Luca De Sano scite author profile

The genomic evolution inherent to cancer relates directly to a renewed focus on the voluminous next-generation sequencing data and machine learning for the inference of explanatory models of how the (epi)genomic events are choreographed in cancer initiation and development. However, despite the increasing availability of multiple additional -omics data, this quest has been frustrated by various theoretical and technical hurdles, mostly stemming from the dramatic heterogeneity of the disease. In this paper, we build on our recent work on the "selective advantage" relation among driver mutations in cancer progression and investigate its applicability to the modeling problem at the population level. Here, we introduce PiCnIc (Pipeline for Cancer Inference), a versatile, modular, and customizable pipeline to extract ensemble-level progression models from cross-sectional sequenced cancer genomes. The pipeline has many translational implications because it combines state-of-theart techniques for sample stratification, driver selection, identification of fitness-equivalent exclusive alterations, and progression model inference. We demonstrate PiCnIc's ability to reproduce much of the current knowledge on colorectal cancer progression as well as to suggest novel experimentally verifiable hypotheses.cancer evolution | selective advantage | Bayesian structural inference | next generation sequencing | causality

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SIMLR: A Tool for Large‐Scale Genomic Analyses by Multi‐Kernel Learning

Wang

Ramazzotti

Sano

et al. 2018

Proteomics

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SIMLR (Single-cell Interpretation via Multi-kernel LeaRning), an open-source tool that implements a novel framework to learn a sample-to-sample similarity measure from expression data observed for heterogenous samples, is presented here. SIMLR can be effectively used to perform tasks such as dimension reduction, clustering, and visualization of heterogeneous populations of samples. SIMLR was benchmarked against state-of-the-art methods for these three tasks on several public datasets, showing it to be scalable and capable of greatly improving clustering performance, as well as providing valuable insights by making the data more interpretable via better a visualization. SIMLR is available on https://github.com/BatzoglouLabSU/SIMLRGitHub in both R and MATLAB implementations. Furthermore, it is also available as an R package on http://bioconductor.org.

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Algorithmic Methods to Infer the Evolutionary Trajectories in Cancer Progression

Caravagna

Graudenzi

Ramazzotti

et al. 2015

Preprint

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OncoScore: a novel, Internet-based tool to assess the oncogenic potential of genes

Piazza

Ramazzotti

Spinelli

et al. 2017

Sci Rep

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The complicated, evolving landscape of cancer mutations poses a formidable challenge to identify cancer genes among the large lists of mutations typically generated in NGS experiments. The ability to prioritize these variants is therefore of paramount importance. To address this issue we developed OncoScore, a text-mining tool that ranks genes according to their association with cancer, based on available biomedical literature. Receiver operating characteristic curve and the area under the curve (AUC) metrics on manually curated datasets confirmed the excellent discriminating capability of OncoScore (OncoScore cut-off threshold = 21.09; AUC = 90.3%, 95% CI: 88.1–92.5%), indicating that OncoScore provides useful results in cases where an efficient prioritization of cancer-associated genes is needed.

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SIMLR: a tool for large-scale single-cell analysis by multi-kernel learning

Wang

Ramazzotti

Sano

et al. 2017

Preprint

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Motivation: We here present SIMLR (Single-cell Interpretation via Multi-kernel LeaRning), an open-source tool that implements a novel framework to learn a cell-to-cell similarity measure from single-cell RNAseq data. SIMLR can be effectively used to perform tasks such as dimension reduction, clustering, and visualization of heterogeneous populations of cells. SIMLR was benchmarked against state-of-the-art methods for these three tasks on several public datasets, showing it to be scalable and capable of greatly improving clustering performance, as well as providing valuable insights by making the data more interpretable via better a visualization.

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Luca De Sano

Algorithmic methods to infer the evolutionary trajectories in cancer progression

SIMLR: A Tool for Large‐Scale Genomic Analyses by Multi‐Kernel Learning

Algorithmic Methods to Infer the Evolutionary Trajectories in Cancer Progression

OncoScore: a novel, Internet-based tool to assess the oncogenic potential of genes

SIMLR: a tool for large-scale single-cell analysis by multi-kernel learning

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