Andrée Rothermel

Of layers and spheres: the reaggregate approach in tissue engineering

The reaggregate approach involves the regeneration of histotypical three-dimensional spheres from dispersed cells of a given tissue in suspension culture. Reaggregated spheres are used as tumour, genetic, toxicological, biohybrid and neurosphere models, and often replace animal experimentation. A particularly instructive example is the use of reaggregation to regenerate complete laminar tissue from avian embryonic retina. By revealing constraints of layered tissue formation, such retinal spheres could be instrumental for regenerative medicine, including stem cell-based tissue engineering.

Pigmented epithelium induces complete retinal reconstitution from dispersed embryonic chick retinae in reaggregation culture.

Reaggregation of dispersed retinal cells of the chick embryo leads to histotypic retinospheroids in which the laminar organization remains incomplete: photoreceptors form rosettes which are surrounded by constituents of the other retinal layers. Here, for the first time, a complete arrangement of layers is achieved in cellular spheres (stratoids), provided that fully dispersed retinal cells are younger than embryonic day E6, and are reaggregated in the presence of a monolayer of retinal pigmented epithelium (RPE). A remarkable mechanism of stratoid formation from 1 to 15 days in vitro is revealed by the establishment of a radial Müller glia scaffold and of photoreceptors. During the first two days of reaggregation on RPE, rosettes are still observed. At this stage immunostaining with vimentin and F11 antibodies for radial Müller glia reveal a disorganized pattern. Subsequently, radial glia processes organize into long parallel fibre bundles which are arranged like spokes to stabilize the surface and centre of the stratoid. The opsin–specific antibody CERN 901 detects photoreceptors as they gradually build up an outer nuclear layer at the surface. These findings assign to the RPE a decisive role for the genesis and regeneration of a vertebrate retina.

Microcavity array (MCA)-based biosensor chip for functional drug screening of 3D tissue models.

Multicellular tumour spheroids that mimic a native cellular environment are widely used as model systems for drug testing. To study drug effects on three-dimensional cultures in real-time we designed and fabricated a novel type of sensor chip for fast, non-destructive impedance spectroscopy and extracellular recording. Precultured spheroids are trapped between four gold electrodes. Fifteen individual 100microm deep square microcavities with sizes from 200 to 400microm allow an optimised positioning during the measurement. Although apoptosis was induced in human melanoma spheroids by Camptothecin (CTT), treated cultures did not show disintegration but displayed increased impedance magnitudes compared to controls after 8h resulting from an altered morphology of the outer cells. Contractions in cardiomyocyte spheroids were monitored when the innovative chip was used for recording of extracellular potentials. The silicon-based electrode array is used as an acute test system for the monitoring of any kind of 3D cell cultures. Since no adherence of cells or labelling is necessary the multifunctional sensor chip provides a basis for improved drug development by high content screenings with reduced costs and assay times. Additional improvements for parallel testing of different substances on one chip are presented.

From stem cells towards neural layers: a lesson from re-aggregated embryonic retinal cells

Cells from dissociated embryonic avian retinae have the capacity to re-aggregate in rotation culture and form cellular spheres reconstituting a complete arrangement of all retinal layers. This exquisite phenomenon is based upon in vitro proliferation of multipotent precursor stem cells and spatial organization of their differentiating descendants. The addition of soluble factors from cultured retinal pigmented epithelial (RPE) or radial glial cells is essential to revert inside-out spheres (rosetted retinal spheres) into correctly laminated outside-out spheres (stratified spheres). Such complete restoration of a laminated brain tissue by cell re-aggregation has been achieved only for the embryonic avian retina, but not the mammalian retina, nor for other brain parts. This review summarises the history of the re-aggregation approach, presents avian retinal re-aggregate models, and analyses roles of the RPE and Müller cells for successful retinal tissue regeneration. It is predicted that these results will become biomedically relevant, as stem cell biology will soon open ways to produce large amounts of human retinal precursors.

Müller glia cells reorganize reaggregating chicken retinal cells into correctly laminated in vitro retinae.

