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MOTS-c

Name: MOTS-c
Brand: Peptide Titans
SKU: 549
Availability: InStock

Price range: $219.99 through $429.99

MOTS-c (Mitochondrial Open Reading Frame of the 12S rRNA-c) is a mitochondria-derived peptide studied for its role in cellular energy regulation and metabolic homeostasis. In research settings, it’s explored for interactions with AMPK signaling, glucose metabolism pathways, and stress-response mechanisms related to mitochondrial function. Intended for research use only, not for human or veterinary use.

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Molecular Characteristics

Complete Specifications

CAS Registry Number: Not assigned (mitochondrial-derived peptide)
PubChem CID: Not available
Peptide Classification: Synthetic 16-amino-acid mitochondrial-derived peptide
Molecular Formula: C₁₀₁H₁₅₂N₂₈O₂₂
Molecular Weight: ~2,174.6 Da

Structural Composition

Amino Acid Sequence:
Met-Arg-Trp-Gln-Glu-Met-Gly-Tyr-Ile-Phe-Tyr-Pro-Arg-Lys-Leu-Arg
Length: 16 amino acids

Physical Properties

Appearance: White to off-white lyophilized powder
Solubility: Water, bacteriostatic water, buffered aqueous solutions (e.g., PBS)

Structural & Stability Notes

MOTS-c is a 16-amino-acid peptide encoded within mitochondrial DNA and synthesized as a short mitochondrial-derived peptide. Its compact structure supports aqueous solubility and practical handling under laboratory conditions. The peptide contains multiple basic residues contributing to overall positive charge at physiological pH. As with other short peptides, lyophilized storage and protection from moisture, light exposure, and repeated freeze–thaw cycles help preserve structural integrity and analytical consistency during research applications.

Research Applications

Mitochondrial Signaling and Metabolic Regulation Research

MOTS-c is utilized as a mitochondrial-derived peptide in research studies examining cellular energy sensing and metabolic regulatory signaling pathways. Laboratory investigations focus on its role in:

AMPK Activation Models: Investigation of cellular energy-sensing pathways and downstream metabolic adaptations
Glucose Uptake Signaling Studies: Evaluation of intracellular pathways influencing glucose transport mechanisms
Mitochondrial–Nuclear Communication Research: Analysis of retrograde signaling interactions between mitochondria and nuclear gene expression systems
Second Messenger Pathway Models: Examination of intracellular cascades associated with metabolic stress adaptation
Energy Homeostasis Studies: Investigation of coordinated signaling networks maintaining cellular energy balance

Experimental protocols commonly employ metabolic flux assays, mitochondrial respiration measurements, and gene expression profiling techniques to characterize MOTS-c–mediated cellular responses.

Glucose and Lipid Metabolism Research

MOTS-c has been examined in research contexts involving substrate utilization and metabolic flexibility models. Key areas of investigation include:

Insulin Signaling Interaction Models: Evaluation of cross-talk between energy-sensing pathways and insulin-mediated responses
Fatty Acid Oxidation Studies: Investigation of lipid substrate utilization under metabolic stress conditions
Adipocyte Signaling Research: Analysis of intracellular pathways influencing energy storage and mobilization
Mitochondrial Biogenesis Models: Research into transcriptional regulation associated with mitochondrial adaptation
Metabolic Flexibility Studies: Examination of adaptive substrate switching mechanisms

These studies utilize glucose uptake assays, lipid oxidation measurements, and transcriptional profiling systems to evaluate metabolic signaling outcomes.

Skeletal Muscle and Exercise Physiology Research

MOTS-c has also been explored in research models examining skeletal muscle metabolism and energy-demand adaptation, including:

Muscle Cell Energy Utilization Studies: Evaluation of mitochondrial respiration and ATP production efficiency
Oxidative Stress Response Models: Investigation of redox signaling pathways during metabolic challenge
Gene Expression Adaptation Research: Analysis of transcriptional responses to energetic demand shifts
Substrate Efficiency Studies: Examination of intracellular energy partitioning mechanisms

Laboratory protocols assess mitochondrial function, oxygen consumption rates, and metabolic biomarker expression using biochemical and imaging-based techniques.

