Your search keyword '"Caitlin Vestal Tibbetts"' showing total 2 results

1. Discovery of RXFP2 genetic association in resistant hypertensive men and RXFP2 antagonists for the treatment of resistant hypertension

Author

Shan-Shan Zhang, Lance Larrabee, Andrew H. Chang, Sapna Desai, Lisa Sloan, Xin Wang, Yixuan Wu, Nazia Parvez, Karen Amaratunga, Allison C. Hartman, Abby Whitnall, Joseph Mason, Nicholas P. Barton, Audrey Y. Chu, Jonathan M. Davitte, Adam J. Csakai, Caitlin Vestal Tibbetts, Audrey E. Tolbert, Heather O’Keefe, Jessie Polanco, Joseph Foley, Casey Kmett, Jonathan Kehler, Gabriela Kozejova, Feng Wang, Andrew P. Mayer, Patrick Koenig, Davide Foletti, Steven J. Pitts, and Christine G. Schnackenberg

Subjects

Medicine, Science

Abstract

Abstract Hypertension remains a leading cause of cardiovascular and kidney diseases. Failure to control blood pressure with ≥ 3 medications or control requiring ≥ 4 medications is classified as resistant hypertension (rHTN) and new therapies are needed to reduce the resulting increased risk of morbidity and mortality. Here, we report genetic evidence that relaxin family peptide receptor 2 (RXFP2) is associated with rHTN in men, but not in women. This study shows that adrenal gland gene expression of RXFP2 is increased in men with hypertension and the RXFP2 natural ligand, INSL3, increases adrenal steroidogenesis and corticosteroid secretion in human adrenal cells. To address the hypothesis that RXFP2 activation is an important mechanism in rHTN, we discovered and characterized small molecule and monoclonal antibody (mAb) blockers of RXFP2. The novel chemical entities and mAbs show potent, selective inhibition of RXFP2 and reduce aldosterone and cortisol synthesis and release. The RXFP2 mAbs have suitable rat pharmacokinetic profiles to evaluate the role of RXFP2 in the development and maintenance of rHTN. Overall, we identified RXFP2 activity as a potential new mechanism in rHTN and discovered RXFP2 antagonists for the future interrogation of RXFP2 in cardiovascular and renal diseases.

Published

2024

2. RNA Aptamer Delivery through Intact Human Skin

Author

Jessica Neil, Caitlin Vestal Tibbetts, Kellie Marie Demock, Susan H. Smith, Christine Patricia Donahue, Jon D. Lenn, Javier Cote-Sierra, P. Shannon Pendergrast, Jason R. Killough, Adrian C. Williams, Marc B. Brown, Jean-Philippe Therrien, and David Rubenstein

Subjects

0301 basic medicine, Aptamer, Skin Absorption, Endogeny, Human skin, Dermatology, Biology, Administration, Cutaneous, Biochemistry, Interleukin-23, 03 medical and health sciences, Dermis, medicine, Humans, Molecular Biology, Epidermis (botany), Oligonucleotide, Interleukins, Interleukin-17, RNA, Biological activity, Cell Biology, Aptamers, Nucleotide, Molecular biology, Up-Regulation, 030104 developmental biology, medicine.anatomical_structure, Epidermal Cells, Epidermis

Abstract

It is generally recognized that only relatively small molecular weight (typically∼ 500 Da) drugs can effectively permeate through intact stratum corneum. Here, we challenge this orthodoxy using a 62-nucleotide (molecular weight = 20,395 Da) RNA-based aptamer, highly specific to the human IL-23 cytokine, with picomolar activity. Results demonstrate penetration of the aptamer into freshly excised human skin using two different fluorescent labels. A dual hybridization assay quantified aptamer from the epidermis and dermis, giving levels far exceeding the cellular half maximal inhibitory concentration values (100,000-fold), and aptamer integrity was confirmed using an oligonucleotide precipitation assay. A T helper 17 response was stimulated in freshly excised human skin resulting in significantly upregulated IL-17f, and IL-22; topical application of the IL-23 aptamer decreased both IL-17f and IL-22 by approximately 45% but did not result in significant changes to IL-23 mRNA levels, confirming that the aptamer did not globally suppress mRNA levels. This study demonstrates that very-large-molecular-weight RNA aptamers can permeate across the intact human skin barrier to therapeutically relevant levels into both the epidermis and dermis and that the skin-penetrating aptamer retains its biologically active conformational structure capable of binding to endogenous IL-23.

Published

2017