Dietary Ketosis: Fatty Acids Activate AMPK Energy Circuits Modulating Global Methylation

NCT ID: NCT03319173

Last Updated: 2019-11-12

Basic Information

• Recruitment Status: COMPLETED
• Clinical Phase: NA
• Total Enrollment: 98 participants
• Study Classification: INTERVENTIONAL
• Study Start Date: 2017-10-15
• Study Completion Date: 2018-09-30

Brief Summary

The study explores whether selective memory complaints (SMC), mild cognitive impairment (MCI) and the comorbidity of Metabolic Syndrome symptomatic of peripheral and cerebral hypo-metabolism with corresponding epigenetic shifts in global DNA (deoxyribonucleic acid) methylation (away from nutrient availability and toward biosynthesis) are initiated by chronic metabolic inflexibility, over-activation of the mTOR (mammalian target of rapamycin) pathway, and the deregulation of neural oxidative phosphorylation.

Detailed Description

Nutritional epigenetics denotes gene-diet interactions and highlights the modulatory role of cellular energy status in aging and age-related diseases like cancer, cardiovascular disease (CVD), diabetes and neurodegeneration. Nutrients are epigenetic modifiers; macro and micronutrients regulate the placement and distribution of DNA histone modifiers distinguishing phenotype from genotype. Cellular energy status (AMP/ATP) modulates the regulatory mechanics of DNA methylation via the SAM (S-adenosylmethionine) methlytransferase and the SAH (S-adenosyl homocysteine) methyltransferase inhibitor index. Whole blood histamine and homocysteine levels provide additional information on the status of methylation. Hyperinsulinemia and cellular insulin resistance dysregulate nutrient sensing pathways; perpetual fed-state signaling exacerbates systemic metabolic inflexibility. Chronic elevations in insulin with long-standing impairments in glucose delivery are associated with profound changes in epigenetic expression consequent of hyper-activation of mTOR and inhibition of AMPK kinase pathways. Dietary ketosis is known to govern adaptive mitonuclear energy availability by increasing cellular reduction potential via >AMP/ATP ratio. AMPK activation adapts rRNA synthesis away from fed-state growth/storage toward energy production/release, common to fasted-states. Research suggests that induced and controlled dietary ketogenesis, a fasting mimetic, transcriptionally modifies gene expression thereby attenuating metabolic diseases.

The study will explore whether early stage memory loss (SMC & MCI) and comorbidity of Metabolic Syndrome are symptomatic of peripheral and cerebral hypo-metabolism resultant of sustained cellular insulin resistance. The investigators will attempt to show that consequent to systemic hyperinsulinemia, mitonuclear crosstalk dysregulates the energy sensing kinases, mTOR/AMPK, thereby modifying the intra/extracellular nutrient signaling pathways. The suppression of AMPK, coupled with chronic fed-state signaling, adapts rRNA synthesis away from nutrient availability toward ATP consuming processes. Increased biosynthesis of proteins, lipids and cholesterol with concurrent inhibition of fat oxidation, energy cofactors (NAD+, SAHH) and programmed apoptosis results in the epigenetic drift of methylation toward global gene activation with region-specific silencing of key regulatory/longevity genes, SIRTs (sirtuins), FOX03 and Nrf2. This global shift in energy is marked by suppression of the SAM/SAH methylation index and correlative jumps in whole blood histamine and/or homocysteine. The study explores whether the aforementioned shift in nutrient sensing pathways modulates metabolic inflexibility via energy shunts toward cytosolic, substrate level phosphorylation via activation of PDK (pyruvate dehydrogenase kinase). An insulin resistant energy surplus (<AMP/ATP) fosters low cellular reduction potential, which triggers mitonuclear crosstalk inhibiting oxidative ATP via PDC (pyruvate dehydrogenase complex), the regulatory gateway between anaerobic glycolysis and oxidative mitochondrial respiration. The study will attempt to show that induced and controlled dietary ketosis initiates the spontaneous/favorable release of energy ( >AMP/ATP), activating the AMPK circuitry thereby inhibiting the synthesis/storage of protein, cholesterol and lipids. Thus, a shift in cellular energy from low reduction potential (ATP/NADH) to high reduction potential (AMP/NAD+) attenuates methylation drift evidenced by marked reductions in biosynthesis: fasting lipid profile (TRI., VLDL, LDL, HDL), LP-IR score (particle concentration/size), HgA1c, fasting insulin, HOMA-IR and epigenetic modification of DNA measured by improved methylation index (>SAM/SAH) with correlating reductions in whole blood histamine and/or homocysteine. The resultant change in cerebral glucose metabolism and correlative improvement in SMC/MCI will be assessed by valid clinical measures of cognition: Montreal Cognitive Assessment (MoCA), Brief Visual Memory Test-Revised (BVMT-R) and Rey Auditory Verbal Learning Task (RAVLT) administered at baseline and weeks 2/4/6/8/10/12.

