Your search keyword '"P. Mroz"' showing total 8 results

1. Validation of Mct8/Oatp1c1 dKO mice as a model organism for the Allan-Herndon-Dudley Syndrome

Author

Gandhari Maity-Kumar, Lisa Ständer, Meri DeAngelis, Sooyeon Lee, Anna Molenaar, Lore Becker, Lillian Garrett, Oana V. Amerie, Sabine M. Hoelter, Wolfgang Wurst, Helmut Fuchs, Annette Feuchtinger, Valerie Gailus-Durner, Cristina Garcia-Caceres, Ahmed E. Othman, Caroline Brockmann, Vanessa I. Schöffling, Katja Beiser, Heiko Krude, Piotr A. Mroz, Susanna Hofmann, Jan Tuckermann, Richard D. DiMarchi, Martin Hrabe de Angelis, Matthias H. Tschöp, Paul T. Pfluger, and Timo D. Müller

Subjects

Allan-Herndon Dudley Syndrome, Thyroid hormone, Mct8, Oatp1c1, Energy metabolism, Myelination, Internal medicine, RC31-1245

Abstract

Objective: The Allan-Herndon-Dudley syndrome (AHDS) is a severe disease caused by dysfunctional central thyroid hormone transport due to functional loss of the monocarboxylate transporter 8 (MCT8). In this study, we assessed whether mice with concomitant deletion of the thyroid hormone transporters Mct8 and the organic anion transporting polypeptide (Oatp1c1) represent a valid preclinical model organism for the AHDS. Methods: We generated and metabolically characterized a new CRISPR/Cas9 generated Mct8/Oatp1c1 double-knockout (dKO) mouse line for the clinical features observed in patients with AHDS. Results: We show that Mct8/Oatp1c1 dKO mice mimic key hallmarks of the AHDS, including decreased life expectancy, central hypothyroidism, peripheral hyperthyroidism, impaired neuronal myelination, impaired motor abilities and enhanced peripheral thyroid hormone action in the liver, adipose tissue, skeletal muscle and bone. Conclusions: We conclude that Mct8/Oatp1c1 dKO mice are a valuable model organism for the preclinical evaluation of drugs designed to treat the AHDS.

Published

2022

2. Optimized GIP analogs promote body weight lowering in mice through GIPR agonism not antagonism

Author

Piotr A. Mroz, Brian Finan, Vasily Gelfanov, Bin Yang, Matthias H. Tschöp, Richard D. DiMarchi, and Diego Perez-Tilve

