Your search keyword '"Miguel A. Andrade-Navarro"' showing total 329 results

1. Unveiling cell-type-specific microRNA networks through alternative polyadenylation in glioblastoma

Author

Mert Cihan, Greta Schmauck, Maximilian Sprang, and Miguel A. Andrade-Navarro

Subjects

Glioblastoma, MicroRNA, Alternative polyadenylation, Stem cell, Single-cell RNA, Biology (General), QH301-705.5

Abstract

Abstract Background Glioblastoma multiforme (GBM) is characterized by its cellular complexity, with a microenvironment consisting of diverse cell types, including oligodendrocyte precursor cells (OPCs) and neoplastic CD133 + radial glia-like cells. This study focuses on exploring the distinct cellular transitions in GBM, emphasizing the role of alternative polyadenylation (APA) in modulating microRNA-binding and post-transcriptional regulation. Results Our research identified unique APA profiles that signify the transitional phases between neoplastic cells and OPCs, underscoring the importance of APA in cellular identity and transformation in GBM. A significant finding was the disconnection between differential APA events and gene expression alterations, indicating that APA operates as an independent regulatory mechanism. We also highlighted the specific genes in neoplastic cells and OPCs that lose microRNA-binding sites due to APA, which are crucial for maintaining stem cell characteristics and DNA repair, respectively. The constructed networks of microRNA-transcription factor-target genes provide insights into the cellular mechanisms influencing cancer cell survival and therapeutic resistance. Conclusions This study elucidates the APA-driven regulatory framework within GBM, spotlighting its influence on cell state transitions and microRNA network dynamics. Our comprehensive analysis using single-cell RNA sequencing data to investigate the microRNA-binding sites altered by APA profiles offers a robust foundation for future research, presenting a novel approach to understanding and potentially targeting the complex molecular interplay in GBM.

Published

2025

2. Overlooked poor-quality patient samples in sequencing data impair reproducibility of published clinically relevant datasets

Author

Maximilian Sprang, Jannik Möllmann, Miguel A. Andrade-Navarro, and Jean-Fred Fontaine

Subjects

Quality, RNA-seq, ChIP-seq, Quality markers, Clinical datasets, Bioinformatics, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Background Reproducibility is a major concern in biomedical studies, and existing publication guidelines do not solve the problem. Batch effects and quality imbalances between groups of biological samples are major factors hampering reproducibility. Yet, the latter is rarely considered in the scientific literature. Results Our analysis uses 40 clinically relevant RNA-seq datasets to quantify the impact of quality imbalance between groups of samples on the reproducibility of gene expression studies. High-quality imbalance is frequent (14 datasets; 35%), and hundreds of quality markers are present in more than 50% of the datasets. Enrichment analysis suggests common stress-driven effects among the low-quality samples and highlights a complementary role of transcription factors and miRNAs to regulate stress response. Preliminary ChIP-seq results show similar trends. Quality imbalance has an impact on the number of differential genes derived by comparing control to disease samples (the higher the imbalance, the higher the number of genes), on the proportion of quality markers in top differential genes (the higher the imbalance, the higher the proportion; up to 22%) and on the proportion of known disease genes in top differential genes (the higher the imbalance, the lower the proportion). We show that removing outliers based on their quality score improves the resulting downstream analysis. Conclusions Thanks to a stringent selection of well-designed datasets, we demonstrate that quality imbalance between groups of samples can significantly reduce the relevance of differential genes, consequently reducing reproducibility between studies. Appropriate experimental design and analysis methods can substantially reduce the problem.

Published

2024

3. CT-based radiomics for predicting breast cancer radiotherapy side effects

Author

Óscar Llorián-Salvador, Nora Windeler, Nicole Martin, Lucas Etzel, Miguel A. Andrade-Navarro, Denise Bernhardt, Burkhard Rost, Kai J. Borm, Stephanie E. Combs, Marciana N. Duma, and Jan C. Peeken

Subjects

Radiomics, Machine learning, Breast cancer, Computed tomography, Radiotherapy, Side effects, Medicine, Science

Abstract

Abstract Skin inflammation with the potential sequel of moist epitheliolysis and edema constitute the most frequent breast radiotherapy (RT) acute side effects. The aim of this study was to compare the predictive value of tissue-derived radiomics features to the total breast volume (TBV) for the moist cells epitheliolysis as a surrogate for skin inflammation, and edema. Radiomics features were extracted from computed tomography (CT) scans of 252 breast cancer patients from two volumes of interest: TBV and glandular tissue (GT). Machine learning classifiers were trained on radiomics and clinical features, which were evaluated for both side effects. The best radiomics model was a least absolute shrinkage and selection operator (LASSO) classifier, using TBV features, predicting moist cells epitheliolysis, achieving an area under the receiver operating characteristic (AUROC) of 0.74. This was comparable to TBV breast volume (AUROC of 0.75). Combined models of radiomics and clinical features did not improve performance. Exclusion of volume-correlated features slightly reduced the predictive performance (AUROC 0.71). We could demonstrate the general propensity of planning CT-based radiomics models to predict breast RT-dependent side effects. Mammary tissue was more predictive than glandular tissue. The radiomics features performance was influenced by their high correlation to TBV volume.

Published

2024

4. Predicting the involvement of polyQ- and polyA in protein-protein interactions by their amino acid context

Author

Pablo Mier and Miguel A. Andrade-Navarro

Subjects

Homorepeat, Polyglutamine, Polyalanine, Protein-protein interaction, Machine learning, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Homorepeats, specifically polyglutamine (polyQ) and polyalanine (polyA), are often implicated in protein-protein interactions (PPIs). So far, a method to predict the participation of homorepeats in protein interactions is lacking. We propose a machine learning approach to identify PPI-involved polyQ and polyA regions within the human proteome based on known interacting regions. Using the dataset of human homorepeats, we identified 157 polyQ and 745 polyA regions potentially involved in PPIs. Machine learning models, trained on amino acid context and homorepeat length, demonstrated high precision (0.90–0.98) but variable recall (0.42–0.85). Random forest outperformed other models (AUC polyQ = 0.686, AUC polyA = 0.732) using the positions surrounding the homorepeat −10 to +10. Integrating paralog information marginally improved predictions but was excluded for model simplicity. Further optimization revealed that for polyQ, using amino acid surrounding positions from −6 to +6 increased AUC to 0.715. For polyA, no improvement was found. Incorporating coiled coil overlap information enhanced polyA predictions (AUC = 0.745) but not polyQ. Finally, we applied these models to predict PPI involvement across all polyQ and polyA regions, identifying potential interactions. Case studies illustrated the method's predictive capacity, highlighting known interacting regions with high scores and elucidating potential false negatives.

Published

2024

5. A Systematic Review of Lipid-Focused Cardiovascular Disease Research: Trends and Opportunities

Author

Uchenna Alex Anyaegbunam, Piyush More, Jean-Fred Fontaine, Vincent ten Cate, Katrin Bauer, Ute Distler, Elisa Araldi, Laura Bindila, Philipp Wild, and Miguel A. Andrade-Navarro

Subjects

lipids, cardiovascular diseases, lipoproteins, lipid-protein network, research trends, Biology (General), QH301-705.5

Abstract

Lipids are important modifiers of protein function, particularly as parts of lipoproteins, which transport lipophilic substances and mediate cellular uptake of circulating lipids. As such, lipids are of particular interest as blood biological markers for cardiovascular disease (CVD) as well as for conditions linked to CVD such as atherosclerosis, diabetes mellitus, obesity and dietary states. Notably, lipid research is particularly well developed in the context of CVD because of the relevance and multiple causes and risk factors of CVD. The advent of methods for high-throughput screening of biological molecules has recently resulted in the generation of lipidomic profiles that allow monitoring of lipid compositions in biological samples in an untargeted manner. These and other earlier advances in biomedical research have shaped the knowledge we have about lipids in CVD. To evaluate the knowledge acquired on the multiple biological functions of lipids in CVD and the trends in their research, we collected a dataset of references from the PubMed database of biomedical literature focused on plasma lipids and CVD in human and mouse. Using annotations from these records, we were able to categorize significant associations between lipids and particular types of research approaches, distinguish non-biological lipids used as markers, identify differential research between human and mouse models, and detect the increasingly mechanistic nature of the results in this field. Using known associations between lipids and proteins that metabolize or transport them, we constructed a comprehensive lipid–protein network, which we used to highlight proteins strongly connected to lipids found in the CVD-lipid literature. Our approach points to a series of proteins for which lipid-focused research would bring insights into CVD, including Prostaglandin G/H synthase 2 (PTGS2, a.k.a. COX2) and Acylglycerol kinase (AGK). In this review, we summarize our findings, putting them in a historical perspective of the evolution of lipid research in CVD.

