Scott L. Pratt

Isolation, Characterization, Gene Modification, and Nuclear Reprogramming of Porcine Mesenchymal Stem Cells

Abstract Bone marrow mesenchymal stem cells (MSCs) are adult pluripotent cells that are considered to be an important resource for human cell-based therapies. Understanding the clinical potential of MSCs may require their use in preclinical large-animal models, such as pigs. The objectives of the present study were 1) to establish porcine MSC (pMSC) cultures; 2) to optimize in vitro pMSC culture conditions, 3) to investigate whether pMSCs are amenable to genetic manipulation, and 4) to determine pMSC reprogramming potential using somatic cell nuclear transfer (SCNT). The pMSCs isolated from bone marrow grew, attached to plastic with a fibroblast-like morphology, and expressed the mesenchymal surface marker THY1 but not the hematopoietic marker ITGAM. Furthermore, pMSCs underwent lipogenic, chondrogenic, and osteogenic differentiation when exposed to specific inducing conditions. The pMSCs grew well in a variety of media, and proliferative capacity was enhanced by culture under low oxygen atmosphere. Transient transduction of pMSCs and isogenic skin fibroblasts (SFs) with a human adenovirus carrying the gene for green fluorescent protein (GFP; Ad5-F35eGFP) resulted in more pMSCs expressing GFP compared with SFs. Cell lines with stable genetic modifications and extended expression of transgene were obtained when pMSCs were transfected with a plasmid containing the GFP gene. Infection of pMSC and SF cell lines by an adeno-associated virus resulted in approximately 12% transgenic cells, which formed transgenic clonal lines after propagation as single cells. The pMSCs can be expanded in vitro and used as nuclear donors to produce SCNT embryos. Thus, pMSCs are an attractive cell type for large-animal autologous and allogenic cell therapy models and for SCNT transgenesis.

Brief Report: Chimeric Pigs Produced from Induced Pluripotent Stem Cells Demonstrate Germline Transmission and No Evidence of Tumor Formation in Young Pigs

The recent development of porcine induced pluripotent stem cells (piPSCs) capable of generating chimeric animals, a feat not previously accomplished with embryonic stem cells or iPSCs in a species outside of rodents, has opened the doors for in‐depth study of iPSC tumorigenicity, autologous transplantation, and other key aspects to safely move iPSC therapies to the clinic. The study of iPSC tumorigenicity is critical as previous research in the mouse showed that iPSC‐derived chimeras possessed large numbers of tumors, rising significant concerns about the safety of iPSC therapies. Additionally, piPSCs capable of generating germline chimeras could revolutionize the transgenic animal field by enabling complex genetic manipulations (e.g., knockout or knockin of genes) to produce biomedically important large animal models or improve livestock production. In this study, we demonstrate for the first time in a nonrodent species germline transmission of iPSCs with the live birth of a transgenic piglet that possessed genome integration of the human POU5F1 and NANOG genes. In addition, gross and histological examination of necropsied porcine chimeras at 2, 7, and 9 months showed that these animals lacked tumor formation and demonstrated normal development. Tissue samples positive for human POU5F1 DNA showed no C‐MYC gene expression, further implicating C‐MYC as a cause of tumorigenicity. The development of germline‐competent porcine iPSCs that do not produce tumors in young chimeric animals presents an attractive and powerful translational model to study the efficacy and safety of stem cell therapies and perhaps to efficiently produce complex transgenic animals. STEM CELLS 2011;29:1640–1643

Improvements in Cloning Efficiencies May Be Possible by Increasing Uniformity in Recipient Oocytes and Donor Cells

Abstract The low efficiency of somatic cell cloning is the major obstacle to widespread use of this technology. Incomplete nuclear reprogramming following the transfer of donor nuclei into recipient oocytes has been implicated as a primary reason for the low efficiency of the cloning procedure. The mechanisms and factors that affect the progression of the nuclear reprogramming process have not been completely elucidated, but the identification of these factors and their subsequent manipulation would increase cloning efficiency. At present, many groups are studying donor nucleus reprogramming. Here, we present an approach in which the efficiency of producing viable offspring is improved by selecting recipient oocytes and donor cells that will produce cloned embryos with functionally reprogrammed nuclei. This approach will produce information useful in future studies aimed at further deciphering the nuclear reprogramming process.

Corn oil or corn grain supplementation to steers grazing endophyte-free tall fescue. II. Effects on subcutaneous fatty acid content and lipogenic gene expression.

