Your search keyword '"Elmar van der Wijk"' showing total 4 results

1. Disentangling the genetic basis of rhizosphere microbiome assembly in tomato

Author

Ben O. Oyserman, Stalin Sarango Flores, Thom Griffioen, Xinya Pan, Elmar van der Wijk, Lotte Pronk, Wouter Lokhorst, Azkia Nurfikari, Joseph N. Paulson, Mercedeh Movassagh, Nejc Stopnisek, Anne Kupczok, Viviane Cordovez, Víctor J. Carrión, Wilco Ligterink, Basten L. Snoek, Marnix H. Medema, and Jos M. Raaijmakers

Subjects

Science

Abstract

Genetics factors involved in rhizosphere microbiomes assembly remain largely elusive. Here, the authors integrate microbiomics and quantitative plant genetics to reveal genetic loci associated with specific microbes and rhizobacterial traits underlying microbiome assembly in tomato.

Published

2022

2. Probing DNA - Transcription Factor Interactions Using Single-Molecule Fluorescence Detection in Nanofluidic Devices

Author

Mattia Fontana, Klaus Mathwig, Dolf Weijers, Elmar van der Wijk, Simon Lindhoud, Willy A. M. van den Berg, Šarunė Ivanovaitė, Johannes Hohlbein, and Pharmaceutical Analysis

Subjects

single-molecule biophysics, Response element, Biomedical Engineering, Biophysics, Oligonucleotides, microfluidics, Biochemie, Biochemistry, General Biochemistry, Genetics and Molecular Biology, Biomaterials, chemistry.chemical_compound, single-molecule fluorescence detection, Fluorescence Resonance Energy Transfer, Nanotechnology, single-molecule Förster resonance energy transfer, Transcription factor, auxin response factor, chemistry.chemical_classification, lab-on-a-chip, Oligonucleotide, total-internal reflection fluorescence microscopy, Biomolecule, DNA-binding domain, DNA, Single-molecule experiment, Förster resonance energy transfer, Biofysica, chemistry, EPS, DNA Probes, Transcription Factors

Abstract

Single-molecule fluorescence detection offers powerful ways to study biomolecules and their complex interactions. Here, nanofluidic devices and camera-based, single-molecule Förster resonance energy transfer (smFRET) detection are combined to study the interactions between plant transcription factors of the auxin response factor (ARF) family and DNA oligonucleotides that contain target DNA response elements. In particular, it is shown that the binding of the unlabeled ARF DNA binding domain (ARF-DBD) to donor and acceptor labeled DNA oligonucleotides can be detected by changes in the FRET efficiency and changes in the diffusion coefficient of the DNA. In addition, this data on fluorescently labeled ARF-DBDs suggest that, at nanomolar concentrations, ARF-DBDs are exclusively present as monomers. In general, the fluidic framework of freely diffusing molecules minimizes potential surface-induced artifacts, enables high-throughput measurements, and proved to be instrumental in shedding more light on the interactions between ARF-DBDs monomers and between ARF-DBDs and their DNA response element.

Published

2022

3. Disentangling the genetic basis of rhizosphere microbiome assembly in tomato

Author

Ben O Oyserman, Stalin Sarango Flores, Thom Griffioen, Xinya Pan, Elmar van der Wijk, Lotte Pronk, Wouter Lokhorst, Azkia Nurfikari, Nejc Stopnisek, Anne Kupczok, Viviane Cordovez, Víctor J Carrión, Wilco Ligterink, Basten L Snoek, Marnix H Medema, and Jos M Raaijmakers

Subjects

fungi, food and beverages

Abstract

Microbiomes play a pivotal role in plant growth and health, but the genetic factors involved in microbiome assembly remain largely elusive. Here, 16S amplicon and metagenomic features of the rhizosphere microbiome were mapped as quantitative traits of a recombinant inbred line population of a cross between wild and domesticated tomato. Gene content analysis of prioritized tomato QTLs suggested a genetic basis for differential recruitment of various rhizobacterial lineages, including a Streptomyces-associated 6.31-Mbp region harboring tomato domestication sweeps and encoding, among others, the iron regulator FIT and the aquaporin SlTIP2.3. Within metagenome-assembled genomes of the rhizobacterial lineages Streptomyces and Cellvibrio, we identified microbial genes involved in metabolism of plant polysaccharides, iron, sulfur, trehalose, and vitamins, whose genetic variation associated with either modern or wild tomato QTLs. Integrating ‘microbiomics’ and quantitative plant genetics pinpointed putative plant and reciprocal microbial traits underlying microbiome assembly, thereby providing the first step towards plant-microbiome breeding programs.

