M. del Cerro

Retinal ganglion cell survival is promoted by genetically modified astrocytes designed to secrete brain-derived neurotrophic factor (BDNF).

Genetically engineered cells carrying genes for neurotrophic factors have potential application for treatment of neurodegenerative diseases and injuries to the nervous system. Brain-derived neurotrophic factor (BDNF) promotes the survival of specific neurons, including retinal ganglion cells (RGC). To determine whether genetically engineered astrocytes might be used for delivering bioactive BDNF, we infected primary type 1 rat astrocytes with a retrovirus harboring a human prepro-BDNF cDNA and assayed the medium conditioned by these astrocytes for effects on survival of rat RGCs in vitro. High levels of BDNF mRNA were expressed by infected astrocytes, but not by control astrocytes as determined by RNase protection assay using a BDNF specific probe. To test for secretion of bioactive BDNF from the transgenic astrocytes, embryonic day 17 rat retinas were dissociated and grown in medium conditioned (CM) for 24 h by astrocytes infected with a replication deficient retrovirus carrying BDNF, NGF, or alkaline phosphatase (AP) cDNA. After 3 days, the number of Thy-1 immunoreactive RGCs was counted. BDNF astrocyte CM significantly enhanced RGC survival by 15-fold compared to the AP control. NGF astrocyte CM had no significant effect. The rate of BDNF secretion was estimated at 83-166 pg/10(5) cells/h. This study demonstrates that astrocytes can be genetically engineered to synthesize and secrete bioactive BDNF. These techniques may be applicable to rescuing neurons from degenerative processes and also for enhancing their survival following transplantation.

Intraretinal xenografts of differentiated human retinoblastoma cells integrate with the host retina

We report on the successful use of chemically modified Y79 human retinoblastoma cells for intraretinal xenografting into damaged adult mammalian eyes. Y79 cells were exposed in vitro to retinoic acid/butyrate to induce differentiation. Using a multisite transplantation method, the suspension was injected into the subretinal space of Fischer 344 rats. The survival, integration, and differentiation potential of these cells was studied, following their return to the intraocular milieu from which the progenitor cells originated. The grafted cells survived and differentiated into immature photoreceptor elements in the subretinal and intraretinal locations, as multiple clusters of rosette-forming cells intimately attached to the host neuroretina. The differentiation process included development of synaptic connectivity of the ribbon type with the surrounding neuropil. No signs of renewed cell division were found within grafts performed on 42 rat eyes, and there was no indication of cell-mediated host reaction against the transplants. This study indicates that tumorigenicity can be suppressed in mitotically arrested Y79 cells, and that these cells are capable of undergoing differentiation in vivo. This provides evidence of the remarkable differentiation properties of human retinoblastomas while indicating that Y79 cells may ultimately be able to substitute for fetal cells in experimental retinal transplantation.

Evolution of the extracellular space in immature nervous tissue

En el cerebelo de rata recién nacida existen espacios extracelulares mayores que 1000 Å los cuales progresivamente se reducen hasta que en la tercera semana, como en el adulto, las celulas y fibras se hallan separadas por endiduras de 150–200 Å. Estas observaciones indican que el reducido espacio usualmente hallado en el adulto no es un artificio tecnico como ha sido sugerido por algunos autores.

Retinal transplants into the anterior chamber of the rat eye

Developing retinas from 13-18-day fetuses and 2-day neonatal Long-Evans rats transplanted into the anterior chamber of adult eyes of the same or different strain (Lewis) survive and differentiate. Light and electron microscopic studies show that the transplants undergo histogenetic differentiation, resulting in the development of neurons and Müller glial cells and formation of nuclear and plexiform layers. Vascular connections develop between the host iris and the retinal transplant. Vessels and nerves, presumably of iridal origin, were seen on the surface of some transplants. Possible manifestations of graft rejection were monitored; signs of tissue rejection in transplants performed in the Long-Evans rats, an outbred strain, were rare and if present they were mild, at least during the survival periods of up to 91 days allowed in these experiments. Transplants into the eyes of Lewis rats were also well tolerated during the survival period. These observations indicate that retinal transplantation to the adult eye of a genetically different host can be successfully achieved and that both embryonic and perinatal retinas are suitable as donor tissue for ocular transplants. The procedure offers ample opportunities for the study of problems related to retinal plasticity.

