Potential of iPSC-Derived Mesenchymal Stromal Cells for Treating Periodontal Disease.

Mesenchymal stromal cell-like populations have been derived from mouse-induced pluripotent stem cells (miPSC-MSC) with the capability for tissue regeneration. In this study, murine iPSC underwent differentiation towards an MSC-like immunophenotype. Stable miPSC-MSC cultures expressed the MSC-associated markers, CD73, CD105, and Sca-1, but lacked expression of the pluripotency marker, SSEA1, and hematopoietic markers, CD34 and CD45. Functionally, miPSC-MSC exhibited the potential for trilineage differentiation into osteoblasts, adipocytes, and chondrocytes and the capacity to suppress the proliferation of mitogen-activated splenocytes. The efficacy of miPSC-MSC was assessed in an acute inflammation model following systemic or local delivery into mice with subcutaneous implants containing heat-inactivated P. gingivalis. Histological analysis revealed less inflammatory cellular infiltrate within the sponges in mice treated with miPSC-MSC cells delivered locally rather than systemically. Assessment of proinflammatory cytokines in mouse spleens found that CXCL1 transcripts and protein were reduced in mice treated with miPSC-MSC. In a periodontitis model, mice subjected to oral inoculation with P. gingivalis revealed less bone tissue destruction and inflammation within the jaws when treated with miPSC-MSC compared to PBS alone. Our results demonstrated that miPSC-MSC derived from iPSC have the capacity to control acute and chronic inflammatory responses associated with the destruction of periodontal tissue. Therefore, miPSC-MSC present a promising novel source of stromal cells which could be used in the treatment of periodontal disease and other inflammatory systemic diseases such as rheumatoid arthritis.

Activation of in vivo- and in vitro-derived porcine oocytes by using multiple electrical pulses.

The current protocols used to activate pig nuclear transfer embryos are less efficient than those used for other species. To address this problem, the effect of multiple sets of electrical pulses on the parthenogenetic development of in vivo- and in vitro-derived porcine oocytes was examined. Each set of pulses consisted of two 1.5 kV cm(-1) DC pulses of 60 micros duration each, administered 1 s apart. For in vivo-derived oocytes, application of a second set of pulses 30 min after the first set increased the proportion of oocytes that developed to the blastocyst stage compared with a single treatment (51 v. 34%). Application of a third set of pulses 30 min after the second set reduced the rate of blastocyst formation compared with two sets of pulses. In contrast, the rate of blastocyst formation was greater with one set of pulses compared with two sets for in vitro matured oocytes (31 v. 16%). Additional sets of electrical pulses did not affect the number of cells in blastocysts obtained from either group of oocytes compared with a single treatment. In summary, the study demonstrates that the application of a second set of activating pulses 30 min after the first set is beneficial to in vivo-derived oocytes, but detrimental to in vitro matured oocytes, in terms of their ability to develop parthenogenetically to the blastocyst stage.

In vitro assessment of the viability of sheep zygotes after pronuclear microinjection.

Microinjected sheep zygotes were cultured in synthetic oviduct fluid medium (SOFM) for either 1 or 3 days and their subsequent developmental capacity was compared with that of microinjected zygotes cultured in vivo. Two experiments were carried out, using zygotes microinjected with one of three gene constructs containing the CysE and CysM genes from Salmonella typhimurium. In Experiment 1, microinjected zygotes were allocated to one of three treatments: (1) immediate transfer to recipient ewes (in vivo culture) followed by recollection 1 or 3 days later and subsequent transfer of viable embryos to other recipient ewes, (2) culture in SOFM (in vitro culture) for either 1 or 3 days before transfer to recipient ewes, and (3) immediate transfer to recipient ewes without subsequent interference. Recipient ewes were slaughtered on Day 14 of pregnancy and the number of elongated conceptuses determined. Although fewer zygotes failed to divide during in vitro culture than during in vivo culture, there were, overall, no significant differences between treatments in the percentage of zygotes that developed into elongated conceptuses (32.6-50.0%). In Experiment 2, microinjected zygotes were transferred immediately to recipient ewes or cultured in vitro for either 1 or 3 days before transfer. The number of fetuses per ewe on Day 50 of pregnancy and the number of lambs delivered per ewe were recorded. Neither the percentage of recipient ewes that became pregnant (overall 114/166, 68.7%) nor the percentage of zygotes that developed into lambs (overall 186/803, 23.2%) was significantly influenced by the culture treatment or by the gene construct microinjected.(ABSTRACT TRUNCATED AT 250 WORDS)

Inducing pluripotency in somatic cells from the snow leopard (Panthera uncia), an endangered felid.

