Your search keyword '"Stutzman HE"' showing total 4 results

1. In vivo Treatment of a Severe Vascular Disease via a Bespoke CRISPR-Cas9 Base Editor.

Author

Alves CRR, Das S, Krishnan V, Ha LL, Fox LR, Stutzman HE, Shamber CE, Kalailingam P, McCarthy S, Cardenas CLL, Fong CE, Imai T, Mitra S, Yun S, Wood RK, Benning FMC, Lawton J, Kim N, Silverstein RA, Ferreira da Silva J, de la Cruz D, Richa R, Malhotra R, Chung DY, Chao LH, Tsai SQ, Maguire CA, Lindsay ME, Kleinstiver BP, and Musolino PL

Abstract

Genetic vascular disorders are prevalent diseases that have diverse etiologies and few treatment options. Pathogenic missense mutations in the alpha actin isotype 2 gene ( ACTA2 ) primarily affect smooth muscle cell (SMC) function and cause multisystemic smooth muscle dysfunction syndrome (MSMDS), a genetic vasculopathy that is associated with stroke, aortic dissection, and death in childhood. Here, we explored genome editing to correct the most common MSMDS-causative mutation ACTA2 R179H. In a first-in-kind approach, we performed mutation-specific protein engineering to develop a bespoke CRISPR-Cas9 enzyme with enhanced on-target activity against the R179H sequence. To directly correct the R179H mutation, we screened dozens of configurations of base editors (comprised of Cas9 enzymes, deaminases, and gRNAs) to develop a highly precise corrective A-to-G edit with minimal deleterious bystander editing that is otherwise prevalent when using wild-type SpCas9 base editors. We then created a murine model of MSMDS that exhibits phenotypes consistent with human patients, including vasculopathy and premature death, to explore the in vivo therapeutic potential of this base editing strategy. Delivery of the customized base editor via an engineered SMC-tropic adeno-associated virus (AAV-PR) vector substantially prolonged survival and rescued systemic phenotypes across the lifespan of MSMDS mice, including in the vasculature, aorta, and brain. Together, our optimization of a customized base editor highlights how bespoke CRISPR-Cas enzymes can enhance on-target correction while minimizing bystander edits, culminating in a precise editing approach that may enable a long-lasting treatment for patients with MSMDS.

Published

2024

2. Base editing strategies to convert CAG to CAA diminish the disease-causing mutation in Huntington's disease.

Author

Choi DE, Shin JW, Zeng S, Hong EP, Jang JH, Loupe JM, Wheeler VC, Stutzman HE, Kleinstiver B, and Lee JM

Subjects

Animals, Mice, Disease Models, Animal, Humans, Mutation, Gene Knock-In Techniques, Huntington Disease genetics, Huntington Disease therapy, Gene Editing methods, Huntingtin Protein genetics, Huntingtin Protein metabolism, Trinucleotide Repeat Expansion genetics

Abstract

An expanded CAG repeat in the huntingtin gene ( HTT ) causes Huntington's disease (HD). Since the length of uninterrupted CAG repeat, not polyglutamine, determines the age-at-onset in HD, base editing strategies to convert CAG to CAA are anticipated to delay onset by shortening the uninterrupted CAG repeat. Here, we developed base editing strategies to convert CAG in the repeat to CAA and determined their molecular outcomes and effects on relevant disease phenotypes. Base editing strategies employing combinations of cytosine base editors and guide RNAs (gRNAs) efficiently converted CAG to CAA at various sites in the CAG repeat without generating significant indels, off-target edits, or transcriptome alterations, demonstrating their feasibility and specificity. Candidate BE strategies converted CAG to CAA on both expanded and non-expanded CAG repeats without altering HTT mRNA and protein levels. In addition, somatic CAG repeat expansion, which is the major disease driver in HD, was significantly decreased in the liver by a candidate BE strategy treatment in HD knock-in mice carrying canonical CAG repeats. Notably, CAG repeat expansion was abolished entirely in HD knock-in mice carrying CAA-interrupted repeats, supporting the therapeutic potential of CAG-to-CAA conversion strategies in HD and potentially other repeat expansion disorders., Competing Interests: DC, JS, SZ, EH, JJ, JL, HS No competing interests declared, VW V.C.W. was a founding scientific advisory board member with financial interest in Triplet Therapeutics Inc, Her financial interests were reviewed and are managed by Massachusetts General Hospital and Mass General Brigham in accordance with their conflict of interest policies. V.C.W. is a scientific advisory board member of LoQus23 Therapeutics Ltd. and has provided paid consulting services to Acadia Pharmaceuticals Inc, Alnylam Inc, Biogen Inc and Passage Bio. V.C.W. has received research support from Pfizer Inc, BK B.P.K is an inventor on patents and/or patent applications filed by Mass General Brigham that describe genome engineering technologies. B.P.K. is a consultant for EcoR1 capital and is a scientific advisory board member of Acrigen Biosciences, Life Edit Therapeutics, and Prime Medicine, JL J-ML consults for GenKOre and serves in the advisory board of GenEdit Inc, (© 2023, Choi et al.)

