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9 results on '"Hunter M. Nisonoff"'

4. Epistatic Net allows the sparse spectral regularization of deep neural networks for inferring fitness functions

Author

Yijie Huang, Kannan Ramchandran, Hunter M. Nisonoff, Orhan Ocal, Amirali Aghazadeh, David H. Brookes, O. Ozan Koyluoglu, and Jennifer Listgarten

Subjects
Fitness landscape, Computer science, Science, Green Fluorescent Proteins, General Physics and Astronomy, Protein function predictions, Overfitting, Regularization (mathematics), Article, General Biochemistry, Genetics and Molecular Biology, Sequence space, 03 medical and health sciences, 0302 clinical medicine, Machine learning, Prior probability, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Bacteria, Inductive bias, business.industry, Pattern recognition, General Chemistry, Coding theory, Applied mathematics, Neural Networks, Computer, Artificial intelligence, Computational problem, business, Algorithms, 030217 neurology & neurosurgery
Abstract

Despite recent advances in high-throughput combinatorial mutagenesis assays, the number of labeled sequences available to predict molecular functions has remained small for the vastness of the sequence space combined with the ruggedness of many fitness functions. While deep neural networks (DNNs) can capture high-order epistatic interactions among the mutational sites, they tend to overfit to the small number of labeled sequences available for training. Here, we developed Epistatic Net (EN), a method for spectral regularization of DNNs that exploits evidence that epistatic interactions in many fitness functions are sparse. We built a scalable extension of EN, usable for larger sequences, which enables spectral regularization using fast sparse recovery algorithms informed by coding theory. Results on several biological landscapes show that EN consistently improves the prediction accuracy of DNNs and enables them to outperform competing models which assume other priors. EN estimates the higher-order epistatic interactions of DNNs trained on massive sequence spaces-a computational problem that otherwise takes years to solve., Finding a biologically-relevant inductive bias for training DNNs on large fitness landscapes is challenging. Here, the authors propose a method called Epistatic Net that improves DNN prediction accuracy and interpretation speed by integrating the knowledge that higher-order epistatic interactions are usually sparse.

Published
2021

5. XYZeq: Spatially resolved single-cell RNA sequencing reveals expression heterogeneity in the tumor microenvironment

Author

Jonathan M. Woo, Sadaf Mehdizadeh, Cody T. Mowery, Hunter M. Nisonoff, Yang Sun, Youjin V. Lee, Theodore L. Roth, George C. Hartoularos, Yutong Wang, David Lee, Eric Shifrut, Eric D. Chow, Alexander Marson, Yun S. Song, Derek Bogdanoff, Joshua Cantlon, David N. Ngyuen, James Lee, and Chun Jimmie Ye

Subjects
Cell type, ComputingMethodologies_SIMULATIONANDMODELING, Cell, Computational biology, Biology, Transcriptome, Mice, 03 medical and health sciences, 0302 clinical medicine, Neoplasms, Exome Sequencing, Tumor Microenvironment, medicine, Animals, Gene, Research Articles, Cancer, 030304 developmental biology, 0303 health sciences, Tumor microenvironment, Multidisciplinary, Sequence Analysis, RNA, Gene Expression Profiling, Systems Biology, Mesenchymal stem cell, SciAdv r-articles, RNA, ComputingMethodologies_PATTERNRECOGNITION, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Single-Cell Analysis, Function (biology), Research Article
Abstract

XYZeq is a novel scalable platform that directly encodes spatial location from tissue into single-cell RNA sequencing libraries., Single-cell RNA sequencing (scRNA-seq) of tissues has revealed remarkable heterogeneity of cell types and states but does not provide information on the spatial organization of cells. To better understand how individual cells function within an anatomical space, we developed XYZeq, a workflow that encodes spatial metadata into scRNA-seq libraries. We used XYZeq to profile mouse tumor models to capture spatially barcoded transcriptomes from tens of thousands of cells. Analyses of these data revealed the spatial distribution of distinct cell types and a cell migration-associated transcriptomic program in tumor-associated mesenchymal stem cells (MSCs). Furthermore, we identify localized expression of tumor suppressor genes by MSCs that vary with proximity to the tumor core. We demonstrate that XYZeq can be used to map the transcriptome and spatial localization of individual cells in situ to reveal how cell composition and cell states can be affected by location within complex pathological tissue.

Published
2021
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6. OSPREY 3.0: Open‐source protein redesign for you, with powerful new features

Author

Anna U. Lowegard, Adegoke Ojewole, Jeffrey W. Martin, Siyu Wang, Jonathan D. Jou, Elizabeth Dowd, Bruce R. Donald, Graham T. Holt, Marcel S. Frenkel, Pablo Gainza, Aditya Mukund, David Zhou, Mark A. Hallen, and Hunter M. Nisonoff

Subjects
Models, Molecular, 0301 basic medicine, Speedup, Protein Conformation, Computer science, business.industry, Proteins, Usability, General Chemistry, Parallel computing, Python (programming language), Article, 03 medical and health sciences, Computational Mathematics, 030104 developmental biology, Open source, Software, Software design, business, computer, Algorithms, Protein Binding, computer.programming_language
Abstract

We present osprey 3.0, a new and greatly improved release of the osprey protein design software. Osprey 3.0 features a convenient new Python interface, which greatly improves its ease of use. It is over two orders of magnitude faster than previous versions of osprey when running the same algorithms on the same hardware. Moreover, osprey 3.0 includes several new algorithms, which introduce substantial speedups as well as improved biophysical modeling. It also includes GPU support, which provides an additional speedup of over an order of magnitude. Like previous versions of osprey, osprey 3.0 offers a unique package of advantages over other design software, including provable design algorithms that account for continuous flexibility during design and model conformational entropy. Finally, we show here empirically that osprey 3.0 accurately predicts the effect of mutations on protein-protein binding. Osprey 3.0 is available at http://www.cs.duke.edu/donaldlab/osprey.php as free and open-source software. © 2018 Wiley Periodicals, Inc.

