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1. Cross-feeding percolation phase transitions of inter-cellular metabolic networks

Author

Latoski, Luís C. F., De Martino, Andrea, and De Martino, Daniele

Subjects
Condensed Matter - Statistical Mechanics, Quantitative Biology - Cell Behavior
Abstract

Intercellular exchange networks are essential for the adaptive capabilities of populations of cells. While diffusional exchanges have traditionally been difficult to map, recent advances in nanotechnology enable precise probing of exchange fluxes with the medium at single-cell resolution. Here we introduce a tiling-based method to reconstruct the dynamic unfolding of exchange networks from flux data, subsequently applying it to an experimental mammalian co-culture system where lactate exchanges affect the acidification of the environment. We observe that the network, which initially exhibits a dense matrix of exchanges, progressively breaks up into small disconnected clusters of cells. To explain this behaviour, we develop a two-parameter Maximum-Entropy multicellular metabolic model that incorporates diffusion-driven exchanges through a set of global constraints that couple cellular behaviors. The model predicts a transition from a densely interconnected network to a sparse, motif-dominated state as glucose and oxygen consumption levels shift. We characterize such a crossover both numerically, revealing a power-law decay in the cluster-size distribution at the critical transition, and analytically, by computing the critical line through a mean-field approximation based on percolation theory. By comparing empirical data with theoretical predictions, we find that populations evolve towards the sparse phase by remaining near the crossover point between these two regimes. These findings offer new insights into the collective organization driving the adaptive dynamics of cell populations., Comment: 12 pages, 5 figures, comments are welcome

Published
2024

2. Synthetic Lagrangian Turbulence by Generative Diffusion Models

Author

Li, Tianyi, Biferale, Luca, Bonaccorso, Fabio, Scarpolini, Martino Andrea, and Buzzicotti, Michele

Subjects
Physics - Fluid Dynamics, Condensed Matter - Statistical Mechanics, Computer Science - Computational Engineering, Finance, and Science, Computer Science - Machine Learning, Nonlinear Sciences - Chaotic Dynamics
Abstract

Lagrangian turbulence lies at the core of numerous applied and fundamental problems related to the physics of dispersion and mixing in engineering, bio-fluids, atmosphere, oceans, and astrophysics. Despite exceptional theoretical, numerical, and experimental efforts conducted over the past thirty years, no existing models are capable of faithfully reproducing statistical and topological properties exhibited by particle trajectories in turbulence. We propose a machine learning approach, based on a state-of-the-art diffusion model, to generate single-particle trajectories in three-dimensional turbulence at high Reynolds numbers, thereby bypassing the need for direct numerical simulations or experiments to obtain reliable Lagrangian data. Our model demonstrates the ability to reproduce most statistical benchmarks across time scales, including the fat-tail distribution for velocity increments, the anomalous power law, and the increased intermittency around the dissipative scale. Slight deviations are observed below the dissipative scale, particularly in the acceleration and flatness statistics. Surprisingly, the model exhibits strong generalizability for extreme events, producing events of higher intensity and rarity that still match the realistic statistics. This paves the way for producing synthetic high-quality datasets for pre-training various downstream applications of Lagrangian turbulence., Comment: We include Supplementary Information as a separate PDF file available in the Tex Source download area

Published
2023
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3. Optimal metabolic strategies for microbial growth in stationary random environments

Author

Muntoni, Anna Paola and De Martino, Andrea

Subjects
Physics - Biological Physics, Condensed Matter - Disordered Systems and Neural Networks, Quantitative Biology - Molecular Networks, Quantitative Biology - Populations and Evolution
Abstract

In order to grow in any given environment, bacteria need to collect information about the medium composition and implement suitable growth strategies by adjusting their regulatory and metabolic degrees of freedom. In the standard sense, optimal strategy selection is achieved when bacteria grow at the fastest rate possible in that medium. While this view of optimality is well suited for cells that have perfect knowledge about their surroundings (e.g. nutrient levels), things are more involved in uncertain or fluctuating conditions, especially when changes occur over timescales comparable to (or faster than) those required to organize a response. Information theory however provides recipes for how cells can choose the optimal growth strategy under uncertainty about the stress levels they will face. Here we analyse the theoretically optimal scenarios for a coarse-grained, experiment-inspired model of bacterial metabolism for growth in a medium described by the (static) probability density of a single variable (the `stress level'). We show that heterogeneity in growth rates consistently emerges as the optimal response when the environment is sufficiently complex and/or when perfect adjustment of metabolic degrees of freedom is not possible (e.g. due to limited resources). In addition, outcomes close to those achievable with unlimited resources are often attained effectively with a modest amount of fine tuning. In other terms, heterogeneous population structures in complex media may be rather robust with respect to the resources available to probe the environment and adjust reaction rates.

