Project description:Syntrichia caninervis overview

Project description:Syntrichia ruralis overview

Project description:Syntrichia caninervis Raw sequence reads

Project description:Proteomic and Phosphoproteomic sequencing under dehydration and rehydration process of Syntrichia caninervis Mitt. from Gurbantonggute desert, Xinjiang

Project description:Syntrichia caninervis isolate:UNLV-B-0003721 | cultivar:Stark NV-107 Genome sequencing and assembly

Project description:Expression Profiling to Identify Novel Desiccation Response Transcripts from Tortula ruralis gametophytes

Project description:Syntrichia ruraliformis (sandhill screwmoss)

Project description:The phylogeny of Syntrichia Brid.

Project description:Population genetics in Syntrichia caninervis

Project description:Abstract Syntrichia relies on external water conduction for photosynthesis, survival, and reproduction, a condition referred to as ectohydry. Capillarity spaces are abundant in Syntrichia, but the link between function and morphology is complex. The aim of this study was to provide a better understanding of species-specific morphological traits underlying the functions of water conduction and storage. We used an environmental scanning electron microscope and confocal microscopy for observing anatomical characters in the leaves of Syntrichia species. We also measured hydration/dehydration curves to understand the rate of conduction and dehydration by experimental approaches. Syntrichia is an ectohydric moss that can externally transport and store water from the base of the stem using capillary action. We propose a new framework to study ectohydric capabilities, which incorporates three morphological scales and the timing of going from completely dehydrated to fully hydrated. Characters of interest in this model include cell anatomy (papillae development, hyaline basal cells and laminar cells), architecture of the stem (concavity and orientation) and whole clump characteristics (density of stems). We report significant variations in the speed of conduction, water holding capacity and hydration associated with each species studied (11 in total). All Syntrichia species are capable of external water conduction and storage, but the relevant traits differ among species. These results help to understand potential evolutionary and ecological trade-offs among speed of water conduction, water holding capacity, ontogeny, and differing habitat requirements. An integrative view of ectohydry in Syntrichia contributes to understanding the water relationships of mosses. Terrestrialization imposed major challenges for photosynthetic organisms. Bryophytes adapted to move and store water externally (ectohydry) rather than through a specialized internal machinery (vascular system). This study provides the basis for understanding the main factors influencing ectohydry and understanding of species-specific morphological traits underlying functions of conduction or storage in the dryland moss Syntrichia. Better understanding of the roles of mosses and their water relations, in habitats where these plants form thick 'buffering' layers between the substrate and the atmosphere, will lead to better appreciation of their importance for water retention, storage and flow in dryland ecosystems