Your search keyword '"Campolo, Allison"' showing total 12 results

1. Diabetes Causes Significant Alterations in Pulmonary Glucose Transporter Expression.

Author

Campolo, Allison, Maria, Zahra, and Lacombe, Véronique A.

Subjects

ETIOLOGY of diabetes, GLUCOSE transporters, TYPE 1 diabetes, PROTEIN expression, LUNG infections, INSULIN therapy

Abstract

Diabetes has been identified as a significant and independent risk factor for the development or increased severity of respiratory infections. However, the role of glucose transport in the healthy and diseased lung has received little attention. Specifically, the protein expression of the predominant glucose transporter (GLUT) isoforms in the adult lung remains largely to be characterized in both healthy and diabetic states. Type 1 diabetes was induced via streptozotocin and rescued via subcutaneous semi-osmotic insulin pump for 8 weeks. The gene and/or protein expression of the most predominant GLUT isoforms from Classes I and III, including the major insulin-sensitive isoform (i.e., GLUT4) and novel isoforms (i.e., GLUT-8 and GLUT-12), was quantified in the lung of healthy and diabetic mice via qRT-PCR and/or Western blotting. Pulmonary cell surface GLUT protein was measured using a biotinylated photolabeling assay, as a means to evaluate GLUT trafficking. Diabetic mice demonstrated significant alterations of total pulmonary GLUT protein expression, which were isoform- and location-dependent. Long-term insulin treatment rescued the majority of GLUT protein expression alterations in the lung during diabetes, as well as GLUT-4 and -8 trafficking to the pulmonary cell surface. These alterations in glucose homeostasis during diabetes may contribute to an increased severity of pulmonary infection during diabetes and may point to novel metabolic therapeutic strategies for diabetic patients with concurrent respiratory infections. [ABSTRACT FROM AUTHOR]

Published

2024

2. Dysregulation of insulin-sensitive glucose transporters during insulin resistance-induced atrial fibrillation

Author

Maria, Zahra, Campolo, Allison R., Scherlag, Benjamin J., Ritchey, Jerry W., and Lacombe, Véronique A.

Published

2018

3. Complete Recovery of Acanthamoeba Motility among Surviving Organisms after Contact Lens Care Disinfection.

Author

Campolo, Allison, Patterson, Brian, Lara, Esther, Shannon, Paul, and Crary, Monica

Subjects

CONTACT lenses, ACANTHAMOEBA, ACANTHAMOEBA keratitis, PHYSIOLOGIC salines, AXENIC cultures

Abstract

Acanthamoeba keratitis is a sight-threatening infection of the cornea which is extremely challenging to treat. Understanding this organism's responses during contact lens contact and disinfection could enhance our understanding of how Acanthamoebae colonize contact lens cases, better inform us on contact lens care solution (CLC) efficacy, and help us better understand the efficacy required of CLC products. To explore this gap in knowledge, we used Acanthamoeba ATCC 30461 and ATCC 50370 trophozoites to examine Acanthamoeba behavior during and after CLC disinfection. Amoebae were added to sterile aluminum flow cells and flow cell solutions were changed to Ringer's solution (control), or one of four CLCs based on biocides (PHMB, PAPB/Polyquad, Polyquad/Aldox, or Polyquad/Alexidine) for 6 h. Each flow cell solution was then changed to axenic culture media (AC6) for 12 h to determine the behavior of amoebae following disinfection. Distance, speed, and displacement were calculated for each organism. As compared to the control of one-quarter Ringer's solution, each CLC significantly impacted Acanthamoeba motility in both the CLC and AC6 conditions. However, the amoebae challenged with the PHMB CLC traveled a significantly greater total distance than with the other three CLCs, indicating differences in effectiveness between biocides. Furthermore, amoebae regaining motility post-disinfection by CLCs were observed to travel considerable distances and thus could be considered dangerous to ocular health. We determined that while all CLCs produced a substantial or complete cessation of movement vs. the control condition during disinfection, those which relied on the Polyquad biocides were the most effective, and that any amoebae which survived disinfection were able to recover motility. Future examinations of these findings should include direct correlations between motility and viability, and how infectivity and motility may be related. [ABSTRACT FROM AUTHOR]

Published

2023

4. Acanthamoeba spp. aggregate and encyst on contact lens material increasing resistance to disinfection.

Author

Campolo, Allison, Pifer, Reed, Walters, Rhonda, Thomas, Megan, Miller, Elise, Harris, Valerie, King, Jamie, Rice, Christopher A., Shannon, Paul, Patterson, Brian, and Crary, Monica

