Survival ofEscherichia coli after storage in various frozen menstrua

The effect of storage at –9 C onEscherichia coli was examined. In buffer or water, survival after three days was less than 40%. Dimethylsulfoxide (DMSO) (10%) and glycerol (10%) were very protective with over 90% survivors. Variability of replicate samples was greater with frozen than with non-frozen suspensions.With a slide culture technique, it was found that the time required for the thawed cells to complete their first division was increased up to a time equivalent to over two divisions, dependent upon the protective storage menstrua.Injury as shown by inability to grow on a minimal medium after thawing was negligible when the cells were frozen in DMSO or glycerol. Cells stored in frozen buffer were sensitive to a 20 min treatment with actinomycin D following thawing but cells frozen in glycerol or DMSO showed little death or injury. The results suggest that an alteration of the cell envelope is initially responsible for death by freezing.This work was supported in part by U.S. Public Health Service Research Grant EF-428 from the Division of Environmental Engineering and Food Protection.     

Medium composition for effective slow freezing of embryonic cell lines derived from marine medaka (Oryzias dancena)

This study was conducted to identify optimal medium composition for freezing Oryzias dancena embryonic cell lines. Different freezing media consisting of various concentration of dimethyl sulfoxide (DMSO), fetal bovine serum (FBS), and trehalose were prepared and long-term cultured embryonic cell line was frozen in each freezing medium by conventional slow freezing program for 7 days. Through measurement of viability and growth of post-thaw cells frozen in each freezing medium, it was determined that optimal composition of three components was 10 % DMSO, 20 % FBS, and 0.1 M trehalose. The post-thaw cells frozen in optimal freezing medium showed similar morphology and growth rate with non-frozen cells. Next, this condition was applied to two different sets of experiment; (1) freezing of the same cells during expanded period (57 days) and (2) freezing of short-term cultured cells from other batches for 7 days. The viability of post-thaw cells was significantly low and comparable in set 1 and 2, respectively, when compared with the result of long term-cultured cells frozen in optimal freezing medium for 7 days and similar morphology and growth rate with non-frozen counterparts were detected in the post-thaw cells from both sets. In conclusion, this study first reports the optimal medium composition for freezing O. dancena embryonic cells, which can contribute to fish species preservation as well as improvement of cell-based biotechnology by providing stable cell storage.     

Effect of cryoprotectants on release of various enzymes from buck spermatozoa during freezing

Semen samples from 12 bucks Were extended with 10 different extenders containing glycerol, DMSO, glycerol + DMSO, and glycerol + lactose in varying concentrations as cryoprotective agents. The activities of acrosin, hyaluronidase, alkaline phosphatase (AKP), aspartate aminotransferase (AST), alanine amino transferase (ALT) and lactic dehydrogenase (LDH) were assayed in equilibrated (Prefreeze) and frozen thawed (Postfreeze) semen samples. Significantly (P < 0.01) higher intracellular activity of acrosin was recorded in semen samples extended with lactose than with the other extenders, with the maximum being with Tris yolk glycerol lactose (TYGL(180)). Effects of extenders on acrosin activity were significant (P < 0.01) at both of the pre-and postfreeze stages. However, extracellular activities of hyaluronidase, alkaline phosphatase, transaminases (AST and ALT), and lactic dehydrogenase were significantly higher in extenders containing DMSO than lactose. Leakage of these enzymes was found to increase from the prefreeze to the post freeze stage.     

Comparison of permeating and nonpermeating cryoprotectants for mouse sperm cryopreservation