Published
2022
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4. Statistical-physics approaches to RNA molecules, families and networks

Author

Cocco, Simona, De Martino, Andrea, Pagnani, Andrea, and Weigt, Martin

Subjects
Condensed Matter - Statistical Mechanics, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics, Quantitative Biology - Biomolecules, Quantitative Biology - Molecular Networks
Abstract

This contribution focuses on the fascinating RNA molecule, its sequence-dependent folding driven by base-pairing interactions, the interplay between these interactions and natural evolution, and its multiple regulatory roles. The four of us have dug into these topics using the tools and the spirit of the statistical physics of disordered systems, and in particular the concept of a disordered (energy/fitness) landscape. After an introduction to RNA molecules and the perspectives they open not only in evolutionary and synthetic biology but also in medicine, we will introduce the important notions of energy and fitness landscapes for these molecules. In Section III we will review some models and algorithms for RNA sequence-to-secondary-structure mapping. Section IV discusses how the secondary-structure energy landscape can be derived from unzipping data. Section V deals with the inference of RNA structure from evolutionary sequence data sampled in different organisms. This will shift the focus from the `sequence-to-structure' mapping described in Section III to a `sequence-to-function' landscape that can be inferred from laboratory evolutionary data on DNA aptamers. Finally, in Section VI, we shall discuss the rich theoretical picture linking networks of interacting RNA molecules to the organization of robust, systemic regulatory programs. Along this path, we will therefore explore phenomena across multiple scales in space, number of molecules and time, showing how the biological complexity of the RNA world can be captured by the unifying concepts of statistical physics., Comment: 19 pages, 6 figures, to appear in "Spin Glass Theory and Far Beyond - Replica Symmetry Breaking after 40 years" (edited by P Charbonneau, E Marinari, G Parisi, F Ricci Tersenghi, G Sicuro and F Zamponi)

Published
2022

8. Path-integral solution of MacArthur's resource-competition model for large ecosystems with random species-resources couplings

Author

Batista-Tomas, A. R., De Martino, Andrea, and Mulet, Roberto

Subjects
Quantitative Biology - Populations and Evolution, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics
Abstract

We solve MacArthur's resource-competition model with random species-resource couplings in the `thermodynamic' limit of infinitely many species and resources using dynamical path-integrals a la De Domincis. We analyze how the steady state picture changes upon modifying several parameters, including the degree of heterogeneity of metabolic strategies (encoding the preferences of species) and of maximal resource levels (carrying capacities), and discuss its stability. Ultimately, the scenario obtained by other approaches is recovered by analyzing an effective one-species-one-resource ecosystem that is fully equivalent to the original multi-species one. The technique used here can be applied for the analysis of other model ecosystems related to the version of MacArthur's model considered here., Comment: This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in Chaos 31, 103113 (2021) and may be found at https://aip.scitation.org/doi/full/10.1063/5.0046972

Published
2021
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9. Relationship between fitness and heterogeneity in exponentially growing microbial populations

Author

Muntoni, Anna Paola, Braunstein, Alfredo, Pagnani, Andrea, De Martino, Daniele, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Physics - Biological Physics, Quantitative Biology - Quantitative Methods
Abstract

Despite major environmental and genetic differences, microbial metabolic networks are known to generate consistent physiological outcomes across vastly different organisms. This remarkable robustness suggests that, at least in bacteria, metabolic activity may be guided by universal principles. The constrained optimization of evolutionarily-motivated objective functions like the growth rate has emerged as the key theoretical assumption for the study of bacterial metabolism. While conceptually and practically useful in many situations, the idea that certain functions are optimized is hard to validate in data. Moreover, it is not always clear how optimality can be reconciled with the high degree of single-cell variability observed in experiments within microbial populations. To shed light on these issues, we develop an inverse modeling framework that connects the fitness of a population of cells (represented by the mean single-cell growth rate) to the underlying metabolic variability through the Maximum-Entropy inference of the distribution of metabolic phenotypes from data. While no clear objective function emerges, we find that, as the medium gets richer, the fitness and inferred variability for Escherichia coli populations follow and slowly approach the theoretically optimal bound defined by minimal reduction of variability at given fitness. These results suggest that bacterial metabolism may be crucially shaped by a population-level trade-off between growth and heterogeneity., Comment: 12+30 pages (includes Supporting Text)

Published
2021
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14. Competing endogenous RNA crosstalk at system level

Author

Miotto, Mattia, Marinari, Enzo, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics, Quantitative Biology - Quantitative Methods
Abstract

microRNAs (miRNAs) regulate gene expression at post-transcriptional level by repressing target RNA molecules. Competition to bind miRNAs tends in turn to correlate their targets, establishing effective RNA-RNA interactions that can influence expression levels, buffer fluctuations and promote signal propagation. Such a potential has been characterized mathematically for small motifs both at steady state and \red{away from stationarity}. Experimental evidence, on the other hand, suggests that competing endogenous RNA (ceRNA) crosstalk is rather weak. Extended miRNA-RNA networks could however favour the integration of many crosstalk interactions, leading to significant large-scale effects in spite of the weakness of individual links. To clarify the extent to which crosstalk is sustained by the miRNA interactome, we have studied its emergent systemic features in silico in large-scale miRNA-RNA network reconstructions. We show that, although generically weak, system-level crosstalk patterns (i) are enhanced by transcriptional heterogeneities, (ii) can achieve high-intensity even for RNAs that are not co-regulated, (iii) are robust to variability in transcription rates, and (iv) are significantly non-local, i.e. correlate weakly with miRNA-RNA interaction parameters. Furthermore, RNA levels are generically more stable when crosstalk is strongest. As some of these features appear to be encoded in the network's topology, crosstalk may functionally be favoured by natural selection. These results suggest that, besides their repressive role, miRNAs mediate a weak but resilient and context-independent network of cross-regulatory interactions that interconnect the transcriptome, stabilize expression levels and support system-level responses., Comment: 25 pages, includes Supporting Information; to appear in PLoS Comp Biol

Published
2019
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15. Independent channels for miRNA biosynthesis ensure efficient static and dynamic control in the regulation of the early stages of myogenesis

Author

Fiorentino, Jonathan and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Physics - Biological Physics
Abstract