Unequivocal demonstration of the hematogenous origin of brain macrophages in a stab wound by a double-label technique

Abstract We studied the origin of the phagocytic cells observed in the Neurol parenchyma in response to injury. Suckling albino rats were given repeated intraperitoneal injections of india ink to label circulating macrophages. Following this treatment, a discrete track lesion was produced in the cerebellar vermis by inserting into it a hypodermic needle which would deliver a minute amount of a second tracer, iron dextran. Electron-microscopic observation showed that 2 days later phagocytes within the lesion contained both iron dextran and carbon particles in their cytoplasm, indicating their hematogenous origin and the persistence of phagocytic activity.

Colloidal carbon as a multilevel marker for experimental lesions

The use of colloidal carbon for the anatomical marking of experimental lesions is proposed. Visualization of the lesion site may be readily performed through this procedure at the macroscopic, light microscopic, and ultrastructural levels in the same specimen. The chemical inertness of the marker and its relative permanency greatly add to its usefulness.

Cilia in axolotl neurons (Siredon mexicanum)

Un estudio electro-microscópico de la médula espinal del axalote reveló la existencia de neuronas ciliadas, tanto en medulas normales como en segmentos medulares implantados por tiempos variables en la aleta dorsal de animales de la misma especie. La cilia que es única e implantada cerca de una dendrita se extiende en la neuropila por una longitud de varios μm.

Cyclosporine Treatment Promotes Survival of Human Fetal Neural Retina Transplanted to the Subretinal Space of the Light-damaged Fischer 344 Rat.

We have reported that xenografts of human fetal neural retina survive in the subretinal space of cyclosporine-immunosuppressed rats. In view of the current controversy regarding the role of cyclosporine, we wished to determine if cyclosporine immunosuppression was an absolute requirement for retinal xenograft survival. Neural retinas from human fetal eyes obtained within 1 h of termination of pregnancy were stored in Optisol medium (Chiron Vision, Irvine, CA) at 4 degrees C for 2 and 7 days. Retinas were then transplanted to the subretinal space of either cyclosporine-treated (10 mg/kg/day) light-damaged Fischer 344 rat eyes (17 animals, 28 eyes) or to the subretinal space of light-damaged Fischer 344 rat eyes (9 animals, 15 eyes) receiving no cyclosporine treatment. Grafted eyes were observed clinically at 10, 20, and 30 days posttransplantation. At 30 days, the animals were sacrificed and the grafts observed histologically. Human fetal retina xenografted to the subretinal space of immunosuppressed rats survived (9/17 animals, 12/28 eyes), showed good integration with the host retina and initial photoreceptor differentiation. Tissue xenografted to the subretinal space of non-cyclosporine-treated rats was not observed to survive (0/9 animals, 0/15 eyes). A low level cellular reaction was seen around three of the injection sites within the nonimmunosuppressed rats. We conclude that immunosuppression is necessary for the survival of human fetal neural retina xenografted to the subretinal space.

Cytomegalovirus Infection of Human Retinal Tissue: An In Vivo Model

BACKGROUND Cytomegalovirus (CMV) retinitis is a common, devastating complication of AIDS. Strict host specificity of human CMV (HCMV), has limited the study of the virus. The purpose of this research was to create a model that allowed the in vivo infection of human retinal tissue with HCMV. EXPERIMENTAL DESIGN Small fragments of 13-week human fetal retina were transplanted into the anterior chambers of immune-deficient mice. One week later, 15 of 30 grafts were inoculated with HCMV. Infected and noninfected specimens were compared for histopathologic changes at 14, 30, and 60 days at light and electron microscopic levels. Histochemistry was performed to characterize: level of graft differentiation, range of viral replication cycle, and effects on neuronal, glial, and monocytic elements of the retina. RESULTS At 30 and 60 days, grafts were well differentiated histologically and histochemically. The infected grafts showed numerous large cells containing intranuclear and intracytoplasmic inclusions. Ultrastructural examination revealed viral particles within cytoplasm and nuclei. Infected cells expressed proteins representative of all phases of the HCMV replication cycle. Most HCMV-infected cells expressed the neuronal marker, protein gene product 9.5. In a second series of experiments, tissue from one graft harvested at 45 days postinfection was used to recover HCMV in fibroblast cultures and also used successfully to passage the virus to two control grafts. CONCLUSIONS This model allows HCMV to actively infect and replicate within highly differentiated human neural tissue. It produces pathology characteristic of CMV-infected neural tissue in a time course suitable for long-term study. The nature of this model will allow the study of: the replication properties of HCMV in nervous tissue, the specific effects of HCMV on the human retina, the interaction of HCMV with other viruses, e.g., HIV, and various anti-viral therapies.