[Chromosomal microarray comparative genome hybridization (arrayCGH) in prenatal settings. Proposal for Hungarian application in clinical practice]. / A microarray-komparatív genomhibridizálás (arrayCGH) praenatalis alkalmazása. Javaslat a hazai bevezetésre.

Invasive prenatal testing and conventional G-banding chromosome analysis have been considered to be the gold standard of fetal cytogenetic diagnosis. Standard karyotyping is, however, constrained by the limits of the resolution of using a microscope. The advantage of molecular karyotyping, array based methods is the evaluation of sub-microscopic copy number changes across the whole genome in a single analysis. The application of array comparative genome hybridization has greatly increased the detection of pathogenic chromosomal abnormalities in prenatal settings. Based on available data in the international literature of the last decade, the clinical utility of arrayCGH is the recognition of some 1-2% and 5-7% additional genetical information compared to metaphase karyotype alone in fetuses without ultrasound anomaly and in fetuses with ultrasonographically detected malformations, respectively. Thus arrayCGH improves the prenatal diagnosis of genetic abnormalities mainly in fetuses with structural sonographic findings. In the present paper we review the literature of chromosomal microarray and make a proposal for the application of the method in Hungarian prenatal genetical practice. Orv Hetil. 2019; 160(13): 484-493.

[Comparative study of somatic oncogene mutations in normal thyroid tissues and thyroid neoplasms]. / Szomatikus onkogén mutációk összehasonlító vizsgálata egészséges és tumoros pajzsmirigy-szövetmintákban.

It is established that numerous somatic oncogene mutation (BRAF, NRAS, HRAS, KRAS) and gene translocations (RET/PTC, PAX8/PPAR-gamma) are associated with the development of thyroid cancer. In this study 22 intraoperative thyroid tissue samples (11 pathologic and 11 normal) were examined. Somatic single nucleotide polymorphisms were analyzed by LigthCycler melting method, while translocations were identified by real-time polymerase chain reaction technique. In tumorous sample 3 BRAF, 2 NRAS and one HRAS mutations were found, as well as one RET/PTC1 translocation. Results confirm international data showing that these oncogene mutations and translocations are linked to thyroid cancer. Cytological examination completed with genetic data may support the diagnosis of thyroid malignancies. In addition, genetic alterations may indicate malignant transformation and may become prognostic factors in future.

[Changes of gene expression and its role in pathogenesis in fibrous and non-fibrous dysplastic bone tissues in women]. / A génexpresszió változásai és patogenetikai jelentôségük fibrosus dysplasiás és nem fibrosus dysplasiás nôk csontszövetében.

UNLABELLED: Fibrous dysplasia is an isolated skeletal disorder caused by a somatic activating mutation of GNAS1 gene with abnormal unmineralized matrix overproduction and extensive undifferentiated bone cell accumulation in fibro-osseous lesions. The aim of the investigation was to identify genes that are differently expressed in fibrous vs. non-fibrous human bone and to describe the relationships between these genes using multivariate data analysis. MATERIALS AND METHODS: Six bone tissue samples from fibrous dysplastic female patients and 7 bone tissue samples from non-fibrous dysplastic women were examined. The 6 female fibrous samples were taken from the fibrous dysplastic lesion itself while the control samples of 7 non-fibrous dysplastic females were taken from the femoral neck during the hip replacement procedure. The expression differences of selected 118 genes were analyzed in TaqMan probe based quantitative real-time RT-PCR system. RESULTS: The Mann-Whitney U test indicated significant differences in the expression of 27 genes of fibrous dysplasial and non fibrous dysplasial individuals (p≤0.05). Nine genes were significantly up-regulated in fibrous dysplasial women compared to non fibrous dysplasial ones and eighteen genes showed a down-regulated pattern. These significantly altered genes coding for minor collagen molecules, extracellular matrix digesting enzymes, transcription factors, adhesion molecules, growth factors, pro-inflammatory cytokines and lipid metabolism-affected substrates. Canonical variety analysis demonstrated that fibrous dysplastic and non fibrous dysplastic bone tissues can be distinguished by the multiple expression profile analysis of numerous genes controlled via a G-protein coupled pathway and BMP cascade as well as genes coding for extracellular matrix composing molecules. CONCLUSIONS: The significantly altered gene expression profile observed in the fibrous dysplastic human bone tissue may provide further insight into the pathogenetic process of fibrous degeneration of bone.