Your search keyword '"Fulton, William B"' showing total 7 results

1. Human milk oligosaccharides reduce necrotizing enterocolitis induced-neuroinflammation and cognitive impairment in mice

Author

Sodhi, Chhinder P., primary, Ahmad, Raheel, additional, Fulton, William B., additional, Lopez, Carla, additional, Eke, Benjamin, additional, Scheese, Daniel, additional, Duess, Johannes, additional, Steinway, Steven, additional, Raouf, Zachariah, additional, Moore, Hannah, additional, Tsuboi, Koichi, additional, Sampah, Maame, additional, Jang, Hee-Seong, additional, Buck, Rachael H., additional, Hill, David R., additional, Niemiro, Grace M., additional, Prindle, Thomas, additional, Wang, Sanxia, additional, Wang, Meghan, additional, Jia, Hongpeng, additional, Catazaro, Jonathan, additional, Lu, Peng, additional, and Hackam, David J., additional

Published

2023

2. The administration of amnion-derived multipotent cell secretome ST266 protects against necrotizing enterocolitis in mice and piglets

Author

Sodhi, Chhinder P., primary, Ahmad, Raheel, additional, Jia, Hongpeng, additional, Fulton, William B., additional, Lopez, Carla, additional, Gonzalez Salazar, Andres J., additional, Ishiyama, Asuka, additional, Sampah, Maame, additional, Steinway, Steve, additional, Wang, Sanxia, additional, Prindle, Thomas, additional, Wang, Menghan, additional, Steed, David L., additional, Wessel, Howard, additional, Kirshner, Ziv, additional, Brown, Larry R., additional, Lu, Peng, additional, and Hackam, David J., additional

Published

2022

3. Attenuation of pulmonary ACE2 activity impairs inactivation of des-Arg9 bradykinin/BKB1R axis and facilitates LPS-induced neutrophil infiltration

Author

Sodhi, Chhinder P., primary, Wohlford-Lenane, Christine, additional, Yamaguchi, Yukihiro, additional, Prindle, Thomas, additional, Fulton, William B., additional, Wang, Sanxia, additional, McCray, Paul B., additional, Chappell, Mark, additional, Hackam, David J., additional, and Jia, Hongpeng, additional

Published

2018

4. Attenuation of pulmonary ACE2 activity impairs inactivation of des-Arg9 bradykinin/BKB1R axis and facilitates LPS-induced neutrophil infiltration.

Author

Sodhi, Chhinder P., Wohlford-Lenane, Christine, Yukihiro Yamaguchi, Prindle, Thomas, Fulton, William B., Sanxia Wang, McCray Jr., Paul B., Chappell, Mark, Hackam, David J., and Hongpeng Jia

Subjects

ANGIOTENSIN converting enzyme, CARBOXYPEPTIDASES, BRADYKININ

Abstract

Angiotensin-converting enzyme 2 (ACE2) is a terminal carboxypeptidase with important functions in the renin-angiotensin system and plays a critical role in inflammatory lung diseases. ACE2 cleaves single-terminal residues from several bioactive peptides such as angiotensin II. However, few of its substrates in the respiratory tract have been identified, and the mechanism underlying the role of ACE2 in inflammatory lung disease has not been fully characterized. In an effort to identify biological targets of ACE2 in the lung, we tested its effects on des-Arg9 bradykinin (DABK) in airway epithelial cells on the basis of the hypothesis that DABK is a biological substrate of ACE2 in the lung and ACE2 plays an important role in the pathogenesis of acute lung inflammation partly through modulating DABK/bradykinin receptor B1 (BKB1R) axis signaling. We found that loss of ACE2 function in mouse lung in the setting of endotoxin inhalation led to activation of the DABK/BKB1R axis, release of proinflammatory chemokines such as C-X-C motif chemokine 5 (CXCL5), macrophage inflammatory protein-2 (MIP2), C-X-C motif chemokine 1 (KC), and TNF-α from airway epithelia, increased neutrophil infiltration, and exaggerated lung inflammation and injury. These results indicate that a reduction in pulmonary ACE2 activity contributes to the pathogenesis of lung inflammation, in part because of an impaired ability to inhibit DABK/BKB1R axis-mediated signaling, resulting in more prompt onset of neutrophil infiltration and more severe inflammation in the lung. Our study identifies a biological substrate of ACE2 within the airways, as well as a potential new therapeutic target for inflammatory diseases. [ABSTRACT FROM AUTHOR]

Published

2018

5. Human milk oligosaccharides reduce necrotizing enterocolitis-induced neuroinflammation and cognitive impairment in mice.

