Your search keyword '"Atsushi Nakano"' showing total 8 results

1. Recessive ciliopathy mutations in primary endocardial fibroelastosis: a rare neonatal cardiomyopathy in a case of Alstrom syndrome

Author

Stanley F. Nelson, Marlin Touma, Steven L. Lee, Myke Federman, Wayne W. Grody, Ryan J. Schmidt, Stacy L. Pineles, Reshma Biniwale, Yan Zhao, Aaron Nagiel, Gary Satou, Zubin Mehta, Glen Van Arsdell, Juan C. Alejos, Xuedong Kang, Atsushi Nakano, Lee-kai Wang, Ascia Eskin, Gregory A. Fishbein, Fabiola Quintero-Rivera, Meena Garg, Leigh C. Reardon, Nancy Halnon, Negar Khanlou, and Viviana M. Fajardo

Subjects

Proband, Exome sequencing, Cardiomyopathy, Cell Cycle Proteins, Cardiovascular, Neonatal cardiomyopathy, Congenital, Drug Discovery, 2.1 Biological and endogenous factors, RNA-Seq, Aetiology, Alstrom syndrome, Genetics (clinical), Genetics, Pediatric, Retinal dystrophy, RNA sequencing, Endocardial Fibroelastosis, Phenotype, Heart Disease, Molecular Medicine, Original Article, Female, Cardiomyopathies, Biotechnology, Epithelial-Mesenchymal Transition, Immunology, Frameshift mutation, Medicinal and Biomolecular Chemistry, Rare Diseases, medicine, Humans, Loss function, Rare undiagnosed disease, business.industry, Myocardium, Human Genome, Infant, Fibroblasts, medicine.disease, Fibrosis, Human genetics, Ciliopathies, Brain Disorders, Ciliopathy, Good Health and Well Being, Mutation, Congenital Structural Anomalies, business, Transcriptome, Epithelial mesenchymal transition, Primary endocardial fibroelastosis, Alström syndrome

Abstract

Abstract Among neonatal cardiomyopathies, primary endocardial fibroelastosis (pEFE) remains a mysterious disease of the endomyocardium that is poorly genetically characterized, affecting 1/5000 live births and accounting for 25% of the entire pediatric dilated cardiomyopathy (DCM) with a devastating course and grave prognosis. To investigate the potential genetic contribution to pEFE, we performed integrative genomic analysis, using whole exome sequencing (WES) and RNA-seq in a female infant with confirmed pathological diagnosis of pEFE. Within regions of homozygosity in the proband genome, WES analysis revealed novel parent-transmitted homozygous mutations affecting three genes with known roles in cilia assembly or function. Among them, a novel homozygous variant [c.1943delA] of uncertain significance in ALMS1 was prioritized for functional genomic and mechanistic analysis. Loss of function mutations of ALMS1 have been implicated in Alstrom syndrome (AS) [OMIM 203800], a rare recessive ciliopathy that has been associated with cardiomyopathy. The variant of interest results in a frameshift introducing a premature stop codon. RNA-seq of the proband’s dermal fibroblasts confirmed the impact of the novel ALMS1 variant on RNA-seq reads and revealed dysregulated cellular signaling and function, including the induction of epithelial mesenchymal transition (EMT) and activation of TGFβ signaling. ALMS1 loss enhanced cellular migration in patient fibroblasts as well as neonatal cardiac fibroblasts, while ALMS1-depleted cardiomyocytes exhibited enhanced proliferation activity. Herein, we present the unique pathological features of pEFE compared to DCM and utilize integrated genomic analysis to elucidate the molecular impact of a novel mutation in ALMS1 gene in an AS case. Our report provides insights into pEFE etiology and suggests, for the first time to our knowledge, ciliopathy as a potential underlying mechanism for this poorly understood and incurable form of neonatal cardiomyopathy. Key message Primary endocardial fibroelastosis (pEFE) is a rare form of neonatal cardiomyopathy that occurs in 1/5000 live births with significant consequences but unknown etiology. Integrated genomics analysis (whole exome sequencing and RNA sequencing) elucidates novel genetic contribution to pEFE etiology. In this case, the cardiac manifestation in Alstrom syndrome is pEFE. To our knowledge, this report provides the first evidence linking ciliopathy to pEFE etiology. Infants with pEFE should be examined for syndromic features of Alstrom syndrome. Our findings lead to a better understanding of the molecular mechanisms of pEFE, paving the way to potential diagnostic and therapeutic applications.

