to changes in accessibility and expression of a subset of hormone-induced transcription factors involved in the progression of terminal differentiation. Our results uncover a mechanism that acts as a cell cycle-independent timer to limit the response to mitogenic signaling and aberrant cycling in terminally differentiating tissues. In addition, we provide a new molecular description of the cross talk between cell cycle exit and terminal differentiation during metamorphosis.

Published

2019

3. Cell growth and the cell cycle: New insights about persistent questions

Author

Jan Inge Øvrebø, Yiqin Ma, and Bruce A. Edgar

Subjects

DNA-Binding Proteins, Mammals, Cyclins, Cell Cycle, Animals, Cell Cycle Proteins, DNA, Saccharomyces cerevisiae, General Biochemistry, Genetics and Molecular Biology, Article, Cell Proliferation, Transcription Factors

Abstract

Before a cell divides into two daughter cells, it typically doubles not only its DNA, but also its mass. Numerous studies in cells ranging from yeast to mammals have shown that cellular growth, stimulated by nutrients and/or growth factor signaling, is a prerequisite for cell cycle progression in most types of cells. The textbook view of growth-regulated cell cycles is that growth signaling activates the transcription of G1 Cyclin genes to induce cell proliferation, and also stimulates anabolic metabolism and cell growth in parallel. However, genetic knockout tests in model organisms indicate that this is not the whole story, and new studies show that additional, “smarter” mechanisms help to coordinate the cell cycle with growth itself. Here we summarize recent advances in this field, and discuss current models in which growth signaling regulates cell proliferation by targeting core cell cycle regulators via non-transcriptional mechanisms.

Published

2022

4. A Method for Point Spread Function Estimation of Single Lens Based on Corner Point Detection

Author

Kai Li, Weili Li, Yiqin Ma, Zhe Li, and Xiaotong Xie

Published

2022

5. The Krüppel-like factor Cabut has cell cycle regulatory properties similar to E2F1

Author

Yiqin Ma, Laura Buttitta, Huaqi Jiang, Jan Inge Øvrebø, Peng Zhang, Bruce A. Edgar, Derek W. Nickerson, and Alexia J. Katzaroff

Subjects

endocrine system, Cyclin E, Cell division, Biology, behavioral disciplines and activities, mental disorders, Animals, Drosophila Proteins, Compound Eye, Arthropod, Intestinal Mucosa, Multidisciplinary, Cell growth, Cell Cycle, Genetic Complementation Test, E2F1 Transcription Factor, Cell cycle, Biological Sciences, Cell Cycle Gene, Cell biology, Drosophila melanogaster, Gain of Function Mutation, Cancer cell, Stem cell, biological phenomena, cell phenomena, and immunity, Transcription Factors

Abstract

Using a gain-of-function screen in Drosophila, we identified the Kruppel-like factor Cabut (Cbt) as a positive regulator of cell cycle gene expression and cell proliferation. Enforced cbt expression is sufficient to induce an extra cell division in the differentiating fly wing or eye, and also promotes intestinal stem cell divisions in the adult gut. Although inappropriate cell proliferation also results from forced expression of the E2f1 transcription factor or its target, Cyclin E, Cbt does not increase E2F1 or Cyclin E activity. Instead, Cbt regulates a large set of E2F1 target genes independently of E2F1, and our data suggest that Cbt acts via distinct binding sites in target gene promoters. Although Cbt was not required for cell proliferation during wing or eye development, Cbt is required for normal intestinal stem cell divisions in the midgut, which expresses E2F1 at relatively low levels. The E2F1-like functions of Cbt identify a distinct mechanism for cell cycle regulation that may be important in certain normal cell cycles, or in cells that cycle inappropriately, such as cancer cells.

Published

2021

6. CDK4: Linking cell size to cell cycle control

Author

Yiqin Ma and Bruce A. Edgar

Subjects

Cell cycle progression, Biology, General Biochemistry, Genetics and Molecular Biology, S Phase, Cell size, 03 medical and health sciences, 0302 clinical medicine, Cyclin D1, Molecular Biology, book, Cell Size, 030304 developmental biology, 0303 health sciences, integumentary system, Kinase, Cell growth, Developmental cell, Cyclin-Dependent Kinase 4, Cell Cycle Checkpoints, Cell Biology, Cell biology, Cell cycle control, book.journal, 030217 neurology & neurosurgery, Function (biology), Developmental Biology

Abstract

A size checkpoint active during cell proliferation ensures that cells reach a certain target size before transitioning into S phase. In this issue of Developmental Cell, Tan et al. identify a distinct function of cyclin-dependent kinase 4 (CDK4) in determining the target cell size for cell cycle progression.

