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Life under quartz: Hypolithic mosses in the Mojave Desert.
PLoS One. 2020; 15(7):e0235928.Plos

Abstract

Several species of dryland cyanobacteria are known to occur as hypoliths under semi-translucent rocks. In the Mojave Desert, these organisms find refuge from intense solar radiation under milky quartz where moisture persists for a longer period of time than in adjacent soil surface habitat. Desert mosses, which are extremely desiccation-tolerant, can also occur in these hypolithic spaces, though little is known about this unique moss microhabitat and how species composition compares to that of adjacent soil surface communities. To address this question, we deployed microclimate dataloggers and collected moss samples from under and adjacent to 18 milky quartz rocks (quartz mean center thickness 26 ± 15 mm) in a western high elevation Mojave Desert site. Light transmission through Mojave quartz rocks may be as low as 1.2%, and data from microclimate loggers deployed for five months support the hypothesis that quartz provides thermal buffering and higher relative humidity compared to the soil surface. Of the 53 samples collected from hypolith and surface microhabitats, 68% were Syntrichia caninervis, the dominant bryophyte of the Mojave Desert biological soil crust. Tortula inermis accounted for 28% of the samples and 4% were Bryum argenteum. In a comparison of moss community composition, we found that S. caninervis was more likely to be on the soil surface, though it was abundant in both microhabitats, while T. inermis was more restricted to hypoliths, perhaps due to protection from temperature extremes. In our study site, the differences between hypolithic and surface microhabitats enable niche partitioning between T. inermis and S. caninervis, enhancing alpha diversity. This work points to the need to thoroughly consider microhabitats when assessing bryophyte species diversity and modelling species distributions. This focus is particularly important in extreme environments, where mosses may find refuge from the prevailing macroclimatic conditions in microhabitats such as hypoliths.

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Authors+Show Affiliations

Ekwealor JTB
Department of Integrative Biology, University of California, Berkeley, California, United States of America.
Fisher KM
Department of Biological Sciences, California State University, Los Angeles, California, United States of America.

MeSH

BryophytaDesert ClimateEcosystemHumidityMicroclimatePlant LeavesPlant ShootsQuartzSoil

Pub Type(s)

Journal Article
Research Support, N.I.H., Extramural
Research Support, Non-U.S. Gov't
Research Support, U.S. Gov't, Non-P.H.S.

Language

eng

PubMed ID

32697785

Citation

Ekwealor, Jenna T B., and Kirsten M. Fisher. "Life Under Quartz: Hypolithic Mosses in the Mojave Desert." PloS One, vol. 15, no. 7, 2020, pp. e0235928.
Ekwealor JTB, Fisher KM. Life under quartz: Hypolithic mosses in the Mojave Desert. PLoS One. 2020;15(7):e0235928.
Ekwealor, J. T. B., & Fisher, K. M. (2020). Life under quartz: Hypolithic mosses in the Mojave Desert. PloS One, 15(7), e0235928. https://doi.org/10.1371/journal.pone.0235928
Ekwealor JTB, Fisher KM. Life Under Quartz: Hypolithic Mosses in the Mojave Desert. PLoS One. 2020;15(7):e0235928. PubMed PMID: 32697785.
* Article titles in AMA citation format should be in sentence-case
TY - JOUR T1 - Life under quartz: Hypolithic mosses in the Mojave Desert. AU - Ekwealor,Jenna T B, AU - Fisher,Kirsten M, Y1 - 2020/07/22/ PY - 2020/03/28/received PY - 2020/06/25/accepted PY - 2020/7/23/entrez PY - 2020/7/23/pubmed PY - 2020/9/20/medline SP - e0235928 EP - e0235928 JF - PloS one JO - PLoS One VL - 15 IS - 7 N2 - Several species of dryland cyanobacteria are known to occur as hypoliths under semi-translucent rocks. In the Mojave Desert, these organisms find refuge from intense solar radiation under milky quartz where moisture persists for a longer period of time than in adjacent soil surface habitat. Desert mosses, which are extremely desiccation-tolerant, can also occur in these hypolithic spaces, though little is known about this unique moss microhabitat and how species composition compares to that of adjacent soil surface communities. To address this question, we deployed microclimate dataloggers and collected moss samples from under and adjacent to 18 milky quartz rocks (quartz mean center thickness 26 ± 15 mm) in a western high elevation Mojave Desert site. Light transmission through Mojave quartz rocks may be as low as 1.2%, and data from microclimate loggers deployed for five months support the hypothesis that quartz provides thermal buffering and higher relative humidity compared to the soil surface. Of the 53 samples collected from hypolith and surface microhabitats, 68% were Syntrichia caninervis, the dominant bryophyte of the Mojave Desert biological soil crust. Tortula inermis accounted for 28% of the samples and 4% were Bryum argenteum. In a comparison of moss community composition, we found that S. caninervis was more likely to be on the soil surface, though it was abundant in both microhabitats, while T. inermis was more restricted to hypoliths, perhaps due to protection from temperature extremes. In our study site, the differences between hypolithic and surface microhabitats enable niche partitioning between T. inermis and S. caninervis, enhancing alpha diversity. This work points to the need to thoroughly consider microhabitats when assessing bryophyte species diversity and modelling species distributions. This focus is particularly important in extreme environments, where mosses may find refuge from the prevailing macroclimatic conditions in microhabitats such as hypoliths. SN - 1932-6203 UR - https://www.unboundmedicine.com/medline/citation/32697785/Life_under_quartz:_Hypolithic_mosses_in_the_Mojave_Desert_ DB - PRIME DP - Unbound Medicine ER -