Your search keyword '"Ian Steinke"' showing total 8 results

1. Dual PPAR delta/gamma agonists offer therapeutic potential for Alzheimer’s disease

Author

Ian Steinke, Meenakshi Singh, and Rajesh Amin

Subjects

Neurology. Diseases of the nervous system, RC346-429

Published

2024

2. Selective PPAR-Delta/PPAR-Gamma Activation Improves Cognition in a Model of Alzheimer’s Disease

Author

Ian Steinke, Manoj Govindarajulu, Priyanka Das Pinky, Jenna Bloemer, Sieun Yoo, Tracey Ward, Taylor Schaedig, Taylor Young, Fajar Setyo Wibowo, Vishnu Suppiramaniam, and Rajesh H. Amin

Subjects

peroxisomal proliferator activating receptor, in silico drug design, neurodegeneration, Alzheimer’s disease, synaptic plasticity, behavioral deficits, Cytology, QH573-671

Abstract

Background: The continuously increasing association of Alzheimer’s disease (AD) with increased mortality rates indicates an unmet medical need and the critical need for establishing novel molecular targets for therapeutic potential. Agonists for peroxisomal proliferator activating receptors (PPAR) are known to regulate energy in the body and have shown positive effects against Alzheimer’s disease. There are three members of this class (delta, gamma, and alpha), with PPAR-gamma being the most studied, as these pharmaceutical agonists offer promise for AD because they reduce amyloid beta and tau pathologies, display anti-inflammatory properties, and improve cognition. However, they display poor brain bioavailability and are associated with several adverse side effects on human health, thus limiting their clinical application. Methods: We have developed a novel series of PPAR-delta and PPAR-gamma agonists in silico with AU9 as our lead compound that displays selective amino acid interactions focused upon avoiding the Tyr-473 epitope in the PPAR-gamma AF2 ligand binding domain. Results: This design helps to avoid the unwanted side effects of current PPAR-gamma agonists and improve behavioral deficits and synaptic plasticity while reducing amyloid-beta levels and inflammation in 3xTgAD animals. Conclusions: Our innovative in silico design of PPAR-delta/gamma agonists may offer new perspectives for this class of agonists for AD.

Published

2023

3. The Cardioprotective Mechanism of Phenylaminoethyl Selenides (PAESe) Against Doxorubicin-Induced Cardiotoxicity Involves Frataxin

Author

Xiaoyu Fu, Mathew Eggert, Sieun Yoo, Nikhil Patel, Juming Zhong, Ian Steinke, Manoj Govindarajulu, Emine Akyuz Turumtay, Shravanthi Mouli, Peter Panizzi, Ronald Beyers, Thomas Denney, Robert Arnold, and Rajesh H. Amin

Subjects

doxorubicin, phenylaminoethyl selenides, frataxin, cardiomyopathy, cardiotoxicity, glutathione, Therapeutics. Pharmacology, RM1-950

Abstract

Doxorubicin (DOX) is an anthracycline cancer chemotherapeutic that exhibits cumulative dose-limiting cardiotoxicity and limits its clinical utility. DOX treatment results in the development of morbid cardiac hypertrophy that progresses to congestive heart failure and death. Recent evidence suggests that during the development of DOX mediated cardiac hypertrophy, mitochondrial energetics are severely compromised, thus priming the cardiomyocyte for failure. To mitigate cumulative dose (5 mg/kg, QIW x 4 weeks with 2 weeks recovery) dependent DOX, mediated cardiac hypertrophy, we applied an orally active selenium based compound termed phenylaminoethyl selenides (PAESe) (QIW 10 mg/kg x 5) to our animal model and observed that PAESe attenuates DOX-mediated cardiac hypertrophy in athymic mice, as observed by MRI analysis. Mechanistically, we demonstrated that DOX impedes the stability of the iron-sulfur cluster biogenesis protein Frataxin (FXN) (0.5 fold), resulting in enhanced mitochondrial free iron accumulation (2.5 fold) and reduced aconitase activity (0.4 fold). Our findings further indicate that PAESe prevented the reduction of FXN levels and the ensuing elevation of mitochondrial free iron levels. PAESe has been shown to have anti-oxidative properties in part, by regeneration of glutathione levels. Therefore, we observed that PAESe can mitigate DOX mediated cardiac hypertrophy by enhancing glutathione activity (0.4 fold) and inhibiting ROS formation (1.8 fold). Lastly, we observed that DOX significantly reduced cellular respiration (basal (5%) and uncoupled (10%)) in H9C2 cardiomyoblasts and that PAESe protects against the DOX-mediated attenuation of cellular respiration. In conclusion, the current study determined the protective mechanism of PAESe against DOX mediated myocardial damage and that FXN is implicitly involved in DOX-mediated cardiotoxicity.