Published

2021

7. The coordination of terminal differentiation and cell cycle exit is mediated through the regulation of chromatin accessibility

Author

Laura Buttitta, Yiqin Ma, and Daniel J. McKay

Subjects

0303 health sciences, Cell, Cell cycle, Biology, Cell Cycle Gene, Cell biology, Chromatin, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Transcriptional repressor complex, medicine, E2F1, Enhancer, Transcription factor, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

During terminal differentiation most cells will exit the cell cycle and enter into a prolonged or permanent G0. Cell cycle exit is usually initiated through the repression of cell cycle gene expression by formation of a transcriptional repressor complex called DREAM. However when DREAM repressive function is compromised during terminal differentiation, additional unknown mechanisms act to stably repress cycling and ensure robust cell cycle exit. Here we provide evidence that developmentally programmed, temporal changes in chromatin accessibility at a subset of critical cell cycle genes acts to enforce cell cycle exit during terminal differentiation in the Drosophila melanogaster wing. We show that during terminal differentiation, chromatin closes at a set of pupal wing enhancers for the key rate-limiting cell cycle regulators cycE, e2f1 and stg. This closing coincides with wing cells entering a robust postmitotic state that is strongly refractory to cell cycle re-activation. When cell cycle exit is genetically disrupted, chromatin accessibility at cell cycle genes remains largely unaffected and the closing of enhancers at cycE, e2f1 and stg proceeds independent of the cell cycling status. Instead, disruption of cell cycle exit leads to changes in accessibility and expression of a subset of hormone-induced transcription factors involved in the progression of terminal differentiation. Our results uncover a mechanism that acts as a cell cycle-independent timer to limit aberrant cycling in terminally differentiating tissues. In addition, we provide a new molecular description of the cross-talk between cell cycle exit and terminal differentiation during metamorphosis.

Published

2018

8. The Krüppel-like factor Cabut has cell cycle regulatory properties similar to E2F1.

Author

Peng Zhang, Katzaroff, Alexia J., Buttitta, Laura A., Yiqin Ma, Huaqi Jiang, Nickerson, Derek W., Øvrebø, Jan Inge, and Edgar, Bruce A.

Subjects

CELL cycle, CELL cycle regulation, CELL division, CELL proliferation, INTESTINES, COMMERCIAL products, CURCUMIN

Abstract

Using a gain-of-function screen in Drosophila, we identified the Krüppel-like factor Cabut (Cbt) as a positive regulator of cell cycle gene expression and cell proliferation. Enforced cbt expression is sufficient to induce an extra cell division in the differentiating fly wing or eye, and also promotes intestinal stem cell divisions in the adult gut. Although inappropriate cell proliferation also results from forced expression of the E2f1 transcription factor or its target, Cyclin E, Cbt does not increase E2F1 or Cyclin E activity. Instead, Cbt regulates a large set of E2F1 target genes independently of E2F1, and our data suggest that Cbt acts via distinct binding sites in target gene promoters. Although Cbt was not required for cell proliferation during wing or eye development, Cbt is required for normal intestinal stem cell divisions in the midgut, which expresses E2F1 at relatively low levels. The E2F1-like functions of Cbt identify a distinct mechanism for cell cycle regulation that may be important in certain normal cell cycles, or in cells that cycle inappropriately, such as cancer cells. [ABSTRACT FROM AUTHOR]

Published

2021

9. Hormone-dependent control of developmental timing through regulation of chromatin accessibility

Author

Spencer L. Nystrom, Daniel J. McKay, Yiqin Ma, Matthew J. Niederhuber, Laura Buttitta, Christopher M. Uyehara, and Mary Leatham-Jensen

Subjects

0301 basic medicine, congenital, hereditary, and neonatal diseases and abnormalities, Ecdysone, education, Biology, Chromatin remodeling, 03 medical and health sciences, chemistry.chemical_compound, Gene expression, Genetics, Animals, Drosophila Proteins, Wings, Animal, Enhancer, Transcription factor, ChIA-PET, Pupa, Gene Expression Regulation, Developmental, humanities, Chromatin, Cell biology, 030104 developmental biology, Enhancer Elements, Genetic, chemistry, Drosophila, Female, DNA, Outlook, Developmental Biology, Bivalent chromatin, Signal Transduction, Transcription Factors

Abstract

Specification of tissue identity during development requires precise coordination of gene expression in both space and time. Spatially, master regulatory transcription factors are required to control tissue-specific gene expression programs. However, the mechanisms controlling how tissue-specific gene expression changes over time are less well understood. Here, we show that hormone-induced transcription factors control temporal gene expression by regulating the accessibility of DNA regulatory elements. Using the Drosophila wing, we demonstrate that temporal changes in gene expression are accompanied by genome-wide changes in chromatin accessibility at temporal-specific enhancers. We also uncover a temporal cascade of transcription factors following a pulse of the steroid hormone ecdysone such that different times in wing development can be defined by distinct combinations of hormone-induced transcription factors. Finally, we show that the ecdysone-induced transcription factor E93 controls temporal identity by directly regulating chromatin accessibility across the genome. Notably, we found that E93 controls enhancer activity through three different modalities, including promoting accessibility of late-acting enhancers and decreasing accessibility of early-acting enhancers. Together, this work supports a model in which an extrinsic signal triggers an intrinsic transcription factor cascade that drives development forward in time through regulation of chromatin accessibility.

