Cell confluency is as efficient as serum starvation for inducing arrest in the G0/G1 phase of the cell cycle in granulosa and fibroblast cells of cattle.

The cell cycle stage of donor cells is an important factor influencing developmental ability of nuclear transfer embryos. In the present experiment, cumulus and fibroblast cells of cattle were subjected to flow cytometric cell cycle analysis before being used in somatic cloning experiments. The following experimental groups were analyzed for each cell type: (1) actively dividing cells, (2) cells confluent for 4 days, (3) cells starved for 1, 2, 3 or 5 days. Using the propidium iodide flow cytometric assay, there were no significant differences (P > or = 0.05) in the percentage of cells in G0/G1 regardless of origin and type of cell, after confluency or serum starvation. Differences with the growing cells were found (P < or = 0.01). To determine what subset of cells in G0/G1 were in the G0 subphase of the cell cycle, an immunofluorescence analysis was conducted using monoclonal anti-PCNA antibodies in a FACS assay. There were not statistically significant differences in the percentage of cells that enter G0, between confluent and any starved group for either type of cells. Bovine fibroblast cells, confluent or serum starved for 3 days, were used in nuclear transfer experiments. A slight trend for a more desirable fusion rate in starved cells was detected, and embryo cleavage was greater in starved cells, however, in vitro development to blastocysts was similar between groups. Data indicate that prolonged culture of cells in the absence of serum does not imply a shift in the percentage of cells that enter G0/G1 or G0 alone, and that confluency is sufficient to induce quiescence. This finding can be beneficial in nuclear transfer programs, because there are negative effects such as apoptosis, associated with serum starvation.

[1]  J. Nevins,et al.  The accumulation of an E2F-p130 transcriptional repressor distinguishes a G0 cell state from a G1 cell state , 1996, Molecular and cellular biology.

[2]  E. Wolf,et al.  Remodeling of donor nuclei, DNA‐synthesis, and ploidy of bovine cumulus cell nuclear transfer embryos: Effect of activation protocol , 2001, Molecular reproduction and development.

[3]  H. R. Tervit,et al.  Coordination between donor cell type and cell cycle stage improves nuclear cloning efficiency in cattle. , 2003, Theriogenology.

[4]  F. A. P. León,et al.  Cloned transgenic calves produced from nonquiescent fetal fibroblasts. , 1998, Science.

[5]  I Wilmut,et al.  Cell cycle co-ordination in embryo cloning by nuclear transfer. , 1996, Reviews of reproduction.

[6]  H. Steen,et al.  CELLULAR AND NUCLEAR VOLUME DURING THE CELL CYCLE OF NHIK 3025 CELLS , 1978, Cell and tissue kinetics.

[7]  B. N. Day,et al.  Flow cytometric cell cycle analysis of cultured porcine fetal fibroblast cells. , 1999, Biology of reproduction.

[8]  I. Wilmut,et al.  "Viable Offspring Derived from Fetal and Adult Mammalian Cells" (1997), by Ian Wilmut et al. , 2014 .

[9]  H. Niemann,et al.  Cell Cycle Synchronization of Porcine Fetal Fibroblasts: Effects of Serum Deprivation and Reversible Cell Cycle Inhibitors1 , 2000, Biology of reproduction.

[10]  Y Tsunoda,et al.  Eight calves cloned from somatic cells of a single adult. , 1998, Science.

[11]  S. Stice,et al.  Enhanced Survivability of Cloned Calves Derived from Roscovitine-Treated Adult Somatic Cells , 2002, Biology of reproduction.

[12]  H. R. Tervit,et al.  Production of cloned calves following nuclear transfer with cultured adult mural granulosa cells. , 1999, Biology of reproduction.

[13]  J. Mills,et al.  Differentiation to an NGF-dependent state and apoptosis following NGF removal both occur asynchronously in cultures of PC12 cells. , 1997, Experimental cell research.

[14]  E. Rothenberg,et al.  Apoptosis induced by serum deprivation of PC12 cells is not preceded by growth arrest and can occur at each phase of the cell cycle. , 1995, Cancer research.

[15]  J. Larsen,et al.  Detection of proliferating cell nuclear antigen. , 2001, Methods in cell biology.

[16]  T. Tani,et al.  DEVELOPMENTAL POTENTIAL OF CUMULUS CELL-DERIVED CULTURED CELLS FROZEN IN A QUIESCENT STATE AFTER NUCLEUS TRANSFER , 2000 .

[17]  I. Wilmut,et al.  Sheep cloned by nuclear transfer from a cultured cell line , 1996, Nature.

[18]  E. Sahin,et al.  Soluble Collagen VI Drives Serum-starved Fibroblasts through S Phase and Prevents Apoptosis via Down-regulation of Bax* , 1999, The Journal of Biological Chemistry.

[19]  C. Hodges,et al.  Generation of transgenic livestock by somatic cell nuclear transfer , 2004 .

[20]  J. Fléchon,et al.  Developmental potential of bovine embryos reconstructed from enucleated matured oocytes fused with cultured somatic cells. , 1998, Comptes rendus de l'Academie des sciences. Serie III, Sciences de la vie.

[21]  H. Niemann,et al.  Cell cycle synchronization of porcine fetal fibroblasts by serum deprivation initiates a nonconventional form of apoptosis. , 2002, Cloning and stem cells.

[22]  J. Modiano,et al.  Growth arrest of melanoma cells is differentially regulated by contact inhibition and serum deprivation. , 1999, DNA and cell biology.

[23]  Matthew W. Miller,et al.  Clinical and pathologic features of cloned transgenic calves and fetuses (13 case studies). , 1999, Theriogenology.

[24]  M. Stojkovic,et al.  Effects of serum starvation and re-cloning on the efficiency of nuclear transfer using bovine fetal fibroblasts. , 1999, Journal of reproduction and fertility.

[25]  D. Loo,et al.  Death of serum-free mouse embryo cells caused by epidermal growth factor deprivation , 1991, The Journal of cell biology.

[26]  M. Taverne,et al.  Aspiration of bovine oocytes during transvaginal ultrasound scanning of the ovaries. , 1988, Theriogenology.

[27]  I. Marinov,et al.  Cell cycle synchronization of porcine granulosa cells in G1 stage with mimosine. , 2003, Animal reproduction science.

[28]  D. J. Jerry,et al.  Production of calves from G1 fibroblasts , 2001, Nature Biotechnology.

[29]  A. Yabuuchi,et al.  Developmental potential of mouse follicular epithelial cells and cumulus cells after nuclear transfer. , 1999, Biology of reproduction.

[30]  D. Wells,et al.  Practical aspects of donor cell selection for nuclear cloning. , 2002, Cloning and stem cells.

[31]  T. Nagai,et al.  Production of calves by transfer of nuclei from cultured somatic cells obtained from Japanese black bulls. , 1999, Theriogenology.

[32]  D. Wells,et al.  Donor cells for nuclear cloning: many are called, but few are chosen. , 2002, Cloning and stem cells.

[33]  C. Kubota,et al.  Six cloned calves produced from adult fibroblast cells after long-term culture. , 2000, Proceedings of the National Academy of Sciences of the United States of America.