Gene expression profile in monocyte during in vitro mineral fiber degradation.

A human monocytes cell line, U-937, incubated in the presence of filtered medium from Escherichia coli culture (FS) has been previously reported to degrade man made mineral fiber and it has been indicated as a good paradigm of in vivo fiber biopersistence evaluation (manuscript accepted for publication). In the present paper, a study is reported aimed to define the molecular modification occurring in the U-937 monocytes during in vitro fiber degradation. The induction of gene expression was investigated in U-937 exposed to rock wool fibers (HDN) in the presence of FS by transcriptome analysis using 20 K DNA microarrays and quantitative RT-PCR. The over-expression of genes related to mobility and cellular adhesion, oxidative stress, immune system stimulation, enzymes, and ions transport protein systems were identified. Among them NCF1 gene, the gene encoding a subunit of NADPH oxidase, over-expression was detected. As the product of this gene allows the formation of superoxide anion that could lead to oxidative stress, HDN fibers were exposed to hydrogen peroxide. Fiber degradation similar to those observed upon incubation with U-937 in the presence of FS was obtained thus suggesting that reactive oxygen species production may be responsible for fiber degradation by U-937 monocytes.

A new in vitro cellular system for the analysis of mineral fiber biopersistence.

The toxicity of mineral fibers, whether they are natural or man made (MMMF), is usually evaluated in vivo using biopersistence tests in rodents. Development of an in vitro cellular model would be worthwhile in order to reduce, refine and finally replace animal models. For this purpose, we developed an in vitro assay using human monocytic cell line (U-937) to evaluate a new manufactured rock wool fiber (HDN) biodegradation. Experiments on earlier known mineral fibers asbestos (crocidolite) and glass wool fibers (CM44) were also performed. U-937 responded to HDN and CM44 only if they were activated. Among the different activators we used, Escherichia coli living cells as well as FS were the most efficient as evidenced by alterations of HDN and CM44 surface, detected by scanning electron microscopy, and by the measure of silicon released from the rock wool fibers. Asbestos fibers were not degraded when incubated in the presence of living bacteria. The MMMF modifications were function of the fiber composition, the time of exposure to activated cells and the concentration of activators. The pattern of MMMF degradation by our in vitro system was in accordance with those observed in an in vivo study, thus indicating that the fiber degradation by macrophage cells activated by E. coli living cells as well as FS is a valuable system to assess mineral fibers' biopersistence.