Joanna Wroblewski

Effects of IGF-I, rGH, FGF, EGF and NCS on DNA-synthesis, cell proliferation and morphology of chondrocytes isolated from rat rib growth cartilage

The effects of IGF-I, rGH, FGF, EGF and NCS on DNA-synthesis were analyzed in resting, proliferative and hypertrophic chondrocytes obtained by fractionation. Proliferation and morphology were studied on non-fractionated cells. The highest stimulation of DNA-synthesis was induced by NCS followed by IGF-I at all stages of chondrocyte differentiation. DNA-synthesis was also stimulated by a low concentration of FGF (1 microgram/1) in proliferative and hypertrophic chondrocytes, while FGF in a higher concentration (10 micrograms/1) had no significant mitogenic effect. Cell proliferation was stimulated by both NCS and IGF-I, whereas FGF and EGF only caused morphological changes. Our data indicate that IGF-I is the main serum growth factor regulating growth and proliferation by interacting with chondrocytes at all stages of differentiation.

Quantitative X-ray microanalysis of semi-thick cryosections

SummaryMethodological aspects of quantitative X-ray microanalysis of semi-thick cryosections (2–6 μm) of biological soft tissue were investigated. The preparation of a low background specimen holder is described. Scanning and scanning transmission images of the sections could be obtained, allowing identification and separate analysis of nuclei and cytoplasm. Parallel observations of histochemically stained adjacent sections in the light microscope allowed correlation of the microanalytical data with tissue morphology and histochemistry. Quantitative analysis could be carried out with the help of a standard: a gelatin/glycerol matrix containing mineral salts in known quantities, frozen and sectioned in the same way as the specimen. Mass loss under the electron beam was found to be comparable in specimen and standard. Comparison of various theoretical models for quantitative analysis showed that the ‘P/B-method’ (determination of the background intensity under the characteristic peak) is the most suitable for semi-thick sections. Factors determining the choice of accelerating voltage were analyzed. The usefulness of this specimen type is illustrated in some biological applications (human oral mucosa, rat salivary gland).

Effects of IGF-I, EGF, and FGF on proteoglycans synthesized by fractionated chondrocytes of rat rib growth plate☆

The effects of insulin-like growth factor (IGF-I), epidermal growth factor (EGF), fibroblast growth factor (FGF), or 10% newborn calf serum (NCS) on the amount and structure of the proteoglycans synthesized by fractionated chondrocytes from rat growth plate were investigated. Proliferative cells (fraction II) or resting cells (fraction III) synthesized more proteoglycans than hypertrophic cells (fraction I). Addition of IGF-I to the cultures increased proteoglycan synthesis more than addition of EGF or FGF. EGF and FGF induced synthesis of proteoglycans of smaller molecular size with a lower proportion of aggregates. The size of the constituent glycosaminoglycan chains did not differ between control and growth factor-treated cells. The present study demonstrates that proteoglycan structure and synthesis are modified by growth factors to different extents, depending on the maturation stage of the target cells.

PDGF BB stimulates proliferation and differentiation in cultured chondrocytes from rat rib growth plate

The role of two isoforms (PDGF AA and PDGF BB) of platelet derived growth factor either alone or in combination with insulin-like growth factor I, on the regulation of proliferation and differentiation of rat rib growth plate chondrocytes was analyzed. PDGF BB increased DNA-synthesis in a dose dependent manner with a half maximal effect at 1 ng/ml. When PDGF BB was combined with IGF-I, an additive effect on DNA-synthesis was observed. PDGF AA and BB alone or combined with IGF-I had no appreciable effects on proteoglycan synthesis. Both homodimers caused an increase in AP-activity, indicating stimulation of cell differentiation. Cultured chondrocytes bound 125I-PDGF AA and 125I-PDGF BB and after stimulation with PDGF expressed c-fos protein. Thus, both homodimers play an important role in chondrocyte differentiation and together with IGF-I interact in the regulation of longitudinal bone growth.

Characterization of chondrogenesis in cells isolated from limb buds in mouse.

Micromass cultures of mesenchymal cells isolated from limb buds of 11.5-day-old mouse fetuses were used to study chondrogenesis. After 3 days of culture, dense cell aggregates were observed. They then were converted into macroscopically visible cartilage foci during the following 2–4 days. Comparison of 2-, 4- and 7-day-old cultures has shown that the cells first expressed collagen type I, then switched to collagen type II expression as shown by immunohistochemistry and in situ hybridization. At day 7, proteoglycans were synthesized centrally in the foci. At the same time, most cells expressed collagen type II, with the highest expression in the periphery of the aggregates. The oncogene c-fos and homeodomain protein FS-1 were found in the cells expressing collagen type II, indicating that these transcription factors may be involved in the regulation of cell differentiation. The expression of alkaline phosphatase was detected first in mature cartilage foci (day 4) and increased during culture. Early in culture, DNA-replicating cells were uniformly distributed. With differentiation, the proliferating cells were present predominantly between the aggregates and their total number became significantly reduced. Our results indicate that the process of chondrogenesis in micromass cultures of mesenchymal cells mimics the differentiation process occurring during fetal development in vivo and can be directly studied by in situ hybridization, immunohistochemical and histochemical methods.