Müller cells, that belong to the family of radial glia cells, have central functions during retinogenesis. They form a stabilizing scaffold, they are candidate targets for the mediation of extraneous retinogenetic factors, and they are an important source for retina‐borne retinogenetic factors. Reaggregate cultures allow the analysis of retinogenesis from dispersed cells to fully laminated tissues. Reaggregating cells from the embryonic chick retina reassemble to reversed laminated cellular spheres including constituents of all retinal layers, yet the outer nuclear layer is represented by internal rosettes. Using spheroids, we tested whether Müller cells have a decisive function in establishing retinal polarity and in determining the lamination pattern. To this end, we established confluent monolayers of highly enriched Müller cells derived from E6 or E13 chicken retinas, and then let dispersed E5.5 retinal cells reaggregate either in the absence of these monolayers or on top of them. In the presence of Müller cells, the reversed lamina polarity of rosetted spheroids progressively transformed within a week into correctly laminated retinal spheres, whereas all initial rosettes vanished. Moreover, photoreceptors formed a regular outer nuclear layer, as visualized by the rod‐specific CERN901 antibody. In correctly laminated spheroids, staining for vimentin and glutamine synthetase was much more pronounced than in rosetted spheroids; in particular, a well‐established inner limiting membrane stood out wherever the retinal lamination was complete. Because these effects can be similarly achieved by supernatants derived from Müller cells, direct cell‐cell contacts or cellular replenishment from the monolayer do not account for these effects. We conclude that Müller cells are involved in the establishment of a correct retinal lamination and in the arrangement of the cells in the reaggregate cultures. In particular, rosette formation is counteracted and the formation of an inner limiting membrane is induced. Because rosettes are objects of concern in several ophthalmological defects, these results are highly relevant, both biomedically and also for normal retinogenesis. GLIA 29:45–57, 2000.

An impedimetric microelectrode-based array sensor for label-free detection of tau hyperphosphorylation in human cells.

Tauopathies such as Alzheimers disease (AD) belong to the group of neurodegenerative diseases that are characterised by hyperphosphorylation of the protein tau. Hyperphosphorylation of tau is one of the salient events leading to neuronal cytotoxicity and cognitive impairments. In this context, inhibition of tau hyperphosphorylation by specific tau kinase inhibitors can provide an excellent drug target for the treatment of AD and other tau-related neurodegenerative diseases. To improve the identification, optimisation and validation during the high-cost hit-to-lead cycle of AD drugs, we established a fast and sensitive label-free technique for testing the efficacy of tau kinase inhibitors in vitro. Here, we report for the first time that microelectrode-based impedance spectroscopy can be used to detect the pathological risk potential of hyperphosphorylated tau in the human neuroblastoma cell line SH-SY5Y. Our findings provide a novel real-time recording technique for testing the efficiency of tau kinase inhibitors or other lead structures directed to tau hyperphosphorylation on differentiated SH-SY5Y cells.

Photoreceptor plasticity in reaggregates of embryonic chick retina: rods depend on proximal cones and on tissue organization.

Plasticity of photoreceptors and their integration into epithelial structures homologous to an outer nuclear layer (ONL), was investigated in embryonic chick retinal cell reaggregates by immunohistochemistry using an antibody specific for red plus green cones (RG‐cones) and an antibody for rods. If reaggregates are raised in the presence of pigmented epithelium (RPE), completely reconstructed, stratified retinal spheres are produced, where all rods and cones are integrated into an outer laminar ONL, similar to a normal retina. In the absence of RPE, ‘rosetted’ spheres form which contain internal rosettes homologous to an ONL. Only a minor fraction of cones and rods of ‘rosetted’ spheres are located within rosettes, while a larger fraction is diffusely displaced in nonorganized areas, thus, not contributing to an ONL‐like epithelium. In both types of spheres, the total percentage of RG‐cones was similar to the in vivo retina, indicating that expression of cones is autonomous. Following cones, after about one day, rods developed only within already existing RG‐cone clusters. Thereby, the ratio of rods to RG‐cones increases as the tissue organization decreases: for stratified spheres this ratio is, 0.50 (1 rod/2 cones; similar to mature retina); for rosettes, 0.74 (3 rods/4 cones) and for nonorganized areas, 1.09 (1 rod/1 cone) – a higher ratio under our conditions has never been detected. Thus, rod expression depends strictly on the presence of nearby cones; their relative numbers are distinctively adjusted according to the cytoarchitecture of the tissue environment. The biomedical implications of these findings are briefly discussed.