Published

2017

10. MOESM7 of Chromatin organization changes during the establishment and maintenance of the postmitotic state

Author

Yiqin Ma and Buttitta, Laura

Subjects

endocrine system, biological phenomena, cell phenomena, and immunity

Abstract

Additional file 7: Table S2. Genes associated with senescence that are upregulated during robust G0 in the presence of ectopic E2F1/DP.

Published

2017

11. Changes in chromatin accessibility ensure robust cell cycle exit in terminally differentiated cells

Author

Laura Buttitta, Daniel J. McKay, and Yiqin Ma

Subjects

0301 basic medicine, Cellular differentiation, Gene Expression, Biochemistry, Mechanical Treatment of Specimens, 0302 clinical medicine, Wings, Animal, E2F1, Regulatory Elements, Transcriptional, Cell Cycle and Cell Division, Biology (General), Cell Disruption, Chromosome Biology, General Neuroscience, Cell Cycle, Metamorphosis, Biological, Gene Expression Regulation, Developmental, Cell Differentiation, Cell cycle, Cell Cycle Gene, Chromatin, Cell biology, Drosophila melanogaster, Specimen Disruption, Cell Processes, Epigenetics, General Agricultural and Biological Sciences, Research Article, QH301-705.5, Biology, Research and Analysis Methods, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Transcriptional repressor complex, DNA-binding proteins, Genetics, Animals, Gene Regulation, E2F, Transcription factor, Metamorphosis, General Immunology and Microbiology, Biology and Life Sciences, Proteins, Cell Biology, Regulatory Proteins, 030104 developmental biology, Specimen Preparation and Treatment, 030217 neurology & neurosurgery, Developmental Biology, Transcription Factors

Abstract

During terminal differentiation, most cells exit the cell cycle and enter into a prolonged or permanent G0 in which they are refractory to mitogenic signals. Entry into G0 is usually initiated through the repression of cell cycle gene expression by formation of a transcriptional repressor complex called dimerization partner (DP), retinoblastoma (RB)-like, E2F and MuvB (DREAM). However, when DREAM repressive function is compromised during terminal differentiation, additional unknown mechanisms act to stably repress cycling and ensure robust cell cycle exit. Here, we provide evidence that developmentally programmed, temporal changes in chromatin accessibility at a small subset of critical cell cycle genes act to enforce cell cycle exit during terminal differentiation in the Drosophila melanogaster wing. We show that during terminal differentiation, chromatin closes at a set of pupal wing enhancers for the key rate-limiting cell cycle regulators Cyclin E (cycE), E2F transcription factor 1 (e2f1), and string (stg). This closing coincides with wing cells entering a robust postmitotic state that is strongly refractory to cell cycle reactivation, and the regions that close contain known binding sites for effectors of mitogenic signaling pathways such as Yorkie and Notch. When cell cycle exit is genetically disrupted, chromatin accessibility at cell cycle genes remains unaffected, and the closing of distal enhancers at cycE, e2f1, and stg proceeds independent of the cell cycling status. Instead, disruption of cell cycle exit leads to changes in accessibility and expression of a subset of hormone-induced transcription factors involved in the progression of terminal differentiation. Our results uncover a mechanism that acts as a cell cycle–independent timer to limit the response to mitogenic signaling and aberrant cycling in terminally differentiating tissues. In addition, we provide a new molecular description of the cross talk between cell cycle exit and terminal differentiation during metamorphosis., The longer a cell remains in G0, the more refractory it becomes to re-entering the cell cycle. This study shows that in terminally differentiated cells in vivo, regulatory elements at genes encoding just three key cell cycle regulators (cycE, e2f1 and stg) become inaccessible, limiting their aberrant activation and maintaining a prolonged, robust G0.

