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27 results on '"Matthis, Andrea L."'

1. Deficient Active Transport Activity in Healing Mucosa After Mild Gastric Epithelial Damage

Author

Matthis, Andrea L, Kaji, Izumi, Engevik, Kristen A, Akiba, Yasutada, Kaunitz, Jonathan D, Montrose, Marshall H, and Aihara, Eitaro

Subjects
Medical Physiology, Biomedical and Clinical Sciences, Digestive Diseases, Acetic Acid, Animals, Disease Models, Animal, Electric Impedance, Epithelial Cells, Female, Gastric Mucosa, Hydrogen-Ion Concentration, Hypertonic Solutions, Male, Mice, Inbred C57BL, Mice, Knockout, Re-Epithelialization, Sodium Chloride, Sodium-Hydrogen Exchangers, Stomach Ulcer, Time Factors, Trefoil Factor-2, Wound Healing, Ulcer, Gastric, Epithelial cell, Repair, TFF2, NHE2, Ussing chamber, Confocal microscopy, Photodamage, Actin, Clinical Sciences, Gastroenterology & Hepatology, Clinical sciences
Abstract

BackgroundPeptic ulcers recur, suggesting that ulcer healing may leave tissue predisposed to subsequent damage. In mice, we have identified that the regenerated epithelium found after ulcer healing will remain abnormal for months after healing.AimTo determine whether healed gastric mucosa has altered epithelial function, as measured by electrophysiologic parameters.MethodUlcers were induced in mouse gastric corpus by serosal local application of acetic acid. Thirty days or 8 months after ulcer induction, tissue was mounted in an Ussing chamber. Transepithelial electrophysiologic parameters (short-circuit current, Isc. resistance, R) were compared between the regenerated healed ulcer region and the non-ulcerated contralateral region, in response to luminal hyperosmolar NaCl challenge (0.5 M).ResultsIn unperturbed stomach, luminal application of hyperosmolar NaCl transiently dropped Isc followed by gradual recovery over 2 h. Compared to the starting baseline Isc, percent Isc recovery was reduced in 30-day healing mucosa, but not at 8 months. Prior to NaCl challenge, a lower baseline Isc was observed in trefoil factor 2 (TFF2) knockout (KO) versus wild type (WT), with no Isc recovery in either non-ulcerated or healing mucosa of KO. Inhibiting Na/H exchanger (NHE) transport in WT mucosa inhibited Isc recovery in response to luminal challenge. NHE2-KO baseline Isc was reduced versus NHE2-WT. In murine gastric organoids, NHE inhibition slowed recovery of intracellular pH and delayed the repair of photic induced damage.ConclusionHealing gastric mucosa has deficient electrophysiological recovery in response to hypertonic NaCl. TFF2 and NHE2 contribute to Isc regulation, and the recovery and healing of transepithelial function.

Published
2020

2. Helicobacter pylori Uses the TlpB Receptor To Sense Sites of Gastric Injury.

Author

Hanyu, Hikaru, Engevik, Kristen A, Matthis, Andrea L, Ottemann, Karen M, Montrose, Marshall H, and Aihara, Eitaro

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Infectious Diseases, Emerging Infectious Diseases, Digestive Diseases, Digestive Diseases - (Peptic Ulcer), Underpinning research, 1.1 Normal biological development and functioning, Animals, Bacterial Proteins, Chemotactic Factors, Chemotaxis, Disease Models, Animal, Gastric Mucosa, Helicobacter Infections, Helicobacter pylori, Mice, Stomach Diseases, TlpB, chemotaxis, gastric organoids, injury, intravital microscopy, pathogenesis, photodamage, repair, stomach, Biological Sciences, Agricultural and Veterinary Sciences, Medical and Health Sciences, Microbiology, Immunology, Medical microbiology
Abstract