Cellular Signaling and Longevity-Associated Research

Additional research applications explore MOTS-c’s influence on intracellular regulatory systems associated with metabolic resilience and adaptive signaling, including:

SIRT and AMPK Interaction Studies: Investigation of coordinated pathways involved in cellular energy sensing
Gene Regulation Profiling: Analysis of nuclear transcriptional responses influenced by mitochondrial signaling
Stress Adaptation Models: Research into signaling pathways activated during metabolic challenge conditions
Integrated Energy Homeostasis Systems: Examination of coordinated signaling networks maintaining metabolic equilibrium

Research in this domain focuses on understanding how MOTS-c influences mitochondrial-derived signaling, metabolic regulation pathways, and cellular adaptive responses under controlled experimental conditions.

Laboratory Handling and Storage Protocols

Lyophilized Powder Storage

Store at –20°C to –80°C in the original, sealed vial
Protect from light exposure and moisture
A desiccated storage environment is recommended
Stability data suggests extended stability when stored at −20 °C or below.

Reconstitution Guidelines

Reconstitute using sterile water, bacteriostatic water (0.9% benzyl alcohol), or an appropriate laboratory buffer
Introduce solvent slowly along the vial wall to minimize foaming
Mix using gentle swirling; avoid vigorous agitation or shaking
Allow complete dissolution prior to use (typically 1–2 minutes)
Ensure the final solution is within a physiologically neutral pH range appropriate for laboratory use

Reconstituted Solution Storage

Short-term storage: Up to 7 days at 4°C
Long-term storage: Store at –20°C in aliquots
Use single-use aliquots to preserve peptide integrity
Minimize freeze–thaw cycles; single-use aliquots are strongly recommended

Stability Characteristics

MOTS-c is a synthetic mitochondrial-derived peptide research compound that demonstrates stable handling characteristics when managed according to standard peptide laboratory protocols. Proper cold storage of the lyophilized material, careful reconstitution, and minimized freeze–thaw exposure help preserve structural integrity and solubility. When handled appropriately, MOTS-c supports consistent use in in vitro and analytical research applications.

Frequently Asked Questions

What is MOTS-c?

MOTS-c is a short peptide encoded within mitochondrial DNA and classified as a mitochondrial-derived peptide (MDP). It is used in research to investigate mitochondrial communication and metabolic signaling pathways.

What is MOTS-c commonly researched for?

In laboratory and preclinical models, MOTS-c is studied for:

Mitochondrial stress-response signaling
AMPK pathway interaction research
Metabolic regulation models
Cellular energy homeostasis studies
Exercise-response and metabolic adaptation investigations

All applications are exploratory and conducted in controlled research environments.

Is MOTS-c a naturally occurring peptide?

Yes. MOTS-c is naturally encoded within mitochondrial DNA. Synthetic MOTS-c used in research replicates this endogenous peptide sequence for experimental investigation.

How does MOTS-c differ from traditional peptides?

Unlike nuclear DNA–encoded peptides, MOTS-c is derived from mitochondrial DNA. It is studied for its potential role in mitochondrial–nuclear communication and metabolic regulation mechanisms in research models.

How is MOTS-c supplied?

MOTS-c is typically supplied as a lyophilized (freeze-dried) powder in sealed research vials to preserve stability during storage and shipment.

How should unreconstituted MOTS-c be stored?

Lyophilized MOTS-c should be stored:

Long-term: −20 °C to −80 °C
Short-term: 2–8 °C

Keep vials sealed and protected from light and moisture until use.

How should reconstituted MOTS-c be handled and stored?

Once reconstituted:

Store at 2–8 °C for short-term laboratory use
For extended storage, aliquot and freeze at −20 °C or below
Minimize freeze–thaw cycles using single-use aliquots
Gently swirl to mix; avoid vigorous agitation

Does MOTS-c require a Certificate of Analysis (COA)?

Yes. A Certificate of Analysis (COA) should be available for each batch, verifying the identity and purity of each peptide component within the blend to ensure research quality and traceability.

Is MOTS-c FDA-approved?

No. MOTS-c is not FDA-approved as a drug, supplement, or therapeutic product. It is sold exclusively as a research compound and must not be marketed or used for diagnostic, therapeutic, or consumption purposes.

⚠️ Research Use Only

This product is not for human consumption. It is sold strictly for research and educational purposes and is not intended to diagnose, treat, cure, or prevent any disease.

Any clinical data or research information referenced on this page is derived from peer-reviewed scientific literature and official publications. This information is provided for educational reference only and does not constitute medical advice or product claims.

By purchasing this product, you acknowledge that you are a qualified researcher and agree to use it in full compliance with all applicable laws and regulations.