Xenografts of expanded primate olfactory ensheathing glia support transient behavioral recovery that is independent of serotonergic or corticospinal axonal regeneration in nude rats following spinal cord transection.

Transplantation of olfactory ensheathing glial cells (OEG) may improve the outcome from spinal cord injury. Proof-of-principle studies in primates are desirable and the feasibility and efficacy of using in vitro expanded OEG should be tested. An intermediate step between the validation of rodent studies and human clinical trials is to study expanded primate OEG (POEG) xenografts in immunotolerant rodents. In this study the time course to generate purified POEG was evaluated as well as their survival, effect on damaged axons of the corticospinal and serotonergic systems, tissue sparing, and chronic locomotor recovery following transplantation. Fifty-seven nude rats underwent T9/10 spinal cord transection. Thirty-eight rats received POEG, 19 controls were injected with cell medium, and 10 received lentivirally-GFP-transfected POEG. Histological evaluation was conducted at 6 weeks, 8 weeks, 14 weeks and 23-24 weeks. Of these 57 rats, 18 were studied with 5-HT immunostaining, 16 with BDA anterograde CST labeling, and six were used for transmission electron microscopy. In grafted animals, behavioral recovery, sprouting and limited regeneration of 5-HT fibers, and increased numbers of proximal collateral processes but not regeneration of CST fibers was observed. Grafted animals had less cavitation in the spinal cord stumps than controls. Behavioral recovery peaked at three months and then declined. Five POEG-transplanted animals that had shown behavioral recovery underwent retransection and behavioral scores did not change significantly, suggesting that long tract axonal regeneration did not account for the locomotor improvement. At the ultrastructural level presumptive POEG were found to have direct contacts with astrocytes forming the glia limitans, distinct from those formed by Schwann cells. At 6 weeks GFP expression was detected in cells within the lesion site and within nerve roots but did not match the pattern of Hoechst nuclear labeling. At 3.5 months only GFP-positive debris in macrophages could be detected. Transplanted POEG support behavioral recovery via mechanisms that appear to be independent of long tract regeneration.

Density dependent regulation of human Schwann cell proliferation.

Cessation of division is prerequisite for Schwann cell differentiation but regulation of this critical function is poorly understood. Heregulin/forskolin-induced growth of human Schwann cells (HSCs) in vitro was found to be strongly regulated by cell density and thus could model some aspects of negative growth-regulation in vivo. To better understand this phenomenon, the production of an autocrine growth-inhibitor and the role of contact-inhibition were investigated. The possible involvement of two membrane proteins, contactinhibin (CI) and peripheral myelin protein 22 (PMP22) in regulating growth was studied. Thymidine-labeling of HSCs on collagen-coated dishes was inhibited at cell densities less than one tenth of the density at maximal growth-inhibition. Medium from high density cultures did not inhibit the thymidine-labeling of HSCs at low density, a result that argues against the production of a soluble inhibitor. The expression of CI and PMP22 in nerve and HSCs, and the effect of a function-blocking antibody to CI on HSC growth, were determined. CI was detected in fresh nerve by western blotting, and could easily be detected by immunocytochemistry in cultured HSCs by five days and for several weeks thereafter. Twenty-four hour treatment with anti-CI antibody did not increase the thymidine-labeling of HSCs at any density but a significant increase in HSC number was observed in cultures treated with anti-CI for 20 days. This increase was not related to decreased cell death. PMP22, unlike other myelin proteins, was not down-regulated after nerve dissociation and by seven days nearly all HSCs were PMP22 positive. These results provide evidence for a contact-mediated mechanism of growth-regulation in HSCs and suggest that CI is involved in this mechanism.

Expression of N-acetylglucosaminyltransferase V mRNA in mammalian tissues and cell lines.

The expression of N-acetylglucosaminyltransferase V (Glc-NAc-T V) is increased in many oncogenically transformed cells and in cell lines which are induced to proliferate. In order to characterize the regulation of GlcNAc-T V at the molecular level, we have examined the expression of Glc-NAc-T V mRNAs in a number of mouse tissues and in several human and rodent cell lines. The GlcNAc-T V mRNA is expressed in different amounts in the various mouse tissues, with the greatest amount observed in brain, followed by thymus, kidney, lung, intestine, heart and stomach, and no transcripts detected in liver or skeletal muscle. Measurements of GlcNAc-T V enzymatic activity, by contrast, show brain to have lower levels of activity than several of the other tissues, suggesting possible post-translational regulation. We find that there are two GlcNAc-T V transcripts in most of the RNAs analysed. The rodent cell lines all express both a 7.5 and a 9.5 kb mRNA, with the smaller transcript being more abundant. The human cells have mRNAs of 4.5 and 9.5 kb. Both mRNAs are expressed in HepG2 and MCF-7 cells, while A431 cells express only the 4.5 kb mRNA and HL60 cells express only the 9.5 kb transcript. Furthermore, only the 9.5 kb mRNA appears to be increased, along with activity, when HepG2 cells are stimulated to proliferate, suggesting that the two mRNAs may be under different regulatory controls. Also, a GlcNAc-T V-deficient, mutant lymphoma cell line, PHAR2.1, was found to express mRNAs which are larger than the normal mRNAs, possible due to an insertion or aberrant splicing, resulting in a defective mRNA.

Gene mapping on human metaphase chromosomes by in situ hybridization with 3H, 35S, and 32P labeled probes and transmission electron microscopy.

A method based on in situ hybridization, autoradiography and transmission electron microscopy for mapping genes on human metaphase chromosomes is presented. Successful mapping of the tandemly repeated rDNA genes and of two nucleic acid probes, N-myc and probe 3 (Kanda et al. 1983), that are amplified in a homogeneously staining region (HSR) of the neuroblastoma cell line, IMR-32 is described. By using sufficiently thin AgBr emulsions, it is possible to obtain observable grains and good resolution with probes radiolabeled with 3H, 35S, or 32P, but the former gives the best results. We observe that neither of the two probes, N-myc and probe 3, has a uniform spatial distribution along the HSR and that the distributions of the two probes differ from each other. These observations support previous studies which indicated that the formation of an HSR is a more complex process than uniform amplification of a single DNA segment to form an n-fold set of perfect tandem repeats. The present study shows that the electron microscopic method is useful for extending the results of light microscopic studies for problems where higher resolution mapping is needed.