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MOTS-c

Mitochondrial-derived peptide

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1

vial

10mg

Lyophilized powder

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99%+

MOTS-c a Mitochondrial-Derived Peptide for Mitochondrial Genetics, Metabolic Regulation, and Intracellular Signalling Networks.

$66.00

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Form
Lyophilized
Molecular Formula
C101H152N28O22S2
Molecular Weight
2174.6 g/mol
CAS Number
1627580-64-6
PubChem CID
146675088
Research Data
Circulating MOTS-c Exercise Response
Human plasma MOTS-c relative to pre-exercise baseline, n=10 healthy young men
Literature
Cellular Ratio
Final Sprint-Stage Completion
Young-mouse treadmill study after 10 days; final 23 m/min stage
Activity Profile
MOTS-c Research Profile
Mechanism
Cellular Pathway
01
Folate-AICAR-AMPK Cascade
MOTS-c is encoded within mitochondrial 12S rRNA and expressed as a 16-amino-acid peptide.
02
Nuclear Translocation & Stress Gene Regulation
Research links MOTS-c signaling with folate-purine metabolism, AICAR accumulation, and AMPK activation.
03
Age-Dependent Physical Performance Regulation
Under metabolic stress, MOTS-c can translocate to the nucleus and participate in adaptive gene regulation.
04
Muscle and Exercise Adaptation
Studies examine circulating MOTS-c during exercise and its effects on skeletal-muscle homeostasis and physical performance.
Metabolic Network
Biosynthesis Map
Folate-AICAR-AMPK Cascade
MOTS-c is encoded within mitochondrial 12S rRNA and expressed…
Nuclear Translocation & Stress Gene Regulation
Research links MOTS-c signaling with folate-purine metabolism, AICAR accumulation,…
Age-Dependent Physical Performance Regulation
Under metabolic stress, MOTS-c can translocate to the nucleus…
Muscle and Exercise Adaptation
Studies examine circulating MOTS-c during exercise and its effects…
Repair Systems
Stress
Mitochondria
Energy
 MOTS-c CENTRAL HUB
Sequence Analysis
Amino Acid Sequence
Single-letter residue map colored by physicochemical property class. Hover any residue for full name and position.
M R W Q E M G Y I F Y P R K L R
16Residues
2174.6 g/molMol. Weight
+3Net Charge
4Basic
1Acidic
■ Hydrophobic ■ Polar ■ Positively Charged ■ Negatively Charged ■ Glycine
Research Focus
MOTS-c Research Application Scope
Primary research areas
Product Data
Compound Identity
Product NameMOTS-c | Mitochondrial ORF 12S rRNA-c
Functional ClassMetabolic signaling peptide / AMPK-associated
FormLyophilized
Purity99%+
Content10mg
Count1 vial
Research UseFor in vitro and laboratory research use only. Not for human consumption.
Specifications
Technical Specs
CAS Number1627580-64-6
Molecular Weight2174.6 g/mol
Molecular FormulaC101H152N28O22S2
PubChem CID146675088
AppearanceWhite to off-white lyophilized powder
Storage-20°C long-term
Formulation Reference
Anatomy of a Peptide
A reference guide to the components of a lyophilized research peptide — from the active sequence to the excipients, solvents, buffers, and stabilizers used in formulation.
Active Peptide 2 items
Synthetic Amino Acid Sequence
The primary chain of amino acids synthesized via solid-phase peptide synthesis (SPPS). Defined by sequence length and molecular weight.
Peptide Modifications
Acetylation (N-terminus), amidation (C-terminus), PEGylation, or cyclization applied to improve stability, receptor binding, or half-life.
Excipients 4 items
Mannitol
Sugar alcohol bulking agent that forms an elegant lyophilized cake, aids reconstitution, and provides structural matrix during freeze-drying.
Trehalose
Non-reducing disaccharide that stabilizes peptide secondary structure by replacing water molecules through hydrogen bonding during dehydration.
Sucrose
Disaccharide used as a lyoprotectant and tonicity agent. Forms an amorphous glassy matrix that immobilizes the peptide and prevents aggregation.
Glycine
Amino acid bulking agent used in lyophilization. Crystallizes to provide mechanical strength to the freeze-dried cake structure.
Reconstitution Solvents 4 items
Bacteriostatic Water (BAC Water)
Sterile water containing 0.9% benzyl alcohol as a preservative. Preferred for multi-dose vials — inhibits microbial growth after initial puncture.
Sterile Water for Injection
USP-grade water, pyrogen-free, without preservatives. Used for single-dose preparations or when benzyl alcohol sensitivity is a concern.
Acetic Acid Solution (0.1–1%)
Dilute acid used for peptides with poor aqueous solubility at neutral pH. Protonates basic residues to improve dissolution.
Sodium Chloride 0.9%
Isotonic saline diluent. Provides physiological osmolality (~308 mOsm/L) and can improve stability of certain charged peptides.
Buffer Systems 4 items
Phosphate Buffered Saline (PBS)
Maintains pH 7.2–7.4. Composed of sodium phosphate dibasic, potassium phosphate monobasic, NaCl, and KCl. Mimics physiological ionic strength.
Acetate Buffer
Effective pH range 3.7–5.6. Composed of acetic acid and sodium acetate. Ideal for acidic peptides and those requiring lower pH for solubility.
Citrate Buffer