Motivated by recent experimental work, we define and study a deterministic model of the complex miRNA-based regulatory circuit that putatively controls the early stage of myogenesis in human. We aim in particular at a quantitative understanding of (i) the roles played by the separate and independent miRNA biosynthesis channels (one involving a miRNA-decoy system regulated by an exogenous controller, the other given by transcription from a distinct genomic locus) that appear to be crucial for the differentiation program, and of (ii) how competition to bind miRNAs can efficiently control molecular levels in such an interconnected architecture. We show that optimal static control via the miRNA-decoy system constrains kinetic parameters in narrow ranges where the channels are tightly cross-linked. On the other hand, the alternative locus for miRNA transcription can ensure that the fast concentration shifts required by the differentiation program are achieved, specifically via non-linear response of the target to even modest surges in the miRNA transcription rate. While static, competition-mediated regulation can be achieved by the miRNA-decoy system alone, both channels are essential for the circuit's overall functionality, suggesting that that this type of joint control may represent a minimal optimal architecture in different contexts., Comment: 16+eps pages

Published
2019
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16. Surgery and outcome of infective endocarditis in octogenarians: prospective data from the ESC EORP EURO-ENDO registry

Author

Pazdernik, Michal, Iung, Bernard, Mutlu, Bulent, Alla, François, Riezebos, Robert, Kong, William, Nunes, Maria Carmo Pereira, Pierard, Luc, Srdanovic, Ilija, Yamada, Hirotsugu, De Martino, Andrea, Miglioranza, Marcelo Haertel, Magne, Julien, Piper, Cornelia, Laroche, Cécile, Maggioni, Aldo P., Lancellotti, Patrizio, Habib, Gilbert, and Selton-Suty, Christine

Published
2022
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18. Enabling supra-aortic vessels inclusion in statistical shape models of the aorta: a novel non-rigid registration method

Author

Martino Andrea Scarpolini, Marilena Mazzoli, and Simona Celi

Subjects
statistical shape model, non-rigid registration, deformable surface, thoracic aorta, supra-aortic vessels, correspondence optimization, Physiology, QP1-981
Abstract

Statistical Shape Models (SSMs) are well-established tools for assessing the variability of 3D geometry and for broadening a limited set of shapes. They are widely used in medical imaging due to their ability to model complex geometries and their high efficiency as generative models. The principal step behind these techniques is a registration phase, which, in the case of complex geometries, can be a critical issue due to the correspondence problem, as it necessitates the development of correspondence mapping between shapes. The thoracic aorta, with its high level of morphological complexity, poses a multi-scale deformation problem due to the presence of several branch vessels with varying diameters. Moreover, branch vessels exhibit significant variability in shape, making the correspondence optimization even more challenging. Consequently, existing studies have focused on developing SSMs based only on the main body of the aorta, excluding the supra-aortic vessels from the analysis. In this work, we present a novel non-rigid registration algorithm based on optimizing a differentiable distance function through a modified gradient descent approach. This strategy enables the inclusion of custom, domain-specific constraints in the objective function, which act as landmarks during the registration phase. The algorithm’s registration performance was tested and compared to an alternative Statistical Shape modeling framework, and subsequently used for the development of a comprehensive SSM of the thoracic aorta, including the supra-aortic vessels. The developed SSM was further evaluated against the alternative framework in terms of generalisation, specificity, and compactness to assess its effectiveness.

Published
2023
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19. Kinetic modelling of competition and depletion of shared miRNAs by competing endogenous RNAs

Author

Martirosyan, Araks, Del Giudice, Marco, Bena, Chiara Enrico, Pagnani, Andrea, Bosia, Carla, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics
Abstract

Non-conding RNAs play a key role in the post-transcriptional regulation of mRNA translation and turnover in eukaryotes. miRNAs, in particular, interact with their target RNAs through protein-mediated, sequence-specific binding, giving rise to extended and highly heterogeneous miRNA-RNA interaction networks. Within such networks, competition to bind miRNAs can generate an effective positive coupling between their targets. Competing endogenous RNAs (ceRNAs) can in turn regulate each other through miRNA-mediated crosstalk. Albeit potentially weak, ceRNA interactions can occur both dynamically, affecting e.g. the regulatory clock, and at stationarity, in which case ceRNA networks as a whole can be implicated in the composition of the cell's proteome. Many features of ceRNA interactions, including the conditions under which they become significant, can be unraveled by mathematical and in silico models. We review the understanding of the ceRNA effect obtained within such frameworks, focusing on the methods employed to quantify it, its role in the processing of gene expression noise, and how network topology can determine its reach., Comment: review article, 29 pages, 7 figures

Published
2018

20. Exploration-exploitation tradeoffs dictate the optimal distributions of phenotypes for populations subject to fitness fluctuations

Author

De Martino, Andrea, Gueudré, Thomas, and Miotto, Mattia

Subjects
Quantitative Biology - Populations and Evolution, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Physics - Biological Physics
Abstract

We study a minimal model for the growth of a phenotypically heterogeneous population of cells subject to a fluctuating environment in which they can replicate (by exploiting available resources) and modify their phenotype within a given landscape (thereby exploring novel configurations). The model displays an exploration-exploitation trade-off whose specifics depend on the statistics of the environment. Most notably, the phenotypic distribution corresponding to maximum population fitness (i.e. growth rate) requires a non-zero exploration rate when the magnitude of environmental fluctuations changes randomly over time, while a purely exploitative strategy turns out to be optimal in two-state environments, independently of the statistics of switching times. We obtain analytical insight into the limiting cases of very fast and very slow exploration rates by directly linking population growth to the features of the environment., Comment: 13 pages, 5 figures