Induced pluripotency is a new approach to produce embryonic stem-like cells from somatic cells that provides a unique means to understand both pluripotency and lineage assignment. To investigate whether this technology could be applied to endangered species, where the limited availability of gametes makes production and research on embryonic stem cells difficult, we attempted generation of induced pluripotent stem (iPS) cells from snow leopard (Panthera uncia) fibroblasts by retroviral transfection with Moloney-based retroviral vectors (pMXs) encoding four factors (OCT4, SOX2, KLF4 and cMYC). This resulted in the formation of small colonies of cells, which could not be maintained beyond four passages (P4). However, addition of NANOG, to the transfection cocktail produced stable iPS cell colonies, which formed as early as D3. Colonies of cells were selected at D5 and expanded in vitro. The resulting cell line was positive for alkaline phosphatase (AP), OCT4, NANOG, and Stage-Specific embryonic Antigen-4 (SSEA-4) at P14. RT-PCR also confirmed that endogenous OCT4 and NANOG were expressed by snow leopard iPS cells from P4. All five human transgenes were transcribed at P4, but OCT4, SOX2 and NANOG transgenes were silenced as early as P14; therefore, reprogramming of the endogenous pluripotent genes had occurred. When injected into immune-deficient mice, snow leopard iPS cells formed teratomas containing tissues representative of the three germ layers. In conclusion, this was apparently the first derivation of iPS cells from the endangered snow leopard and the first report on induced pluripotency in felid species. Addition of NANOG to the reprogramming cocktail was essential for derivation of iPS lines in this felid. The iPS cells provided a unique source of pluripotent cells with utility in conservation through cryopreservation of genetics, as a source of reprogrammed donor cells for nuclear transfer or for directed differentiation to gametes in the future.

A novel, efficient method to derive bovine and mouse embryonic stem cells with in vivo differentiation potential by treatment with 5-azacytidine.

Pluripotent embryonic stem cells (ESCs) were first isolated nearly three decades ago from mice, yet efficient ESC isolation has been limited to rodents and primates to date. We report a novel and robust technique for isolating ESCs from mammalian pre-implantation embryos by altering the epigenotype of embryonic explants and using pressed zona pellucida-free blastocysts. We first examined this technique for murine ESC derivation. Compared with controls, murine ESCs were efficiently derived when explants were exposed to 1 µM 5-azacytidine, an epigenetic modifier that causes DNA demethylation (56.1% vs 31.6%; P < 0.01). Mouse ESCs stained positively for alkaline phosphatase, expressed markers of pluripotency including Oct4, Rex1 and SSEA1 and formed teratomas when injected into Severe Combined Immuno-Deficient (SCID) mice. The approach was subsequently used for bovine ESC derivation. In bovine a higher concentration of 5-azacytidine (5 µM) was required to elicit a response. This technique resulted in up to 18 times more efficient isolation of pluripotent cells than traditional methods (71.4% vs 4.0%; P < 0.001). These putative bovine ESCs expressed OCT4, REX1 mRNA and SSEA-1 and SSEA-4 proteins; and were able to form embryoid bodies in vitro and teratomas when injected in Severe Combined Immuno Deficient (SCID) mice. This is the first report on derivation of ESCs with both in vitro and in vivo differentiation potential in a livestock species.

NANOG is a key factor for induction of pluripotency in bovine adult fibroblasts.