Subjects

CONTACT lenses, ACANTHAMOEBA, STRENGTH of materials, GENE expression profiling, ACANTHAMOEBA keratitis

Abstract

Introduction: Acanthamoeba keratitis is often caused when Acanthamoeba contaminate contact lenses and infect the cornea. Acanthamoeba is pervasive in the environment as a motile, foraging trophozoite or biocide resistant and persistent cyst. As contact lens contamination is a potential first step in infection, we studied Acanthamoeba’s behavior and interactions on different contact lens materials. We hypothesized that contact lenses may induce aggregation, which is a precursor to encystment, and that aggregated encystment would be more difficult to disinfect than motile trophozoites. Methods: Six clinically and/or scientifically relevant strains of Acanthamoeba (ATCC 30010, ATCC 30461, ATCC 50370, ATCC 50702, ATCC 50703, and ATCC PRA-115) were investigated on seven different common silicone hydrogel contact lenses, and a no-lens control, for aggregation and encystment for 72 h. Cell count and size were used to determine aggregation, and fluorescent staining was used to understand encystment. RNA seq was performed to describe the genome of Acanthamoeba which was individually motile or aggregated on different lens materials. Disinfection efficacy using three common multi-purpose solutions was calculated to describe the potential disinfection resistance of trophozoites, individual cysts, or spheroids. Results: Acanthamoeba trophozoites of all strains examined demonstrated significantly more aggregation on specific contact lens materials than others, or the no-lens control. Fluorescent staining demonstrated encystment in as little as 4 hours on contact lens materials, which is substantially faster than previously reported in natural or laboratory settings. Gene expression profiles corroborated encystment, with significantly differentially expressed pathways involving actin arrangement and membrane complexes. High disinfection resistance of cysts and spheroids with multi-purpose solutions was observed. Discussion: Aggregation/encystment is a protective mechanism which may enable Acanthamoeba to be more disinfection resistant than individual trophozoites. This study demonstrates that some contact lens materials promote Acanthamoeba aggregation and encystment, and Acanthamoeba spheroids obstruct multi-purpose solutions from disinfecting Acanthamoeba. [ABSTRACT FROM AUTHOR]

Published

2022

5. Differential Antimicrobial Efficacy of Multipurpose Solutions against Acanthamoeba Trophozoites.

Author

Walters, Rhonda, Miller, Elise, Campolo, Allison, Gabriel, Manal M., Shannon, Paul, McAnally, Cindy, and Crary, Monica

Published

2021

6. Glial Growth Factor 2 Regulates Glucose Transport in Healthy Cardiac Myocytes and During Myocardial Infarction via an Akt-Dependent Pathway.

Author

Shoop, Shanell, Maria, Zahra, Campolo, Allison, Rashdan, Nabil, Martin, Dominic, Lovern, Pamela, and Lacombe, Véronique A.

Subjects

GROWTH factors, GLUCOSE transporters, MYOCARDIAL infarction, NEUREGULINS, CARDIOTONIC agents

Abstract

Neuregulin (NRG), a paracrine factor in myocytes, promotes cardiac development via the ErbB receptors. NRG-1β also improves cardiac function and cell survival after myocardial infarction (MI), although the mechanisms underlying these cardioprotective effects are not well elucidated. Increased glucose uptake has been shown to be cardio-protective during MI. We hypothesized that treatment with a recombinant version of NRG-1β, glial growth factor 2 (GGF2), will enhance glucose transport in the healthy myocardium and during MI. Cardiac myocytes were isolated from MI and healthy adult rats, and subsequently incubated with or without insulin or GGF2. Glucose uptake was measured using a fluorescent D-glucose analog. The translocation of glucose transporter (GLUT) 4 to the cell surface, the rate-limiting step in glucose uptake, was measured using a photolabeled biotinylation assay in isolated myocytes. Similar to insulin, acute in vitro GGF2 treatment increased glucose uptake in healthy cardiac myocytes (by 40 and 49%, respectively, P = 0.002). GGF2 treatment also increased GLUT4 translocation in healthy myocytes by 184% (P < 0.01), while ErbB 2/4 receptor blockade (by afatinib) abolished these effects. In addition, GGF2 treatment enhanced Akt phosphorylation (at both threonine and serine sites, by 75 and 139%, respectively, P = 0.029 and P = 0.01), which was blunted by ErbB 2/4 receptor blockade. GGF2 treatment increased the phosphorylation of AS160 (an Akt effector) by 72% (P < 0.05), as well as the phosphorylation of PDK-1 and PKC (by 118 and 92%, respectively, P < 0.05). During MI, cardiac GLUT4 translocation was downregulated by 44% (P = 0.004) and was partially rescued by both in vitro insulin and GGF2 treatment. Our data demonstrate that acute GGF2 treatment increased glucose transport in cardiac myocytes by activating the ErbB 2/4 receptors and subsequent key downstream effectors (i.e., PDK-1, Akt, AS160, and PKC). These findings highlight novel mechanisms of action of GGF2, which warrant further investigation in patients with heart failure. [ABSTRACT FROM AUTHOR]