Helicobacter pylori is a pathogen that chronically colonizes the stomachs of approximately half of the world's population and contributes to the development of gastric inflammation. We demonstrated previously in vivo that H. pylori uses motility to preferentially colonize injury sites in the mouse stomach. However, the chemoreceptor responsible for sensing gastric injury has not yet been identified. In this study, we utilized murine gastric organoids (gastroids) and mutant H. pylori strains to investigate the components necessary for H. pylori chemotaxis. High-intensity 730-nm light (two-photon photodamage) was used to cause single-cell damage in gastroids, and repair of the damage was monitored over time; complete repair occurred within ∼10 min in uninfected gastroids. Wild-type H. pylori accumulated at the damage site after gastric damage induction. In contrast, mutants lacking motility (ΔmotB) or chemotaxis (ΔcheY) did not accumulate at the injury site. Using mutants lacking individual chemoreceptors, we found that only TlpB was required for H. pylori accumulation, while TlpA, TlpC, and TlpD were dispensable. All strains that were able to accumulate at the damage site limited repair. When urea (an identified chemoattractant sensed by TlpB) was microinjected into the gastroid lumen, it prevented the accumulation of H. pylori at damage sites. Overall, our findings demonstrate that H. pylori colonizes and limits repair at damage sites via chemotactic motility that requires the TlpB chemoreceptor to sense signals generated by gastric epithelial cells.

Published
2019

3. Motility and chemotaxis mediate the preferential colonization of gastric injury sites by Helicobacter pylori.

Author

Aihara, Eitaro, Closson, Chet, Matthis, Andrea L, Schumacher, Michael A, Engevik, Amy C, Zavros, Yana, Ottemann, Karen M, and Montrose, Marshall H

Subjects
Gastric Mucosa, Animals, Mice, Helicobacter pylori, Helicobacter Infections, Stomach Ulcer, Acetic Acid, Indicators and Reagents, Virology, Microbiology, Immunology, Medical Microbiology
Abstract

Helicobacter pylori (H. pylori) is a pathogen contributing to peptic inflammation, ulceration, and cancer. A crucial step in the pathogenic sequence is when the bacterium first interacts with gastric tissue, an event that is poorly understood in vivo. We have shown that the luminal space adjacent to gastric epithelial damage is a microenvironment, and we hypothesized that this microenvironment might enhance H. pylori colonization. Inoculation with 106 H. pylori (wild-type Sydney Strain 1, SS1) significantly delayed healing of acetic-acid induced ulcers at Day 1, 7 and 30 post-inoculation, and wild-type SS1 preferentially colonized the ulcerated area compared to uninjured gastric tissue in the same animal at all time points. Gastric resident Lactobacillus spp. did not preferentially colonize ulcerated tissue. To determine whether bacterial motility and chemotaxis are important to ulcer healing and colonization, we analyzed isogenic H. pylori mutants defective in motility (ΔmotB) or chemotaxis (ΔcheY). ΔmotB (10(6)) failed to colonize ulcerated or healthy stomach tissue. ΔcheY (10(6)) colonized both tissues, but without preferential colonization of ulcerated tissue. However, ΔcheY did modestly delay ulcer healing, suggesting that chemotaxis is not required for this process. We used two-photon microscopy to induce microscopic epithelial lesions in vivo, and evaluated accumulation of fluorescently labeled H. pylori at gastric damage sites in the time frame of minutes instead of days. By 5 min after inducing damage, H. pylori SS1 preferentially accumulated at the site of damage and inhibited gastric epithelial restitution. H. pylori ΔcheY modestly accumulated at the gastric surface and inhibited restitution, but did not preferentially accumulate at the injury site. H. pylori ΔmotB neither accumulated at the surface nor inhibited restitution. We conclude that bacterial chemosensing and motility rapidly promote H. pylori colonization of injury sites, and thereby biases the injured tissue towards sustained gastric damage.

Published
2014

7. Enteroendocrine cells couple nutrient sensing to nutrient absorption by regulating ion transport

Author

McCauley, Heather A., primary, Matthis, Andrea L., additional, Enriquez, Jacob R., additional, Nichol, Jonah, additional, Sanchez, J. Guillermo, additional, Stone, William J., additional, Sundaram, Nambirajan, additional, Helmrath, Michael A., additional, Montrose, Marshall H., additional, Aihara, Eitaro, additional, and Wells, James M., additional

Published
2020
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8. Oxidation of yeast iso-1 ferrocytochrome c by yeast cytochrome c peroxidase compounds I and II. Dependence upon ionic strength

Author

Matthis, Andrea L., Vitello, Lidia B., and Erman, James E.