Published

2023

6. The importance of planning CT-based imaging features for machine learning-based prediction of pain response

Author

Óscar Llorián-Salvador, Joachim Akhgar, Steffi Pigorsch, Kai Borm, Stefan Münch, Denise Bernhardt, Burkhard Rost, Miguel A. Andrade-Navarro, Stephanie E. Combs, and Jan C. Peeken

Subjects

Medicine, Science

Abstract

Abstract Patients suffering from painful spinal bone metastases (PSBMs) often undergo palliative radiation therapy (RT), with an efficacy of approximately two thirds of patients. In this exploratory investigation, we assessed the effectiveness of machine learning (ML) models trained on radiomics, semantic and clinical features to estimate complete pain response. Gross tumour volumes (GTV) and clinical target volumes (CTV) of 261 PSBMs were segmented on planning computed tomography (CT) scans. Radiomics, semantic and clinical features were collected for all patients. Random forest (RFC) and support vector machine (SVM) classifiers were compared using repeated nested cross-validation. The best radiomics classifier was trained on CTV with an area under the receiver-operator curve (AUROC) of 0.62 ± 0.01 (RFC; 95% confidence interval). The semantic model achieved a comparable AUROC of 0.63 ± 0.01 (RFC), significantly below the clinical model (SVM, AUROC: 0.80 ± 0.01); and slightly lower than the spinal instability neoplastic score (SINS; LR, AUROC: 0.65 ± 0.01). A combined model did not improve performance (AUROC: 0,74 ± 0,01). We could demonstrate that radiomics and semantic analyses of planning CTs allowed for limited prediction of therapy response to palliative RT. ML predictions based on established clinical parameters achieved the best results.

Published

2023

7. Intranuclear inclusions of polyQ-expanded ATXN1 sequester RNA molecules

Author

Ioannis Gkekas, Aimilia-Christina Vagiona, Nikolaos Pechlivanis, Georgia Kastrinaki, Katerina Pliatsika, Sebastian Iben, Konstantinos Xanthopoulos, Fotis E. Psomopoulos, Miguel A. Andrade-Navarro, and Spyros Petrakis

Subjects

spinocerebellar ataxia type 1, ataxin-1, intranuclear inclusion bodies, RNA sequestration, RNA-seq, protein–protein interaction network, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Spinocerebellar ataxia type 1 (SCA1) is an autosomal dominant neurodegenerative disease caused by a trinucleotide (CAG) repeat expansion in the ATXN1 gene. It is characterized by the presence of polyglutamine (polyQ) intranuclear inclusion bodies (IIBs) within affected neurons. In order to investigate the impact of polyQ IIBs in SCA1 pathogenesis, we generated a novel protein aggregation model by inducible overexpression of the mutant ATXN1(Q82) isoform in human neuroblastoma SH-SY5Y cells. Moreover, we developed a simple and reproducible protocol for the efficient isolation of insoluble IIBs. Biophysical characterization showed that polyQ IIBs are enriched in RNA molecules which were further identified by next-generation sequencing. Finally, a protein interaction network analysis indicated that sequestration of essential RNA transcripts within ATXN1(Q82) IIBs may affect the ribosome resulting in error-prone protein synthesis and global proteome instability. These findings provide novel insights into the molecular pathogenesis of SCA1, highlighting the role of polyQ IIBs and their impact on critical cellular processes.

Published

2023

8. DNA methylation and cardiovascular disease in humans: a systematic review and database of known CpG methylation sites

Author

Mykhailo Krolevets, Vincent ten Cate, Jürgen H. Prochaska, Andreas Schulz, Steffen Rapp, Stefan Tenzer, Miguel A. Andrade-Navarro, Steve Horvath, Christof Niehrs, and Philipp S. Wild

Subjects

Epigenetics, DNA methylation, Cardiovascular, CpG, Systematic review, CVD, Medicine, Genetics, QH426-470

Abstract

Abstract Background Cardiovascular disease (CVD) is the leading cause of death worldwide and considered one of the most environmentally driven diseases. The role of DNA methylation in response to the individual exposure for the development and progression of CVD is still poorly understood and a synthesis of the evidence is lacking. Results A systematic review of articles examining measurements of DNA cytosine methylation in CVD was conducted in accordance with PRISMA (preferred reporting items for systematic reviews and meta-analyses) guidelines. The search yielded 5,563 articles from PubMed and CENTRAL databases. From 99 studies with a total of 87,827 individuals eligible for analysis, a database was created combining all CpG-, gene- and study-related information. It contains 74,580 unique CpG sites, of which 1452 CpG sites were mentioned in ≥ 2, and 441 CpG sites in ≥ 3 publications. Two sites were referenced in ≥ 6 publications: cg01656216 (near ZNF438) related to vascular disease and epigenetic age, and cg03636183 (near F2RL3) related to coronary heart disease, myocardial infarction, smoking and air pollution. Of 19,127 mapped genes, 5,807 were reported in ≥ 2 studies. Most frequently reported were TEAD1 (TEA Domain Transcription Factor 1) and PTPRN2 (Protein Tyrosine Phosphatase Receptor Type N2) in association with outcomes ranging from vascular to cardiac disease. Gene set enrichment analysis of 4,532 overlapping genes revealed enrichment for Gene Ontology molecular function “DNA-binding transcription activator activity” (q = 1.65 × 10–11) and biological processes “skeletal system development” (q = 1.89 × 10–23). Gene enrichment demonstrated that general CVD-related terms are shared, while “heart” and “vasculature” specific genes have more disease-specific terms as PR interval for “heart” or platelet distribution width for “vasculature.” STRING analysis revealed significant protein–protein interactions between the products of the differentially methylated genes (p = 0.003) suggesting that dysregulation of the protein interaction network could contribute to CVD. Overlaps with curated gene sets from the Molecular Signatures Database showed enrichment of genes in hemostasis (p = 2.9 × 10–6) and atherosclerosis (p = 4.9 × 10–4). Conclusion This review highlights the current state of knowledge on significant relationship between DNA methylation and CVD in humans. An open-access database has been compiled of reported CpG methylation sites, genes and pathways that may play an important role in this relationship.