Mouse sperm has proven to be more difficult to cryopreserve than sperm of other mammalian species. Published reports show that only three cryoprotectant agents (CPAs), alone or combined, have been studied: glycerol and dimethyl sulfoxide (DMSO), as permeating agents, and raffinose, as a nonpermeating agent. To date, the most consistent results for mouse sperm cryopreservation have been achieved by use of raffinose/skim milk as cryoprotectant with rapid cooling at 20 degrees C per minute. In this study, we compared the cryoprotection provided by permeating (glycerol, formamide, propanediol, DMSO, adonitol) or nonpermeating (lactose, raffinose, sucrose, trehalose, d-mannitol) compounds for freezing mouse sperm. Different solutions were made using 3% skim milk solution as the buffer or extender in which all different cryoprotectant agents were dissolved at a concentration of 0.3 M, with a final osmolality of approx. 400 mOsm. Sperm samples from CB6F1 (hybrid) and C57BL/6J (inbred) mice collected directly into each CPA were frozen/thawed under identical conditions. After thawing and CPA elimination (centrifugation) raffinose (59%), trehalose (61%), and sucrose (61%) sustained the best motility (P = < 0.1) of the nonpermeating agents, whereas the best of the permeating agents was DMSO (42%). Membrane integrity was analyzed and showed that the simple exposure (prefreeze) to sugars was less harmful than the exposure to glycols. Coincidentally, sperm frozen in trehalose (41%), raffinose (40.5%), and sucrose (37.5%) were the samples less injured among all different postthawed CPA tested. The in vitro fertilization results demonstrated that hybrid mouse spermatozoa frozen with sugars (lactose 80%, raffinose 80%, trehalose 79% of two-cell embryos production) were more fertile than those frozen with glycols (glycerol 11%).     

Evaluation of the effects of cryopreservation of isolated erythrocytes and leukocytes of largemouth bass by flow cytometry

We examined the effects of separation and freezing on fish leukocyte and erythrocyte morphology by light microscopy and on DNA content as measured by flow cytometry (FCM). Leukocytes and erythrocytes of largemouth bass Micropterus salmoides were isolated by density gradient centrifugation of whole blood, and frozen in liquid nitrogen in a buffer containing DMSO as a cryopreservative. The coefficient of variation (CV) of the G₀/G₁ peak of the cells was used to assess variation in nuclear DNA content within cell populations before and after separation and freezing treatments. In erythrocytes, the CV did not change significantly (P>0.05) when nuclei were isolated and stained without freezing or when erythrocytes were frozen prior to nuclear isolation and staining. In leukocytes, freezing and thawing prior to isolation and staining of nuclei significantly increased the CV (P<0.05), and produced hyperdiploid shoulders of the G₀/G₁ peak. However, the CV of leukocyte nuclei that were isolated and stained prior to freezing and the CV of non-frozen leukocyte nuclei did not differ (P>0.05). Microscopy showed that the freezing protocol had little effect on erythrocyte morphology, but caused irregular swelling in leukocytes. Freezing intact leukocytes also significantly (p<0.05) altered the apparent distribution of cells among the phases of the cell cycle as measured by FCM. The distributions of leukocyte nuclei that were isolated and stained prior to freezing were not different to non-frozen leukocytes. DNA measurements of nucleated blood cells are widely used in physiological, genetic and toxicological studies. Our results suggest that whole blood and erythrocytes for use in such studies can be frozen whole using a simple protocol, but leukocyte nuclei must be isolated and stained before freezing to avoid serious artifacts.     

Ultrastructure of bovine embryos frozen and thawed by a two-step freezing method

An ultrastructural evaluation of a rapid tow-step freezing method, by which 6-7-day-old bovine embryos equilibrated in 1.4 M glycerol in Dulbecco's phosphate-buffered saline were frozen and thawed, was undertaken. In all non-frozen control embryos trophoblastic and embryonic cells formed a spherical structure enclosed by an intact zona pellucida. The spacial arrangement of the cells of the frozen embryos was less regular and the surrounding zona pellucida was damaged in approximately half of the cases. Some embryonic cells had increased electron density and lysosomal content showing reaction sites for acid phosphatase. In all frozen embryos, cytoplasmic defects appearing as non-membrane-bound 'empty spaces' were observed more frequently in the trophoblastic cells than in the embryonic cells. Culture of frozen embryos for 24 h revealed that cells appearing nondefective after culture may have the capability of organizing a viable embryonic structure. It was found that the most commonly used freezing method is associated with certain morphological changes. However, no additional cryoinjuries were observed in comparisons with the more complicated freezing procedures using dimethylsulfoxide as cryoprotectant.     

Differing actions of penetrating and nonpenetrating cryoprotective agents.

