Association between coagulation factor levels, cytokine profiles, clinical manifestations and genotypic features in factor X deficiency

Thwala, Cyprian Mcwayizeni

25 March 2011

MSc (Med), Molecular Medicine and Haematology, Faculty of Health Sciences, University of the Witwatersrand / Factor X deficiency is a rare bleeding disorder with an incidence of one in a million in the general population. Patients with the severe form of factor X deficiency suffer from serious bleeds occurring mainly into the joints and the muscle. In the two factor X deficient families currently looked after at the Haemophilia Comprehensive Care Centre, there are definite differences in the bleeding tendencies between and within family members. We hypothesize the differences in genetic mutations and the influence of cytokines to be responsible for these bleeding variabilities. These factors were explored in our study. The study population included a total of fourteen members of the two families with factor X deficiency. Blood for factor X measurement, cytokine studies and genetic studies was collected in the Haemophilia Comprehensive Care Centre of the Charlotte Maxeke Johannesburg Academic Hospital. Each blood was processed according to the test to be performed. Factor X activity levels were measured using the factor X assay, and the information on each patient’s bleeding episodes was obtained from the Haemophiliac Clinic database. Cytokines were analyzed in all patients using the ELISA kits from Biosource. Factor X gene was amplified using PCR and sequenced with Spectrumedix SCE 2410. iv For cytokine studies, high levels of IL-1beta and TNF-alpha were observed in frequent bleeding patients compared to infrequent bleeders. These cytokines are known to be involved in acute inflammatory process leading to cellular infiltrate and joint swelling. This results in synovitis and the creation of massive joint bleeding. The low levels of IL-1beta and TNF-alpha detected in infrequent bleeding patients appear to be related to the high levels of IL-1Ra and IL-10. These anti-inflammatory cytokines are known to inhibit the inflammatory synovitis and lessen the severity of joint bleeding. For genetic studies, differences were observed between the amino acid sequence of the three frequent bleeding patients and the consensus. In addition, a novel mutation Cys350Phe was detected in two of these patients. This mutation is characterized by very low factor X levels which sometimes are not detectable in circulation. The substituted cystine is known to cause defect in the substrate binding, leading to the lost of enzyme activity. From these findings we have concluded that the origin of the heterogeneity of bleeding in factor X deficiency is multifactorial, cytokines and genetic mutations seems to have a role in determining the clinical manifestations of the factor X deficient patients.

factor X

bleeding disorder

genetic mutations

cytokines

The experience of prophylactic bilateral mastectomy in women to reduce the risk of breast cancer : an interpretative phenomenological analysis

Jones, Katharine

January 2013

Objectives: Increasing knowledge of genetics has found that a mutation to the BRCA 1 or 2 genes are associated with a high risk of developing breast cancer throughout the lifespan. A woman with this genetic mutation may consider preventive surgery to reduce the risk of breast cancer. This involves a prophylactic bilateral mastectomy to remove the breasts when there is no cancer present and may be followed by breast reconstruction. This study aimed to explore the lived experience and psycho-social impact on women of this surgery. Design: Interpretative phenomenological analysis was employed in an in-depth study of a small sample of eleven female patients with BRCA 1/2 genetic mutations who had undergone preventive surgery of prophylactic bilateral mastectomy. Methods: Semi-structured interviews were carried out. The transcripts of those interviews served as the data for an interpretative phenomenological analysis. Results and conclusions: Three themes were identified from the Interpretative Phenomenological Analysis to convey the lived experience of participants. These were (1) focus on reduced risk of cancer; taking control, relief and benefit finding, (2) a focus on relationships; family life, medical professional and BRCA support group and other women with lived experience, and (3) Focus on experiencing surgery and impact on self; the importance of reconstruction, loss of sexual attractiveness, impact on self from negative reaction of others and adjusting to surgical results. The implications are discussed in relation to the current literature and clinical practice.