Since the first reports on isolation of pluripotent mouse embryonic stem (ES) cells 3 decades ago, there have been numerous attempts to derive ES cell lines from commercially important livestock species with limited success. The recent discovery that ectopic expression of a handful of stem cell-related genes was capable of inducing pluripotency in rodents and primates provided a novel approach to derivation of pluripotent stem cell lines. We used this approach in cattle and demonstrated that the ectopic expression of POU5F1 (also known as Oct4), SOX2, KLF4, and c-MYC alone was not sufficient for stable induction of pluripotency in bovine adult fibroblasts and that the additional expression of NANOG to the reprogramming cocktail was essential for the generation of stable bovine (b) induced pluripotent stem (iPS) cells. The resulting biPS cells were characterized by reverse-transcription PCR for a panel of ES marker genes. Immunocytochemical localization of POU5F1, SSEA-1, SSEA-4, and colorimetric alkaline phosphatase activity was measured in the iPS clones. The differentiation potential of the biPS cells was determined in vitro by expression of differentiation markers in embryoid bodies. Injection of biPS into immunocompromised mice resulted in teratomas containing cell types of the 3 germ lineages. This study reports the first generation of bovine induced pluripotent cell lines and paves the way for the use of biPS cells for biotechnological and agricultural purposes.

The use of signalling pathway inhibitors and chromatin modifiers for enhancing pluripotency.

Pluripotent embryonic stem cells have been isolated from a limited number of species. The new advances with inducing pluripotency in somatic cells have resulted in the generation of pluripotent stem cells while circumventing the need for embryos. In this review we describe the main signalling pathways involved in maintaining pluripotency and inducing differentiation. Inhibition of the signalling pathways involved in differentiation enhances the derivation and cultivation of pluripotent stem cells. Furthermore, we discuss the use of chromatin modifiers to maintain an open chromatin state which is characteristic of pluripotent stem cells, to facilitate the derivation of pluripotent cell lines.

Hatching rate: an optimal discriminator for the assessment of single-blastomere biopsy.

PURPOSE: In order to determine an optimal marker to discriminate embryo injury following single-blastomere embryo biopsy, mouse embryos were examined for rates of blastocyst formation, hatching, implantation, and fetal development following single-blastomere biopsy. RESULTS: Early studies of single-blastomere biopsy (1-8 series) resulted in similar rates of blastocyst formation (P > 0.05) but a lower rate of hatching of biopsied (n = 140) versus control (nonbiopsied) (n = 145) embryos (78.6 vs 95.2%; p < 0.01). Subsequent experience (9-13 series) eliminated this difference between biopsied (n = 145) and control embryos (n = 133) (95.9 vs 94.0%; P > 0.05). Embryo transfer of hatching blastocysts of biopsied (n = 100) and nonbiopsied control (n = 100) groups resulted in equivalent rate of fetal development (70.0 vs 68.0%; p > 0.05). CONCLUSIONS: The hatching rate appeared to be a simple, sensitive, and reliable method to evaluate the single-blastomere biopsy technique.

Expression of bacterial cysteine biosynthesis genes in transgenic mice and sheep: toward a new in vivo amino acid biosynthesis pathway and improved wool growth.

It is possible to improve wool growth through increasing the supply of cysteine available for protein synthesis and cell division in the wool follicle. As mammals can only synthesise cysteine indirectly from methionine via trans-sulphuration, expression of transgenes encoding microbial cysteine biosynthesis enzymes could provide a more efficient pathway to cysteine synthesis in the sheep. If expressed in the rumen epithelium, the abundant sulphide, produced by ruminal microorganisms and normally excreted, could be captured for conversion to cysteine. This paper describes the characterisation of expression of the cysteine biosynthesis genes of Salmonella typhimurium, cysE, cysM and cysK, and linked cysEM, cysME and cysKE genes as transgenes in mice and sheep. The linked transgenes were constructed with each gene driven by a separate promoter, either with the Rous sarcoma virus long terminal repeat (RSVLTR) promoter or the mouse phosphoglycerate kinase-1 (mPgk-1) promoter, and with human growth hormone (hGH) polyadenylation sequences. Transgenesis of mice with the RSVLTR-cysE gene afforded tissue-specific, heritable expression of the gene. Despite high levels of expression in a number of tissues, extremely low levels of expression occurred in the stomach and small intestine. Results of a concurrent sheep transgenesis experiment using the RSVLTR-cysEM and -cysME linked transgenes revealed that the RSVLTR promoter was inadequate for expression in the rumen. Moreover, instability of transgenes containing the RSVLTR sequence was observed. Expression of mPgk-cysME and -cysKE linked transgenes in most tissues of the mice examined, including the stomach and small intestine, suggested this promoter to be a better candidate for expression of these transgenes in the analogous tissues of sheep. However, a subsequent sheep transgenesis experiment indicated that use of the mPgk-1 promoter, active ubiquitously and early in development, may be inappropriate for expression of the cysteine biosynthesis transgenes. In summary, these results indicate that enzymically active bacterial cysteine biosynthesis gene products can be coexpressed in mammalian cells in vivo but that expression of the genes should be spatio-temporally restricted to the adult sheep rumen epithelium.

