40 CHARACTERIZATION OF EARLY G1 CELLS AS NUCLEAR DONORS FOR SOMATIC CELL CLONING IN CATTLE

A. Kasamatsu; K. Saeki; T. Tamari; K. Shirouzu; S. Taniguchi; T. Mitani; Y. Aoyagi; M. Urakawa; A. Ideta; K. Matsumoto; Y. Hosoi; A. Iritani

doi:10.1071/RDv17n2Ab40

RESEARCH ARTICLE

40 CHARACTERIZATION OF EARLY G₁ CELLS AS NUCLEAR DONORS FOR SOMATIC CELL CLONING IN CATTLE

A. Kasamatsu ^B , K. Saeki ^A ^B , T. Tamari ^B , K. Shirouzu ^B , S. Taniguchi ^C , T. Mitani ^A ^B , Y. Aoyagi ^D , M. Urakawa ^D , A. Ideta ^D , K. Matsumoto ^A ^B , Y. Hosoi ^A ^B and A. Iritani ^A ^B

+ Author Affiliations

- Author Affiliations

^A Institute of Advanced Technology, Kinki University, Wakayama, Japan

^B Department of Genetic Engineering, Kinki University, Wakayama, Japan

^C Wakayama Prefecture Livestock Experimental Station, Wakayama, Japan

^D ZEN-NOH Embryo Transfer Center, Tsukuba, Ibaraki, Japan. email: cfawr703@jtw.zaq.ne.jp

Reproduction, Fertility and Development 17(2) 170-170 https://doi.org/10.1071/RDv17n2Ab40
Submitted: 1 August 2004 Accepted: 1 October 2004 Published: 1 January 2005

Abstract

In somatic cell cloning, the cell cycle phase of the donor cells has critical impact on nuclear reprogramming and chromosomal normality of the reconstructed embryos. Recently, enhanced development to full term was obtained with embryos reconstructed with bovine fibroblasts soon after cell division (early G₁ cells, Kasinathan P et al. 2001 Nat. Biotech. 19, 1176–1178; Urakawa M et al. 2004 Theriogenology 62, 714–728). In this study, to investigate the detailed cell cycle characteristics and gene expression of the early G₁ cells as nuclear donors, we examined the cell proliferating and nuclear activity by detecting PCNA and Ki-67 in the cells, and the gene expression in the cells transfected with the luciferase gene. Bovine fibroblasts were transfected with chicken β-actin/firefly luciferase fusion gene (β-act/luc+), and stably transfected; cloned cells were used for cell analysis. We compared cell cycle characteristics for quiescent cells (0.4% serum for 7 days), cell doublets (early G₁ cells) prepared by the “shake-off” method, and proliferating (30 to 40% confluency) cells. The presence of PCNA and Ki-67 and the incorporation of BrdU in the cells were determined by immunohistochemical analysis. The LUC+ signal (luminescence) in the cells was detected with an imaging photon counter for 10 consecutive min. Embryos reconstructed with these cells were cultured for 168 h for examination of blastocyst development. Experiments were repeated three times, and the data were analyzed with Fisher's PLSD test following ANOVA. Incorporation of BrdU was observed only in proliferating cells (24% of the cells). Neither PCNA nor Ki-67 signals were detected in the quiescent cells. PCNA was detected but Ki-67 was not detected in early G₁ cells. Both PCNA and Ki-67 were detected in the proliferating cells. A strong LUC+ signal (6354 ± 673 pixels/cell) was detected in the proliferating cells, and weak signals were detected in the early G₁ (2044 ± 303 pixels/cell, P < 0.05) and quiescent cells (617 ± 59 pixels/cell, P < 0.05). The rate of blastocyst development with early G₁ cells was higher (45/133, 32%) than that with starved and proliferating cells (47/233, 21%, and 41/258, 14%, respectively, P < 0.05). These results indicate that early G₁ cells were actively proliferating cells because of the positive PCNA signals, but their nuclei were silent because of the absence of Ki-67 signals and the weak LUC+ signals. These characteristics of the early G₁ cells might enhance the development of the reconstructed embryos.

This study was supported by a Grant-in-Aid for the 21st Century COE Program of the Japan MEXT, and by a grant from the Wakayama Prefecture Collaboration of Regional Entities for the Advancement of Technological Excellence of the JST.