Research Question: Are selective memory complaints (SMC), mild cognitive impairments (MCI) and comorbid Metabolic Syndrome symptomatic of peripheral/cerebral insulin resistance with a resultant epigenetic drift in methylation away from energy production toward anabolic synthesis/storage, initiated and sustained by metabolic inflexibility, aerobic glycolysis and PDK inhibition of oxidative phosphorylation?

Conditions

Mild Cognitive Impairment; Metabolic Syndrome

Study Design

• Allocation Method: RANDOMIZED
• Intervention Model: PARALLEL
• Primary Study Purpose: TREATMENT
• Blinding Strategy: NONE

Study Groups

Experimental group

Dietary interventions for subjects in the experimental group include clinically regulated meal plans designed to facilitate prolonged benign dietary ketosis (BDK) in order to regulate glucose with restored insulin sensitivity focused at reversing the impaired capacity to switch between fat and carbohydrate oxidation. Subjects will consume 3 meals per day with the following approximate macronutrient breakdown per meal: 65% fat, 25% protein, 10% carbohydrate.

Both groups will play the Advanced PEAK brain training games on iPhone, iPad or Android devices for 75 minutes per week.

Group Type: EXPERIMENTAL

Dietary intervention

Intervention Type: BEHAVIORAL

Subjects in the experimental group will receive clinically regulated meal plans designed to facilitate prolonged benign dietary ketosis (BDK) in order to regulate glucose with restored insulin sensitivity focused at reversing the impaired capacity to switch between fat and carbohydrate oxidation.

Subjects in the control group will follow the their current dietary protocol (Standard American Diet-SAD).

Control group

Dietary interventions for subjects in the control group include the subjects' current dietary protocol (Standard American Diet-SAD). Subjects will consume 4-6 small meals per day with the following approximate macronutrient breakdown per meal: 50% carbohydrate, 35% protein, 15% fat.

Both groups will play the Advanced PEAK brain training games on iPhone, iPad or Android devices for 75 minutes per week.

Group Type: ACTIVE_COMPARATOR

Dietary intervention

Intervention Type: BEHAVIORAL

Subjects in the experimental group will receive clinically regulated meal plans designed to facilitate prolonged benign dietary ketosis (BDK) in order to regulate glucose with restored insulin sensitivity focused at reversing the impaired capacity to switch between fat and carbohydrate oxidation.

Subjects in the control group will follow the their current dietary protocol (Standard American Diet-SAD).

Interventions

Dietary intervention

Subjects in the experimental group will receive clinically regulated meal plans designed to facilitate prolonged benign dietary ketosis (BDK) in order to regulate glucose with restored insulin sensitivity focused at reversing the impaired capacity to switch between fat and carbohydrate oxidation.

Subjects in the control group will follow the their current dietary protocol (Standard American Diet-SAD).

Intervention Type: BEHAVIORAL

Eligibility Criteria

Inclusion Criteria

• Male or Female (age 35-80)
• Previously diagnosed with MetS and/or T2DM as measured by possessing at least two of the following physiological measures: type 2 diabetes, BMI > 30, HgA1c > 5.7%, waist/height ratio > .6, fasting glucose > 125 mg/dL
• Subjective Memory Complaints (SCM) - Subjects score > 3 'yes' answers on the Subjective Memory Complaints Questionnaire
• Previously diagnosed with Mild Cognitive Impairment (MCI)

Exclusion Criteria

• Previously diagnosed with Alzheimer's disease (AD), dementia or Parkinson's disease

• Minimum Eligible Age: 35 Years
• Maximum Eligible Age: 80 Years
• Eligible Sex: ALL
• Accepts Healthy Volunteers: Yes

Sponsors

University of Minnesota

OTHER

Sponsor Role: collaborator

Bristlecone Health, Inc.

INDUSTRY

Sponsor Role: lead

Responsible Party

Responsibility Role: SPONSOR

Principal Investigators

Kelly J Gibas, Doctorate

Role: PRINCIPAL_INVESTIGATOR

Bristlecone Health, Inc.

Locations

Bristlecone Health, Inc.

Maple Grove, Minnesota, United States

Countries

United States

Provided Documents

Document Type: Study Protocol

View Document

Document Type: Statistical Analysis Plan

View Document

Other Identifiers

Bristlecone-001

Identifier Type: -

Identifier Source: org_study_id