Christian Schöfer

Recruitment of bone-marrow-derived cells by skeletal and cardiac muscle in adult dystrophic mdx mice.

 It is commonly accepted, that regenerative capacity of striated muscle is confined to skeletal muscle by activation of satellite cells that normally reside quiescent between the plasmalemma and the basement membrane of muscle fibers. Muscular dystrophies are characterized by repetitive cycles of de- and regeneration of skeletal muscle fibers and by the frequent involvement of the cardiac muscle. Since during the longstanding course of muscular dystrophies there is a permanent demand of myogenic progenitors we hypothesized that this may necessitate a recruitment of additional myogenic precursors from an undifferentiated, permanently renewed cell pool, such as bone marrow (BM) cells. To this end normal and dystrophic (mdx) female mice received bone marrow transplantation (BMT) from normal congenic male donor mice. After 70 days, histological sections of skeletal and cardiac muscle from BMT mice were probed for the donor-derived Y chromosomes. In normal BMT recipients, no Y chromosome-containing myonuclei were detected, either in skeletal or in cardiac muscle. However, in all samples from dystrophic mdx skeletal muscles Y chromosome-specific signals were detected within muscle fiber nuclei, which additionally were found to express the myoregulatory proteins myogenin and myf-5. Moreover, in the hearts of BMT-mdx mice single cardiomyocytes with donor derived nuclei were identified, indicating, that even cardiac muscle cells are able to regenerate by recruitment of circulating BM-derived progenitors. Our findings suggest that further characterization and identification of the BM cells capable of undergoing myogenic differentiation may have an outstanding impact on therapeutic strategies for diseases of skeletal and cardiac muscle.

Ribosomal gene transcription is organized in foci within nucleolar components

Abstract We investigated how only three morphologically distinguished nucleolar components can integrate the many necessary tasks in ribosome biogenesis. For the mapping of ribosomal (r)DNA transcription loci, we combined non-autoradiographic in situ transcription assays with the immunological analysis of the ultrastructural distribution of transcription-associated proteins, i.e., polymerase I, the human polymerase I-specific upstream binding factor, and topoisomerase I. Furthermore, we visualized the nascent transcripts simultaneously with the rDNA in the nucleoli. All tested transcription proteins were found in both the fibrillar center and the dense fibrillar component (DF) of nucleoli in human cells. In the DF the nascent transcripts, detected by bromouridine incorporation, were found colocalized with the transcription proteins only within circumscribed regions. We did not observe colocalization of rDNA with nascent transcripts within the fibrillar centers, which corroborates the view that transcription proteins in this component are rather inactive. Our results suggests that only a minor portion of the DF is involved in transcriptional activity. Transcription appears to be confined to small foci, which exist close to or associated with the DF. Our results are in favor of the view that the DF has different functions which are localized in subcompartments of the DF.

Signal amplification at the ultrastructural level using biotinylated tyramides and immunogold detection

Abstract The tyramide amplification technique has recently been developed for signal enhancement in enzyme-linked immunosorbent assays and western blots. This method relies on using labelled tyramides as substrates for peroxidase, resulting in an immobilization of the labelled tyramide residues (tyramide reaction). We succeeded in establishing reliable protocols for the use of the tyramide reaction at the electron microscopic (EM) level. As model systems we chose the visualization of DNA in late spermatocytes, of actin in skeletal muscle, and the visualization of an rDNA probe after DNA-DNA in situ hybridization. We observed a significant increase in signal density after performing the tyramide reaction at the EM level. The tyramide amplification technique at the ultrastructural level therefore appears to be a useful tool to detect even a few epitopes present at the surface of a section as shown after in situ hybridization. It offers advantages over other amplification systems, such as the peroxidase-mediated deposition of diaminobenzidine, because of an increased spatial resolution, whereas specificity and sensitivity are comparable to the conventional immunogold detection method.

