Arsenate suppression of human keratinocyte programming.

The human keratinocyte line SCC-9 has been used as a model for arsenate-induced perturbations of differentiation. Growth of these cells in 10 microM arsenate permitted the cultures to reach confluence, but prevented expression of 6 markers of suprabasal differentiation (involucrin, loricrin, filaggrin, spr 1, keratin 1 and keratin 10) as assayed by Northern blotting. By contrast, only slight alterations in mRNA levels were observed for one differentiation marker (keratinocyte transglutaminase) and for keratin 5, keratin 14, AP2 or glyceraldehyde phosphate dehydrogenase. The transition metal oxyanions vanadate and chromate had essentially the same suppressive effect on these markers as arsenate, while chronic treatment with tetradecanoylphorbol acetate was generally less effective in suppressing differentiation. To determine whether the previously observed arsenate-mediated alteration in AP1 and AP2 activities could account for the suppression of involucrin, a promoter analysis was conducted. Putative AP1 and AP2 response elements were identified in regions important for transcriptional activity of the 5'-flanking DNA. Mutations in two AP1 sites and one AP2 site were observed to decrease promoter activity significantly, and in combination, to reduce it to approximately 10% of that conferred by the native sequence. These results lend support to the working hypothesis that arsenate suppresses involucrin expression, and, more generally, keratinocyte programming, by altering the transcription factors AP1 and AP2.

Arsenate perturbation of human keratinocyte differentiation.

Treatment of cultured malignant human keratinocytes with sodium arsenate greatly suppressed expression of involucrin, a specific marker of keratinocyte differentiation. This action was primarily attributable to inhibition of involucrin transcription according to message run-on and stability measurements. Involucrin was suppressed in nontumorigenic keratinocytes as well, although the efficacy of suppression was less dramatic in cells derived from clinically normal epidermis. Several transition metal oxyanions (vanadate, molybdate, and tungstate) also substantially suppressed involucrin expression, but okadaic acid was ineffective. Immunoblotting detected marked increases in tyrosine phosphorylation of several proteins as a consequence of arsenate treatment of the cultures, while mobility shift analysis revealed a dramatic loss of DNA binding by the transcription factor AP2. These findings support a proposed role for altered levels of protein tyrosine phosphorylation in keratinocyte differentiation. They also suggest that arsenate perturbs the differentiation program in target cells by altering this phosphorylation level and transcription factor activity.