Preservation of pancreatic tissue morphology, viability and energy metabolism during extended cold storage in two-layer oxygenated University of Wisconsin/perfluorocarbon solution.

BACKGROUND: In contrast to the relative scarcity of donor kidneys and hearts, the potential supply of deceased donor pancreata is exceeding the demand. However, this organ surplus is not being fully realized because, in current transplantation practice, the duration of pancreas storage before transplantation is limited to 8-10 hours due to the extreme vulnerability of pancreatic tissue to anaerobic damage caused by preservation. OBJECTIVES: To reduce cold ischemic injury in order to increase the utilization of donor pancreases in Israel for whole-organ and cell transplantation. METHODS: We evaluated a novel two-layer preservation oxygenated cold storage method that uses perfluorocarbon to continuously supply oxygen to the pancreas during preservation in conventional University of Wisconsin solution. RESULTS: Pancreatic tissue morphology, viability and adenosine-triphosphate content were serially examined during preservation of the pig pancreas for 24 hours either by a two-layer or by conventional simple cold storage. Already after 12 hours of storage, the superiority of the two-layer method over the University of Wisconsin method was apparent. Starting at this time point and continuing throughout the 24 hours of preservation, the tissue architecture, mitochondrial integrity, cellular viability and ATP tissue concentration were improved in samples preserved in oxygenated UW/PFC as compared to controls stored in conventional UW solution alone. CONCLUSIONS: The UW/PFC two-layer preservation method allowed tissue ATP synthesis and amelioration of cold ischemic tissue damage during extended 24 hour pancreas preservation. This method could be implemented in clinical practice to maximize utilization of pancreata for whole-organ and islet transplantation as well as for pancreas sharing with remote centers.

Functional analysis of the mouse myelin/oligodendrocyte glycoprotein gene promoter in the oligodendroglial CG4 cell line.

Myelin/oligodendrocyte glycoprotein (MOG) is a late phylogenetic acquisition among vertebrates that is found only in mammals. MOG is a minor component of myelin protein, representing approximately 0.01-0.05% of the total. Regulatory elements in the MOG gene were identified by transfecting the oligodendroglial CG4 cell line with chimeric MOG-luciferase genes. Only a few hundred base pairs upstream of the coding sequence were necessary for high-level activity of the mouse MOG promoter. More distal recognition sites may exist, because silencing activity, indicative of negative regulatory elements, was detected upstream of base pair 657. Transcriptional activity of chimeric MOG- and myelin basic protein-luciferase genes was greater in CG4 cells than in 3T3 fibroblasts or C6 glioblastoma, demonstrating their superiority for functional analysis of myelin gene regulatory elements.

Myelin/oligodendrocyte glycoprotein (MOG) expression is associated with myelin deposition.

We investigated the onset of expression of the myelin/oligodendrocyte glycoprotein (MOG) mRNA and protein in the developing mouse central nervous system. In situ hybridization on brain sections at different stages of embryonic and postnatal development showed that MOG transcripts were first detected at birth in the medulla oblongata. During the first week after birth, cells expressing MOG mRNA were located in the ventral longitudinal funiculus. During the second postnatal week, the pattern of MOG mRNA expression extended rostrally to the mid-forebrain regions and reached completion by the beginning of the third week. MOG transcription was delayed by several days with respect to myelin basic protein (MBP), and it appeared that while the MBP probe labeled both non-myelinating and myelinating oligodendrocytes, only the latter were MOG-positive. In vitro, immunocytochemical analysis of MOG protein expression, performed on myelinating cultures derived from mouse brain embryos at 15 days of gestation, confirmed the strict restriction of MOG expression to myelinating oligodendrocytes. In particular, oligodendrocytes lining up their processes along axons, but not yet having started to deposit a myelin sheath, were still MOG negative. However, in the same cultures, pseudo-myelinating oligodendrocytes (i.e., cells not associated with neurites, but forming whorls of myelin-like figures) were MOG positive. Similarly, rat CG4 cells, an oligodendrocyte-like cell line, expressed MOG only after they had extended sheet-like processes, which suggested that the activation of MOG transcription depends more on an intrinsic oligodendroglial maturation program of myelination than on a neuronal signal.

The E. coli envY gene encodes a high affinity opioid binding site.

In an attempt to isolate a cDNA encoding an opioid receptor, a cDNA library was constructed in the lambda ZAP vector using NG108-15 mRNA as template. Using an in vitro transcription-translation assay and a sib selection strategy, a single phage was isolated. An RNA transcribed from this cDNA was able to direct in vitro translation of opioid binding sites. The insert was sequenced and comparison with data banks showed a 100% homology with the E. coli envY gene. We assume that the presence of the envY sequence in the NG108-15 cDNA library was due to a contamination of the lambda ZAP vector with E. coli DNA. A search for opioid binding sites on E. coli strains showed that envY+ strains, but not envY- mutants were able to bind opiates. On envY+ cells, the sites are stereospecific, saturable and of high affinity for the opiate ligands. These sites bind opiate agonists and antagonists but neither mu nor delta opioid peptides. In contrast, rabbit reticulocyte lysate primed with RNA transcribed in vitro from the envY sequence elicited the synthesis of an opioid binding site with mixed mu and delta properties. In addition, transfection of the envY sequence into mammalian cells resulted in the expression of opioid binding sites. Depending on the type of cells transfected, these sites were selective for either the mu or delta ligands.