Published

2021

2. The role of glucose in physiological and pathological heart formation

Author

Atsushi Nakano, Haruko Nakano, and Viviana M. Fajardo

Subjects

Heart disease, Organogenesis, Regulator, Cardiovascular, Medical and Health Sciences, Congenital, 0302 clinical medicine, Fetal Stage, Pregnancy, 2.1 Biological and endogenous factors, Aetiology, Heart formation, Heart Defects, Pediatric, 0303 health sciences, Cardiac neural crest cells, Diabetes, Heart, Cell Differentiation, Biological Sciences, medicine.anatomical_structure, Heart Disease, Neural Crest, Prenatal Exposure Delayed Effects, Female, Heart Defects, Congenital, medicine.medical_specialty, 1.1 Normal biological development and functioning, Carbohydrate metabolism, Biology, Article, 03 medical and health sciences, Underpinning research, Internal medicine, medicine, Animals, Humans, Molecular Biology, Metabolic and endocrine, 030304 developmental biology, Nutrition, Fetus, Mesenchymal stem cell, Cell Biology, Perinatal Period - Conditions Originating in Perinatal Period, medicine.disease, Endocrinology, Glucose, Hyperglycemia, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Cells display distinct metabolic characteristics depending on its differentiation stage. The fuel type of the cells serves not only as a source of energy but also as a driver of differentiation. Glucose, the primary nutrient to the cells, is a critical regulator of rapidly growing embryos. This metabolic change is a consequence as well as a cause of changes in genetic program. Disturbance of fetal glucose metabolism such as in diabetic pregnancy is associated with congenital heart disease. In utero hyperglycemia impacts the left-right axis establishment, migration of cardiac neural crest cells, conotruncal formation and mesenchymal formation of the cardiac cushion during early embryogenesis and causes cardiac hypertrophy in late fetal stages. In this review, we focus on the role of glucose in cardiogenesis and the molecular mechanisms underlying heart diseases associated with hyperglycemia.

Published

2021

3. GLUT1 overexpression enhances glucose metabolism and promotes neonatal heart regeneration

Author

Peter M. Clark, Haruko Nakano, Iris Feng, Matteo Pellegrini, Bao Ying Chen, Baochen Shi, Ching-Ling Lien, Atsushi Nakano, Cesar A. Perez-Ramirez, Viviana M. Fajardo, Heather R. Christofk, and Rong Tian

Subjects

Male, Cell biology, Science, Transgene, Glucose uptake, Mice, Transgenic, Carbohydrate metabolism, Regenerative Medicine, Cardiovascular, Transgenic, Article, Mice, chemistry.chemical_compound, Developmental biology, Animals, Metabolomics, Regeneration, Myocytes, Cardiac, Nutrition, Pediatric, Myocytes, Glucose Transporter Type 1, Mice, Inbred ICR, Multidisciplinary, Glycogen, biology, Nucleotides, Regeneration (biology), Glucose transporter, Heart, Newborn, Inbred ICR, Cardiovascular biology, Glucose, Heart Disease, Animals, Newborn, chemistry, biology.protein, Medicine, Female, GLUT1, Cardiac, Intracellular

Abstract

The mammalian heart switches its main metabolic substrate from glucose to fatty acids shortly after birth. This metabolic switch coincides with the loss of regenerative capacity in the heart. However, it is unknown whether glucose metabolism regulates heart regeneration. Here, we report that glucose metabolism is a determinant of regenerative capacity in the neonatal mammalian heart. Cardiac-specific overexpression of Glut1, the embryonic form of constitutively active glucose transporter, resulted in an increase in glucose uptake and concomitant accumulation of glycogen storage in postnatal heart. Upon cryoinjury, Glut1 transgenic hearts showed higher regenerative capacity with less fibrosis than non-transgenic control hearts. Interestingly, flow cytometry analysis revealed two distinct populations of ventricular cardiomyocytes: Tnnt2-high and Tnnt2-low cardiomyocytes, the latter of which showed significantly higher mitotic activity in response to high intracellular glucose in Glut1 transgenic hearts. Metabolic profiling shows that Glut1-transgenic hearts have a significant increase in the glucose metabolites including nucleotides upon injury. Inhibition of the nucleotide biosynthesis abrogated the regenerative advantage of high intra-cardiomyocyte glucose level, suggesting that the glucose enhances the cardiomyocyte regeneration through the supply of nucleotides. Our data suggest that the increase in glucose metabolism promotes cardiac regeneration in neonatal mouse heart.