616.89

Using Xenopus laevis to investigate developmental mechanisms underlying human neurodevelopmental disorders and intellectual disabilities:

Lasser, Micaela Cari

January 2020

Thesis advisor: Laura Anne Lowery / Thesis advisor: Sarah McMenamin / Development of the central nervous system (CNS) is a complex process that requires the proper function of many genes in order for neurons to proliferate and divide, differentiate, and subsequently migrate long distances to form connections with one another. Abnormalities in any one of these cellular processes can lead to detrimental developmental defects. Growing evidence suggests that genetic mutations caused by rare copy number variants (CNVs) are associated with neurodevelopmental disorders including intellectual disabilities (ID), Autism spectrum disorder (ASD), and schizophrenia. Additionally, these pathogenic CNVs are characterized by extensive phenotypic heterogeneity, as affected individuals often present with microcephaly, craniofacial and heart defects, growth retardation, and seizures. Despite their strong association as risk factors towards neurodevelopmental disorders, the developmental role of individual CNV-affected genes and disrupted cellular mechanisms underlying these mutations remains poorly understood. Moreover, it is unclear as to how the affected genes both individually and combinatorially contribute to the phenotypes associated with pathogenic CNVs. Thus, in this thesis, we explore the functional basis of phenotypic variability of pathogenic CNVs linked to neurodevelopmental disorders. In particular, we focus on the 3q29 deletion and 16p12.1 deletion, to provide insight towards the convergent cellular, molecular, and developmental mechanisms associated with decreased dosage of the affected gene homologs using two complementary model systems, Xenopus laevis and Drosophila melanogaster. First, we examine the role of individual homologs of several CNV-affected genes at chromosome 3q29 and their interactions towards cellular processes underlying the deletion. We find that multiple 3q29-affected genes, including NCBP2, DLG1, FBXO45, PIGZ, and BDH1, contribute to disruptions in apoptosis and cell cycle pathways, leading to neuronal and developmental defects. We then expand further upon this work by discerning the individual contribution of four CNV-affected genes at chromosome 16p12.1, POLR3E, MOSMO, UQCRC2, and CDR2, towards neurodevelopment and craniofacial morphogenesis. We demonstrate that several of these genes affect multiple phenotypic domains during neurodevelopment leading to brain size alterations, abnormal neuronal morphology, and cellular proliferation defects. We then explore their functions during vertebrate craniofacial morphogenesis and demonstrate that some 16p12.1-affected genes are enriched in migratory neural crest, and contribute to early craniofacial patterning and formation of cartilaginous tissue structures. Together, these data are the first to suggest that signature neurodevelopmental phenotypes demonstrated in the 3q29 deletion and 16p12.1 deletion may stem from convergent cellular mechanisms including aberrations in neuronal proliferation, apoptosis and cell cycle regulation, and neural crest cell development. / Thesis (PhD) — Boston College, 2020. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

Xenopus laevis

Neurodevelopmental disorders

Intellectual disabilities

Genetic mutations

Regulation of the MEK/ERK signaling cascade by ADAM12 in triple-negative breast cancer cells

Hodge, Jacob G.

January 1900

Master of Science / Biochemistry and Molecular Biophysics Interdepartmental Program / Anna Zolkiewska / Mitogen-activated protein kinase (MAPK) signaling plays an important role in the proliferation, survival, and therapy resistance of breast cancer cells. Two important protein kinases involved in the MAPK pathway are MEK and ERK. The MEK/ERK signaling cascade can be stimulated by activation of the epidermal growth factor receptor (EGFR) upon binding of EGF-like ligands, which are released from cells by ADAM proteases. EGFR is frequently overexpressed in triple-negative breast cancer (TNBC), a particularly aggressive form of breast cancer. Our analysis of clinical data revealed that high expression of ADAM12, but not other ADAMs, in TNBC is associated with poor patient survival. Thus, we hypothesized that ADAM12 plays a critical role in the progression of TNBC, possibly by stimulating MEK/ERK activity in an EGFR-dependent manner. To test this hypothesis, ADAM12 was knocked-down (KD) in SUM159PT TNBC cells, which express high levels of the endogenous ADAM12 protein. An antibody array assay indicated a significant decrease in the activation of the MAPK pathway in SUM159PT cells after ADAM12 KD. The decrease in MAPK activity was further confirmed by Western blotting using phospho-MEK and phospho-ERK specific antibodies. Additionally, conditioned media from ADAM12-deficient SUM159PT cells failed to support the survival of MCF10A cells, suggesting that ADAM12 KD reduced the release of pro-survival growth factors from SUM159PT cells. Based upon this data, we propose that ADAM12 is a novel regulator of the MAPK pathway and a potential therapeutic target in breast cancer.

