I. E. Maslyukova scite author profile

I. E. Maslyukova

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Siberian Federal University

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Программное Обеспечение «minor Variant Finder» Как Инструмент Для Анализа Уровня Аллельной Нагрузки Соматическими Мутациями При Онкогематологических Заболеваниях

Maslyukova¹,

Karnyushka²,

Субботина³

et al. 2019

SJSA

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Соматическая мутация JAK2 c.1849 G>T (V617F) приводит к цитокин-независимому росту клеточных линий костного мозга. Она является одним из диагностических критерий хронических миелопролиферативных неоплазм. Секвенирование по Сэнгеру является золотым стандартом для анализа этой мутации, но имеет низкую чувствительность. Программное обеспечение «Minor Variant Finder» способно обнаружить мутацию при уровне аллельной нагрузки от 5%. Для проверки чувствительности ПО, были взяты ДНК 7-ми пациентов с ХМН с уже известным уровнем аллельной нагрузки. Секвенирование по Сэнгеру и анализ в «Minor Variant Finder» подтвердили заявленную чувствительность ПО.

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Comparison of fragment analysis and PCR electrophoresis methods for the detection of FLT3‑ITD mutations in patients with acute myeloid leukemia

Maslyukova

Kurochkin

Martynova³

et al. 2022

Onkogematologiâ

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Background. The presence of the FLT3-ITD mutations in patients with AML serves as a marker of poor prognosis, which is included in the ELN 2017 risk stratification guideline. The main criterion for dividing patients into groups according to the predicted outcomes was the allelic ratio (AR) with a cutoff of 0.5: an AR value <0.5 is considered low, and ≥0.5 is considered high. At the same time, if the importance of AR determination is beyond doubt, the value of information about the length of the repeat and localization is still controversial. There are two common approaches for FLT3-ITD screening. The first, more accessible and cheaper method is the method of pCR electrophoresis and the second, more expensive and requiring special equipment, is the fragment analysis method, which allows not only to detect a mutation and determine the repeat length, but also to quantify or calculate AR.Aim. To compare fragment analysis and pCR electrophoresis in the search for the FLT3-ITD mutations in dNA samples from AML patients.Materials and methods. for the period of 2020–2022 fragment analysis and pCR electrophoresis were used to analyze blood and/or bone marrow samples taken from 45 patients with a confirmed diagnosis of AML who were treated at the Regional Clinical Hospital (Krasnoyarsk). Confirmation and identification of the FLT3-ITD mutations was performed by means of Sanger sequencing.Results. both methods revealed the FLT3-ITD mutations in 11 (24.45 %) patients among the 45 patients studied. According to the results of fragment analysis, the median repeat length was 42.70 base pairs (range 26.01–99.84 base pairs), AR was 0.532 (0.027–3.328), and the allelic frequency (Af) was 34.71 (2.67–76.90) %. Three different ITds were identified in one sample. Sanger sequencing identified mutations in 9 of 11 patients.Conclusion. fragment analysis and pCR electrophoresis showed similar results when analyzing samples with different ITd lengths and with different allelic ratios. but it can be assumed that in the case of a small ITd and low AR and Af values, when using pCR electrophoresis, the mutant allele will not be visualized, which can lead to a false negative result. The disadvantage of using the pCR electrophoresis method is also that without the use of special programs that allow determining the size and intensity of the band corresponding to the mutant allele, it is impossible to determine the AR value, which is important for AML risk stratification. Thus, for detection of the FLT3-ITD we recommend using the fragment analysis method.

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Analysis of somatic mutations in the JAK2, CALR, MPL and ASXL1 genes and evaluation of their impact on the survival of patients with myelofibrosis