Published

2023

9. Phase separating Rho: a widespread regulatory function of disordered regions in proteins revealed in bacteria

Author

Eric Schumbera, Pablo Mier, and Miguel A. Andrade-Navarro

Subjects

Medicine, Biology (General), QH301-705.5

Published

2023

10. The nucleotide landscape of polyXY regions

Author

Pablo Mier and Miguel A. Andrade-Navarro

Subjects

Protein sequence analysis, Low complexity regions, Linear motifs, PolyXY, Biotechnology, TP248.13-248.65

Abstract

PolyXY regions are compositionally biased regions composed of two different amino acids. They are classified according to the arrangement of the two amino acid types ‘X′ and ‘Y′ into direpeats (composed of alternating amino acids, e.g. ‘XYXYXY’), joined (composed of two consecutive stretches of each amino acid, e.g. ‘XXXYYY’) and shuffled (other arrangements, e.g., ‘XYXXYY’). They have been characterized at the amino acid level in all domains of life, and are described as often found within intrinsically disordered regions. Since DNA replication slippage has been proposed as a driver of repeat variation, and given that some polyXY have a repetitive nature, we hypothesized that characterizing the nucleotide coding of various types of polyXY could give hints about their origin and evolution. To test this, we obtained all polyXY regions in the human transcriptome, categorized them, and studied their coding nucleotide sequences. We observed that polyXY exacerbates the codon biases, and that the similarity between the X and Y codons is higher than in the background proteome. Our results support a general mechanism of emergence and evolution of polyXY from single-codon polyX. PolyXY are revealed as hotspots for replication slippage, particularly those composed of repeats: joined and direpeat polyXY. Inter-conversion to shuffled polyXY disrupts nucleotide repeats and restricts further evolution by replication slippage, a mechanism that we previously observed in polyX. Our results shed light on polyXY composition and should simplify the determination of their functions.

Published

2023

11. Batch effect detection and correction in RNA-seq data using machine-learning-based automated assessment of quality

Author

Maximilian Sprang, Miguel A. Andrade-Navarro, and Jean-Fred Fontaine

Subjects

Batch effect, Quality control, NGS, RNA-seq, Next-generation sequencing, Machine learning, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background The constant evolving and development of next-generation sequencing techniques lead to high throughput data composed of datasets that include a large number of biological samples. Although a large number of samples are usually experimentally processed by batches, scientific publications are often elusive about this information, which can greatly impact the quality of the samples and confound further statistical analyzes. Because dedicated bioinformatics methods developed to detect unwanted sources of variance in the data can wrongly detect real biological signals, such methods could benefit from using a quality-aware approach. Results We recently developed statistical guidelines and a machine learning tool to automatically evaluate the quality of a next-generation-sequencing sample. We leveraged this quality assessment to detect and correct batch effects in 12 publicly available RNA-seq datasets with available batch information. We were able to distinguish batches by our quality score and used it to correct for some batch effects in sample clustering. Overall, the correction was evaluated as comparable to or better than the reference method that uses a priori knowledge of the batches (in 10 and 1 datasets of 12, respectively; total = 92%). When coupled to outlier removal, the correction was more often evaluated as better than the reference (comparable or better in 5 and 6 datasets of 12, respectively; total = 92%). Conclusions In this work, we show the capabilities of our software to detect batches in public RNA-seq datasets from differences in the predicted quality of their samples. We also use these insights to correct the batch effect and observe the relation of sample quality and batch effect. These observations reinforce our expectation that while batch effects do correlate with differences in quality, batch effects also arise from other artifacts and are more suitably corrected statistically in well-designed experiments.

Published

2022

12. Association of FXI activity with thrombo-inflammation, extracellular matrix, lipid metabolism and apoptosis in venous thrombosis

Author

Alejandro Pallares Robles, Vincent ten Cate, Andreas Schulz, Jürgen H. Prochaska, Steffen Rapp, Thomas Koeck, Marina Panova-Noeva, Stefan Heitmeier, Stephan Schwers, Kirsten Leineweber, Hans-Jürgen Seyfarth, Christian F. Opitz, Henri Spronk, Christine Espinola-Klein, Karl J. Lackner, Thomas Münzel, Miguel A. Andrade-Navarro, Stavros V. Konstantinides, Hugo ten Cate, and Philipp S. Wild

Subjects

Medicine, Science

Abstract

Abstract Animal experiments and early phase human trials suggest that inhibition of factor XIa (FXIa) safely prevents venous thromboembolism (VTE), and specific murine models of sepsis have shown potential efficacy in alleviating cytokine storm. These latter findings support the role of FXI beyond coagulation. Here, we combine targeted proteomics, machine learning and bioinformatics, to discover associations between FXI activity (FXI:C) and the plasma protein profile of patients with VTE. FXI:C was measured with a modified activated partial prothrombin time (APTT) clotting time assay. Proximity extension assay-based protein profiling was performed on plasma collected from subjects from the Genotyping and Molecular Phenotyping of Venous Thromboembolism (GMP-VTE) Project, collected during an acute VTE event (n = 549) and 12-months after (n = 187). Among 444 proteins investigated, N = 21 and N = 66 were associated with FXI:C during the acute VTE event and at 12 months follow-up, respectively. Seven proteins were identified as FXI:C-associated at both time points. These FXI-related proteins were enriched in immune pathways related to causes of thrombo-inflammation, extracellular matrix interaction, lipid metabolism, and apoptosis. The results of this study offer important new avenues for future research into the multiple properties of FXI, which are of high clinical interest given the current development of FXI inhibitors.

Published

2022

13. Regions with two amino acids in protein sequences: A step forward from homorepeats into the low complexity landscape

Author

Pablo Mier and Miguel A. Andrade-Navarro

Subjects

Protein sequence analysis, Low complexity regions, Linear motifs, polyXY, Biotechnology, TP248.13-248.65

Abstract

Low complexity regions (LCRs) differ in amino acid composition from the background provided by the corresponding proteomes. The simplest LCRs are homorepeats (or polyX), regions composed of mostly-one amino acid type. Extensive research has been done to characterize homorepeats, and their taxonomic, functional and structural features depend on the amino acid type and sequence context. From them, the next step towards the study of LCRs are the regions composed of two types of amino acids, which we call polyXY. We classify polyXY in three categories based on the arrangement of the two amino acid types ‘X’ and ‘Y’: direpeats (e.g. ‘XYXYXY’), joined (e.g. ‘XXXYYY’) and shuffled (e.g. ‘XYYXXY’). We developed a script to search for polyXY, and located them in a comprehensive set of 20,340 reference proteomes. These results are available in a dedicated web server called XYs, in which the user can also submit their own protein datasets to detect polyXY. We studied the distribution of polyXY types by amino acid pair XY and category, and show that polyXY in Eukaryota are mainly located within intrinsically disordered regions. Our study provides a first step towards the characterization of polyXY as protein motifs.

Published

2022

14. Evolutionary Study of Protein Short Tandem Repeats in Protein Families

Author

Pablo Mier and Miguel A. Andrade-Navarro

Subjects

low complexity regions, repeats, protein sequence analysis, Microbiology, QR1-502

Abstract

Tandem repeats in proteins are patterns of residues repeated directly adjacent to each other. The evolution of these repeats can be assessed by using groups of homologous sequences, which can help pointing to events of unit duplication or deletion. High pressure in a protein family for variation of a given type of repeat might point to their function. Here, we propose the analysis of protein families to calculate protein short tandem repeats (pSTRs) in each protein sequence and assess their variability within the family in terms of number of units. To facilitate this analysis, we developed the pSTR tool, a method to analyze the evolution of protein short tandem repeats in a given protein family by pairwise comparisons between evolutionarily related protein sequences. We evaluated pSTR unit number variation in protein families of 12 complete metazoan proteomes. We hypothesize that families with more dynamic ensembles of repeats could reflect particular roles of these repeats in processes that require more adaptability.

Published

2023

15. seqQscorer: automated quality control of next-generation sequencing data using machine learning

Author

Steffen Albrecht, Maximilian Sprang, Miguel A. Andrade-Navarro, and Jean-Fred Fontaine

Subjects

Next-generation sequencing data, Quality control, Machine learning, Classification, Bioinformatics, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Controlling quality of next-generation sequencing (NGS) data files is a necessary but complex task. To address this problem, we statistically characterize common NGS quality features and develop a novel quality control procedure involving tree-based and deep learning classification algorithms. Predictive models, validated on internal and external functional genomics datasets, are to some extent generalizable to data from unseen species. The derived statistical guidelines and predictive models represent a valuable resource for users of NGS data to better understand quality issues and perform automatic quality control. Our guidelines and software are available at https://github.com/salbrec/seqQscorer .