Author

Sodhi CP, Ahmad R, Fulton WB, Lopez CM, Eke BO, Scheese D, Duess JW, Steinway SN, Raouf Z, Moore H, Tsuboi K, Sampah ME, Jang HS, Buck RH, Hill DR, Niemiro GM, Prindle T Jr, Wang S, Wang M, Jia H, Catazaro J, Lu P, and Hackam DJ

Subjects

Humans, Infant, Newborn, Infant, Female, Animals, Mice, Milk, Human metabolism, Brain-Derived Neurotrophic Factor, Neuroinflammatory Diseases, Oligosaccharides pharmacology, Oligosaccharides therapeutic use, Oligosaccharides analysis, Enterocolitis, Necrotizing etiology, Cognitive Dysfunction prevention & control, Cognitive Dysfunction complications, Brain Injuries complications, Brain Injuries metabolism

Abstract

Necrotizing enterocolitis (NEC) is the leading cause of morbidity and mortality in premature infants. One of the most devastating complications of NEC is the development of NEC-induced brain injury, which manifests as impaired cognition that persists beyond infancy and which represents a proinflammatory activation of the gut-brain axis. Given that oral administration of the human milk oligosaccharides (HMOs) 2'-fucosyllactose (2'-FL) and 6'-sialyslactose (6'-SL) significantly reduced intestinal inflammation in mice, we hypothesized that oral administration of these HMOs would reduce NEC-induced brain injury and sought to determine the mechanisms involved. We now show that the administration of either 2'-FL or 6'-SL significantly attenuated NEC-induced brain injury, reversed myelin loss in the corpus callosum and midbrain of newborn mice, and prevented the impaired cognition observed in mice with NEC-induced brain injury. In seeking to define the mechanisms involved, 2'-FL or 6'-SL administration resulted in a restoration of the blood-brain barrier in newborn mice and also had a direct anti-inflammatory effect on the brain as revealed through the study of brain organoids. Metabolites of 2'-FL were detected in the infant mouse brain by nuclear magnetic resonance (NMR), whereas intact 2'-FL was not. Strikingly, the beneficial effects of 2'-FL or 6'-SL against NEC-induced brain injury required the release of the neurotrophic factor brain-derived neurotrophic factor (BDNF), as mice lacking BDNF were not protected by these HMOs from the development of NEC-induced brain injury. Taken in aggregate, these findings reveal that the HMOs 2'-FL and 6'-SL interrupt the gut-brain inflammatory axis and reduce the risk of NEC-induced brain injury. NEW & NOTEWORTHY This study reveals that the administration of human milk oligosaccharides, which are present in human breast milk, can interfere with the proinflammatory gut-brain axis and prevent neuroinflammation in the setting of necrotizing enterocolitis, a major intestinal disorder seen in premature infants.

Published

2023

6. The administration of amnion-derived multipotent cell secretome ST266 protects against necrotizing enterocolitis in mice and piglets.

Author

Sodhi CP, Ahmad R, Jia H, Fulton WB, Lopez C, Gonzalez Salazar AJ, Ishiyama A, Sampah M, Steinway S, Wang S, Prindle T Jr, Wang M, Steed DL, Wessel H, Kirshner Z, Brown LR, Lu P, and Hackam DJ

Subjects

Amnion cytology, Animals, Disease Models, Animal, Intestinal Mucosa metabolism, Mice, Swine, Toll-Like Receptor 4 metabolism, Enterocolitis, Necrotizing prevention & control, Multipotent Stem Cells metabolism, Secretome

