Sensing the environment: lessons from fungi

Key Points G-protein-coupled receptors (GPCRs) function as both pheromone and glucose sensors in fungi, whereas transceptors such as Snf3 and Rgt2 are involved in glucose sensing. Fungi have evolved sophisticated amino-acid-sensing systems including Ssy1–Ptr3–Ssy5 (SPS), Gap1 and GPCRs. The transcep...

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Veröffentlicht in:	Nature reviews. Microbiology 2007-01, Vol.5 (1), p.57-69
Hauptverfasser:	Bahn, Yong-Sun, Xue, Chaoyang, Idnurm, Alexander, Rutherford, Julian C, Heitman, Joseph, Cardenas, Maria E
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptation, Physiological Ammonia - analysis Ammonia - metabolism Analysis Animal communication Animals Biomedical and Life Sciences Carbon Dioxide - analysis Carbon Dioxide - metabolism Cellular signal transduction Fungi - physiology G proteins Glucose - analysis Glucose - metabolism Humans Infectious Diseases Kinases Life Sciences Light Medical Microbiology Microbiology Mycoses - microbiology Parasitology Pheromones Pheromones - analysis Pheromones - metabolism Plants - microbiology review-article Senses and sensation Sensors Signal Transduction Virology Yeast
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creator	Bahn, Yong-Sun Xue, Chaoyang Idnurm, Alexander Rutherford, Julian C Heitman, Joseph Cardenas, Maria E
description	Key Points G-protein-coupled receptors (GPCRs) function as both pheromone and glucose sensors in fungi, whereas transceptors such as Snf3 and Rgt2 are involved in glucose sensing. Fungi have evolved sophisticated amino-acid-sensing systems including Ssy1–Ptr3–Ssy5 (SPS), Gap1 and GPCRs. The transceptors Pho84 and Pho87 have key roles in phosphate sensing. In eukaryotic organisms, the cyclic AMP–protein kinase A (cAMP–PKA) and TOR pathways transmit nutrient-derived signals to regulate a myriad of common targets that control complex translational and transcriptional programmes to coordinate nutrient availability with cell growth and differentiation. Fungi sense gases, such as CO 2 and ammonia, to control various cellular responses. Carbonic anhydrase maintains CO 2 /HCO 3 − homeostasis and thereby regulates the cAMP–PKA pathway, which in turn controls growth, differentiation and virulence factors of pathogenic fungi. Ammonia gas is an intercolony signalling mediator that has an important role in the growth and survival of multicellular yeast colonies. Opsins, phytochromes and white collar-1 proteins function in light sensing in fungi, with a conserved role for white collar proteins in blue-light sensing in diverse species. The downstream signalling events after light exposure are yet to be fully illuminated. Fungi use evolutionarily conserved signalling pathways, including the p38/Hog1 mitogen-activated protein kinase (MAPK) pathway and the nutrient sensing Tor and cAMP–PKA pathway, to confer cellular responses against various environmental stresses. However, the development of fungal-specific upstream and downstream systems is also evident, as exemplified by the multi-component phosphorelay system. For successful virulence, pathogenic fungi must counteract a plethora of host-specific factors, such as serum and immune cells in animals, and plant hormones, fatty acids and hard mechanical surface in plants. Signalling pathways that are responsible for the fungus–host interaction include the cAMP–PKA pathway and calcineurin pathway, however many aspects of fungal–host interactions remain to be elucidated. All organisms use numerous signal-transduction systems to sense and respond to their environments and survive in a range of biological niches. Here, the authors review the molecular mechanisms used by the fungal kingdom to sense, and adapt in response to, diverse environmental cues. All living organisms use numerous signal-transduction systems to sense and res
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Fungi have evolved sophisticated amino-acid-sensing systems including Ssy1–Ptr3–Ssy5 (SPS), Gap1 and GPCRs. The transceptors Pho84 and Pho87 have key roles in phosphate sensing. In eukaryotic organisms, the cyclic AMP–protein kinase A (cAMP–PKA) and TOR pathways transmit nutrient-derived signals to regulate a myriad of common targets that control complex translational and transcriptional programmes to coordinate nutrient availability with cell growth and differentiation. Fungi sense gases, such as CO 2 and ammonia, to control various cellular responses. Carbonic anhydrase maintains CO 2 /HCO 3 − homeostasis and thereby regulates the cAMP–PKA pathway, which in turn controls growth, differentiation and virulence factors of pathogenic fungi. Ammonia gas is an intercolony signalling mediator that has an important role in the growth and survival of multicellular yeast colonies. Opsins, phytochromes and white collar-1 proteins function in light sensing in fungi, with a conserved role for white collar proteins