Published

2021

16. The features of polyglutamine regions depend on their evolutionary stability

Author

Pablo Mier and Miguel A. Andrade-Navarro

Subjects

Homorepeat, polyQ, Glutamine, Codon usage, Evolutionary stability, Evolution, QH359-425

Abstract

Abstract Background Polyglutamine regions (polyQ) are one of the most studied and prevalent homorepeats in eukaryotes. They have a particular length-dependent codon usage, which relates to a characteristic CAG-slippage mechanism. Pathologically expanded tracts of polyQ are known to form aggregates and are involved in the development of several human neurodegenerative diseases. The non-pathogenic function of polyQ is to mediate protein-protein interactions via a coiled-coil pairing with an interactor. They are usually located in a helical context. Results Here we study the stability of polyQ regions in evolution, using a set of 60 proteomes from four distinct taxonomic groups (Insecta, Teleostei, Sauria and Mammalia). The polyQ regions can be distinctly grouped in three categories based on their evolutionary stability: stable, unstable by length variation (inserted), and unstable by mutations (mutated). PolyQ regions in these categories can be significantly distinguished by their glutamine codon usage, and we show that the CAG-slippage mechanism is predominant in inserted polyQ of Sauria and Mammalia. The polyQ amino acid context is also influenced by the polyQ stability, with a higher proportion of proline residues around inserted polyQ. By studying the secondary structure of the sequences surrounding polyQ regions, we found that regarding the structural conformation around a polyQ, its stability category is more relevant than its taxonomic information. The protein-protein interaction capacity of a polyQ is also affected by its stability, as stable polyQ have more interactors than unstable polyQ. Conclusions Our results show that apart from the sequence of a polyQ, information about its orthologous sequences is needed to assess its function. Codon usage, amino acid context, structural conformation and the protein-protein interaction capacity of polyQ from all studied taxa critically depend on the region stability. There are however some taxa-specific polyQ features that override this importance. We conclude that a taxa-driven evolutionary analysis is of the highest importance for the comprehensive study of any feature of polyglutamine regions.

Published

2020

17. The importance of definitions in the study of polyQ regions: A tale of thresholds, impurities and sequence context

Author

Pablo Mier, Carlos Elena-Real, Annika Urbanek, Pau Bernadó, and Miguel A. Andrade-Navarro

Subjects

Homorepeat, polyQ, Glutamine, Sequence context, Codon usage, Biotechnology, TP248.13-248.65

Abstract

Polyglutamine (polyQ) regions are one of the most prevalent homorepeats in eukaryotes. It is however difficult to evaluate their prevalence because various studies claim different results. The reason is the lack of a consensus to define what is indeed a polyQ region. We have tackled this issue by studying how the use of different thresholds (i.e., minimum number of glutamines required in a protein region of a given size), to detect polyQ regions in the human proteome influences not only their prevalence but also their general features and sequence context. Threshold definition shapes the length distribution of the polyQ dataset, and changes the observed number and position of impurities (amino acids other than glutamine) within polyQ regions. Irrespective of the chosen threshold, leucine and proline residues are enriched both within and around polyQ. While leucine is enriched at the N-terminus of polyQ and specially at position −1 (amino acid preceding the polyQ), proline is prevalent in the C-terminus (positions +1 to +5, that is, the first five amino acids after the polyQ). We also checked the suitability of these thresholds for other species, and compared their polyQ features with those found in humans. As the sequence context and features of polyQ regions are threshold-dependent, we propose a method to quickly scan the polyQ landscape of a proteome. We complement our results with a summarized overview about which biases are to be expected per threshold when studying polyQ regions.

Published

2020

18. The distributions of protein coding genes within chromatin domains in relation to human disease

Author

Enrique M. Muro, Jonas Ibn-Salem, and Miguel A. Andrade-Navarro

Subjects

Chromatin structure, Topologically associating domains, TAD, Human diseases, Genes associated with disease, Housekeeping genes, Genetics, QH426-470

Abstract

Abstract Background Our understanding of the nuclear chromatin structure has increased hugely during the last years mainly as a consequence of the advances in chromatin conformation capture methods like Hi-C. The unprecedented resolution of genome-wide interaction maps shows functional consequences that extend the initial thought of an efficient DNA packaging mechanism: gene regulation, DNA repair, chromosomal translocations and evolutionary rearrangements seem to be only the peak of the iceberg. One key concept emerging from this research is the topologically associating domains (TADs) whose functional role in gene regulation and their association with disease is not fully untangled. Results We report that the lower the number of protein coding genes inside TADs, the higher the tendency of those genes to be associated with disease (p-value = 4 × $$10^{-54}$$ 10-54 ). Moreover, housekeeping genes are less associated with disease than other genes. Accordingly, they are depleted in TADs containing less than three protein coding genes (p-value = 3.9 × $$10^{-34}$$ 10-34 ). We observed that TADs with higher ratios of enhancers versus genes contained higher numbers of disease-associated genes. We interpret these results as an indication that sharing enhancers among genes reduces their involvement in disease. Larger TADs would have more chances to accommodate many genes and select for enhancer sharing along evolution. Conclusions Genes associated with human disease do not distribute randomly over the TADs. Our observations suggest general rules that confer functional stability to TADs, adding more evidence to the role of TADs as regulatory units.

Published

2019

19. Assessment of computational methods for the analysis of single-cell ATAC-seq data

Author

Huidong Chen, Caleb Lareau, Tommaso Andreani, Michael E. Vinyard, Sara P. Garcia, Kendell Clement, Miguel A. Andrade-Navarro, Jason D. Buenrostro, and Luca Pinello

Subjects

scATAC-seq, Feature matrix, Benchmarking, Regulatory genomics, Clustering, Visualization, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Background Recent innovations in single-cell Assay for Transposase Accessible Chromatin using sequencing (scATAC-seq) enable profiling of the epigenetic landscape of thousands of individual cells. scATAC-seq data analysis presents unique methodological challenges. scATAC-seq experiments sample DNA, which, due to low copy numbers (diploid in humans), lead to inherent data sparsity (1–10% of peaks detected per cell) compared to transcriptomic (scRNA-seq) data (10–45% of expressed genes detected per cell). Such challenges in data generation emphasize the need for informative features to assess cell heterogeneity at the chromatin level. Results We present a benchmarking framework that is applied to 10 computational methods for scATAC-seq on 13 synthetic and real datasets from different assays, profiling cell types from diverse tissues and organisms. Methods for processing and featurizing scATAC-seq data were compared by their ability to discriminate cell types when combined with common unsupervised clustering approaches. We rank evaluated methods and discuss computational challenges associated with scATAC-seq analysis including inherently sparse data, determination of features, peak calling, the effects of sequencing coverage and noise, and clustering performance. Running times and memory requirements are also discussed. Conclusions This reference summary of scATAC-seq methods offers recommendations for best practices with consideration for both the non-expert user and the methods developer. Despite variation across methods and datasets, SnapATAC, Cusanovich2018, and cisTopic outperform other methods in separating cell populations of different coverages and noise levels in both synthetic and real datasets. Notably, SnapATAC is the only method able to analyze a large dataset (> 80,000 cells).

