Your search keyword '"Rosário-Ferreira N"' showing total 14 results

1. Targeting GPCRs Via Multi-Platform Arrays and AI

Author

Preto, A.J., primary, Marques-Pereira, C, additional, Baptista, Salete J., additional, Bueschbell, B., additional, Barreto, Carlos A.V., additional, Gaspar, A.T., additional, Pinheiro, I., additional, Pereira, N., additional, Pires, M., additional, Ramalhão, D., additional, Silvério, D., additional, Rosário-Ferreira, N., additional, Melo, R., additional, Mourão, J., additional, and Moreira, I.S., additional

Published

2022

2. From single-omics to interactomics: How can ligand-induced perturbations modulate single-cell phenotypes?

Author

Piochi, L.F., primary, Gaspar, A.T., additional, Rosário-Ferreira, N., additional, Preto, A.J., additional, and Moreira, I.S., additional

Published

2022

3. Chapter Two - From single-omics to interactomics: How can ligand-induced perturbations modulate single-cell phenotypes?

Author

Piochi, L.F., Gaspar, A.T., Rosário-Ferreira, N., Preto, A.J., and Moreira, I.S.

Published

2022

4. Targeting GPCRs Via Multi-Platforms Arrays and AI

Author

Preto, A.J., Marques-Pereira, C, Baptista, Salete J., Bueschbell, B., Barreto, Carlos A.V., Gaspar, A.T., Pinheiro, I., Pereira, N., Pires, M., Ramalhão, D., Silvério, D., Rosário-Ferreira, N., Melo, R., Mourão, J., and Moreira, I.S.

Published

2015

5. Leveraging Artificial Intelligence in GPCR Activation Studies: Computational Prediction Methods as Key Drivers of Knowledge.

Author

Caniceiro AB, Orzeł U, Rosário-Ferreira N, Filipek S, and Moreira IS

Subjects

Humans, Ligands, Algorithms, Databases, Protein, Signal Transduction, Receptors, G-Protein-Coupled metabolism, Receptors, G-Protein-Coupled chemistry, Artificial Intelligence, Molecular Dynamics Simulation, Computational Biology methods

Abstract

G protein-coupled receptors (GPCRs) are key molecules involved in cellular signaling and are attractive targets for pharmacological intervention. This chapter is designed to explore the range of algorithms used to predict GPCRs' activation states, while also examining the pharmaceutical implications of these predictions. Our primary objective is to show how artificial intelligence (AI) is key in GPCR research to reveal the intricate dynamics of activation and inactivation processes, shedding light on the complex regulatory mechanisms of this vital protein family. We describe several computational strategies that leverage diverse structural data from the Protein Data Bank, molecular dynamic simulations, or ligand-based methods to predict the activation states of GPCRs. We demonstrate how the integration of AI into GPCR research not only enhances our understanding of their dynamic properties but also presents immense potential for driving pharmaceutical research and development, offering promising new avenues in the search for newer, better therapeutic agents., (© 2025. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2025

6. Advancing Drug Safety in Drug Development: Bridging Computational Predictions for Enhanced Toxicity Prediction.

Author

Amorim AMB, Piochi LF, Gaspar AT, Preto AJ, Rosário-Ferreira N, and Moreira IS

Subjects

Humans, Animals, Drug Development, Drug-Related Side Effects and Adverse Reactions

Abstract

The attrition rate of drugs in clinical trials is generally quite high, with estimates suggesting that approximately 90% of drugs fail to make it through the process. The identification of unexpected toxicity issues during preclinical stages is a significant factor contributing to this high rate of failure. These issues can have a major impact on the success of a drug and must be carefully considered throughout the development process. These late-stage rejections or withdrawals of drug candidates significantly increase the costs associated with drug development, particularly when toxicity is detected during clinical trials or after market release. Understanding drug-biological target interactions is essential for evaluating compound toxicity and safety, as well as predicting therapeutic effects and potential off-target effects that could lead to toxicity. This will enable scientists to predict and assess the safety profiles of drug candidates more accurately. Evaluation of toxicity and safety is a critical aspect of drug development, and biomolecules, particularly proteins, play vital roles in complex biological networks and often serve as targets for various chemicals. Therefore, a better understanding of these interactions is crucial for the advancement of drug development. The development of computational methods for evaluating protein-ligand interactions and predicting toxicity is emerging as a promising approach that adheres to the 3Rs principles (replace, reduce, and refine) and has garnered significant attention in recent years. In this review, we present a thorough examination of the latest breakthroughs in drug toxicity prediction, highlighting the significance of drug-target binding affinity in anticipating and mitigating possible adverse effects. In doing so, we aim to contribute to the development of more effective and secure drugs.

