Your search keyword '"Rutkowska, Lena"' showing total 12 results

1. Clinical reality and challenges with familial hypercholesterolemia patients' management. 2024 results from the Regional Center for Rare Diseases (RCRD) Registry in Poland

Author

Lewek, Joanna, Sosnowska, Bożena, Starostecka, Ewa, Konopka, Agnieszka, Gach, Agnieszka, Rutkowska, Lena, Adach, Weronika, Mierczak, Karina, Bielecka-Dąbrowa, Agata, and Banach, Maciej

Published

2025

2. Is Nuchal Translucency of 3.0–3.4 mm an Indication for cfDNA Testing or Microarray? – A Multicenter Retrospective Clinical Cohort Study.

Author

Rybak-Krzyszkowska, Magda, Madetko-Talowska, Anna, Szewczyk, Katarzyna, Bik-Multanowski, Mirosław, Sakowicz, Agata, Stejskal, David, Trková, Marie, Smetanová, Dagmar, Serafim, Sílvia, Correia, Hildeberto, Nevado, Julian, Angeles Mori, Maria, Mansilla, Elena, Rutkowska, Lena, Kucińska, Agata, Gach, Agnieszka, Huras, Hubert, Kołak, Magdalena, and Srebniak, Malgorzata Ilona

Subjects

CHROMOSOME abnormalities, SEX chromosomes, PRENATAL diagnosis, DOWN syndrome, CELL-free DNA

Abstract

Introduction: This study aimed to evaluate the occurrence of clinically relevant (sub)microscopic chromosomal aberrations in fetuses with the nuchal translucency (NT) range from 3.0 to 3.4 mm, which would be potentially missed by cfDNA testing. Methods: A retrospective data analysis of 271 fetuses with NT between 3.0 and 3.4 mm and increased first trimester combined test (CT) risk in five cohorts of pregnant women referred for invasive testing and chromosomal microarray was performed. Results: A chromosomal aberration was identified in 18.8% fetuses (1:5; 51/271). In 15% (41/271) of cases, trisomy 21, 18, or 13 were found. In 0.7% (2/271) of cases, sex chromosome aneuploidy was found. In 1.1% (3/271) of cases, CNV >10 Mb was detected, which would potentially also be detected by genome-wide cfDNA testing. The residual risk for missing a submicroscopic chromosome aberration in the presented cohorts is 1.8% (1:54; 5/271). Conclusion: Our results indicate that a significant number of fetuses with increased CT risk and presenting NT of 3.0–3.4 mm carry a clinically relevant chromosomal abnormality other than common trisomy. Invasive testing should be offered, and counseling on NIPT should include the test limitations that may result in NIPT false-negative results in a substantial percentage of fetuses. [ABSTRACT FROM AUTHOR]

Published

2024

3. “Apple does not fall far from the tree” – subclinical atherosclerosis in children with familial hypercholesterolemia

Author

Podgórski, Michał, Szatko, Katarzyna, Stańczyk, Małgorzata, Pawlak-Bratkowska, Monika, Konopka, Agnieszka, Starostecka, Ewa, Tkaczyk, Marcin, Góreczny, Sebastian, Rutkowska, Lena, Gach, Agnieszka, Łukaszewski, Maciej, Grzelak, Piotr, and Banach, Maciej

Published

2020

4. The Use of CGH Arrays for Identifying Copy Number Variations in Children with Autism Spectrum Disorder.

Author

Kucińska, Agata, Hawuła, Wanda, Rutkowska, Lena, Wysocka, Urszula, Kępczyński, Łukasz, Piotrowicz, Małgorzata, Chilarska, Tatiana, Wieczorek-Cichecka, Nina, Połatyńska, Katarzyna, Przysło, Łukasz, and Gach, Agnieszka

Subjects

CHILDREN with autism spectrum disorders, COMMUNICATIVE disorders, AUTISM spectrum disorders, COMPARATIVE genomic hybridization, DNA copy number variations

