Your search keyword '"Nemudraia A"' showing total 3 results

1. The diverse evolutionary histories of domesticated metaviral capsid genes in mammals.

Author

Henriques WS, Young JM, Nemudryi A, Nemudraia A, Wiedenheft B, and Malik HS

Abstract

Selfish genetic elements and their remnants comprise at least half of the human genome. Active transposons duplicate by inserting copies at new sites in a host genome. Following insertion, transposons can acquire mutations that render them inactive; the accrual of additional mutations can render them unrecognizable over time. However, in rare instances, segments of transposons become useful for the host, in a process called gene domestication. Using the first complete human genome assembly and 25 additional vertebrate genomes, we analyzed the evolutionary trajectories and functional potential of genes domesticated from the capsid genes of Metaviridae , a retroviral-like retrotransposon family. Our analysis reveals four families of domesticated capsid genes in placental mammals with varied evolutionary outcomes, ranging from universal retention to lineage-specific duplications or losses and from purifying selection to lineage-specific rapid evolution. The four families of domesticated capsid genes have divergent amino-terminal domains, inherited from four distinct ancestral metaviruses. Structural predictions reveal that many domesticated genes encode a previously unrecognized RNA-binding domain retained in multiple paralogs in mammalian genomes both adjacent to and independent from the capsid domain. Collectively, our study reveals diverse outcomes of domestication of diverse metaviruses, which led to structurally and evolutionarily diverse genes that encode important, but still largely-unknown functions in placental mammals. (207).

Published

2023

2. Repair of CRISPR-guided RNA breaks enables site-specific RNA editing in human cells.

Author

Nemudraia A, Nemudryi A, and Wiedenheft B

Abstract

Genome editing with CRISPR RNA-guided endonucleases generates DNA breaks that are resolved by cellular DNA repair machinery. However, analogous methods to manipulate RNA remain unavailable. Here, we show that site-specific RNA breaks generated with RNA-targeting CRISPR complexes are repaired in human cells, and this repair can be used for programmable deletions in human transcripts that restore gene function. Collectively, this work establishes a technology for precise RNA manipulation with potential therapeutic applications., Competing Interests: Competing interests: B.W. is the founder of SurGene LLC and VIRIS Detection Systems Inc. B.W., A. Nemudryi, and A. Nemudraia are inventors of the patent applications US 63/523,592 and US 63/534,305 pertaining to use type III CRISPR-Cas system for sequence-specific editing of RNA filed by Montana State University.

Published

2023

3. CRISPR-based engineering of RNA viruses.

Author

Nemudryi A, Nemudraia A, Nichols JE, Scherffius AM, Zahl T, and Wiedenheft B

Abstract

CRISPR RNA-guided endonucleases have enabled precise editing of DNA. However, options for editing RNA remain limited. Here, we combine sequence-specific RNA cleavage by CRISPR ribonucleases with programmable RNA repair to make precise deletions and insertions in RNA. This work establishes a new recombinant RNA technology with immediate applications for the facile engineering of RNA viruses., One-Sentence Summary: Programmable CRISPR RNA-guided ribonucleases enable recombinant RNA technology.

Published

2023