Published

2024

7. Designer high-density lipoprotein particles enhance endothelial barrier function and suppress inflammation.

Author

Lin YC, Swendeman S, Moreira IS, Ghosh A, Kuo A, Rosário-Ferreira N, Guo S, Culbertson A, Levesque MV, Cartier A, Seno T, Schmaier A, Galvani S, Inoue A, Parikh SM, FitzGerald GA, Zurakowski D, Liao M, Flaumenhaft R, Gümüş ZH, and Hla T

Subjects

Humans, Mice, Animals, Receptors, Lysosphingolipid metabolism, Apolipoproteins M, Inflammation, Lipoproteins, HDL pharmacology, Lipoproteins, HDL metabolism, Lysophospholipids pharmacology, Lysophospholipids metabolism, Sphingosine, Apolipoproteins metabolism, Apolipoproteins pharmacology, Lipocalins metabolism, Lipocalins pharmacology

Abstract

High-density lipoprotein (HDL) nanoparticles promote endothelial cell (EC) function and suppress inflammation, but their utility in treating EC dysfunction has not been fully explored. Here, we describe a fusion protein named ApoA1-ApoM (A1M) consisting of apolipoprotein A1 (ApoA1), the principal structural protein of HDL that forms lipid nanoparticles, and ApoM, a chaperone for the bioactive lipid sphingosine 1-phosphate (S1P). A1M forms HDL-like particles, binds to S1P, and is signaling competent. Molecular dynamics simulations showed that the S1P-bound ApoM moiety in A1M efficiently activated EC surface receptors. Treatment of human umbilical vein ECs with A1M-S1P stimulated barrier function either alone or cooperatively with other barrier-enhancing molecules, including the stable prostacyclin analog iloprost, and suppressed cytokine-induced inflammation. A1M-S1P injection into mice during sterile inflammation suppressed neutrophil influx and inflammatory mediator secretion. Moreover, systemic A1M administration led to a sustained increase in circulating HDL-bound S1P and suppressed inflammation in a murine model of LPS-induced endotoxemia. We propose that A1M administration may enhance vascular endothelial barrier function, suppress cytokine storm, and promote resilience of the vascular endothelium.

Published

2024

8. SARS-CoV-2 Membrane Protein: From Genomic Data to Structural New Insights.

Author

Marques-Pereira C, Pires MN, Gouveia RP, Pereira NN, Caniceiro AB, Rosário-Ferreira N, and Moreira IS

Subjects

Binding Sites genetics, COVID-19 prevention & control, COVID-19 virology, Coronavirus M Proteins chemistry, Coronavirus M Proteins metabolism, Humans, Molecular Dynamics Simulation, Protein Binding, Protein Domains, Protein Multimerization, SARS-CoV-2 physiology, Coronavirus M Proteins genetics, Genome, Viral genetics, Mutation, Polymorphism, Single Nucleotide, SARS-CoV-2 genetics

Abstract

Severe Acute Respiratory Syndrome CoronaVirus-2 (SARS-CoV-2) is composed of four structural proteins and several accessory non-structural proteins. SARS-CoV-2's most abundant structural protein, Membrane (M) protein, has a pivotal role both during viral infection cycle and host interferon antagonism. This is a highly conserved viral protein, thus an interesting and suitable target for drug discovery. In this paper, we explain the structural nature of M protein homodimer. To do so, we developed and applied a detailed and robust in silico workflow to predict M protein dimeric structure, membrane orientation, and interface characterization. Single Nucleotide Polymorphisms (SNPs) in M protein were retrieved from over 1.2 M SARS-CoV-2 genomes and proteins from the Global Initiative on Sharing All Influenza Data (GISAID) database, 91 of which were located at the predicted dimer interface. Among those, we identified SNPs in Variants of Concern (VOC) and Variants of Interest (VOI). Binding free energy differences were evaluated for dimer interfacial SNPs to infer mutant protein stabilities. A few high-prevalent mutated residues were found to be especially relevant in VOC and VOI. This realization may be a game-changer to structure-driven formulation of new therapeutics for SARS-CoV-2.

