| Abstract: | A growing body of evidence indicates that early mitotic inhibitor 1 (Emi1) is essential for genomic stability, but how this function relates to embryonic development and cancer pathogenesis remains unclear. We have identified a zebrafish mutant line in which deficient emi1 gene expression results in multilineage hematopoietic defects and widespread developmental defects that are p53 independent. Cell cycle analyses of Emi1-depleted zebrafish or human cells showed chromosomal rereplication, and metaphase preparations from mutant zebrafish embryos revealed rereplicated, unsegregated chromosomes and polyploidy. Furthermore, EMI1-depleted mammalian cells relied on topoisomerase IIα-dependent mitotic decatenation to progress through metaphase. Interestingly, the loss of a single emi1 allele in the absence of p53 enhanced the susceptibility of adult fish to neural sheath tumorigenesis. Our results cast Emi1 as a critical regulator of genomic fidelity during embryogenesis and suggest that the factor may act as a tumor suppressor.Successful cell division requires faithful replication of the genome, and defects in this process can contribute to genomic instability and subsequent malignant transformation (23). A key regulator of the normal cell cycle is the early mitotic inhibitor 1 (EMI1/FBXO5), a zinc finger protein expressed by a variety of adult tissues and especially in proliferating Ki-67-positive cells (39). Studies of the mammalian and Xenopus homologues of EMI1 have shown that it inhibits the anaphase-promoting complex/cyclosome (APC/C), a ubiquitin ligase complex that targets cell cycle-regulated proteins, such as the S- and M-phase cyclins (A and B), securin, and geminin (13, 25, 31). Depletion of EMI1 by small interfering RNA (siRNA) knockdown in cell lines or immunodepletion in cycling Xenopus extracts results in the untimely degradation of APC/C substrates, delaying G1/S- and M-phase progression and inducing rereplication (6, 21, 25, 31). Such rereplication is a consequence of decreased levels of the APC/C substrates cyclin A and geminin, which are regulators of replication licensing (6, 21). The result of EMI1 depletion in some cell lines is senescence (39).Despite these insights into the molecular underpinnings of EMI1 function, little is known about the role of this protein in development. Knockout of murine Emi1 results in an embryonic-lethal phenotype prior to implantation, while a deficiency of Emi1 in cultured pronuclear zygotes leads to multipolar and tangled spindle structures, orphan chromosomes, large nuclei, and apoptosis by the 16-cell stage (17). Otherwise, the dynamic influence of EMI1 on early vertebrate development remains undefined. We sought to close this gap by taking advantage of the zebrafish model system. Zebrafish embryos harboring homozygous mutations of emi1 (emi1m/m) develop beyond the onset of circulation, providing a unique opportunity to examine the developmental roles of Emi1 in vivo. The zebrafish emi1 mutant (hi2648) line was originally identified by a proviral insertional mutagenesis screen designed to identify genes that are necessary for normal morphological development in embryos (1, 8, 9). Subsequent studies showed that the insertion was located between the first and second exons of the emi1 gene (2). The morphological defects in emi1m/m embryos at 2 days postfertilization (p.f.) are described in the public access zebrafish model organism database (http://zfin.org). Briefly, abnormalities in emi1m/m embryos can be identified as early as 20 h p.f. and include slightly smaller heads and a lack of ventral curving of the posterior presomitic mesoderm. By 25 h p.f., the tail is more ventrally curved than in normal embryos, and increased cell death is observed throughout the central nervous system. Mutant embryos have circulating blood cells, although the onset of circulation is delayed. We became interested in this mutant because it harbors defects in the numbers and morphology of granulocytes, an important myeloid cell type within the innate immune system.There is evidence that EMI1 may function in cancer pathogenesis, and a variety of human tumors express this factor very highly, although in some cases this may be a consequence of elevated proliferation rates (11, 18). In fact, the human homologue of emi1 resides within chromosome 6q25, a region often deleted in leukemia, which, together with the cell cycle-regulatory role of EMI1, suggested that this factor may also function as a tumor suppressor whose loss of function could promote genetic instability. Thus, in addition to investigating the role of zebrafish emi1 in zebrafish development, with particular emphasis on hematopoiesis, we examined mammalian cells to identify mechanisms that may be important in EMI1-related malignant transformation and explored a putative tumor suppressor role for this cell cycle-regulatory protein. |
