Unveiling the species‐rank abundance distribution by generalizing the Good‐Turing sample coverage theory

Chao, Anne; Hsieh, Tsung‐Hsin; Chazdon, Robin L.; Colwell, Robert K.; Gotelli, Nicholas J.

doi:10.1890/14-0550.1

Cited by 87 publications

(116 citation statements)

References 27 publications

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“…A minimum bound on the estimate of unseen clones was determined using the Chao1 estimator (37). The complete clonal abundance distribution was inferred using the one-parameter variant of the Chao et al, 2015 method (38), with confidence intervals derived via bootstrapping (resampling with replacement) from the inferred complete distribution using 2,000 realizations. Repertoire diversity and evenness was characterized using the generalized diversity index proposed by Hill (39).…”

Section: Methodsmentioning

confidence: 99%

Dysregulation of B Cell Repertoire Formation in Myasthenia Gravis Patients Revealed through Deep Sequencing

Heiden

Stathopoulos

Zhou

et al. 2017

The Journal of Immunology

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Myasthenia gravis (MG) is a prototypical B cell-mediated autoimmune disease affecting 20–50 per 100,000 people. The majority of patients fall into two clinically distinguishable types based on whether they produce autoantibodies targeting the acetylcholine receptor (AChR-MG) or muscle specific kinase (MuSK-MG). The autoantibodies are pathogenic, but whether their generation is associated with broader defects in the B cell repertoire is unknown. To address this question, we performed deep sequencing of the B cell receptor repertoire of AChR-MG, MuSK-MG and healthy subjects to generate approximately 518,000 unique VH and VL sequences from sorted naïve and memory B cell populations. AChR-MG and MuSK-MG subjects displayed distinct gene segment usage biases in both VH and VL sequences within the naïve and memory compartments. The memory compartment of AChR-MG was further characterized by reduced positive selection of somatic mutations in the H-CDR regions and altered H-CDR3 physicochemical properties. The VL repertoire of MuSK-MG was specifically characterized by reduced V/J segment distance in recombined sequences, suggesting diminished VL receptor editing during B cell development. Our results identify large-scale abnormalities in both the naïve and memory B cell repertoires. Particular abnormalities were unique to either AChR-MG or MuSK-MG indicating that the repertoires reflect the distinct properties of the subtypes. These repertoire abnormalities are consistent with previously observed defects in B cell tolerance checkpoints in MG, thereby offering additional insight regarding the impact of tolerance defects on peripheral autoimmune repertoires. These collective findings point toward a deformed B cell repertoire as a fundamental component of MG.

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Section: Methodsmentioning

confidence: 99%

Dysregulation of B Cell Repertoire Formation in Myasthenia Gravis Patients Revealed through Deep Sequencing

Heiden

Stathopoulos

Zhou

et al. 2017

The Journal of Immunology

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“…Therefore, we estimated average species richness per genus after sampling standardization. We employed shareholder quorum subsampling (SQS; Alroy 2010; Chao and Jost 2012), which uses coverage statistics (Good 1953;Chao et al 2015) to approximate comparable levels of sampling among intervals. Thus, genera are species rich only if they have many frequently subsampled species.…”

Section: Assessing Correlates Of Excess or Deficient Occupancymentioning

confidence: 99%

Evidence for Trait-Based Dominance in Occupancy among Fossil Taxa and the Decoupling of Macroecological and Macroevolutionary Success

Wagner

Plotnick

Lyons

2018

The American Naturalist

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Online enhancements: supplementary materials.abstract: Biological systems provide examples of differential success among taxa, from ecosystems with a few dominant species (ecological success) to clades that possess far more species than sister clades (macroevolutionary success). Macroecological success, the occupation by a species or clade of an unusually high number of areas, has received less attention. If macroecological success reflects heritable traits, then successful species should be related. Genera composed of species possessing those traits should occupy more areas than genera with comparable species richness that lack such traits. Alternatively, if macroecological success reflects autapomorphic traits, then generic occupancy should be a by-product of species richness among genera and occupancy of constituent species. We test this using Phanerozoic marine invertebrates. Although temporal patterns of species and generic occupancy are strongly correlated, inequality in generic occupancy typically is greater than expected. Genus-level patterns cannot be explained solely with species-level patterns. Within individual intervals, deviations between the observed and expected generic occupancy correlate with the number of lithological units (stratigraphic formations), particularly after controlling for geographic range and species richness. However, elevated generic occupancy is unrelated to or negatively associated with either generic geographic ranges or within-genus species richness. Our results suggest that shared traits among congeneric species encourage shortterm macroecological success without generating short-term macroevolutionary success. A broad niche may confer high occupancy but does not necessarily promote speciation.

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“…Values of ACE (Abundance Coverage-based Estimator of species richness), Jack1 (First-order jackknife estimator of species richness), Jack2 (Secondorder jackknife estimator of species richness), Chao1 and Chao2 (Chao richness estimators) and the dominance index (D) [Colwell et al 2004, Magurran 2004, Chao et al 2005, Colwell et al 2012, Chao et al 2015 are also calculated. The dominance index for subfamilies was determined as a percentage of specimens of a particular subfamily in the total of specimens caught.…”

Section: Study Areamentioning

confidence: 99%

The Number and Abundance of Ichneumonidae (Hymenoptera, Apocrita) Subfamilies Occurring in Apple Orchards and on Their Edges

Piekarska-Boniecka

Zyprych-Walczak

Rzańska-Wieczorek

et al. 2018

Acta.Sci.Pol.,Hortorum Cultus

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Plant communities which form orchard edges are a vital element of ecological infrastructure enriching these agrocenoses. The research was conducted in an orchard environment made up of apple orchards and their edges in the form of agricultural cultivations, tree clumps and a road lined with trees and shrubberies. The study aim was to determine the impact of the orchard edge plant diversity onto the number and abundance of Ichneumonidae subfamilies in the orchards. The study showed that orchard environments made up of an apple orchard and edge plants of various species create better living conditions for Ichneumonidae parasitoids than the environment of an orchard and neighbouring agricultural cultivations. The diversity of orchard edge plants positively influences the abundance of the Ichneumonidae subfamilies rather than the number of subfamilies in the orchard. In the orchard habitat the following dominant subfamilies were found: Campopleginae, Cryptinae, Orthocentrinae and Pimplinae. These entomophages may control the abundance of pests infesting orchards.

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Unveiling the species‐rank abundance distribution by generalizing the Good‐Turing sample coverage theory

Cited by 87 publications

References 27 publications

Dysregulation of B Cell Repertoire Formation in Myasthenia Gravis Patients Revealed through Deep Sequencing

Dysregulation of B Cell Repertoire Formation in Myasthenia Gravis Patients Revealed through Deep Sequencing

Evidence for Trait-Based Dominance in Occupancy among Fossil Taxa and the Decoupling of Macroecological and Macroevolutionary Success

The Number and Abundance of Ichneumonidae (Hymenoptera, Apocrita) Subfamilies Occurring in Apple Orchards and on Their Edges

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