In situ flat embedding of monolayers and cell relocation in the acrylic resin LR White for comparative light and electron microscopy studies

SummaryA simple and reliable method has been developed for thein situ LR White embedding of cell monolayers grown on glass cover-slips. Combined with cytochemical or immunological procedures, this technique allows light and/or electron microscopy investigations of a large number of cells in the same horizontal plane within a relatively short period of time. It can be applied to cells grown on microgrid finder cover-slips which allows a distinct site of even an individual cell of a monolayer to be studied at first at the light microscope level and subsequently at the electron microscope level. Hence, it is also suitable for controlling manipulation of single cells, followed by their serial sectioning after relocation in the electron microscope.

Arrangement of individual human ribosomal DNA fragments on stretched DNA fibers

Abstract We studied the arrangement of individual human ribosomal (r)DNA repeats by direct visualization of rDNA sequences. We used high resolution fluorescence in situ hybridization on preparations of DNA fibers released from interphase nuclei of HeLa cells. Probes from both the transcription unit and the intergenic spacer were used, and lengths of signals and of the gaps in between were measured and compared to molecular data. We could visualize the repetitive arrangement of individual rDNA sequences at the single gene level. No inversions or deletions were detected. The intergenic spacer was found to be shorter than expected, indicating a length polymorphism.

Ribosomal genes and nucleolar morphology

Nucleoli were noted by biologists very early (Fontana, 1781) and a lot of data has been accumulated on the structure of nucleoli in the last decades. Due to the work of Perry (1962; Perry et al., 1961) it is known that the nucleolus is the site of ribosome biogenesis. Its visibility both in the light-and the electron microscope is due to the fact that the genes for ribosomal RNA are not only transcribed but also processed and complexed with ribosomal proteins in nucleoli, rendering them morphologically different from the rest of the karyoplasm.

Cytochemistry of satellite nucleoli in human lymphocytes

Satellite nucleoli of lymphocytes were studied to provide additional information on the cytochemistry of these nucleoli particularly with respect to the presence of rDNA and RNA polymerase I. According to the results of the in situ hybridization satellite nucleoli contain rDNA similarly as characteristic nucleoli. Immunostaining demonstrated that satellite nucleoli similarly as characteristic nucleoli possess RNA polymerase I in addition to proteins B23, C23 and fibrillarin. RNA of satellite nucleoli was detected in satellite as well as in characteristic nucleoli with buffered toluidine or methylene blue. The cytochemical evidence and morphology of satellite nucleoli strongly supports the supposition that these nucleoli represent solitary small nucleoli containing nucleolus organizer regions which did not participate in the formation of characteristic nucleoli.

The apical ectodermal ridge, fibroblast growth factors (FGF-2 and FGF-4) and insulin-like growth factor I (IGF-I) control the migration of epidermal melanoblasts in chicken wing buds.

The role of the apical ectodermal ridge and of fibroblast growth factors FGF-2 and FGF-4 and of the insulin-like growth factor I (IGF-I) in the control of the migration of epidermal melanoblasts was investigated using quail–chicken chimeras. Wing buds of a strain of unpigmented chicken were microsurgically modified in several ways (ablation, displacement or implantation of additional apical ectodermal ridges, implantation of grafts devoid of apical ectodermal ridges, ectopic application of growth factors) and received grafts containing quail neural crest cells. The distribution of the epidermal melanoblasts which had differentiated from the quail grafts revealed that both the apical ectodermal ridge and the growth factors invariably caused the migration of epidermal melanoblasts towards them. This leads to the conclusion that the presence of the apical ectodermal ridge is the sufficient condition to direct the migration of epidermal melanoblasts within the avian embryonic wing bud. Furthermore, FGF-2 and IGF-I and to a lesser extent FGF-4 play a decisive role in directing the migration of epidermal melanoblasts within chicken wing buds and are likely to be involved in the molecular cascade by means of which the apical ectodermal ridge controls the migration of epidermal melanoblasts.