Published

2019

20. 7C: Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs

Author

Jonas Ibn-Salem and Miguel A. Andrade-Navarro

Subjects

Chromatin interactions, Three-dimensional genome architecture, Transcription factors, ChIP-seq, 3C, 4C, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Knowledge of the three-dimensional structure of the genome is necessary to understand how gene expression is regulated. Recent experimental techniques such as Hi-C or ChIA-PET measure long-range chromatin interactions genome-wide but are experimentally elaborate, have limited resolution and such data is only available for a limited number of cell types and tissues. Results While ChIP-seq was not designed to detect chromatin interactions, the formaldehyde treatment in the ChIP-seq protocol cross-links proteins with each other and with DNA. Consequently, also regions that are not directly bound by the targeted TF but interact with the binding site via chromatin looping are co-immunoprecipitated and sequenced. This produces minor ChIP-seq signals at loop anchor regions close to the directly bound site. We use the position and shape of ChIP-seq signals around CTCF motif pairs to predict whether they interact or not. We implemented this approach in a prediction method, termed Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs (7C). We applied 7C to all CTCF motif pairs within 1 Mb in the human genome and validated predicted interactions with high-resolution Hi-C and ChIA-PET. A single ChIP-seq experiment from known architectural proteins (CTCF, Rad21, Znf143) but also from other TFs (like TRIM22 or RUNX3) predicts loops accurately. Importantly, 7C predicts loops in cell types and for TF ChIP-seq datasets not used in training. Conclusion 7C predicts chromatin loops which can help to associate TF binding sites to regulated genes. Furthermore, profiling of hundreds of ChIP-seq datasets results in novel candidate factors functionally involved in chromatin looping. Our method is available as an R/Bioconductor package: http://bioconductor.org/packages/sevenC.

Published

2019

21. Imidazopyridines as Potent KDM5 Demethylase Inhibitors Promoting Reprogramming Efficiency of Human iPSCs

Author

Yasamin Dabiri, Rodrigo A. Gama-Brambila, Katerina Taškova, Kristina Herold, Stefanie Reuter, James Adjaye, Jochen Utikal, Ralf Mrowka, Jichang Wang, Miguel A. Andrade-Navarro, and Xinlai Cheng

Subjects

Science

Abstract

Summary: Pioneering human induced pluripotent stem cell (iPSC)-based pre-clinical studies have raised safety concerns and pinpointed the need for safer and more efficient approaches to generate and maintain patient-specific iPSCs. One approach is searching for compounds that influence pluripotent stem cell reprogramming using functional screens of known drugs. Our high-throughput screening of drug-like hits showed that imidazopyridines—analogs of zolpidem, a sedative-hypnotic drug—are able to improve reprogramming efficiency and facilitate reprogramming of resistant human primary fibroblasts. The lead compound (O4I3) showed a remarkable OCT4 induction, which at least in part is due to the inhibition of H3K4 demethylase (KDM5, also known as JARID1). Experiments demonstrated that KDM5A, but not its homolog KDM5B, serves as a reprogramming barrier by interfering with the enrichment of H3K4Me3 at the OCT4 promoter. Thus our results introduce a new class of KDM5 chemical inhibitors and provide further insight into the pluripotency-related properties of KDM5 family members. : Biological Sciences; Biochemistry; Molecular Biology Subject Areas: Biological Sciences, Biochemistry, Molecular Biology

Published

2019

22. Functional Tuning of Intrinsically Disordered Regions in Human Proteins by Composition Bias

Author

Kristina Kastano, Pablo Mier, Zsuzsanna Dosztányi, Vasilis J. Promponas, and Miguel A. Andrade-Navarro

Subjects

compositionally biased regions, low complexity regions, intrinsically disordered regions, liquid–liquid phase separation, Microbiology, QR1-502

Abstract

Intrinsically disordered regions (IDRs) in protein sequences are flexible, have low structural constraints and as a result have faster rates of evolution. This lack of evolutionary conservation greatly limits the use of sequence homology for the classification and functional assessment of IDRs, as opposed to globular domains. The study of IDRs requires other properties for their classification and functional prediction. While composition bias is not a necessary property of IDRs, compositionally biased regions (CBRs) have been noted as frequent part of IDRs. We hypothesized that to characterize IDRs, it could be helpful to study their overlap with particular types of CBRs. Here, we evaluate this overlap in the human proteome. A total of 2/3 of residues in IDRs overlap CBRs. Considering CBRs enriched in one type of amino acid, we can distinguish CBRs that tend to be fully included within long IDRs (R, H, N, D, P, G), from those that partially overlap shorter IDRs (S, E, K, T), and others that tend to overlap IDR terminals (Q, A). CBRs overlap more often IDRs in nuclear proteins and in proteins involved in liquid-liquid phase separation (LLPS). Study of protein interaction networks reveals the enrichment of CBRs in IDRs by tandem repetition of short linear motifs (rich in S or P), and the existence of E-rich polar regions that could support specific protein interactions with non-specific interactions. Our results open ways to pin down the function of IDRs from their partial compositional biases.

Published

2022

23. Low Complexity Induces Structure in Protein Regions Predicted as Intrinsically Disordered

Author

Mariane Gonçalves-Kulik, Pablo Mier, Kristina Kastano, Juan Cortés, Pau Bernadó, Friederike Schmid, and Miguel A. Andrade-Navarro

Subjects

intrinsically disordered regions, low complexity regions, protein structure, homorepeats, Microbiology, QR1-502

Abstract

There is increasing evidence that many intrinsically disordered regions (IDRs) in proteins play key functional roles through interactions with other proteins or nucleic acids. These interactions often exhibit a context-dependent structural behavior. We hypothesize that low complexity regions (LCRs), often found within IDRs, could have a role in inducing local structure in IDRs. To test this, we predicted IDRs in the human proteome and analyzed their structures or those of homologous sequences in the Protein Data Bank (PDB). We then identified two types of simple LCRs within IDRs: regions with only one (polyX or homorepeats) or with only two types of amino acids (polyXY). We were able to assign structural information from the PDB more often to these LCRs than to the surrounding IDRs (polyX 61.8% > polyXY 50.5% > IDRs 39.7%). The most frequently observed polyX and polyXY within IDRs contained E (Glu) or G (Gly). Structural analyses of these sequences and of homologs indicate that polyEK regions induce helical conformations, while the other most frequent LCRs induce coil structures. Our work proposes bioinformatics methods to help in the study of the structural behavior of IDRs and provides a solid basis suggesting a structuring role of LCRs within them.

Published

2022

24. RNA Sequencing of Human Peripheral Blood Cells Indicates Upregulation of Immune-Related Genes in Huntington's Disease

Author

Miguel A. Andrade-Navarro, Katja Mühlenberg, Eike J. Spruth, Nancy Mah, Adrián González-López, Tommaso Andreani, Jenny Russ, Matthew R. Huska, Enrique M. Muro, Jean-Fred Fontaine, Vyacheslav Amstislavskiy, Alexei Soldatov, Wilfried Nietfeld, Erich E. Wanker, and Josef Priller

Subjects

RNA-Seq, differential gene expression, Huntington's disease, disease markers, inflammation, Neurology. Diseases of the nervous system, RC346-429

Abstract

Huntington's disease (HD) is an autosomal dominantly inherited neurodegenerative disorder caused by a trinucleotide repeat expansion in the Huntingtin gene. As disease-modifying therapies for HD are being developed, peripheral blood cells may be used to indicate disease progression and to monitor treatment response. In order to investigate whether gene expression changes can be found in the blood of individuals with HD that distinguish them from healthy controls, we performed transcriptome analysis by next-generation sequencing (RNA-seq). We detected a gene expression signature consistent with dysregulation of immune-related functions and inflammatory response in peripheral blood from HD cases vs. controls, including induction of the interferon response genes, IFITM3, IFI6 and IRF7. Our results suggest that it is possible to detect gene expression changes in blood samples from individuals with HD, which may reflect the immune pathology associated with the disease.