Abstract

Autism spectrum disorders (ASDs) encompass a broad group of neurodevelopmental disorders with varied clinical symptoms, all being characterized by deficits in social communication and repetitive behavior. Although the etiology of ASD is heterogeneous, with many genes involved, a crucial role is believed to be played by copy number variants (CNVs). The present study examines the role of copy number variation in the development of isolated ASD, or ASD with additional clinical features, among a group of 180 patients ranging in age from two years and four months to 17 years and nine months. Samples were taken and subjected to array-based comparative genomic hybridization (aCGH), the gold standard in detecting gains or losses in the genome, using a 4 × 180 CytoSure Autism Research Array, with a resolution of around 75 kb. The results indicated the presence of nine pathogenic and six likely pathogenic imbalances, and 20 variants of uncertain significance (VUSs) among the group. Relevant variants were more prevalent in patients with ASD and additional clinical features. Twelve of the detected variants, four of which were probably pathogenic, would not have been identified using the routine 8 × 60 k microarray. These results confirm the value of microarrays in ASD diagnostics and highlight the need for dedicated tools. [ABSTRACT FROM AUTHOR]

Published

2024

5. NGS analysis of collagen type I genes in Polish patients with Osteogenesis imperfecta: a nationwide multicenter study.

Author

Sałacińska, Kinga, Pinkier, Iwona, Rutkowska, Lena, Chlebna-Sokół, Danuta, Jakubowska-Pietkiewicz, Elżbieta, Michałus, Izabela, Kępczyński, Łukasz, Salachna, Dominik, Wieczorek-Cichecka, Nina, Piotrowicz, Małgorzata, Chilarska, Tatiana, Jamsheer, Aleksander, Matusik, Paweł, Wilk, Małgorzata, Petriczko, Elżbieta, Giżewska, Maria, Stecewicz, Iwona, Walczak, Mieczysław, Rybak-Krzyszkowska, Magda, and Lewiński, Andrzej

Subjects

OSTEOGENESIS imperfecta, COLLAGEN, GENETIC variation, CONNECTIVE tissues, NUCLEOTIDE sequencing

Abstract

Osteogenesis imperfecta (OI) is a rare genetic disorder of the connective tissue. It presents with a wide spectrum of skeletal and extraskeletal features, and ranges in severity from mild to perinatal lethal. The disease is characterized by a heterogeneous genetic background, where approximately 85%-90% of cases have dominantly inherited heterozygous pathogenic variants located in the COL1A1 and COL1A2 genes. This paper presents the results of the first nationwide study, performed on a large cohort of 197 Polish OI patients. Variants were identified using a next-generation sequencing (NGS) custom gene panel and multiplex ligation probe amplification (MLPA) assay. The following OI types were observed: 1 (42%), 2 (3%), 3 (35%), and 4 (20%). Collagen type I pathogenic variants were reported in 108 families. Alterations were observed in a1 and a2 in 70% and 30% of cases, respectively. The presented paper reports 97 distinct causative variants and expands the OI database with 38 novel pathogenic changes. It also enabled the identification of the first glycine- to-tryptophan substitution in the COL1A1 gene and brought new insights into the clinical severity associated with variants localized in "lethal regions". Our results contribute to a better understanding of the clinical and genetic aspects of OI. [ABSTRACT FROM AUTHOR]

Published

2023

6. Identification of New Copy Number Variation and the Evaluation of a CNV Detection Tool for NGS Panel Data in Polish Familial Hypercholesterolemia Patients.