Published
2018
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7. Algorithms for protein design

Author

Bruce R. Donald, Pablo Gainza, and Hunter M. Nisonoff

Subjects
0301 basic medicine, Computer science, Protein design, Computational Biology, Proteins, Protein Engineering, Article, 03 medical and health sciences, ComputingMethodologies_PATTERNRECOGNITION, 030104 developmental biology, Structural Biology, Proteins metabolism, Heuristics, Thermodynamics, Molecular Biology, Algorithm, Algorithms
Abstract

Computational structure-based protein design programs are becoming an increasingly important tool in molecular biology. These programs compute protein sequences that are predicted to fold to a target structure and perform a desired function. The success of a program's predictions largely relies on two components: first, the input biophysical model, and second, the algorithm that computes the best sequence(s) and structure(s) according to the biophysical model. Improving both the model and the algorithm in tandem is essential to improving the success rate of current programs, and here we review recent developments in algorithms for protein design, emphasizing how novel algorithms enable the use of more accurate biophysical models. We conclude with a list of algorithmic challenges in computational protein design that we believe will be especially important for the design of therapeutic proteins and protein assemblies.

Published
2016
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8. Beyond medical pluralism: characterising health-care delivery of biomedicine and traditional medicine in rural Guatemala

Author

Elizabeth Hoyler, David Boyd, Roxana Martinez, Kurren Mehta, and Hunter M. Nisonoff

Subjects
Adult, Male, medicine.medical_specialty, Psychological intervention, Alternative medicine, Indigenous, 03 medical and health sciences, 0302 clinical medicine, Converse, Health care, Health Services, Indigenous, Humans, Medicine, Maya, 0601 history and archaeology, 030212 general & internal medicine, Biomedicine, Aged, Aged, 80 and over, 060101 anthropology, Traditional medicine, business.industry, Anthropology, Medical, Public Health, Environmental and Occupational Health, 06 humanities and the arts, Middle Aged, Guatemala, Pluralism (political theory), Female, Medicine, Traditional, Rural Health Services, business, Delivery of Health Care
Abstract

Although approximately one half of Guatemalans are indigenous, the Guatemalan Maya account for 72% of the extremely poor within the country. While some biomedical services are available in these communities, many Maya utilise traditional medicine as a significant, if not primary, source of health care. While existing medical anthropological research characterises these modes of medicine as medically dichotomous or pluralistic, our research in a Maya community of the Western Highlands, Concepción Huista, builds on previous studies and finds instead a syncretistic, imbricated local health system. We find significant overlap and interpenetration of the biomedical and traditional medical models that are described best as a framework where practitioners in both settings employ elements of the other in order to best meet community needs. By focusing on the practitioner's perspective, we demonstrate that in addition to patients' willingness to seek care across health systems, practitioners converse across seemingly distinct systems via incorporation of certain elements of the 'other'. Interventions to date have not accounted for this imbrication. Guatemalan governmental policies to support local healers have led to little practical change in the health-care landscape of the country. Therefore, understanding this complex imbrication is crucial for interventions and policy changes.

Published
2016
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9. OSPREY 3.0: Open-Source Protein Redesign for You, with Powerful New Features

Author

Jeffrey W. Martin, Bruce R. Donald, Elizabeth Dowd, Marcel S. Frenkel, Aditya Mukund, Pablo Gainza, Siyu Wang, Hunter M. Nisonoff, Anna U. Lowegard, Graham T. Holt, Mark A. Hallen, David Zhou, Adegoke Ojewole, and Jonathan D. Jou

Subjects
0303 health sciences, Speedup, business.industry, Computer science, Protein design, Parallel computing, 010501 environmental sciences, Python (programming language), 01 natural sciences, 03 medical and health sciences, Software, Open source, Software design, business, computer, 030304 developmental biology, 0105 earth and related environmental sciences, computer.programming_language
Abstract

We present OSPREY 3.0, a new and greatly improved release of the OSPREY protein design software. OSPREY 3.0 features a convenient new Python interface, which greatly improves its ease of use. It is over two orders of magnitude faster than previous versions of OSPREY when running the same algorithms on the same hardware. Moreover, OSPREY 3.0 includes several new algorithms, which introduce substantial speedups as well as improved biophysical modeling. It also includes GPU support, which provides an additional speedup of over an order of magnitude. Like previous versions of OSPREY, OSPREY 3.0 offers a unique package of advantages over other design software, including provable design algorithms that account for continuous flexibility during design and model conformational entropy. Finally, we show here empirically that OSPREY 3.0 accurately predicts the effect of mutations on protein-protein binding. OSPREY 3.0 is available at http://www.cs.duke.edu/donaldlab/osprey.php as free and open-source software.

Published
2018
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