Effective pH range 3.0–6.2. Offers strong buffering capacity and metal-chelating properties. Used when oxidation-sensitive residues (Met, Cys) are present.
Histidine Buffer
Effective pH range 5.5–7.0. Low ionic strength, minimal interaction with peptides. Increasingly preferred in modern biopharmaceutical formulations.
Lyoprotectants & Cryoprotectants 3 items
Trehalose / Sucrose (Lyoprotectant)
Protect peptide conformation during the drying phase of lyophilization by forming hydrogen bonds that substitute for water molecules around the peptide.
Glycerol (Cryoprotectant)
Polyol that depresses the freezing point and reduces ice crystal formation, preventing mechanical damage to peptide structure during freezing steps.
Polyethylene Glycol (PEG)
Hydrophilic polymer that provides steric stabilization, reduces aggregation, and can serve as both cryoprotectant and solubility enhancer.
Preservatives & Antimicrobials 3 items
Benzyl Alcohol (0.9%)
Aromatic alcohol preservative in bacteriostatic water. Acts as antimicrobial agent by disrupting microbial cell membranes. Standard for multi-use vials.
Methyl / Propyl Parabens
Broad-spectrum antimicrobial preservatives effective against fungi and bacteria. Used in some peptide formulations where benzyl alcohol is incompatible.
Phenol (0.5%)
Bacteriostatic preservative used in certain injectable peptide formulations. Also acts as a conformational stabilizer for some peptide structures.
Counter Ions & Salt Forms 3 items
Trifluoroacetate (TFA)
Most common counter ion from RP-HPLC purification. Forms TFA salt with basic residues (Lys, Arg, His). May affect bioassay results and cell toxicity.
Acetate
Milder alternative to TFA obtained via ion exchange. Lower cytotoxicity, preferred for cell-based research assays and in vivo studies.
Hydrochloride (HCl)
Chloride salt form, sometimes used for improved stability or specific solubility profiles. Common in pharmaceutical-grade peptide preparations.
Chelating Agents 2 items
EDTA (Disodium)
Chelates divalent metal ions (Cu²⁺, Fe²⁺, Zn²⁺) that catalyze oxidative degradation of methionine and cysteine residues in peptides.
Citric Acid
Natural chelator with moderate metal-binding capacity. Dual function as buffer component and oxidation inhibitor in peptide formulations.
Antioxidants & Stabilizers 3 items
L-Methionine
Free methionine added as a sacrificial antioxidant. Preferentially oxidizes before methionine residues within the peptide chain.
Ascorbic Acid
Water-soluble antioxidant that scavenges reactive oxygen species. Used at low concentrations to prevent oxidative peptide degradation.
Polysorbate 20 / 80
Non-ionic surfactants that prevent surface adsorption and aggregation of peptides at air-liquid and container-liquid interfaces.
Preparation Tool
Reconstitution Calculator
Enter your target working concentration to calculate the exact solvent volume needed for this vial.
mg
Recommended solvents
Bacteriostatic Water Sterile Water for Injection Acetic Acid 0.1% Sodium Chloride 0.9%
Product Specs
Solubility Profile
WaterHighly soluble
Acidified WaterHighly soluble
DMSOHighly soluble
EthanolModerate
Lipid solventsPoor compatibility
Product Specs
Storage Specs
Lyophilized2–8°C preferred
Long-term−20°C recommended
Light SensitivityModerate
MoistureHigh sensitivity
StabilityStable when dry
ContainerSterile sealed vial
Literature
Research Citations
[1]Lee C, Zeng J, Drew BG, Sallam T, Martin-Montalvo A, Wan J, Kim SJ, Mehta H, Hevener AL, de Cabo R, Cohen P. The mitochondrial-derived peptide MOTS-c promotes metabolic homeostasis and reduces obesity and insulin resistance. Cell Metab. 2015;21(3):443-454.
[2]Reynolds JC, Lai RW, Woodhead JST, Joly JH, Mitchell CJ, Cameron-Smith D, Lu R, Cohen P, Graham NA, Benayoun BA, Merry TL, Lee C. MOTS-c is an exercise-induced mitochondrial-encoded regulator of age-dependent physical decline and muscle homeostasis. Nat Commun. 2021;12(1):470.
[3]Kim KH, Son JM, Benayoun BA, Lee C. The Mitochondrial-Encoded Peptide MOTS-c Translocates to the Nucleus to Regulate Nuclear Gene Expression in Response to Metabolic Stress. Cell Metab. 2018;28(3):516-524.e7.
[4]Ming W, Xu W, Zhang W, Zhuang H, Lu F, Shang J, Zhang F, Zhu X, Peng J, Li D. Mitochondria related peptide MOTS-c suppresses ovariectomy-induced bone loss via AMPK activation. Biochem Biophys Res Commun. 2016;476(4):412-419.
[5]Wan W, You Z, Zhou L, Xu Y, Peng C, Zhou T, Yi C, Shi Y, Liu W. Mitochondria-derived peptide MOTS-c: effects and mechanisms related to stress, metabolism and aging. J Transl Med. 2023;21(1):36.
Catalogue Pathway
Related Systems
Use this for internal linking, adjacent products, and quick route-back buttons.
METABOLIC SIGNALING
SLU-PP-332
Related research context for exercise-mimetic signaling, mitochondrial function, and metabolic adaptation.
CELLULAR ENERGY
NAD+
Adjacent research system for cellular redox balance, energy metabolism, and stress-response pathways.
NAD+ PRECURSOR
NMN
Companion catalogue item for NAD+ precursor availability and metabolic research comparisons.
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Important Notice
Research Use Only

