Anne Neddermeyer scite author profile

Anne Neddermeyer

4Publications

27Citation Statements Received

276Citation Statements Given

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325

271

Affiliations

Uppsala University

Publications

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AML displays increased CTCF occupancy associated with aberrant gene expression and transcription factor binding

Mujahed

Miliara

Neddermeyer

et al. 2020

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CCTC-binding factor (CTCF) is a key regulator of gene expression through organization of the chromatin structure. Still, it is unclear how CTCF binding is perturbed in leukemia or in cancer in general. We studied CTCF binding by chromatin immunoprecipitation sequencing in cells from patients with acute myeloid leukemia (AML) and in normal bone marrow (NBM) in the context of gene expression, DNA methylation, and azacitidine exposure. CTCF binding was increased in AML compared with NBM. Aberrant CTCF binding was enriched for motifs for key myeloid transcription factors such as CEBPA, PU.1, and RUNX1. AML with TET2 mutations was characterized by a particularly strong gain of CTCF binding, highly enriched for gain in promoter regions, while AML in general was enriched for changes at enhancers. There was a strong anticorrelation between CTCF binding and DNA methylation. Gain of CTCF occupancy was associated with increased gene expression; however, the genomic location (promoter vs distal regions) and enrichment of motifs (for repressing vs activating cofactors) were decisive for the gene expression pattern. Knockdown of CTCF in K562 cells caused loss of CTCF binding and transcriptional repression of genes with changed CTCF binding in AML, as well as loss of RUNX1 binding at RUNX1/CTCF-binding sites. In addition, CTCF knockdown caused increased differentiation. Azacitidine exposure caused major changes in CTCF occupancy in AML patient cells, partly by restoring a CTCF-binding pattern similar to NBM. We conclude that AML displays an aberrant increase in CTCF occupancy that targets key genes for AML development and impacts gene expression.

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Challenging conventional karyotyping by next-generation karyotyping in 281 intensively treated patients with AML

Mareschal

Palau

Lindberg

et al. 2021

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Although copy number alterations (CNAs) and translocations constitute the backbone of the diagnosis and prognostication of acute myeloid leukemia (AML), techniques used for their assessment in routine diagnostics have not been reconsidered for decades. We used a combination of 2 next-generation sequencing–based techniques to challenge the currently recommended conventional cytogenetic analysis (CCA), comparing the approaches in a series of 281 intensively treated patients with AML. Shallow whole-genome sequencing (sWGS) outperformed CCA in detecting European Leukemia Net (ELN)–defining CNAs and showed that CCA overestimated monosomies and suboptimally reported karyotype complexity. Still, the concordance between CCA and sWGS for all ELN CNA–related criteria was 94%. Moreover, using in silico dilution, we showed that 1 million reads per patient would be enough to accurately assess ELN-defining CNAs. Total genomic loss, defined as a total loss ≥200 Mb by sWGS, was found to be a better marker for genetic complexity and poor prognosis compared with the CCA-based definition of complex karyotype. For fusion detection, the concordance between CCA and whole-transcriptome sequencing (WTS) was 99%. WTS had better sensitivity in identifying inv(16) and KMT2A rearrangements while showing limitations in detecting lowly expressed PML-RARA fusions. Ligation-dependent reverse transcription polymerase chain reaction was used for validation and was shown to be a fast and reliable method for fusion detection. We conclude that a next-generation sequencing–based approach can replace conventional CCA for karyotyping, provided that efforts are made to cover lowly expressed fusion transcripts.

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Investigating Tick-borne Flaviviral-like Particles as a Delivery System for Gene Therapy

Neddermeyer

Hultenby

Paidikondala

et al. 2018

Current Therapeutic Research

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BackgroundResearch on the biogenesis of tick-borne encephalitis virus (TBEV) would benefit gene therapy. Due to specific arrangements of genes along the TBEV genome, its viral-like particles (VLPs) could be exploited as shuttles to deliver their replicon, which carries therapeutic genes, to immune system cells.ObjectiveTo develop a flaviviral vector for gene delivery as a part of gene therapy research that can be expressed in secretable VLP suicidal shuttles and provide abundant unique molecular and structural data supporting this gene therapy concept.MethodTBEV structural gene constructs of a Swedish Torö strain were cloned into plasmids driven by the promoters CAG and CMV and then transfected into various cell lines, including COS-1 and BHK-21. Time-course sampling of the cells, culture fluid, cell lysate supernatant, and pellet specimens were performed. Western blotting and electron microscopy analyses of collected specimens were used to investigate molecular and structural processing of TBEV structural proteins.ResultsWestern blotting analysis showed differences between promoters in directing the gene expression of the VLPs constructs. The premature flaviviral polypeptides as well as mature VLPs could be traced. Using electron microscopy, the premature and mature VLP accumulation in cellular compartments—and also endoplasmic reticulum proliferation as a virus factory platform—were observed in addition to secreted VLPs.ConclusionsThe abundant virologic and cellular findings in this study show the natural processing and safety of inserting flaviviral structural genes into suicidal VLP shuttles. Thus, we propose that these VLPs are a suitable gene delivering system model in gene therapy.

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The biological and prognostic role of long non-coding RNA NEAT1 in acute myeloid leukemia

Miliara

Neddermeyer

Bonetti

et al. 2022

Preprint

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Nuclear paraspeckle assembly transcript 1 (NEAT1) is a long non-coding RNA associated with the promotion of several solid cancers. As part of the FANTOM6 project, we aimed to define its role in acute myeloid leukemia (AML) and myelopoiesis, since it remains largely uninvestigated. We show that NEAT1 expression increases during myelopoiesis, especially in monocytes. NEAT1 expression is elevated in AML compared to normal bone marrow (NBM), especially in AML with inv(16)and t(8;21). In addition, NEAT1 expression correlates positively with ASXL1, KRAS and NRAS mutations, but negatively with TP53 mutant AML. Higher NEAT1 expression is associated with better overall survival in AML, independent of other known risk factors. Knockdown of NEAT1 in AML cells induces monocytic differentiation and upregulated gene expression of genes involved in glucose metabolism. By investigating genome-wide RNA and DNA interactions using RADICL-sequencing, we show that NEAT1 binds to the RUNX2 locus that is associated with differentiation, metabolism, and glucose uptake. The results suggest that the lncRNA NEAT1 has a role in myelopoiesis, AML and is implicated in glycolysis.

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