Published

2021

4. Drug Discovery and Development of Novel Therapeutics for Inhibiting TMAO in Models of Atherosclerosis and Diabetes

Author

Ian Steinke, Nila Ghanei, Manoj Govindarajulu, Sieun Yoo, Juming Zhong, and Rajesh H. Amin

Subjects

FMO3, TMA, CVD, T2D, TMAO, dysbiosis, Physiology, QP1-981

Abstract

Diabetes mellitus exists as a comorbidity with congestive heart failure (CHF). However, the exact molecular signaling mechanism linking CHF as the major form of mortality from diabetes remains unknown. Type 2 diabetic patients display abnormally high levels of metabolic products associated with gut dysbiosis. One such metabolite, trimethylamine N-oxide (TMAO), has been observed to be directly related with increased incidence of cardiovascular diseases (CVD) in human patients. TMAO a gut-liver metabolite, comes from the metabolic degenerative product trimethylamine (TMA) that is produced from gut microbial metabolism. Elevated levels of TMAO in diabetics and obese patients are observed to have a direct correlation with increased risk for major adverse cardiovascular events. The pro-atherogenic effect of TMAO is attributed to enhancing inflammatory pathways with cholesterol and bile acid dysregulation, promoting foam cell formation. Recent studies have revealed several potential therapeutic strategies for reducing TMAO levels and will be the central focus for the current review. However, few have focused on developing rational drug therapeutics and may be due to the gaps in knowledge for understanding the mechanism by which microbial TMA producing enzymes and hepatic flavin-containing monoxygenase (FMO) can work together in preventing elevation of TMAO levels. Therefore, it is critical to understand the advantages of developing a novel rational drug design strategy that manipulates FMO production of TMAO and TMA production by microbial enzymes. This review will focus on the inspection of FMO manipulation, as well as gut microbiota dysbiosis and its influence on metabolic disorders including cardiovascular disease and describe novel potential pharmacological therapeutic development.

Published

2020

5. Gut Metabolite TMAO Induces Synaptic Plasticity Deficits by Promoting Endoplasmic Reticulum Stress

Author

Manoj Govindarajulu, Priyanka D. Pinky, Ian Steinke, Jenna Bloemer, Sindhu Ramesh, Thiruchelvan Kariharan, Robert T. Rella, Subhrajit Bhattacharya, Muralikrishnan Dhanasekaran, Vishnu Suppiramaniam, and Rajesh H. Amin

Subjects

trimethylamine N-oxide (TMAO), synaptic plasticity, long-term potentiation (LTP), endoplasmic reticulum stress (ER stress), insulin resistance, Alzheimer’s disease, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Dysbiosis of gut microbiota is strongly associated with metabolic diseases including diabetes mellitus, obesity, and cardiovascular disease. Recent studies indicate that Trimethylamine N-oxide (TMAO), a gut microbe-dependent metabolite is implicated in the development of age-related cognitive decline. However, the mechanisms of the impact of TMAO on neuronal function has not been elucidated. In the current study, we investigated the relationship between TMAO and deficits in synaptic plasticity in an Alzheimer’s model (3×Tg-AD) and insulin resistance (Leptin deficient db/db) mouse by measuring plasma and brain levels of TMAO. We observed increased TMAO levels in the plasma and brain of both db/db and 3×Tg-AD mice in comparison to wild-type mice. Besides, TMAO levels further increased as mice progressed in age. Deficits in synaptic plasticity, in the form of reduced long-term potentiation (LTP), were noted in both groups of mice in comparison to wild-type mice. To further explore the impact of TMAO on neuronal function, we utilized an ex-vivo model by incubating wild-type hippocampal brain slices with TMAO and found impaired synaptic transmission. We observed that TMAO induced the PERK-EIF2α-ER stress signaling axis in TMAO treated ex-vivo slices as well as in both db/db and 3×Tg-AD mice. Lastly, we also observed altered presynaptic and reduced postsynaptic receptor expression. Our findings suggest that TMAO may induce deficits in synaptic plasticity through the ER stress-mediated PERK signaling pathway. Our results offer novel insight into the mechanism by which TMAO may induce cognitive deficits by promoting ER stress and identifies potential targets for therapeutic intervention.

