Showing total 6 results

1. Paper-based synthetic gene networks.

Author

Pardee K, Green AA, Ferrante T, Cameron DE, DaleyKeyser A, Yin P, and Collins JJ

Subjects

Ebolavirus classification, Ebolavirus genetics, Nucleic Acid Conformation, Paper, Synthetic Biology, Cell-Free System, Gene Regulatory Networks, In Vitro Techniques

Abstract

Synthetic gene networks have wide-ranging uses in reprogramming and rewiring organisms. To date, there has not been a way to harness the vast potential of these networks beyond the constraints of a laboratory or in vivo environment. Here, we present an in vitro paper-based platform that provides an alternate, versatile venue for synthetic biologists to operate and a much-needed medium for the safe deployment of engineered gene circuits beyond the lab. Commercially available cell-free systems are freeze dried onto paper, enabling the inexpensive, sterile, and abiotic distribution of synthetic-biology-based technologies for the clinic, global health, industry, research, and education. For field use, we create circuits with colorimetric outputs for detection by eye and fabricate a low-cost, electronic optical interface. We demonstrate this technology with small-molecule and RNA actuation of genetic switches, rapid prototyping of complex gene circuits, and programmable in vitro diagnostics, including glucose sensors and strain-specific Ebola virus sensors.

Published

2014

2. Synthetic Biology Looks Good on Paper.

Author

Lopatkin, Allison J. and You, Lingchong

Subjects

*SYNTHETIC biology, *GENE regulatory networks, *PAPER, *PROTOTYPES, *GENE expression

Abstract

Tremendous progress has been made in the design and implementation of synthetic gene circuits, but real-world applications of such circuits have been limited. Cell-free circuits embedded on paper developed by Pardee et al. promise to deliver specific and rapid diagnostics on a low-cost, highly scalable platform. [ABSTRACT FROM AUTHOR]

Published

2014

3. Systematic dissection of dysregulated transcription factor–miRNA feed-forward loops across tumor types

Author

Feixiong Cheng, Ramkrishna Mitra, Zhongming Zhao, Quan Wang, Chen Ching Lin, and Wei Jiang

Subjects

Paper, 0301 basic medicine, Epithelial-Mesenchymal Transition, pan-cancer, Gene regulatory network, drug repositioning, Computational biology, feed-forward loop, Biology, Bioinformatics, 03 medical and health sciences, TF and miRNA regulatory network, Neoplasms, Cancer genome, microRNA, medicine, Humans, Gene Regulatory Networks, Epithelial–mesenchymal transition, Molecular Biology, Transcription factor, Gene, gene and miRNA expression, Cancer, medicine.disease, 3. Good health, MicroRNAs, Drug repositioning, 030104 developmental biology, Transcription Factors, Information Systems

Abstract

Transcription factor and microRNA (miRNA) can mutually regulate each other and jointly regulate their shared target genes to form feed-forward loops (FFLs). While there are many studies of dysregulated FFLs in a specific cancer, a systematic investigation of dysregulated FFLs across multiple tumor types (pan-cancer FFLs) has not been performed yet. In this study, using The Cancer Genome Atlas data, we identified 26 pan-cancer FFLs, which were dysregulated in at least five tumor types. These pan-cancer FFLs could communicate with each other and form functionally consistent subnetworks, such as epithelial to mesenchymal transition-related subnetwork. Many proteins and miRNAs in each subnetwork belong to the same protein and miRNA family, respectively. Importantly, cancer-associated genes and drug targets were enriched in these pan-cancer FFLs, in which the genes and miRNAs also tended to be hubs and bottlenecks. Finally, we identified potential anticancer indications for existing drugs with novel mechanism of action. Collectively, this study highlights the potential of pan-cancer FFLs as a novel paradigm in elucidating pathogenesis of cancer and developing anticancer drugs.

