XNA Synthesis and Reverse Transcription by Engineered Thermophilic Polymerases

Cozens, Christopher; Pinheiro, Vitor B.

doi:10.1002/cpch.47

Cited by 8 publications

(9 citation statements)

References 40 publications

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“…The unique biochemistry not only eliminated the time needed before the exponential phase, but also enable direct amplification from the RNA molecules, decreasing error rate traditionally associated with the RT steps (and the resulted nonspecific amplification) [143] [144]. Each RNA molecules are amplified multiple times, leading to more copies of amplification product from the original sample templates [145] [146] [147] [148]. It is unclear how RNA degradation at high temperature compares with RNA templated polymerization efficiency.…”

Section: Engineered Polymerasementioning

confidence: 99%

Navigating the Pandemic Response Life Cycle: Molecular Diagnostics and Immunoassays in the Context of COVID-19 Management

Gharizadeh

Yue

et al. 2021

IEEE Rev. Biomed. Eng.

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Coronavirus disease 2019 (COVID-19) is an infectious disease caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). To counter COVID-19 spreading, an infrastructure to provide rapid and thorough molecular diagnostics and serology testing is the cornerstone of outbreak and pandemic management. We hereby review the clinical insights with regard to using molecular tests and immunoassays in the context of COVID-19 management life cycle: the preventive phase, the preparedness phase, the response phase and the recovery phase. The spatial and temporal distribution of viral RNA, antigens and antibodies during human infection is summarized to provide a biological foundation for accurate detection of the disease. We shared the lessons learned and the obstacles encountered during real world high-volume screening programs. Clinical needs are discussed to identify existing technology gaps in these tests. Leverage technologies, such as engineered polymerases, isothermal amplification, and direct amplification from complex matrices may improve the productivity of current infrastructure, while emerging technologies like CRISPR diagnostics, visual end point detection, and PCR free methods for nucleic acid sensing may lead to at-home tests. The lessons learned, and innovations spurred from the COVID-19 pandemic could upgrade our global public health infrastructure to better combat potential outbreaks in the future.

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Section: Engineered Polymerasementioning

confidence: 99%

Navigating the Pandemic Response Life Cycle: Molecular Diagnostics and Immunoassays in the Context of COVID-19 Management

Gharizadeh

Yue

et al. 2021

IEEE Rev. Biomed. Eng.

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“…It was originally isolated from a screen for HNA reverse transcriptases from T. gorgonarius mutants [13] alongside two other variants, I521P and I521H [23]. It has been shown to be a key enabling mutation for the reverse transcription of a wide range of XNAs [13,24]. Structurally, I521 is in close proximity to a loop crucial to catalysis (C-motif: 538 YSDTDGF 544 in KOD) but how it affects catalysis is less clear.…”

Section: Bypassing Knowledge Gaps With Focused Libraries -The Second mentioning

confidence: 99%

Engineering-driven biological insights into DNA polymerase mechanism

Pinheiro

2019

Current Opinion in Biotechnology

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DNA-dependent DNA polymerases have been extensively studied for over 60 years and lie at the core of multiple biotechnological and diagnostic applications. Nevertheless, these complex molecular machines remain only partially understood. Here we present some evidence on how polymerase engineering for the synthesis and replication of xenobiotic nucleic acids (XNAs) have improved our understanding of these enzymes and how that can be used to gain further insight into their mechanism. Better understanding of the mechanisms of DNA polymerases can accelerate their engineering and we highlight how it is now feasible to use structure-and function-based approaches to systematically and iteratively develop XNA polymerases for increasingly divergent chemistries.

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“…temperature to block them [2]. Capture the beads using the magnetic stand and resuspend beads in 50 µl 2x BWBS-T.…”

Section: Incubate Washed Beads In 1 ML 2x Bwbs-t For 1 H In a Rotatormentioning

confidence: 99%

“…Large-scale screening and characterization of protein libraries is a powerful approach for both protein engineering and directed evolution as it enables (depending on the platform) sampling of up to 10 12 [1] variants facilitating the identification of proteins with tailored functionalities [2,3,4,5]. Nevertheless, that represents only a miniscule fraction of the available variation in a small 100-residue protein (where 10 12 variants equate to approximately 1 x 10 -116 % of the available sequences).…”

Section: Introductionmentioning

confidence: 99%

“…e) In the Phosphorylate Primer Mixes element, the concentration of each individual mutagenic primer can be varied across reactions, if desired.In the above example, all mutagenic primers used in Reaction1 will be made up to a final concentration of 15 µM in the phosphorylation reaction, while the two mutagenic primers used in Reaction2 will be made up to 10 and 30 µM. This flexibility is particularly important when constructing libraries, where it allows controlling the expected ratio of different variants in the final population[2]. The "default" term is used to set the mutagenic primer concentration of all mutagenic primers in all remaining reactions to 20 µM.…”

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confidence: 99%

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Antha-guided Automation of Darwin Assembly for the Construction of Bespoke Gene Libraries

Marquez

Koch

Kestemont

et al. 2019

Preprint

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Protein engineering through directed evolution facilitates the screening and characterization of protein libraries. Efficient and effective methods for multiple sitesaturation mutagenesis, such as Darwin Assembly, can accelerate the sampling of relevant sequence space and the identification of variants with desired functionalities.Here, we present the automation of the Darwin Assembly method, using a Gilson PIPETMAX™ liquid handling platform under the control of the Antha software platform, which resulted in the accelerated construction of complex, multiplexed gene libraries with minimal hands-on time and error-free, while maintaining flexibility over experimental parameters through a graphical user interface rather than requiring userdriven library-dependent programming of the liquid handling platform. We also present an approach for barcoding libraries that overcomes amplicon length limitations in next generation sequencing and enables fast reconstruction of library reads.

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XNA Synthesis and Reverse Transcription by Engineered Thermophilic Polymerases

Cited by 8 publications

References 40 publications

Navigating the Pandemic Response Life Cycle: Molecular Diagnostics and Immunoassays in the Context of COVID-19 Management

Navigating the Pandemic Response Life Cycle: Molecular Diagnostics and Immunoassays in the Context of COVID-19 Management

Engineering-driven biological insights into DNA polymerase mechanism

Antha-guided Automation of Darwin Assembly for the Construction of Bespoke Gene Libraries

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