Published

2020

6. Cardiovascular toxin-induced hyperglycemic and hypoarousal pathology-associated cognitive impairment: an in silico and in vivo validation

Author

S. Karpagam Kumara Sundari, Mansour Alturki, Ian Steinke, Jack Deruiter, Sindhu Ramesh, Manoj Y. Govindarajulu, Mohammed Almaghrabi, Suhrud Pathak, A. Mohamed Rassa, K. A. S. Mohamed Shafeeq, Payton Lowery, Rishi M. Nadar, R. Jayachandra Babu, Jun Ren, K. Reeta Vijaya Rani, Forrest Smith, Timothy Moore, and Muralikrishnan Dhanasekaran

Subjects

General Earth and Planetary Sciences

Published

2022

7. Design of Novel PPAR Agonist for Neurodegenerative Disease

Author

Ian Steinke and Rajesh Amin

Subjects

chemistry.chemical_classification, business.industry, Neurodegeneration, Peroxisome proliferator-activated receptor, Pharmacology, medicine.disease, Partial agonist, PPAR agonist, Energy homeostasis, Nuclear receptor, chemistry, Medicine, business, Receptor, Transcription factor

Abstract

Peroxisome proliferator-activated receptors (PPARs) are ligand-activated transcription factors of the nuclear hormone receptor superfamily comprising three subtypes: PPARα, PPARγ, and PPARβ/δ. The PPAR family of nuclear receptors is centrally involved in regulating whole-body energy homeostasis and metabolic function. Endogenous ligands include free fatty acids, eicosanoids, and leukotrienes. Synthetic ligands developed to serve as full agonists aim at treating diabetes type 2, hyperlipidemia, and other metabolic-related diseases. Further, there has been a developing interest in the role of PPAR agonist’s role in neurodegenerative disease. However, many of these clinically practical therapeutics are associated with harmful effects on human health. Therefore, new approaches have led to a new class of selective PPAR modulators (SPARMs), or partial agonists meet this challenge. In addition, these partial agonists have been observed to show a favorable impact on insulin sensitivity, blood glucose levels, and dyslipidemia with significantly reduced side effects on human health. Partial agonists have been found to display differences in transcriptional and cellular outcomes by acting through distinct structural and dynamic mechanisms within the ligand-binding region when compared to full agonists. Recently, a new focus on PPAR agonists’ class has intensified for neurodegenerative diseases, as new ligands and novel biological roles have emerged particularly for its therapeutic potential in Alzheimer’s disease (AD). The present chapter critically analyzes current PPAR ligands using in silico modeling and the implication of promising new therapeutics in neurodegenerative disorders.

Published

2021

8. Drug Discovery and Development of Novel Therapeutics for Inhibiting TMAO in Models of Atherosclerosis and Diabetes

Author

Nila Ghanei, Manoj Govindarajulu, Rajesh Amin, Juming Zhong, Ian Steinke, and Sieun Yoo

Subjects

0301 basic medicine, Physiology, Mini Review, Metabolite, microbiome, TMAO, 030204 cardiovascular system & hematology, Gut flora, Pharmacology, lcsh:Physiology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Physiology (medical), Diabetes mellitus, medicine, T2D, Microbiome, TMA, Foam cell, lcsh:QP1-981, biology, Cholesterol, business.industry, FMO3, Type 2 Diabetes Mellitus, dysbiosis, CVD, biology.organism_classification, medicine.disease, 030104 developmental biology, chemistry, atherosclerosis, business, Dysbiosis

Abstract

Diabetes mellitus exists as a comorbidity with congestive heart failure (CHF). However, the exact molecular signaling mechanism linking CHF as the major form of mortality from diabetes remains unknown. Type 2 diabetic patients display abnormally high levels of metabolic products associated with gut dysbiosis. One such metabolite, trimethylamine N-oxide (TMAO), has been observed to be directly related with increased incidence of cardiovascular diseases (CVD) in human patients. TMAO a gut-liver metabolite, comes from the metabolic degenerative product trimethylamine (TMA) that is produced from gut microbial metabolism. Elevated levels of TMAO in diabetics and obese patients are observed to have a direct correlation with increased risk for major adverse cardiovascular events. The pro-atherogenic effect of TMAO is attributed to enhancing inflammatory pathways with cholesterol and bile acid dysregulation, promoting foam cell formation. Recent studies have revealed several potential therapeutic strategies for reducing TMAO levels and will be the central focus for the current review. However, few have focused on developing rational drug therapeutics and may be due to the gaps in knowledge for understanding the mechanism by which microbial TMA producing enzymes and hepatic flavin-containing monoxygenase (FMO) can work together in preventing elevation of TMAO levels. Therefore, it is critical to understand the advantages of developing a novel rational drug design strategy that manipulates FMO production of TMAO and TMA production by microbial enzymes. This review will focus on the inspection of FMO manipulation, as well as gut microbiota dysbiosis and its influence on metabolic disorders including cardiovascular disease and describe novel potential pharmacological therapeutic development.

Published

2020