Improved monitoring of cryptogam gas-exchange and volatile emissions during desiccation-rehydration cycles with a within-chamber hydration method

Desiccation-rehydration studies in cryptogams constitute an important tool to understand the relation of key physiological traits with species stress tolerance and environmental adaptability. Real-time monitoring of re-sponses has been limited by the design of commercial or custom measuring cuvettes and difficulties in experi-mental manipulation. We developed a within-chamber rehydration method that allows to rewater the samples rapidly, without the need to open the chamber and take out the sample for manual rehydration by the inves-tigator. Data is collected in real-time and simultaneously with an infrared gas-analyzer (LICOR-7000), a chlo-rophyll fluorometer (Maxi Imaging-PAM) and a proton transfer reaction time-of-flight mass-spectrometer (PTR-TOF-MS) for volatile organic compound emissions. The system was tested on four cryptogam species with contrasting ecological distributions. No major errors or kinetics disruptions were found during system testing and measurements. Our within-chamber rehydration method improved accuracy, as measurement periods were not lacking, and repeatability of the protocol by reducing error variance in sample manipulation. This method provides an improved technique to conduct desiccation-rehydration measurements, contributing to the stan-dardization and accuracy of current existing methodologies. A close real-time and simultaneous monitoring of photosynthesis, chlorophyll fluorescence and volatile organic compound emission data, offers a novel perspec-tive in the analysis of the cryptogam stress responses that is yet to be fully explored.

Automated summary

Desiccation-rehydration studies in cryptogams provide valuable insights into the relationship between key physiological traits and species stress tolerance and environmental adaptability. Our developed within-chamber rehydration method enables rapid and precise measurement of sample rehydration without the need for manual intervention. The real-time monitoring of multiple parameters offers a novel perspective in understanding cryptogam stress responses. Evaluation: 8/10.