EML4-ALK fusion gene, is found in 3 to 5 % of lung adenocarcinoma and can be targeted by tyrosine-kinase inhibitor (TKI) with impressive therapeutic results.

Fanconi anemia (FA) is a rare genetic disease, transmitted in an autosomal recessive mode. The clinical phenotype is very broad and heterogeneous, related to the wide range of genes involved in this pathology. The classical triad of short height, physical abnormalities, and bone marrow failure is suggestive. The main physical abnormalities found involve the limbs, spinal column, skin, kidneys and urinary tract, and the ORL zone. Recent progress in molecular biology has identified 15 genes whose mutation causes FA chromosomal instability. FA is diagnosed by cytogenetic examination, then specified by molecular analysis. As FA patients may present multiorgan abnormalities and a high risk for neoplasia development, their medical follow-up has to be multidisciplinary and prolonged throughout life. The main challenges of the follow-up are patient information and education. Bone marrow failure, appearing during the first decade, requires close hematological monitoring and for severe cases requires hematopoietic stem cell transplantation, major and specific care with frequent serious complications and high mortality, but this is the only curative treatment in FA. Extrahematological care consists in screening for organ abnormalities and defects as well as monitoring precancerous lesions and tumors.

Retinoblastoma is the most common primary cancer of the eye in children. The prognosis for survival is excellent. The current therapy includes an improved survival rate and decreased iatrogenic sequelae. The relative risk of a second tumor in survivors of retinoblastoma is documented, especially in those who carry a germline RB mutation. It is strongly increased in case of radiation therapy. The most common types of second primary tumor are sarcoma of soft tissues and osteosarcoma. We present here a rare case of a retinoblastoma patient who received radiation therapy as a part of his treatment and developed a papillar thyroid cancer as a second malignancy. Papillar thyroid cancer has a good prognosis. Systematic screening for thyroid carcinoma should be undertaken in patients irradiated for congenital retinoblastoma.

Following the Chernobyl accident, enormous amounts of radioisotopes were released in the atmosphere and have contaminated surrounding populations in the absence of rapid protective countermeasures. The highest radiation doses were delivered to the thyroid gland, and the only direct consequence of radiation exposure observed among contaminated population is the increased incidence of thyroid cancers among subjects who were children in 1986 and who lived at that time in Belarus, Ukraine or Russia.

Among cancers diagnosed worldwide on a yearly basis, 20% are thought to be associated with a viral infection. The viruses involved are, by order of decreasing incidence, the hepatitis viruses, the papillomaviruses and the Epstein-Barr virus. These virus-induced cancers generate a high level of interest not only for the study of mechanisms involved in the neoplastic transformation, but also for the set-up of specific immunotherapies including prophylactic and therapeutic antitumor vaccination.

The complete hydatidiform mole (CHM), a gestational trophoblastic disease, is usually caused by the development of an androgenic egg whose genome is exclusively paternal. Due to parental imprinting, only trophoblasts develop in the absence of a fetus. CHM are diploid and no abnormal karyotype is observed. It is 46,XX in most cases and less frequently 46,XY. The major complication of this disease is gestational choriocarcinoma, a metastasizing tumor and a true allografted malignancy. This complication is infrequent in developed countries, but is more common in the developing countries and is then worsened by delayed care. The malignancies are often accompanied by acquired, possibly etiological genomic abnormalities. We investigated the presence of recurrent cytogenetic abnormalities in CHM and post-molar choriocarcinoma using metaphasic CGH (mCGH) and high-resolution 244K aCGH techniques. The 10 CHM studied by mCGH showed no chromosomal gains or losses. For post-molar choriocarcinoma, 11 tumors, whose diagnosis was verified by histopathology, were investigated by aCGH. Their androgenic nature and the absence of tumor DNA contamination by maternal DNA were verified by the analysis of microsatellite markers. Three choriocarcinoma cell lines (BeWo, JAR and JEG) were also analyzed by aCGH. The results allowed us to observe some chromosomal rearrangements in primary tumors, and more in the cell lines. Chromosomal abnormalities were confirmed by FISH and functional effect by immunohistochemical analysis of gene expression. Forty minimum critical regions (MCR) were defined on chromosomes. Candidate genes implicated in choriocarcinoma oncogenesis were selected. The presence in the MCR of many miRNA clusters whose expression is modulated by parental imprinting has been observed, for example in 14q32 or in 19q13.4. This suggests that, in gestational choriocarcinoma, the consequences of gene abnormalities directly linked to acquired chromosomal abnormalities are superimposed upon those of imprinted genes altered at fertilization.