Published

2015

4. It is time to apply biclustering: a comprehensive review of biclustering applications in biological and biomedical data

Author

Jing Zhao, Anne Fennell, Qin Ma, Anjun Ma, and Juan Xie

Subjects

Big Data, Paper, Computer science, 0206 medical engineering, Big data, Gene Expression, 02 engineering and technology, computer.software_genre, Data type, Biclustering, 03 medical and health sciences, Biomedical data, Databases, Genetic, Cluster Analysis, Data Mining, Humans, Disease, Gene Regulatory Networks, Cluster analysis, Molecular Biology, 030304 developmental biology, 0303 health sciences, Biological data, business.industry, Gene Expression Profiling, Computational Biology, Molecular Sequence Annotation, Variety (cybernetics), Data set, ComputingMethodologies_PATTERNRECOGNITION, Data mining, business, computer, 020602 bioinformatics, Algorithms, Information Systems

Abstract

Biclustering is a powerful data mining technique that allows clustering of rows and columns, simultaneously, in a matrix-format data set. It was first applied to gene expression data in 2000, aiming to identify co-expressed genes under a subset of all the conditions/samples. During the past 17 years, tens of biclustering algorithms and tools have been developed to enhance the ability to make sense out of large data sets generated in the wake of high-throughput omics technologies. These algorithms and tools have been applied to a wide variety of data types, including but not limited to, genomes, transcriptomes, exomes, epigenomes, phenomes and pharmacogenomes. However, there is still a considerable gap between biclustering methodology development and comprehensive data interpretation, mainly because of the lack of knowledge for the selection of appropriate biclustering tools and further supporting computational techniques in specific studies. Here, we first deliver a brief introduction to the existing biclustering algorithms and tools in public domain, and then systematically summarize the basic applications of biclustering for biological data and more advanced applications of biclustering for biomedical data. This review will assist researchers to effectively analyze their big data and generate valuable biological knowledge and novel insights with higher efficiency.

Published

2017

5. Gene co-expression analysis for functional classification and gene-disease predictions

Author

Sipko, van Dam, Urmo, Võsa, Adriaan, van der Graaf, Lude, Franke, and João Pedro, de Magalhães

Subjects

Paper, Gene Expression Profiling, Computational Biology, transcriptomics, Phenotype, disease gene prediction, Gene Expression Regulation, Genes, Humans, Disease, Gene Regulatory Networks, next-generation sequencing, functional genomics, network analysis

Abstract

Gene co-expression networks can be used to associate genes of unknown function with biological processes, to prioritize candidate disease genes or to discern transcriptional regulatory programmes. With recent advances in transcriptomics and next-generation sequencing, co-expression networks constructed from RNA sequencing data also enable the inference of functions and disease associations for non-coding genes and splice variants. Although gene co-expression networks typically do not provide information about causality, emerging methods for differential co-expression analysis are enabling the identification of regulatory genes underlying various phenotypes. Here, we introduce and guide researchers through a (differential) co-expression analysis. We provide an overview of methods and tools used to create and analyse co-expression networks constructed from gene expression data, and we explain how these can be used to identify genes with a regulatory role in disease. Furthermore, we discuss the integration of other data types with co-expression networks and offer future perspectives of co-expression analysis.

Published

2016

6. Paper-Based Synthetic Gene Networks

Author

Keith Pardee, Alexander A. Green, Tom Ferrante, D. Ewen Cameron, Ajay DaleyKeyser, Peng Yin, and James J. Collins

Subjects

Paper, Cell-Free System, Biochemistry, Genetics and Molecular Biology(all), business.industry, Extramural, Clinical settings, Paper based, Biology, In Vitro Techniques, Ebolavirus, Article, General Biochemistry, Genetics and Molecular Biology, 3. Good health, Biotechnology, Synthetic biology, Synthetic gene, Nucleic Acid Conformation, Gene Regulatory Networks, Synthetic Biology, Biochemical engineering, business

Abstract

SummarySynthetic gene networks have wide-ranging uses in reprogramming and rewiring organisms. To date, there has not been a way to harness the vast potential of these networks beyond the constraints of a laboratory or in vivo environment. Here, we present an in vitro paper-based platform that provides an alternate, versatile venue for synthetic biologists to operate and a much-needed medium for the safe deployment of engineered gene circuits beyond the lab. Commercially available cell-free systems are freeze dried onto paper, enabling the inexpensive, sterile, and abiotic distribution of synthetic-biology-based technologies for the clinic, global health, industry, research, and education. For field use, we create circuits with colorimetric outputs for detection by eye and fabricate a low-cost, electronic optical interface. We demonstrate this technology with small-molecule and RNA actuation of genetic switches, rapid prototyping of complex gene circuits, and programmable in vitro diagnostics, including glucose sensors and strain-specific Ebola virus sensors.