Although it is known that sunlight is carcinogenic,few molecular data are available concerning the mutagenic effects of ultraviolet (UV) B (290-320 nm) and UVA (320-400 nm) radiation in human cells. To analyze the biologic effects of UVA and UVB, we irradiated the 293 human cell line, derived from adenovirus-transformed human embryonic kidney cells, in which we had stably introduced a shuttle vector harboring the lacZ' bacterial gene as the mutagenesis target. Identical cell survival occurred after UVA doses 700-fold higher than UVB. This comparable to the UVA/UVB ratio that reaches the basal cell layer of the skin after sunlight exposure with UVB sunscreen. The frequency of UVA- and UVB- induced mutations increased with the UV dose as cell survival decreased. At cell survival levels greater than 10%, UVA and UVB induced similar frequencies of mutations in the episomal lacZ gene, whereas for cell survival lower than 10%, UVA induced twice as many mutations as UVB. Sequence analysis of 81 independent lacZ mutants (36 UVA- and 45 UVB-induced) revealed specific characteristics for some UV-induced-mutations, particularly for UVB. Mutations at A/T base pairs were induced more frequently by UVA than by UVB. The UVA-induced mutation spectrum that we have observed in human cells may help help to elucidate the mechanism of skin carcinogenesis.
Nucleotide excision repair (NER)-deficient human cells have been assigned so far to a genetic complementation group by a somatic cell fusion assay and, more recently, by microinjection of cloned DNA repair genes. We describe a new technique, based on the host cell reactivation assay, for the rapid determination of the complementation group of NER-deficient xeroderma pigmentosum (XP), Cockayne's syndrome (CS) and photosensitive trichothiodystrophy (TTD) human cells by cotransfection of a UV-irradiated reporter plasmid with a second vector containing a cloned repair gene. Expression of the reporter gene, either chloramphenicol acetyltransferase (CAT) or luciferase, reflects the DNA repair ability restored by the introduction of the appropriate repair gene. All genetically characterized XP, CS and TTD/XP-D cells tested failed to express the UV-irradiated reporter gene, this reflecting their NER deficiency whereas cotransfection with the repair plasmid expressing a gene specific for the given complementation group increased the enzyme activity to the level reached by normal cells. Selective recovery of both reporter enzyme activities was observed after cotransfection with the XPC gene for the XP17VI cells and with the XPA gene for both XP18VI and XP19VI cells. Using this method, we assigned three new NER-deficient human cells obtained from patients presenting clinical symptoms described as classical XP to either XP group A (XP18VI and XP19VI) and XP group C (XP17VI). Therefore, this technique increases the range of methods now available to determine the complementation group of new NER deficient patients with the advantage, unlike the somatic cell fusion assay or the microinjection procedure, of being simple, rapid, and inexpensive.
Xeroderma pigmentosum (XP) and trichothiodystrophy (TTD) are autosomal recessive diseases associated with extreme cutaneous photosensitivity, a defect in nucleotide excision repair (NER), and genetic complexity. Severe prognosis and lack of treatment led families at risk to request genetic counseling. Unscheduled DNA synthesis (UDS) is the classic method for diagnosis and requires 4 to 5 wk before conclusion. The use of the alkaline comet assay (single cell gel electrophoresis assay) is proposed as a simple repair test for earlier prenatal diagnosis. Amniotic or chorionic villus cells in two pregnancies at risk for XP and one for TTD were examined in comparison with skin fibroblasts of family members or with repair-proficient or -deficient control cells. The comet assay and the UDS test were performed in parallel. In repair-proficient cells, DNA strand breaks due to the incision of UV-induced DNA damage result in increased migration of high molecular weight DNA in the comet assay. Fetal cells demonstrate repair capacity similar to that of fibroblasts. In incision repair-deficient XP and TTD cells, after post-UV incubation, migration does not occur and comet moments are reduced. Two fetuses belonging to two XP families responded normally and were diagnosed as unaffected. Fetal cells in a TTD family had reduced comet moments and a low UDS. This fetus was diagnosed and confirmed later as affected. Heterozygotes had normal responses with both assays. The comet assay offers discrimination similar to that of the UDS assay in identifying NER-deficient phenotypes. Practical advantages in view of prenatal diagnosis include the reduced number of cells required, a 24-h delay in obtaining results, and no need for radioactivity.
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