Author

Rutkowska, Lena, Pinkier, Iwona, Sałacińska, Kinga, Kępczyński, Łukasz, Salachna, Dominik, Lewek, Joanna, Banach, Maciej, Matusik, Paweł, Starostecka, Ewa, Lewiński, Andrzej, Płoski, Rafał, Stawiński, Piotr, and Gach, Agnieszka

Subjects

*FAMILIAL hypercholesterolemia, *PANEL analysis, *FRAMESHIFT mutation, *CHILD patients, *SINGLE nucleotide polymorphisms, *GENETIC testing

Abstract

Familial hypercholesterolemia (FH) is an inherited, autosomal dominant metabolic disorder mostly associated with disease-causing variant in LDLR, APOB or PCSK9. Although the dominant changes are small-scale missense, frameshift and splicing variants, approximately 10% of molecularly defined FH cases are due to copy number variations (CNVs). The first-line strategy is to identify possible pathogenic SNVs (single nucleotide variants) using multiple PCR, Sanger sequencing, or with more comprehensive approaches, such as NGS (next-generation sequencing), WES (whole-exome sequencing) or WGS (whole-genome sequencing). The gold standard for CNV detection in genetic diagnostics are MLPA (multiplex ligation-dependent amplification) or aCGH (array-based comparative genome hybridization). However, faster and simpler analyses are needed. Therefore, it has been proposed that NGS data can be searched to analyze CNV variants. The aim of the study was to identify novel CNV changes in FH patients without detected pathogenic SNVs using targeted sequencing and evaluation of CNV calling tool (DECoN) working on gene panel NGS data; the study also assesses its suitability as a screening step in genetic diagnostics. A group of 136 adult and child patients were recruited for the present study. The inclusion criteria comprised at least "possible FH" according to the Simon Broome diagnostic criteria in children and the DLCN (Dutch Lipid Clinical Network) criteria in adults. NGS analysis revealed potentially pathogenic SNVs in 57 patients. Thirty selected patients without a positive finding from NGS were subjected to MLPA analysis; ten of these revealed possibly pathogenic CNVs. Nine patients were found to harbor exons 4–8 duplication, two harbored exons 6–8 deletion and one demonstrated exon 9–10 deletion in LDLR. To test the DECoN program, the whole study group was referred for bioinformatic analysis. The DECoN program detected duplication of exons 4–8 in the LDLR gene in two patients, whose genetic analysis was stopped after the NGS step. The integration of the two methods proved to be particularly valuable in a five-year-old girl presenting with extreme hypercholesterolemia, with both a pathogenic missense variant (c.1747C>T) and exons 9–10 deletion in LDLR. This is the first report of a heterozygous deletion of exons 9 and 10 co-occurring with SNV. Our results suggest that the NGS-based approach has the potential to identify large-scale variation in the LDLR gene and could be further applied to extend CNV screening in other FH-related genes. Nevertheless, the outcomes from the bioinformatic approach still need to be confirmed by MLPA; hence, the latter remains the reference method for assessing CNV in FH patients. [ABSTRACT FROM AUTHOR]

Published

2022

7. The first glycine‐to‐tryptophan substitution in the COL1A1 gene identified in a patient with progressively‐deforming Osteogenesis imperfecta.

Author

Sałacińska, Kinga, Michałus, Izabela, Pinkier, Iwona, Rutkowska, Lena, Chlebna‐Sokół, Danuta, Jakubowska‐Pietkiewicz, Elżbieta, Kępczyński, Łukasz, Salachna, Dominik, and Gach, Agnieszka

Subjects

OSTEOGENESIS imperfecta, CONNECTIVE tissues, GENETIC disorders, GENES, RARE diseases

Abstract

Background: Osteogenesis imperfecta (OI) is a genetic disorder of connective tissue with variable phenotype and heterogeneous genetic background. Majority of reported mutations are glycine substitutions, whose clinical outcome ranges from mild to perinatal lethal. The phenotype appears to be influenced by the properties of amino acid side chain and the degree of structural aberration of collagen molecules. Since the genotype–phenotype correlation remains unclear, the severity of mutation is mostly predicted according to previously‐reported cases. Although the number of OI variants is constantly expanding, no glycine‐to‐tryptophan substitutions have been reported in COL1A1 gene. Methods: A sample from a 15‐year‐old girl presenting with progressively‐deforming OI type III was tested using an NGS custom gene panel. Multiple bioinformatic and interpretation tools, including mutation databases and conservation analysis, were used for variant classification. The presence of the mutation was verified by Sanger sequencing. Results: A novel heterozygous mutation c.733G>T was identified in the COL1A1 gene (p.Gly245Trp). Conclusions: The discovery of this novel glycine‐to‐tryptophan substitution located in the COL1A1 gene broadens the spectrum of mutations underlying this rare disease and provides useful information on the clinical outcome of such substitutions. [ABSTRACT FROM AUTHOR]