Published
2018
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24. Initial cell density encodes proliferative potential in cancer cell populations

Author

Bena, Chiara Enrico, Del Giudice, Marco, Grob, Alice, Gueudré, Thomas, Miotto, Mattia, Gialama, Dimitra, Osella, Matteo, Turco, Emilia, Ceroni, Francesca, De Martino, Andrea, and Bosia, Carla

Subjects
Quantitative Biology - Quantitative Methods, Physics - Biological Physics, Quantitative Biology - Populations and Evolution, 92-05, 92C30, 92B05
Abstract

Individual cells exhibit specific proliferative responses to changes in microenvironmental conditions. Whether such potential is constrained by the cell density throughout the growth process is however unclear. Here, we identify a theoretical framework that captures how the information encoded in the initial density of cancer cell populations impacts their growth profile. By following the growth of hundreds of populations of cancer cells, we found that the time they need to adapt to the environment decreases as the initial cell density increases. Moreover, the population growth rate shows a maximum at intermediate initial densities. With the support of a mathematical model, we show that the observed interdependence of adaptation time and growth rate is significantly at odds both with standard logistic growth models and with the Monod-like function that governs the dependence of the growth rate on nutrient levels. Our results (i) uncover and quantify a previously unnoticed heterogeneity in the growth dynamics of cancer cell populations; (ii) unveil how population growth may be affected by single-cell adaptation times; (iii) contribute to our understanding of the clinically-observed dependence of the primary and metastatic tumor take rates on the initial density of implanted cancer cells., Comment: 25 pages (13 main text + 12 supplementary information), 16 figures (5 main text + 11 supplementary information). Comments welcome

Published
2017
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25. Statistics of optimal information flow in ensembles of regulatory motifs

Author

Crisanti, Andrea, De Martino, Andrea, and Fiorentino, Jonathan

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Quantitative Biology - Quantitative Methods
Abstract

Genetic regulatory circuits universally cope with different sources of noise that limit their ability to coordinate input and output signals. In many cases, optimal regulatory performance can be thought to correspond to configurations of variables and parameters that maximize the mutual information between inputs and outputs. Such optima have been well characterized in several biologically relevant cases over the past decade. Here we use methods of statistical field theory to calculate the statistics of the maximal mutual information (the `capacity') achievable by tuning the input variable only in an ensemble of regulatory motifs, such that a single controller regulates N targets. Assuming (i) sufficiently large N, (ii) quenched random kinetic parameters, and (iii) small noise affecting the input-output channels, we can accurately reproduce numerical simulations both for the mean capacity and for the whole distribution. Our results provide insight into the inherent variability in effectiveness occurring in regulatory systems with heterogeneous kinetic parameters., Comment: 14 pages, 6 figures

Published
2017
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26. A k-means procedure based on a Mahalanobis type distance for clustering multivariate functional data

Author

Martino, Andrea, Ghiglietti, Andrea, Ieva, Francesca, and Paganoni, Anna M.

Subjects
Statistics - Methodology
Abstract

This paper proposes a clustering procedure for samples of multivariate functions in $(L^2(I))^{J}$, with $J\geq1$. This method is based on a k-means algorithm in which the distance between the curves is measured with a metrics that generalizes the Mahalanobis distance in Hilbert spaces, considering the correlation and the variability along all the components of the functional data. The proposed procedure has been studied in simulation and compared with the k-means based on other distances typically adopted for clustering multivariate functional data. In these simulations, it is shown that the k-means algorithm with the generalized Mahalanobis distance provides the best clustering performances, both in terms of mean and standard deviation of the number of misclassified curves. Finally, the proposed method has been applied to two real cases studies, concerning ECG signals and growth curves, where the results obtained in simulation are confirmed and strengthened., Comment: 22 pages

Published
2017

27. Constraint-based inverse modeling of metabolic networks: a proof of concept

Author

De Martino, Daniele and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Physics - Biological Physics
Abstract

We consider the problem of inferring the probability distribution of flux configurations in metabolic network models from empirical flux data. For the simple case in which experimental averages are to be retrieved, data are described by a Boltzmann-like distribution ($\propto e^{F/T}$) where $F$ is a linear combination of fluxes and the `temperature' parameter $T\geq 0$ allows for fluctuations. The zero-temperature limit corresponds to a Flux Balance Analysis scenario, where an objective function ($F$) is maximized. As a test, we have inverse modeled, by means of Boltzmann learning, the catabolic core of Escherichia coli in glucose-limited aerobic stationary growth conditions. Empirical means are best reproduced when $F$ is a simple combination of biomass production and glucose uptake and the temperature is finite, implying the presence of fluctuations. The scheme presented here has the potential to deliver new quantitative insight on cellular metabolism. Our implementation is however computationally intensive, and highlights the major role that effective algorithms to sample the high-dimensional solution space of metabolic networks can play in this field., Comment: 4 pages, comments welcome

Published
2017

28. ceRNA crosstalk stabilizes protein expression and affects the correlation pattern of interacting proteins

Author

Martirosyan, Araks, De Martino, Andrea, Pagnani, Andrea, and Marinari, Enzo

Subjects
Quantitative Biology - Molecular Networks
Abstract

Gene expression is a noisy process and several mechanisms, both transcriptional and posttranscriptional, can stabilize protein levels in cells. Much work has focused on the role of miRNAs, showing in particular that miRNA-mediated regulation can buffer expression noise for lowly expressed genes. Here, using in silico simulations and mathematical modeling, we demonstrate that miRNAs can exert a much broader influence on protein levels by orchestrating competition-induced crosstalk between mRNAs. Most notably, we find that miRNA-mediated cross-talk (i) can stabilize protein levels across the full range of gene expression rates, and (ii) modifies the correlation pattern of co-regulated interacting proteins, changing the sign of correlations from negative to positive. The latter feature may constitute a potentially robust signature of the existence of RNA crosstalk induced by endogenous competition for miRNAs in standard cellular conditions.