Breast cancer

Cell signaling

Protein chemistry

Stem cells

Genetic mutations

Membrane receptors

Biophysical modelling of functional impacts of potassium channel mutations on human atrial and ventricular dynamics

Ni, Haibo

January 2017

Atrial fibrillation (AF) is the most common cardiac arrhythmia causing morbidity and mortality. Despite recent advances, developing effective and safe anti-AF pharmaceutical therapies remains challenging and is prone to adverse effects in the ventricles. Atrial-selective therapies are promising in managing AF. A better understanding of the role of the atrial-specific ion channels in the atrial arrhythmogenesis and contractility, as well as the anti-AF effects of blocking these channels is of interests. Also, a 3D ventricle-torso model capable of modelling ventricular electrical activities and the resulting electrocardiogram (ECG) is a valuable tool in evaluating the selectiveness and safety of an anti-AF pharmaceutical therapy. In part I, the role of an atrial-specific ion channel, IKur, in atrial electrical and mechanical activities and the potential of the current as a pharmaceutical target for anti-AF therapies were investigated in silico. The role of IKur in atrial arrhythmogenesis and mechanical contraction was revealed by elucidating the functional impacts of the KCNA5 mutations exerting either gain- or loss-in-function, on the atria. First, novel IKur models were developed and incorporated into multiscale biophysical models of human atrial electrophysiology to assess the effects of mutated IKur on atrial electrical dynamics. Then, a family of single cell human atrial electromechanical models was developed and incorporated into an updated 3D anatomical electromechanical model of human atria to clarify the effects of mutated IKur on the atrial contractile function. Finally, the antiarrhythmic effect of IKur block was assessed together with INa and other K+-current block. It was shown that the gain-of-function in IKur impaired atrial contractility and promoted atrial arrhythmogenesis by shortening the APD, whereas the down-regulated IKur exerted positive inotropic effects and increased the susceptibility of the atria to the genesis of early-afterdepolarisations. Both simulated IKur and INa block in human-AF demonstrated antiarrhythmic effects; the multi-channel block exerted synergistic anti-AF effects and enhanced the AF-selectivity of INa inhibitions. In Part II, a human ventricle-torso model was developed through proposing a new family of single cell ventricular models accounting for transmural, apicobasal and interventricular electrical heterogeneities and integrating an updated 3D biophysical and anatomical model of human ventricles with a heterogeneous anatomical model of a human torso. First, using the model, the role of heterogeneities in the genesis of T-wave was revealed. Then, ECG manifestations of bundle branch block and ventricular ischaemia were simulated. Finally, the platform was applied to investigate the impact of a long-QT-linked mutation (KCNQ1-G269S) on the ventricles and ECG. Good agreement between simulated and experimental/clinical ECG was reached under both normal and diseased conditions. It was shown that the apicobasal heterogeneity had a more pronounced effect on the T-wave than other heterogeneities. Simulations of the KCNQ1-G269S elucidated the causal link between the mutation and ECG manifestations of the patients.

