Angelica M. Giraldo

Effect of Epigenetic Modifications of Donor Somatic Cells on the Subsequent Chromatin Remodeling of Cloned Bovine Embryos

Evidence indicates that failure of nuclear transfer (NT) embryos to develop normally can be attributed, at least partially, to the use of differentiated cells as the donor karyoplast. Blastocyst production and development to term of cloned embryos has been hypothesized to differ between population doublings of the same cell line as a consequence of changes in the levels of DNA methyltransferase 1 (DNMT1) and methylated DNA during in vitro culture. The objective of this study was to determine embryo production, developmental potential, and gene expression patterns of prehatched and posthatched embryos generated using donor cells with different levels of DNMT1 transcript. Day 7 embryos generated using donor cells with high and low levels of DNMT1 mRNA were transferred to recipient cows. Embryos recovered on Day 13 were morphologically characterized or used for gene expression analysis of DNMT, INFT, and MHC1. A higher proportion of 8- to 16-cell embryos developed to the blastocyst stage when cells with low levels of DNMT1 mRNA were used as donor nuclei. Day 13 NT embryos generated using donor cells with decreased levels of DNMT1 mRNA and capable of developing beyond the 8- to 16-cell stage produced a larger number of apparently developing embryos, larger conceptuses, and a higher expression of DNMT3A transcript than NT embryos reconstructed using cells with high levels of DNMT1 mRNA. However, abnormal gene expression of DNMT, INFT, and MHC1 was noted in the majority of cloned embryos, indicating inefficient nuclear reprogramming and retarded embryo development. Furthermore, aberrant DNMT1 expression may partially contribute to the inefficient nuclear reprogramming observed in cloned embryos.

Isolation and Characterization of Porcine Adipose Tissue-Derived Adult Stem Cells

Background: Stem cell characteristics such as self-renewal, differentiation and expression of CD34 and CD44 stem cell markers have not been identified in porcine adipose tissue-derived adult stem (ADAS) cells. The objective of this study was to develop a protocol for the isolation and culture of porcine adipose tissue-derived cells and to determine stem cell-like characteristics. Methods: Primary cultures were established and cell cultures were maintained. Cloning capacity was determined using a ring cloning procedure. Primary cultures and clones were differentiated and stained for multiple differentiated phenotypes. CD34 and CD44 messenger ribonucleic acid (mRNA) was isolated and reverse transcriptase polymerase chain reaction was used to compare expression profiles. Results: An average of 2,700,000 nucleated cells/ml was isolated; 26% were adherent, and cells completed a cell cycle approximately every 3.3 days. Ring cloning identified 19 colonies. Primary cultures and clones were determined to differentiate along osteogenic, adipogenic and chondrogenic tissue lineages. The mRNA expression profiles showed CD34 expression was higher for undifferentiated ADAS cells versus differentiated cell types and the CD34 expression level was lower than that of CD44 among differentiated cells. Conclusion: Improved culture conditions and defined cellular characteristics of these porcine ADAS cells have been identified. Porcine ADAS can self-renew, can differentiate into multiple tissue lineages and they express CD34.

Effects of culture medium and protein supplementation on mRNA expression of in vitro produced bovine embryos

Numerous studies have reported aberrant gene expression levels attributed to suboptimal in vitro culture conditions. This study investigated the effects of different culture systems and protein sources on the developmental competence of in vitro production (IVP) embryos measured by cleavage and blastocyst rates, cell number, and relative abundance of POU5F1 (OCT4), nanog, GJA1 (connexin 43), and SLC2A1 (GLUT1) transcripts when compared to in vivo embryos. Experiment 1 compared IVP embryos cultured in either synthetic oviductal fluid (SOFaa) or potassium simplex optimized medium supplemented with amino acids (KSOMaa). Experiment 2 compared the same two culture systems with and without the addition of calf serum (CS). Results from both experiments indicated that despite similar developmental rates, significant differences were observed at the mRNA level. In Experiment 1, OCT4 was the only transcript to have a mean abundance level significantly higher in KSOMaa blastocysts when compared with both SOFaa and in vivo embryos. The same pattern of upregulation of OCT4 mRNA was noted in Experiment 2. There were no significant alterations of the ICM specific transcript nanog in either experiment. In contrast to reports by others, connexin 43 mRNA was not expressed at detectable levels in in vivo embryos analyzed in our studies. Blastocysts cultured in SOFaa with CS or KSOMaa had a significant upregulation of GLUT1 mRNA when compared with other treatments and in vivo embryos. Until differences between IVP and in vivo embryos are minimized, aberrations in IVP will continue to arise. Mol. Reprod. Dev. 76: 783–793, 2009.