Published

2021

4. Atrial GIRK Channels Mediate the Effects of Vagus Nerve Stimulation on Heart Rate Dynamics and Arrhythmogenesis

Author

Atsushi Nakano, Elena G. Tolkacheva, Pilar A. Guzman, Steven W. Lee, Allison Anderson, and Kevin Wickman

Subjects

0301 basic medicine, medicine.medical_specialty, Physiology, medicine.medical_treatment, 1.1 Normal biological development and functioning, Medical Physiology, 030204 cardiovascular system & hematology, Cardiovascular, lcsh:Physiology, 03 medical and health sciences, 0302 clinical medicine, arrhythmogenesis, Underpinning research, Internal medicine, Physiology (medical), GIRK channel, Heart rate, Muscarinic acetylcholine receptor, medicine, 2.1 Biological and endogenous factors, Psychology, G protein-coupled inwardly-rectifying potassium channel, Aetiology, Original Research, lcsh:QP1-981, business.industry, urogenital system, Neurosciences, vagus nerve stimulation, atrial, medicine.disease, Vagus nerve, Cardiovascular physiology, 030104 developmental biology, Heart Disease, Good Health and Well Being, Heart failure, Cardiology, cardiovascular system, Cholinergic, business, Kir3, Vagus nerve stimulation, parasympathetic

Abstract

Diminished parasympathetic influence is central to the pathogenesis of cardiovascular diseases, including heart failure and hypertension. Stimulation of the vagus nerve has shown promise in treating cardiovascular disease, prompting renewed interest in understanding the signaling pathway(s) that mediate the vagal influence on cardiac physiology. Here, we evaluated the contribution of G protein-gated inwardly rectifying K+ (GIRK/Kir3) channels to the effect of vagus nerve stimulation (VNS) on heart rate (HR), HR variability (HRV), and arrhythmogenesis in anesthetized mice. As parasympathetic fibers innervate both atria and ventricle, and GIRK channels contribute to the cholinergic impact on atrial and ventricular myocytes, we collected in vivo electrocardiogram recordings from mice lacking either atrial or ventricular GIRK channels, during VNS. VNS decreased HR and increased HRV in control mice, in a muscarinic receptor-dependent manner. This effect was preserved in mice lacking ventricular GIRK channels, but was nearly completely absent in mice lacking GIRK channels in the atria. In addition, atrial-specific ablation of GIRK channels conferred resistance to arrhythmic episodes induced by VNS. These data indicate that atrial GIRK channels are the primary mediators of the impact of VNS on HR, HRV, and arrhythmogenesis in the anesthetized mouse.

Published

2018

5. Glucose inhibits cardiac muscle maturation through nucleotide biosynthesis

Author

Xueqin Ding, Haruko Nakano, Itsunari Minami, James K. Gimzewski, Norio Nakatsuji, Marco Morselli, Aldons J. Lusis, Laurent Vergnes, Addelynn Sagadevan, Heather R. Christofk, Matteo Pellegrini, Daniel Braas, Xiuju Wu, Herman Pappoe, Christopher Dunham, Peter M. Clark, Bernard Ribalet, Adam Z. Stieg, Karen Reue, Atsushi Nakano, Siavash K. Kurdistani, and Kai Fu

