Organotypic culture of adult rabbit retina

Organotypic culture systems of functional neural tissues are important tools in neurobiological research. Ideally, such a system should be compatible with imaging techniques, genetic manipulation, and electrophysiological recording. Here we present a simple interphase tissue culture system for adult rabbit retina that requires no specialized equipment and very little maintenance. We demonstrate the dissection and incubation of rabbit retina and particle-mediated gene transfer of plasmids encoding GFP or a variety of subcellular markers into retinal ganglion cells. Rabbit retinas cultured this way can be kept alive for up to 6 days with very little changes of the overall anatomical structure or the morphology of individual ganglion- and amacrine cells.     

Stability of the transformants obtained by phage particle-mediated gene transfer

Recombinant lambda phage DNA, encapsulated in phage particles and coprecipitated with calcium phosphate, efficiently transforms cultured mammalian cells without a requirement for carrier DNA. The present paper analyzes the stability of the transformants obtained by the phage transfer method. lambda phage particles containing recombinant DNA that includes the thymidine kinase (TK) gene of herpes simplex virus type 1 as a selective marker were introduced into Ltk- cells deficient in TK activity, and TK+ transformants were selected in HAT medium. To test the stability of the TK+ phenotype of the transformants, seven individual transformant clones were isolated, cultured in HAT selective medium and then in non-selective medium for various lengths of time. After such culture, transformants were allowed to develop colonies in both selective and non-selective medium. For all seven transformant clones, the numbers of colonies obtained in the two types of medium were almost identical, irrespective of whether or not each transformant clone had been previously cultured for 15 to 50 days in non-selective medium. This result suggests that most transformants obtained by the phage transfer method maintain the TK+ phenotype stably, for at least 50 days, when grown in non-selective medium.     

Organotypic culture of neural retina as a research model of neurodegeneration of ganglion cells

Organotypic models deserve special attention among the large variety of methods of vertebrate retina cultivation. The purpose of this study was to make a detailed qualitative and quantitative characterization of a model employing roller organotypic cultivation of the neural retina of rat eye posterior segment, with special attention to morphological and functional characteristics of retinal ganglion cells. The study included morphological analysis of retina histological preparations as well as estimation of RNA synthesis and evaluation of neuron survival by the Brachet and TUNEL methods, respectively. Retina has been shown to display normal morphofunctional characteristics for the first 12 h of cultivation. After 24 h, a substantial number of ganglion cells underwent pyknosis and stopped RNA synthesis. Almost all the cells of the retinal ganglion layer became apoptotic by 3–4 days in vitro. In the course of cultivation, neural retina is detached from the underlying layers of the posterior eye segment and undergoes significant cytoarchitectonic changes. The causes of ganglion cell death during organotypic cultivation of eye posterior segment are discussed. This method can serve as a suitable model for the screening of new retinoprotectors and for research on ganglion cell death resulting from retina degenerative diseases, e.g. glaucoma.     

Development of auxotrophic agrobacterium tumefaciens for gene transfer in plant tissue culture

Auxotrophic strains of Agrobacterium tumefaciens were generated for use in liquid co-culture with plant tissue for transient gene expression. Twenty-one auxotrophs were recovered from 1,900 tetracycline-resistant insertional mutants generated with a suicide vector transposon mutagenesis system. Twelve of these auxotrophs were characterized on a nutrient matrix. Isolates were screened for growth in plant cell and root culture, and three auxotrophs were identified that had limited growth: adenine (ade-24), leucine (leu-27), and cysteine (cys-32). Ade-24 displayed poor T-DNA delivery in a transient expression test delivering GUS from a binary vector, while cys-32 displayed the best ability to deliver DNA of these three auxotrophs. The growth yield of cys-32 on cysteine was assessed to provide a quantitative basis for co-culture nutrient supplementation. The utility of cys-32 for delivering T-DNA to plant tissues is demonstrated, where an 85-fold enhancement in GUS expression over wild-type A. tumefaciens was achieved.     

Rapid propagation of agave by in vitro tissue culture

A procedure for rapid propagation of Agave (A. cantala Roxb., A. fourcroydes Lem. and A. sisalana Perrine, (Agavaceae) have been developed. The explants were excised from stolon plantlets, sterilized and cultivated on Murashige and Skoog (MS) basal medium containing 2% sucrose, 10% coconut water and 0.8% agar. The addition of following combination of growth substances—0.075 mgl^-1 naphthalenacetic acid (NAA)+0.1 mgl^-1 indolylbutyric acid (IBA)+0.5 mgl^-1 kinetin (KIN) caused an extensive proliferation of multiple shoot primordia. Subcultures of these on the same medium were successful for the multiplication with an index of 3–4 times per 4 weeks subculture period. Shoots were rooted on hormone free MS medium and then transferred into a sand bed for acclimation before field planting.     

Advances in tissue culture of adult larch

Summary This paper reviews some of the recent research on micropropagation of mature larch (Larix) trees. Different methods are reported concerning the use of the organogenic and embryogenic potential of adult plant material. Successful plant regeneration of adult larch trees by combining tissue culture methods is presented. The growth behavior of regenerated plants was compared with seedlings. Special attention was focused on preconditioning of donor material. Possible basic principles, responsible for a successful propagation of adult donor trees, are discussed. Based on a presentation at the IUFRO Meeting (Somatic Cell Genetics, and Molecular Genetics of Trees) held in Quebec City, PQ, Canada, August 12–16, 1997.     