A two-step freezing technique has been used to examine the role of cryoprotective agents during cooling. Chinese hamster fibroblasts were cooled to various subzero holding temperatures and subsequently thawed or cooled to ?196 °C before thawing. Cells were suspended in various concentrations of dimethylsulfoxide (DMSO) or hydroxyethyl starch (HES) before freezing. The results indicated differing protective actions of DMSO and HES. These differences were verified using glycerol as either a penetrating or a nonpenetrating agent.The results are consistent with the concepts that cryoprotection is based on the avoidance or minimization of intracellular freezing and the minimization of damage to the cell from the environment of concentrated solutes during cooling, and that the colligative action of both penetrating and nonpenetrating agents allows the cells to survive the conditions for a reduction of cell water content during cooling thereby reducing the amount of intracellular freezing. The results indicate that penetrating and nonpenetrating agents accomplish this in different ways. Penetrating agents create the environment for a reduction of cell water content at temperatures sufficiently low to reduce the damaging effect of the concentrated solutes on the cells. Nonpenetrating agents osmotically “squeeze” water from the cells primarily during the initial phases of freezing at temperatures between ?10 and ?20 °C when these additives become concentrated in the extracellular regions.     

Flow cytometric cell cycle analysis of somatic cells primary cultures established for bovine cloning

An important factor governing developmental rates of somatic cloned embryos is the phase of the cell cycle of donor nuclei. The aim of this experiment was to investigate the distribution of cell cycle phases in bovine cumulus and fibroblast cells cultured using routine treatment, and under cell cycle-arresting treatments. The highest percentages of cumulus cells in the G0 + G1 stage were observed in uncultured, frozen/thawed cells originating from immature oocytes (79.8 +/- 2.2%), fresh and frozen/thawed cells from in vitro matured oocytes (84.1 +/- 6.2 and 77.8 +/- 5.7%, respectively), and in cycling cells (72.7 +/- 16.3 and 78.4 +/- 11.2%, respectively for cumulus cells from immature and in vitro matured oocytes). Serum starvation of cumulus cultures markedly decreased percentages of cells in G0 + G1, and prolonged starvation significantly increased (P < 0.05) percentages of cells in G2 + M phase. Culture of cumulus cells to confluency did not increase percentages of cells in G0 + G1. Contrary to findings in cumulus cells, significantly higher percentages of cells in G0 + G1 were apparent when fibroblast cells were cultured to confluency or serum starved, and significantly increased (P < 0.01) as the starvation period was prolonged. It is concluded that for particular cell types specific strategies should be used to attain improvements in the efficiency of cloning procedures.     

Cryopreservation of isolated rat hepatocytes

Summary Isolated parenchymal hepatocytes from adult rats were frozen in media containing 10% glycerol, 10% dimethylsulfoxide (DMSO), or 20% DMSO. Three microsome-associated functions were compared in nonfrozen cells and cells frozen in each of the above cryoprotectant solutions. Freezing in DMSO maintains cytochromes P-450 and b₅ and NADPH-cytochrome C reductase at levels nearer to control values than does freezing in glycerol. Cells frozen and subsequently thawed and cultured for 24 h lose a greater amount of cytochrome P-450 than do nonfrozen cultured cells. The levels of cytochrome b₅ and reductase in frozen-thawed cells remain close to control values. Cell viability (trypan blue dye exclusion and percentage of attached cells) after freezing is maintained better using DMSO as a cryoprotectant. Dimethylsulfoxide protects the hepatocytes from freeze-induced damage to the extent that many viable cells attach to collagen-coated petri dishes, survive for at least 24 h, and still maintain significant levels of enzymes of importance to drug and carcinogen metabolism. This work was supported by Grant CA-30241 from the National Institutes of Health, Bethesda, Maryland.     

Development of in vitro matured bovine oocytes after cryopreservation with different cryoprotectants

In vitro matured bovine oocytes at the metaphase-II stage were slowly frozen in phosphate buffered saline (PBS) containing 1.0 M glycerol, 1.0 M dimethylsulfoxide (DMSO) or 1.0 M propylene glycol (PROH). When thawed rapidly, more (P<0.05) oocytes were morphologically normal after being frozen with DMSO (86%) or PROH (83%) than with glycerol (62%). When inseminated in vitro with frozen-thawed bull spermatozoa, higher (P<0.05) penetration rates were observed in DMSO (79%) or PROH (76%) than in glycerol (48%). The percentages of oocytes developing to the 2-cell stage at 48 h postinsemination were also significantly (P<0.05) higher in DMSO (51%) and PROH (54%) than in glycerol (33%). However, a significant increase in the proportions of 8-cell embryos (46 vs 21 to 26%; P<0.05) at 72 h postinsemination and morulae (14 vs. 6 to 8%; P<0.05) was derived from oocytes frozen with PROH than with DMSO or glycerol. In conclusion, the type of cryoprotectant used is one of the critical factors affecting developmental competence of bovine oocytes frozen at the metaphase-II stage. For this stage of oocytes, PROH was the most effective, yielding a large number of 8-cell embryos and morulae than either glycerol or DMSO in a slow freezing method combined with a 3-step thawing protocol.     