Published
2017
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29. A yield-cost tradeoff governs Escherichia coli's decision between fermentation and respiration in carbon-limited growth

Author

Mori, Matteo, Marinari, Enzo, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics
Abstract

Many microbial systems are known to actively reshape their proteomes in response to changes in growth conditions induced e.g. by nutritional stress or antibiotics. Part of the re-allocation accounts for the fact that, as the growth rate is limited by targeting specific metabolic activities, cells simply respond by fine-tuning their proteome to invest more resources into the limiting activity (i.e. by synthesizing more proteins devoted to it). However, this is often accompanied by an overall re-organization of metabolism, aimed at improving the growth yield under limitation by re-wiring resource through different pathways. While both effects impact proteome composition, the latter underlies a more complex systemic response to stress. By focusing on E. coli's `acetate switch', we use mathematical modeling and a re-analysis of empirical data to show that the transition from a predominantly fermentative to a predominantly respirative metabolism in carbon-limited growth results from the trade-off between maximizing the growth yield and minimizing its costs in terms of required the proteome share. In particular, E. coli's metabolic phenotypes appear to be Pareto-optimal for these objective functions over a broad range of dilutions., Comment: 13 pages (includes Supporting Text)

Published
2017

30. Quantifying the entropic cost of cellular growth control

Author

De Martino, Daniele, Capuani, Fabrizio, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics, Quantitative Biology - Populations and Evolution, Quantitative Biology - Quantitative Methods
Abstract

We quantify the amount of regulation required to control growth in living cells by a Maximum Entropy approach to the space of underlying metabolic states described by genome-scale models. Results obtained for E. coli and human cells are consistent with experiments and point to different regulatory strategies by which growth can be fostered or repressed. Moreover we explicitly connect the `inverse temperature' that controls MaxEnt distributions to the growth dynamics, showing that the initial size of a colony may be crucial in determining how an exponentially growing population organizes the phenotypic space., Comment: 3 pages

Published
2017
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31. Microenvironmental cooperation promotes early spread and bistability of a Warburg-like phenotype

Author

Fernandez-de-Cossio-Diaz, Jorge, De Martino, Andrea, and Mulet, Roberto

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics, Quantitative Biology - Tissues and Organs
Abstract

We introduce an in silico model for the initial spread of an aberrant phenotype with Warburg-like overflow metabolism within a healthy homeostatic tissue in contact with a nutrient reservoir (the blood), aimed at characterizing the role of the microenvironment for aberrant growth. Accounting for cellular metabolic activity, competition for nutrients, spatial diffusion and their feedbacks on aberrant replication and death rates, we obtain a phase portrait where distinct asymptotic whole-tissue states are found upon varying the tissue-blood turnover rate and the level of blood-borne primary nutrient. Over a broad range of parameters, the spreading dynamics is bistable as random fluctuations can impact the final state of the tissue. Such a behaviour turns out to be linked to the re-cycling of overflow products by non-aberrant cells. Quantitative insight on the overall emerging picture is provided by a spatially homogeneous version of the model., Comment: 14 pages

Published
2017
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32. Translating ceRNA susceptibilities into correlation functions

Author

Martirosyan, Araks, Marsili, Matteo, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Quantitative Biology - Quantitative Methods
Abstract

Competition to bind microRNAs induces an effective positive crosstalk between their targets, therefore known as `competing endogenous RNAs' or ceRNAs. While such an effect is known to play a significant role in specific conditions, estimating its strength from data and, experimentally, in physiological conditions appears to be far from simple. Here we show that the susceptibility of ceRNAs to different types of perturbations affecting their competitors (and hence their tendency to crosstalk) can be encoded in quantities as intuitive and as simple to measure as correlation functions. We confirm this scenario by extensive numerical simulations and validate it by re-analyzing PTEN's crosstalk pattern from TCGA breast cancer dataset. These results clarify the links between different quantities used to estimate the intensity of ceRNA crosstalk and provide new keys to analyze transcriptional datasets and effectively probe ceRNA networks in silico., Comment: 12 pages, includes supporting text

Published
2017
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33. An image-based approach for the estimation of arterial local stiffness in vivo

Author

Simona Celi, Emanuele Gasparotti, Katia Capellini, Francesco Bardi, Martino Andrea Scarpolini, Carlo Cavaliere, Filippo Cademartiri, and Emanuele Vignali

Subjects
in vivo arterial stiffness, tissue mechanics, ECG-gated CT images, mesh-morphing, inverse engineering, Biotechnology, TP248.13-248.65
Abstract

The analysis of mechanobiology of arterial tissues remains an important topic of research for cardiovascular pathologies evaluation. In the current state of the art, the gold standard to characterize the tissue mechanical behavior is represented by experimental tests, requiring the harvesting of ex-vivo specimens. In recent years though, image-based techniques for the in vivo estimation of arterial tissue stiffness were presented. The aim of this study is to define a new approach to provide local distribution of arterial stiffness, estimated as the linearized Young’s Modulus, based on the knowledge of in vivo patient-specific imaging data. In particular, the strain and stress are estimated with sectional contour length ratios and a Laplace hypothesis/inverse engineering approach, respectively, and then used to calculate the Young’s Modulus. After describing the method, this was validated by using a set of Finite Element simulations as input. In particular, idealized cylinder and elbow shapes plus a single patient-specific geometry were simulated. Different stiffness distributions were tested for the simulated patient-specific case. After the validation from Finite Element data, the method was then applied to patient-specific ECG-gated Computed Tomography data by also introducing a mesh morphing approach to map the aortic surface along the cardiac phases. The validation process revealed satisfactory results. In the simulated patient-specific case, root mean square percentage errors below 10% for the homogeneous distribution and below 20% for proximal/distal distribution of stiffness. The method was then successfully used on the three ECG-gated patient-specific cases. The resulting distributions of stiffness exhibited significant heterogeneity, nevertheless the resulting Young’s moduli were always contained within the 1–3 MPa range, which is in line with literature.

