Your search keyword '"Raymond T. O’Keefe"' showing total 8 results

1. Structural determination of oleanane-28,13β-olide and taraxerane-28,14β-olide fluorolactonization products from the reaction of oleanolic acid with SelectfluorTM

Author

Megan A. Eadsforth, Linghan Kong, George Whitehead, Iñigo J. Vitórica-Yrezábal, Raymond T. O'Keefe, Richard A. Bryce, and Roger C. Whitehead

Subjects

crystal structure, oleanolic acid, fluorolactone, selectfluor, taraxerane, oleanane, triterpenoids, lactone, Crystallography, QD901-999

Abstract

The X-ray crystal structure data of 12-α-fluoro-3β-hydroxyolean-28,13β-olide methanol hemisolvate, 2C30H47FO3·CH3OH, (1), and 12-α-fluoro-3β-hydroxytaraxer-28,14β-olide methanol hemisolvate, 2C30H47FO3·CH3OH, (2), are described. The fluorolactonization of oleanolic acid using SelectfluorTM yielded a mixture of the six-membered δ-lactone (1) and the unusual seven-membered γ-lactone (2) following a 1,2-shift of methyl C-27 from C-14 to C-13.

Published

2024

2. Bi-allelic FRA10AC1 variants in a multisystem human syndrome

Author

Siddharth Banka, Stavit Shalev, Soo-Mi Park, Katherine A Wood, Huw B Thomas, Helen L Wright, Mohammed Alyahya, Sean Bankier, Ola Alimi, Elena Chervinsky, Leo A H Zeef, and Raymond T O’Keefe

Subjects

Neurology (clinical)

Published

2022

3. Eisosome disruption by noncoding RNA deletion increases protein secretion in yeast

Author

Matthew Wenjie Feng, Daniela Delneri, Catherine B Millar, and Raymond T O'Keefe

Abstract

Noncoding RNAs (ncRNAs) regulate many aspects of gene expression. We investigated how ncRNAs affected protein secretion in yeast by large-scale screening for improved endogenous invertase secretion in ncRNA deletion strains with deletion of stable unannotated transcripts (SUTs), cryptic unstable transcripts (CUTs), tRNAs, or snRNAs. We identified three candidate ncRNAs, SUT418, SUT390, and SUT125, that improved endogenous invertase secretion when deleted. As SUTs can affect expression of nearby genes, we quantified adjacent gene transcription and found that the PIL1 gene was down-regulated in the SUT125 deletion strain. Pil1 is a core component of eisosomes, nonmobile invaginations found throughout the plasma membrane. PIL1 knockout alone, or in combination with eisosome components LSP1 or SUR7, resulted in further increased secretion of invertase. Secretion of heterologous GFP was also increased upon PIL1 deletion, but this increase was signal sequence dependent. To reveal the potential for increased biopharmaceutical production, secretion of monoclonal antibody Pexelizumab scFv peptide was increased by PIL1 deletion. Global analysis of secreted proteins revealed that approximately 20% of secreted proteins, especially serine-enriched secreted proteins, including invertase, were increased upon eisosome disruption. Eisosomes are enriched with APC transporters and sphingolipids, which are essential components for secretory vesicle formation and protein sorting. Sphingolipid and serine biosynthesis pathways were up-regulated upon PIL1 deletion. We propose that increased secretion of endogenous and heterologous proteins upon PIL1 deletion resulted from sphingolipid redistribution in the plasma membrane and up-regulated sphingolipid biosynthesis. Overall, a new pathway to improve protein secretion in yeast via eisosome disruption has been identified.

Published

2022

4. A basement membrane discovery pipeline uncovers network complexity, regulators, and human disease associations

Author

Ranjay, Jayadev, Mychel R P T, Morais, Jamie M, Ellingford, Sandhya, Srinivasan, Richard W, Naylor, Craig, Lawless, Anna S, Li, Jack F, Ingham, Eric, Hastie, Qiuyi, Chi, Maryline, Fresquet, Nikki-Maria, Koudis, Huw B, Thomas, Raymond T, O'Keefe, Emily, Williams, Antony, Adamson, Helen M, Stuart, Siddharth, Banka, Damian, Smedley, David R, Sherwood, and Rachel, Lennon

