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Intermediate filaments—Chemical heterogeneity in differentiation

Focal adhesions (FAs) are highly dynamic multi-protein complexes, through which cells interact with the extracellular matrix (ECM) via integrin receptors. These large assemblies, which typically measure several micrometers in diameter, mediate interactions of cells with external surfaces, and are linked at their cytoplasmic faces with F-actin bundles. Over the last four decades, the molecular diversity of these adhesions and their roles in cell migration and matrix sensing have been extensively studied. Microscopy-based research is considered critical for characterizing and understanding the nature of these assemblies. Here, we review the contributions of, advanced microscopy to the characterization of the functional architecture of integrin-mediated, cell–matrix adhesions.

“Knowledge of structure is critical to an understanding of function” (Dorothy Hodgkin)

We propose a modification of the conventional keratinocyte isolation method which has shown a significant improvement in the purity, colony forming efficiency (c.f.e.) and growth capacity of the isolated epidermal cell population. This method utilized thermolysin since it selectively digests the dermo-epidermal junction. Following separation from the dermis, the epidermis was digested with trypsin to obtain a single cell suspension. Compared with the conventional procedure, this isolation method was shorter and resulted in (i) cells displaying a higher colony forming efficiency, (ii) cells reaching confluence 1–3 days earlier, (iii) cells not contaminated by fibroblasts, (iv) a cell population containing all the basal layer keratinocytes. These cells were suitable for the establishment of primary cultures and could be subcultured. Such cell populations should be advantageous in studies of epithelial-mesenchymal interactions in which keratinocyte populations, free of fibroblasts, are desirable. In the treatment of extensively burned patients using cultured epidermal sheets, the main problem remains the time required for their production. Thus, the absence of fibroblast overgrowth of the keratinocyte cultures and the significantly reduced time to obtain confluent cultures and epidermal sheets with our method have very important implications for the treatment of large burn wounds.

Out of several monoclonal antibodies secreted by hybridomas resulting from the fusion of a mouse myeloma cell line with spleen cells from mice immunized with cerebellar membranes from 12 day old rats, one, called 11.9, produced an unusual immunolabelling pattern when tested on sections of rat cerebellum. The cerebellar distribution of the antigenic sites recognized by this antibody using an immunoperoxidase technique at the optical and ultrastructural levels is described in detail in this report. The immunoreaction product was found in the adult rat to be associated with the microtubules and the zone immediately beneath the plasma membrane of parallel fibres. In young animals the density of immunostaining appears to be higher than in the adult, and the staining is detectable in addition in the perikaryal cytoplasm of granule cells. Biochemical studies using the Western immunoblot technique demonstrate that the antigens consist of two polypeptides of molecular weights 120 and 185 kD. The possible relation of the antigens to cytoskeletal structures is discussed and the labelling pattern is compared with that produced by other known monoclonal antibodies.

When Y-1 mouse adrenal tumor cells were treated with sodium orthovanadate, an agent disrupting BHK21-F cell microtubule-intermediate filament (IF) interactions, there was no change in the amount of 20-dihydroprogesterone produced. A neurofilament-microtubule perturbing agent, beta, beta-iminodipropionitrile (IDPN), enhanced the ability of Y-1 cells to produce steroid in response to ACTH by acting on the plasma membrane. Electron microscopy of Y-1 cells extracted with Triton X-100 revealed that both vanadate and IDPN caused the aggregation of granular structures in the perinuclear area. Based on the steroidogenic effects of IDPN, perinuclear granule aggregation may result from an altered interaction between intermediate filaments, microtubules and the plasma membrane. The reason for the ultrastructural changes caused by vanadate is unknown.

Plasma membrane receptors are essential for lymphocytes, providing the specificity through which the cells interact with antigens and regulatory molecules, and initiating the events which alter the lymphocytes' activity and state of differentiation. Here, Jonathan Braun discusses the lymphocyte contractile system and how it influences these membrane receptors.