500

Roles of ADAM12 in triple-negative breast cancer: regulation of cancer stem cells

Qi, Yue

January 1900

Doctor of Philosophy / Biochemistry and Molecular Biophysics Interdepartmental Program / Anna Zolkiewska / ADAM12 (A Disintegrin and Metalloprotease 12) is a cell surface protease, which is deregulated in many human diseases. High expression of ADAM12 in triple-negative breast cancers (lacking estrogen receptor, progesterone receptor, and HER2 expression) is associated with poor patient prognosis. My dissertation focused on the understanding of the biological functions of ADAM12 in triple-negative breast cancers. I found that ADAM12 is significantly upregulated in the claudin-low molecular subtype of breast cancer. Claudin-low tumors are typically triple-negative and are enriched in cancer stem cells. Here, I demonstrated that the loss of ADAM12 expression not only decreased the number of cancer stem-like cells in vitro but also significantly compromised the tumor-initiating capabilities of breast cancer cells in vivo. This is the first evidence showing that ADAM12 might regulate the cancer stem cell-like phenotype in triple-negative breast cancers. I also discovered a novel mechanism of ADAM12-regulated signaling by transforming growth factor β (TGFβ) through modulation of TGFBR1 mRNA expression in breast cancer cells. Lastly, I characterized the effects of six different somatic mutations in the ADAM12 gene found in human breast cancers on the intracellular trafficking, post-translational processing, and function of ADAM12 protein. Collectively, the findings of this study support the notion that ADAM12 with catalytically active metalloprotease domain is required for the progression of triple-negative breast cancers.

Breast cancer

Cell signaling

Protein chemistry

Stem cells

Genetic mutations

Membrane receptors

Význam genetických mutací u karcinomu prsu / The Role of Genetic Mutations in Breast Cancer

Šustr, Jan

January 2022

Introduction: About 5 - 10% of breast carcinomas are caused by genetic mutations. The most common genetic mutation that is involved in the development of this malignancy is a mutation in the tumor suppressor genes BRCA1/2 whose carriers have approximately a 70% lifetime risk of developing breast cancer. The prognosis of patients with BRCA1/2-asociated breast carcinoma, compared to patients with sporadic breast carcinoma is the subject of many studies with ambiguous results. Aim: The aim of the theoretical part of this work was to approach the issue of breast cancer and the most common genetic syndromes associated with it. In the practical part of this work a retrospective study was carried out in order to compare BRCA1/2 mutated breast cancer patients with non-mutated breast cancer patients in the tumor profile, methods of treatment and prognosis. Methods: We retrospectively analyzed the data of 134 patients who were tested for the presence of BRCA1/2 mutation at the Institute of Medical Genetics, University Hospital in Pilsen during the years 2013-2018 and at the same time were treated for early breast cancer at the University Hospital in Pilsen during the years 2000-2020. 32 patients were BRCA1 positive (24%), 10 BRCA2 positive (7%) and 92 without BRCA1/2 mutation (69%). The follow- up time was...

Identification of mechanisms regulating the intra cellular concentration of rifampicin in Mycobacterium Tuberculosis