Subjects

Extracellular Matrix Proteins, Multidisciplinary, Basement Membrane/metabolism, Extracellular Matrix/genetics, Animals, Humans, Caenorhabditis elegans, Caenorhabditis elegans/genetics, Basement Membrane, Zebrafish, Extracellular Matrix Proteins/metabolism, Zebrafish/genetics, Extracellular Matrix

Abstract

Basement membranes (BMs) are ubiquitous extracellular matrices whose composition remains elusive, limiting our understanding of BM regulation and function. By developing a bioinformatic and in vivo discovery pipeline, we define a network of 222 human proteins and their animal orthologs localized to BMs. Network analysis and screening in C. elegans and zebrafish uncovered BM regulators, including ADAMTS, ROBO, and TGFβ. More than 100 BM network genes associate with human phenotypes, and by screening 63,039 genomes from families with rare disorders, we found loss-of-function variants in LAMA5 , MPZL2 , and MATN2 and show that they regulate BM composition and function. This cross-disciplinary study establishes the immense complexity of BMs and their impact on in human health.

Published

2022

5. Global mapping of RNA homodimers in living cells

Author

Marta M. Gabryelska, Andrew P. Badrock, Jian You Lau, Raymond T. O'Keefe, Yanick J. Crow, and Grzegorz Kudla

Subjects

Base Sequence, SARS-CoV-2, Zika Virus Infection, Genetics, Animals, COVID-19, RNA, Small Nucleolar, RNA, Viral, Zika Virus, Zebrafish, Genetics (clinical)

Abstract

RNA homodimerization is important for various physiological processes, including the assembly of membraneless organelles, RNA subcellular localization, and packaging of viral genomes. However, understanding RNA dimerization has been hampered by the lack of systematic in vivo detection methods. Here, we show that CLASH, PARIS, and other RNA proximity ligation methods detect RNA homodimers transcriptome-wide as “overlapping” chimeric reads that contain more than one copy of the same sequence. Analyzing published proximity ligation data sets, we show that RNA:RNA homodimers mediated by direct base-pairing are rare across the human transcriptome, but highly enriched in specific transcripts, including U8 snoRNA, U2 snRNA, and a subset of tRNAs. Mutations in the homodimerization domain of U8 snoRNA impede dimerization in vitro and disrupt zebrafish development in vivo, suggesting an evolutionarily conserved role of this domain. Analysis of virus-infected cells reveals homodimerization of SARS-CoV-2 and Zika genomes, mediated by specific palindromic sequences located within protein-coding regions of N gene in SARS-CoV-2 and NS2A gene in Zika. We speculate that regions of viral genomes involved in homodimerization may constitute effective targets for antiviral therapies.

Published

2022

6. Homozygous missense variants in BMPR15 can result in primary ovarian insufficiency

Author

Leigh A.M. Demain, Kay Metcalfe, Eline Boetje, Peter Clayton, Elizabeth A. Martindale, Gail Busby, Raymond T. O'Keefe, and William G. Newman

Subjects

Reproductive Medicine, Adolescent, Homozygote, Mutation, Missense, Obstetrics and Gynecology, Humans, Female, Primary Ovarian Insufficiency, Bone Morphogenetic Protein 15, Developmental Biology

Abstract

Does a genetic condition underlie the diagnosis of primary ovarian insufficiency (POI) in a 13-year-old girl with primary amenorrhoea?A case report of a next-generation sequencing panel of 24 genes associated with syndromal and non-syndromal POI was conducted.A homozygous missense variant c.1076CT, p.(Pro359Leu) in BMP15 was identified.The biallelic variant c.1076CT, p.(Pro359Leu) in BMP15 is associated with primary ovarian failure.