et al. 2023

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Background. The development of myelofibrosis (MF) is driven by complex molecular genetic events that include driver somatic mutations responsible for the constitutive activation of the JAK/STAT signaling pathway (JAK2, CALR, and MPL), additional mutations affecting epigenetic regulators (TET2, ASXL1, IDH1/2, etc.) and RNA splicing (SRSF2, U2AF1, SF3B1, etc.), as well as genetic aberrations that contribute to genomic instability and disease progression.Aim. To analyze driver (JAK2, CALR, MPL) and prognostic (ASXL1) somatic mutations in patients with MF and evaluate their impact on survival.Materials and methods. The study included 29 patients diagnosed with MF, selected by hematologists from the City Clinical Hospital No. 7 and Regional Clinical Hospital (Krasnoyarsk).Results. 26 (89.6 %) out of 29 examined patients had some driver mutations in JAK2, CALR, MPL genes. The p.V617F mutation in the JAK2 gene was found in 20 (68.9 %) patients. Mutations in the CALR gene were detected in 4 (13.8 %) patients, mutations in the MPL gene were found in 3 patients (10.3 %). In 1 of 26 patients, 2 driver mutations were present simultaneously. 3 (10.3 %) patients were triple negative. Mutations in the ASXL1 gene were detected in 12 (41.4 %) out of 29 examined patients. Conducted targeted NGS (next generation sequencing) for 13 out of 29 patients revealed additional genetic variants that contribute to the understanding of the development mechanism and disease course. When evaluating the overall survival in the groups of patients diagnosed with MF examined by us, depending on the combination of driver (JAK2, CALR, MPL) and prognostic (ASXL1) mutations, no statistically significant differences were found (p = 0.12). This appears to be due to the small sample size. At the same time, assessment of patient survival depending on ASXL1 status showed that in the presence of mutations in the ASXL1 gene, the median survival was 45 months (range 7–120 months), while in the absence of mutations it was 48 months (range 21–359 months) (p = 0.03).Conclusion. The results obtained allow us to assume that the presence of mutations in the ASXL1 gene is an unfavorable factor in the course of the disease.

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Screening of somatic mutations in the JAK2 and CALR genes by high-resolution melting curve analysis

et al. 2021

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Somatic mutations associated with oncological diseases, including Ph-myeloproliferative neoplasms (Ph-MPN), are very diverse, occur with different frequencies and different allelic burden levels. Therefore, at the initial stage of performing molecular-genetic diagnostic procedures, it is desirable to be able to conduct screening tests in the laboratory. This is especially important when analyzing rare and diverse mutations. Analysis of high resolution melting curves (HRM analysis), which has high sensitivity and is suitable for screening all types of mutations, in a number of studies is proposed for the analysis of Ph-MPN associated mutations in the JAK2 and CALR genes. For analysis of somatic mutations in the majority of literature sources that we reviewed, the authors use the LightCycler (Roche) thermocycler and much rarely the CFX96 (Bio-Rad), which is often presented in Russian scientific and practical and medical organizations. The aim of the study was to screen the somatic JAK2 and CALR mutations by HRM analysis using the CFX96 thermocycler and the Precision Melt Analysis software (Bio-Rad, USA) for patients with Ph-MPN. In the present research, HRM analysis was conducted on the DNA samples from patients with mutations in the JAK2 or in the CALR gene. The Precision Melt Analysis software identified all variants of the analyzed mutations, both a single nucleotide substitution in the JAK2 gene (with allelic burden level in the range of 5-40%), and various indel mutations in the CALR gene (with allelic burden level in the range of 40-50%) Therefore, the HRM analysis that was conducted on the CFX96 allows screening of highly specific mutation for the diagnosis of Ph-MPN in the exon 14 of the JAK2 gene and in the exon 9 of the CALR gene. The inclusion of this screening research in the laboratory testing algorithm improves the efficiency and accessibility of molecular genetic technologies in the diagnosis of Ph-MPN.

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P1056: Screening of Jak2 Exon 12 Somatic Mutations by High-Resolution Melting Curve Analysis

Kurochkin

Maslyukova

Субботина

et al. 2022

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I. E. Maslyukova

Программное Обеспечение «minor Variant Finder» Как Инструмент Для Анализа Уровня Аллельной Нагрузки Соматическими Мутациями При Онкогематологических Заболеваниях

Comparison of fragment analysis and PCR electrophoresis methods for the detection of FLT3‑ITD mutations in patients with acute myeloid leukemia

Analysis of somatic mutations in the <i>JAK2</i>, <i>CALR</i>, <i>MPL</i> and <i>ASXL1</i> genes and evaluation of their impact on the survival of patients with myelofibrosis

Screening of somatic mutations in the JAK2 and CALR genes by high-resolution melting curve analysis

P1056: Screening of Jak2 Exon 12 Somatic Mutations by High-Resolution Melting Curve Analysis

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