Histopathology of drug rash with eosinophilia and systemic symptoms syndrome: a morphological and phenotypical study.

BACKGROUND: The histopathological features of drug rash with eosinophilia and systemic symptoms (DRESS) syndrome remain poorly characterized. OBJECTIVES: To better characterize the histopathological features of DRESS syndrome, and define the phenotype of the effector cells in the skin and compare it with maculopapular rash (MPR). METHODS: We conducted a retrospective study on 50 skin biopsies from patients with DRESS syndrome (n = 36). Histopathological and immunophenotypical features were studied and compared with a series of MPRs (n = 20). RESULTS: Foci of interface dermatitis, involving cutaneous adnexae, were frequently seen in cases of DRESS. Eosinophils were seen in only 20% of cases and neutrophils in 42%. Eczematous (40%), interface dermatitis (74%), acute generalized exanthematic pustulosis-like (20%) and erythema multiforme-like (24%) patterns were observed. The association of two or three of these patterns in a single biopsy was significantly more frequent in cases of DRESS than in a series of nondrug-induced dermatoses (P < 0.01), and appeared to be more marked in DRESS syndrome with severe cutaneous lesions (P = 0.01) than in less severe cases of DRESS and MPR. A higher proportion of CD8(+) and granzyme B(+) lymphocytes was observed in cases of DRESS with severe cutaneous eruptions (erythroderma and/or bullae). Atypical lymphocytes were found in 28% of biopsies, and expressed CD8 in most cases; a cutaneous T-cell clone was rarely found (6%). CONCLUSIONS: The histopathology of DRESS syndrome highlights various associated inflammatory patterns in a single biopsy. Cutaneous effector lymphocytes comprise a high proportion of polyclonal CD8(+) granzyme B(+) T lymphocytes.

Pol eta is required for DNA replication during nucleotide deprivation by hydroxyurea.

Hydroxyurea reduces DNA replication by nucleotide deprivation, whereas UV damage generates DNA photoproducts that directly block replication fork progression. We show that the low fidelity class Y polymerase Pol eta is recruited to proliferating cell nuclear antigen at replication forks both by hydroxyurea and UV light. Under nucleotide deprivation, Pol eta allows cells to accumulate at the G1/S boundary by facilitating slow S-phase progression and promotes apoptosis. Normal cells consequently enter apoptosis at a faster rate than Pol eta-deficient cells. Coincident with hydroxyurea-induced S-phase delay, Pol eta-deficient cells undergo more replication fork breakage and accumulate more foci of the Mre11/Rad50/Nbs1 complex and phosphorylated histone H2AX. We conclude that under conditions of nucleotide deprivation, Pol eta is required for S-phase progression but is proapoptotic. However, as Pol eta is reported to require higher nucleotide concentrations than class B replicative polymerases, its recruitment by hydroxyurea requires it to function under suboptimal conditions. Our results suggest that hydroxyurea-induced apoptosis occurs at the G1/S boundary and that initiation of the S-phase requires greater nucleotide concentrations than does S-phase progression.