in blue-light sensing in diverse species. The downstream signalling events after light exposure are yet to be fully illuminated. Fungi use evolutionarily conserved signalling pathways, including the p38/Hog1 mitogen-activated protein kinase (MAPK) pathway and the nutrient sensing Tor and cAMP–PKA pathway, to confer cellular responses against various environmental stresses. However, the development of fungal-specific upstream and downstream systems is also evident, as exemplified by the multi-component phosphorelay system. For successful virulence, pathogenic fungi must counteract a plethora of host-specific factors, such as serum and immune cells in animals, and plant hormones, fatty acids and hard mechanical surface in plants. Signalling pathways that are responsible for the fungus–host interaction include the cAMP–PKA pathway and calcineurin pathway, however many aspects of fungal–host interactions remain to be elucidated. All organisms use numerous signal-transduction systems to sense and respond to their environments and survive in a range of biological niches. Here, the authors review the molecular mechanisms used by the fungal kingdom to sense, and adapt in response to, diverse environmental cues. All living organisms use numerous signal-transduction systems to sense and respond to their environments and thereby survive and proliferate in a range of biological niches. Molecular dissection of these signalling networks has increased our understanding of these communication processes and provides a platform for therapeutic intervention when these pathways malfunction in disease states, including infection. Owing to the expanding availability of sequenced genomes, a wealth of genetic and molecular tools and the conservation of signalling networks, members of the fungal kingdom serve as excellent model systems for more complex, multicellular organisms. 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Microbiology</title><addtitle>Nat Rev Microbiol</addtitle><addtitle>Nat Rev Microbiol</addtitle><description>Key Points G-protein-coupled receptors (GPCRs) function as both pheromone and glucose sensors in fungi, whereas transceptors such as Snf3 and Rgt2 are involved in glucose sensing. Fungi have evolved sophisticated amino-acid-sensing systems including Ssy1–Ptr3–Ssy5 (SPS), Gap1 and GPCRs. The transceptors Pho84 and Pho87 have key roles in phosphate sensing. In eukaryotic organisms, the cyclic AMP–protein kinase A (cAMP–PKA) and TOR pathways transmit nutrient-derived signals to regulate a myriad of common targets that control complex translational and transcriptional programmes to coordinate nutrient availability with cell growth and differentiation. Fungi sense gases, such as CO 2 and ammonia, to control various cellular responses. Carbonic anhydrase maintains CO 2 /HCO 3 − homeostasis and thereby regulates the cAMP–PKA pathway, which in turn controls growth, differentiation and virulence factors of pathogenic fungi. Ammonia gas is an intercolony signalling mediator that has an important role in the growth and survival of multicellular yeast colonies. Opsins, phytochromes and white collar-1 proteins function in light sensing in fungi, with a conserved role for white collar proteins in blue-light sensing in diverse species. The downstream signalling events after light exposure are yet to be fully illuminated. Fungi use evolutionarily conserved signalling pathways, including the p38/Hog1 mitogen-activated protein kinase (MAPK) pathway and the nutrient sensing Tor and cAMP–PKA pathway, to confer cellular responses against various environmental stresses. However, the development of fungal-specific upstream and downstream systems is also evident, as exemplified by the multi-component phosphorelay system. For successful virulence, pathogenic fungi must counteract a plethora of host-specific factors, such as serum and immune cells in animals, and plant hormones, fatty acids and hard mechanical surface in plants. Signalling pathways that are responsible for the fungus–host interaction include the cAMP–PKA pathway and calcineurin pathway, however many aspects of fungal–host interactions remain to be elucidated. All organisms use numerous signal-transduction systems to sense and respond to their environments and survive in a range of biological niches. Here, the authors review the molecular mechanisms used by the fungal kingdom to sense, and adapt in response to, diverse environmental cues. All living organisms use numerous signal-transduction systems to sense and respond to their environments and thereby survive and proliferate in a range of biological niches. Molecular dissection of these signalling networks has increased our understanding of these communication processes and provides a platform for therapeutic intervention when these pathways malfunction in disease states, including infection. Owing to the expanding availability of sequenced genomes, a wealth of genetic and molecular tools and the conservation of signalling networks, members of the fungal kingdom serve as excellent model systems for more complex, multicellular organisms. 