Published

2022

9. From single-omics to interactomics: How can ligand-induced perturbations modulate single-cell phenotypes?

Author

Piochi LF, Gaspar AT, Rosário-Ferreira N, Preto AJ, and Moreira IS

Subjects

Epigenomics, Ligands, Phenotype, Genomics, Metabolomics

Abstract

Cells suffer from perturbations by different stimuli, which, consequently, rise to individual alterations in their profile and function that may end up affecting the tissue as a whole. This is no different if we consider the effect of a therapeutic agent on a biological system. As cells are exposed to external ligands their profile can change at different single-omics levels. Detecting how these changes take place through different sequencing technologies is key to a better understanding of the effects of therapeutic agents. Single-cell RNA-sequencing stands out as one of the most common approaches for cell profiling and perturbation analysis. As a result, single-cell transcriptomics data can be integrated with other omics data sources, such as proteomics and epigenomics data, to clarify the perturbation effects and mechanism at the cell level. Appropriate computational tools are key to process and integrate the available information. This chapter focuses on the recent advances on ligand-induced perturbation and single-cell omics computational tools and algorithms, their current limitations, and how the deluge of data can be used to improve the current process of drug research and development., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

10. Network biology and artificial intelligence drive the understanding of the multidrug resistance phenotype in cancer.

Author

Bueschbell B, Caniceiro AB, Suzano PMS, Machuqueiro M, Rosário-Ferreira N, and Moreira IS

Subjects

Biology, Drug Resistance, Multiple genetics, Humans, Phenotype, Artificial Intelligence, Neoplasms drug therapy, Neoplasms genetics, Neoplasms metabolism

Abstract

Globally with over 10 million deaths per year, cancer is the most transversal disease across countries, cultures, and ethnicities, affecting both developed and developing regions. Tumorigenesis is dynamically altered by distinct events and can be lethal when untreated. Despite the innovative therapeutics available, multidrug resistance (MDR) to chemotherapy remains the major hindrance to the success of cancer therapy. The multiple mechanisms by which cancer cells evade cell death are diverse, indicating that MDR involves complex interconnected biological networks. Molecular profiling is currently able to stratify cancer into its distinct subtypes and help identify the best therapeutics, leading to "translational systems medicine". Highly specialized methodologies are generating a large amount of "omics" data - including epigenetics, genomics, transcriptomics, proteomics, metabolomics, as well as pharmacogenomics. Many of the resulting databases store data in non-standard formats, which need to be converted, interpreted, and merged into readable formats. The latest development of artificial intelligence (AI) methodologies and tools, coupled with advancements in large-scale data management and powerful graphic processing computing units, potentiate the integration of these large data sources into relevant biological networks, which will enhance our understanding of cancer MDR. In this review, we revisit common MDR mechanisms and compile a list of the most relevant "omics" public databases. We highlight examples of AI methods that are now decisively contributing to clear advances in cancer research, such as identification of new drugs from large databases and prediction of relevant drug, target, and system properties. An overview of several freely available "ready-to-use" algorithms is also provided. The described molecular scale AI algorithms and tools will undoubtedly guide important improvements in efficiency and efficacy of traditional methods of cancer diagnostics and treatment., (Copyright © 2022. Published by Elsevier Ltd.)

Published

2022

11. In Silico End-to-End Protein-Ligand Interaction Characterization Pipeline: The Case of SARS-CoV-2.

Author

Rosário-Ferreira N, Baptista SJ, Barreto CAV, Rodrigues FEP, Silva TFD, Ferreira SGF, Vitorino JNM, Melo R, Victor BL, Machuqueiro M, and Moreira IS

Subjects

Antiviral Agents therapeutic use, Humans, Ligands, Antiviral Agents chemistry, Databases, Protein, Molecular Docking Simulation, Molecular Dynamics Simulation, SARS-CoV-2 chemistry, Viral Proteins chemistry, COVID-19 Drug Treatment

Abstract

SARS-CoV-2 triggered a worldwide pandemic disease, COVID-19, for which an effective treatment has not yet been settled. Among the most promising targets to fight this disease is SARS-CoV-2 main protease (M pro ), which has been extensively studied in the last few months. There is an urgency for developing effective computational protocols that can help us tackle these key viral proteins. Hence, we have put together a robust and thorough pipeline of in silico protein-ligand characterization methods to address one of the biggest biological problems currently plaguing our world. These methodologies were used to characterize the interaction of SARS-CoV-2 M pro with an α-ketoamide inhibitor and include details on how to upload, visualize, and manage the three-dimensional structure of the complex and acquire high-quality figures for scientific publications using PyMOL (Protocol 1); perform homology modeling with MODELLER (Protocol 2); perform protein-ligand docking calculations using HADDOCK (Protocol 3); run a virtual screening protocol of a small compound database of SARS-CoV-2 candidate inhibitors with AutoDock 4 and AutoDock Vina (Protocol 4); and, finally, sample the conformational space at the atomic level between SARS-CoV-2 M pro and the α-ketoamide inhibitor with Molecular Dynamics simulations using GROMACS (Protocol 5). Guidelines for careful data analysis and interpretation are also provided for each Protocol.