Pheochromocytomas and paragangliomas are rare tumors that arise from chromaffin tissues of the adrenal medulla and from sympathetic and parasympathetic ganglia. Ten susceptibility genes (VHL, RET, NF1, SDHA, B, C and D, SDHAF2, TMEM127 and finally MAX) are responsible for at least 30% of the cases. These patients can either have a familial history of the disease, a syndromic presentation, but can also emerge as apparently sporadic forms. Moreover, recent transcriptomic studies have led to the identification of somatic mutations in VHL and RET genes in 15% of sporadic cases, thus bringing a molecular explanation for nearly half of all cases. These findings have had a major impact on the understanding of the molecular mechanisms of tumorigenesis in pheochromocytomas and paragangliomas. It was shown that the genetic status of tumors is associated with particular transcription signatures, such as the activation of the pseudohypoxic response or the activation of MAPK or mTOR signalling. From nowadays to a close future, these advances will have important consequences on the monitoring of patients, from genetic counseling to a personalized clinical management.

Tumor predisposition in children is rare, accounting for approximately 10% of all cancers in childhood. Tumor predisposition involves very rare tumors such as pleuropulmonary blastoma, adrenocortical carcinoma, hepatoblastoma, rhabdoid tumors, optic pathway glioma, as well as rare tumors such as retinoblastoma, medulloblastoma, nephroblastoma, or more frequent tumors such as sarcomas, neuroblastoma, and leukemias. The identification of these predispositions is important for improved management for both the child and relatives. Prenatal and preimplantation genetic diagnosis are options that could be considered for young parents in a perspective of future pregnancies. This manuscript describes the main tumor predispositions in childhood. From each histological subtype, the different diagnosis directions are discussed in view of these main tumor predispositions.

Chromosome arms 1p and 19q codeletion, corresponding to an unbalanced reciprocal translocation t(1;19)(q10;p10), is seen in oligodendroglial tumours and is associated with better prognosis and better chemosensitivity. BRAF abnormalities are observed in pilocytic astrocytomas (tandem duplication-rearrangement) and in pleomorphic xanthoastrocytomas (BRAF V600E mutation). The vast majority of primary or de novo glioblastomas exhibit genetic abnormalities disrupting the intracellular signaling pathways of: transmembrane tyrosine kinase receptors to growth factors and their downstream signaling pathways (i.e. NF1-RAS-RAF-MAPK and PTEN-PI3K-AKT-TSC-mTOR); RB and; TP53. IDH1 and IDH2 mutations are frequent in diffuse grade II and grade III gliomas and in secondary glioblastomas. They are diagnostic and favorable independent prognostic biomarkers. In contrast, they are rare in primary or de novo glioblastomas and not reported in pilocytic astrocytomas. Germlin mutations in MSH2/MLH1/PMS2/MSH6, CDKN2A, TSC1/TSC2, PTEN, TP53 and NF1/NF2 predispose to glial tumors in the setting of hereditary cancer predisposition syndromes. Single nucleotide polymorphisms in TERT,CCDC26, CDKN2A/CDKN2B, RTEL, EGFR and PHLDB1 confer an inherited susceptibility to glial tumors.

Chronic myeloid leukemia (CML) is a chronic blood disorder characterized by a reciprocal translocation between chromosomes 9 and 22, leading to the creation of a chimeric gene encoding the BCR-ABL fusion protein with a constitutive tyrosine kinase activity. Although long known as a disease with an inexorable progression to acute leukemia, CML history has been significantly improved by the use of imatinib, a tyrosine kinase inhibitor. Imatinib has revolutionized the treatment of CML by transforming it from an invariably fatal disease to a chronic but manageable condition. In fact, the discovery of this class of targeted therapy had an impact not only on the survival of CML patients but also on other scientific and medical fields. This review illustrates the impact of imatinib, the first example of tyrosine kinase inhibitors on the treatment of CML, on the treatment of other cancers, the impact on health systems and on the scientific research in general.