Subjects

Internal medicine, RC31-1245

Abstract

Objective: Structurally-improved GIP analogs were developed to determine precisely whether GIP receptor (GIPR) agonism or antagonism lowers body weight in obese mice. Methods: A series of peptide-based GIP analogs, including structurally diverse agonists and a long-acting antagonist, were generated and characterized in vitro using functional assays in cell systems overexpressing human and mouse derived receptors. These analogs were characterized in vivo in DIO mice following acute dosing for effects on glycemic control, and following chronic dosing for effects on body weight and food intake. Pair-feeding studies and indirect calorimetry were used to survey the mechanism for body weight lowering. Congenital Gipr−/− and Glp1r−/− DIO mice were used to investigate the selectivity of the agonists and to ascribe the pharmacology to effects mediated by the GIPR. Results: Non-acylated, Aib2 substituted analogs derived from human GIP sequence showed full in vitro potency at human GIPR and subtly reduced in vitro potency at mouse GIPR without cross-reactivity at GLP-1R. These GIPR agonists lowered acute blood glucose in wild-type and Glp1r−/− mice, and this effect was absent in Gipr−/− mice, which confirmed selectivity towards GIPR. Chronic treatment of DIO mice resulted in modest yet consistent, dose-dependent decreased body weight across many studies with diverse analogs. The mechanism for body weight lowering is due to reductions in food intake, not energy expenditure, as suggested by pair-feeding studies and indirect calorimetry assessment. The weight lowering effect was preserved in DIO Glp-1r−/− mice and absent in DIO Gipr−/− mice. The body weight lowering efficacy of GIPR agonists was enhanced with analogs that exhibit higher mouse GIPR potency, with increased frequency of administration, and with fatty-acylated peptides of extended duration of action. Additionally, a fatty-acylated, N-terminally truncated GIP analog was shown to have high in vitro antagonism potency for human and mouse GIPR without cross-reactive activity at mouse GLP-1R or mouse glucagon receptor (GcgR). This acylated antagonist sufficiently inhibited the acute effects of GIP to improve glucose tolerance in DIO mice. Chronic treatment of DIO mice with high doses of this acylated GIPR antagonist did not result in body weight change. Further, co-treatment of this acylated GIPR antagonist with liraglutide, an acylated GLP-1R agonist, to DIO mice did not result in increased body weight lowering relative to liraglutide-treated mice. Enhanced body weight lowering in DIO mice was evident however following co-treatment of long-acting selective individual agonists for GLP-1R and GIPR, consistent with previous data. Conclusions: We conclude that peptide-based GIPR agonists, not peptide-based GIPR antagonists, that are suitably optimized for receptor selectivity, cross-species activity, and duration of action consistently lower body weight in DIO mice, although with moderate efficacy relative to GLP-1R agonists. These preclinical rodent pharmacology results, in accordance with recent clinical results, provide definitive proof that systemic GIPR agonism, not antagonism, is beneficial for body weight loss. Keywords: Glucose-dependent insulinotropic polypeptide (GIP), Agonism, Obesity, Diet-induced obese (DIO) mice, Pharmacology

Published

2019

3. Molecular elements in FGF19 and FGF21 defining KLB/FGFR activity and specificity

Author

Archita Agrawal, Sebastian Parlee, Diego Perez-Tilve, Pengyun Li, Jia Pan, Piotr A. Mroz, Ann Maria Kruse Hansen, Birgitte Andersen, Brian Finan, Alexei Kharitonenkov, and Richard D. DiMarchi

Subjects

Internal medicine, RC31-1245

Abstract

Objective: To signal, FGF19 and FGF21 require co-receptor βKlotho (KLB) to act in concert with FGF receptors, and yet there is appreciable variance in the C-terminal sequences of these two novel metabolic hormones where binding is believed to be primary. We seek to determine the functional consequences for these amino acid differences and determine whether such information can be used to design high potency antagonists and agonists. Methods: We employed a functional in vitro assay to identify C-terminal protein fragments capable of fully blocking KLB-mediated FGF19 and 21 receptor signaling. The key residues in each hormone responsible for support full bioactivity were identified through peptide-based Ala-scanning. Chemical optimization of the peptides was employed to increase their antagonistic potency. An optimized sequence as a substituted part of a full length FGF21 was assessed for enhanced FGFR/KLB-mediated agonism using tissue culture and obese mice. Results: C-terminal FGF19 and FGF21 peptides of relatively short length were observed to potently inhibit the activity of these two hormones, in vitro and in vivo. These FGFs of different sequence also demonstrated a striking conservation of structural determinants to maintain KLB binding. A single C-terminal amino acid in FGF19 was observed to modulate relative activity through FGFR1 and FGFR4. The substitution of native FGF21 C-terminal sequence with a peptide optimized for the highest antagonistic activity resulted in significantly enhanced FGF potency, as measured by in vitro signaling and improvements in metabolic outcomes in diet-induced obese mice. Conclusions: We report here the ability of short C-terminal peptides to bind KLB and function as antagonists of FGF19 and 21 actions. These proteins maintain high conservation of sequence in those residues central to KLB binding. An FGF21 chimeric protein possessing an optimized C-terminal sequence proved to be a super-agonist in delivery of beneficial metabolic effects in obese mice. Keywords: FGF19, FGF21, KLB, FGFR isoforms, FGF antagonism, Structure-activity-relationship, Alanine-scan

