The secrets of life lie in the molecular flexibility.

Welcome to Prof. Mariusz Jaremko's research group, the

Flexible Systems Lab!

Our research group works mainly on metabolites which are important for human health, and our current main focus in this discipline is oriented towards food, food safety, food quality, and food fraud by utilizing state-of-the-art instrumentation in metabolomics studies. We are also working on aggregation of amylin, a biological peptide that is connected tightly with diabetes II, a disease that is closely related to unhealthy diets. So, food science and the consequences of the food we eat are one of the main areas which the group Flexible Systems investigates. We are also working to develop methods and pulse programs in Nuclear Magnetic Resonance (NMR) that allow us to uncover obscured metabolites and to detect them at lower concentrations, in order to understand metabolic pathways better. 


Why the name Flexible Systems?

It's simple; because metabolites, as well as amylin and its analogues, are very flexible systems i.e. amylin does not have a defined 3D structure, and in the case of the small molecules and metabolites we study, while they do have defined structures, they often exhibit very high levels of dynamic flexibility due to their size.

Untangling untidy folds to understand diseases

Copper ions could play a key role when peptide folding goes wrong and leads to harmful aggregates.

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Picking the best methods for metabolomics research

Comparison of different nuclear magnetic resonance spectroscopy methods has helped to identify the most robust approach for studying different types of biomolecules.

Latest Publications

Fluxomics - New Metabolomics Approaches to Monitor Metabolic Pathways

by Abdul-Hamid Emwas, Kacper Szczepski, Inas Al-Younis, Joanna Izabela Lachowicz, Mariusz Jaremko
Review Article Year: 2022 DOI: https://doi.org/10.3389/fphar.2022.805782

Abstract

Fluxomics is an innovative -omics research field that measures the rates of all intracellular fluxes in the central metabolism of biological systems. Fluxomics gathers data from multiple different -omics fields, portraying the whole picture of molecular interactions. Recently, fluxomics has become one of the most relevant approaches to investigate metabolic phenotypes. Metabolic flux using 13C-labeled molecules is increasingly used to monitor metabolic pathways, to probe the corresponding gene-RNA and protein-metabolite interaction networks in actual time. Thus, fluxomics reveals the functioning of multi-molecular metabolic pathways and is increasingly applied in biotechnology and pharmacology. Here, we describe the main fluxomics approaches and experimental platforms. Moreover, we summarize recent fluxomic results in different biological systems.