Published

2021

12. SicknessMiner: a deep-learning-driven text-mining tool to abridge disease-disease associations.

Author

Rosário-Ferreira N, Guimarães V, Costa VS, and Moreira IS

Subjects

Data Mining, Knowledge, Deep Learning

Abstract

Background: Blood cancers (BCs) are responsible for over 720 K yearly deaths worldwide. Their prevalence and mortality-rate uphold the relevance of research related to BCs. Despite the availability of different resources establishing Disease-Disease Associations (DDAs), the knowledge is scattered and not accessible in a straightforward way to the scientific community. Here, we propose SicknessMiner, a biomedical Text-Mining (TM) approach towards the centralization of DDAs. Our methodology encompasses Named Entity Recognition (NER) and Named Entity Normalization (NEN) steps, and the DDAs retrieved were compared to the DisGeNET resource for qualitative and quantitative comparison., Results: We obtained the DDAs via co-mention using our SicknessMiner or gene- or variant-disease similarity on DisGeNET. SicknessMiner was able to retrieve around 92% of the DisGeNET results and nearly 15% of the SicknessMiner results were specific to our pipeline., Conclusions: SicknessMiner is a valuable tool to extract disease-disease relationship from RAW input corpus., (© 2021. The Author(s).)

Published

2021

13. Guardians of the Cell: State-of-the-Art of Membrane Proteins from a Computational Point-of-View.

Author

Rosário-Ferreira N, Marques-Pereira C, Gouveia RP, Mourão J, and Moreira IS

Subjects

Algorithms, Computational Biology methods, Computer Simulation, Models, Molecular, Protein Folding, Membrane Proteins chemistry

Abstract

Membrane proteins (MPs) encompass a large family of proteins with distinct cellular functions, and although representing over 50% of existing pharmaceutical drug targets, their structural and functional information is still very scarce. Over the last years, in silico analysis and algorithm development were essential to characterize MPs and overcome some limitations of experimental approaches. The optimization and improvement of these methods remain an ongoing process, with key advances in MPs' structure, folding, and interface prediction being continuously tackled. Herein, we discuss the latest trends in computational methods toward a deeper understanding of the atomistic and mechanistic details of MPs., (© 2021. Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2021

14. The Central Role of Non-Structural Protein 1 (NS1) in Influenza Biology and Infection.

Author

Rosário-Ferreira N, Preto AJ, Melo R, Moreira IS, and Brito RMM

Subjects

Animals, Humans, Influenza A Virus, H1N1 Subtype genetics, Influenza A Virus, H1N1 Subtype metabolism, Influenza Vaccines administration & dosage, Influenza, Human prevention & control, Influenza, Human virology, Mutation, Orthomyxoviridae Infections prevention & control, Orthomyxoviridae Infections virology, Protein Conformation, Viral Nonstructural Proteins chemistry, Viral Nonstructural Proteins metabolism, Virion genetics, Virion metabolism, Influenza A Virus, H1N1 Subtype immunology, Influenza Vaccines immunology, Influenza, Human immunology, Orthomyxoviridae Infections immunology, Viral Nonstructural Proteins immunology, Virion immunology

Abstract

Influenza (flu) is a contagious viral disease, which targets the human respiratory tract and spreads throughout the world each year. Every year, influenza infects around 10% of the world population and between 290,000 and 650,000 people die from it according to the World Health Organization (WHO). Influenza viruses belong to the Orthomyxoviridae family and have a negative sense eight-segment single-stranded RNA genome that encodes 11 different proteins. The only control over influenza seasonal epidemic outbreaks around the world are vaccines, annually updated according to viral strains in circulation, but, because of high rates of mutation and recurrent genetic assortment, new viral strains of influenza are constantly emerging, increasing the likelihood of pandemics. Vaccination effectiveness is limited, calling for new preventive and therapeutic approaches and a better understanding of the virus-host interactions. In particular, grasping the role of influenza non-structural protein 1 (NS1) and related known interactions in the host cell is pivotal to better understand the mechanisms of virus infection and replication, and thus propose more effective antiviral approaches. In this review, we assess the structure of NS1, its dynamics, and multiple functions and interactions, to highlight the central role of this protein in viral biology and its potential use as an effective therapeutic target to tackle seasonal and pandemic influenza.

Published

2020