Published

2019

7. Adverse Metabolic Effects of Diltiazem Treatment During Diabetic Cardiomyopathy.

Author

Parriman, Matt, Campolo, Allison, Waller, Amanda P., and Lacombe, Véronique A.

Subjects

DILTIAZEM, CARDIOMYOPATHIES, GLYCEMIC control

Abstract

Diabetes is a global epidemic disease, which leads to multiorgan dysfunction, including heart disease. Diabetes results from the limited absorption of glucose into insulin-sensitive tissues. The heart is one of the main organs to utilize glucose as an energy substrate. Glucose uptake into striated muscle is regulated by a family of membrane proteins called glucose transporters (GLUTs). Although calcium channel blockers, including diltiazem, are widely prescribed drugs for cardiovascular diseases, including in patients with diabetes, their pharmacological effects on glucose metabolism are somewhat controversial. We hypothesized that diltiazem treatment will exhibit detrimental effects on whole body glucose homeostasis and glucose transport in the striated muscle of patients with diabetes. Healthy and streptozotocin-treated rats were randomly assigned to receive diltiazem treatment or a placebo for 8 weeks. Blood glucose was significantly increased in the untreated diabetic groups, which worsened after diltiazem treatment. Diabetes decreased protein content of both GLUT4 (the predominate insulin-sensitive glucose transporter) and AS160 (Akt Substrate at 160 kDa, the downstream protein in the signaling cascade that regulates GLUT4 trafficking) in striated muscle of diabetic rats, with a more pronounced alteration after diltiazem treatment. We additionally reported that diabetic rodents displayed marked systolic dysfunction, which was not rescued by diltiazem treatment. In conclusion, diltiazem treatment worsened the effects of diabetes-induced hyperglycemia and diabetes-induced alterations in the regulation of glucose transport in striated muscle. [ABSTRACT FROM AUTHOR]

Published

2019

8. Diabetes Alters the Expression and Translocation of the Insulin-Sensitive Glucose Transporters 4 and 8 in the Atria.

Author

Maria, Zahra, Campolo, Allison R., and Lacombe, Veronique A.

Subjects

*DIABETES, *GLUCOSE transporters, *ATRIAL fibrillation risk factors, *GLUCOSE metabolism, *STREPTOZOTOCIN

Abstract

Although diabetes has been identified as a major risk factor for atrial fibrillation, little is known about glucose metabolism in the healthy and diabetic atria. Glucose transport into the cell, the rate-limiting step of glucose utilization, is regulated by the Glucose Transporters (GLUTs). Although GLUT4 is the major isoform in the heart, GLUT8 has recently emerged as a novel cardiac isoform. We hypothesized that GLUT-4 and -8 translocation to the atrial cell surface will be regulated by insulin and impaired during insulin-dependent diabetes. GLUT protein content was measured by Western blotting in healthy cardiac myocytes and type 1 (streptozotocin-induced, T1Dx) diabetic rodents. Active cell surface GLUT content was measured using a biotinylated photolabeled assay in the perfused heart. In the healthy atria, insulin stimulation increased both GLUT-4 and -8 translocation to the cell surface (by 100% and 240%, respectively, P<0.05). Upon insulin stimulation, we reported an increase in Akt (Th308 and s473 sites) and AS160 phosphorylation, which was positively (P<0.05) correlated with GLUT4 protein content in the healthy atria. During diabetes, active cell surface GLUT-4 and -8 content was downregulated in the atria (by 70% and 90%, respectively, P<0.05). Akt and AS160 phosphorylation was not impaired in the diabetic atria, suggesting the presence of an intact insulin signaling pathway. This was confirmed by the rescued translocation of GLUT-4 and -8 to the atrial cell surface upon insulin stimulation in the atria of type 1 diabetic subjects. In conclusion, our data suggest that: 1) both GLUT-4 and -8 are insulin-sensitive in the healthy atria through an Akt/AS160 dependent pathway; 2) GLUT-4 and -8 trafficking is impaired in the diabetic atria and rescued by insulin treatment. Alterations in atrial glucose transport may induce perturbations in energy production, which may provide a metabolic substrate for atrial fibrillation during diabetes. [ABSTRACT FROM AUTHOR]