Published

2022

8. Identification of New Genetic Determinants in Pediatric Patients with Familial Hypercholesterolemia Using a Custom NGS Panel.

Author

Rutkowska, Lena, Sałacińska, Kinga, Salachna, Dominik, Matusik, Paweł, Pinkier, Iwona, Kępczyński, Łukasz, Piotrowicz, Małgorzata, Starostecka, Ewa, Lewiński, Andrzej, and Gach, Agnieszka

Subjects

*FAMILIAL hypercholesterolemia, *CHILD patients, *FRAMESHIFT mutation, *LDL cholesterol, *GENETIC variation, *FRAGILE X syndrome

Abstract

The most common form of inherited lipid disorders is familial hypercholesterolemia (FH). It is characterized primarily by high concentrations of the clinical triad of low-density lipoprotein cholesterol, tendon xanthomas and premature CVD. The well-known genetic background are mutations in LDLR, APOB and PCSK9 gene. Causative mutations can be found in 60–80% of definite FH patients and 20–30% of those with possible FH. Their occurrence could be attributed to the activity of minor candidate genes, whose causal mechanism has not been fully discovered. The aim of the conducted study was to identify disease-causing mutations in FH-related and candidate genes in pediatric patients from Poland using next generation sequencing (NGS). An NGS custom panel was designed to cover 21 causative and candidate genes linked to primary dyslipidemia. Recruitment was performed using Simon Broome diagnostic criteria. Targeted next generation sequencing was performed on a MiniSeq sequencer (Illumina, San Diego, CA, USA) using a 2 × 150 bp paired-end read module. Sequencing data analysis revealed pathogenic and possibly pathogenic variants in 33 out of 57 studied children. The affected genes were LDLR, APOB, ABCG5 and LPL. A novel pathogenic 7bp frameshift deletion c.373_379delCAGTTCG in the exon 4 of the LDLR gene was found. Our findings are the first to identify the c.373_379delCAGTTCG mutation in the LDLR gene. Furthermore, the double heterozygous carrier of frameshift insertion c.2416dupG in the LDLR gene and missense variant c.10708C>T in the APOB gene was identified. The c.2416dupG variant was defined as pathogenic, as confirmed by its cosegregation with hypercholesterolemia in the proband's family. Although the APOB c.10708C>T variant was previously detected in hypercholesterolemic patients, our data seem to demonstrate no clinical impact. Two missense variants in the LPL gene associated with elevated triglyceride plasma level (c.106G>A and c.953A>G) were also identified. The custom NGS panel proved to be an effective research tool for identifying new causative aberrations in a genetically heterogeneous disease as familial hypercholesterolemia (FH). Our findings expand the spectrum of variants associated with the FH loci and will be of value in genetic counseling among patients with the disease. [ABSTRACT FROM AUTHOR]

Published

2022

9. Familial Partial Lipodystrophy—Literature Review and Report of a Novel Variant in PPARG Expanding the Spectrum of Disease-Causing Alterations in FPLD3.

