MOTS-C (Mitochondrial Derived Peptide) – 10 mg

MOTS-C is a mitochondrial-derived peptide that plays a key role in regulating cellular energy, metabolism, and mitochondrial function. This 10 mg lyophilized powder is highly purified and stable, making it suitable for research and experimental applications focusing on energy regulation, metabolic optimization, and overall cellular health. MOTS-C has demonstrated potential in supporting glucose metabolism, fatty acid oxidation, and cellular vitality.

Mechanism of Action:

MOTS-C activates AMP-activated protein kinase (AMPK) and other metabolic pathways, enhancing mitochondrial efficiency and promoting fat oxidation. By improving cellular energy utilization, MOTS-C helps regulate glucose, supports endurance, and strengthens overall mitochondrial and cellular function.

Potential Benefits:

1. Cellular Energy & Metabolic Support
Optimizes mitochondrial function and boosts energy production at the cellular level.

2. Fat Metabolism & Body Composition
Encourages fat oxidation, contributing to improved metabolism and body composition.

3. Mitochondrial Health & Cellular Vitality
Supports mitochondrial resilience, enhancing overall cellular function and energy.

4. Exercise Performance & Endurance
May improve stamina and physical performance by increasing energy availability.

5. Anti-Aging & Longevity Research
Supports metabolic balance and cellular maintenance, potentially contributing to healthy aging.

Key Features:

• 10 mg high-purity MOTS-C per vial

• Lyophilized powder for stability and long-term storage

• Targets mitochondrial energy and metabolic pathways

• Ideal for research and experimental studies

Storage & Handling:

• Store in a cool, dry place prior to reconstitution

• Refrigerate after reconstitution to maintain activity

• Protect from light, heat, and moisture

Why Choose Peptides Analytics?

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✔ High Purity Standards

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We deliver to major regions including:

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✔ Research-Only Supply

All peptides are strictly intended for laboratory research use, ensuring compliance with international standards.

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Quality Assurance & Testing

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Who Should Buy MOTS-C Peptide?

Our products are intended for:

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• Qualified professionals

If you plan to Buy MOTS-C Peptide Online For Sale, it is essential that usage remains strictly within controlled research environments.

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Compliance Notice

All products available at Peptides Analytics, including MOTS-C, are strictly intended for research purposes only.

When you Buy MOTS-C Peptide Online For Sale, you acknowledge that:

• The product is not for human consumption
• It is not intended for medical or therapeutic use
• You comply with all applicable laws and regulations

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How to Order

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MOTS-c Research

MOTS-c and Fat Metabolism
Estrogen research in mice models suggests that the availability of the hormone at low levels may increase fat mass and dysfunction of normal adipose tissues. The introduction of MOTS-c in these mice models appeared to increase the prevalence of brown fat and reduce the accumulation of adipose tissue. The peptide, to an extent, may block the adipose dysfunction and inflammation that follows insulin resistance.^[1]

Researchers suggest that a fraction of MOTS-c’s potential action on fat metabolism is mediated via AMP-activated protein kinase (AMPK) pathway activation. The AMPK pathway is activated when cellular energy levels are low, which spurs glucose and fatty acid uptake by cells for metabolism. MOTS-c may act directly on the methionine folate cycle, increasing AICAR levels and AMPK activation. Scientific records in mice studies indicate that in laboratory models of obesity, the peptide is a potentially vital regulator of monoacylglycerol, dicarboxylate, and sphingolipid metabolism. By reducing the activity of these pathways and enhancing beta-oxidation, the peptide may halt fat accumulation. Most of these actions appear to be due to the action of the peptide in the nucleus.^[2] The dysregulation of fat metabolism in mitochondria may possibly cause a lack of fat oxidation, resulting in increased levels of fat circulation as insulin levels increase to flush out lipids from the bloodstream. In addition, there is enhanced deposition of fat and a change in homeostasis through increased insulin levels.^[3] The scientists also note that “The implications of plasma MOTS-c for […] metabolic homeostasis deserve future examination.”

MOTS-c and Muscle Metabolism
Research suggests that MOTS-c possibly functions by targeting skeletal muscle, where it may inhibit the folate cycle and the connected de novo purine biosynthesis pathway, leading to the activation of AMPK. Specifically, MOTS-c may activate AMPK in a manner independent of changes in AMP/ATP ratios. This pathway, in turn, might be crucial for modulating glucose metabolism, fatty acid oxidation, and overall energy expenditure in muscle tissues.

This potential action may be possible by enhancing skeletal muscle response to the activation of AMPK activation, which appears to sequentially increase the expression of glucose transporters. Moreover, this activation does not appear to be dependent on the insulin pathway and may present another means of enhancing muscle cell glucose uptake when insulin is defective or inept. Thus, MOTS-c, according to research in mice, may cause a change in age-related insulin-resistant muscles, with improved glucose uptake in muscle cells.^[4] Such an outcome may enhance muscle cell growth, function, and reduce insulin resistance. The researchers conclude that “MOTS-c has implications in the regulation of obesity, diabetes, […] and longevity, representing an entirely novel mitochondrial signaling mechanism to regulate metabolism within and between cells.” Consequently, the actions of the peptide on muscle tissues may also influence systemic energy balance, as observed by its actions on reducing diet-induced obesity and improving glucose tolerance in murine models. This implies that MOTS-c might be an important modulator of metabolic responses to nutrient intake, potentially offering a mechanism by which mitochondria might exert a more active role in energy homeostasis beyond their traditionally touted bioenergetic functions.^[5]

