MatriGrid® Based Biological Morphologies: Tools for 3D Cell Culturing.

Recent trends in 3D cell culturing has placed organotypic tissue models at another level. Now, not only is the microenvironment at the cynosure of this research, but rather, microscopic geometrical parameters are also decisive for mimicking a tissue model. Over the years, technologies such as micromachining, 3D printing, and hydrogels are making the foundation of this field. However, mimicking the topography of a particular tissue-relevant substrate can be achieved relatively simply with so-called template or morphology transfer techniques. Over the last 15 years, in one such research venture, we have been investigating a micro thermoforming technique as a facile tool for generating bioinspired topographies. We call them MatriGrid®s. In this research account, we summarize our learning outcome from this technique in terms of the influence of 3D micro morphologies on different cell cultures that we have tested in our laboratory. An integral part of this research is the evolution of unavoidable aspects such as possible label-free sensing and fluidic automatization. The development in the research field is also documented in this account.

PARP-1 expression and activity in primary human lung cells.

Activation of poly(ADP-ribose) polymerase-1 (PARP-1) in response to DNA damage is an important mechanism to keep homeostasis or to trigger apoptosis. The expression and function of (PARP-1) was studied in primary cells cultured from human lung. Normal human bronchial epithelial cells (NHBEC) and peripheral lung cells (PLC) from lung cancer patients were grown as explant cultures and were followed over a period of 12 weeks. PARP-1 protein was expressed in all explant cultures from bronchial epithelium. The levels of PARP protein differed between individuals by a factor of 2.3 in the first explant. Three cases were followed for more than 100 days. The expression levels varied intra-individually by a factor of 1.3-1.4 over this time period. PARP-1 activity was determined immunohistochemically after induction of DNA damage with H(2)O(2) (0.05-0.3 mM, 5 min). The fluorescence signal for ADP-ribose polymers attached to chromatin proteins correlated well with the concentration of H(2)O(2). PARP-1 activity differed by a factor of 3.1 in NHBECs obtained from the first generation of explants from 11 cases. PARP-1 activity is present in NHBECs until the 8th and in PLCs until the 12th week and declined to about half of the start level. Primary cultures of NHBECs and PLC are suitable to study the effect of external factors on PARP-1 expression and function.

Cadmium, cobalt and lead cause stress response, cell cycle deregulation and increased steroid as well as xenobiotic metabolism in primary normal human bronchial epithelial cells which is coordinated by at least nine transcription factors.

Workers occupationally exposed to cadmium, cobalt and lead have been reported to have increased levels of DNA damage. To analyze whether in vivo relevant concentrations of heavy metals cause systematic alterations in RNA expression patterns, we performed a gene array study using primary normal human bronchial epithelial cells. Cells were incubated with 15 microg/l Cd(II), 25 microg/l Co(II) and 550 microg/l Pb(II) either with individual substances or in combination. Differentially expressed genes were filtered out and used to identify enriched GO categories as well as KEGG pathways and to identify transcription factors whose binding sites are enriched in a given set of promoters. Interestingly, combined exposure to Cd(II), Co(II) and Pb(II) caused a coordinated response of at least seven stress response-related transcription factors, namely Oct-1, HIC1, TGIF, CREB, ATF4, SRF and YY1. A stress response was further corroborated by up regulation of genes involved in glutathione metabolism. A second major response to heavy metal exposure was deregulation of the cell cycle as evidenced by down regulation of the transcription factors ELK-1 and the Ets transcription factor GABP, as well as deregulation of genes involved in purine and pyrimidine metabolism. A third and surprising response was up regulation of genes involved in steroid metabolism, whereby promoter analysis identified up regulation of SRY that is known to play a role in sex determination. A forth response was up regulation of xenobiotic metabolising enzymes, particularly of dihydrodiol dehydrogenases 1 and 2 (AKR1C1, AKR1C2). Incubations with individual heavy metals showed that the response of AKR1C1 and AKR1C2 was predominantly caused by lead. In conclusion, we have shown that in vivo relevant concentrations of Cd(II), Co(II) and Pb(II) cause a complex and coordinated response in normal human bronchial epithelial cells. This study gives an overview of the most responsive genes.

Arachidonic acid pathway activates multidrug resistance related protein in cultured human lung cells.

Primary cultures of human lung cells can serve as a model system to study the mechanisms underlying the effects of irritants in air and to get a deeper insight into the (patho)physiological roles of the xenobiotic detoxification systems. For 99 human lung cancer cases the culture duration for bronchial epithelium and peripheral lung cells (PLC) are given in term of generations and weeks. Using this system, we investigated whether and how prostaglandins (PG) modify multidrug resistance related protein (MRP) function in normal human lung cells. PGF2alpha had no effect on MRP function, whereas PGE2 induced MRP activity in cultured NHBECs. The transport activity study of MRP in NHBEC, PLC, and A549 under the effect of exogenously supplied PGF2alpha (10 microM, 1 day) using single cell fluorimetry revealed no alteration in transport activity of MRP. PG concentrations were within the physiological range. COX I and II inhibitors indomethacin (5, 10 microM) and celecoxib (5, 10 microM) could substantially decrease the transport activity of MRP in NHBEC, PLC, and A549 in 1- and 4-day trials. Prostaglandin E2 did not change cadmium-induced caspase 3/7 activation in NHBECs and had no own effect on caspase 3/7 activity. Cadmium chloride (5, 10 microM) was an effective inducer of caspase 3/7 activation in NHBECs with a fivefold and ninefold rise of activity. In primary human lung cells arachidonic acid activates MRP transport function only in primary epithelial lung cells by prostaglandin E2 but not by F2alpha mediated pathways and this effect needs some time to develop.

Non-destructive micromethod for MRP1 functional assay in human lung tumor cells.

Defense against toxic endo- and xenobiotics is a major concern of all living species and ABC transporters play a vital role in this defense system. Multidrug resistance associated proteins 1 (MRP1) is a cellular detoxifying factor supposed to transport a wide range of compounds across cell membranes either as GSH conjugates or as co-transport accompanying glutathione transposition. The cellular localization of MRP1 is a determining factor whether the transport function can take place. In this study we have undertaken experiments on the transport activity of MRP1 in cultured human lung tumor cells in order to check whether MRP1 is expressed as a functionally active protein. For this purpose we have adapted a quantitative fluorescence imaging assay to conditions where a small number of attached cells should be repeatedly measured by a non-destructive method. In cultured A549, H358 and H322 cells MRP1 is located in the cell membrane as observed by immunocytochemistry. Efflux of 5,6-carboxy-2'-7'-dichloro-fluorescein (CDF) from lung cells was sensitive toward the MRP1 inhibitor MK571 while verapamil had no effect. On the other hand, efflux of Rhodamin 123, a Pgp-glycoprotein substrate, from lung cells reacted to inhibition by verapamil, while MK571 had no effect. Modulation of glutathion content of lung cells by N-acetyl cystein and buthionine sulfoximine shifted CDF efflux toward higher or lower rates, respectively. These experiments confirm that MRP1 function can be followed in the attached cells in vitro under non-toxic concentrations of the substrates without the need to harvest and destroy the cells.