De Vos, Margaretha

03 1900

Thesis (PhD)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: Rifampicin resistance in clinical isolates of Mycobacterium tuberculosis develops through selection of bacterial variants harbouring mutations in the rpoB gene. These mutations infer a fitness-cost in the absence of antibiotic pressure, however, fitness-levels of rifampicin-resistant strains can be restored by compensatory mutations in rpoA and rpoC. This study was the first to investigate the epidemiological relevance of these compensatory mutations in clinical M. tuberculosis isolates collected in South Africa. Through targeted DNA sequencing, we demonstrated a strong association between rpoC mutations and transmission, and the rpoB S531L mutation. Our study emphasises the epidemiological relevance of compensatory evolution in response to the emergence of rifampicin resistance, and illustrates how compensatory mutations may be selected as a function of epistatic interactions. Recently a hypothesis has been developed which suggests that the activation of efflux systems through exposure to rifampicin may explain the observed spectrum of rifampicin resistance phenotypes. To elucidate whether rifampicin dependent activation of efflux systems also increases energy production, the RNA expression profiles of candidate energy metabolism genes were investigated. This study demonstrated that rifampicin exposure induced an overall increase in the expression of energy metabolism genes. Our findings suggest that the response to rifampicin is not universal and may depend on other genomic mutations. From these results we conclude that the stress response induced by exposure to rifampicin increases the energy production which fuels efflux activity thereby enabling the cell to extrude rifampicin in an energy dependent manner. This also provides a platform to explain the mechanism by which the newly developed drug, TMC207, increases the rate of culture conversion when used in combination with second-line anti-TB drugs. We propose that inhibition of ATP synthesis by TMC207 will deprive the efflux pumps and transporter genes of energy, which will result in the accumulation of second-line anti-TB drugs within the bacilli, leading to more efficient binding of the second-line drugs to their targets and ultimately to cell death. To identify the genetic basis governing the level of rifampicin resistance, we sequenced the genomes of MDR clinical isolates and in vitro generated rifampicin resistant mutants. Only minor genetic changes in addition to the rpoB mutation were identified in the genomes of in vitro rifampicin resistant mutants which displayed varying levels of resistance. This suggests that these mutants may either use alternative regulatory mechanisms or have acquired SNPs outside the genetic regions investigated in this study to modulate rifampicin resistance levels. In contrast, the genomes of clinical MDR isolates from the Low Copy Clade showed considerable variability in genes involved in cell wall, cellular processes and lipid metabolism, while the genomes from the Beijing Clade displayed variability in genes known to confer drug resistance and compensatory mechanisms. These results suggest that the structure and processes of the cell wall, as well as lipid metabolism plays a critical role in determining the intra-cellular concentration of rifampicin. Finally, this study illustrated the complexity in the physiology of M. tuberculosis resistant to rifampicin, whereby multiple mechanisms are employed by the bacteria to modulate its resistance levels. / AFRIKAANSE OPSOMMING: Rifampisien weerstandigheid in kliniese isolate van Mycobacterium tuberculosis ontwikkel deur die seleksie van bakteriële variante wat mutasies in die rpoB geen het. Alhoewel hierdie