Subjects

0301 basic medicine, Heart disease, Mouse, Glucose uptake, Cardiomyopathy, Reproductive health and childbirth, 030204 cardiovascular system & hematology, Inbred C57BL, Muscle Development, Cardiovascular, Pentose Phosphate Pathway, Mice, 0302 clinical medicine, Pregnancy, human pluripotent stem cell, 2.1 Biological and endogenous factors, Myocytes, Cardiac, Biology (General), Aetiology, Heart formation, 2. Zero hunger, Pediatric, diabetes, Stem Cell Research - Induced Pluripotent Stem Cell - Human, Nucleotides, General Neuroscience, Cardiac muscle, Cell Differentiation, General Medicine, 3. Good health, medicine.anatomical_structure, Heart Disease, 5.1 Pharmaceuticals, Medicine, Female, Development of treatments and therapeutic interventions, Research Article, Human, medicine.medical_specialty, QH301-705.5, cardiac, Science, 1.1 Normal biological development and functioning, Pentose phosphate pathway, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, developmental biology, stem cells, Underpinning research, Internal medicine, Diabetes mellitus, medicine, Animals, Humans, human, Conditions Affecting the Embryonic and Fetal Periods, Embryonic Stem Cells, mouse, Nutrition, Fetus, Myocytes, General Immunology and Microbiology, Stem Cell Research - Induced Pluripotent Stem Cell, Myocardium, Gene Expression Profiling, Perinatal Period - Conditions Originating in Perinatal Period, medicine.disease, Stem Cell Research, Mice, Inbred C57BL, 030104 developmental biology, Endocrinology, Developmental Biology and Stem Cells, Glucose, Sweetening Agents, Biochemistry and Cell Biology

Abstract

The heart switches its energy substrate from glucose to fatty acids at birth, and maternal hyperglycemia is associated with congenital heart disease. However, little is known about how blood glucose impacts heart formation. Using a chemically defined human pluripotent stem-cell-derived cardiomyocyte differentiation system, we found that high glucose inhibits the maturation of cardiomyocytes at genetic, structural, metabolic, electrophysiological, and biomechanical levels by promoting nucleotide biosynthesis through the pentose phosphate pathway. Blood glucose level in embryos is stable in utero during normal pregnancy, but glucose uptake by fetal cardiac tissue is drastically reduced in late gestational stages. In a murine model of diabetic pregnancy, fetal hearts showed cardiomyopathy with increased mitotic activity and decreased maturity. These data suggest that high glucose suppresses cardiac maturation, providing a possible mechanistic basis for congenital heart disease in diabetic pregnancy., eLife digest Congenital heart disease is the most common type of birth defect, affecting nearly 1 in 100 children born. It can involve a weak heart, narrowed arteries, narrowed heart valves, or the main arteries of the heart switching places. These conditions can be fatal if untreated and often need surgery to correct. The mother’s blood sugar levels during pregnancy can have a large effect on how likely the baby is to have congenital heart disease. If a pregnant woman has poorly controlled diabetes with rapidly fluctuating sugar levels, she may be at a higher risk of having a child with the condition. High sugar levels in the mother’s blood make the baby up to five times more likely to have congenital heart disease. It has been difficult to find out exactly how sugar levels interfere with heart development because diabetes can affect the fetus in many ways. Nakano et al. used stem cells and experiments in pregnant mice with diabetes to hone in on how high sugar levels affect the fetus’s heart development. First, heart cells were grown from human stem cells, and exposed to high levels of glucose in a dish. This revealed a new mechanism for how high sugar levels affect heart formation: the cells created too many nucleotides, the building blocks of molecules such as DNA. It turns out that high glucose levels boosted a chemical process in the cell known as the pentose phosphate pathway. Some of the products of this pathway are nucleotides. This made the cells divide rapidly, but did not allow them to mature well compared with cells exposed to normal levels of sugar. In another experiment, Nakano et al. found similar results in pregnant diabetic mice. The heart cells in mouse fetuses also divided quickly but matured slowly when exposed to high sugar levels. An estimated 60 million women at an age to have children have diabetes. These new findings help us to understand why and how these women are more likely to have children with congenital heart disease, and further study will hopefully lead to a better way to prevent this condition.

Published

2017

6. Light-sheet fluorescence imaging to localize cardiac lineage and protein distribution

Author

Neha Singh, Jianguo Ma, Tzung K. Hsiai, Parinaz Abiri, Atsushi Nakano, Yichen Ding, Peng Fei, Rajan P. Kulkarni, Juhyun Lee, Thao P. Nguyen, Mojdeh Dooraghi, Tomohiro Yokota, Kevin Sung, and Yibin Wang

