Zachary P Harmer scite author profile

Chemistry drives many biological interactions between the microbiota and host animals, yet it is often challenging to identify the chemicals involved. This poses a problem, as such small molecules are excellent sources of potential pharmaceuticals, pretested by nature for animal compatibility. We discovered anti-HIV compounds from small, marine tunicates from the Eastern Fields of Papua New Guinea. Tunicates are a reservoir for novel bioactive chemicals, yet their small size often impedes identification or even detection of the chemicals within. We solved this problem by combining chemistry, metagenomics, and synthetic biology to directly identify and synthesize the natural products. We show that these anti-HIV compounds, the divamides, are a novel family of lanthipeptides produced by symbiotic bacteria living in the tunicate. Neighboring animal colonies contain structurally related divamides that differ starkly in their biological properties, suggesting a role for biosynthetic plasticity in a native context where biological interactions take place.

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MIC-Drop: A platform for large-scale in vivo CRISPR screens

Parvez

Herdman

Beerens

et al. 2021

Science

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Screen time for CRISPR CRISPR-Cas9 has been used to edit the genomes of organisms ranging from fruit flies to primates, but it has not been used in large-scale genetic screens in animals because generating, validating, and keeping track of large numbers of mutant animals is prohibitively laborious. Parvez et al . have developed Multiplexed Intermixed CRISPR Droplets, or MIC-Drop, a platform combining droplet microfluidics, en masse CRISPR injections, and barcoding, to enable large-scale genetic screens. In pilot phenotypic screens in zebrafish, MIC-Drop enabled rapid identification of the target of a small molecule and discovery of several new genes governing cardiovascular development. MIC-Drop is potentially scalable to thousands of targets and adaptable to diverse organisms and experiments. —DJ

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Co-targeting strategy for precise, scarless gene editing with CRISPR/Cas9 and donor ssODNs in Chlamydomonas

Akella

Bačová

et al. 2021

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Programmable site-specific nucleases, such as the CRISPR/Cas9 ribonucleoproteins (RNPs), have allowed creation of valuable knockout mutations and targeted gene modifications in Chlamydomonas (Chlamydomonas reinhardtii). However, in walled strains, present methods for editing genes lacking a selectable phenotype involve co-transfection of RNPs and exogenous double-stranded DNA (dsDNA) encoding a selectable marker gene. Repair of the double-stranded DNA breaks induced by the ribonucleoproteins is usually accompanied by genomic insertion of exogenous dsDNA fragments, hindering the recovery of precise, scarless mutations in target genes of interest. Here, we tested whether co-targeting two genes by electroporation of pairs of CRISPR/Cas9 RNPs and single-stranded oligodeoxynucleotides (ssODNs) would facilitate the recovery of precise edits in a gene of interest (lacking a selectable phenotype) by selection for precise editing of another gene (creating a selectable marker) - in a process completely lacking exogenous dsDNA. We used PPX1 (encoding protoporphyrinogen IX oxidase) as the generated selectable marker, conferring resistance to oxyfluorfen, and identified precise edits in the homolog of bacterial ftsY or the WD and TetratriCopeptide repeats protein 1 (WDTC1) genes in ∼1% of the oxyfluorfen resistant colonies. Analysis of the target site sequences in edited mutants suggested that ssODNs were used as templates for DNA synthesis during homology directed repair, a process prone to replicative errors. The Chlamydomonas acetolactate synthase gene could also be efficiently edited to serve as an alternative selectable marker. This transgene-free strategy may allow creation of individual strains containing precise mutations in multiple target genes, to study complex cellular processes, pathways or structures.

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Lustro: High-Throughput Optogenetic Experiments Enabled by Automation and a Yeast Optogenetic Toolkit

Harmer

McClean

2023

ACS Synth. Biol.

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Optogenetic systems use genetically encoded lightsensitive proteins to control cellular processes. This provides the potential to orthogonally control cells with light; however, these systems require many design−build−test cycles to achieve a functional design and multiple illumination variables need to be laboriously tuned for optimal stimulation. We combine laboratory automation and a modular cloning scheme to enable highthroughput construction and characterization of optogenetic split transcription factors in Saccharomyces cerevisiae. We expand the yeast optogenetic toolkit to include variants of the cryptochromes and enhanced Magnets, incorporate these light-sensitive dimerizers into split transcription factors, and automate illumination and measurement of cultures in a 96-well microplate format for high-throughput characterization. We use this approach to rationally design and test an optimized enhanced Magnet transcription factor with improved light-sensitive gene expression. This approach is generalizable to the high-throughput characterization of optogenetic systems across a range of biological systems and applications.

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High-Throughput Optogenetics Experiments in Yeast Using the Automated Platform Lustro

Harmer

McClean

2023

JoVE

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Zachary P Harmer

Accessing chemical diversity from the uncultivated symbionts of small marine animals

MIC-Drop: A platform for large-scale in vivo CRISPR screens

Co-targeting strategy for precise, scarless gene editing with CRISPR/Cas9 and donor ssODNs in Chlamydomonas

Lustro: High-Throughput Optogenetic Experiments Enabled by Automation and a Yeast Optogenetic Toolkit

High-Throughput Optogenetics Experiments in Yeast Using the Automated Platform Lustro

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