Adult and Embryonic Stem Cell Sources for Use in a Canine Model of In Utero Transplantation

Vaags, Andrea Kathleen

05 March 2012

Dogs are useful preclinical models for the translation of cell transplantation therapies from the bench to the bedside. In order for canine models to be utilized for stem cell transplantation research, it is necessary to advance discoveries in the fields of canine stem cell biology and transplantation. The use of side population hematopoietic stem cells (HSCs) has garnered much interest for the purification of mouse HSCs and has been translated to several other species, including human. In order to assess if this method of purification of HSCs could be useful for stem cell therapies in humans, safety and efficacy studies in a large animal model, such as the dog would be required. With this objective in mind, we isolated canine bone marrow-derived side population (SP) stem cells and assessed their multilineage differentiation in vitro and engraftment potential in vivo. Utilizing a pregating strategy to enrich for small, agranular SP cells we were able to enrich for blast cells, expressing the ABCG2 transmembrane pump known to be associated with murine and human SP cells. Canine SP cells were also enriched for C-KIT positive cells and lacked expression of CD34 as identified in other species. The small, agranular SP fraction had high CFU potential after long-term culture with canine bone marrow stromal cells and cytokine supplementation. Yet, canine SP cells demonstrated low-level engraftment within the NOD/SCID-β2m-/- xenotransplantation model as compared to unfractionated canine bone marrow, which was indicative of suboptimal activation of quiescent canine SP cells within the murine bone marrow niche. A second source of transplantable canine stem cells was examined through the derivation of canine embryonic stem cells (cESCs). The cESC lines described herein were determined to have similar pluripotent stem cell characteristics to human embryonic stem cells, in that they were maintained in an undifferentiated state upon extended passaging as determined by their expression of the human stem cell markers, OCT3/4, NANOG, SOX2, SSEA3, SSEA4, TRA1-60, TRA1-81 and alkaline phosphatase. In addition, cESCs could be induced to differentiate to cells of the three germ layers within in vitro embryoid body cultures and adherent differentiation cultures. Importantly, these cESC lines were the first reported to differentiate in vivo within teratomas. One method of transplanting stem cells to canine recipients involves the delivery of donor cells to the yolk sacs of developing fetuses in utero. Utilizing cells labeled with supraparamagnetic particles conjugated to a Dragon Green fluorophore and the intracellular fluorescent dye, CMTMR, donor cells were tracked from the yolk sac injection site to fetal tissues after transplantation in early (day-25) and mid (day-35) gestation canine fetuses. Labeled cells were localized primarily to the fetal liver and developing bone marrow cavities when examined at gestational day 32, and had been redistributed to not only the fetal liver and bone marrow by day 42, but also to nonhematopoietic tissues, including the lungs and hearts. No labeled cells were detected within the yolk sacs of transplanted fetuses at either time point. These studies demonstrated the efficacy of yolk sac in utero transplantation for the delivery of donor cells to fetal tissues. Collectively, these results indicate that canine stem cells with characteristics similar to human can be isolated and their engraftment, proliferation and differentiation may be assessed in future studies utilizing the canine in utero transplantation model employing yolk sac delivery.