Twenty-eight Angus steers (289 kg) were finished on a high-concentrate diet (85% concentrate: 15% roughage; CONC), or endophyte-free tall fescue pastures with corn grain supplement (0.52% of BW; PC), corn oil plus soybean hull supplement (0.10% of BW corn oil plus 0.45% of BW soybean hulls; PO), or no supplement (pasture only; PA). Subcutaneous adipose tissues were processed for total cellular RNA extraction and fatty acid composition by GLC. Relative expression of genes involved in lipogenesis [fatty acid synthase (FASN), acetyl-CoA carboxylase, lipoprotein lipase, stearoyl-CoA desaturase (SCD)] and activators of transcription [(peroxisome proliferator-activated receptor-gamma), C/EBPalpha, sterol regulatory binding protein-1, signal transducer and activator of transcription-5, and Spot-14] was determined by real-time quantitative PCR. Housekeeping gene (glyceraldehyde 3-phosphate dehydrogenase and beta-actin) expression was used in analysis to normalize expression data. Total fatty acid content was greatest (P < 0.001) for CONC and least (P < 0.001) for PA. Supplementation of grazing cattle increased (P < 0.001) total fatty acid content compared with PA, but concentrations were less (P < 0.001) than for CONC. Myristic and palmitic acid contents were greater (P < 0.001) for CONC than for PO and PC, which were greater (P < 0.001) than for PA. Stearic acid content was greater (P < 0.01) for PO than for CONC, PC, and PA. Finishing on CONC increased (P < 0.001) total MUFA content by 68% compared with PA. Corn grain supplementation increased (P < 0.001) MUFA content compared with PA; in contrast, MUFA content did not differ (P > 0.05) between PO and PA. Corn oil supplementation increased (P < 0.001) trans-11 vaccenic acid content in subcutaneous fat by 1.2-, 1.7- and 5.6-fold relative to PA, PC, and CONC, respectively. Concentrations of the cis-9, trans-11 CLA isomer were 54, 58, and 208% greater (P < 0.01) for PO than for PA, PC, and CONC, respectively. Corn grain supplementation to grazing steers did not alter (P > 0.05) the cis-9, trans-11 CLA isomer compared with PA. Oil supplementation increased (P < 0.001) linoleic acid (C18:2) content by 56, 98 and 262% compared with CONC, PC, and PA, respectively. Relative mRNA expression of SCD was upregulated (P < 0.001) by 46-, 18- and 7-fold, respectively, for CONC, PC, and PO compared with PA. Relative FASN mRNA expression was also upregulated (P = 0.004) by 9- and 5-fold, respectively, for CONC and PC compared with PA. Grain feeding, either on CONC or supplemented on pasture, upregulated FASN and SCD mRNA to increase MUFA and de novo fatty acids in subcutaneous adipose tissue. Upregulation of SCD with grain feeding and reduced tissue CLA concentrations suggest that the decreased CLA concentrations were the result of limited substrate (trans-11 vaccenic acid) availability.

Differential expression of porcine sperm microRNAs and their association with sperm morphology and motility.

MicroRNAs (miRNAs) are involved in nearly every biological process examined to date, but little is known of the identity or function of miRNA in sperm cells or their potential involvement in spermatogenesis. The objective was to identify differences in miRNA expression between normal porcine sperm samples and those exhibiting high percentages of morphological abnormalities or low motility. Quantitative RT-PCR was performed on sperm RNA to compare expression levels of 10 specific miRNAs that are predicted to target genes that code for proteins involved in spermatogenesis, sperm structure, motility, or metabolism. There were increases in the expression of four miRNAs, let-7a, -7d, -7e, and miR-22, in the abnormal group (P < 0.05), whereas miR-15b was decreased compared to controls (P < 0.05). Two miRNAs, let-7d and let-7e, were increased in the low motility group when compared to controls (P < 0.05). Bioinformatic analyses revealed that messenger RNA targets of the differentially expressed miRNAs encode proteins previously described to play roles in sperm function. Although the precise role of miRNA in sperm remains to be determined, their changes as associated with morphology and motility signify a critical biological function. Perhaps they are remnants of spermatogenesis, stored for a later role in fertilization, or are delivered to the oocyte to influence early embryonic development. Although there is no single cause of male infertility, the identification of miRNAs associated with sperm motility, structural integrity, or metabolism could lead to the development of a microarray or real time-based diagnostic assay to provide an assessment of male fertility status.

Detection of porcine sperm microRNAs using a heterologous microRNA microarray and reverse transcriptase polymerase chain reaction