Author

Rutkowska, Lena, Salachna, Dominik, Lewandowski, Krzysztof, Lewiński, Andrzej, and Gach, Agnieszka

Subjects

*LIPODYSTROPHY, *GENETIC disorders, *METABOLIC disorders, *SYMPTOMS, *ADIPOSE tissue diseases, *GENETIC variation

Abstract

Familial partial lipodystrophy (FPLD) is a rare genetic disorder characterized by the selective loss of adipose tissue. Its estimated prevalence is as low as 1 in 1 million. The deficiency of metabolically active adipose tissue is closely linked with a wide range of metabolic complications, such as insulin resistance, lipoatrophic diabetes, dyslipidemia with severe hypertriglyceridemia, hypertension or hepatic steatosis. Moreover, female patients often develop hyperandrogenism, hirsutism, polycystic ovaries and infertility. The two most common types are FPLD type 2 and 3. Variants within LMNA and PPARG genes account for more than 50% of all reported FPLD cases. Because of its high heterogeneity and rarity, lipodystrophy can be easily unrecognized or misdiagnosed. To determine the genetic background of FPLD in a symptomatic woman and her close family, an NGS custom panel was used to sequence LMNA and PPARG genes. The affected patient presented fat deposits in the face, neck and trunk, with fat loss combined with muscular hypertrophy in the lower extremities and hirsutism, all features first manifesting at puberty. Her clinical presentation included metabolic disturbances, including hypercholesterolemia with severe hypertriglyceridemia, diabetes mellitus and hepatic steatosis. This together with her typical fat distribution and physical features raised a suspicion of FPLD. NGS analysis revealed the presence of missense heterozygous variant c.443G>A in exon 4 of PPARG gene, causing glycine to glutamic acid substitution at amino acid position 148, p.(Gly148Glu). The variant was also found in the patient's mother and son. The variant was not previously reported in any public database. Based on computational analysis, crucial variant localization within DNA-binding domain of PPARγ, available literature data and the variant cosegregation in the patient's family, novel c.443G>A variant was suspected to be causative. Functional testing is needed to confirm the pathogenicity of the novel variant. Inherited lipodystrophy syndromes represent a heterogenous group of metabolic disorders, whose background often remains unclear. A better understating of the genetic basis would allow earlier diagnosis and targeted treatment implementation. [ABSTRACT FROM AUTHOR]

Published

2022

10. Correction: Kucińska et al. The Use of CGH Arrays for Identifying Copy Number Variations in Children with Autism Spectrum Disorder. Brain Sci. 2024, 14 , 273.

Author

Kucińska, Agata, Hawuła, Wanda, Rutkowska, Lena, Wysocka, Urszula, Kępczyński, Łukasz, Piotrowicz, Małgorzata, Chilarska, Tatiana, Wieczorek-Cichecka, Nina, Połatyńska, Katarzyna, Przysło, Łukasz, and Gach, Agnieszka

Subjects

CHILDREN with autism spectrum disorders

Abstract

This document is a correction notice for an article titled "The Use of CGH Arrays for Identifying Copy Number Variations in Children with Autism Spectrum Disorder." The correction includes missing citations, text corrections, and corrections to the reference list. The authors state that the scientific conclusions of the original publication are unaffected. [Extracted from the article]

Published

2024

11. New findings in oligogenic inheritance of congenital hypogonadotropic hypogonadism.

Author

Gach, Agnieszka, Pinkier, Iwona, Wysocka, Urszula, Sałacińska, Kinga, Salachna, Dominik, Szarras-Czapnik, Maria, Pietrzyk, Aleksandra, Sakowicz, Agata, Nykel, Anna, Rutkowska, Lena, Rybak-Krzyszkowska, Magda, Socha, Magda, Jamsheer, Aleksander, and Jakubowski, Lucjusz

Subjects

HEREDITY, KALLMANN syndrome, HYPOGONADISM, GENITALIA, NUCLEOTIDE sequencing, GONAD development

