Oncogenic Mutations (oncogenic + mutation)

Distribution by Scientific Domains


Selected Abstracts


The role of genetic testing in soft tissue sarcoma

HISTOPATHOLOGY, Issue 1 2006
C R Antonescu
Soft tissue tumours represent a heterogeneous group of mesenchymal lesions and their classification continues to evolve as a result of incorporating advances in cytogenetic and molecular techniques. In the last decade traditional diagnostic approaches were supplemented with a significant number of reliable molecular diagnostic tools, detecting tumour type-specific genetic alterations. In addition, the successful application of some of these techniques to formalin-fixed paraffin-embedded tissue made it possible to subject a broader range of clinical material to molecular analysis. Thus, molecular genetics has already become an integral part of the work-up in some tumours, such as paediatric small blue round cell tumours, which demonstrate characteristic translocations. Several lines of evidence suggest that sarcomas can be divided into two major genetic groups: (i) sarcomas with specific genetic alterations and usually simple karyotypes, such as reciprocal chromosomal translocations (e.g. FUS-DDIT3 in myxoid liposarcoma) and specific oncogenic mutations (e.g. KIT mutation in gastrointestinal stromal tumours); and (i) sarcomas with non-specific genetic alterations and complex unbalanced karyotypes. Some of these genetic abnormalities, including chromosomal numerical changes, translocations, gene amplifications or large deletions can be apparent at the cytogenetic level (karyotyping, fluoresence in situ hybridization), while others, such as small deletions, insertions or point mutations, require molecular genetic techniques (polymerase chain reaction and sequence analysis). This review focuses on the applicability of genetic testing in the diagnosis and prognosis of soft tissue sarcomas, and gives a realistic appraisal of the ancillary role of molecular techniques, including its advantages and limitations. [source]


PIK3CA cancer mutations display gender and tissue specificity patterns,

HUMAN MUTATION, Issue 2 2008
Silvia Benvenuti
Abstract The occurrence of oncogenic alleles can display striking tissue specificity. For example KRAS mutations are very frequent in pancreatic cancers but relatively rare in melanomas. The opposite is true for BRAF mutations. Somatic mutations in the gene encoding for the phosphatidylinositol 3-kinase (PI3KCA) catalytic subunit, PIK3CA, occur at high frequency in many solid cancers. We have examined whether PI3K oncogenic mutations (exons 9 and 20) might exhibit gender and/or tissue specificity. By examining large cohorts of breast and colorectal cancers affecting both men and women we found that the pattern of PIK3CA mutations is distinctive. In colorectal cancers, PIK3CA (but not KRAS, APC, or TP53) mutations display a gender bias occurring at higher frequencies in women. We also found that male breast cancers display PIK3CA mutations at an overall frequency similar to that observed in female breast tumors. In male breast cancers, however, PIK3CA mutations are found mainly in exon 20. We conclude that PI3KCA mutations affecting exons 9 and 20 display gender- and tissue-specific patterns, thus suggesting that the different amino acid changes could exert distinct functional effects on the oncogenic properties of this enzyme. Furthermore, we propose that sexual dimorphisms and tissue specific factors might directly or indirectly influence the occurrence of PI3KCA cancer alleles. Hum Mutat 29(2), 284,288, 2008. © 2007 Wiley-Liss, Inc. [source]


Lack of oncogenic mutations in the c-Met catalytic tyrosine kinase domain in acral lentiginous melanoma

INTERNATIONAL JOURNAL OF DERMATOLOGY, Issue 12 2008
Hannes Seidl PhD
No abstract is available for this article. [source]


The effect of IFN, on the hepatocyte: cell cycle and apoptosis

INTERNATIONAL JOURNAL OF EXPERIMENTAL PATHOLOGY, Issue 6 2001
Benjamin J. Tura
The inflammatory cytokine interferon gamma (IFN,) can cause cell cycle arrest and apoptosis in the hepatocyte. Primarily these processes are protective but in chronic liver disease oncogenic mutations may prosper. IFN, signalling is discussed showing how p53 is induced to cause cell cycle arrest. While caspases are are known to be responsible for IFN, induced apoptosis, how they are activated is unclear. Potential mechanisms are reviewed. [source]


Adult neural stem cells and their role in brain pathology,

THE JOURNAL OF PATHOLOGY, Issue 2 2009
G Yadirgi
Abstract Stem cells are multipotent cells that can give rise to a differentiated progeny as well as self-renew. The balanced coordination of these two stem cell fates is essential for embryonic development and tissue homeostasis in the adult. Perturbed stem cell function contributes significantly to a variety of pathological conditions, eg impaired self-renewal capacity due to cellular senescence contributes to ageing, and degenerative diseases or impaired stem cell differentiation by oncogenic mutations contribute to cancer formation. This review focuses on the molecular mechanisms involved in regulating the normal function of neural stem cells in the adult mammalian brain and on the involvement of these cells in brain pathology. Copyright © 2008 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd. [source]