Published

2022

7. Genome-wide analysis of the non-coding RNA synthetic genetic network reveals extensive plasticity and unique phenotypes in yeast

Author

Marcin G Fraczek, Soukaina Timouma, Laura Natalia Balarezo-Cisneros, Steven Parker, Kobchai Duangrattanalert, Matthew Wenjie Feng, Sam Griffiths-Jones, Raymond T O’Keefe, and Daniela Delneri

Abstract

Recent studies identified non-coding RNAs (ncRNAs) with unknown function that are responsible for major fitness changes in yeast. To understand ncRNA interplay and aid their functional assignment, the synthetic genetic array (SGA) methodology was employed to create >15,000 double mutants and to score their epistasis in different environments. Unlike the protein network, ncRNAs mostly displayed positive epistasis in rich medium. Interestingly, the negative interactions significantly increased under stressors, showing environmental-dependent functions for ncRNAs. No correlation was found between the network of ncRNAs and that of their neighbouring genes, suggesting functional independence. The U3 paralogs, SNR17A and SNR17B, share the majority of genetic interactions in rich medium as expected. For example, SUT480 interacted with both paralogs and its function was linked to 18S rRNA processing. However, under stressors, a large number of unique epistatic interactions were observed, supporting the notion that SNR17A and SNR17B have diverged and sub-functionalised after genome duplication.

Published

2022

8. Combining a prioritization strategy and functional studies nominates 5’UTR variants underlying inherited retinal disease

Author

Alfredo Dueñas Rey, Marta del Pozo Valero, Manon Bouckaert, Katherine A Wood, Filip Van den Broeck, Malena Daich Varela, Huw B Thomas, Mattias Van Heetvelde, Marieke De Bruyne, Stijn Van de Sompele, Miriam Bauwens, Hanne Lenaerts, Quinten Mahieu, Dragana Josifova, Genomics England Research Consortium, Carlo Rivolta, Raymond T O’Keefe, Jamie Ellingford, Andrew R Webster, Gavin Arno, Carmen Ayuso, Julie De Zaeytijd, Bart P Leroy, Elfride De Baere, and Frauke Coppieters

Subjects

5’untranslated region (5’UTR), Upstream open reading frame (uORF), Non-coding variation, Whole genome sequencing (WGS), Whole exome sequencing (WES), In silico prioritization, Medicine, Genetics, QH426-470

Abstract

Abstract Background 5’ untranslated regions (5’UTRs) are essential modulators of protein translation. Predicting the impact of 5’UTR variants is challenging and rarely performed in routine diagnostics. Here, we present a combined approach of a comprehensive prioritization strategy and functional assays to evaluate 5’UTR variation in two large cohorts of patients with inherited retinal diseases (IRDs). Methods We performed an isoform-level re-analysis of retinal RNA-seq data to identify the protein-coding transcripts of 378 IRD genes with highest expression in retina. We evaluated the coverage of their 5’UTRs by different whole exome sequencing (WES) kits. The selected 5’UTRs were analyzed in whole genome sequencing (WGS) and WES data from IRD sub-cohorts from the 100,000 Genomes Project (n = 2397 WGS) and an in-house database (n = 1682 WES), respectively. Identified variants were annotated for 5’UTR-relevant features and classified into seven categories based on their predicted functional consequence. We developed a variant prioritization strategy by integrating population frequency, specific criteria for each category, and family and phenotypic data. A selection of candidate variants underwent functional validation using diverse approaches. Results Isoform-level re-quantification of retinal gene expression revealed 76 IRD genes with a non-canonical retina-enriched isoform, of which 20 display a fully distinct 5’UTR compared to that of their canonical isoform. Depending on the probe design, 3–20% of IRD genes have 5’UTRs fully captured by WES. After analyzing these regions in both cohorts, we prioritized 11 (likely) pathogenic variants in 10 genes (ARL3, MERTK, NDP, NMNAT1, NPHP4, PAX6, PRPF31, PRPF4, RDH12, RD3), of which 7 were novel. Functional analyses further supported the pathogenicity of three variants. Mis-splicing was demonstrated for the PRPF31:c.-9+1G>T variant. The MERTK:c.-125G>A variant, overlapping a transcriptional start site, was shown to significantly reduce both luciferase mRNA levels and activity. The RDH12:c.-123C>T variant was found in cis with the hypomorphic RDH12:c.701G>A (p.Arg234His) variant in 11 patients. This 5’UTR variant, predicted to introduce an upstream open reading frame, was shown to result in reduced RDH12 protein but unaltered mRNA levels. Conclusions This study demonstrates the importance of 5’UTR variants implicated in IRDs and provides a systematic approach for 5’UTR annotation and validation that is applicable to other inherited diseases.

Published

2024