Pigmented Epithelium Sustains Cell Proliferation and Decreases Expression of Opsins and Acetylcholinesterase in Reaggregated Chicken Retinospheroids

We investigated the effect of the retinal pigmented epithelium on cell proliferation and differentiation in rosetted retinospheroids, which are retina‐like spheres reaggregated in the complete absence of retinal pigmented epithelium from dissociated retinal cells of 6‐day‐old chick embryos in a rotation culture system. In spheroids raised in the absence of retinal pigmented epithelium (controls), acetylcholinesterase was expressed in cells of an inner nuclear‐like layer and their neuropil matrices. Moreover, the ratio between rods and cones was found to be approximately normal throughout the spheroid. When spheroids were cultured in the presence of retinal pigmented epithelium monolayers, cell proliferation in spheroids as determined by BrdU labelling was significantly increased and extended for 1 week, while acetylcholinesterase protein levels and specific activities in homogenates were decreased to ∼30%. At the same time, opsin immunoreactivity was completely suppressed within the spheroid and appeared slowly in cells around its periphery; i.e. the proportion of rhodopsin‐positive cells decreased from 14 to 3%. This study reveals that the retinal pigmented epithelium in vifro sustains cell proliferation but inhibits the differentiation of acetylcholinesterase‐positive cells and of photoreceptors.

Microelectrode chip based real time monitoring of vital MCF-7 mamma carcinoma cells by impedance spectroscopy

Sensorchip based impedance spectroscopy can detect inhibitory effects of human neuropeptide Y (hNPY) on living cells in a non-invasive labelling free way in real time without the need of supporting reagents. Since the discovery that neoplasmatic transformations in breast cancer are correlated with a change of the receptor subtype expression of hNPY in the affected tissue, the hNPY receptor-ligand system has come to the fore of cancer research. Today there are different methods detecting hNPY receptor interactions like fluorescent and radioactive labelling or detecting hNPY-pathway activation like cyclic adenosine monophosphate (cAMP) and G protein-coupled receptor (GPCR)-assays. For all these assays it is necessary to either label related proteins with additional substances, which can affect the nature state of the cell, or the need of producing cell lysate which allows only a snapshot of the investigated cells. To overcome these problems we established a new method to detect hNPY-receptor interactions. Therefore, we monitor the complex electric resistance (impedance) of cells attached to a microelectrode over a wide frequency range. Cell alterations are detected as changes in the impedance spectra. After application of the adenylyl cyclase-stimulating reagent forskolin, impedance is decreased at 5 kHz frequency within minutes. This effect can be inhibited by preincubating the cells with hNPY for a time range of 20 min. The inhibitory effect of hNPY can be washed out and the same cells can be stimulated by forskolin again.

Cells on a Chip - the Use of Electric Properties for Highly Sensitive Monitoring of Blood-Derived Factors Involved in Angiotensin II Type 1 Receptor Signalling

Background: We developed a highly sensitive cardiomyocyte based screening system for the non-destructive electronic detection of chronotropic drugs and tissue-secreted factors involved in AT1 receptor-mediated cardiovascular diseases. Methods: For this purpose we cultured spontaneously beating neonatal rat cardiomyocytes on microelectrode arrays (MEAs), and tested the optimised, stable culture parameters for a reproducible real-time recording of alterations in contraction frequency. After the evaluation of culture parameters, computer-based electronic measurement systems were used for counting of contractions by recording of the field potential of cardiomyocytes. Results: Using the biosensor, angiotensin II, the predominant ligand of the AT1 receptor, was detected at very low concentrations of 10-11 M via altered contractions of cardiomyocytes. Moreover, we demonstrated that cardiomyocyte coupled microarrays allow the detection of blood-derived low concentrated anti-AT1 receptor autoimmune antibodies of pregnant women suffering from preeclampsia. Conclusion: This study demonstrates the first well-suited electrophysiological recording of cardiomyocytes on multielectrode arrays as a benefit for functional biomonitoring for the detection of AT1 receptor/ligand interactions and other marker proteins in sera directed to cardiovascular diseases.