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Microbiology</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Bahn, Yong-Sun</au><au>Xue, Chaoyang</au><au>Idnurm, Alexander</au><au>Rutherford, Julian C</au><au>Heitman, Joseph</au><au>Cardenas, Maria E</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Sensing the environment: lessons from fungi</atitle><jtitle>Nature reviews. Microbiology</jtitle><stitle>Nat Rev Microbiol</stitle><addtitle>Nat Rev Microbiol</addtitle><date>2007-01-01</date><risdate>2007</risdate><volume>5</volume><issue>1</issue><spage>57</spage><epage>69</epage><pages>57-69</pages><issn>1740-1526</issn><eissn>1740-1534</eissn><abstract>Key Points G-protein-coupled receptors (GPCRs) function as both pheromone and glucose sensors in fungi, whereas transceptors such as Snf3 and Rgt2 are involved in glucose sensing. Fungi have evolved sophisticated amino-acid-sensing systems including Ssy1–Ptr3–Ssy5 (SPS), Gap1 and GPCRs. The transceptors Pho84 and Pho87 have key roles in phosphate sensing. In eukaryotic organisms, the cyclic AMP–protein kinase A (cAMP–PKA) and TOR pathways transmit nutrient-derived signals to regulate a myriad of common targets that control complex translational and transcriptional programmes to coordinate nutrient availability with cell growth and differentiation. Fungi sense gases, such as CO 2 and ammonia, to control various cellular responses. Carbonic anhydrase maintains CO 2 /HCO 3 − homeostasis and thereby regulates the cAMP–PKA pathway, which in turn controls growth, differentiation and virulence factors of pathogenic fungi. Ammonia gas is an intercolony signalling mediator that has an important role in the growth and survival of multicellular yeast colonies. Opsins, phytochromes and white collar-1 proteins function in light sensing in fungi, with a conserved role for white collar proteins in blue-light sensing in diverse species. The downstream signalling events after light exposure are yet to be fully illuminated. Fungi use evolutionarily conserved signalling pathways, including the p38/Hog1 mitogen-activated protein kinase (MAPK) pathway and the nutrient sensing Tor and cAMP–PKA pathway, to confer cellular responses against various environmental stresses. However, the development of fungal-specific upstream and downstream systems is also evident, as exemplified by the multi-component phosphorelay system. For successful virulence, pathogenic fungi must counteract a plethora of host-specific factors, such as serum and immune cells in animals, and plant hormones, fatty acids and hard mechanical surface in plants. Signalling pathways that are responsible for the fungus–host interaction include the cAMP–PKA pathway and calcineurin pathway, however many aspects of fungal–host interactions remain to be elucidated. All organisms use numerous signal-transduction systems to sense and respond to their environments and survive in a range of biological niches. Here, the authors review the molecular mechanisms used by the fungal kingdom to sense, and adapt in response to, diverse environmental cues. All living organisms use numerous signal-transduction systems to sense and respond to their environments and thereby survive and proliferate in a range of biological niches. Molecular dissection of these signalling networks has increased our understanding of these communication processes and provides a platform for therapeutic intervention when these pathways malfunction in disease states, including infection. Owing to the expanding availability of sequenced genomes, a wealth of genetic and molecular tools and the conservation of signalling networks, members of the fungal kingdom serve as excellent model systems for more complex, multicellular organisms. Here, we review recent progress in our understanding of how fungal-signalling circuits operate at the molecular level to sense and respond to a plethora of environmental cues.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>17170747</pmid><doi>10.1038/nrmicro1578</doi><tpages>13</tpages></addata></record>
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subjects	Adaptation, Physiological Ammonia - analysis Ammonia - metabolism Analysis Animal communication Animals Biomedical and Life Sciences Carbon Dioxide - analysis Carbon Dioxide - metabolism Cellular signal transduction Fungi - physiology G proteins Glucose - analysis Glucose - metabolism Humans Infectious Diseases Kinases Life Sciences Light Medical Microbiology Microbiology Mycoses - microbiology Parasitology Pheromones Pheromones - analysis Pheromones - metabolism Plants - microbiology review-article Senses and sensation Sensors Signal Transduction Virology Yeast
title	Sensing the environment: lessons from fungi
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