In Silico Development of Combinatorial Therapeutic Approaches Targeting Key Signaling Pathways in Metabolic Syndrome

Maksim Khotimchenko; Nicholas E Brunk; Mark S Hixon; Daniel M Walden; Hypatia Hou; Kaushik Chakravarty; Jyotika Varshney

doi:10.1007/s11095-022-03231-z

In Silico Development of Combinatorial Therapeutic Approaches Targeting Key Signaling Pathways in Metabolic Syndrome

Pharm Res. 2022 Nov;39(11):2937-2950. doi: 10.1007/s11095-022-03231-z. Epub 2022 Mar 21.

Authors

Maksim Khotimchenko¹, Nicholas E Brunk¹, Mark S Hixon¹, Daniel M Walden¹, Hypatia Hou¹, Kaushik Chakravarty², Jyotika Varshney³

Affiliations

¹ VeriSIM Life, 1 Sansome Street, Suite 3500, San Francisco, California, 94104, USA.
² VeriSIM Life, 1 Sansome Street, Suite 3500, San Francisco, California, 94104, USA. kaushik.chakravarty@verisimlife.com.
³ VeriSIM Life, 1 Sansome Street, Suite 3500, San Francisco, California, 94104, USA. jo.varshney@verisimlife.com.

PMID: 35313359
DOI: 10.1007/s11095-022-03231-z

Abstract

Purpose: Dysregulations of key signaling pathways in metabolic syndrome are multifactorial, eventually leading to cardiovascular events. Hyperglycemia in conjunction with dyslipidemia induces insulin resistance and provokes release of proinflammatory cytokines resulting in chronic inflammation, accelerated lipid peroxidation with further development of atherosclerotic alterations and diabetes. We have proposed a novel combinatorial approach using FDA approved compounds targeting IL-17a and DPP4 to ameliorate a significant portion of the clustered clinical risks in patients with metabolic syndrome. In our current research we have modeled the outcomes of metabolic syndrome treatment using two distinct drug classes.

Methods: Targets were chosen based on the clustered clinical risks in metabolic syndrome: dyslipidemia, insulin resistance, impaired glucose control, and chronic inflammation. Drug development platform, BIOiSIM™, was used to narrow down two different drug classes with distinct modes of action and modalities. Pharmacokinetic and pharmacodynamic profiles of the most promising drugs were modeling showing predicted outcomes of combinatorial therapeutic interventions.

Results: Preliminary studies demonstrated that the most promising drugs belong to DPP-4 inhibitors and IL-17A inhibitors. Evogliptin was chosen to be a candidate for regulating glucose control with long term collateral benefit of weight loss and improved lipid profiles. Secukinumab, an IL-17A sequestering agent used in treating psoriasis, was selected as a repurposed candidate to address the sequential inflammatory disorders that follow the first metabolic insult.

Conclusions: Our analysis suggests this novel combinatorial therapeutic approach inducing DPP4 and Il-17a suppression has a high likelihood of ameliorating a significant portion of the clustered clinical risk in metabolic syndrome.

Keywords: Artificial intelligence; Drug repurposing; Glucose metabolism; Inherited metabolic disease; Pharmacotherapy.

MeSH terms

Blood Glucose / metabolism
Dipeptidyl Peptidase 4 / metabolism
Humans
Inflammation
Insulin Resistance*
Interleukin-17
Metabolic Syndrome* / drug therapy
Signal Transduction

Substances

Interleukin-17
Blood Glucose
Dipeptidyl Peptidase 4