Published

2018

4. Metabolic profiling of single cells by exploiting NADH and FAD fluorescence via flow cytometry.

Author

Abir, Ariful Haque, Weckwerth, Leonie, Wilhelm, Artur, Thomas, Jana, Reichardt, Clara M., Munoz, Luis, Völkl, Simon, Appelt, Uwe, Mroz, Markus, Niesner, Raluca, Hauser, Anja, Sophie Fischer, Rebecca, Pracht, Katharina, Jäck, Hans-Martin, Schett, Georg, Krönke, Gerhard, and Mielenz, Dirk

Abstract

The metabolism of different cells within the same microenvironment can differ and dictate physiological or pathological adaptions. Current single-cell analysis methods of metabolism are not label-free. The study introduces a label-free, live-cell analysis method assessing endogenous fluorescence of NAD(P)H and FAD in surface-stained cells by flow cytometry. OxPhos inhibition, mitochondrial uncoupling, glucose exposure, genetic inactivation of glucose uptake and mitochondrial respiration alter the optical redox ratios of FAD and NAD(P)H as measured by flow cytometry. Those alterations correlate strongly with measurements obtained by extracellular flux analysis. Consequently, metabolically distinct live B-cell populations can be resolved, showing that human memory B-cells from peripheral blood exhibit a higher glycolytic flexibility than naïve B cells. Moreover, the comparison of blood-derived B- and T-lymphocytes from healthy donors and rheumatoid arthritis patients unleashes rheumatoid arthritis-associated metabolic traits in human naïve and memory B-lymphocytes. Taken together, these data show that the optical redox ratio can depict metabolic differences in distinct cell populations by flow cytometry. • Real-time simultaneous metabolic analysis of different cell populations. • Label-free detection of the optical redox ratio of FAD/NADH fluorescence via flow cytometry. • Correlation with Seahorse extracellular flux analysis and enzymatic NAD(P)H detection. • Applicable to human T cell lymphoma, primary mouse and human lymphocytes. • Distinction of naïve and memory B cell populations in healthy and inflamed background. [ABSTRACT FROM AUTHOR]

Published

2024

5. Optimized GIP analogs promote body weight lowering in mice through GIPR agonism not antagonism.

Author

Mroz, Piotr A., Finan, Brian, Gelfanov, Vasily, Yang, Bin, Tschöp, Matthias H., DiMarchi, Richard D., and Perez-Tilve, Diego