mutasies lei tot „n afname in fiksheid van die bakterieë in die teenwoordigheid van antibiotika, kan die fiksheids vlakke van rifampisien weerstandige stamme herstel word deur vergoedende mutasies in rpoA en rpoC. Hierdie is die eerste studie wat die epidemiologiese relevansie van hierdie vergoedende mutasies in kliniese M. tuberculosis isolate wat in Suid-Afrika versamel is, ondersoek. Deur middel van doelgerigte DNA volgordebepaling het ons „n sterk assosiasie tussen rpoC mutasies en transmissie, en die rpoB S31L mutasie getoon. Hierdie studie beklemtoon die epidemiologiese relevansie van regstellende evolusie na aanleiding van die ontwikkeling van rifampisien weerstandigheid en illustreer hoe regstellende mutasies geselekteer mag word as „n funksie van epistatiese interaksies. „n Hipotese is onlangs ontwikkel wat voorstel dat blootstelling aan rifampisien uitvloei sisteme in die bakterium aktiveer, wat moontlik die waargenome spektrum van rifampisien weerstandige fenotipes kan verklaar. Ons het die RNA uitdrukkingsprofiele van kandidaat-energiemetabolisme gene ondersoek om te bepaal of rifampisien afhanklike aktivering van uitvloei sisteme ook energieproduksie verhoog. Hierdie studie demonstreer dat rifampisien-blootstelling „n algehele verhoging in die uitdrukking van energiemetabolisme gene induseer. Ons bevindinge stel voor dat die reaksie van die sel op rifampisien blootstelling nie universeel is nie, en moontlik ook afhanklik is van ander genomiese mutasies. Uit hierdie resultate kan ons aflei dat die stres respons wat geïnduseer word deur rifampisien-blootstelling energieproduksie verhoog, wat weer die uitvloei aktiwiteit aanvuur, en gevolglik die sel in staat stel om rifampisien op „n energie-afhanklike wyse uit te dryf. Dit bied ook „n basis om die meganisme te verklaar waardeur die nuwe middel, TMC207, die tempo van kultuuromskakeling verhoog wanneer dit saam met tweede-linie anti-TB middels gebruik word. Ons stel voor dat die inhibisie van ATP sintese deur TMC207 die uitvloeipompe en transporteerder gene van energie ontneem. Gevolglik veroorsaak dit „n ophoping van tweedelinie anti-TB middels binne-in die bakterium, wat geleentheid bied vir meer effektiewe binding tussen die middels en hulle teikens en uiteindelik seldood veroorsaak. Ons het DNA volgordes bepaal van die genome van MDR kliniese isolate en in vitro selekteerde rifampisienweerstandige mutante om sodoende die genetiese grondslag waarop die vlak van rifampisienweerstandigheid beheer word, te identifiseer. Slegs klein verskille, bo en behalwe die rpoB mutasie, is geïdentifiseer in die genome van in vitro rifampisien weerstandige mutante wat verskillende vlakke van weerstandigheid getoon het. Dit dui aan dat hierdie mutante of ander regulatoriese meganismes gebruik, of hulle het enkelnukleotied polimorfismes buite die genetiese area wat in hierdie studie ondersoek is, waarmee rifampisien weerstandigheid gemoduleer word. In teenstelling hiermee het die genome van kliniese MDR isolate van die “Low Copy Clade” aansienlike variasie getoon in gene wat betrokke is by die selwand, sellulêre prosesse en lipiedmetabolisme. Verder het die genome van die Beijing genotipe variasie in gene getoon wat betrokke is by middelweerstandigheid en regstellende meganismes. Hierdie resultate dui aan dat die struktuur en prosesse van die selwand, asook lipiedmetabolisme, „n kritiese rol speel in die bepaling van die intrasellulêre konsentrasie van rifampisien. Opsommend, hierdie studie toon verskeie meganismes aan wat deur die bakterieë gebruik word om weerstandigheidsvlakke te moduleer en die kompleksiteit van die fisiologie van M. tuberculosis wat weerstandig is teen rifampisien. / The National Research Foundation (NRF) / South African Medical Research Council (MRC) / Harry Crossley Foundation

