Two hybrid histidine kinases, TcsB and the phytochrome FphA, are involved in temperature sensing in Aspergillus nidulans

Two hybrid histidine kinases, TcsB and the phytochrome FphA, are involved in temperature sensing in Aspergillus nidulans

Summary The adaptation of microorganisms to different temperatures is an advantage in habitats with steadily changing conditions and raises the question about temperature sensing. Here we show that in the filamentous fungus Aspergillus nidulans, the hybrid histidine kinase TcsB and phytochrome are i...

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Bibliographic Details
Published in:Molecular microbiology Vol. 112; no. 6; pp. 1814 - 1830
Main Authors: Yu, Zhenzhong, Ali, Arin, Igbalajobi, Olumuyiwa Ayokunle, Streng, Christian, Leister, Kai, Krauß, Norbert, Lamparter, Tilman, Fischer, Reinhard
Format: Journal Article
Language:English
Published: England Blackwell Publishing Ltd 01-12-2019
Subjects:
Aspergillus nidulans
Biliverdin
Detection
Fungi
Heat stress
Heat tolerance
High temperature
Histidine
Histidine kinase
Kinases
Light effects
MAP kinase
Microorganisms
Mimicry
Photoactivation
Reversion
Temperature
Temperature sensors
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Summary:Summary The adaptation of microorganisms to different temperatures is an advantage in habitats with steadily changing conditions and raises the question about temperature sensing. Here we show that in the filamentous fungus Aspergillus nidulans, the hybrid histidine kinase TcsB and phytochrome are involved in temperature‐induced gene transcription. Temperature‐activated phytochrome fed the signal into the HOG MAP kinase pathway. There is evidence that the photoreceptor phytochrome fulfills a temperature sensory role in plants and bacteria. The effects in plants are based on dark reversion from the active form of phytochrome, Pfr, to the inactive form, Pr. Elevated temperature leads to higher dark reversion rates, and hence, temperature sensing depends on light. In A. nidulans and in Alternaria alternata, the temperature response was light‐independent. In order to understand the primary temperature response of phytochrome, we performed spectral analyses of recombinant FphA from both fungi. Spectral properties after heat stress resembled the spectrum of free biliverdin, suggesting conformational changes and a softening of the binding pocket of phytochrome, possibly mimicking photoactivation. We propose a novel function for fungal phytochrome as temperature sensor. Phytochrome has been extensively characterized as red‐light sensor in plants. Recently, it was also discovered in bacteria and fungi. In Aspergillus nidulans and Alternaria alternata, phytochrome is tightly connected to the central stress‐sensing signaling HOG MAP kinase pathway. Here we show that in both fungi, phytochrome plays a dual role in light and in temperature sensing. The temperature‐sensing function of phytochrome was independent of light. We speculate that temperature sensing could be the ancient function of phytochromes.
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ISSN:0950-382X
1365-2958
DOI:10.1111/mmi.14395