Published

2020

25. Nuclear inclusions of pathogenic ataxin-1 induce oxidative stress and perturb the protein synthesis machinery

Author

Stamatia Laidou, Gregorio Alanis-Lobato, Jan Pribyl, Tamás Raskó, Boris Tichy, Kamil Mikulasek, Maria Tsagiopoulou, Jan Oppelt, Georgia Kastrinaki, Maria Lefaki, Manvendra Singh, Annika Zink, Niki Chondrogianni, Fotis Psomopoulos, Alessandro Prigione, Zoltán Ivics, Sarka Pospisilova, Petr Skladal, Zsuzsanna Izsvák, Miguel A. Andrade-Navarro, and Spyros Petrakis

Subjects

Ataxin-1, Polyglutamine, Sleeping beauty transposon, Oxidative stress, Protein network, Ribosome, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Spinocerebellar ataxia type-1 (SCA1) is caused by an abnormally expanded polyglutamine (polyQ) tract in ataxin-1. These expansions are responsible for protein misfolding and self-assembly into intranuclear inclusion bodies (IIBs) that are somehow linked to neuronal death. However, owing to lack of a suitable cellular model, the downstream consequences of IIB formation are yet to be resolved. Here, we describe a nuclear protein aggregation model of pathogenic human ataxin-1 and characterize IIB effects. Using an inducible Sleeping Beauty transposon system, we overexpressed the ATXN1(Q82) gene in human mesenchymal stem cells that are resistant to the early cytotoxic effects caused by the expression of the mutant protein. We characterized the structure and the protein composition of insoluble polyQ IIBs which gradually occupy the nuclei and are responsible for the generation of reactive oxygen species. In response to their formation, our transcriptome analysis reveals a cerebellum-specific perturbed protein interaction network, primarily affecting protein synthesis. We propose that insoluble polyQ IIBs cause oxidative and nucleolar stress and affect the assembly of the ribosome by capturing or down-regulating essential components. The inducible cell system can be utilized to decipher the cellular consequences of polyQ protein aggregation. Our strategy provides a broadly applicable methodology for studying polyQ diseases.

Published

2020

26. Automated selection of homologs to track the evolutionary history of proteins

Author

Pablo Mier, Antonio J. Pérez-Pulido, and Miguel A. Andrade-Navarro

Subjects

Homology, Web tool, Evolutionary path, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background The selection of distant homologs of a query protein under study is a usual and useful application of protein sequence databases. Such sets of homologs are often applied to investigate the function of a protein and the degree to which experimental results can be transferred from one organism to another. In particular, a variety of databases facilitates static browsing for orthologs. However, these resources have a limited power when identifying orthologs between taxonomically distant species. In addition, in some situations, for a given query protein, it is advantageous to compare the sets of orthologs from different specific organisms: this recursive step-wise search might give an idea of the evolutionary path of the protein as a series of consecutive steps, for example gaining or losing domains. However, a step-wise orthology search is a time-consuming task if the number of steps is high. Results To illustrate a solution for this problem, we present the web tool ProteinPathTracker, which allows to track the evolutionary history of a query protein by locating homologs in selected proteomes along several evolutionary paths. Additional functionalities include locking a region of interest to follow its evolution in the discovered homologous sequences and the study of the protein function evolution by analysis of the annotations of the homologs. Conclusions ProteinPathTracker is an easy-to-use web tool that automatises the practice of looking for selected homologs in distant species in a straightforward way for non-expert users.

Published

2018

27. Evolutionary stability of topologically associating domains is associated with conserved gene regulation

Author

Jan Krefting, Miguel A. Andrade-Navarro, and Jonas Ibn-Salem

Subjects

Genome rearrangements, Topologically associating domains, TAD, Chromatin interactions, 3D genome architecture, Hi-C, Biology (General), QH301-705.5

Abstract

Abstract Background The human genome is highly organized in the three-dimensional nucleus. Chromosomes fold locally into topologically associating domains (TADs) defined by increased intra-domain chromatin contacts. TADs contribute to gene regulation by restricting chromatin interactions of regulatory sequences, such as enhancers, with their target genes. Disruption of TADs can result in altered gene expression and is associated to genetic diseases and cancers. However, it is not clear to which extent TAD regions are conserved in evolution and whether disruption of TADs by evolutionary rearrangements can alter gene expression. Results Here, we hypothesize that TADs represent essential functional units of genomes, which are stable against rearrangements during evolution. We investigate this using whole-genome alignments to identify evolutionary rearrangement breakpoints of different vertebrate species. Rearrangement breakpoints are strongly enriched at TAD boundaries and depleted within TADs across species. Furthermore, using gene expression data across many tissues in mouse and human, we show that genes within TADs have more conserved expression patterns. Disruption of TADs by evolutionary rearrangements is associated with changes in gene expression profiles, consistent with a functional role of TADs in gene expression regulation. Conclusions Together, these results indicate that TADs are conserved building blocks of genomes with regulatory functions that are often reshuffled as a whole instead of being disrupted by rearrangements.

Published

2018

28. Geometric characterisation of disease modules

Author

Franziska Härtner, Miguel A. Andrade-Navarro, and Gregorio Alanis-Lobato

Subjects

Protein interactions, Hyperbolic geometry, Disease modules, Greedy routing, Systems biology, Network medicine, Applied mathematics. Quantitative methods, T57-57.97

Abstract

Abstract There is an increasing accumulation of evidence supporting the existence of a hyperbolic geometry underlying the network representation of complex systems. In particular, it has been shown that the latent geometry of the human protein network (hPIN) captures biologically relevant information, leading to a meaningful visual representation of protein-protein interactions and translating challenging systems biology problems into measuring distances between proteins. Moreover, proteins can efficiently communicate with each other, without global knowledge of the hPIN structure, via a greedy routing (GR) process in which hyperbolic distances guide biological signals from source to target proteins. It is thanks to this effective information routing throughout the hPIN that the cell operates, communicates with other cells and reacts to environmental changes. As a result, the malfunction of one or a few members of this intricate system can disturb its dynamics and derive in disease phenotypes. In fact, it is known that the proteins associated with a single disease agglomerate non-randomly in the same region of the hPIN, forming one or several connected components known as the disease module (DM). Here, we present a geometric characterisation of DMs. First, we found that DM positions on the two-dimensional hyperbolic plane reflect their fragmentation and functional heterogeneity, rendering an informative picture of the cellular processes that the disease is affecting. Second, we used a distance-based dissimilarity measure to cluster DMs with shared clinical features. Finally, we took advantage of the GR strategy to study how defective proteins affect the transduction of signals throughout the hPIN.

Published

2018

29. Proteome-wide comparison between the amino acid composition of domains and linkers

Author

Daniel Brüne, Miguel A. Andrade-Navarro, and Pablo Mier

Subjects

Amino acid composition, Domains, Linkers, Medicine, Biology (General), QH301-705.5, Science (General), Q1-390

Abstract

Abstract Objective Amino acid composition is a sequence feature that has been extensively used to characterize proteomes of many species and protein families. Yet the analysis of amino acid composition of protein domains and the linkers connecting them has received less attention. Here, we perform both a comprehensive full-proteome amino acid composition analysis and a similar analysis focusing on domains and linkers, to uncover domain- or linker-specific differential amino acid usage patterns. Results The amino acid composition in the 38 proteomes studied showcase the greater variability found in archaea and bacteria species compared to eukaryotes. When focusing on domains and linkers, we describe the preferential use of polar residues in linkers and hydrophobic residues in domains. To let any user perform this analysis on a given domain (or set of them), we developed a dedicated R script called RACCOON, which can be easily used and can provide interesting insights into the compositional differences between a domain and its surrounding linkers.

