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Regulation of structural and functional synapse density by L-threonate through modulation of intraneuronal magnesium concentration.

Neuropharmacology
September 1, 2016
Qifeng Sun et al. (4 authors)
Journal ArticleResearch Support, Non-U.S. Gov'tHuman StudyAnimal StudyMolecular Study
Study Details

Study Goal

The researchers aimed to determine the unique role of threonate in L-TAMS, specifically whether it directly elevates intraneuronal Mg(2+) and why Mg(2+) alone is ineffective for cognitive enhancement.

Results Summary

The study found that threonate elevates CSF threonate levels, increases intracellular Mg(2+), upregulates NR2B-containing NMDAR expression, boosts mitochondrial membrane potential, and enhances synapse density in neurons. These effects were unique to threonate and mediated through glucose transporters.

Population

Young rats, aging rats, Alzheimer's disease model mice, older adults (human clinical trial), cultured hippocampal neurons, and human neural stem cell-derived neurons.

Effective Dosage

Not specified

Duration

Not specified

Interactions

None mentioned

Extracted Claims (10)
InterventionDirectionEndpointPopulationDosageImpactClaim #
Oral administration of the combination of L-threonate (threonate) and magnesium (Mg(2+)) in the form of L-Threonic acid Magnesium salt (L-TAMS)
increase
learning and memory
young rats
-
can enhance
#1
Oral administration of the combination of L-threonate (threonate) and magnesium (Mg(2+)) in the form of L-Threonic acid Magnesium salt (L-TAMS)
decrease
memory decline
aging rats and in Alzheimer's disease model mice
-
prevent
#2
L-TAMS
increase
global cognitive abilities
older adults
-
demonstrate the efficacy in restoring
#3
oral administration of L-TAMS
increase
brain Mg(2+)
intact animals
-
elevation of
#4
oral treatment with L-TAMS
increase
CSF threonate
-
-
elevated
#5
threonate treatment
increase
intracellular Mg(2+) concentration
cultured hippocampal neurons
-
directly induced an increase in
#6
elevating threonate
increase
NR2B-containing NMDAR
-
-
upregulated expression of
#7
elevating threonate
increase
mitochondrial membrane potential (ΔΨm)
-
-
boosted
#8
elevating threonate
increase
functional synapse density
neuronal cultures
-
increased
#9
threonate
increase
synapse density
human neural stem cell-derived neurons
-
was equally effective at upregulating
#10
Abstract

Oral administration of the combination of L-threonate (threonate) and magnesium (Mg(2+)) in the form of L-Threonic acid Magnesium salt (L-TAMS) can enhance learning and memory in young rats and prevent memory decline in aging rats and in Alzheimer's disease model mice. Recent results from a human clinical trial demonstrate the efficacy of L-TAMS in restoring global cognitive abilities of older adults. Previously, we reported that neuronal intracellular Mg(2+) serves as a critical signaling molecule for controlling synapse density, a key factor that determines cognitive ability. The elevation of brain Mg(2+) by oral administration of L-TAMS in intact animals plays a significant role in mediating the therapeutic effects of L-TAMS. The current study sought to elucidate the unique role of threonate. We aimed to understand if threonate acts directly to elevate intraneuronal Mg(2+), and why Mg(2+) given without threonate is ineffective for enhancing learning and memory ability. We discovered that threonate is naturally present in cerebrospinal fluid (CSF) and oral treatment with L-TAMS elevated CSF threonate. In cultured hippocampal neurons, threonate treatment directly induced an increase in intracellular Mg(2+) concentration. Functionally, elevating threonate upregulated expression of NR2B-containing NMDAR, boosted mitochondrial membrane potential (ΔΨm), and increased functional synapse density in neuronal cultures. These effects are unique to threonate, as other common Mg(2+) anions failed to have the same results. Mechanistically, threonate's effects were specifically mediated through glucose transporters (GLUTs). We also evaluated the effects of threonate in human neural stem cell-derived neurons, and found it was equally effective at upregulating synapse density. The current study provides an explanation for why threonate is an essential component of L-TAMS and supports the use of L-TAMS to promote cognitive abilities in human.

Medical Subject Headings (MeSH)
AnimalsAnimals, NewbornButyratesCells, CulturedFetusHippocampusHumansIntracellular FluidMagnesiumMaleNeural Stem CellsNeuronsRatsRats, Sprague-DawleySynapses
Study Links
Quality Scores
SafetyNot Assessed
Efficacy85/10
Quality80/10
Citation Metrics
Total Citations29
Citations/Year3.2
Relative Citation Ratio1.40
NIH Percentile62.6%
Research Impact Scores
APT Score0.75
Weight Score0.96
Normalized Score0.70
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