Deconvoluting lung evolution: From phenotypes to gene regulatory networks

Keyphrases

• Lung Evolution 100%
• Terminal Unit 33%
• Co-evolving 33%
• Erythropoietin 33%
• Flexible Control 33%
• Respiratory Regulation 33%
• Alveolar Oxygen Tension 33%
• Alveolarization 33%
• Levels of Organization 33%
• Sensing Molecules 33%
• High Oxygen 33%
• Lung Hyperinflation 33%
• Normoxic Conditions 33%
• Non-athletic 33%
• Oxygen Sensing 33%
• Lung Development 33%
• Functional Evolution 33%
• Dead Space 33%
• Pharynx 33%
• Large Mammals 33%
• Aquatic Organisms 33%
• Low Compliance 33%
• Parathyroid Hormone-related Protein (PTHrP) 33%
• Lung Growth 33%
• Whole Organ 33%
• Molecular Signaling 33%
• Terrestrial Organisms 33%
• Swim Bladder 33%
• Unique Mechanism 33%
• Cardiopulmonary Response 33%
• Diaphragm 33%
• Nematodes 33%
• All Levels 33%
• Crocodile 33%
• Gas Pump 33%
• Arterial Oxygen Tension 33%

Biochemistry, Genetics and Molecular Biology

• Oxygen Consumption 100%
• Gas Exchange 100%
• Gene Regulatory Network 100%
• Signal Transduction 50%
• Erythropoietin 50%
• Respiration Control 50%
• Pharynx 50%
• Morphogenesis 50%
• Growth Factor 50%
• Flight 50%
• Lung Alveolus Oxygen Tension 50%
• Parathyroid Hormone-Related Protein 50%
• Oxygen Sensing 50%
• Nematode 50%
• Lung Development 50%
• Lung Diffusion Capacity 50%
• Metabolic Rate 50%
• Terrestrial Species 50%
• Hypoxia Inducible Factor 1alpha 50%
• Arterial Oxygen Tension 50%
• Aquatic Species 50%

Immunology and Microbiology

• Oxygen Consumption 100%
• Gas Exchange 100%
• Gene Regulatory Network 100%
• Growth Factor 50%
• Signal Transduction 50%
• Flight 50%
• Metabolic Rate 50%
• Lung Diffusion Capacity 50%
• Morphogenesis 50%
• Lung Development 50%
• Respiration Control 50%
• Oxygen Sensing 50%
• Hypoxia Inducible Factor 1alpha 50%
• Terrestrial Species 50%
• Aquatic Species 50%
• Arterial Oxygen Tension 50%
• Nematode 50%
• Lung Alveolus Oxygen Tension 50%
• Diaphragm 50%
• Erythropoietin 50%