Margaret H. Frank scite author profile

Rapid development of high-throughput sequencing (HTS) techniques has led biology into the "big-data" era. Data analysis using various bioinformatics softwares or pipelines relying on programming and command-line environment is challenging and time-consuming for most wet-lab biologists. Bioinformatics tools with a user-friendly interface are preferred. Here, we present TBtools (a Toolkit for Biologists integrating various biological data handling tools), a stand-alone software with a user-friendly interface. It has powerful data handling engines for both bulk sequence processing and interactive data visualization. It includes a large collection of functions, which may facilitate much simple, routine but elaborate work on biological data, such as bulk sequence extraction, gene set enrichment analysis, Venn diagram preparation, heatmap illustration, comparative sequence visualization, etc. Availability and implementation:TBtools is a platform-independent software that can be run under all operating systems with Java Runtime Environment 1.

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TBtools - an integrative toolkit developed for interactive analyses of big biological data

Chen

Zhang

et al. 2018

Preprint

937

1,080

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Rootstocks: Diversity, Domestication, and Impacts on Shoot Phenotypes

Warschefsky

Klein

Frank

et al. 2016

Trends in Plant Science

346

270

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Dissecting the molecular signatures of apical cell‐type shoot meristems from two ancient land plant lineages

et al. 2015

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SummaryShoot apical meristem (SAM) structure varies markedly within the land plants. The SAMs of many seedless vascular plants contain a conspicuous inverted, pyramidal cell called the apical cell (AC), which is unidentified in angiosperms.In this study, we use transcriptomic sequencing with precise laser microdissections of meristem subdomains to define the molecular signatures of anatomically distinct zones from the AC-type SAMs of a lycophyte (Selaginella moellendorffii) and a monilophyte (Equisetum arvense). The two model species for this study represent vascular plant lineages that diverged > 400 million yr ago.Our data comprise comprehensive molecular signatures for the distinct subdomains within AC-type SAMs, an anatomical anomaly whose functional significance has been debated in the botanical literature for over two centuries.Moreover, our data provide molecular support for distinct gene expression programs between the AC-type SAMs of Selaginella and Equisetum, as compared with the SAM transcriptome of the angiosperm maize. The results are discussed in light of the functional significance and evolutionary success of the AC-type SAM within the embryophytes.

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Modifications to aLATE MERISTEM IDENTITY1gene are responsible for the major leaf shapes of Upland cotton (Gossypium hirsutumL.)

Andres

Coneva

Frank

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Leaf shape varies spectacularly among plants. Leaves are the primary source of photoassimilate in crop plants, and understanding the genetic basis of variation in leaf morphology is critical to improving agricultural productivity. Leaf shape played a unique role in cotton improvement, as breeders have selected for entire and lobed leaf morphs resulting from a single locus, okra (L-D 1 ), which is responsible for the major leaf shapes in cotton. The L-D 1 locus is not only of agricultural importance in cotton, but through pioneering chimeric and morphometric studies, it has contributed to fundamental knowledge about leaf development. Here we show that an HD-Zip transcription factor homologous to the LATE MERISTEM IDENTITY1 (LMI1) gene of Arabidopsis is the causal gene underlying the L-D 1 locus. The classical okra leaf shape allele has a 133-bp tandem duplication in the promoter, correlated with elevated expression, whereas an 8-bp deletion in the third exon of the presumed wild-type normal allele causes a frame-shifted and truncated coding sequence. Our results indicate that subokra is the ancestral leaf shape of tetraploid cotton that gave rise to the okra allele and that normal is a derived mutant allele that came to predominate and define the leaf shape of cultivated cotton. Virusinduced gene silencing (VIGS) of the LMI1-like gene in an okra variety was sufficient to induce normal leaf formation. The developmental changes in leaves conferred by this gene are associated with a photosynthetic transcriptomic signature, substantiating its use by breeders to produce a superior cotton ideotype. cotton | leaf shape | okra | gene cloning

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Margaret H. Frank

TBtools: An Integrative Toolkit Developed for Interactive Analyses of Big Biological Data

TBtools - an integrative toolkit developed for interactive analyses of big biological data

Rootstocks: Diversity, Domestication, and Impacts on Shoot Phenotypes

Dissecting the molecular signatures of apical cell‐type shoot meristems from two ancient land plant lineages

Modifications to aLATE MERISTEM IDENTITY1gene are responsible for the major leaf shapes of Upland cotton (Gossypium hirsutumL.)

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