Sex Ratio of Bovine Embryos and Calves Originating from the Left and Right Ovaries

An asymmetric distribution of the sexes within the left and right uterine horns has been described in multiple species. A series of experiments were conducted to evaluate the sex ratio (% male) of calves gestated in the left and right uterine horns, as well as the sex ratio of embryos originating from the left and right ovaries of cattle. The sex ratio of calves gestated in the right uterine horn of naturally mated cows was significantly higher compared with the sex ratio of calves gestated in the left uterine horn. In addition, the sex ratio of the left and right uterine horns differed significantly from parity. The sex ratio of embryo transfer calves born following transfer to the left and right uterine horns was not significantly different. Additionally, the proportion of male embryos collected from the right uterine horns was significantly greater than from the left uterine horns of superovulated cows. The sex ratio of embryos collected from the left and right uterine horns of unilaterally ovariectomized cows was not significantly different. However, more female than male embryos were produced when left ovary oocytes fertilized in vitro. In conclusion, the results of these experiments demonstrate that a significantly greater proportion of males are gestated in the right uterine horn of cattle and a greater proportion of females in the left. Additionally, the data indicate that sex-specific selection pressure may be applied to embryos by ovarian factors rather than by the uterine environment.

Inhibition of DNA methyltransferase 1 expression in bovine fibroblast cells used for nuclear transfer

The aberrant expression of DNA methyltransferase 1 (DNMT1) in cloned embryos has been implicated as a possible factor in the improper donor genome reprogramming during nuclear transfer. DNMT1 is responsible for maintaining DNA methylation and the subsequent differentiation status of somatic cells. The presence of DNMT1 transcript in the donor cell may contribute to perpetuation of the highly methylated status of the somatic nuclei in cloned embryos. The objective of the present study was to determine the methylation pattern of cloned embryos reconstructed with cells treated with DNMT1-specific small interfering RNA (siRNA). Bovine fibroblasts were transfected with a DNMT1-specific siRNA under optimised conditions. The expression patterns of DNMT1 were characterised by Q-PCR using the DeltaDeltaC(T) method. The level of DNMT1 was successfully decreased in bovine fibroblast cells using a DNMT1-specific siRNA. Additionally, reduction in the expression of DNMT1 mRNA and DNMT1 protein led to a moderate hypomethylation pattern in the siRNA-treated cells. The use of siRNA-treated cells as donor nuclei during nuclear transplantation induced a reduction in methylation levels compared with controls but did not reduce methylation levels to that of IVF embryos. Further studies are required to determine if this level of reduced methylation is sufficient to improve subsequent development.

Production of Transgenic and Knockout Pigs by Somatic Cell Nuclear Transfer

Xenotransplantation is one alternative to transplantation of human organs which has been investigated. It is generally accepted that the pig represents the most logical choice of animals to serve as organ donors for xenotransplantation. Moreover, the implementation of cloning by somatic cell nuclear transfer (SCNT) and transgenic techniques have resulted in the production of numerous transgenic pigs than can be used for xenotransplantation purposes as well as models for human diseases.