Published
2023
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34. Surgical Treatment of Post-Infarction Left Ventricular Free-Wall Rupture: A Multicenter Study

Author

Matteucci, Matteo, Kowalewski, Mariusz, De Bonis, Michele, Formica, Francesco, Jiritano, Federica, Fina, Dario, Meani, Paolo, Folliguet, Thierry, Bonaros, Nikolaos, Sponga, Sandro, Suwalski, Piotr, De Martino, Andrea, Fischlein, Theodor, Troise, Giovanni, Dato, Guglielmo Actis, Serraino, Giuseppe Filiberto, Shah, Shabir Hussain, Scrofani, Roberto, Antona, Carlo, Fiore, Antonio, Kalisnik, Jurij Matija, D’Alessandro, Stefano, Villa, Emmanuel, Lodo, Vittoria, Colli, Andrea, Aldobayyan, Ibrahim, Massimi, Giulio, Trumello, Cinzia, Beghi, Cesare, and Lorusso, Roberto

Published
2021
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36. Constrained Allocation Flux Balance Analysis

Author

Mori, Matteo, Hwa, Terence, Martin, Olivier C., De Martino, Andrea, and Marinari, Enzo

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics, Quantitative Biology - Quantitative Methods
Abstract

New experimental results on bacterial growth inspire a novel top-down approach to study cell metabolism, combining mass balance and proteomic constraints to extend and complement Flux Balance Analysis. We introduce here Constrained Allocation Flux Balance Analysis, CAFBA, in which the biosynthetic costs associated to growth are accounted for in an effective way through a single additional genome-wide constraint. Its roots lie in the experimentally observed pattern of proteome allocation for metabolic functions, allowing to bridge regulation and metabolism in a transparent way under the principle of growth-rate maximization. We provide a simple method to solve CAFBA efficiently and propose an "ensemble averaging" procedure to account for unknown protein costs. Applying this approach to modeling E. coli metabolism, we find that, as the growth rate increases, CAFBA solutions cross over from respiratory, growth-yield maximizing states (preferred at slow growth) to fermentative states with carbon overflow (preferred at fast growth). In addition, CAFBA allows for quantitatively accurate predictions on the rate of acetate excretion and growth yield based on only 3 parameters determined by empirical growth laws., Comment: 21 pages, 6 figures (main) + 33 pages, various figures and tables (supporting); for the supplementary MatLab code, see http://tinyurl.com/h763es8

Published
2016
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37. Noise Processing by MicroRNA-Mediated Circuits: the Incoherent Feed-Forward Loop, Revisited

Author

Grigolon, Silvia, Di Patti, Francesca, De Martino, Andrea, and Marinari, Enzo

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Statistical Mechanics, Physics - Biological Physics
Abstract

The intrinsic stochasticity of gene expression is usually mitigated in higher eukaryotes by post-transcriptional regulation channels that stabilise the output layer, most notably protein levels. The discovery of small non-coding RNAs (miRNAs) in specific motifs of the genetic regulatory network has led to identifying noise buffering as the possible key function they exert in regulation. Recent in vitro} and in silico studies have corroborated this hypothesis. It is however also known that miRNA-mediated noise reduction is hampered by transcriptional bursting in simple topologies. Here, using stochastic simulations validated by analytical calculations based on van Kampen's expansion, we revisit the noise-buffering capacity of the miRNA-mediated Incoherent Feed Forward Loop (IFFL), a small module that is widespread in the gene regulatory networks of higher eukaryotes, in order to account for the effects of intermittency in the transcriptional activity of the modulator gene. We show that bursting considerably alters the circuit's ability to control static protein noise. By comparing with other regulatory architectures, we find that direct transcriptional regulation significantly outperforms the IFFL in a broad range of kinetic parameters. This suggests that, under pulsatile inputs, static noise reduction may be less important than dynamical aspects of noise and information processing in characterising the performance of regulatory elements., Comment: 25 pages (Main Text and Supplementary Information), 5 figures

Published
2016
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38. Probing the limits to microRNA-mediated control of gene expression

Author

Martirosyan, Araks, Figliuzzi, Matteo, Marinari, Enzo, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics
Abstract