Abstract

Necrotizing enterocolitis (NEC) is the leading cause of death from gastrointestinal disease in premature infants and is steadily rising in frequency. Patients who develop NEC have a very high mortality, illustrating the importance of developing novel prevention or treatment approaches. We and others have shown that NEC arises in part from exaggerated signaling via the bacterial receptor, Toll-like receptor 4 (TLR4) on the intestinal epithelium, leading to widespread intestinal inflammation and intestinal ischemia. Strategies that limit the extent of TLR4 signaling, including the administration of amniotic fluid, can reduce NEC development in mouse and piglet models. We now seek to test the hypothesis that a secretome derived from amnion-derived cells can prevent or treat NEC in preclinical models of this disease via a process involving TLR4 inhibition. In support of this hypothesis, we show that the administration of this secretome, named ST266, to mice or piglets can prevent and treat experimental NEC. The protective effects of ST266 occurred in the presence of marked TLR4 inhibition in the intestinal epithelium of cultured epithelial cells, intestinal organoids, and human intestinal samples ex vivo, independent of epidermal growth factor. Strikingly, RNA-seq analysis of the intestinal epithelium in mice reveals that the ST266 upregulates critical genes associated with gut remodeling, intestinal immunity, gut differentiation. and energy metabolism. These findings show that the amnion-derived secretome ST266 can prevent and treat NEC, suggesting the possibility of novel therapeutic approaches for patients with this devastating disease. NEW & NOTEWORTHY This work provides hope for children who develop NEC, a devastating disease of premature infants that is often fatal, by revealing that the secreted product of amniotic progenitor cells (called ST266) can prevent or treat NEC in mice, piglet, and "NEC-in-a-dish" models of this disease. Mechanistically, ST266 prevented bacterial signaling, and a detailed transcriptomic analysis revealed effects on gut differentiation, immunity, and metabolism. Thus, an amniotic secretome may offer novel approaches for NEC.

Published

2022

7. Attenuation of pulmonary ACE2 activity impairs inactivation of des-Arg 9 bradykinin/BKB1R axis and facilitates LPS-induced neutrophil infiltration.

Author

Sodhi CP, Wohlford-Lenane C, Yamaguchi Y, Prindle T, Fulton WB, Wang S, McCray PB Jr, Chappell M, Hackam DJ, and Jia H

Subjects

Angiotensin-Converting Enzyme 2, Animals, Anti-Inflammatory Agents, Bradykinin pharmacology, Cells, Cultured, Chemokine CXCL5 metabolism, Humans, Mice, Mice, Inbred C57BL, Mice, Knockout, Neutrophil Infiltration drug effects, Pneumonia chemically induced, Pneumonia drug therapy, Pneumonia metabolism, Trachea drug effects, Trachea pathology, Bradykinin analogs & derivatives, Lipopolysaccharides toxicity, Neutrophil Infiltration immunology, Peptidyl-Dipeptidase A physiology, Pneumonia immunology, Receptor, Bradykinin B1 metabolism, Trachea immunology

Abstract

Angiotensin-converting enzyme 2 (ACE2) is a terminal carboxypeptidase with important functions in the renin-angiotensin system and plays a critical role in inflammatory lung diseases. ACE2 cleaves single-terminal residues from several bioactive peptides such as angiotensin II. However, few of its substrates in the respiratory tract have been identified, and the mechanism underlying the role of ACE2 in inflammatory lung disease has not been fully characterized. In an effort to identify biological targets of ACE2 in the lung, we tested its effects on des-Arg 9 bradykinin (DABK) in airway epithelial cells on the basis of the hypothesis that DABK is a biological substrate of ACE2 in the lung and ACE2 plays an important role in the pathogenesis of acute lung inflammation partly through modulating DABK/bradykinin receptor B1 (BKB1R) axis signaling. We found that loss of ACE2 function in mouse lung in the setting of endotoxin inhalation led to activation of the DABK/BKB1R axis, release of proinflammatory chemokines such as C-X-C motif chemokine 5 (CXCL5), macrophage inflammatory protein-2 (MIP2), C-X-C motif chemokine 1 (KC), and TNF-α from airway epithelia, increased neutrophil infiltration, and exaggerated lung inflammation and injury. These results indicate that a reduction in pulmonary ACE2 activity contributes to the pathogenesis of lung inflammation, in part because of an impaired ability to inhibit DABK/BKB1R axis-mediated signaling, resulting in more prompt onset of neutrophil infiltration and more severe inflammation in the lung. Our study identifies a biological substrate of ACE2 within the airways, as well as a potential new therapeutic target for inflammatory diseases.

Published

2018