Response of desert biological soil crusts to alterations in precipitation frequency

Belnap, Jayne; Phillips, Susan L.; Miller, Mark E.

doi:10.1007/s00442-003-1438-6

Cited by 260 publications

(197 citation statements)

References 34 publications

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“…Changes in regional weather that alter precipitation and temperature patterns have caused losses of mosses, lichens and cyanobacteria from the surface biocrust that display many parallels to the effects of physical disturbance shown here. For example, multiple years of low rainfall and high temperatures has resulted in a large decline in lichen cover in the Colorado Plateau region (Belnap, 2006;Belnap and Troxler (2006)), and even short-term alterations in summer precipitation pattern have been shown to result in dramatic biocrust decline, with loss of both mosses and cyanobacteria (Belnap et al, 2004;Belnap et al, unpublished data;Johnson, Kuske and Belnap, unpublished data). Soil in stability, and removal of the primary soil C and N inputs conferred by biocrusts, whether instigated by physical disturbance or physiological responses to altered weather conditions, is predicted to have cascading effects on soil erosion and soil biogeochemical cycles that control soil nutrition, and ultimately influence plant establishment and performance in these fragile ecosystems.…”

Section: Discussionmentioning

confidence: 99%

Response and resilience of soil biocrust bacterial communities to chronic physical disturbance in arid shrublands

et al. 2011

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The impact of 10 years of annual foot trampling on soil biocrusts was examined in replicated field experiments at three cold desert sites of the Colorado Plateau, USA. Trampling detrimentally impacted lichens and mosses, and the keystone cyanobacterium, Microcoleus vaginatus, resulting in increased soil erosion and reduced C and N concentrations in surface soils. Trampled biocrusts contained approximately half as much extractable DNA and 20-52% less chlorophyll a when compared with intact biocrusts at each site. Two of the three sites also showed a decline in scytonemin-containing, diazotrophic cyanobacteria in trampled biocrusts. 16S rRNA gene sequence and terminal restriction fragment length polymorphism (T-RFLP) analyses of soil bacteria from untrampled and trampled biocrusts demonstrated a reduced proportion (23-65% reduction) of M. vaginatus and other Cyanobacteria in trampled plots. In parallel, other soil bacterial species that are natural residents of biocrusts, specifically members of the Actinobacteria, Chloroflexi and Bacteroidetes, became more readily detected in trampled than in untrampled biocrusts. Replicate 16S rRNA T-RFLP profiles from trampled biocrusts at all three sites contained significantly more fragments (n ¼ 17) than those of untrampled biocrusts (np6) and exhibited much higher variability among field replicates, indicating transition to an unstable disturbed state. Despite the dramatic negative impacts of trampling on biocrust physical structure and composition, M. vaginatus could still be detected in surface soils after 10 years of annual trampling, suggesting the potential for biocrust re-formation over time. Physical damage of biocrusts, in concert with changing temperature and precipitation patterns, has potential to alter performance of dryland ecosystems for decades.

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Section: Discussionmentioning

confidence: 99%

Response and resilience of soil biocrust bacterial communities to chronic physical disturbance in arid shrublands

et al. 2011

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“…These organisms strongly influence key functional processes, including C and N cycling, soil stabilization and infiltration [6,73,150]. Despite the multiple ecosystem processes and organisms affected by them, relatively few experimental studies have evaluated the response of BSC constituents to global change drivers, and most of them have been carried out in drylands from North America and Australia [64,[151][152][153][154]. Escolar et al [65] evaluated how the composition, structure and performance of lichen-dominated BSCs respond to predicted climatic changes in semi-arid, central Spain.…”

Section: Research Gaps and Future Directionsmentioning

confidence: 99%

It is getting hotter in here: determining and projecting the impacts of global environmental change on drylands

Maestre

Salguero‐Gómez

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2012

Phil. Trans. R. Soc. B

271

209

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Drylands occupy large portions of the Earth, and are a key terrestrial biome from the socio-ecological point of view. In spite of their extent and importance, the impacts of global environmental change on them remain poorly understood. In this introduction, we review some of the main expected impacts of global change in drylands, quantify research efforts on the topic, and highlight how the articles included in this theme issue contribute to fill current gaps in our knowledge. Our literature analyses identify key under-studied areas that need more research (e.g. countries such as Mauritania, Mali, Burkina Faso, Chad and Somalia, and deserts such as the Thar, Kavir and Taklamakan), and indicate that most global change research carried out to date in drylands has been done on a unidisciplinary basis. The contributions included here use a wide array of organisms (from micro-organisms to humans), spatial scales (from local to global) and topics (from plant demography to poverty alleviation) to examine key issues to the socio-ecological impacts of global change in drylands. These papers highlight the complexities and difficulties associated with the prediction of such impacts. They also identify the increased use of long-term experiments and multidisciplinary approaches as priority areas for future dryland research. Major advances in our ability to predict and understand global change impacts on drylands can be achieved by explicitly considering how the responses of individuals, populations and communities will in turn affect ecosystem services. Future research should explore linkages between these responses and their effects on water and climate, as well as the provisioning of services for human development and well-being.

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“…Recently, scientists have focused on the direct and indirect influences vegetation patches and bare patches (or BSC patches) have on infiltration, runoff, erosion, soil water and productivity after precipitation events [122][123][124]. Furthermore, the influences of extreme precipitation events and extreme drought on vegetation pattern are key research fields for domestic and overseas scientists [125].…”

Section: Hydrological Control Of Vegetation Patterns and Processesmentioning

confidence: 99%

“…However, given the unique plant community patterns and hydrological processes in arid desert regions, scientists now prefer to consider the water response and feedback mechanisms in plants from stochastic eco-hydrological viewpoints. Some studies built a kinetic model and analyzed vegetation patterns and dynamics on the basis of the feedback between hydrological processes and vegetation [77,78,129,130] or interpreted the ecological pattern formation process in arid regions, as controlled by hydrology, using a conceptual model such as "Trigger-transmit-reserve-pulse" (TTRP) [122][123][124]. However, the former does not embody the stochastic attributes of precipitation, which is the best way to describe the hydrological characteristics in arid regions, while the latter was only a conceptual model.…”

Section: Building the Eco-hydrological Modelmentioning

confidence: 99%

Review of the ecohydrological processes and feedback mechanisms controlling sand-binding vegetation systems in sandy desert regions of China

et al. 2013

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Soil water is the key abiotic limiting factor in desert areas and hydrological processes determine the vegetation composition, patterns and processes in desert regions. The hydrological processes can be altered by vegetation succession. In this paper, we review the major advances in ecohydrological research and their potential impact on plant-water relations in revegetated desert communities. The major advances in ecohydrological research over the past 50 years in desert areas were analyzed using a case study that investigated the long-term ecosystem effects of sand-binding vegetation in the Tengger Desert. Key challenges and opportunities for ecohydrology research in the future are also discussed in the context of the major scientific issues affecting sand binding vegetation.

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Response of desert biological soil crusts to alterations in precipitation frequency

Cited by 260 publications

References 34 publications

Response and resilience of soil biocrust bacterial communities to chronic physical disturbance in arid shrublands

Response and resilience of soil biocrust bacterial communities to chronic physical disturbance in arid shrublands

It is getting hotter in here: determining and projecting the impacts of global environmental change on drylands

Review of the ecohydrological processes and feedback mechanisms controlling sand-binding vegetation systems in sandy desert regions of China

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