In vitro development of porcine nuclear transfer embryos constructed using fetal fibroblasts.

The in vitro development of porcine nuclear transfer embryos constructed using primary cultures from day 25 fetal fibroblasts which were either rapidly dividing (cycling) or had their cell-cycle synchronized in G0/G1 using serum starvation (serum-starved) was examined. Oocyte-karyoplast complexes were fused and activated simultaneously and then cultured in vitro for seven days to assess development. Fusion rates were not different for either cell population. The proportion of reconstructed embryos that cleaved was higher in the cycling group compared to the serum-starved group (79 vs. 56% respectively; P < 0.05). Development to the 4-cell stage was not different using either population. Both treatments supported similar rates of development to the morula (1.5 vs. 7%, cycling vs. serum-starved) and blastocyst stage (1.5 vs. 3%, cycling vs. serum-starved). The blastocyst produced using cycling cells had a total cell number of 10. Total cell numbers for the three blastocysts produced serum-starved cells were 22, 24, and 33. These blastocysts had inner cell mass numbers of 0, 15, and 4, respectively. Six hundred and thirty-five nuclear transfer embryos reconstructed using serum-starved cells were transferred to 15 temporarily mated recipients for 3-4 days. Of these, 486 were recovered (77% recovery rate) of which 106 (22%) had developed to the 4-cell stage or later. These were transferred to a total of 15 recipients which were either unmated or mated. Seven recipients farrowed a total of 51 piglets. Microsatellite analysis revealed that none of these were derived from the nuclear transfer embryos transferred.

Developments in transgenic techniques in pigs.

Manipulation of the pig genome is currently restricted to the random insertion of new DNA using pronuclear microinjection. This method suffers from a number of inherent limitations, the majority of which result from the inability to control the site at which the transgene becomes integrated. These drawbacks, together with the need to be able to target existing genes, will result in the replacement of pronuclear injection by new methods that have the capability to direct insertion to a particular genomic site that does not influence expression. Currently, it is possible to control the site of insertion in mice using embryonic stem (ES) cell and homologous recombination technologies. However, pluripotent ES cells have yet to be isolated in pigs. The possibility of using nuclear transfer to reprogramme early differentiated embryonic cells as well as somatic cells from adult animals may provide an alternative method for generating precise genetic modifications. Methods that allow these changes to be carried out in situ are also likely to be developed in the future.

Effect of DNA concentration on transgenesis rates in mice and pigs.

A retrospective analysis of transgenesis rates obtained in seven pronuclear microinjection programs was undertaken to determine if a relationship existed between the amount of DNA injected and transgenesis rates in the pig. Logistic regression analysis showed that as the concentration of DNA injected increased from 1 to 10 ng/microl, the number of transgenics when expressed as a proportion of the number liveborn (integration rate) increased from 4% to an average of 26%. A similar relationship was found when the number of molecules of DNA injected per picolitre was analysed. No evidence was obtained to suggest either parameter influenced integration rate in mice when the same constructs were injected. The number of transgenics liveborn when expressed as a proportion of ova injected (efficiency rate), increased as DNA concentration increased up to 7.5 ng/microl and then decreased at 10 ng/microl for both species suggesting that at this concentration DNA (or possible contaminants) may have influenced embryo survival. The relationship between efficiency and the number of molecules injected per picolitre was complex suggesting that the concentration at which DNA was injected was a better determinant of integration and efficiency rates. In conclusion, the present study suggests that transgenes need to be injected at concentrations of between 5 and 10 ng/microl to maximise integration and efficiency rates in pigs.