Published

2024

3. Base editing strategies to convert CAG to CAA diminish the disease-causing mutation in Huntington's disease.

Author

Choi DE, Shin JW, Zeng S, Hong EP, Jang JH, Loupe JM, Wheeler VC, Stutzman HE, Kleinstiver BP, and Lee JM

Abstract

An expanded CAG repeat in the huntingtin gene ( HTT ) causes Huntington's disease (HD). Since the length of uninterrupted CAG repeat, not polyglutamine, determines the age-at-onset in HD, base editing strategies to convert CAG to CAA are anticipated to delay onset by shortening the uninterrupted CAG repeat. Here, we developed base editing strategies to convert CAG in the repeat to CAA and determined their molecular outcomes and effects on relevant disease phenotypes. Base editing strategies employing combinations of cytosine base editors and gRNAs efficiently converted CAG to CAA at various sites in the CAG repeat without generating significant indels, off-target edits, or transcriptome alterations, demonstrating their feasibility and specificity. Candidate BE strategies converted CAG to CAA on both expanded and non-expanded CAG repeats without altering HTT mRNA and protein levels. In addition, somatic CAG repeat expansion, which is the major disease driver in HD, was significantly decreased by a candidate BE strategy treatment in HD knock-in mice carrying canonical CAG repeats. Notably, CAG repeat expansion was abolished entirely in HD knock-in mice carrying CAA-interrupted repeats, supporting the therapeutic potential of CAG-to-CAA conversion base editing strategies in HD and potentially other repeat expansion disorders.

Published

2023

4. Precise DNA cleavage using CRISPR-SpRYgests.

Author

Christie KA, Guo JA, Silverstein RA, Doll RM, Mabuchi M, Stutzman HE, Lin J, Ma L, Walton RT, Pinello L, Robb GB, and Kleinstiver BP

Subjects

DNA genetics, Gene Editing methods, RNA, Guide, CRISPR-Cas Systems, CRISPR-Cas Systems genetics, DNA Cleavage

Abstract

Methods for in vitro DNA cleavage and molecular cloning remain unable to precisely cleave DNA directly adjacent to bases of interest. Restriction enzymes (REs) must bind specific motifs, whereas wild-type CRISPR-Cas9 or CRISPR-Cas12 nucleases require protospacer adjacent motifs (PAMs). Here we explore the utility of our previously reported near-PAMless SpCas9 variant, named SpRY, to serve as a universal DNA cleavage tool for various cloning applications. By performing SpRY DNA digests (SpRYgests) using more than 130 guide RNAs (gRNAs) sampling a wide diversity of PAMs, we discovered that SpRY is PAMless in vitro and can cleave DNA at practically any sequence, including sites refractory to cleavage with wild-type SpCas9. We illustrate the versatility and effectiveness of SpRYgests to improve the precision of several cloning workflows, including those not possible with REs or canonical CRISPR nucleases. We also optimize a rapid and simple one-pot gRNA synthesis protocol to streamline SpRYgest implementation. Together, SpRYgests can improve various DNA engineering applications that benefit from precise DNA breaks., (© 2022. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2023