Your search keyword '"White, IJ"' showing total 2 results

1. A human urothelial microtissue model reveals shared colonization and survival strategies between uropathogens and commensals.

Author

Flores C, Ling J, Loh A, Maset RG, Aw A, White IJ, Fernando R, and Rohn JL

Subjects

Animals, Humans, Escherichia coli metabolism, Fimbriae Proteins metabolism, Adhesins, Escherichia coli metabolism, Urinary Tract Infections metabolism, Escherichia coli Infections

Abstract

Urinary tract infection is among the most common infections worldwide, typically studied in animals and cell lines with limited uropathogenic strains. Here, we assessed diverse bacterial species in a human urothelial microtissue model exhibiting full stratification, differentiation, innate epithelial responses, and urine tolerance. Several uropathogens invaded intracellularly, but also commensal Escherichia coli , suggesting that invasion is a shared survival strategy, not solely a virulence hallmark. The E. coli adhesin FimH was required for intracellular bacterial community formation, but not for invasion. Other shared lifestyles included filamentation (Gram-negatives), chaining (Gram-positives), and hijacking of exfoliating cells, while biofilm-like aggregates were formed mainly with Pseudomonas and Proteus . Urothelial cells expelled invasive bacteria in Rab-/LC3-decorated structures, while highly cytotoxic/invasive uropathogens, but not commensals, disrupted host barrier function and strongly induced exfoliation and cytokine production. Overall, this work highlights diverse species-/strain-specific infection strategies and corresponding host responses in a human urothelial microenvironment, providing insights at the microtissue, cell, and molecular level.

Published

2023

2. Pathophysiology of Dyt1- Tor1a dystonia in mice is mediated by spinal neural circuit dysfunction.

Author

Pocratsky AM, Nascimento F, Özyurt MG, White IJ, Sullivan R, O'Callaghan BJ, Smith CC, Surana S, Beato M, and Brownstone RM

Subjects

Humans, Mice, Animals, Mice, Knockout, Brain metabolism, Molecular Chaperones metabolism, Dystonia genetics, Dystonia metabolism, Dystonia Musculorum Deformans genetics, Dystonia Musculorum Deformans metabolism

Abstract

Dystonia, a neurological disorder defined by abnormal postures and disorganized movements, is considered to be a neural circuit disorder with dysfunction arising within and between multiple brain regions. Given that spinal neural circuits constitute the final pathway for motor control, we sought to determine their contribution to this movement disorder. Focusing on the most common inherited form of dystonia in humans, DYT1- TOR1A , we generated a conditional knockout of the torsin family 1 member A ( Tor1a ) gene in the mouse spinal cord and dorsal root ganglia (DRG). We found that these mice recapitulated the phenotype of the human condition, developing early-onset generalized torsional dystonia. Motor signs emerged early in the mouse hindlimbs before spreading caudo-rostrally to affect the pelvis, trunk, and forelimbs throughout postnatal maturation. Physiologically, these mice bore the hallmark features of dystonia, including spontaneous contractions at rest and excessive and disorganized contractions, including cocontractions of antagonist muscle groups, during voluntary movements. Spontaneous activity, disorganized motor output, and impaired monosynaptic reflexes, all signs of human dystonia, were recorded from isolated mouse spinal cords from these conditional knockout mice. All components of the monosynaptic reflex arc were affected, including motor neurons. Given that confining the Tor1a conditional knockout to DRG did not lead to early-onset dystonia, we conclude that the pathophysiological substrate of this mouse model of dystonia lies in spinal neural circuits. Together, these data provide new insights into our current understanding of dystonia pathophysiology.

Published

2023