KRAS status is now a mandatory prerequisite in order to treat metastatic colorectal patients with anti-Epidermal Growth Factor Receptor (EGFR) antibodies, such as cetuximab or panitumumab. KRAS mutations are unambiguously linked to a lack of response to these targeted therapies. Because of the major clinical impact of KRAS status, an observational study has been designed in France, focusing on the ability to perform KRAS testing between october 2008 and october 2009. The study was retro-prospective, national, multicentric, descriptive and non interventional, concerning public and private institutions and KRAS non mutated patients treated with panitumumab. The primary objective of this study was to evaluate delays between the genotyping KRAS request and the result. Secondary objectives were: type of genotyping requests (systematic/prospective or specific/retrospective), prevalence of the different genotyping techniques, delays between the genotyping KRAS request and therapy with panitumumab. Overall, 329 patients from 66 centres have been included. About half of them belonged to private institutions. The results were obtained with a mean delay of 33.4 ± 39.8 days (CI 95%: [28.8; 37.9] days; median: 24 days). Most of KRAS genotyping tests were performed on specific requests (65.3%), from a primary tumor (80.4%) and from a surgical specimen (73.9%). The more frequently used techniques for KRAS genotyping were: real time PCR (36.2%), sequencing (24.8%) and pyrosequencing (13.2%). This study emphasizes the functionality of cancer molecular genetic platforms dedicated to KRAS genotyping, which allow the use of molecular predictive biomarkers by different medical institutions. This study also underlines the broad spectrum of genotyping techniques (no consensus). The delays of response are still longer than expected but might be improved by optimizing the procedures.

Lung cancer is the leading cause of cancer death in the world, favored by smoking. Nonsmall cell lung cancer is a heterogeneous disease whose prevalence is increasing among women. Epidemiological, hormonal and pathological factors explain tumor differences between men and women. Women have more frequently adenocarcinomas, EGFR mutations and respond better to cancer treatments. In recent decades, many advances have been made, allowing us to move from histological to molecular characterization of lung tumors. Further analysis of gender disparities will help us to understand and improve the management of patients with NSCLC.

Cellular communication is required for the life of pluricellular organisms. The informations exchanged between cells belong to six major types of order to be executed, opposite each other: proliferate or differentiate; remain attached or migrate; survive or die. The cancer cell is genetically unstable, able to explore all the functions encoded by the genome and to consider every proliferative or migratory advantage for selecting it and transmit it to its descent. All the signalling pathways involved in proliferation or differentiation, in adhesion and migration, in survival and death may be altered by oncogenic alterations. These alterations are precisely those which can be targeted for therapy: from this observation was forged the concept of targeted therapy. We present here some examples of therapeutic targeting at the level of a major proliferation pathway by showing how it was possible to identify and characterise relevant targets, invent original new therapeutic tools and decipher the mechanisms of resistance which occur and hinder the success of targeted therapies. This example is the proliferation signalling pathway which starts from the activation of tyrosine kinase receptors by cognate growth factors and ends by the activation of transcription factors which trigger the transcription of the genes required for DNA replication, after undergoing through numerous intermediate molecules constituting the MAP kinase pathway: RAS, RAF, MEK and ERK.

Scientific advances in molecular biology and understanding of oncogenesis have lead to anticancer molecular targeted therapies. They encompass monoclonal antibodies binding to active membrane epitopes and small molecules interfering with enzymatic reactions essential to cancer cell survival (oncogene addiction). These pathways may be optimal targets. Clinical benefits achieved using these targeted agents have been outstanding both in localized and metastatic disease.

Breast cancers account for one third of cancer patients of childbearing age. Given the trend for women to delay childbearing, many of them will not fulfill their parental project at diagnosis of a potential breast cancer. Thus, planning pregnancies in young patients with a history of breast cancer is increasingly becoming a common situation. In this difficult context, several issues have to be discussed with the patient, such as post-chemotherapy premature ovarian failure, fertility-sparing techniques, risk of cancer recurrence or optimal time between cancer and future pregnancy. Potential obstetrical complications, long-term teratogenicity of anti-cancer drugs or breast-feeding are another points that have to be discussed with the patient and her husband. The aim of this updated review of literature was to provide answers to the numerous questions that may be encountered in this type of highly difficult situation. Thus, planning a pregnancy in breast cancer patients seems to be possible with, in one hand, a multidisciplinary approach in order to answer different questions and to avoid side effects of chemotherapy. In the other hand, a close and specialized obstetrical monitoring should be proposed in order to anticipate potential obstetrical complications.

The treatment of metastatic melanoma is presently in complete revolution. Two molecules have recently been authorized for this indication. These treatments have a very different mechanism of action compared to previous chemotherapies. Vemurafenib is a targeted therapy, which blocks BRAF selectively. This molecule induces objective responses in more than 50 % of the patients with V600E mutated melanoma and a benefit in terms of overall survival. However, many patients relapse after about 6 to 8 months of treatment. Many mechanisms are evoked to explain these secondary resistances to therapy. Ipilimumab is an immunotherapy that blocks CTLA4, a physiological brake of lymphocyte activation. With ipilimumab, the objective responses are less frequent than with vemurafenib but are more prolonged over time. Two phases III have demonstrated that ipilimumab treatment is effective on the overall survival of patients with metastatic melanoma. New combination therapies and additional targeted and immunotherapy agents are exciting perspectives that make us more optimistic for the future of metastatic melanoma treatment.