Abstract

Abstract Objective Structurally-improved GIP analogs were developed to determine precisely whether GIP receptor (GIPR) agonism or antagonism lowers body weight in obese mice. Methods A series of peptide-based GIP analogs, including structurally diverse agonists and a long-acting antagonist, were generated and characterized in vitro using functional assays in cell systems overexpressing human and mouse derived receptors. These analogs were characterized in vivo in DIO mice following acute dosing for effects on glycemic control, and following chronic dosing for effects on body weight and food intake. Pair-feeding studies and indirect calorimetry were used to survey the mechanism for body weight lowering. Congenital Gipr−/− and Glp1r−/− DIO mice were used to investigate the selectivity of the agonists and to ascribe the pharmacology to effects mediated by the GIPR. Results Non-acylated, Aib2 substituted analogs derived from human GIP sequence showed full in vitro potency at human GIPR and subtly reduced in vitro potency at mouse GIPR without cross-reactivity at GLP-1R. These GIPR agonists lowered acute blood glucose in wild-type and Glp1r−/− mice, and this effect was absent in Gipr−/− mice, which confirmed selectivity towards GIPR. Chronic treatment of DIO mice resulted in modest yet consistent, dose-dependent decreased body weight across many studies with diverse analogs. The mechanism for body weight lowering is due to reductions in food intake, not energy expenditure, as suggested by pair-feeding studies and indirect calorimetry assessment. The weight lowering effect was preserved in DIO Glp-1r−/− mice and absent in DIO Gipr −/− mice. The body weight lowering efficacy of GIPR agonists was enhanced with analogs that exhibit higher mouse GIPR potency, with increased frequency of administration, and with fatty-acylated peptides of extended duration of action. Additionally, a fatty-acylated, N-terminally truncated GIP analog was shown to have high in vitro antagonism potency for human and mouse GIPR without cross-reactive activity at mouse GLP-1R or mouse glucagon receptor (GcgR). This acylated antagonist sufficiently inhibited the acute effects of GIP to improve glucose tolerance in DIO mice. Chronic treatment of DIO mice with high doses of this acylated GIPR antagonist did not result in body weight change. Further, co-treatment of this acylated GIPR antagonist with liraglutide, an acylated GLP-1R agonist, to DIO mice did not result in increased body weight lowering relative to liraglutide-treated mice. Enhanced body weight lowering in DIO mice was evident however following co-treatment of long-acting selective individual agonists for GLP-1R and GIPR, consistent with previous data. Conclusions We conclude that peptide-based GIPR agonists, not peptide-based GIPR antagonists, that are suitably optimized for receptor selectivity, cross-species activity, and duration of action consistently lower body weight in DIO mice, although with moderate efficacy relative to GLP-1R agonists. These preclinical rodent pharmacology results, in accordance with recent clinical results, provide definitive proof that systemic GIPR agonism, not antagonism, is beneficial for body weight loss. Highlights • Structurally-refined and diverse GIP receptor agonists consistently lower body weight in DIO mice. • Body weight lowering of GIP receptor agonists is maintained in GLP-1R−/− mice yet abolished in GIPR−/− mice. • GIP receptor agonism promotes body weight lowering via food intake mechanism. • A fully potent long-acting GIP receptor antagonist does not lower body weight in DIO mice. [ABSTRACT FROM AUTHOR]

Published

2019

6. Molecular elements in FGF19 and FGF21 defining KLB/FGFR activity and specificity.

Author

Agrawal, Archita, Parlee, Sebastian, Perez-Tilve, Diego, Li, Pengyun, Pan, Jia, Mroz, Piotr A., Kruse Hansen, Ann Maria, Andersen, Birgitte, Finan, Brian, Kharitonenkov, Alexei, and DiMarchi, Richard D.

Abstract

Objective To signal, FGF19 and FGF21 require co-receptor βKlotho (KLB) to act in concert with FGF receptors, and yet there is appreciable variance in the C-terminal sequences of these two novel metabolic hormones where binding is believed to be primary. We seek to determine the functional consequences for these amino acid differences and determine whether such information can be used to design high potency antagonists and agonists. Methods We employed a functional in vitro assay to identify C-terminal protein fragments capable of fully blocking KLB-mediated FGF19 and 21 receptor signaling. The key residues in each hormone responsible for support full bioactivity were identified through peptide-based Ala-scanning. Chemical optimization of the peptides was employed to increase their antagonistic potency. An optimized sequence as a substituted part of a full length FGF21 was assessed for enhanced FGFR/KLB-mediated agonism using tissue culture and obese mice. Results C-terminal FGF19 and FGF21 peptides of relatively short length were observed to potently inhibit the activity of these two hormones, in vitro and in vivo . These FGFs of different sequence also demonstrated a striking conservation of structural determinants to maintain KLB binding. A single C-terminal amino acid in FGF19 was observed to modulate relative activity through FGFR1 and FGFR4. The substitution of native FGF21 C-terminal sequence with a peptide optimized for the highest antagonistic activity resulted in significantly enhanced FGF potency, as measured by in vitro signaling and improvements in metabolic outcomes in diet-induced obese mice. Conclusions We report here the ability of short C-terminal peptides to bind KLB and function as antagonists of FGF19 and 21 actions. These proteins maintain high conservation of sequence in those residues central to KLB binding. An FGF21 chimeric protein possessing an optimized C-terminal sequence proved to be a super-agonist in delivery of beneficial metabolic effects in obese mice. [ABSTRACT FROM AUTHOR]

