Your search keyword '"Catiana H Cartwright-Acar"' showing total 3 results

1. Single B cell transcriptomics identifies multiple isotypes of broadly neutralizing antibodies against flaviviruses.

Author

Jay Lubow, Lisa M Levoir, Duncan K Ralph, Laura Belmont, Maya Contreras, Catiana H Cartwright-Acar, Caroline Kikawa, Shruthi Kannan, Edgar Davidson, Veronica Duran, David E Rebellon-Sanchez, Ana M Sanz, Fernando Rosso, Benjamin J Doranz, Shirit Einav, Frederick A Matsen Iv, and Leslie Goo

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

Sequential dengue virus (DENV) infections often generate neutralizing antibodies against all four DENV serotypes and sometimes, Zika virus. Characterizing cross-flavivirus broadly neutralizing antibody (bnAb) responses can inform countermeasures that avoid enhancement of infection associated with non-neutralizing antibodies. Here, we used single cell transcriptomics to mine the bnAb repertoire following repeated DENV infections. We identified several new bnAbs with comparable or superior breadth and potency to known bnAbs, and with distinct recognition determinants. Unlike all known flavivirus bnAbs, which are IgG1, one newly identified cross-flavivirus bnAb (F25.S02) was derived from IgA1. Both IgG1 and IgA1 versions of F25.S02 and known bnAbs displayed neutralizing activity, but only IgG1 enhanced infection in monocytes expressing IgG and IgA Fc receptors. Moreover, IgG-mediated enhancement of infection was inhibited by IgA1 versions of bnAbs. We demonstrate a role for IgA in flavivirus infection and immunity with implications for vaccine and therapeutic strategies.

Published

2023

2. A genetic screen in C. elegans reveals roles for KIN17 and PRCC in maintaining 5' splice site identity.

Author

Jessie M N G L Suzuki, Kenneth Osterhoudt, Catiana H Cartwright-Acar, Destiny R Gomez, Sol Katzman, and Alan M Zahler

Subjects

Genetics, QH426-470

Abstract

Pre-mRNA splicing is an essential step of eukaryotic gene expression carried out by a series of dynamic macromolecular protein/RNA complexes, known collectively and individually as the spliceosome. This series of spliceosomal complexes define, assemble on, and catalyze the removal of introns. Molecular model snapshots of intermediates in the process have been created from cryo-EM data, however, many aspects of the dynamic changes that occur in the spliceosome are not fully understood. Caenorhabditis elegans follow the GU-AG rule of splicing, with almost all introns beginning with 5' GU and ending with 3' AG. These splice sites are identified early in the splicing cycle, but as the cycle progresses and "custody" of the pre-mRNA splice sites is passed from factor to factor as the catalytic site is built, the mechanism by which splice site identity is maintained or re-established through these dynamic changes is unclear. We performed a genetic screen in C. elegans for factors that are capable of changing 5' splice site choice. We report that KIN17 and PRCC are involved in splice site choice, the first functional splicing role proposed for either of these proteins. Previously identified suppressors of cryptic 5' splicing promote distal cryptic GU splice sites, however, mutations in KIN17 and PRCC instead promote usage of an unusual proximal 5' splice site which defines an intron beginning with UU, separated by 1nt from a GU donor. We performed high-throughput mRNA sequencing analysis and found that mutations in PRCC, and to a lesser extent KIN17, changed alternative 5' splice site usage at native sites genome-wide, often promoting usage of nearby non-consensus sites. Our work has uncovered both fine and coarse mechanisms by which the spliceosome maintains splice site identity during the complex assembly process.

Published

2022

3. A forward genetic screen in C. elegans identifies conserved residues of spliceosomal proteins PRP8 and SNRNP200/BRR2 with a role in maintaining 5' splice site identity

Author

Catiana H Cartwright-Acar, Kenneth Osterhoudt, Jessie M N G L Suzuki, Destiny R Gomez, Sol Katzman, and Alan M Zahler

Subjects

Saccharomyces cerevisiae Proteins, RNA Splicing, Saccharomyces cerevisiae, Ribonucleoproteins, Small Nuclear, Mutation, Genetics, Spliceosomes, RNA Precursors, Animals, Humans, RNA Splice Sites, Caenorhabditis elegans, Ribonucleoprotein, U5 Small Nuclear, RNA Helicases

Abstract

The spliceosome undergoes extensive rearrangements as it assembles onto precursor messenger RNAs. In the earliest assembly step, U1snRNA identifies the 5′ splice site. However, U1snRNA leaves the spliceosome relatively early in assembly, and 5′ splice site identity is subsequently maintained through interactions with U6snRNA, protein factor PRP8, and other components during the rearrangements that build the catalytic site. Using a forward genetic screen in Caenorhabditis elegans, we have identified suppressors of a locomotion defect caused by a 5′ss mutation. Here we report three new suppressor alleles from this screen, two in PRP8 and one in SNRNP200/BRR2. mRNASeq studies of these suppressor strains indicate that they also affect specific native alternative 5′ss, especially for suppressor PRP8 D1549N. A strong suppressor at the unstructured N-terminus of SNRNP200, N18K, indicates a novel role for this region. By examining distinct changes in the splicing of native genes, examining double mutants between suppressors, comparing these new suppressors to previously identified splicing suppressors from yeast, and mapping conserved suppressor residues onto cryoEM structural models of assembling human spliceosomes, we conclude that there are multiple interactions at multiple stages in spliceosome assembly responsible for maintaining the initial 5′ss identified by U1snRNA for entry into the catalytic core.

Published

2022