Genetically engineered human mesenchymal stem cells produce met-enkephalin at augmented higher levels in vitro

We have reported that transplantation of adrenal medullary chromaffin cells that release endogenous opioid peptides into pain modulatory regions in the CNS produce significant antinociceptive effects in patients with terminal cancer pain. However, the usefulness of this procedure is minimal because the availability of human adrenal tissue is very limited. Alternative xenogeneic materials, such as porcine and bovine adrenal chromaffin cells present problems of immune rejection and possible pathogenic contamination. In an attempt to develop opioid peptide-producing cells of autologous origin, we have transfected human mesenchymal stem cells (hMeSCs) with a mammalian expression vector containing a fusion gene of green fluorescent protein (GFP) and human preprocrikephalin (hPPE), a precursor protein for enkephalin opioid peptides. Enkephalins are major neurotransmitters that play an important role in analgesia by activating peripheral opioid receptors. Following the establishment of stable transfection of hMeSCs, the expressions of hPPE and GFP were confirmed and the production of methionine enkephalin (Met-enkephalin) was significantly increased compared to control naive hMeSCs (p \u3c 0.05). Our in vitro data demonstrated that genetically engineered hMeSCs with transfected hPPE gene can constitutively produce opioid peptide Met-enkephalin at an augmented high level. hMeSCs are relatively easy to isolate from a patient\u27s bone marrow aspirates and expand in culture by repeated passages. Autologous hMeSCs would not require immunosuppression when transplanted back into the same patient. Through targeted gene manipulation such as hPPE gene transfection, this may offer a virtually unlimited safe cell supply for the treatment of opioid-sensitive pain in humans

High Glucose Increases Metallothionein Expression in Renal Proximal Tubular Epithelial Cells

Metallothionein (MT) is an intracellular metal-binding, cysteine-rich protein, and is a potent antioxidant that protects cells and tissues from oxidative stress. Although the major isoforms MT-1 and -2 (MT-1/-2) are highly inducible in many tissues, the distribution and role of MT-1/-2 in diabetic nephropathy are poorly understood. In this study, diabetes was induced in adult male rats by streptozotocin, and renal tissues were stained with antibodies for MT-1/-2. MT-1/-2 expression was also evaluated in mProx24 cells, a mouse renal proximal tubular epithelial cell line, stimulated with high glucose medium and pretreated with the antioxidant vitamin E. MT-1/-2 expression was gradually and dramatically increased, mainly in the proximal tubular epithelial cells and to a lesser extent in the podocytes in diabetic rats, but was hardly observed in control rats. MT-1/-2 expression was also increased by high glucose stimulation in mProx24 cells. Because the induction of MT was suppressed by pretreatment with vitamin E, the expression of MT-1/-2 is induced, at least in part, by high glucose-induced oxidative stress. These observations suggest that MT-1/-2 is induced in renal proximal tubular epithelial cells as an antioxidant to protect the kidney from oxidative stress, and may offer a novel therapeutic target against diabetic nephropathy

Reelin Expression Is Upregulated Following Ocular Tissue Injury

Purpose: Reelin is important in the guidance of neuronal stem cells in the central nervous system during normal development. We wished to determine whether reelin is expressed in the retina and cornea after injury. Methods: Mice underwent laceration of their retina as well as corneal epithelial debridement. The mice were sacrificed at 3 days, and eyes were fixed and stained for reelin expression and reelin messenger ribonucleic acid (mRNA). Results: In normal eyes, reelin was expressed only at very low levels in the ganglion cell layer of the retina and the endothelial cell layer of the cornea. In injured eyes, there was marked expression in reelin immunoreactivity in the retina and cornea. Reelin gene expression was seen in the retina and cornea. Conclusions: Reelin is expressed during normal retinogenesis. This study shows that reelin is also upregulated following injury to the retina and cornea. The expression of reelin following injury suggests that reelin may play an important role in regulating stem cell trafficking in neuronal and nonneuronal tissues following injury similar to its role in normal organogenesis. © Springer-Verlag 2006

Bromodeoxyuridine Increases Multipotency Of Human Bone Marrow-Derived Stem Cells

Purpose: Recent reports show that marrow derived mesenchymal stem cells (MeSCs) may have the ability to differentiate into diverse cell types unrelated to their phenotypical embryonic origin, including neural cells. While demonstrated in vitro and neonatally, efforts to demonstrate this ability in adult animal brains have had limited success. If it can be shown that human MeSC (HMeSC) can differentiate into neural cells in adult brain, it would open up the possibility that HMeSCs may be of potential therapeutic use in cell replacement therapies for neurological diseases. Here, we demonstrate that adult HMeSCs treated with 5-bromo-2-deoxyuridine (BrdU) for 3 weeks develop the capability to differentiate into neural and retinal cells when provided the appropriate lineage specific differentiation signals in vitro and in adult animals. HMeSC without BrdU treatment did not differentiate into neurons in vitro or adult animal or retinal cells in adult animal. Methods: MeSCs isolated from adult human bone marrow were treated with BrdU (3 μM) for 3 weeks and then subjected to differentiation conditions both in vitro and in vivo. Results: BrdU pretreated HMeSCs express neuronal and glial markers after co-culture with differentiated human neural stem cells and after transplantation into the adult rat brain. HMeSCs pretreated with BrdU and transforming growth factor-β3 express a photoreceptor marker after transplantation into the adult rat vitreous. Conclusions: These results suggest that BrdU treatment may increase the multipotency of HMeSCs for possible use in autologous cell therapies for neurological and opthamological diseases. 2004 - IOS Press and the authors. All rights reserved