Freeze drying and freeze substitution combined with low temperature-embedding

SummaryAn X-ray microanalytical and morphological investigation was carried out on rapidly frozen freeze-dried or freeze-substituted tissues. A comparison was made between different embedding and polymerisation procedures following freeze substitution and freeze drying. The investigation also included an analysis of specimens which had been infiltrated, embedded and polymerised by ultraviolet irradiation at low temperatures with Lowicryl-HM20. The method of freeze drying, followed by embedding and polymerisation at low temperatures in vacuo was found to give satisfactory results, comparable with more tedious and hazardous freeze substitution technique.

Cell fractions from rat rib growth cartilage. Biochemical characterization of matrix molecules.

In an attempt to isolate and characterize the putative target cells for growth hormone, chondrocytes were isolated from rat rib growth cartilage and fractionated by centrifugation in a discontinuous Percoll gradient. This resulted in three cell fractions with differing properties. The fraction with the lowest density consisted mainly of large, lipid-containing cells which became flattened in subsequent culture. The cells in this fraction were fair collagen producers but synthesized only minor amounts of proteoglycans and apparently no proteoglycan aggregates. These cells probably originate in the hypertrophy zone of the growth plate. The fraction with highest density, on the other hand, consisted of small cells which upon cell culture became polygonal and surrounded with refractile matrix. They synthesized less collagen, but more proteoglycans than the low-density fraction. The proportion of proteoglycan aggregates was rather low (10-20%) but otherwise the proteoglycans were similar to those synthesized by other chondrocytes. This cell fraction was tentatively identified as cells from the upper part of the growth plate. Finally, the middle fraction was heterogeneous, consisting of cells of varying shape. This fraction synthesized large amounts of both collagen and proteoglycans. In all three cell fractions, type II collagen predominated. There were also minor amounts of (1a, 2a, 3a) collagen, and, in the two denser fractions, of type I collagen.

Why low temperature embedding for X-ray microanalytical investigations?

Freeze‐drying followed by infiltration with resin and polymerization by UV light at low temperatures and under constant vacuum conditions is an alternative tissue preparation technique for microprobe analysis. Embedding is carried out with the nonpolar low‐temperature embedding resin (Lowicryl HM20) which allows infiltration and polymerization at temperatures down to −50°C. Sections of low temperature embedded material can be cut dry at −60°C or at room temperature. Sectioning at low temperatures is an alternative for preparations that are difficult to cut at room temperature.

Elemental changes associated with chondrocyte differentiation in rat rib growth plate

SummaryQuantitative X-ray microanalysis was under-taken to follow the elemental changes that occur in the process of chondrocyte differentiation. For analysis at the cellular level, semi-thick freeze-dried cryosections of rat rib growth plate cartilage were used. For evaluation of the elemental concentrations at the subcellular level, thin sections of freeze-dried and low temperature vacuum embedded cartilage were analyzed. Levels of Na, P, S, Cl, K, and Ca were determined in the cells and extracellular matrix in different zones of the cartilage — resting, proliferative, and hypertrophic. Proliferative cells had a sodium concentration that was twice that of resting cells, suggesting that Na may play an important role in the regulation of DNA- and protein-synthesis in chondrocytes. A concomitant rise in Na and S concentration occurred between resting zone and proliferative zone cartilage matrix. The high concentrations of Na and K in the matrix are probably due to the high amount of sulfate in proteoglycans which may bind these cations.

Distribution of C-CAM in developing oral tissues.

C-CAM is a cell surface glycoprotein that is involved in cell adhesion and may play a role in histogenesis and organogenesis. It is a member of the carcinoembryonic antigen (CEA) gene family, which is a subfamily of the immunoglobulin gene superfamily. We have analyzed the expression of C-CAM during normal and disturbed craniofacial development in the mouse by immunohistochemistry and in situ hybridization. Developmental disturbances were induced by retinoic acid (RA) treatment of pregnant mice. Normal and malformed fetuses were examined on days 14, 15, 16, 17 and 18 of gestation. The expression of C-CAM was detected first at day 16. With age, the signal became gradually stronger. C-CAM was detected in the epithelia of both ectodermal and mesodermal origin, including oral and respiratory epithelia, epithelia of the developing vessels, glands and their ducts. In the RA-treated fetuses, the expression of C-CAM was higher in the epithelium of the oral cavity than in that of the nasal cavity, with a distinct borderline between differentiating nasal and oral epithelium of the palatal shelves. However, the submucosal nasal glands and ducts showed higher expression than oral glands in both normal and RA-treated mice. The expression of C-CAM did not differ significantly between control and RA-treated animals. The presence of C-CAM in all proliferating craniofacial epithelia indicates that this molecule may play an important role in development.