Subjects

0301 basic medicine, Fluorescence-lifetime imaging microscopy, Lineage (genetic), Potassium Channels, Heart Ventricles, 1.1 Normal biological development and functioning, Green Fluorescent Proteins, Bioengineering, Biology, Cardiovascular, 01 natural sciences, Regenerative medicine, Article, Fluorescence, Imaging, 010309 optics, 03 medical and health sciences, Mice, Imaging, Three-Dimensional, Underpinning research, 0103 physical sciences, Microscopy, Fluorescence microscope, Animals, Cell Lineage, Progenitor, Multidisciplinary, Myocardium, Proteins, Newborn, Transmembrane protein, Potassium channel, 3. Good health, Cell biology, Other Physical Sciences, 030104 developmental biology, Heart Disease, Animals, Newborn, Microscopy, Fluorescence, Three-Dimensional, Calibration, Biochemistry and Cell Biology

Abstract

Light-sheet fluorescence microscopy (LSFM) serves to advance developmental research and regenerative medicine. Coupled with the paralleled advances in fluorescence-friendly tissue clearing technique, our cardiac LSFM enables dual-sided illumination to rapidly uncover the architecture of murine hearts over 10 by 10 by 10 mm3 in volume; thereby allowing for localizing progenitor differentiation to the cardiomyocyte lineage and AAV9-mediated expression of exogenous transmembrane potassium channels with high contrast and resolution. Without the steps of stitching image columns, pivoting the light-sheet and sectioning the heart mechanically, we establish a holistic strategy for 3-dimentional reconstruction of the “digital murine heart” to assess aberrant cardiac structures as well as the spatial distribution of the cardiac lineages in neonates and ion-channels in adults.

Published

2017

7. Simplified three-dimensional tissue clearing and incorporation of colorimetric phenotyping

Author

Yichen Ding, Michelle Cheng, Cindy F. Yang, Harrison Chen, Dino Di Carlo, Jocelyn T. Kim, Atsushi Nakano, Kevin Sung, Tzung K. Hsiai, Vincent Huang, Rajan P. Kulkarni, Daniel Eguchi, and Jianguo Ma

Subjects

0301 basic medicine, Pathology, medicine.medical_specialty, Computer science, Tissue imaging, Bioengineering, Horseradish peroxidase, Article, Imaging, 03 medical and health sciences, Imaging, Three-Dimensional, 0302 clinical medicine, Microscopy, medicine, Animals, Humans, Colorimetry, Histocytological Preparation Techniques, Microscopy, Confocal, Multidisciplinary, Tissue clearing, biology, 030104 developmental biology, Phenotype, Light sheet fluorescence microscopy, Confocal, Three-Dimensional, biology.protein, Microscopic imaging, Biomedical Imaging, Generic health relevance, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

Tissue clearing methods promise to provide exquisite three-dimensional imaging information; however, there is a need for simplified methods for lower resource settings and for non-fluorescence based phenotyping to enable light microscopic imaging modalities. Here we describe the simplified CLARITY method (SCM) for tissue clearing that preserves epitopes of interest. We imaged the resulting tissues using light sheet microscopy to generate rapid 3D reconstructions of entire tissues and organs. In addition, to enable clearing and 3D tissue imaging with light microscopy methods, we developed a colorimetric, non-fluorescent method for specifically labeling cleared tissues based on horseradish peroxidase conversion of diaminobenzidine to a colored insoluble product. The methods we describe here are portable and can be accomplished at low cost and can allow light microscopic imaging of cleared tissues, thus enabling tissue clearing and imaging in a wide variety of settings.

Published

2016

8. Mitochondrial Ca(2+) uptake by the voltage-dependent anion channel 2 regulates cardiac rhythmicity

Author

Joshua I. Goldhaber, Sarah Franklin, James K. Gimzewski, Huanqi Zhu, Johann Schredelseker, György Hajnóczky, Ohyun Kwon, Atsushi Nakano, Fei Lu, Kevin Wang, Haruko Nakano, Hirohito Shimizu, Thomas M. Vondriska, Junichi Nakai, Amy Ehrlich, Kui Lu, Billy Lin, Cheng Tian, Adam Z. Stieg, Jau-Nian Chen, Hannah D. G. Fiji, Jie Huang, and Shamim Naghdi