Published

2015

9. Antimicrobial Efficacy of Contact Lens Solutions Assessed by ISO Standards.

Author

McAnally, Cindy, Walters, Rhonda, Campolo, Allison, Harris, Valerie, King, Jamie, Thomas, Megan, Gabriel, Manal M, Shannon, Paul, and Crary, Monica

Subjects

CONTACT lenses, SERRATIA marcescens, OPPORTUNISTIC infections, CORNEAL ulcer, EYE infections

Abstract

Microbial keratitis (MK) is an eye infection caused by opportunistic bacteria or fungi, which may lead to sight-threatening corneal ulcers. These microorganisms can be introduced to the eye via improper contact lens usage or hygiene, or ineffective multipurpose solutions (MPSs) to disinfect daily wear contact lenses. Thus, the patient's choice and use of these MPSs is a known risk factor for the development of MK. It is then critical to determine the efficacy of popular MPSs against ubiquitous ocular microorganisms. Therefore, we compare the efficacy of nine major MPSs on the global market against four different microorganism species, and with four different common contact lenses. In accordance with International Standards Organization protocol 14729 and 18259, the microorganisms were inoculated into each MPS with and without contact lenses, and held for the manufacturer's disinfection time, 24 h, and 7 days after challenge with Serratia marcescens or Fusarium spp. Plates were incubated for 2–7 days and plate counts were conducted to determine the number of surviving microorganisms. The majority of MPSs demonstrated significantly higher disinfection efficacies without contact lenses. Broadly, among the microorganisms tested, the OPTI-FREE products (Puremoist, Express, and Replenish) maintained the highest disinfection efficacies at the manufacturer's stated disinfection time when paired with any contact lens, compared with other MPSs. These were followed closely by RevitaLens and renu Advanced. MPSs containing dual biocides polyquaternium-1 and myristamidopropyl dimethylamine possessed the highest disinfection efficacy against multiple ocular pathogens. [ABSTRACT FROM AUTHOR]

Published

2021

10. Continuous Real-Time Motility Analysis of Acanthamoeba Reveals Sustained Movement in Absence of Nutrients.

Author

Campolo, Allison, Harris, Valerie, Walters, Rhonda, Miller, Elise, Patterson, Brian, and Crary, Monica

Subjects

ACANTHAMOEBA, ACANTHAMOEBA keratitis, AXENIC cultures, PHYSIOLOGIC salines, CONTACT lenses, OBJECT tracking (Computer vision)

Abstract

Acanthamoeba keratitis is a serious ocular infection which is challenging to treat and can lead to blindness. While this pathogen is ubiquitous and can contaminate contact lenses after contact with water, its habits remain elusive. Understanding this organism's natural behavior will better inform us on how Acanthamoeba colonize contact lens care systems. Acanthamoeba trophozoites were allowed to adhere to either a glass coverslip or non-nutrient agar (NNA) within a flow cell with nutrients (Escherichia coli or an axenic culture medium (AC6)) or without nutrients (Ringer's solution). Images were taken once every 24 s over 12 h and compiled, and videos were analyzed using ImageJ Trackmate software. Acanthamoeba maintained continuous movement for the entire 12 h period. ATCC 50370 had limited differences between conditions and surfaces throughout the experiment. Nutrient differences had a noticeable impact for ATCC 30461, where E. coli resulted in the highest total distance and speed during the early periods of the experiment but had the lowest total distance and speed by 12 h. The Ringer's and AC6 conditions were the most similar between strains, while Acanthamoeba in the E. coli and NNA conditions demonstrated significant differences between strains (p < 0.05). These results indicate that quantifiable visual tracking of Acanthamoeba may be a novel and robust method for identifying the movement of Acanthamoeba in relation to contact lens care products. The present study indicates that Acanthamoeba can undertake sustained movement for at least 12 h with and without nutrients, on both rough and smooth surfaces, and that different strains have divergent behavior. [ABSTRACT FROM AUTHOR]

Published

2021

11. Evaluating Alternate Methods of Determining the Antimicrobial Efficacy of Contact Lens Care Products against Acanthamoeba Trophozoites.