Subjects
Cytochrome c -- Research, Oxidation-reduction reaction -- Analysis, Biological sciences, Chemistry
Abstract

The steady-state kinetic studies of cytochrome c peroxidase (CcP) show that the cytochrome c peroxidase compound I (CcP-I) does not participate in Trp-191 radical formed during the reaction between the CcP and hydrogen peroxide. This CcP-I(sub A) form is directly reduced to cytochrome c peroxidase compound II CcP-II(sub F) by ferrocytochrome c. The steady-state velocity is seen when the rate of reduction of CcP-I(sub A) and CcP-II(sub F) is same as the rate of reduction of CcP-I.

Published
1995

9. Cytochrome c peroxidase-catalyzed oxidation of yeast iso-1 ferrocytochrome c by hydrogen peroxide. Ionic strength dependence of the steady-state parameters

Author

Matthis, Andrea L. and Erman, James E.

Subjects
Cytochrome c -- Analysis, Hydrogen peroxide -- Usage, Binding sites (Biochemistry) -- Observations, Yeast -- Research, Biological sciences, Chemistry
Abstract

The oxidation of yeast takes place at the high-affinity binding sites on cytochrome c peroxidase (CcP). The high-affinity binding sites increase their ionic strength from 0.010 to 0.20 M. The cytochrome c peroxidase catalyzes the oxidation of yeast iso-1 ferrocytochrome c by utilizing hydrogen peroxide. The two oxidized intermediates of CcP compound I and II to couple the reduction of two radicals of hydrogen peroxidase are in the ratio 2:1.

Published
1995

19. Cell injury triggers actin polymerization to initiate epithelial restitution.

Author

Eitaro Aihara, Medina-Candelaria, Neisha M., Hikaru Hanyu, Matthis, Andrea L., Engevik, Kristen A., Gurniak, Christine B., Witke, Walter, Turner, Jerrold R., Tongli Zhang, and Montrose, Marshall H.

Subjects
ACTIN, EPITHELIAL cells, CELL migration
Abstract

The role of the actin cytoskeleton in the sequence of physiological epithelial repair in the intact epithelium has yet to be elucidated. Here, we explore the role of actin in gastric repair in vivo and in vitro gastric organoids (gastroids). In response to two-photon-induced cellular damage of either an in vivo gastric or in vitro gastroid epithelium, actin redistribution specifically occurred in the lateral membranes of cells neighboring the damaged cell. This was followed by their migration inward to close the gap at the basal pole of the dead cell, in parallel with exfoliation of the dead cell into the lumen. The repair and focal increase of actin was significantly blocked by treatment with EDTA or the inhibition of actin polymerization. Treatment with inhibitors of myosin light chain kinase, myosin II, trefoil factor 2 signaling or phospholipase C slowed both the initial actin redistribution and the repair. While Rac1 inhibition facilitated repair, inhibition of RhoA/Rho-associated protein kinase inhibited it. Inhibitors of focal adhesion kinase and Cdc42 had negligible effects. Hence, initial actin polymerization occurs in the lateral membrane, and is primarily important to initiate dead cell exfoliation and cell migration to close the gap. [ABSTRACT FROM AUTHOR]

Published
2018
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20. Characterization of stem/progenitor cell cycle using murine circumvallate papilla taste bud organoid

Author

Aihara, Eitaro, primary, Mahe, Maxime M., additional, Schumacher, Michael A., additional, Matthis, Andrea L., additional, Feng, Rui, additional, Ren, Wenwen, additional, Noah, Taeko K., additional, Matsu-ura, Toru, additional, Moore, Sean R., additional, Hong, Christian I., additional, Zavros, Yana, additional, Herness, Scott, additional, Shroyer, Noah F., additional, Iwatsuki, Ken, additional, Jiang, Peihua, additional, Helmrath, Michael A., additional, and Montrose, Marshall H., additional

Published
2015
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21. Motility and Chemotaxis Mediate the Preferential Colonization of Gastric Injury Sites by Helicobacter pylori.

Author

Aihara, Eitaro, Closson, Chet, Matthis, Andrea L., Schumacher, Michael A., Engevik, Amy C., Zavros, Yana, Ottemann, Karen M., and Montrose, Marshall H.