Published

2018

7. Validation of Mct8/Oatp1c1 dKO mice as a model organism for the Allan-Herndon-Dudley Syndrome.

Author

Maity-Kumar, Gandhari, Ständer, Lisa, DeAngelis, Meri, Lee, Sooyeon, Molenaar, Anna, Becker, Lore, Garrett, Lillian, Amerie, Oana V., Hoelter, Sabine M., Wurst, Wolfgang, Fuchs, Helmut, Feuchtinger, Annette, Gailus-Durner, Valerie, Garcia-Caceres, Cristina, Othman, Ahmed E., Brockmann, Caroline, Schöffling, Vanessa I., Beiser, Katja, Krude, Heiko, and Mroz, Piotr A.

Abstract

The Allan-Herndon-Dudley syndrome (AHDS) is a severe disease caused by dysfunctional central thyroid hormone transport due to functional loss of the monocarboxylate transporter 8 (MCT8). In this study, we assessed whether mice with concomitant deletion of the thyroid hormone transporters Mct8 and the organic anion transporting polypeptide (Oatp1c1) represent a valid preclinical model organism for the AHDS. We generated and metabolically characterized a new CRISPR/Cas9 generated Mct8/Oatp1c1 double-knockout (dKO) mouse line for the clinical features observed in patients with AHDS. We show that Mct8/ Oatp1c1 dKO mice mimic key hallmarks of the AHDS, including decreased life expectancy, central hypothyroidism, peripheral hyperthyroidism, impaired neuronal myelination, impaired motor abilities and enhanced peripheral thyroid hormone action in the liver, adipose tissue, skeletal muscle and bone. We conclude that Mct8/Oatp1c1 dKO mice are a valuable model organism for the preclinical evaluation of drugs designed to treat the AHDS. • Mct8/Oatp1c1 mice represent a valuable model organism for the Allan-Herndon-Dudley Syndrome. • Mct8/Oatp1c1 show central hypothyroidism and peripheral hyperthyroidism. • Mct8/Oatp1c1 show decreased life expectancy. • Mct8/Oatp1c1 show loss of body weight and fat, enhanced bone catabolism and increased T3 action in liver and adipose tissue. • Mct8/Oatp1c1 show severe neuronal hypomyelination and motor impairments. [ABSTRACT FROM AUTHOR]

Published

2022

8. Metabolic profiling of single cells by exploiting NADH and FAD fluorescence via flow cytometry

Author

Ariful Haque Abir, Leonie Weckwerth, Artur Wilhelm, Jana Thomas, Clara M. Reichardt, Luis Munoz, Simon Völkl, Uwe Appelt, Markus Mroz, Raluca Niesner, Anja Hauser, Rebecca Sophie Fischer, Katharina Pracht, Hans-Martin Jäck, Georg Schett, Gerhard Krönke, and Dirk Mielenz

Subjects

NADH, FAD, Metabolism, Fluorescence, Real-time, Flow cytometry, Internal medicine, RC31-1245

Abstract

Objective: The metabolism of different cells within the same microenvironment can differ and dictate physiological or pathological adaptions. Current single-cell analysis methods of metabolism are not label-free. Methods: The study introduces a label-free, live-cell analysis method assessing endogenous fluorescence of NAD(P)H and FAD in surface-stained cells by flow cytometry. Results: OxPhos inhibition, mitochondrial uncoupling, glucose exposure, genetic inactivation of glucose uptake and mitochondrial respiration alter the optical redox ratios of FAD and NAD(P)H as measured by flow cytometry. Those alterations correlate strongly with measurements obtained by extracellular flux analysis. Consequently, metabolically distinct live B-cell populations can be resolved, showing that human memory B-cells from peripheral blood exhibit a higher glycolytic flexibility than naïve B cells. Moreover, the comparison of blood-derived B- and T-lymphocytes from healthy donors and rheumatoid arthritis patients unleashes rheumatoid arthritis-associated metabolic traits in human naïve and memory B-lymphocytes. Conclusions: Taken together, these data show that the optical redox ratio can depict metabolic differences in distinct cell populations by flow cytometry.

Published

2024