Your search keyword '"Cox-Vazquez SJ"' showing total 2 results

1. Delineating Bovine Milk Derived Microvesicles from Exosomes Using Proteomics.

Author

Couse AD, Cox-Vazquez SJ, Ghatak S, Trinidad JC, and Clemmer DE

Subjects

Animals, Cattle, Extracellular Vesicles chemistry, Extracellular Vesicles metabolism, Milk Proteins analysis, Milk Proteins metabolism, Milk Proteins chemistry, Mass Spectrometry methods, Exosomes chemistry, Exosomes metabolism, Proteomics methods, Milk chemistry, Ultracentrifugation methods

Abstract

In the work presented herein, a simple serial-pelleting purification strategy combined with a mass spectrometry-based proteomics analysis was developed as a means of discerning differences in extracellular vesicle (EV) populations found in bovine milk samples. A sequence of ultracentrifugation speeds was used to generate changes in the abundances of EV populations, allowing for the identification of associated proteins. A metric was developed to determine the relative abundances of proteins in large EVs (>200 nm) and small EVs (<200 nm). Of the 476 proteins consistently found in this study, 340 are associated with vesicular components. Of these, 156 were heavily enriched in large EVs, 155 shared between large and small EVs, and 29 heavily enriched in small EVs. Additionally, out of 68 proteins annotated as exosome proteins, 32 were enriched in large EVs, 27 shared between large and small EVs, 5 enriched in small EVs, and 7 were found to be nonvesicular contaminant proteins. The top correlated proteins in the small EV group were predominantly membrane-bound proteins, whereas the top correlated proteins in the large EV group were mostly cytosolic enzymes for molecular processing. This method provides a means of assessing the origins of vesicle components and provides new potential marker proteins within discrete vesicle populations.

Published

2024

2. Predicting Antimicrobial Activity of Conjugated Oligoelectrolyte Molecules via Machine Learning.

Author

Tiihonen A, Cox-Vazquez SJ, Liang Q, Ragab M, Ren Z, Hartono NTP, Liu Z, Sun S, Zhou C, Incandela NC, Limwongyut J, Moreland AS, Jayavelu S, Bazan GC, and Buonassisi T

Abstract

New antibiotics are needed to battle growing antibiotic resistance, but the development process from hit, to lead, and ultimately to a useful drug takes decades. Although progress in molecular property prediction using machine-learning methods has opened up new pathways for aiding the antibiotics development process, many existing solutions rely on large data sets and finding structural similarities to existing antibiotics. Challenges remain in modeling unconventional antibiotic classes that are drawing increasing research attention. In response, we developed an antimicrobial activity prediction model for conjugated oligoelectrolyte molecules, a new class of antibiotics that lacks extensive prior structure-activity relationship studies. Our approach enables us to predict the minimum inhibitory concentration for E. coli K12, with 21 molecular descriptors selected by recursive elimination from a set of 5305 descriptors. This predictive model achieves an R 2 of 0.65 with no prior knowledge of the underlying mechanism. We find the molecular representation optimum for the domain is the key to good predictions of antimicrobial activity. In the case of conjugated oligoelectrolytes, a representation reflecting the three-dimensional shape of the molecules is most critical. Although it is demonstrated with a specific example of conjugated oligoelectrolytes, our proposed approach for creating the predictive model can be readily adapted to other novel antibiotic candidate domains.

Published

2021