According to the `ceRNA hypothesis', microRNAs (miRNAs) may act as mediators of an effective positive interaction between long coding or non-coding RNA molecules, carrying significant potential implications for a variety of biological processes. Here, inspired by recent work providing a quantitative description of small regulatory elements as information-conveying channels, we characterize the effectiveness of miRNA-mediated regulation in terms of the optimal information flow achievable between modulator (transcription factors) and target nodes (long RNAs). Our findings show that, while a sufficiently large degree of target derepression is needed to activate miRNA-mediated transmission, (a) in case of differential mechanisms of complex processing and/or transcriptional capabilities, regulation by a post-transcriptional miRNA-channel can outperform that achieved through direct transcriptional control; moreover, (b) in the presence of large populations of weakly interacting miRNA molecules the extra noise coming from titration disappears, allowing the miRNA-channel to process information as effectively as the direct channel. These observations establish the limits of miRNA-mediated post-transcriptional cross-talk and suggest that, besides providing a degree of noise buffering, this type of control may be effectively employed in cells both as a failsafe mechanism and as a preferential fine tuner of gene expression, pointing to the specific situations in which each of these functionalities is maximized., Comment: 16 pages

Published
2016
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39. Growth against entropy in bacterial metabolism: the phenotypic trade-off behind empirical growth rate distributions in E. coli

Author

De Martino, Daniele, Capuani, Fabrizio, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics, Quantitative Biology - Populations and Evolution
Abstract

The solution space of genome-scale models of cellular metabolism provides a map between physically viable flux configurations and cellular metabolic phenotypes described, at the most basic level, by the corresponding growth rates. By sampling the solution space of E. coli's metabolic network, we show that empirical growth rate distributions recently obtained in experiments at single-cell resolution can be explained in terms of a trade-off between the higher fitness of fast-growing phenotypes and the higher entropy of slow-growing ones. Based on this, we propose a minimal model for the evolution of a large bacterial population that captures this trade-off. The scaling relationships observed in experiments encode, in such frameworks, for the same distance from the maximum achievable growth rate, the same degree of growth rate maximization, and/or the same rate of phenotypic change. Being grounded on genome-scale metabolic network reconstructions, these results allow for multiple implications and extensions in spite of the underlying conceptual simplicity., Comment: 12 pages, 5 figures

Published
2016
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41. Long-term survival after surgical treatment for post-infarction mechanical complications: results from the Caution study

Author

Matteucci, Matteo, Ronco, Daniele, Kowalewski, Mariusz, Massimi, Giulio, De Bonis, Michele, Formica, Francesco, Jiritano, Federica, Folliguet, Thierry, Bonaros, Nikolaos, Sponga, Sandro, Suwalski, Piotr, De Martino, Andrea, Fischlein, Theodor, Troise, Giovanni, Dato, Guglielmo Actis, Serraino, Filiberto Giuseppe, Shah, Shabir Hussain, Scrofani, Roberto, Kalisnik, Jurij Matija, Colli, Andrea, Russo, Claudio Francesco, Ranucci, Marco, Pettinari, Matteo, Kowalowka, Adam, Thielmann, Matthias, Meyns, Bart, Khouqeer, Fareed, Obadia, Jean-Francois, Boeken, Udo, Simon, Caterina, Naito, Shiho, Musazzi, Andrea, and Lorusso, Roberto

Abstract

Graphical Abstract

Published
2024
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42. High-resolution stratigraphy and seismic site characterization of late Quaternary paleovalley systems (Adriatic coastal plain, Italy)

Author

Amorosi, Alessandro, Di Martino, Andrea <1992>, Amorosi, Alessandro, and Di Martino, Andrea <1992>

Abstract

In highly urbanized coastal lowlands, effective site characterization is crucial for assessing seismic risk. It requires a comprehensive stratigraphic analysis of the shallow subsurface, coupled with the precise assessment of the geophysical properties of buried deposits. In this context, late Quaternary paleovalley systems, shallowly buried fluvial incisions formed during the Late Pleistocene sea-level fall and filled during the Holocene sea-level rise, are crucial for understanding seismic amplification due to their soft sediment infill and sharp lithologic contrasts. In this research, we conducted high-resolution stratigraphic analyses of two regions, the Pescara and Manfredonia areas along the Adriatic coastline of Italy, to delineate the geometries and facies architecture of two paleovalley systems. Furthermore, we carried out geophysical investigations to characterize the study areas and perform seismic response analyses. We tested the microtremor-based horizontal-to-vertical spectral ratio as a mapping tool to reconstruct the buried paleovalley geometries. We evaluated the relationship between geological and geophysical data and identified the stratigraphic surfaces responsible for the observed resonances. To perform seismic response analysis of the Pescara paleovalley system, we integrated the stratigraphic framework with microtremor and shear wave velocity measurements. The seismic response analysis highlights strong seismic amplifications in frequency ranges that can interact with a wide variety of building types. Additionally, we explored the applicability of artificial intelligence in performing facies analysis from borehole images. We used a robust dataset of high-resolution digital images from continuous sediment cores of Holocene age to outline a novel, deep-learning-based approach for performing automatic semantic segmentation directly on core images, leveraging the power of convolutional neural networks. We propose an automated model to rapidly char

Published
2024

43. Quantitative constraint-based computational model of tumor-to-stroma coupling via lactate shuttle

Author

Capuani, Fabrizio, De Martino, Daniele, Marinari, Enzo, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks
Abstract

Cancer cells utilize large amounts of ATP to sustain growth, relying primarily on non-oxidative, fermentative pathways for its production. In many types of cancers this leads, even in the presence of oxygen, to the secretion of carbon equivalents (usually in the form of lactate) in the cell's surroundings, a feature known as the Warburg effect. While the molecular basis of this phenomenon are still to be elucidated, it is clear that the spilling of energy resources contributes to creating a peculiar microenvironment for tumors, possibly characterized by a degree of toxicity. This suggests that mechanisms for recycling the fermentation products (e.g. a lactate shuttle) may be active, effectively inducing a mutually beneficial metabolic coupling between aberrant and non-aberrant cells. Here we analyze this scenario through a large-scale in silico metabolic model of interacting human cells. By going beyond the cell-autonomous description, we show that elementary physico-chemical constraints indeed favor the establishment of such a coupling under very broad conditions. The characterization we obtained by tuning the aberrant cell's demand for ATP, amino-acids and fatty acids and/or the imbalance in nutrient partitioning provides quantitative support to the idea that synergistic multi-cell effects play a central role in cancer sustainment., Comment: 26 pages incl. supporting material

