Anna Singer scite author profile

CRISPR-Cas systems offer versatile technologies for genome engineering, yet their implementation has been outpaced by ongoing discoveries of new Cas nucleases and anti-CRISPR proteins. Here, we present the use of E. coli cell-free transcription-translation (TXTL) systems to vastly improve the speed and scalability of CRISPR characterization and validation. TXTL can express active CRISPR machinery from added plasmids and linear DNA, and TXTL can output quantitative dynamics of DNA cleavage and gene repression-all without protein purification or live cells. We used TXTL to measure the dynamics of DNA cleavage and gene repression for single- and multi-effector CRISPR nucleases, predict gene repression strength in E. coli, determine the specificities of 24 diverse anti-CRISPR proteins, and develop a fast and scalable screen for protospacer-adjacent motifs that was successfully applied to five uncharacterized Cpf1 nucleases. These examples underscore how TXTL can facilitate the characterization and application of CRISPR technologies across their many uses.

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Gene transfers from diverse bacteria compensate for reductive genome evolution in the chromatophore of Paulinella chromatophora

Nowack

Price

Bhattacharya

et al. 2016

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

133

139

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Plastids, the photosynthetic organelles, originated >1 billion y ago via the endosymbiosis of a cyanobacterium. The resulting proliferation of primary producers fundamentally changed global ecology. Endosymbiotic gene transfer (EGT) from the intracellular cyanobacterium to the nucleus is widely recognized as a critical factor in the evolution of photosynthetic eukaryotes. The contribution of horizontal gene transfers (HGTs) from other bacteria to plastid establishment remains more controversial. A novel perspective on this issue is provided by the amoeba Paulinella chromatophora, which contains photosynthetic organelles (chromatophores) that are only 60-200 million years old. Chromatophore genome reduction entailed the loss of many biosynthetic pathways including those for numerous amino acids and cofactors. How the host cell compensates for these losses remains unknown, because the presence of bacteria in all available P. chromatophora cultures excluded elucidation of the full metabolic capacity and occurrence of HGT in this species. Here we generated a high-quality transcriptome and draft genome assembly from the first bacteria-free P. chromatophora culture to deduce rules that govern organelle integration into cellular metabolism. Our analyses revealed that nuclear and chromatophore gene inventories provide highly complementary functions. At least 229 nuclear genes were acquired via HGT from various bacteria, of which only 25% putatively arose through EGT from the chromatophore genome. Many HGT-derived bacterial genes encode proteins that fill gaps in critical chromatophore pathways/processes. Our results demonstrate a dominant role for HGT in compensating for organelle genome reduction and suggest that phagotrophy may be a major driver of HGT.endosymbiosis | genome evolution | organellogenesis | horizontal gene transfer | coevolution

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Massive Protein Import into the Early-Evolutionary-Stage Photosynthetic Organelle of the Amoeba Paulinella chromatophora

et al. 2017

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The endosymbiotic acquisition of mitochondria and plastids more than 1 Ga ago profoundly impacted eukaryote evolution. At the heart of understanding organelle evolution is the re-arrangement of the endosymbiont proteome into a host-controlled organellar proteome. However, early stages in this process as well as the timing of events that underlie organelle integration remain poorly understood. The amoeba Paulinella chromatophora contains cyanobacterium-derived photosynthetic organelles, termed "chromatophores," that were acquired more recently (around 100 Ma ago). To explore the re-arrangement of an organellar proteome during its integration into a eukaryotic host cell, here we characterized the chromatophore proteome by protein mass spectrometry. Apparently, genetic control over the chromatophore has shifted substantially to the nucleus. Two classes of nuclear-encoded proteins-which differ in protein length-are imported into the chromatophore, most likely through independent pathways. Long imported proteins carry a putative, conserved N-terminal targeting signal, and many specifically fill gaps in chromatophore-encoded metabolic pathways or processes. Surprisingly, upon heterologous expression in a plant cell, the putative chromatophore targeting signal conferred chloroplast localization. This finding suggests common features in the protein import pathways of chromatophores and plastids, two organelles that evolved independently and more than 1 Ga apart from each other. By combining experimental data with in silico predictions, we provide a comprehensive catalog of almost 450 nuclear-encoded, chromatophore-targeted proteins. Interestingly, most imported proteins seem to derive from ancestral host genes, suggesting that the re-targeting of nuclear-encoded proteins that resulted from endosymbiotic gene transfers plays only a minor role at the onset of chromatophore integration.

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MXB inhibits murine cytomegalovirus

Vasudevan¹,

Bähr²,

Grothmann³

et al. 2018

Virology

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The MX dynamin GTPases inhibit diverse viruses at early post-entry phases. While MXA acts antiviral against influenza viruses, the anti HIV-1 activity of MXB was discovered recently. Here, we have studied the antiviral effect of MX proteins on murine cytomegalovirus (MCMV). Our data demonstrate that human MXB but not other human or murine MX proteins inhibit MCMV propagation. Evidently, the viral protein expression was delayed and the viral DNA amount in nucleus was diminished in MXB expressing cells indicating an obstruction of nuclear entry. Of note, MCMV did not deplete MX proteins. Considering the role of capsid on HIV-1 sensitivity to MXB, MXB binding to tested MCMV capsids was not detected. Moreover, MCMV restriction occurred only when MXB contained both the nuclear localization signal and a functional GTPase domain. Hence, we propose a new mode of inhibition of MCMV by MXB that is conspicuously different from that of HIV-1.

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Characterization and Validation of a Novel Group of Type V, Class 2 Nucleases forin vivoGenome Editing

Begemann

Gray

January

et al. 2017

Preprint

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1CRISPR-based genome editing is an enabling technology with potential to dramatically transform multiple industries. Identification of additional editing tools will be imperative for broad adoption and application of this technology. A novel Type V, Class 2 CRISPR nuclease system was identified from Microgenomates and Smithella bacterial species (CRISPR from Microgenomates and Smithella, Cms1). This system was shown to efficiently generate indel mutations in the major crop plant rice (Oryza sativa). Cms1 are distinct from other Type V nucleases, are smaller than most other CRISPR nucleases, do not require a tracrRNA, and have an AT-rich protospacer-adjacent motif site requirement. A total of four novel Cms1 nucleases across multiple bacterial species were shown to be functional in a eukaryotic system. This is a major expansion of the Type V CRISPR effector protein toolbox and increases the diversity of options available to researchers.

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Anna Singer

Rapid and Scalable Characterization of CRISPR Technologies Using an E. coli Cell-Free Transcription-Translation System

Gene transfers from diverse bacteria compensate for reductive genome evolution in the chromatophore of Paulinella chromatophora

Massive Protein Import into the Early-Evolutionary-Stage Photosynthetic Organelle of the Amoeba Paulinella chromatophora

MXB inhibits murine cytomegalovirus

Characterization and Validation of a Novel Group of Type V, Class 2 Nucleases forin vivoGenome Editing

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