Gene Expression of Dnmt1 Isoforms in Porcine Oocytes, Embryos, and Somatic Cells

In the mouse, the dynamics of genomic methylation and the initial events of gametic imprinting are controlled by the activity of an oocyte isoform of the DNA methyltransferase-1 (Dnmt1o) enzyme. The objectives of this study were to identify the alternative splicing variants of Dnmt1 in porcine oocytes and determine the gene expression pattern of the different Dnmt1 isoforms during embryo development. A rapid amplification of cDNA ends (RACE ) system was used to amplify the 5 cDNA end of Dnmt1 isoforms in porcine oocytes. RNA levels of the Dnmt1 isoforms were analyzed in porcine oocytes and embryos. DNMT1 protein expression of oocytes and somatic cells were analyzed by western blot and immunostaining. Two new Dnmt1o RNA isoforms were identified--Dnmt1o1 and Dnmt1o2. The previously reported somatic Dnmt1 isoform (Dnmt1s) was expressed at low but constant levels in oocytes and embryos from the two-cell to the blastocyst stage. Abundant RNA levels of Dnmt1o1 and Dnmt1o2 were detected in oocytes and embryos from the two- to the eight- to 16-cell stage. Levels of these Dnmt1o transcripts were low at the morula and blastocyst stages. Although Dnmt1s was present in all the somatic cell types analyzed, Dnmt1o1 and Dnmt1o2 were not detected in any somatic tissues. As predicted by the RNA sequence and verified by western blot analysis, Dnmt1o1 and Dnmt1o2 RNAs translate one DNMT1o enzyme. Western blot analysis confirmed that both the oocyte and the somatic forms of DNMT1 protein are present in porcine oocytes and early embryos, whereas somatic cells produce only DNMT1s protein. DNMT1o is localized mainly in the nuclei of oocytes and early embryos, whereas DNMT1s is expressed in the ooplasm cortex of oocytes and cytoplasm of early embryos.

Gene expression pattern and downregulation of DNA methyltransferase 1 using siRNA in porcine somatic cells.

DNA methylation plays a significant role in the expression of the genetic code and affects early growth and development through their influence on gene expression. Manipulation of the DNA methylation marks of differentiated cells will allow a better understanding of the different molecular processes associated with chromatin structure and gene expression. The objective of this study was to identify small interfering RNAs (siRNAs) with the ability to reduce DNA methyltransferase 1 (Dnmt1) mRNA and consequently decrease Dnmt1 protein as well as DNA methylation in porcine cells. Fibroblasts from four porcine fetuses were established and cultured in 5% CO2 in air at 38 degrees C. Optimal transfection conditions were evaluated using a FITC-labeled control siRNA. Four Dnmt1-specific siRNAs were evaluated upon transfection of each cell line. A nonsilencing siRNA was used as a negative control. The expression patterns of Dnmt1 were analyzed by Q-PCR. The combination of 1 microg of siRNA and a 1:6 siRNA to transfection reagent ratio produced the highest transient transfection rates without affecting cell viability. Downregulation of Dnmt1 varied between siRNAs. Transfection of porcine cells with highly effective siRNAs resulted in a drastic reduction of Dnmt1 mRNA and a slight decrease in protein production. However, this small reduction in the protein concentration induced significant genomic hypomethylation. These data suggest that although Dnmt1 mRNA abundance plays an important role during protein regulation, Dnmt1 enzyme is mainly posttranscriptionally regulated. Subsequent use of these cells for cloning, differentiation, and cancer studies will provide insight as to how methylation of the DNA affects genomic reprogramming.

Inhibition of DNA Methylation in Somatic Cells

DNA methylation plays a significant role in the expression of the genetic code and affects early growth and development through its influence on gene expression. DNA methyltransferase 1 (Dnmt1) is the enzyme responsible for maintaining the methylation marks through cell division. However, the de novo methyltransferases, Dnmt3a and Dnmt3b, can also contribute to the maintenance of the methylation pattern. Manipulation of these enzymes, especially Dnmt1, provides a means to alter DNA methylation levels. Manipulation of the DNA methylation pattern of somatic cells will allow a better understanding of the different molecular process associated with chromatin structure and gene expression. Different approaches to artificially manipulate the expression of Dnmt1 in somatic cells include the addition of 5-azacytidine, culture of cells for an extended period of time, and the use of small interfering RNA technologies.