Mycobacterium tuberculosis

Rifampicin resistance -- Research

Genetic mutations

Theses -- Medicine

Dissertations -- Medicine

Theses -- Molecular biology

Dissertations -- Molecular biology

Biomedical Sciences

MicroRNAs como biomarcadores no carcinoma papilífero de tireóide: associação com mutações somáticas frequentes e significado biológico. / MicroRNAs as biomarkers in papillary thyroid cancer: association with frequent somatic mutations and biological significance.

Moulatlet, Ana Carolina Bernardini

24 February 2014

Os microRNAs são pequenos RNAs importantes na modulação da expressão gênica. O carcinoma papilífero de tireoide (CPT) é responsável pela maior parte dos casos de câncer de tireoide. Mutações somáticas ativam as vias de MAPK e PI3K/AKT e exercem papel importante no desenvolvimento do CPT. Acredita-se que miRNAs regulem genes associados a essas vias. A expressão de miRNAs foi avaliada em amostras parafinadas de CPT caracterizadas quanto à presença da mutação BRAFV600E. A expressão de miRNAs variou devido à heterogeneidade dos tecidos emblocados e entre pacientes, dados importantes quando microRNAs são avaliados como biomarcadores. Microarranjos de DNA mostraram diferenças na expressão de miR-16, miR-19a, miR-21, miR146a, miR-146b, miR-221 e miR-222 entre amostras positivas e negativas para BRAFV600E, indicando um possível papel na modulação de vias influenciadas por esta mutação. Quando amostras adicionais foram analisadas, apenas miR-146b apresentou expressão diferencial entre os dois grupos, ressaltando a variabilidade entre pacientes quanto à expressão de miRNAs. / MicroRNAs are small non-coding RNAs that regulate protein-coding genes. Papillary thyroid cancer (PTC) accounts for most of the thyroid cancer cases. Somatic mutations activate MAPK and PI3K/AKT pathways and play a leading role in PTC. MiRNAs may contribute to the regulation of these pathways. We studied the expression of miRNAs in formalin-fixed, paraffin-embedded (FFPE) PTC samples submitted to mutation characterization. Our results show that miRNA expression varies due to embedded sample heterogeneity and that there is great variability in miRNA expression among patients, both important issues when miRNA expression is evaluated as a biomarker. DNA microarray experiments compared BRAFV600E positive and negative samples. MiR-16, miR-19a miR-21, miR146a, MiR-146b, miR-221 and miR-222 were deregulated, indicating a possible implication in BRAF-related pathways. When additional samples were evaluated, only miR-146b presented consistent variation in expression, highlighting variability among patients

Biomarcadores

Biomarkers

Carcinoma papilar

Expressão gênica

Gene expression

Genetic mutations

Glândula tireóide

Mutações genéticas

Papillary carcinoma

Thyroid gland

MicroRNAs como biomarcadores no carcinoma papilífero de tireóide: associação com mutações somáticas frequentes e significado biológico. / MicroRNAs as biomarkers in papillary thyroid cancer: association with frequent somatic mutations and biological significance.

Ana Carolina Bernardini Moulatlet

24 February 2014

Os microRNAs são pequenos RNAs importantes na modulação da expressão gênica. O carcinoma papilífero de tireoide (CPT) é responsável pela maior parte dos casos de câncer de tireoide. Mutações somáticas ativam as vias de MAPK e PI3K/AKT e exercem papel importante no desenvolvimento do CPT. Acredita-se que miRNAs regulem genes associados a essas vias. A expressão de miRNAs foi avaliada em amostras parafinadas de CPT caracterizadas quanto à presença da mutação BRAFV600E. A expressão de miRNAs variou devido à heterogeneidade dos tecidos emblocados e entre pacientes, dados importantes quando microRNAs são avaliados como biomarcadores. Microarranjos de DNA mostraram diferenças na expressão de miR-16, miR-19a, miR-21, miR146a, miR-146b, miR-221 e miR-222 entre amostras positivas e negativas para BRAFV600E, indicando um possível papel na modulação de vias influenciadas por esta mutação. Quando amostras adicionais foram analisadas, apenas miR-146b apresentou expressão diferencial entre os dois grupos, ressaltando a variabilidade entre pacientes quanto à expressão de miRNAs. / MicroRNAs are small non-coding RNAs that regulate protein-coding genes. Papillary thyroid cancer (PTC) accounts for most of the thyroid cancer cases. Somatic mutations activate MAPK and PI3K/AKT pathways and play a leading role in PTC. MiRNAs may contribute to the regulation of these pathways. We studied the expression of miRNAs in formalin-fixed, paraffin-embedded (FFPE) PTC samples submitted to mutation characterization. Our results show that miRNA expression varies due to embedded sample heterogeneity and that there is great variability in miRNA expression among patients, both important issues when miRNA expression is evaluated as a biomarker. DNA microarray experiments compared BRAFV600E positive and negative samples. MiR-16, miR-19a miR-21, miR146a, MiR-146b, miR-221 and miR-222 were deregulated, indicating a possible implication in BRAF-related pathways. When additional samples were evaluated, only miR-146b presented consistent variation in expression, highlighting variability among patients

Biomarcadores

Carcinoma papilar

Expressão gênica

Glândula tireóide

Mutações genéticas

Biomarkers

Gene expression

Genetic mutations

Papillary carcinoma

Thyroid gland