stem cells

canine

hematopoiesis

mesenchymal stromal cell

embryonic stem cell

dog

side population stem cell

in utero transplantation

cell therapy

supraparamagnetic iron oxide

yolk sac

hematopoietic stem cell

0379

0778

TECNICHE AVANZATE NELLA MESSA A PUNTO DI TECNOLOGIE TRANSGENICHE E NON NELLA SPECIE MURINA

TONDELLI, BARBARA

04 February 2009

L’osteopetrosi autosomale recessiva (ARO) è un gruppo di malattie dovute a un difettoso funzionamento degli osteoclasti che preclude un rimodellamento osseo corretto. Nel 50% dei casi umani il difetto è dovuto ad una delezione nel gene Tcirg1. Il modello murino mutante oc/oc porta lo stesso difetto genetico e fenotipico umano. Nel lavoro di tesi si è dimostrato che gli epatociti fetali di 12.5 giorni di gestazione trapiantati in utero in feti mutati di 13.5 giorni di gestazione sono in grado di curare il fenotipo malato. Si è inoltre derivata una sottolinea di cellule staminali embrionali murine transgeniche per il costrutto plasmidico GOF18eGFP. Si vuole utilizzare la GFP sotto il controllo del promotore del gene Oct-4 come marcatore del livello di staminalità cellulare per microiniettare le ESC in blastocisti murine mutate oc/oc. / Autosomal recessive osteopetrosis (ARO) is a group of genetic disorders due to defects that preclude normal function of osteoclasts. In half the cases, human ARO is due to mutations in the Tcirg1 gene. The oc/oc mutant mouse closely recapitulates human Tcirg1-dependent ARO. In ths work we demonstrate that in utero injection of allogenic fetal liver cells on 12.5 days into oc/oc fetuses at 13.5 day post coitum completely rescue the osteopetrotic phenotype. Moreover, an embryonic stem cells line transgenic for GOF18eGFP was produced. The goal is to use the GFP under the transcriptional control of the Oct-4 promoter as a marker of pluripotency of the ESC that are to microinject into oc/oc blastocysts.

AGR/16: MICROBIOLOGIA AGRARIA

Adult and Embryonic Stem Cell Sources for Use in a Canine Model of In Utero Transplantation

Vaags, Andrea Kathleen

05 March 2012

Dogs are useful preclinical models for the translation of cell transplantation therapies from the bench to the bedside. In order for canine models to be utilized for stem cell transplantation research, it is necessary to advance discoveries in the fields of canine stem cell biology and transplantation. The use of side population hematopoietic stem cells (HSCs) has garnered much interest for the purification of mouse HSCs and has been translated to several other species, including human. In order to assess if this method of purification of HSCs could be useful for stem cell therapies in humans, safety and efficacy studies in a large animal model, such as the dog would be required. With this objective in mind, we isolated canine bone marrow-derived side population (SP) stem cells and assessed their multilineage differentiation in vitro and engraftment potential in vivo. Utilizing a pregating strategy to enrich for small, agranular SP cells we were able to enrich for blast cells, expressing the ABCG2 transmembrane pump known to be associated with murine and human SP cells. Canine SP cells were also enriched for C-KIT positive cells and lacked expression of CD34 as identified in other species. The small, agranular SP fraction had high CFU potential after long-term culture with canine bone marrow stromal cells and cytokine supplementation. Yet, canine SP cells demonstrated low-level engraftment within the NOD/SCID-β2m-/- xenotransplantation model as compared to unfractionated canine bone marrow, which was indicative of suboptimal activation of quiescent canine SP cells within the murine bone marrow niche. A second source of transplantable canine stem cells was examined through the derivation of canine embryonic stem cells (cESCs). The cESC lines described herein were determined to have similar pluripotent stem cell characteristics to human embryonic stem cells, in that they were maintained in an undifferentiated state upon extended passaging as determined by their expression of the human stem cell markers, OCT3/4, NANOG, SOX2, SSEA3, SSEA4, TRA1-60, TRA1-81 and alkaline phosphatase. In addition, cESCs could be induced to differentiate to cells of the three germ layers within in vitro embryoid body cultures and adherent differentiation cultures. Importantly, these cESC lines were the first reported to differentiate in vivo within teratomas. One method of transplanting stem cells to canine recipients involves the delivery of donor cells to the yolk sacs of developing fetuses in utero. Utilizing cells labeled with supraparamagnetic particles conjugated to a Dragon Green fluorophore and the intracellular fluorescent dye, CMTMR, donor cells were tracked from the yolk sac injection site to fetal tissues after transplantation in early (day-25) and mid (day-35) gestation canine fetuses. Labeled cells were localized primarily to the fetal liver and developing bone marrow cavities when examined at gestational day 32, and had been redistributed to not only the fetal liver and bone marrow by day 42, but also to nonhematopoietic tissues, including the lungs and hearts. No labeled cells were detected within the yolk sacs of transplanted fetuses at either time point. These studies demonstrated the efficacy of yolk sac in utero transplantation for the delivery of donor cells to fetal tissues. Collectively, these results indicate that canine stem cells with characteristics similar to human can be isolated and their engraftment, proliferation and differentiation may be assessed in future studies utilizing the canine in utero transplantation model employing yolk sac delivery.

stem cells

canine

hematopoiesis

mesenchymal stromal cell

embryonic stem cell

dog

side population stem cell

in utero transplantation

cell therapy

supraparamagnetic iron oxide

yolk sac

hematopoietic stem cell

0379

0778