Eugenia A. Park scite author profile

This contribution is part of the special series of Inaugural Articles by members of the National Academy of Sciences elected on April 25, 2006. Gene clusters amplified in the ovarian follicle cells of Drosophila serve as powerful models for metazoan DNA replication. In response to developmental signals, specific genomic regions undergo amplification by repeated firing of replication origins and bidirectional movement of replication forks for Ϸ50 kb in each direction. Previous work focused on initiation of amplification, defining replication origins, establishing the role of the prereplication complex and origin recognition complex (ORC), and uncovering regulatory functions for the Myb, E2F1, and Rb transcription factors. Here, we exploit follicle cell amplification to investigate the control of DNA replication fork progression and termination, poorly understood processes in metazoans. We identified a mutant in which, during gene amplification, the replication forks move twice as far from the origin compared with wild type. This phenotype is the result of an amino acid substitution mutation in the cyclinE gene, cyclinE 1f36 . The rate of oogenesis is normal in cyclinE 1f36 /cyclinE Pz8 mutant ovaries, indicating that increased replication fork progression is due to increased replication fork speed, possibly from increased processivity. The increased amplification domains observed in the mutant imply that there are not replication fork barriers preventing replication forks from progressing beyond the normal 100-kb amplified region. These results reveal a previously unrecognized role for CyclinE in controlling replication fork movement.gene amplification ͉ oogenesis ͉ fork progression

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Drosophila Embryonic Cell-Cycle Mutants

Unhavaithaya

Park

Royzman

et al. 2013

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Nearly all cell division mutants in Drosophila were recovered in late larval/pupal lethal screens, with less than 10 embryonic lethal mutants identified, because larval development occurs without a requirement for cell division. Only cells in the nervous system and the imaginal cells that generate the adult body divide during larval stages, with larval tissues growing by increasing ploidy rather than cell number. Thus, most mutants perturbing mitosis or the cell cycle do not manifest a phenotype until the adult body differentiates in late larval and pupal stages. To identify cell-cycle components whose maternal pools are depleted in embryogenesis or that have specific functions in embryogenesis, we screened for mutants defective in cell division during embryogenesis. Five new alleles of Cyclin E were recovered, ranging from a missense mutation that is viable to stop codons causing embryonic lethality. These permitted us to investigate the requirements for Cyclin E function in neuroblast cell fate determination, a role previously shown for a null Cyclin E allele. The mutations causing truncation of the protein affect cell fate of the NB6-4 neuroblast, whereas the weak missense mutation has no effect. We identified mutations in the pavarotti (pav) and tumbleweed (tum) genes needed for cytokinesis by a phenotype of large and multinucleate cells in the embryonic epidermis and nervous system. Other mutations affecting the centromere protein CAL1 and the kinetochore protein Spc105R caused mitotic defects in the nervous system.

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Eugenia A. Park

Death of CD4⁺T-Cell Lines Caused by Human Immunodeficiency Virus Type 1 Does Not Depend on Caspases or Apoptosis

Drosophila follicle cell amplicons as models for metazoan DNA replication: A cyclinE mutant exhibits increased replication fork elongation

Drosophila Embryonic Cell-Cycle Mutants

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Eugenia A. Park

Death of CD4+T-Cell Lines Caused by Human Immunodeficiency Virus Type 1 Does Not Depend on Caspases or Apoptosis

Drosophila follicle cell amplicons as models for metazoan DNA replication: A cyclinE mutant exhibits increased replication fork elongation

Drosophila Embryonic Cell-Cycle Mutants

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Death of CD4⁺T-Cell Lines Caused by Human Immunodeficiency Virus Type 1 Does Not Depend on Caspases or Apoptosis