Published

2021

4. Architecture of DNA elements mediating ARF transcription factor binding and auxin-responsive gene expression in Arabidopsis

Author

Simon Lindhoud, Isidro Crespo, Elmar van der Wijk, Dolf Weijers, Victor G. Levitsky, Mattia Fontana, Victoria V. Mironova, Yana Sizentsova, D. Roeland Boer, Keita Tanaka, Johannes Hohlbein, and Alejandra Freire-Rios

Subjects

Arabidopsis, Biophysics, Biochemie, Cooperativity, Response Elements, Biochemistry, chemistry.chemical_compound, Transcriptional regulation, Gene Expression Regulation, Plant, Basic Helix-Loop-Helix Transcription Factors, Protein–DNA interaction, Auxin, Gene, Transcription factor, ARF transcription factors, Repetitive Sequences, Nucleic Acid, Protein-DNA interaction, Plant biology, Multidisciplinary, Indoleacetic Acids, biology, Arabidopsis Proteins, fungi, Inverted Repeat Sequences, food and beverages, Promoter, Laboratorium voor Celbiologie, Biological Sciences, biology.organism_classification, Cell biology, DNA-Binding Proteins, Laboratory of Cell Biology, Biofysica, chemistry, Multigene Family, protein–DNA interaction, EPS, DNA, Genome-Wide Association Study, Transcription Factors

Abstract

Significance The plant hormone auxin controls many aspects of growth and development. It does so by changing the activity of AUXIN RESPONSE FACTOR (ARF) proteins that recognize specific DNA elements in plant genes and switch gene expression on or off. A major question in plant biology is how these ARF proteins bind unique DNA sequences and thus select which genes are regulated by auxin. Here, the authors systematically study the DNA architecture required for high-affinity binding of ARF proteins, and for auxin-dependent gene regulation in the plant Arabidopsis thaliana. This work shows that repeats of ARF recognition sites are critical for function, and reveals the molecular basis for the distinct activities of different repeat structures., The hormone auxin controls many aspects of the plant life cycle by regulating the expression of thousands of genes. The transcriptional output of the nuclear auxin signaling pathway is determined by the activity of AUXIN RESPONSE transcription FACTORs (ARFs), through their binding to cis-regulatory elements in auxin-responsive genes. Crystal structures, in vitro, and heterologous studies have fueled a model in which ARF dimers bind with high affinity to distinctly spaced repeats of canonical AuxRE motifs. However, the relevance of this "caliper" model, and the mechanisms underlying the binding affinities in vivo, have remained elusive. Here we biochemically and functionally interrogate modes of ARF–DNA interaction. We show that a single additional hydrogen bond in Arabidopsis ARF1 confers high-affinity binding to individual DNA sites. We demonstrate the importance of AuxRE cooperativity within repeats in the Arabidopsis TMO5 and IAA11 promoters in vivo. Meta-analysis of transcriptomes further reveals strong genome-wide association of auxin response with both inverted (IR) and direct (DR) AuxRE repeats, which we experimentally validated. The association of these elements with auxin-induced up-regulation (DR and IR) or down-regulation (IR) was correlated with differential binding affinities of A-class and B-class ARFs, respectively, suggesting a mechanistic basis for the distinct activity of these repeats. Our results support the relevance of high-affinity binding of ARF transcription factors to uniquely spaced DNA elements in vivo, and suggest that differential binding affinities of ARF subfamilies underlie diversity in cis-element function.

Published

2020