Genomic instability in human actinic keratosis and squamous cell carcinoma

OBJECTIVE: To compare the repetitive DNA patterns of human actinic keratoses and squamous cell carcinomas to determine the genetic alterations that are associated with malignant transformation. INTRODUCTION: Cancer cells are prone to genomic instability, which is often due to DNA polymerase slippage during the replication of repetitive DNA and to mutations in the DNA repair genes. The progression of benign actinic keratoses to malignant squamous cell carcinomas has been proposed by several authors. MATERIAL AND METHODS: Eight actinic keratoses and 24 squamous cell carcinomas (SCC), which were pair-matched to adjacent skin tissues and/or leucocytes, were studied. The presence of microsatellite instability (MSI) and the loss of heterozygosity (LOH) in chromosomes 6 and 9 were investigated using nine PCR primer pairs. Random Amplified Polymorphic DNA patterns were also evaluated using eight primers. RESULTS: MSI was detected in two (D6S251, D9S50) of the eight actinic keratosis patients. Among the 8 patients who had squamous cell carcinoma-I and provided informative results, a single patient exhibited two LOH (D6S251, D9S287) and two instances of MSI (D9S180, D9S280). Two LOH and one example of MSI (D6S251) were detected in three out of the 10 patients with squamous cell carcinoma-II. Among the four patients with squamous cell carcinoma-III, one patient displayed three MSIs (D6S251, D6S252, and D9S180) and another patient exhibited an MSI (D9S280). The altered random amplified polymorphic DNA ranged from 70% actinic keratoses, 76% squamous cell carcinoma-I, and 90% squamous cell carcinoma-II, to 100% squamous cell carcinoma-III. DISCUSSION: The increased levels of alterations in the microsatellites, particularly in D6S251, and the random amplified polymorphic DNA fingerprints were statistically significant in squamous cell carcinomas, compared with actinic keratoses. CONCLUSION: The overall alterations that were observed in the repetitive DNA of actinic keratoses and squamous cell carcinomas indicate the presence of a spectrum of malignant progression

Genomic instability as a prognostic and diagnostic factor on the progression of human actinic keratosis, to squamous cell carcinoma

A instabilidade genômica tem sido amplamente usada para caracterizar células cancerosas. Alterações genéticas em queratose actínica (QA) e carcinoma espinocelular (CEC) foram investigadas pelo método de random amplified polymorphic DNA (RAPD) e análise de microssatélites com o objetivo de encontrar marcadores moleculares para auxiliar o prognóstico e o diagnóstico médico. O DNA foi obtido de pacientes brasileiros cirurgiados e tratados no Hospital das Clínicas da Faculdade de Medicina da Universidade de São Paulo, totalizando oito QAs, 24 CECs, e tecidos normais e/ou leucócitos correspondentes. Os microssatélites estudados foram D6S251, D6S252, D9S15, D9S50, D9S52, D9S180, D9S196, D9S280 e D9S287, tendo em vista a detecção de instabilidade genômica representada por perda de heterozigosidade (LOH) e instabilidade de microssatélites (MSI). Os \"primers\" usados para comparar os padrões de RAPD foram OPA-2, OPA-7, OPA-13, OPA-17, OPB-8, OPB-13, OPB-17 e OPB-19. Foi obtida correlação significativa na progressão de QA (1/8) para CEC (5/22) referente ao microssatélite D6S251. As diferenças nos padrões de DNA obtidos pelo método RAPD comparados aos controles foram maiores em lesões com maior grau de severidade segundo critério histológico. O mesmo padrão RAPD foi observado no controle e no tumor em 27% QA, 24% CEC I, 9% CEC II e 0% CEC III. Estes resultados mostram que o microssatélite D6S251 e o método de RAPD são informativos, podendo ser potenciais candidatos para auxílio no diagnóstico e prognóstico de QA e CEC.Genomic instability has been widely used to characterize cancer cells. Genetic alterations in human actinic keratosis (AK) and squamous cell carcinomas (SCC) were investigated by the random amplified polymorphic DNA (RAPD) method, and microsatellite analysis. DNA was obtained from Brazilian patients diagnosed and treated in the School of Medicine of University of Sao Paulo out Clinics Hospital. Eight AKs, 24 SCCs, and 4 BCCs, matched to normal skin tissue and/or leukocytes were studied. Microsatellite patterns were obtained with primers specific to amplify D6S251, D6S252, D9S15, D9S50, D9S52, D9S180, D9S196, D9S280, and D9S287, in search of detection Loss of heterozygosity (LOH) and Microsatellite instability (MSI). The RAPD primers were: OPA-2, OPA-7, OPA-13, OPA-17, OPB-8, OPB-13, OPB-17, and OPB-19. A significant correlation was obtained regarding the progress of AK (1/8) to SCC (5/22) detected with the D6S251 microsatellite. DNA fingerprint obtained with RAPD primers were altered in increasing number of samples, according to their histological degree of differentiation. Similar RAPD patterns were observed in tumor and control in 27% AK, 24% SCC I, 9% SCC II, and zero SCC III. These results suggest microsatellite D6S251 and RAPD method to be potential tools in diagnosis and prognosis of AK and SCC

Genética molecular aplicada ao câncer cutâneo não melanoma Molecular genetics of non-melanoma skin cancer

Os cânceres cutâneos não melanoma são as neoplasias malignas mais comuns em humanos. O carcinoma basocelular e o carcinoma espinocelular representam cerca de 95% dos cânceres cutâneos não melanoma, o que os torna um crescente problema para a saúde p��blica mundial devido a suas prevalências cada vez maiores. As alterações genéticas que ocorrem no desenvolvimento dessas malignidades cutâneas são apenas parcialmente compreendidas, havendo muito interesse no conhecimento e determinação das bases genéticas dos cânceres cutâneos não melanoma que expliquem seus fenótipos, comportamentos biológicos e potenciais metastáticos distintos. Apresenta-se uma revisão atualizada da genética molecular aplicada aos cânceres cutâneos não melanoma, em especial ao carcinoma basocelular e carcinoma espinocelular, enfatizando os mais freqüentes genes e os principais mecanismos de instabilidade genômica envolvidos no desenvolvimento dessas malignidades cutâneas.Non-melanoma skin cancers are the most common malignant neoplasms in humans. About 95% of all non-melanoma skin cancers are represented by basal cell carcinoma and squamous cell carcinoma. Their prevalences are still increasing worldwide, representing an important public health problem. The genetic alterations underlying basal cell carcinoma and squamous cell carcinoma development are only partly understood. Much interest lies in determining the genetic basis of non-melanoma skin cancers, to explain their distinctive phenotypes, biological behaviors and metastatic potential. We present here a molecular genetic update, focusing on the most frequent genes and genomic instability involved in the development and progression of non-melanoma skin cancers