Published

2019

12. How the cell cycle impacts chromatin architecture and influences cell fate

Author

Laura Buttitta, Kiriaki Kanakousaki, and Yiqin Ma

Subjects

DNA Replication, lcsh:QH426-470, Review Article, Biology, Chromatin remodeling, Epigenetic regulation, nucleoporins, histones, Genetics, Histone code, cell fate specification, Genetics (clinical), ChIA-PET, Epigenomics, mitosis, Histone Modifications, Chromatin binding, Cell Cycle Gene, Chromatin, Cell biology, lcsh:Genetics, chromatin, Molecular Medicine, cell cycle, cell cycle regulation, Bivalent chromatin

Abstract

Since the earliest observations of cells undergoing mitosis, it has been clear that there is an intimate relationship between the cell cycle and nuclear chromatin architecture. The nuclear envelope and chromatin undergo robust assembly and disassembly during the cell cycle, and transcriptional and post-transcriptional regulation of histone biogenesis and chromatin modification is controlled in a cell cycle-dependent manner. Chromatin binding proteins and chromatin modifications in turn influence the expression of critical cell cycle regulators, the accessibility of origins for DNA replication, DNA repair, and cell fate. In this review we aim to provide an integrated discussion of how the cell cycle machinery impacts nuclear architecture and vice-versa. We highlight recent advances in understanding cell cycle-dependent histone biogenesis and histone modification deposition, how cell cycle regulators control histone modifier activities, the contribution of chromatin modifications to origin firing for DNA replication, and newly identified roles for nucleoporins in regulating cell cycle gene expression, gene expression memory and differentiation. We close with a discussion of how cell cycle status may impact chromatin to influence cell fate decisions, under normal contexts of differentiation as well as in instances of cell fate re-programming.

Published

2015

13. Live Cell Cycle Analysis of Drosophila Tissues using the Attune Acoustic Focusing Cytometer and Vybrant DyeCycle Violet DNA Stain

Author

Olga Grushko, Yiqin Ma, Laura Buttitta, Kerry Flegel, and Dan Sun

Subjects

education.field_of_study, Cell type, medicine.diagnostic_test, General Immunology and Microbiology, ved/biology, General Chemical Engineering, General Neuroscience, Population, ved/biology.organism_classification_rank.species, Cell, DNA replication, Biology, Cell cycle, General Biochemistry, Genetics and Molecular Biology, Flow cytometry, Cell biology, medicine.anatomical_structure, medicine, education, Model organism, Mitosis

Abstract

Flow cytometry has been widely used to obtain information about DNA content in a population of cells, to infer relative percentages in different cell cycle phases. This technique has been successfully extended to the mitotic tissues of the model organism Drosophila melanogaster for genetic studies of cell cycle regulation in vivo. When coupled with cell-type specific fluorescent protein expression and genetic manipulations, one can obtain detailed information about effects on cell number, cell size and cell cycle phasing in vivo. However this live-cell method has relied on the use of the cell permeable Hoechst 33342 DNA-intercalating dye, limiting users to flow cytometers equipped with a UV laser. We have modified this protocol to use a newer live-cell DNA dye, Vybrant DyeCycle Violet, compatible with the more common violet 405nm laser. The protocol presented here allows for efficient cell cycle analysis coupled with cell type, relative cell size and cell number information, in a variety of Drosophila tissues. This protocol extends the useful cell cycle analysis technique for live Drosophila tissues to a small benchtop analyzer, the Attune Acoustic Focusing Cytometer, which can be run and maintained on a single-lab scale.

Published

2013

14. Hormone-dependent control of developmental timing through regulation of chromatin accessibility.

Author

Uyehara, Christopher M., Nystrom, Spencer L., Niederhuber, Matthew J., Leatham-Jensen, Mary, Yiqin Ma, Buttitta, Laura A., and McKay, Daniel J.

Subjects

*CHROMATIN, *TRANSCRIPTION factors, *GENE expression, *ECDYSONE, *STEROID hormones

Abstract

Specification of tissue identity during development requires precise coordination of gene expression in both space and time. Spatially, master regulatory transcription factors are required to control tissue-specific gene expression programs. However, the mechanisms controlling howtissue-specific gene expression changes over time are less well understood. Here, we show that hormone-induced transcription factors control temporal gene expression by regulating the accessibility of DNA regulatory elements. Using the Drosophila wing, we demonstrate that temporal changes in gene expression are accompanied by genome-wide changes in chromatin accessibility at temporal-specific enhancers. We also uncover a temporal cascade of transcription factors following a pulse of the steroid hormone ecdysone such that different times in wing development can be defined by distinct combinations of hormone-induced transcription factors. Finally, we show that the ecdysone-induced transcription factor E93 controls temporal identity by directly regulating chromatin accessibility across the genome. Notably, we found that E93 controls enhancer activity through three different modalities, including promoting accessibility of late-acting enhancers and decreasing accessibility of early-acting enhancers. Together, this work supports a model in which an extrinsic signal triggers an intrinsic transcription factor cascade that drives development forward in time through regulation of chromatin accessibility. [ABSTRACT FROM AUTHOR]

Published

2017