13 research outputs found
Molecular-Induced Chirality Transfer to Plasmonic Lattice Modes
Molecular chirality plays fundamental roles in biology. The chiral response of a molecule occurs at a specific spectral position, determined by its molecular structure. This fingerprint can be transferred to other spectral regions via the interaction with localized surface plasmon resonances (LSPRs) of gold nanoparticles. The arrangement of such nanoparticles into periodic lattices gives rise to spectrally sharp and tunable surface lattice resonances (SLRs). Here, we demonstrate that molecular chirality transfer occurs also for plasmonic lattice modes, providing a very effective and tunable means to control chirality. We use colloidal self-assembly to fabricate non-close packed, periodic arrays of gold nanoparticles, which are embedded in a polymer film containing chiral molecules. In the presence of the chiral molecules, the SLRs become optically active, i.e. demonstrating handedness-dependent excitation. Numerical simulations where the lattice parameters are systematically varied show circular dichroism peaks shifting along with the spectral positions of the lattice modes, corroborating the chirality transfer to these collective modes. A semi-analytical model based on the coupling of molecular and plasmonic resonances can rationalize this chirality transfer
Bait sequences.
Potato wart disease is caused by the obligate fungal pathogen Synchytrium endobioticum. DNA extraction from compost, purified spores and crude wart tissue derived from tuber galls of infected potatoes often results in low S. endobioticum DNA concentration or highly contaminated with DNA coming from other microorganisms and the potato host. Therefore, Illumina sequencing of these samples generally results in suboptimal recovery of the nuclear genome sequences of S. endobioticum. A hybridization-based target enrichment protocol was developed to strongly enhance the recovery of S. endobioticum DNA while off-target organisms DNA remains uncaptured. The design strategy involved creating a set of 180,000 molecular baits targeting both gene and non-gene regions of S. endobioticum. The baits were applied to whole genome amplified DNA samples of various S. endobioticum pathotypes (races) in compost, from purified spores and crude wart tissue samples. This was followed by Illumina sequencing and bioinformatic analyses. Compared to non-enriched samples, target enriched samples: 1) showed a significant increase in the proportion of sequenced bases mapped to the S. endobioticum nuclear genome, especially for crude wart tissue samples; 2) yielded sequencing data with higher and better nuclear genome coverage; 3) biased genome assembly towards S. endobioticum sequences, yielding smaller assembly sizes but higher representation of putative S. endobioticum contigs; 4) showed an increase in the number of S. endobioticum genes detected in the genome assemblies. Our hybridization-based target enrichment protocol offers a valuable tool for enhancing genome sequencing and NGS-based molecular detection of S. endobioticum, especially in difficult samples.</div
Scatter plot comparing the genome assembly size of all assembled contigs against the genome size produced from pulling out putative <i>S</i>. <i>endobioticum</i> contigs, in non-enriched and target enriched samples.
Scatter plot comparing the genome assembly size of all assembled contigs against the genome size produced from pulling out putative S. endobioticum contigs, in non-enriched and target enriched samples.</p
Calculations for t-tests.
Potato wart disease is caused by the obligate fungal pathogen Synchytrium endobioticum. DNA extraction from compost, purified spores and crude wart tissue derived from tuber galls of infected potatoes often results in low S. endobioticum DNA concentration or highly contaminated with DNA coming from other microorganisms and the potato host. Therefore, Illumina sequencing of these samples generally results in suboptimal recovery of the nuclear genome sequences of S. endobioticum. A hybridization-based target enrichment protocol was developed to strongly enhance the recovery of S. endobioticum DNA while off-target organisms DNA remains uncaptured. The design strategy involved creating a set of 180,000 molecular baits targeting both gene and non-gene regions of S. endobioticum. The baits were applied to whole genome amplified DNA samples of various S. endobioticum pathotypes (races) in compost, from purified spores and crude wart tissue samples. This was followed by Illumina sequencing and bioinformatic analyses. Compared to non-enriched samples, target enriched samples: 1) showed a significant increase in the proportion of sequenced bases mapped to the S. endobioticum nuclear genome, especially for crude wart tissue samples; 2) yielded sequencing data with higher and better nuclear genome coverage; 3) biased genome assembly towards S. endobioticum sequences, yielding smaller assembly sizes but higher representation of putative S. endobioticum contigs; 4) showed an increase in the number of S. endobioticum genes detected in the genome assemblies. Our hybridization-based target enrichment protocol offers a valuable tool for enhancing genome sequencing and NGS-based molecular detection of S. endobioticum, especially in difficult samples.</div
Correlation of the percentages of bases mapped to the <i>S</i>. <i>endobioticum</i> genome and C<sub>q</sub> value of non-enriched samples tested.
The exponential relationship is defined as y = 1E+06e-0.621x with R2 = 0.94.</p
Percentage of the 8671 <i>S</i>. <i>endobioticum</i> LEV6574 genes putatively detected on the genome assemblies by BLASTn.