Subjects
HELICOBACTER pylori, HELICOBACTER pylori infections, PATHOGENIC microorganisms, PEPTIC ulcer, STOMACH cancer, BACTERIAL colonies, CHEMOTAXIS, BACTERIA
Abstract

Helicobacter pylori (H. pylori) is a pathogen contributing to peptic inflammation, ulceration, and cancer. A crucial step in the pathogenic sequence is when the bacterium first interacts with gastric tissue, an event that is poorly understood in vivo. We have shown that the luminal space adjacent to gastric epithelial damage is a microenvironment, and we hypothesized that this microenvironment might enhance H. pylori colonization. Inoculation with 106H. pylori (wild-type Sydney Strain 1, SS1) significantly delayed healing of acetic-acid induced ulcers at Day 1, 7 and 30 post-inoculation, and wild-type SS1 preferentially colonized the ulcerated area compared to uninjured gastric tissue in the same animal at all time points. Gastric resident Lactobacillus spp. did not preferentially colonize ulcerated tissue. To determine whether bacterial motility and chemotaxis are important to ulcer healing and colonization, we analyzed isogenic H. pylori mutants defective in motility (ΔmotB) or chemotaxis (ΔcheY). ΔmotB (106) failed to colonize ulcerated or healthy stomach tissue. ΔcheY (106) colonized both tissues, but without preferential colonization of ulcerated tissue. However, ΔcheY did modestly delay ulcer healing, suggesting that chemotaxis is not required for this process. We used two-photon microscopy to induce microscopic epithelial lesions in vivo, and evaluated accumulation of fluorescently labeled H. pylori at gastric damage sites in the time frame of minutes instead of days. By 5 min after inducing damage, H. pylori SS1 preferentially accumulated at the site of damage and inhibited gastric epithelial restitution. H. pylori ΔcheY modestly accumulated at the gastric surface and inhibited restitution, but did not preferentially accumulate at the injury site. H. pylori ΔmotB neither accumulated at the surface nor inhibited restitution. We conclude that bacterial chemosensing and motility rapidly promote H. pylori colonization of injury sites, and thereby biases the injured tissue towards sustained gastric damage. [ABSTRACT FROM AUTHOR]

Published
2014
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22. Electron Transfer within the Cytochromec-CytochromecPeroxidase Complex: Dependence of the Transient-State and Steady-State Kinetics on Ionic Strength

Author

Erman, James E., primary, Kang, Doe Sun, additional, Kim, Kil Lyong, additional, Summers, Farrel E., additional, Matthis, Andrea L., additional, Vitello, Lidia B., additional, Peroxidase, Cytochrome C, additional, Transfer, Electron, additional, Dependence, Ionic Strength, additional, and Cytochrome, C, additional

Published
1991
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24. Helicobacter pyloriUses the TlpB Receptor To Sense Sites of Gastric Injury

Author

Hanyu, Hikaru, Engevik, Kristen A., Matthis, Andrea L., Ottemann, Karen M., Montrose, Marshall H., and Aihara, Eitaro

Abstract

Helicobacter pyloriis a pathogen that chronically colonizes the stomachs of approximately half of the world’s population and contributes to the development of gastric inflammation. We demonstrated previously in vivothat H. pyloriuses motility to preferentially colonize injury sites in the mouse stomach. However, the chemoreceptor responsible for sensing gastric injury has not yet been identified.

Published
2019
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25. Motility and Chemotaxis Mediate the Preferential Colonization of Gastric Injury Sites by Helicobacter pylori.

Author

Aihara, Eitaro, Closson, Chet, Matthis, Andrea L., Schumacher, Michael A., Engevik, Amy C., Zavros, Yana, Ottemann, Karen M., and Montrose, Marshall H.

