Calcium homeostasis in lens transparency and the involmement of calpains in cataract

Lee, Hannah Yun Young

January 2006

The absolute clarity of the lens of the eye is vital in the visual system. The unique structural and physiological properties of the lens are tightly integrated with highly ordered protein content to allow the lens to remain transparent. Consequently, any alteration or disturbance of these highly ordered proteins can affect the optical properties of the lens. In humans, cataracts are the major cause of blindness, yet the exact aetiology of cataract formation (cataractogenesis) is not fully understood. The purpose of the current research was to investigate whether deregulation of the Ca²⁺-dependent enzyme, calpains, following changes in lens Ca²⁺ homeostasis, is a key mechanism leading to undesired cleavage of a number of proteins that are linked with maintaining lens transparency and contributing to cataractogenesis. An ovine lens culture (in vitro) system and the heritable ovine cataract (in vivo) model were used to test the research hypothesis. The Ca²⁺ ionophore, ionomycin, was used to induce a Ca²⁺ overload and in vitro opacification during lens culture. Opacity in the lens was graded by a computer image analysis program. Protein profile (SDS-PAGE, 2-DE and Western detection), calpain activity (casein zymography), lens structure (microscopic view) and cytotoxicity level (LDH leakage assay) were analysed in Ca²⁺-induced opaque lenses. The involvement of calpain during opacification was further examined by applying synthetic exogenous calpain inhibitors to the in vitro system. Two novel exogenous calpain inhibitors were also assessed for their therapeutic potential in preventing the progression of cataracts in the in vivo cataract model by topical administration of the inhibitor direct to the sheep's eye over a 11 week period. HPLC was used to detect the penetration of these compounds into ocular tissues. Sustained Ca²⁺ influx into cultured lenses caused dense opacification. The opacity was characterised by formation of a turbid fraction and cell death in the outer cortex of the ovine lens. There was increased calpain autolysis associated with the progress of opacification, indicating increased calpain activity. Major degradation of the cytoskeletal proteins, spectrin and vimentin, was observed whilst there was limited degradation of the lens structural soluble proteins, crystallins, in response to a Ca²⁺ flux. Lens proteins were protected from degradation by adding synthetic calpain inhibitors to the culture medium. Topical administration of novel anti-calpain molecules failed to retard the progression of cataractogenesis in the ovine inherited cataract model. Further investigation of drug penetration showed that efficacy of inhibitory compounds was limited by permeability of these molecules across the cornea and the ability of the molecules to reach and penetrate into the lens. The ovine lens Ca²⁺-induced opacification (OLCO) model in this thesis has provided a model to understand the role of Ca²⁺ homeostasis in lens transparency. With sustained intracellular Ca²⁺ level, the degradation of cytoskeletal elements is highly correlated with calpain activity. Cataractogenesis is the pathological response to the loss of lens Ca²⁺ homeostasis in this model. The current results support the hypothesis that the deregulation of calpain activity is a trigger for a series of cascading events, leading to death of the cells in the lens.

cataractogenesis

Ca²⁺ homeostasis

proteolysis

calpain

cytoskeletal proteins

crystallins

calpain inhibitors

ovine lens

culture system

OLCO model

cell death

inheritable ovine cataract model

cataract

0601 - Biochemistry and Cell Biology

Microarrays for the scalable production of metabolically relevant tumour spheroids: a tool for modulating chemosensitivity traits

Hardelauf, Heike, Frimat, Jean-Philippe, Stewart, Joanna D., Schormann, Wiebke, Chiang, Ya-Yu, Lampen, Peter, Franzke, Joachim, Hengstler, Jan G., Cadenas, Cristina, Kunz-Schughart, Leoni A., West, Jonathan

January 2011

We report the use of thin film poly(dimethylsiloxane) (PDMS) prints for the arrayed mass production of highly uniform 3-D human HT29 colon carcinoma spheroids. The spheroids have an organotypic density and, as determined by 3-axis imaging, were genuinely spherical. Critically, the array density impacts growth kinetics and can be tuned to produce spheroids ranging in diameter from 200 to 550 µm. The diffusive limit of competition for media occurred with a pitch of ≥1250 µm and was used for the optimal array-based culture of large, viable spheroids. During sustained culture mass transfer gradients surrounding and within the spheroids are established, and lead to growth cessation, altered expression patterns and the formation of a central secondary necrosis. These features reflect the microenvironment of avascularised tumours, making the array format well suited for the production of model tumours with defined sizes and thus defined spatio-temporal pathophysiological gradients. Experimental windows, before and after the onset of hypoxia, were identified and used with an enzyme activity-based viability assay to measure the chemosensitivity towards irinotecan. Compared to monolayer cultures, a marked reduction in the drug efficacy towards the different spheroid culture states was observed and attributed to cell cycle arrest, the 3-D character, scale and/or hypoxia factors. In summary, spheroid culture using the array format has great potential to support drug discovery and development, as well as tumour biology research. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/570

ddc:570

info:eu-repo/classification/ddc/012

ddc:012