Published
2015
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44. Correction to: Surgery and outcome of infective endocarditis in octogenarians: prospective data from the ESC EORP EURO-ENDO registry

Author

Pazdernik, Michal, Iung, Bernard, Mutlu, Bulent, Alla, François, Riezebos, Robert, Kong, William, Nunes, Maria Carmo Pereira, Pierard, Luc, Srdanovic, Ilija, Yamada, Hirotsugu, De Martino, Andrea, Miglioranza, Marcelo Haertel, Magne, Julien, Piper, Cornelia, Laroche, Cécile, Maggioni, Aldo P., Lancellotti, Patrizio, Habib, Gilbert, and Selton-Suty, Christine

Published
2022
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45. Categorization of Attributes and Features for the Location of Electric Vehicle Charging Stations.

Author

Mazza, Andrea, Russo, Angela, Chicco, Gianfranco, Di Martino, Andrea, Colombo, Cristian Giovanni, Longo, Michela, Ciliento, Paolo, De Donno, Marco, Mapelli, Francesca, and Lamberti, Francesco

Subjects
ELECTRIC vehicle charging stations, INFRASTRUCTURE (Economics), URBAN planning, ELECTRIC power distribution grids, QUALITY of service
Abstract

The location of Electric Vehicle Charging Stations (EVCSs) is gaining significant importance as part of the conversion to a full-electric vehicle fleet. Positive or negative impacts can be generated mainly based on the quality of service offered to customers and operational efficiency, also potentially involving the electrical grid to which the EVCSs are connected. The EVCS location problem requires an in-depth and comprehensive analysis of geographical, market, urban planning, and operational aspects that can lead to several potential alternatives to be evaluated with respect to a defined number of features. This paper discusses the possible use of a multi-criteria decision-making approach, considering the differences between multi-objective decision making (MODM) and multi-attribute decision-making (MADM), to address the EVCS location problem. The conceptual evaluation leads to the conclusion that the MADM approach is more suitable than MODM for the specific problem. The identification of suitable attributes and related features is then carried out based on a systematic literature review. For each attribute, the relative importance of the features is obtained by considering the occurrence and the dedicated weights. The results provide the identification of the most used attributes and the categorization of the selected features to shape the proposed MADM framework for the location of the electric vehicle charging infrastructure. [ABSTRACT FROM AUTHOR]

Published
2024
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47. Inferring metabolic phenotypes from the exometabolome through a thermodynamic variational principle

Author

De Martino, Daniele, Capuani, Fabrizio, and De Martino, Andrea

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics
Abstract

Networks of biochemical reactions, like cellular metabolic networks, are kept in non-equilibrium steady states by the exchange fluxes connecting them to the environment. In most cases, feasible flux configurations can be derived from minimal mass-balance assumptions upon prescribing in- and out-take fluxes. Here we consider the problem of inferring intracellular flux patterns from extracellular metabolite levels. Resorting to a thermodynamic out of equilibrium variational principle to describe the network at steady state, we show that the switch from fermentative to oxidative phenotypes in cells can be characterized in terms of the glucose, lactate, oxygen and carbon dioxide concentrations. Results obtained for an exactly solvable toy model are fully recovered for a large scale reconstruction of human catabolism. Finally we argue that, in spite of the many approximations involved in the theory, available data for several human cell types are well described by the predicted phenotypic map of the problem., Comment: 10 pages, to appear in New J Phys (Special Issue)

Published
2014
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50. RNA-based regulation: dynamics and response to perturbations of competing RNAs

Author

Figliuzzi, Matteo, De Martino, Andrea, and Marinari, Enzo

Subjects
Quantitative Biology - Molecular Networks, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Quantitative Biology - Genomics, Quantitative Biology - Quantitative Methods
Abstract

The observation that, through a titration mechanism, microRNAs (miRNAs) can act as mediators of effective interactions among their common targets (competing endogenous RNAs or ceRNAs) has brought forward the idea ('ceRNA hypothesis') that RNAs can regulate each other in extended 'cross-talk' networks. Such an ability might play a major role in post-transcriptional regulation (PTR) in shaping a cell's protein repertoire. Recent work focusing on the emergent properties of the cross-talk networks has emphasized the high flexibility and selectivity that may be achieved at stationarity. On the other hand, dynamical aspects, possibly crucial on the relevant time scales, are far less clear. We have carried out a dynamical study of the ceRNA hypothesis on a model of PTR. Sensitivity analysis shows that ceRNA cross-talk is dynamically extended, i.e. it may take place on time scales shorter than those required to achieve stationairity even in cases where no cross-talk occurs in the steady state, and is possibly amplified. Besides, in case of large, transfection-like perturbations the system may develop strongly non-linear, threshold response. Finally, we show that the ceRNA effect provides a very efficient way for a cell to achieve fast positive shifts in the level of a ceRNA when necessary. These results indicate that competition for miRNAs may indeed provide an elementary mechanism to achieve system-level regulatory effects on the transcriptome over physiologically relevant time scales., Comment: Main text: 10 pages, 13 figures. Supporting Text: 3 pages, 6 figures

Published
2013
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