Published

2018

30. Prediction of Chromatin Accessibility in Gene-Regulatory Regions from Transcriptomics Data

Author

Sascha Jung, Vladimir Espinosa Angarica, Miguel A. Andrade-Navarro, Noel J. Buckley, and Antonio del Sol

Subjects

Medicine, Science

Abstract

Abstract The epigenetics landscape of cells plays a key role in the establishment of cell-type specific gene expression programs characteristic of different cellular phenotypes. Different experimental procedures have been developed to obtain insights into the accessible chromatin landscape including DNase-seq, FAIRE-seq and ATAC-seq. However, current downstream computational tools fail to reliably determine regulatory region accessibility from the analysis of these experimental data. In particular, currently available peak calling algorithms are very sensitive to their parameter settings and show highly heterogeneous results, which hampers a trustworthy identification of accessible chromatin regions. Here, we present a novel method that predicts accessible and, more importantly, inaccessible gene-regulatory chromatin regions solely relying on transcriptomics data, which complements and improves the results of currently available computational methods for chromatin accessibility assays. We trained a hierarchical classification tree model on publicly available transcriptomics and DNase-seq data and assessed the predictive power of the model in six gold standard datasets. Our method increases precision and recall compared to traditional peak calling algorithms, while its usage is not limited to the prediction of accessible and inaccessible gene-regulatory chromatin regions, but constitutes a helpful tool for optimizing the parameter settings of peak calling methods in a cell type specific manner.

Published

2017

31. Stepwise reprogramming of liver cells to a pancreas progenitor state by the transcriptional regulator Tgif2

Author

Nuria Cerdá-Esteban, Heike Naumann, Silvia Ruzittu, Nancy Mah, Igor M. Pongrac, Corinna Cozzitorto, Angela Hommel, Miguel A. Andrade-Navarro, Ezio Bonifacio, and Francesca M. Spagnoli

Subjects

Science

Abstract

Liver and pancreas cells arise from a common endoderm progenitor in the embryo, but what regulates their cell fate is unclear. Here, the authors show that expression of the Three-Amino-acid-Loop-Extension (TALE) homeobox TG-interacting factor 2 (TGIF2) in hepatocytes reprogrammes the cells to a pancreatic fate.

Published

2017

32. Detection of condition-specific marker genes from RNA-seq data with MGFR

Author

Khadija El Amrani, Gregorio Alanis-Lobato, Nancy Mah, Andreas Kurtz, and Miguel A. Andrade-Navarro

Subjects

Marker genes, Gene expression, Tissue specificity, Cell-type specificity, Single cell, RNA-Seq, Medicine, Biology (General), QH301-705.5

Abstract

The identification of condition-specific genes is key to advancing our understanding of cell fate decisions and disease development. Differential gene expression analysis (DGEA) has been the standard tool for this task. However, the amount of samples that modern transcriptomic technologies allow us to study, makes DGEA a daunting task. On the other hand, experiments with low numbers of replicates lack the statistical power to detect differentially expressed genes. We have previously developed MGFM, a tool for marker gene detection from microarrays, that is particularly useful in the latter case. Here, we have adapted the algorithm behind MGFM to detect markers in RNA-seq data. MGFR groups samples with similar gene expression levels and flags potential markers of a sample type if their highest expression values represent all replicates of this type. We have benchmarked MGFR against other methods and found that its proposed markers accurately characterize the functional identity of different tissues and cell types in standard and single cell RNA-seq datasets. Then, we performed a more detailed analysis for three of these datasets, which profile the transcriptomes of different human tissues, immune and human blastocyst cell types, respectively. MGFR’s predicted markers were compared to gold-standard lists for these datasets and outperformed the other marker detectors. Finally, we suggest novel candidate marker genes for the examined tissues and cell types. MGFR is implemented as a freely available Bioconductor package (https://doi.org/doi:10.18129/B9.bioc.MGFR), which facilitates its use and integration with bioinformatics pipelines.

Published

2019

33. DiseaseLinc: Disease Enrichment Analysis of Sets of Differentially Expressed LincRNAs

Author

Piyush More, Sweta Talyan, Jean-Fred Fontaine, Enrique M. Muro, and Miguel A. Andrade-Navarro

Subjects

lincRNAs, diseases, enrichment analysis, web tool, Cytology, QH573-671

Abstract

Long intergenic non-coding RNAs (LincRNAs) are long RNAs that do not encode proteins. Functional evidence is lacking for most of them. Their biogenesis is not well-known, but it is thought that many lincRNAs originate from genomic duplication of coding material, resulting in pseudogenes, gene copies that lose their original function and can accumulate mutations. While most pseudogenes eventually stop producing a transcript and become erased by mutations, many of these pseudogene-based lincRNAs keep similarity to the parental gene from which they originated, possibly for functional reasons. For example, they can act as decoys for miRNAs targeting the parental gene. Enrichment analysis of function is a powerful tool to discover the functional effects of a treatment producing differential expression of transcripts. However, in the case of lincRNAs, since their function is not easy to define experimentally, such a tool is lacking. To address this problem, we have developed an enrichment analysis tool that focuses on lincRNAs exploiting their functional association, using as a proxy function that of the parental genes and has a focus on human diseases.

Published

2021

34. Author Correction: Loss-of-function uORF mutations in human malignancies

Author

Julia Schulz, Nancy Mah, Martin Neuenschwander, Tabea Kischka, Richard Ratei, Peter M. Schlag, Esmeralda Castaños-Vélez, Iduna Fichtner, Per-Ulf Tunn, Carsten Denkert, Oliver Klaas, Wolfgang E. Berdel, Jens P. von Kries, Wojciech Makalowski, Miguel A. Andrade-Navarro, Achim Leutz, and Klaus Wethmar

Subjects

Medicine, Science

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2021

35. Evolutionary Study of Disorder in Protein Sequences

Author

Kristina Kastano, Gábor Erdős, Pablo Mier, Gregorio Alanis-Lobato, Vasilis J. Promponas, Zsuzsanna Dosztányi, and Miguel A. Andrade-Navarro

Subjects

intrinsically disordered proteins, intrinsically disordered regions, comparative genomics, ortholog comparison, Microbiology, QR1-502

Abstract

Intrinsically disordered proteins (IDPs) contain regions lacking intrinsic globular structure (intrinsically disordered regions, IDRs). IDPs are present across the tree of life, with great variability of IDR type and frequency even between closely related taxa. To investigate the function of IDRs, we evaluated and compared the distribution of disorder content in 10,695 reference proteomes, confirming its high variability and finding certain correlation along the Euteleostomi (bony vertebrates) lineage to number of cell types. We used the comparison of orthologs to study the function of disorder related to increase in cell types, observing that multiple interacting subunits of protein complexes might gain IDRs in evolution, thus stressing the function of IDRs in modulating protein-protein interactions, particularly in the cell nucleus. Interestingly, the conservation of local compositional biases of IDPs follows residue-type specific patterns, with E- and K-rich regions being evolutionarily stable and Q- and A-rich regions being more dynamic. We provide a framework for targeted evolutionary studies of the emergence of IDRs. We believe that, given the large variability of IDR distributions in different species, studies using this evolutionary perspective are required.

Published

2020

36. Comparison of inter- and intraspecies variation in humans and fruit flies

Author

Juliann Shih, Russ Hodge, and Miguel A. Andrade-Navarro

Subjects

Evolution, Population, Variation, Human genome, Drosophila, Genetics, QH426-470

Abstract

Variation is essential to species survival and adaptation during evolution. This variation is conferred by the imperfection of biochemical processes, such as mutations and alterations in DNA sequences, and can also be seen within genomes through processes such as the generation of antibodies. Recent sequencing projects have produced multiple versions of the genomes of humans and fruit flies (Drosophila melanogaster). These give us a chance to study how individual gene sequences vary within and between species. Here we arranged human and fly genes in orthologous pairs and compared such within-species variability with their degree of conservation between flies and humans. We observed that a significant number of proteins associated with mRNA translation are highly conserved between species and yet are highly variable within each species. The fact that we observe this in two species whose lineages separated more than 700 million years ago suggests that this is the result of a very ancient process. We hypothesize that this effect might be attributed to a positive selection for variability of virus-interacting proteins that confers a general resistance to viral hijacking of the mRNA translation machinery within populations. Our analysis points to this and to other processes resulting in positive selection for gene variation.