MicroRNAs (miRNAs) are short (20–24 nt), non-coding, single-stranded, ribonucleic acids that play roles in diverse biological processes by altering messenger RNA translation. Commercially available miRNA microarrays have been developed and microarray procedures have been reported for identification of specific miRNA expression in various tissues. While most arrays are generated from human and rodent miRNA sequences, no information is available as to the efficacy of using a commercial miRNA microarray in a cross-species hybridization. Many miRNAs exhibit high conservation among species; however, when using cross-species microarrays, failure to detect 100% of the miRNA due to sequence mismatches at hybridization should be assumed. The objective of our study was to determine the presence and identity of miRNA in porcine sperm cells using a multi-species miRNA microarray with verification by RT-PCR and sequencing. RNA was isolated from porcine sperm cells and used to hybridize to commercially available arrays (LC Sciences, LLC, Houston, TX) constructed from 1,260 known miRNA sequences from 19 different species. Microarray results showed that of the 1,260 known miRNA probes used, 316 produced a detectable signal (intensity 100), suggesting the presence of 293 miRNAs that have not been previously reported in Sus scrofa. Further RT-PCR and gel analysis investigated the presence of 17 specific miRNAs (Table 1) using human miRNA primer sets (mirVana qRT-PCR Primer Set, Ambion, Austin, TX) in sperm cells, cumulus-oophorus complexes (COCs) and eight other porcine tissues collected from gilts at slaughter. Products were sub-cloned and sequenced to verify product identity. The miRs-124a and -9 primers produced faint bands on the gel, but were not detected in the array. It is possible that miRs-124a and -9 are present in porcine sperm in copy numbers too low to be detected by the microarray hybridization, but were exposed by PCR due its unparalleled sensitivity. In contrast, although miR-150 showed moderate expression in the array, it was not present following RT-PCR of RNA from three separate sperm samples each pooled from multiple boars. miR-150 is present in pigs, as it was amplified in our lab in nine other porcine tissue samples and sequenced from kidney. A sequence very similar to miR-150 that is present in porcine sperm may have bound to the miR150 probe in the array, creating a misleading hybridization signal. Dideoxynucleotide sequencing results revealed that 15 of the 17 miRNA products (88.2%) were identical to reported pig or human sequences (Table 1). Sus scrofa miR-212 contained a single base-pair change when compared to the human miR-212 sequence (A–C at the 12th position) and primers for let-7e amplified the highly similar let-7a sequence. It is possible that let-7e does not exist in Sus scrofa and that, because the sequences differ by only one nucleotide, let-7a bound to the let-7e probe of the array creating misleading hybridization signal. These data confirm the presence of miRNA in porcine sperm and that, due to a high degree of sequence conservation among species, a heterologous microarray is effective for miRNA expression profiling; however, all microarray products identified require subsequent analysis for sequence validation.

Utility of Rapidly Matured Oocytes as Recipients for Production of Cloned Embryos from Somatic Cells in the Pig

Abstract The present study was conducted to examine the utility of rapidly matured oocytes as recipients for production of porcine embryos reconstituted with adult skin fibroblasts and whether arrest of meiotic resumption of recipient oocytes at the germinal vesicle (GV) stage by dibutyryl cyclic AMP (dbcAMP) improves in vitro developmental rates after reconstruction. At 24 h of maturation in the medium, 36.3% of oocytes reached the metaphase II (MII) stage. At 30 h of maturation, the percentage (71.4%) of MII oocytes did not significantly differ from that (78.0%) at 42 h of maturation. When MII oocytes recovered at 24 h of maturation were used as recipients, 22/156 (14.1%) cloned embryos developing to the blastocyst stage was significantly (P < 0.05) higher than those of embryos reconstituted with oocytes collected at 30 h (5/168; 3.0%) and 42 h (13/217; 6.0%) of maturation. Culture of oocytes in medium containing 1 mM dbcAMP for 20 h maintained 72.9% in the GV stage, whereas only 15.0% of nontreated oocytes were in the GV stage (P < 0.05). The effect of dbcAMP was reversible. However, the treatment of recipient oocytes with dbcAMP did not affect the development of reconstructed embryos when compared with nontreated oocytes. These results indicate that rapidly matured oocytes are superior in their ability to support development of porcine reconstructed embryos; however, arrest of meiotic resumption of recipient oocytes at the GV stage by dbcAMP does not improve reconstructed embryo developmental rates.

MEAT SCIENCE AND MUSCLE BIOLOGY SYMPOSIUM--anabolic implants and meat quality.

Anabolic implants are routinely used in the finishing phase of beef production to improve animal performance and feed efficiency. Implanting during the feedlot phase on average increases ADG 18%, feed intake 6%, feed efficiency 8%, carcass weight 5%, and ribeye area 4% compared with nonimplanted controls. Implants reduce the cost of beef production, which is important given current high feed costs and beef prices. In a 1996 review of 37 implant trials, the use of a combination (i.e., estrogenic and trenbolone acetate) implant increased returns by US

Cloning and expression of porcine Dicer and the impact of developmental stage and culture conditions on MicroRNA expression in porcine embryos.

77/head compared with nonimplanted steers. If calculated using todays prices, a combination implant would increase returns by

Effects of fescue toxicosis on bull growth, semen characteristics, and breeding soundness evaluation.

163/head. However, concerns about potential negative effects of implants on marbling scores, quality grades, and tenderness exist. Changes in Warner-Bratzler shear force values of steaks from implanted steers are small (<0.5 kg) and appear related to an increase in initial tenderness, possibly due to hypertrophy of muscle fiber, instead of alterations in postmortem proteolysis. The increase in ribeye size observed with implanting may also reduce marbling scores through a dilution effect. The impact of anabolic implants on gene expression has shown that implanting downregulates expression of certain lipogenic genes (e.g., stearoyl-CoA desaturase, fatty acid synthetase, fatty acid elongase-6) in steers with low quality grades (Select-) but not in implanted steers with high quality grades (Choice-). Examination of the adipocytes transcriptome has shown that 36 genes were differentially expressed due to implant treatment. More research is needed to further determine how anabolic implants alter lipogenic gene expression to address changes in marbling deposition with implant usage. Given our current high feed costs and cattle prices, anabolic implants are one of the most cost-effective technologies that can be used in beef production systems.