Neuromuscular transmission in cultures of adult human and rodent skeletal muscle after innervation in vitro by fetal rodent spinal cord

Electrophysiologic analyses have been carried out on in vitro-coupled explants of fetal rodent spinal cord and adult skeletal muscle of human as well as rodent origin. The studies demonstrate that characteristic neuromuscular transmission can develop and be maintained in these unusual tissue combinations during long-term culture. After coupling periods of 2–7 weeks in vitro, selective stimulation of spinal cord evokes widespread coordinated contractions in the muscle tissue. Simultaneous microelectrode recordings of cord and muscle responses to local cord, or ventral root, stimuli show that muscle action potentials (and contractions) generally occur with latencies of several msec after onset of cord discharges. Similar temporal relations are often seen during spontaneous rhythmic discharges of the coupled cord and muscle tissues. Long series of repetitive discharges, at 2–5 sec intervals, may occur synchronously between these cord and muscle explants, in response to single cord (or dorsal-root ganglion) stimuli, and they may also appear spontaneously. d-Tubocurarine (1–10 μg/ml) selectively and reversibly blocks neuromuscular transmission in these cultures. Eserine accelerates recovery of normal function. Spontaneous repetitive fibrillations of many of the cultured muscle fibers are observed sporadically, and these contractions often continue unabated after block of neuromusclar transmission by d-tubocurarine. Many of the fibers which show asynchronous fibrillations are probably not innervated (as in denervated muscle in situ). In some cases, however, extracellular as well as intracellular recordings indicate that similar fibrillations may also occur in fibers which are clearly innervated. Repetitive cord and muscle discharges are greatly augmented after introduction of strychnine. Complex rhythmic oscillatory (ca. 10/sec) afterdischarges generated in strychninized cord explants lead to similarly patterned muscle discharges (and contractions), which may also occur, at, times, in normal medium.     

Estrogen-controlled gene expression in tissue culture cells by zearalenone

In two estrogen-sensitive cell lines, Le42 and MCF-7, the estrogenic potential of the nonsteroidal mycotoxin zearalenone has been investigated. The chloramphenicol acetyltransferase (CAT) gene expression in Le42 cells is induced by zearalenone after transfection with a CAT-gene construct controlled by an estrogen responsive element [(1986) Cell 46, 1053-1061]. In MCF-7 cells zearalenone induces at least 2 exoproteins (52 and 160 kDa) which are estrogen-specific [(1980) Cell 20, 353-362). These data suggest that zearalenone acts by activating the estrogen receptor. Due to the high sensitivity of these cell lines for zearalenone both test systems are proposed as assays for a quantitative estimation of the biological (estrogenic) activity of this widespread mycotoxin.     

A primary culture technique of adult retina for regeneration studies on adult CNS neurons

This protocol details a tissue culture technique that allows for quantified regeneration studies on adult retinal ganglion cells (RGCs), that is, CNS neurons. The method may also allow for elucidation of molecular cues, for example of signals relevant in neuronal survival and axon regeneration. The procedure relies on fractioned stripe culture of previously injured retina in defined culture media. Naive dendritic cell contacts of RGCs are preserved, and the system is independent of growth factors. In contrast to other techniques, the protocol is based on tissue grown from adult animals; it dispenses immature co-cultures and evaluates the outgrowth of unmyelinated neurites in a milieu lacking CNS myelin. The technique is suitable for rodent retina from mouse or rat. A growth-conditioning injury of the optic nerve is set 10 days before retinal explantation. Explants are cultured for 5-7 days. Mere preparation of a single retina should be completed within 20 min.     

Somatic gene targeting in the developing and adult mouse retina

Retinogenesis is a developmental process that is tightly regulated both temporally and spatially and is therefore an excellent model system for studying the molecular and cellular mechanisms of neurogenesis in the central nervous system. Understanding of these events in vivo is greatly facilitated by the availability of mouse mutant models, including those with natural or targeted mutations and those with conditional knockout or forced expression of genes. This article reviews these genetic modifications and their contribution to the study of retinogenesis in mammals, with special emphasis on conditional gene targeting approaches.     

Conditions affecting direct gene transfer into rodent muscle in vivo.

This report extends our previous findings that mouse muscle cells in situ can take up naked DNA injected intramuscularly in vivo. Various conditions such as needle type, speed of injection, volume of injection fluid, tonicity of injection fluid, type of solute, type of muscle, physiologic condition of the muscle and age of the animals were appraised for their effect on the levels of luciferase activity expressed from the pRSVL plasmid. Specific conditions such as the use of normal saline as an injection fluid increased the efficiency of expression. The implantation of DNA pellets was an effective way to deliver DNA to muscle, especially for smaller muscle groups. Also, newborn and adult rat muscles expressed plasmid DNA delivered intramuscularly.     

Calmodulin gene expression in the neural retina of the adult rat

Calmodulin (CaM) mRNAs are expressed with low abundancy in the adult rat neural retina. However, when digoxigenin (DIG)-labeled cRNA probes specific for each CaM mRNA population were hybridized at slightly alkaline pH (pH 8.0), the widespread distribution of CaM mRNA-expressing cells was revealed, with similar abundance for all three CaM genes. The CaM genes displayed a uniquely similar, layer-specific expression throughout the retina, and no significant differences were found in the distribution patterns of the CaM mRNA populations or the labeled cell types. The strongest signal for all CaM mRNAs was demonstrated in the ganglion cell layer and the inner nuclear layer, where the highest signal intensity was found within the inner sublamina. Similarly intermediate signal intensities for all CaM genes were detected in the inner and outer plexiform layers, within the vicinity of the outer limiting membrane and in the retinal pigment epithelium. A very low specific signal was characteristic in the outer nuclear layer and the photoreceptor inner segment layer, while no specific hybridization signal was observed in the photoreceptor outer segment layer. In summary, all CaM genes exhibited a similar and a characteristically layer-specific expression pattern in the adult rat retina.