Use of sucrose during removal of cryoprotectants after thawing eight-cell mouse embryos

Eight-cell mouse embryos were frozen in 0.5-ml plastic straws in modified Dulbecco's phosphate buffered saline (PBS) plus 5% steer serum plus either 1.32 M dimethyl sulfoxide (DMSO) or 1.32 M glycerol. Upon thawing, embryos were diluted 1:4 with 0.0, 0.2, 0.6, or 1.0 M sucrose solutions within the straws. Thawing was either in air at ambient temperature or in 8 degrees C or 38 degrees C water. After 48 h of culture, more embryos frozen in DMSO and thawed in 8 degrees C and 37 degrees C water developed to blastocysts (87 and 93%, respectively) than embryos thawed in air (75%; P < 0.05). No significant differences in development were noted among the three thawing regimens when embryos were frozen with glycerol. There was no significant effect of concentration of sucrose during dilution on development of embryos postthaw. With glycerol as the cryoprotectant, damage to zonae pellucidae increased as thawing rates increased, whereas the opposite was observed with DMSO as the cryoprotectant (P < 0.05).     

Production of normal young following transfer of mouse embryos obtained by in vitro fertilization using cryopreserved spermatozoa

Spermatozoa from cauda epididymis of mature mice were suspended in preservation solution (Dulbecco's PBS containing raffinose in combination with glycerol, DMSO or skim milk as freezing protective agents). The suspension was frozen by the dry ice-alcohol method and preserved for 1-120 days in liquid nitrogen (-196 degrees C). Highest sperm viability after thawing was obtained with a combination of 10% raffinose and 5% glycerol or with a combination of 10% raffinose and 10% DMSO. These frozen thawed sperm were found to have fertilizing capacity when used for in vitro fertilization. The 2-cell embryos obtained through the above procedures developed into normal pups at a high rate when transferred into the oviducts of pseudopregnant female mice.     

Cryopreservation of Sheep Red Blood Cells

The protection of sheep erythrocytes at freezing temperatures was investigated using glycerol, dimethylsulfoxide (DMSO), glucose and four different types of polyvinylpyrrolidone (PVP) as cryoprotective agents. Depending on type (molecular weight) and concentration good protection was obtained with PVP, whereas glycerol, DMSO and glucose were unsatisfactory. Recovery of cells after thawing was most successful when the cells had been frozen at a concentration of 1–2 × 109 cells/ml. No cells tolerated freezing at −20 °G. Best results were obtained when the cells were frozen directly in liquid nitrogen (−196°G).     

Cryopreservation and subsequent viability of human bone marrow in hematologic malignancies: Comparison of two different methods of cell reconstitution

Bone marrow cells collected from patients with hematologic malignancies were cryopreserved using DMSO as a cryoprotective agent. The growth kinetics of hemopoietic stem cells frozen to −196 °C was monitored immediately after thawing by the semisolid agar CFU-C assay and two different methods of cell reconstitution were compared. In the first procedure, thawed cells were plated after the removal of DMSO by washing the cell suspension; in the second, cell suspensions were cultured after a simple 1:1 dilution of DMSO with medium. The numbers of CFU-C per 2 × 10⁵ cells plated was higher by washing out the DMSO in all the groups studied. However, the absolute numbers of CFU-C contained in the whole ampoules after the freezing procedures was approximately the same using both methods. It is concluded that washing the cells only apparently yielded a better cloning efficiency, suggesting that such a procedure led to a higher mature nucleated cell loss with the consequence of a CFU-C concentration. This trend seems particularly evident in cells from the AML and CML patients.     