Subjects
*HELICOBACTER pylori, *HELICOBACTER pylori infections, *PATHOGENIC microorganisms, *PEPTIC ulcer, *STOMACH cancer, *BACTERIAL colonies, *CHEMOTAXIS, *BACTERIA
Abstract

Helicobacter pylori (H. pylori) is a pathogen contributing to peptic inflammation, ulceration, and cancer. A crucial step in the pathogenic sequence is when the bacterium first interacts with gastric tissue, an event that is poorly understood in vivo. We have shown that the luminal space adjacent to gastric epithelial damage is a microenvironment, and we hypothesized that this microenvironment might enhance H. pylori colonization. Inoculation with 106H. pylori (wild-type Sydney Strain 1, SS1) significantly delayed healing of acetic-acid induced ulcers at Day 1, 7 and 30 post-inoculation, and wild-type SS1 preferentially colonized the ulcerated area compared to uninjured gastric tissue in the same animal at all time points. Gastric resident Lactobacillus spp. did not preferentially colonize ulcerated tissue. To determine whether bacterial motility and chemotaxis are important to ulcer healing and colonization, we analyzed isogenic H. pylori mutants defective in motility (ΔmotB) or chemotaxis (ΔcheY). ΔmotB (106) failed to colonize ulcerated or healthy stomach tissue. ΔcheY (106) colonized both tissues, but without preferential colonization of ulcerated tissue. However, ΔcheY did modestly delay ulcer healing, suggesting that chemotaxis is not required for this process. We used two-photon microscopy to induce microscopic epithelial lesions in vivo, and evaluated accumulation of fluorescently labeled H. pylori at gastric damage sites in the time frame of minutes instead of days. By 5 min after inducing damage, H. pylori SS1 preferentially accumulated at the site of damage and inhibited gastric epithelial restitution. H. pylori ΔcheY modestly accumulated at the gastric surface and inhibited restitution, but did not preferentially accumulate at the injury site. H. pylori ΔmotB neither accumulated at the surface nor inhibited restitution. We conclude that bacterial chemosensing and motility rapidly promote H. pylori colonization of injury sites, and thereby biases the injured tissue towards sustained gastric damage. [ABSTRACT FROM AUTHOR]

Published
2014
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26. Cell injury triggers actin polymerization to initiate epithelial restitution.

Author

Aihara E, Medina-Candelaria NM, Hanyu H, Matthis AL, Engevik KA, Gurniak CB, Witke W, Turner JR, Zhang T, and Montrose MH

Subjects
Animals, Cell Movement, Cells, Cultured, Epithelial Cells physiology, Female, Gastric Mucosa metabolism, Gastric Mucosa physiology, Male, Mice, Mice, Transgenic, Organoids cytology, Organoids physiology, Polymerization, Regeneration physiology, Stomach injuries, Actins metabolism, Gastric Mucosa injuries, Organoids injuries, Protein Multimerization physiology, Re-Epithelialization physiology, Stomach cytology
Abstract

The role of the actin cytoskeleton in the sequence of physiological epithelial repair in the intact epithelium has yet to be elucidated. Here, we explore the role of actin in gastric repair in vivo and in vitro gastric organoids (gastroids). In response to two-photon-induced cellular damage of either an in vivo gastric or in vitro gastroid epithelium, actin redistribution specifically occurred in the lateral membranes of cells neighboring the damaged cell. This was followed by their migration inward to close the gap at the basal pole of the dead cell, in parallel with exfoliation of the dead cell into the lumen. The repair and focal increase of actin was significantly blocked by treatment with EDTA or the inhibition of actin polymerization. Treatment with inhibitors of myosin light chain kinase, myosin II, trefoil factor 2 signaling or phospholipase C slowed both the initial actin redistribution and the repair. While Rac1 inhibition facilitated repair, inhibition of RhoA/Rho-associated protein kinase inhibited it. Inhibitors of focal adhesion kinase and Cdc42 had negligible effects. Hence, initial actin polymerization occurs in the lateral membrane, and is primarily important to initiate dead cell exfoliation and cell migration to close the gap., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published
2018
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27. Organoids as a Model to Study Infectious Disease.

Author

Engevik KA, Matthis AL, Montrose MH, and Aihara E

Subjects
Animals, Helicobacter Infections microbiology, Helicobacter pylori physiology, Mice, Stomach microbiology, Communicable Diseases etiology, Models, Biological, Organoids microbiology
Abstract

The advent of the gastric organoid culture system has provided a new model to emulate native epithelial tissue in vitro. Gastric organoids grow from isolated epithelial stem cells and develop into three dimensional structures that can be used to study host physiology. Here we describe current laboratory protocols for growing gastric organoids and the microinjection of pathogens such as Helicobacter pylori into the lumen of gastric organoids in order to study the cellular response following infection.

Published
2018
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