Author

Campolo, Allison, Shannon, Paul, and Crary, Monica

Subjects

ACANTHAMOEBA, CONTACT lenses, TROPHOZOITES, PROPIDIUM iodide, ACANTHAMOEBA keratitis

Abstract

Acanthamoeba keratitis (AK) is a serious ocular infection caused by a ubiquitous free-living amoeba, Acanthamoeba. This infection often results in extensive corneal damage and blindness, and is notoriously difficult to cure. While Acanthamoeba is an abundant organism, AK is most associated with contact lens hygiene noncompliance and inadequate contact lens care (CLC) disinfection regimens. Thus, accurate and timely antimicrobial efficacy testing of CLC solutions is paramount. Published methods for antimicrobial efficacy testing of Acanthamoeba trophozoites requires 14 days for results. Presently, alternate and/or rapid methods for evaluating CLC products rarely demonstrate equivalent results compared to commonly-reported methods. Propidium iodide is a cellular stain that can only bind to cells with damaged outer membranes. We evaluated propidium iodide staining as an alternative method for determining the relative antimicrobial efficacy of 11 different CLC products against Acanthamoeba trophozoites. Following exposure to a CLC product, the fluorescence intensity of propidium iodide in an Acanthamoeba population demonstrated a strong correlation to the log reduction determined by established, growth-based Acanthamoeba testing used to evaluate the antimicrobial efficacy of CLC products. Thus, propidium iodide was found to be an effective rapid tool for determining cell death in Acanthamoeba trophozoites following exposure to CLC solutions. [ABSTRACT FROM AUTHOR]

Published

2021

12. 404-P: Metformin Treatment Rescues Alterations of Insulin-Sensitive Glucose Transporters in the Lung of Insulin-Resistant Mice.

Author

CAMPOLO, ALLISON, MARIA, ZAHRA, HINSDALE, MYRON, LIU, LIN, and LACOMBE, VERONIQUE

Abstract

Obesity and hyperglycemia have recently been identified as independent risk factors for the development of respiratory infections. Although the lung is a major organ to utilize glucose, the regulation of glucose transport in the healthy and diabetic lung has received little attention. We hypothesized that metformin would rescue diabetes-induced alterations of glucose transport in the lung. To test this hypothesis, we induced an insulin-resistant diabetic mouse model by feeding a high-fat diet for 16 weeks (n=10/group). A subset of mice was treated with metformin for 8 weeks. Protein content of class I glucose transporters (GLUTs -1, -2, -3, -4) and class III GLUTs (-8, -10, -12) was quantified by Western blotting in whole lung homogenates. Cell surface GLUTs were quantified using the biotinylated photolabeling technique. Glucose concentration in bronchoalveolar lavage (BAL) fluid was measured spectrophotometrically. After feeding a high-fat diet, mice became obese, mildly hyperglycemic, hyperinsulinemic, and insulin tolerant. Total protein content of GLUT4 and GLUT12 was significantly decreased in the lung of the insulin-resistant (IR) group (P <0.05). Following metformin treatment, protein content of GLUT4, but not GLUT12, was rescued in the lung of the treated IR mice (P <0.05). Cell-surface protein content of GLUT4 and GLUT8 was significantly decreased in the lung of IR mice, which was rescued in the treated group (P<0.05). IR mice demonstrated a trend towards a higher glucose concentration in the BAL fluid (P < 0.1). These novel findings suggest that 1) regulation of glucose transport is altered in the lung during obesity and hyperglycemia, potentially increasing the risk for pulmonary infection, and 2) metformin treatment rescues GLUT alterations in the lung of IR mice. Insights gained from this study could lead to the identification of significant metabolic therapeutic targets for diabetic patients affected by concurrent respiratory infections. Disclosure: A. Campolo: None. Z. Maria: None. M. Hinsdale: None. L. Liu: None. V. Lacombe: None. Funding: Harold Hamm Diabetes Center; National Institutes of Health [ABSTRACT FROM AUTHOR]

Published

2019