Freezing damage of bovine erythrocytes: Simulation using glycerol concentration changes at subzero temperatures

When a cell is frozen and thawed, it is exposed to (i) lowered temperature, (ii) increased solute concentration during freezing, and (iii) decreased solute concentration during thawing. Without actually freezing the cells, an attempt has been made to simulate physical-chemical changes to which bovine erythrocytes are exposed when frozen and thawed in glycerol solutions. Experimentally, the study consisted of suspending erythrocytes in 1, 2, or 3 glycerol at 20 °C for various times and then exposing them to each of several dilution sequences. The dilution sequences were: (i) transfer from the initial glycerol concentration at 20 °C into the same concentration at −5 °C, (ii) transfer into an increased glycerol concentration at 20 °C, (iii) transfer into an increased followed by a decreased glycerol concentration at 20 °C, (iv) transfer into an increased glycerol concentration at −5 °C, and (v) transfer into an increased followed by a decreased glycerol concentration at −5 °C. This last sequence is analogous to the exposure that cells undergo at subzero temperatures to increased solute concentration during freezing and decreased solute concentration during thawing. This dilution sequence yielded a survival pattern very similar to that obtained when bovine erythrocytes are frozen and thawed, and thus does appear to mimic freezing damage. It is concluded that a major factor in freezing damage is the extent to which a cell must shrink or swell to achieve osmotic equilibrium at subzero temperatures in partially frozen or thawed solutions.     

Effect of different cryoprotectant agents on spermatogenesis efficiency in cryopreserved and grafted neonatal mouse testicular tissue

Restoration of male fertility associated with use of the cryopreserved testicular tissue would be a significant advance in human and animal assisted reproductive technology. The purpose of this study was to test the effects of four different cryoprotectant agents (CPA) on spermatogenesis and steroidogenesis in cryopreserved and allotransplanted neonatal mouse testicular tissue. Hank’s balanced salt solution (HBSS) with 5% fetal bovine serum including either 0.7 M dimethyl sulfoxide (DMSO), 0.7 M propylene glycol (PrOH), 0.7 M ethylene glycol (EG), or glycerol was used as the cryoprotectant solution. Donor testes were collected and dissected from neonatal pups of CD-1 mice (one day old). Freezing and seeding of the testicular whole tissues was performed using an automated controlled-rate freezer. Four fresh (non-frozen) or frozen–thawed pieces of testes were subcutaneously grafted onto the hind flank of each castrated male NCr nude recipient mouse and harvested after 3 months. Fresh neonatal testes grafts recovered from transplant sites had the most advanced rate of spermatogenesis with elongated spermatid and spermatozoa in 46.6% of seminiferous tubules and had higher levels of serum testosterone compared to all other frozen–thawed-graft groups (p < 0.05). Fresh grafts and frozen–thawed grafts in the DMSO group had the highest rate of tissue survival compared to PrOH, EG, and glycerol after harvesting (p > 0.05). The most effective CPA for the freezing and thawing of neonatal mouse testes was DMSO in comparison with EG (p < 0.05) in both pre-grafted and post-grafted tissues based on histopathological evaluation. Likewise, the highest level of serum testosterone was obtained from the DMSO CPA group compared to all other cryoprotectants evaluated (p < 0.05). The typical damage observed in the frozen–thawed grafts included disruption of the interstitial stroma, intercellular connection ruptures, and detachment of spermatogonia from the basement membrane. These findings indicate that neonatal mouse testes were most effectively preserved when frozen with HBSS medium with DMSO and that the type of CPA is a significant factor to obtain the most advanced stages of spermatogenesis and steroidogenesis after cryopreservation, thawing, and transplantation of neonatal mouse testes.     

Novel cryoprotectant significantly improves the post-thaw recovery and quality of HSC from CB

BACKGROUND: Hematopoietic stem cells (HSC) have traditionally been frozen using the cryoprotectant DMSO in dextran-40, saline or albumin. However, the process of freezing and thawing results in loss of HSC numbers and/or function. METHODS: This study investigated the use of CryoStor for the freezing of HSC from cord blood (CB). CB donations (n = 30) were collected under an Institutional Ethics Committee-approved protocol, volume reduced and frozen using three different methods of cryoprotection. Aliquots were frozen with either 10% DMSO in dextran-40, 10% DMSO in CryoStor or 5% DMSO in CryoStor. Prior to freezing samples were separated for nucleated cell (NC) and CD34+ counts and assessment of CD34+ viability. Aliquots were frozen and kept in vapor phase nitrogen for a minimum of 72 h. Vials were rapidly thawed at 37 degrees C and tested for NC and CD34+ counts and CD34+ viability and colony-forming unit (CFU) assay. RESULTS: Cells frozen with CryoStor in 10% DMSO had significantly improved NC (P < 0.001), CD34+ recovery, viable CD34+ (P < 0.001) and CFU numbers (P < 0.001) compared with dextran in 10% DMSO. CryoStor in 5% DMSO resulted in significantly improved NC (P < 0.001) and CFU (P < 0.001). Discussion: These results suggest that improved HSC recovery, viability and functionality can be obtained using CryoStor with 10% DMSO and that similar if not better numbers can be obtained with 5% DMSO compared with dextran-40 with 10% DMSO.     

