Piyush Jain scite author profile

The CRISPR-Cas12a RNA-guided complexes have tremendous potential for nucleic acid detection but are limited to the picomolar detection limit without an amplification step. Here, we develop a platform with engineered crRNAs and optimized conditions that enabled us to detect various clinically relevant nucleic acid targets with higher sensitivity, achieving a limit of detection in the femtomolar range without any target pre-amplification step. By extending the 3′- or 5′-ends of the crRNA with different lengths of ssDNA, ssRNA, and phosphorothioate ssDNA, we discover a self-catalytic behavior and an augmented rate of LbCas12a-mediated collateral cleavage activity as high as 3.5-fold compared to the wild-type crRNA and with significant improvement in specificity for target recognition. Particularly, the 7-mer DNA extension to crRNA is determined to be universal and spacer-independent for enhancing the sensitivity and specificity of LbCas12a-mediated nucleic acid detection. We perform a detailed characterization of our engineered ENHANCE system with various crRNA modifications, target types, reporters, and divalent cations. With isothermal amplification of SARS-CoV-2 RNA using RT-LAMP, the modified crRNAs are incorporated in a paper-based lateral flow assay that can detect the target with up to 23-fold higher sensitivity within 40–60 min.

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Development of Light‐Activated CRISPR Using Guide RNAs with Photocleavable Protectors

Jain

et al. 2016

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The ability to remotely trigger CRISPR/Cas9 activity would enable new strategies to study cellular events with greater precision and complexity. We developed a method to photocage the activity of the guide RNA called ‘CRISPR-plus’ (CRISPR-precise light-mediated unveiling of sgRNAs). The photoactivatable capability of our CRISPR-plus method is compatible with simultaneous targeting of multiple DNA sequences and supports numerous modifications that can enable guide RNA labeling for use in imaging and mechanistic inquiries.

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Patterning of Gene Expression Using New Photolabile Groups Applied to Light Activated RNAi

2010

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The spacing, timing, and amount of gene expression are crucial for a range of biological processes, including development. For this reason, there have been many attempts to bring gene expression under the control of light. We have previously shown that RNA interference (RNAi) can be controlled with light through the use of siRNA and dsRNA that have their terminal phosphates modified with the dimethoxy nitro phenyl ethyl (DMNPE) group. Upon irradiation, these groups photolyze and release native RNA. The main problem with light activated RNA interference (LARI) to date is that the groups used only partially block RNA interference prior to irradiation, thus limiting the utility of the approach. Here, we describe a new photocleavable group, cyclo-dodecyl DMNPE (CD-DMNPE), designed to completely block the interaction of duplexes with the cellular machinery responsible for RNA interference prior to irradiation. This allowed us to switch from normal to a near complete reduction in gene expression using light, and to construct well-defined patterns of gene expression in cell monolayers. Because this approach is built on the RNA interference pathway, it benefits from the ability to quickly identify duplexes that are effective at low or subnanomolar concentrations. In addition, it allows for the targeting of endogenous genes without additional genetic manipulation. Finally, because of the regiospecificity of CD-DMNPE, it allows a standard duplex to be quickly modified in a single step. The combination of its efficacy and ease of application will allow for the facile control of the spacing, timing, and degree of gene expression in a range of biological systems.

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Light-activated RNA interference using double-stranded siRNA precursors modified using a remarkable regiospecificity of diazo-based photolabile groups

Shah¹,

Jain²,

Kala³

et al. 2009

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Diazo-based precursors of photolabile groups have been used extensively for modifying nucleic acids, with the intention of toggling biological processes with light. These processes include transcription, translation and RNA interference. In these cases, the photolabile groups have been typically depicted as modifying the phosphate backbone of RNA and DNA. In this work we find that these diazo-based reagents in fact react very poorly with backbone phosphates. Instead, they show a remarkable specificity for terminal phosphates and very modest modification of the nucleobases. Furthermore, the photo deprotection of these terminal modifications is shown to be much more facile than nucleobase modified sites. In this study we have characterized this regiospecificity using RNA duplexes and model nucleotides, analyzed using LC/MS/MS. We have also applied this understanding of the regio-specificity to our technique of light activated RNA interference (LARI). We examined 27-mer double-stranded precursors of siRNA (‘dsRNA’), and have modified them using the photo-cleavable di-methoxy nitro phenyl ethyl group (DMNPE) group. By incorporating terminal phosphates in the dsRNA, we are able to guide DMNPE to react at these terminal locations. These modified dsRNA duplexes show superior performance to our previously described DMNPE-modified siRNA, with the range of expression that can be toggled by light increasing by a factor of two.

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A thermostable Cas12b from Brevibacillus leverages one-pot discrimination of SARS-CoV-2 variants of concern

et al. 2022

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Piyush Jain

Enhancement of trans-cleavage activity of Cas12a with engineered crRNA enables amplified nucleic acid detection

Development of Light‐Activated CRISPR Using Guide RNAs with Photocleavable Protectors

Patterning of Gene Expression Using New Photolabile Groups Applied to Light Activated RNAi

Light-activated RNA interference using double-stranded siRNA precursors modified using a remarkable regiospecificity of diazo-based photolabile groups

A thermostable Cas12b from Brevibacillus leverages one-pot discrimination of SARS-CoV-2 variants of concern

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