Percentage of the 8671 S. endobioticum LEV6574 genes putatively detected on the genome assemblies by BLASTn.</p
Metadata of <i>Synchytrium endobioticum</i> isolates in this study, their C<sub>q</sub> values and library pooling strategy.
Metadata of Synchytrium endobioticum isolates in this study, their Cq values and library pooling strategy.</p
Metagenome assembly lengths.
Potato wart disease is caused by the obligate fungal pathogen Synchytrium endobioticum. DNA extraction from compost, purified spores and crude wart tissue derived from tuber galls of infected potatoes often results in low S. endobioticum DNA concentration or highly contaminated with DNA coming from other microorganisms and the potato host. Therefore, Illumina sequencing of these samples generally results in suboptimal recovery of the nuclear genome sequences of S. endobioticum. A hybridization-based target enrichment protocol was developed to strongly enhance the recovery of S. endobioticum DNA while off-target organisms DNA remains uncaptured. The design strategy involved creating a set of 180,000 molecular baits targeting both gene and non-gene regions of S. endobioticum. The baits were applied to whole genome amplified DNA samples of various S. endobioticum pathotypes (races) in compost, from purified spores and crude wart tissue samples. This was followed by Illumina sequencing and bioinformatic analyses. Compared to non-enriched samples, target enriched samples: 1) showed a significant increase in the proportion of sequenced bases mapped to the S. endobioticum nuclear genome, especially for crude wart tissue samples; 2) yielded sequencing data with higher and better nuclear genome coverage; 3) biased genome assembly towards S. endobioticum sequences, yielding smaller assembly sizes but higher representation of putative S. endobioticum contigs; 4) showed an increase in the number of S. endobioticum genes detected in the genome assemblies. Our hybridization-based target enrichment protocol offers a valuable tool for enhancing genome sequencing and NGS-based molecular detection of S. endobioticum, especially in difficult samples.</div
Scripts used for bioinformatic analyses.
Potato wart disease is caused by the obligate fungal pathogen Synchytrium endobioticum. DNA extraction from compost, purified spores and crude wart tissue derived from tuber galls of infected potatoes often results in low S. endobioticum DNA concentration or highly contaminated with DNA coming from other microorganisms and the potato host. Therefore, Illumina sequencing of these samples generally results in suboptimal recovery of the nuclear genome sequences of S. endobioticum. A hybridization-based target enrichment protocol was developed to strongly enhance the recovery of S. endobioticum DNA while off-target organisms DNA remains uncaptured. The design strategy involved creating a set of 180,000 molecular baits targeting both gene and non-gene regions of S. endobioticum. The baits were applied to whole genome amplified DNA samples of various S. endobioticum pathotypes (races) in compost, from purified spores and crude wart tissue samples. This was followed by Illumina sequencing and bioinformatic analyses. Compared to non-enriched samples, target enriched samples: 1) showed a significant increase in the proportion of sequenced bases mapped to the S. endobioticum nuclear genome, especially for crude wart tissue samples; 2) yielded sequencing data with higher and better nuclear genome coverage; 3) biased genome assembly towards S. endobioticum sequences, yielding smaller assembly sizes but higher representation of putative S. endobioticum contigs; 4) showed an increase in the number of S. endobioticum genes detected in the genome assemblies. Our hybridization-based target enrichment protocol offers a valuable tool for enhancing genome sequencing and NGS-based molecular detection of S. endobioticum, especially in difficult samples.</div
Coverage of each 1kb window.
Potato wart disease is caused by the obligate fungal pathogen Synchytrium endobioticum. DNA extraction from compost, purified spores and crude wart tissue derived from tuber galls of infected potatoes often results in low S. endobioticum DNA concentration or highly contaminated with DNA coming from other microorganisms and the potato host. Therefore, Illumina sequencing of these samples generally results in suboptimal recovery of the nuclear genome sequences of S. endobioticum. A hybridization-based target enrichment protocol was developed to strongly enhance the recovery of S. endobioticum DNA while off-target organisms DNA remains uncaptured. The design strategy involved creating a set of 180,000 molecular baits targeting both gene and non-gene regions of S. endobioticum. The baits were applied to whole genome amplified DNA samples of various S. endobioticum pathotypes (races) in compost, from purified spores and crude wart tissue samples. This was followed by Illumina sequencing and bioinformatic analyses. Compared to non-enriched samples, target enriched samples: 1) showed a significant increase in the proportion of sequenced bases mapped to the S. endobioticum nuclear genome, especially for crude wart tissue samples; 2) yielded sequencing data with higher and better nuclear genome coverage; 3) biased genome assembly towards S. endobioticum sequences, yielding smaller assembly sizes but higher representation of putative S. endobioticum contigs; 4) showed an increase in the number of S. endobioticum genes detected in the genome assemblies. Our hybridization-based target enrichment protocol offers a valuable tool for enhancing genome sequencing and NGS-based molecular detection of S. endobioticum, especially in difficult samples.</div