MOTS-c and Osteoporosis
MOTS-c appears to be functional in type I collagen synthesis by osteoblasts in bone. Studies closely observing osteoblast cells suggest that it may influence the TGF-beta/SMAD pathway that controls the function and survival of osteoblasts. Osteoblasts improve osteoblast survival, thereby bettering the synthesis of type I collagen and its strength and integrity.^[6]

Specifically, MOTS-C appeared to influence key genes involved in collagen synthesis, such as COL1A1 and COL1A2. According to scientific studies, MOTS-c may mitigate osteoporosis by possible bone marrow enhancement and stem cell differentiation via the action of the TGF-beta/SMAD pathway. TGF-β/Smad pathway was activated upon MOTS-c exposure as noted by the upregulation of TGF-β1, TGF-β2, and Smad7 genes. The study also showed that knockdown of TGF-β1 significantly inhibited the osteogenic actions of MOTS-c, indicating that the TGF-β/Smad pathway may be essential for MOTS-c’s potential osteogenic action.

According to these studies, this may result in enhanced osteogenesis, including the enhancement of osteoblast survival and stem cell development.^[7] This was noted due to the observation that the expression of osteogenesis-related genes, such as ALP, Bglap, and Runx2, was observed to increase under MOTS-c exposure. These genes are considered to be critical markers of osteogenic differentiation, suggesting that MOTS-c potentially stimulates the osteoblast differentiation process.

MOTS-c and Cardiovascular Function
A higher risk of endothelial cell dysfunction was reported in research models of coronary angiography. Endothelial cells line the inner wall of blood vessels and are considered vital in regulating blood clotting, blood pressure, and plaque function. Scientific studies report that the peptide does not appear to alter the responsiveness of blood vessels directly; rather it may possibly sharpen endothelial cells to the signaling actions of other molecules like acetylcholine.^[8] Introducing the peptide in mice appeared to improve endothelial, microvascular, and epicardial blood vessel functions. Research records indicate that MDPs alongside the MOTS-c, may function to stave off inflammation and stress in cardiomyocytes. It is assumed that a down-regulation of MDP may cause a risk of the development of cardiovascular diseases. MOTS-c may be vital in reperfusion injury and endothelial functions. The mechanisms by which MOTS-c might exert these actions may involve the activation of AMPK which might theoretically enhance endothelial nitric oxide synthase (eNOS) activity. This activity is considered to be crucial for endothelial-dependent vasodilation. Additionally, MOTS-c might modulate inflammatory pathways, potentially reducing endothelial inflammation, which is a hallmark of endothelial dysfunction.

MOTS-c and Cell Lifespan
A change in glutamate residue for lysine at the 14th position of the protein appears to be a consequence of changes in the gene MOTS-c. Though, it has not yet been determined how this may influence the functional properties of the peptide. Nonetheless, a change in both structure and function of the MOTS-c gene has been hypothesized, which may result in phenomenal cell longevity. In research conducted by Dr. Changhan David Lee—a researcher at the School of Gerontology at USC—Mitochondrial biology asserts the need to prolong cell lifespan and healthspan.^{[4, 5, 9]} Dietary constraints posit the only means of altering mitochondrial function and longevity.

Moreover, it has been proposed that MOTS-c might influence the cell’s aging process by interacting with pathways that regulate levels of nicotinamide adenine dinucleotide (NAD+), a coenzyme that is believed to play a central role in cellular metabolism and is closely linked to cellular aging. By potentially increasing NAD+ levels and engaging in the folate/methionine cycle—a key pathway in cellular metabolism—MOTS-c may contribute to delaying age-related metabolic decline and possibly extending the healthspan of cells in experimental models.^[10]

MOTS-c and Physical Capacity
In studies using murine models, the peptide MOTS-c has been reported to potentially improve physical performance across different age groups.^[11] Data indicates that the peptide may enhance endurance and motor coordination, as indicated in studies by improved performance in treadmill running and rotarod tests, which assess physical endurance and balance, respectively. Importantly, these observed benefits do not seem to be directly linked to changes in weight, implying that MOTS-c might influence physical capabilities through mechanisms other than weight reduction. It is hypothesized that these mechanisms might involve optimizing energy metabolism—how cells convert nutrients into energy—and enhancing metabolic flexibility, which refers to the cell’s ability to adapt fuel utilization based on availability and demand.

MOTS-c might also play a role in regulating the expression of nuclear genes that are considered to be critical for metabolism and proteostasis (the maintenance of protein homeostasis). This regulation may involve modulating skeletal muscle metabolism, which is deemed essential for muscle contraction and energy production, and improving cellular adaptation to metabolic stress, which is the strain cells experience during changes in energy availability. Additionally, the peptide may influence the expression of genes related to heat shock responses—proteins that help protect cells under stressful conditions—and broader metabolic processes in controlled laboratory settings.

There is some data to suggest that this gene regulation is at least partly mediated by the transcription factor HSF1 (Heat Shock Factor 1), which is believed to support cells adapting to stress and maintaining proteostasis. The potential connection between MOTS-c and HSF1 raises the possibility that MOTS-c might enhance cellular resilience to metabolic stress, which could be particularly important for preserving muscle function and overall physical performance as cells age. However, further research is needed to confirm these mechanisms and fully understand how MOTS-c might contribute to these actions.

Disclaimer: The products mentioned are not intended for human or animal consumption. Research chemicals are intended solely for laboratory experimentation and/or in-vitro testing. Bodily introduction of any sort is strictly prohibited by law. All purchases are limited to licensed researchers and/or qualified professionals. All information shared in this article is for educational purposes only.

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