Distance-Decay Relationships Partially Determine Diversity Patterns of Phyllosphere Bacteria on Tamrix Trees across the Sonoran Desert

Finkel, Omri M.; Burch, Adrien Y.; Elad, Tal; Huse, Susan M.; Lindow, Steven E.; Post, Anton F.; Belkin, Shimshon

doi:10.1128/aem.00888-12

Cited by 104 publications

(83 citation statements)

References 36 publications

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“…Growth at 28°C was observed on solid media over the range of 2.5 to 150 g of NaCl liter Ϫ1 , similar to that reported for other Halomonas strains (9). In addition, growth was observed up to 41°C, which is above the average maximum temperature bacteria would have been expected to encounter in the arid desert samples (1,20). This indicates that the low relative Halomonas populations observed in arid desert samples were likely caused by factors other than temperature.…”

Section: Resultssupporting

confidence: 82%

“…Previous work revealed that while geographical distance represents a significant barrier to bacterial dispersion to Tamarix trees when climatic factors are similar, climatic factors are a major determinant of bacterial community structure on this plant (1,20). The present study has attempted to determine what environmental factors drive the proliferation of Halomonas, a genus exhibiting a strong regional and thus presumably environmental pattern of colonization, on Tamarix trees.…”

Section: Discussionmentioning

confidence: 95%

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Diverse Microhabitats Experienced by Halomonas variabilis on Salt-Secreting Leaves

Burch

Finkel

Cho

et al. 2013

Appl Environ Microbiol

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The leaf surfaces of the salt-excreting tree Tamarix aphylla harbor a wide diversity of halophilic microorganisms, including Halomonas sp., but little is known of the factors that shape community composition in this extreme habitat. We isolated a strain of Halomonas variabilis from the leaf surface of T. aphylla and used it to determine the heterogeneity of salt concentrations experienced by bacteria in this environment. This halophilic strain was transformed with a proU::gfp reporter gene fusion, the fluorescence of which was responsive to NaCl concentrations up to 200 g liter ؊1 . These bioreporting cells were applied to T. aphylla leaves and were subsequently recovered from dew droplets adhering to the leaf surface. Although cells from within a given dew droplet exhibited similar green fluorescent protein fluorescence, the fluorescence intensity varied between droplets and was correlated with the salt concentration measured in each drop. Growth of H. variabilis was observed in all droplets, regardless of the salt concentration. However, cells found in desiccated microniches between dew drops were low in abundance and generally dead. Other bacteria recovered from T. aphylla displayed higher desiccation tolerance than H. variabilis, both in culture and on inoculated plants, despite having lower osmotic tolerance. Thus, the Tamarix leaf surface can be described as a salty desert with occasional oases where water droplets form under humid conditions. While halotolerant bacteria such as Halomonas grow in high concentrations of salt in such wet microniches, other organisms are better suited to survive desiccation in sites that are not wetted.T he leaf surfaces of Tamarix aphylla (hereafter referred to as Tamarix), a resilient tree capable of growth in soils having a wide variety of water availabilities, are colonized by a diverse microbial community (1, 2). Tamarix is successful in saline soils due to an adaptation mechanism that allows it to excrete excess salt onto its scale-like leaf surface. Some of the salt is subsequently shed from the leaf and salinizes the topsoil, thereby inhibiting the growth of other plants and thus enabling some members of this genus to be aggressive invasive species (3). The high levels of salt (NaCl and other salts) and other exudates on the leaves are hygroscopic, and liquid water readily forms droplets on the leaves when the ambient humidity is sufficiently high (4). Chemical characterization of dew droplets and leaf washes from Tamarix reveal that the leaf surface has a high pH (pH Ͼ 9.0) and dissolved salt concentrations that are at least five times higher than those of seawater (2). Thus, in addition to dealing with the normally harsh conditions encountered on all leaves such as high UV irradiation flux and fluctuating temperatures (5), Tamarix epiphytes must also contend with high pH and salinity.Prior research found that the leaves of Tamarix are mainly colonized by halophilic microorganisms adapted to this highly saline environment (2). Although trees at all sites sampled harb...