Abstract

Introduction: Congenital hypogonadotropic hypogonadism results from a dysfunction of the hypothalamic-pituitary-gonadal axis, which is essential for the development and function of the reproductive system. It may be associated with anosmia, referred to as Kallmann syndrome, or a normal sense of smell. Numerous studies have proven that hypogonadotropic hypogonadism is not simply a monogenic Mendelian disease, but that more than one gene may be involved in its pathogenesis in a single patient. The oligogenic complex architecture underlying the disease is still largely unknown.Material and methods: Targeted next-generation sequencing (NGS) was used to screen for DNA variants in a cohort of 47 patients with congenital hypogonadotropic hypogonadism. The NGS panel consists of over 50 well-known and candidate genes, associated with hypogonadotropic state.Results: Here we report the identification of new oligogenic variants in SPRY4/SEMA3A, SRA1/SEMA7A, CHD7/SEMA7A, CCDC141/POLR3B/POLR3B, and PROKR2/SPRY4/NSMF. These genes are known to contribute to the phenotype of hypogonadotropic hypogonadism, yet our results point to potential new "partners" underlying digenic and trigenic patterns.Conclusions: The finding supports the importance of oligogenic inheritance and demonstrates the complexity of genetic architecture in hypogonadotropic hypogonadism. It also underlines the necessity for developing fine-tuned guidelines to provide a tool for adequate and precise sequence variant classification in non-Mendelian conditions. [ABSTRACT FROM AUTHOR]

Published

2022

12. Novel Mutations Within Collagen Alpha1(I) and Alpha2(I) Ligand-Binding Sites, Broadening the Spectrum of Osteogenesis Imperfecta – Current Insights Into Collagen Type I Lethal Regions.

Author

Sałacińska, Kinga, Pinkier, Iwona, Rutkowska, Lena, Chlebna-Sokół, Danuta, Jakubowska-Pietkiewicz, Elżbieta, Michałus, Izabela, Kępczyński, Łukasz, Salachna, Dominik, Jamsheer, Aleksander, Bukowska-Olech, Ewelina, Jaszczuk, Ilona, Jakubowski, Lucjusz, and Gach, Agnieszka

Subjects

OSTEOGENESIS imperfecta, COLLAGEN, LETHAL mutations, PHENOTYPES, GLYCINE

Abstract

Osteogenesis imperfecta (OI) is a rare genetic disorder demonstrating considerable phenotypic and genetic heterogeneity. The extensively studied genotype–phenotype correlation is a crucial issue for a reliable counseling, as the disease is recognized at increasingly earlier stages of life, including prenatal period. Based on population studies, clusters in COL1A1 and COL1A2 genes associated with the presence of glycine substitutions leading to fatal outcome have been distinguished and named as "lethal regions." Their localization corresponds to the ligand-binding sites responsible for extracellular interactions of collagen molecules, which could explain high mortality associated with mutations mapping to these regions. Although a number of non-lethal cases have been identified from the variants located in lethal clusters, the mortality rate of mutations has not been updated. An next generation sequencing analysis, using a custom gene panel of known and candidate OI genes, was performed on a group of 166 OI patients and revealed seven individuals with a causative mutations located in the lethal regions. Patients' age, ranging between 3 and 25 years, excluded the expected fatal outcome. The identification of non-lethal cases caused by mutations located in lethal domains prompted us to determine the actual mortality caused by glycine substitutions mapping to lethal clusters and evaluate the distribution of all lethal glycine mutations across collagen type I genes, based on records deposited in the OI Variant Database. Finally, we identified six glycine substitutions located in lethal regions of COL1A1 and COL1A2 genes, of which four are novel. The review of all mutations in the dedicated OI database, revealed 33 distinct glycine substitutions in two lethal domains of COL1A1 , 26 of which have been associated with a fatal outcome. Similarly, 109 glycine substitutions have been identified in eight lethal clusters of COL1A2 , of which 51 have been associated with a fatal manifestation. An analysis of all glycine substitutions leading to fatal phenotype, showed that their distribution along collagen type I genes is not regular, with 17% (26 out of 154) of mutations reported in COL1A1 and 64% (51 out of 80) in COL1A2 corresponding to localization of the lethal regions. [ABSTRACT FROM AUTHOR]

Published

2021