Subjects

Cardiac rhythmicity, Video Recording, Mitochondrion, Cardiovascular, Heart Rate, cell biology, Myocyte, 2.1 Biological and endogenous factors, Myocytes, Cardiac, Biology (General), Aetiology, Zebrafish, Calcium signaling, biology, VDAC, General Neuroscience, General Medicine, 3. Good health, Cell biology, Mitochondria, Heart Disease, Embryo, 5.1 Pharmaceuticals, Medicine, Development of treatments and therapeutic interventions, VDAC2, Cardiac, Research Article, medicine.medical_specialty, Voltage-dependent anion channel, QH301-705.5, Science, Calcium pump, Molecular Sequence Data, heart, arrhythmia, General Biochemistry, Genetics and Molecular Biology, developmental biology, stem cells, Internal medicine, medicine, Animals, Calcium Signaling, Amino Acid Sequence, human, fibrillation, mouse, Myocytes, General Immunology and Microbiology, Voltage-Dependent Anion Channel 2, Mammalian, T-type calcium channel, Cell Biology, Zebrafish Proteins, Embryo, Mammalian, Myocardial Contraction, Endocrinology, Developmental Biology and Stem Cells, calcium handling, biology.protein, Calcium, Biochemistry and Cell Biology

Abstract

Tightly regulated Ca2+ homeostasis is a prerequisite for proper cardiac function. To dissect the regulatory network of cardiac Ca2+ handling, we performed a chemical suppressor screen on zebrafish tremblor embryos, which suffer from Ca2+ extrusion defects. Efsevin was identified based on its potent activity to restore coordinated contractions in tremblor. We show that efsevin binds to VDAC2, potentiates mitochondrial Ca2+ uptake and accelerates the transfer of Ca2+ from intracellular stores into mitochondria. In cardiomyocytes, efsevin restricts the temporal and spatial boundaries of Ca2+ sparks and thereby inhibits Ca2+ overload-induced erratic Ca2+ waves and irregular contractions. We further show that overexpression of VDAC2 recapitulates the suppressive effect of efsevin on tremblor embryos whereas VDAC2 deficiency attenuates efsevin's rescue effect and that VDAC2 functions synergistically with MCU to suppress cardiac fibrillation in tremblor. Together, these findings demonstrate a critical modulatory role for VDAC2-dependent mitochondrial Ca2+ uptake in the regulation of cardiac rhythmicity. DOI: http://dx.doi.org/10.7554/eLife.04801.001, eLife digest The heart is a large muscle that pumps blood around the body by maintaining a regular rhythm of contraction and relaxation. If the heart loses this regular rhythm it works less efficiently, which can lead to life-threatening conditions. Regular heart rhythms are maintained by changes in the concentration of calcium ions in the cytoplasm of the heart muscle cells. These changes are synchronised so that the heart cells contract in a controlled manner. In each cell, a contraction begins when calcium ions from outside the cell enter the cytoplasm by passing through a channel protein in the membrane that surrounds the cell. This triggers the release of even more calcium ions into the cytoplasm from stores within the cell. For the cells to relax, the calcium ions must then be pumped out of the cytoplasm to lower the calcium ion concentration back to the original level. Shimizu et al. studied a zebrafish mutant—called tremblor—that has irregular heart rhythms because its heart muscle cells are unable to efficiently remove calcium ions from the cytoplasm. Embryos of the tremblor mutant were treated with a wide variety of chemical compounds with the aim of finding some that could correct the heart defect. A compound called efsevin restores regular heart rhythms in tremblor mutants. Efsevin binds to a pump protein called VDAC2, which is found in compartments called mitochondria within the cell. Although mitochondria are best known for their role in supplying energy for the cell, they also act as internal stores for calcium. By binding to VDAC2, efsevin increases the rate at which calcium ions are pumped from the cytoplasm into the mitochondria. This restores rhythmic calcium ion cycling in the cytoplasm and enables the heart muscle cells to develop regular rhythms of contraction and relaxation. Increasing the levels of VDAC2 or another similar calcium ion pump protein in the heart cells can also restore a regular heart rhythm. Efsevin can also correct irregular heart rhythms in human and mouse heart muscle cells, therefore the new role for mitochondria in controlling heart rhythms found by Shimizu et al. appears to be shared in other animals. The experiments have also identified the VDAC family of proteins as potential new targets for drug therapies to treat people with irregular heart rhythms. DOI: http://dx.doi.org/10.7554/eLife.04801.002

Published

2015