Published

2015

37. PU.1 Level-Directed Chromatin Structure Remodeling at the Irf8 Gene Drives Dendritic Cell Commitment

Author

Jörg Schönheit, Christiane Kuhl, Marie Luise Gebhardt, Francisco Fernández Klett, Pia Riemke, Marina Scheller, Gang Huang, Ronald Naumann, Achim Leutz, Carol Stocking, Josef Priller, Miguel A. Andrade-Navarro, and Frank Rosenbauer

Subjects

Biology (General), QH301-705.5

Abstract

Dendritic cells (DCs) are essential regulators of immune responses; however, transcriptional mechanisms that establish DC lineage commitment are poorly defined. Here, we report that the PU.1 transcription factor induces specific remodeling of the higher-order chromatin structure at the interferon regulatory factor 8 (Irf8) gene to initiate DC fate choice. An Irf8 reporter mouse enabled us to pinpoint an initial progenitor stage at which DCs separate from other myeloid lineages in the bone marrow. In the absence of Irf8, this progenitor undergoes DC-to-neutrophil reprogramming, indicating that DC commitment requires an active, Irf8-dependent escape from alternative myeloid lineage potential. Mechanistically, myeloid Irf8 expression depends on high PU.1 levels, resulting in local chromosomal looping and activation of a lineage- and developmental-stage-specific cis-enhancer. These data delineate PU.1 as a concentration-dependent rheostat of myeloid lineage selection by controlling long-distance contacts between regulatory elements and suggest that specific higher-order chromatin remodeling at the Irf8 gene determines DC differentiation.

Published

2013

38. Function and Evolution of Nematode RNAi Pathways

Author

Miguel Vasconcelos Almeida, Miguel A. Andrade-Navarro, and René F. Ketting

Subjects

small RNA, piRNA, 22G RNA, 26G RNA, 21U RNA, siRNA, Argonaute, RdRP, Piwi, C. elegans, nematode, Genetics, QH426-470

Abstract

Selfish genetic elements, like transposable elements or viruses, are a threat to genomic stability. A variety of processes, including small RNA-based RNA interference (RNAi)-like pathways, has evolved to counteract these elements. Amongst these, endogenous small interfering RNA and Piwi-interacting RNA (piRNA) pathways were implicated in silencing selfish genetic elements in a variety of organisms. Nematodes have several incredibly specialized, rapidly evolving endogenous RNAi-like pathways serving such purposes. Here, we review recent research regarding the RNAi-like pathways of Caenorhabditis elegans as well as those of other nematodes, to provide an evolutionary perspective. We argue that multiple nematode RNAi-like pathways share piRNA-like properties and together form a broad nematode toolkit that allows for silencing of foreign genetic elements.

Published

2019

39. FASTA Herder: a web application to trim protein sequence sets

Author

Caroline Louis-Jeune, Miguel A. Andrade-Navarro, and Carol Perez-Iratxeta

Subjects

Multiple sequence alignment, BLAST, FASTA, Software, Web service, Sequence similarity, Science, Social Sciences

Abstract

The ever increasing number of sequences in protein databases usually turns out large numbers of homologs in sequence similarity searches. While information from homology can be very useful for functional prediction based on amino acid conservation, many of these homologs usually have high levels of identity among themselves, which hinders multiple sequence alignment computation and, especially, visualization. More generally, high redundancy reduces the usability of a protein set in machine learning applications and biases statistical analyses. We developed an algorithm to identify redundant sequence homologs that can be culled producing a streamlined FASTA file. As a difference from other automatic approaches that only aggregate sequences with high identity, our method clusters near full-length homologs allowing for lower sequence identity thresholds. Our method was fully tested and implemented in a web application called FASTA Herder, publicly available at http://fh.ogic.ca.

Published

2014

40. The sequence context in poly-alanine regions: structure, function and conservation.

Author

Pablo Mier, Carlos A. Elena-Real, Juan Cortés, Pau Bernadó, and Miguel A. Andrade-Navarro

Published

2022

41. Towards Identifying Drug Side Effects from Social Media Using Active Learning andCrowd Sourcing.

Author

Sophie Burkhardt, Julia Siekiera, Josua Glodde, Miguel A. Andrade-Navarro, and Stefan Kramer 0001

Published

2020

42. RepeatsDB in 2021: improved data and extended classification for protein tandem repeat structures.

Author

Lisanna Paladin, Martina Bevilacqua, Sara Errigo, Damiano Piovesan, Ivan Micetic, Marco Necci, Alexander Miguel Monzon, Maria Laura Fabre, José Luis López, Juliet F. Nilsson, Javier Ríos, Pablo Lorenzano Menna, Maia Cabrera, Martin Gonzalez Buitron, Mariane Gonçalves Kulik, Sebastian Fernandez Alberti, María Silvina Fornasari, Gustavo D. Parisi, Antonio Lagares, Layla Hirsh, Miguel A. Andrade-Navarro, Andrey V. Kajava, and Silvio C. E. Tosatto

Published

2021

43. PlaToLoCo: the first web meta-server for visualization and annotation of low complexity regions in proteins.

Author

Patryk Jarnot, Joanna Ziemska-Legiecka, Laszlo Dobson, Matthew Merski, Pablo Mier, Miguel A. Andrade-Navarro, John M. Hancock, Zsuzsanna Dosztányi, Lisanna Paladin, Marco Necci, Damiano Piovesan, Silvio C. E. Tosatto, Vasilis J. Promponas, Marcin Grynberg, and Aleksandra Gruca

Published

2020

44. Disentangling the complexity of low complexity proteins.

Author

Pablo Mier, Lisanna Paladin, Stella Tamana, Sophia Petrosian, Borbála Hajdu-Soltész, Annika Urbanek, Aleksandra Gruca, Dariusz Plewczynski, Marcin Grynberg, Pau Bernadó, Zoltán Gáspári, Christos A. Ouzounis, Vasilis J. Promponas, Andrey V. Kajava, John M. Hancock, Silvio C. E. Tosatto, Zsuzsanna Dosztányi, and Miguel A. Andrade-Navarro

Published

2020

45. Toward completion of the Earth's proteome: an update a decade later.

Author

Pablo Mier and Miguel A. Andrade-Navarro

Published

2019

46. Lost Strings in Genomes: What Sense Do They Make?

Author

Michael G. Sadovsky, Jean-Fred Fontaine, Miguel A. Andrade-Navarro, Yury Yakubailik, and Natalia Rudenko

Published

2017

47. Disease-Genes Must Guide Data Source Integration in the Gene Prioritization Process.

Author

Marco Frasca 0001, Jean-Fred Fontaine, Giorgio Valentini, Marco Mesiti, Marco Notaro, Dario Malchiodi, and Miguel A. Andrade-Navarro

Published

2017

48. The latent geometry of the human protein interaction network.

Author

Gregorio Alanis-Lobato, Pablo Mier, and Miguel A. Andrade-Navarro

Published

2018

49. LipiDisease: associate lipids to diseases using literature mining.

Author

Piyush More, Laura Bindila, Philipp Wild, Miguel A. Andrade-Navarro, and Jean-Fred Fontaine

Published

2021

50. Traitpedia: a collaborative effort to gather species traits.

Author

Pablo Mier and Miguel A. Andrade-Navarro

Published

2019