Histone H2AX is a critical factor for cellular protection against DNA alkylating agents.

Histone H2A variant H2AX is a dose-dependent suppressor of oncogenic chromosome translocations. H2AX participates in DNA double-strand break repair, but its role in other DNA repair pathways is not known. In this study, role of H2AX in cellular response to alkylation DNA damage was investigated. Cellular sensitivity to two monofunctional alkylating agents (methyl methane sulfonate and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)) was dependent on H2AX dosage, and H2AX null cells were more sensitive than heterozygous cells. In contrast to wild-type cells, H2AX-deficient cells displayed extensive apoptotic death due to a lack of cell-cycle arrest at G(2)/M phase. Lack of G(2)/M checkpoint in H2AX null cells correlated well with increased mitotic irregularities involving anaphase bridges and gross chromosomal instability. Observation of elevated poly(ADP) ribose polymerase 1 (PARP-1) cleavage suggests that MNNG-induced apoptosis occurs by PARP-1-dependent manner in H2AX-deficient cells. Consistent with this, increased activities of PARP and poly(ADP) ribose (PAR) polymer synthesis were detected in both H2AX heterozygous and null cells. Further, we demonstrate that the increased PAR synthesis and apoptotic death induced by MNNG in H2AX-deficient cells are due to impaired activation of mitogen-activated protein kinase pathway. Collectively, our novel study demonstrates that H2AX, similar to PARP-1, confers cellular protection against alkylation-induced DNA damage. Therefore, targeting either PARP-1 or histone H2AX may provide an effective way of maximizing the chemotherapeutic value of alkylating agents for cancer treatment.

Chromosome aberrations induced by dual exposure of protons and iron ions.

During space travel, astronauts will be exposed to protons and heavy charged particles. Since the proton flux is high compared to HZE particles, on average, it is assumed that a cell will be hit by a proton before it is hit by an HZE ion. Although the effects of individual ion species on human cells have been investigated extensively, little is known about the effects of exposure to mixed beam irradiation. To address this, we exposed human epithelial cells to protons followed by HZE particles and analyzed chromosomal damage using the multicolor banding in situ hybridization (mBAND) procedure. With this technique, individually painted chromosomal bands on one chromosome allowed the identification of intra-chromosomal aberrations (inversions and deletions within a single painted chromosome) as well as inter-chromosomal aberrations (translocation to unpainted chromosomes). Our results indicated that chromosome aberration frequencies from exposures to protons followed by Fe ions did not simply decrease as the interval between the two exposures increased, but peak when the interval was 30 min.

Resolution of UV-induced DNA damage in Xiphophorus fishes.

The genus Xiphophorus is an important model for investigating the etiology and genetics of sunlight-induced melanoma as well as other cancers. We investigated the role DNA damage plays in tumorigenesis in Xiphophorus using a variety of immunological techniques to examine the induction, distribution, and repair of the major photoproducts in DNA after exposure to solar (ultraviolet-B) radiation. We found that cyclobutane pyrimidine dimers (CPDs) were induced at 5- to 10-fold greater frequency than the (6-4) photoproduct ((6-4)PD) in Xiphophorus signum, and the efficiency of photoproduct formation was tissue-dependent, with the scales providing considerable photoprotection against both types of damage. Both of these lesions are efficiently repaired in the presence of visible light by photoenzymatic repair with CPDs repaired at about twice the rate of (6-4)PDs. Photoenzymatic repair of cyclobutane dimers is inducible by prior exposure to low levels of visible light and can be extremely rapid, with most of the lesions removed within 30 minutes. In the absence of light, dimers are removed by nucleotide excision repair with somewhat greater efficiency for the (6-4)PD compared with the CPD in most species. The relative efficiencies of nucleotide excision repair and photoenzymatic repair are tissue-specific and species-specific. The diverse photochemical and photobiological responses observed in Xiphophorus fishes suggest that heritable traits governing the induction and repair of DNA damage may be involved in the susceptibility of Xiphophorus hybrids to melanomagenesis.

Induction, distribution and repair of UV photodamage in the platyfish, Xiphophorus signum.

The genus Xiphophorus is an important model for investigating the etiology and genetics of sunlight-induced melanoma as well as other cancers. We used immunological techniques to determine the induction, distribution and repair of cyclobutane pyrimidine dimers (CPD) and pyrimidine(6-4)pyrimidone dimers ([6-4]PD) in different tissues of Xiphophorus signum exposed to ultraviolet-B light. We found that the (6-4)PD was induced at 5 to 10-fold lower frequency than the CPD and that scalation provided considerable photoprotection against both photoproducts. Photoenzymatic repair (PER) was very efficient in X. signum with most of the lesions removed within 20 min; PER of CPD occurred at about twice the rate of (6-4)PD. Nucleotide excision repair (NER) was much less efficient than PER and the rates of CPD and (6-4)PD removal were comparable. PER was more efficient in the caudal fin compared to the lateral epidermis; the opposite was true for NER. Although the initial rate of CPD excision was five-fold faster in the lateral epidermis compared to the caudal fin a considerable amount of residual damage remained in both tissues. The diverse photochemical and photobiological responses observed in X. signum suggest that heritable traits governing deoxyribonucleic acid damage induction and repair may be involved in the susceptibility of other Xiphophorus species to melanomagenesis.

Cerumen impaction in the elderly.

1. Cerumen impaction is a reversible cause of conduction hearing loss in the elderly. 2. Risk factors include ear canal hairs, hearing aids, bony growths secondary to osteophyte or osteoma, and a history of impacted cerumen. 3. Cerumen removal can cause damage to the external auditory meatus, perforation of the tympanic membrane, and/or otitis media. 4. Methods to remove cerumen impactions include: ceruminolytic agents, curette methods and lavage method.