Effect of glycerol and dimethyl sulfoxide on cryopreservation of rhesus monkey (Macaca mulatta) sperm

Glycerol and dimethyl sulfoxide (DMSO) are widely used as penetrating cryoprotectants in the freezing of sperm, and various concentrations are applied in different species and laboratories. The present study aimed to examine the effect of these two cryoprotectants at different concentrations (2%, 5%, 10%, and 15% glycerol or DMSO) on rhesus monkey sperm cryopreservation. The results showed that the highest recovery of post-thaw sperm motility, and plasma membrane and acrosome integrity was achieved when the sperm was frozen with 5% glycerol. Spermatozoa cryopreserved with 15% DMSO showed the lowest post-thaw sperm motility, and spermatozoa cryopreserved with 15% glycerol and 15% DMSO showed the lowest plasma membrane integrity among the eight groups. The results achieved with 5% glycerol were significantly better for all parameters than those obtained with 5% DMSO. The functional cryosurvival of sperm frozen with 5% glycerol was further assessed by in vitro fertilization (IVF). Overall, 85.7% of the oocytes were successfully fertilized, and 51.4% and 5.7% of the resulting zygotes developed into morulae and blastocysts, respectively. The results indicate that the type and concentration of the penetrating cryoprotectant used can greatly affect the survival of rhesus monkey sperm after it is frozen and thawed. The suitable glycerol level for rhesus monkey sperm freezing is 5%, and DMSO is not suitable for rhesus monkey sperm cryopreservation.     

Immune reactivity of frozen-thawed murine spleen cells.

Spleen cells from mice immunized with SRBC were subjected to controlled rate freezing to ?100 °C. Complete recovery of PFC was obtained with DMSO used as the cryopreservative. Simple dilution of spleen cells in DMSO, or a single cycle of freezing and thawing in DMSO prior to short-term culture, resulted in early loss of recoverable cells. A single cycle of freezing and thawing inhibited the in vitro immune response to SRBC while having little effect on the response to TNP-T4. The in vitro blastogenic responses to LPS and PHA-P were severely reduced in cultures of frozen and thawed cells.     

Examination of a modified cell cycle synchronization method and bovine nuclear transfer using synchronized early G1 phase fibroblast cells

Somatic cell nuclear transfer has a low success rate, due to a high incidence of fetal loss and increased perinatal morbidity/mortality. One factor that may affect the successful development of nuclear transfer embryos is the cell cycle stage of the donor cell. In order to establish a cell cycle synchronization method that can consistently produce cloned embryos and offspring, we examined the effects of different combinations of three cell treatments on the recovery rate of mitotic phase cells using bovine fetal fibroblasts. In the first experiment, we examined the recovery rate of mitotic phase cells by a combination of treatment with a metaphase arrestant (1 microM 2-methoxyestradiol), shaking the plate and selecting cells with a diameter of 20 microns. As a result, 99% of mitotic phase cells were recovered by repeating the combined treatment of metaphase arrestant and shaking, and collection of cells with a specific diameter. In the second experiment, nuclear transfer was carried out using early G1 phase cells by choosing pairs of bridged cells derived from mitotic phase cells recovered by the combined treatment of 1 microM 2-methoxyestradiol and shaking, and collection of cells with a diameter of 20 microns. The reconstructed embryos were transferred to recipient heifers to determine post-implantation development. Development of embryos reconstructed from early G1 phase cells from the >/=6 cells stage on Day 3 to the morula-blastocyst stage on Day 6 was 100%. Ten blastocysts constructed from two cell lines were transferred into 10 recipient heifers. Nine of the 10 recipients delivered single live calves. In conclusion, mitotic phase bovine fibroblast cells were easily recovered by the combined treatments of 1 microM 2-methoxyestradiol, shaking, and selecting cells of the appropriate diameter. Furthermore, nuclear transfer using cells in the early G1 phase as donor cells gave a high rate of offspring production.