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Section: Resultssupporting

confidence: 82%

Section: Discussionmentioning

confidence: 95%

Diverse Microhabitats Experienced by Halomonas variabilis on Salt-Secreting Leaves

Burch

Finkel

Cho

et al. 2013

Appl Environ Microbiol

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“…Previous phyllosphere distance-decay studies have found that dispersal limitations are present along with environmental heterogeneity [10,11]. The distribution of abundant taxa, in particular, has suggested that environmental heterogeneity is the likely cause of differences in leaf bacterial communities, while distribution patterns in rare bacterial taxa seemed to support dispersal-driven differences [10].…”

Section: Discussionmentioning

confidence: 97%

“…Compositional differences in the bacterial phyllosphere between different plant species have generally been found to be much greater than intraspecific differences between individuals of the same plant species, even with different geographic origins of the plant host [9]. Conversely, however, geographic location has been found to be a greater predictor of phyllosphere community composition than plant host species and environmental factors [10,11].…”

Section: Introductionmentioning

confidence: 91%

Biogeographic Patterns Between Bacterial Phyllosphere Communities of the Southern Magnolia (Magnolia grandiflora) in a Small Forest

Stone¹,

Jackson²

2016

Microb Ecol

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The phyllosphere presents a unique system of discrete and easily replicable surfaces colonized primarily by bacteria. However, the biogeography of bacteria in the phyllosphere is little understood, especially at small to intermediate scales. Bacterial communities on the leaves of 91 southern magnolia (Magnolia grandiflora) trees 1-452 m apart in a small forest plot were analyzed and fragments of the 16S ribosomal RNA (rRNA) gene sequenced using the Illumina platform. Assemblages were dominated by members of the Alphaproteobacteria, Bacteroidetes, and Acidobacteria. Patterns in community composition were measured by both relative abundance (theta) and presence-absence (Jaccard) dissimilarity metrics. Distance-based Moran's eigenvector map analyses of the distance-decay relationship found a significant, positive relationship between each dissimilarity metric and significant eigenfunctions derived from geographic distance between trees, indicating trees that were closer together had more similar bacterial phyllosphere communities. Indirect gradient analyses revealed that several environmental parameters (canopy cover, tree elevation, and the slope and aspect of the ground beneath trees) were significantly related to multivariate ordination scores based on relative bacterial sequence abundances; however, these relationships were not significant when looking at the incidence of bacterial taxa. This suggests that bacterial growth and abundance in the phyllosphere is shaped by different assembly mechanisms than bacterial presence or absence. More broadly, this study demonstrates that the distance-decay relationship applies to phyllosphere communities at local scales, and that environmental parameters as well as neutral forces may both influence spatial patterns in the phyllosphere.

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“…Similarly, a study measuring bacterial colonization across initially identical sterile microcosms along a 497 m woodland transect found evidence of dispersal limitation over short timescales (a few days) but also demonstrated that such limitation was not important in shaping community composition 5 over longer timescales (more than a week), at which point the local environment became the more important explanatory variable (Bell 2010). In addition, research characterizing the distance-decay relationship among bacterial colonists of the leaf surfaces of saltexcreting Tamarix trees along a 500-km transect found a strong signature of geographic distance in shaping community composition, but also evidence that salinity and humidity 10 were important environmental factors in explaining community dissimilarity (Finkel et al 2012), emphasizing that the spatial scale at which adaptation is occurring is defined both by spatial distance and by the spatial heterogeneity of selection across the landscape.…”

Section: Bacterial Biogeographymentioning

confidence: 98%

Adaptation in Natural Microbial Populations

Koskella

Vos

2015

Annu. Rev. Ecol. Evol. Syst.

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Although their diversity greatly exceeds that of plants and animals, microbial organisms have historically received less attention in ecology and evolutionary biology research. This knowledge gap is rapidly closing, owing to recent technological advances and an increasing appreciation for the role microbes play in shaping ecosystems and human health. In this review, we examine when and how the process and patterns of bacterial adaptation might fundamentally differ from those of macrobes, highlight methods used to measure adaptation in natural microbial populations, and discuss the importance of examining bacterial adaptation across multiple scales. We emphasize the need to consider the scales of adaptation as continua, in which the genetic makeup of bacteria blur boundaries between populations, species, and communities and with them concepts of ecological and evolutionary time. Finally, we examine current directions of the field as we move beyond the stamp-collecting phase and toward a better understanding of microbial adaptation in nature.

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Distance-Decay Relationships Partially Determine Diversity Patterns of Phyllosphere Bacteria on Tamrix Trees across the Sonoran Desert

Cited by 104 publications

References 36 publications

Diverse Microhabitats Experienced by Halomonas variabilis on Salt-Secreting Leaves

Diverse Microhabitats Experienced by Halomonas variabilis on Salt-Secreting Leaves

Biogeographic Patterns Between Bacterial Phyllosphere Communities of the Southern Magnolia (Magnolia grandiflora) in a Small Forest

Adaptation in Natural Microbial Populations

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