AminoBox products are supplied for research, analytical, and laboratory use only. Product information is provided for educational and technical reference and does not constitute medical advice. Products are not intended to diagnose, treat, cure, or prevent any disease.

Product Composition

Property Specification
Product Name MOTS-c
Full Name Mitochondrial Open Reading Frame of the 12S rRNA-c
Peptide Content 10mg
Peptide Class Mitochondrial-derived peptide (MDP)
Physical Form Lyophilized powder
Appearance White to off-white lyophilized powder
Purity Typically ≥98–99%
Research Category Metabolic & mitochondrial research

MOTS-c is classified as a mitochondrial-derived peptide encoded from mitochondrial DNA rather than nuclear DNA.

Molecular Information

Property Specification
Molecular Formula C101H152N28O22S2
Molecular Weight 2174.6 g/mol
CAS Number 1627580-64-6
PubChem CID 146675088
Amino Acid Sequence MRWQEMGYIFYPRKLR
Peptide Length 16 amino acids
Compound Type Synthetic mitochondrial peptide analogue
Encoding Origin Mitochondrial 12S rRNA gene

The published peptide sequence for is MRWQEMGYIFYPRKLR.

Structural Classification

Category Description
Compound Type Mitochondrial-derived peptide
Functional Class Metabolic signaling peptide
Biological Focus Cellular energy and metabolic adaptation research
Mechanistic Focus AMPK activation and mitochondrial signaling
Chemical Family Bioactive mitochondrial peptide

Mechanism Research Profile

Research Focus Description
AMPK Signaling Investigated for activation of metabolic regulatory pathways
Mitochondrial Function Studied in mitochondrial efficiency and energy signaling models
Glucose Metabolism Explored for glucose uptake and insulin sensitivity pathways
Fat Oxidation Investigated in metabolic flexibility and fatty acid utilization
Exercise Mimetic Research Studied for exercise-associated cellular signaling effects

Research literature commonly investigates MOTS-c for AMPK activation and mitochondrial metabolic regulation.

Research Areas Commonly Associated

Research Area Focus
Metabolic Research Energy utilization and glucose signaling
Mitochondrial Biology Cellular bioenergetics and mitochondrial adaptation
Longevity Biology Age-associated metabolic pathways
Exercise Physiology Research Endurance and metabolic adaptation signaling
Cellular Stress Research Adaptive stress response pathways

Solubility Profile

Solvent Solubility
Water Soluble
DMSO Highly soluble
Bacteriostatic Water Compatible for reconstitution
Sterile Water Compatible
Ethanol Insoluble

Published laboratory data describes MOTS-c as water soluble and highly soluble in DMSO.

Storage Specifications

Parameter Recommendation
Lyophilized Storage -20°C preferred
Reconstituted Storage 2–8°C refrigerated
Light Sensitivity Moderate
Moisture Sensitivity High
Stability Stable in dry lyophilized form
Container Type Sterile amber vial

Technical Characteristics

Feature Notes
Delivery Format Lyophilized peptide
Hydrophilicity Hydrophilic peptide structure
Encoded Origin Mitochondrial genome encoded
Stability Profile Sensitive to repeated freeze-thaw cycles
Research Use Laboratory research only

The peptide is translated within mitochondrial compartments and subsequently translocated to the nucleus under metabolic stress conditions, where it participates in transcriptional regulation and metabolic adaptation processes.

This dual-compartment behavior places MOTS-c in a distinct category of peptides that function as retrograde signaling molecules, communicating mitochondrial energetic status to nuclear transcriptional machinery.

Mitochondrial-Nuclear Communication Axis

MOTS-c is fundamentally involved in the regulation of the mitochondrial retrograde response, a signaling system in which mitochondria communicate metabolic status to the nucleus to modulate gene expression.

Under conditions of metabolic stress (e.g., nutrient fluctuation, energetic imbalance, or oxidative challenge), MOTS-c translocates from mitochondria into the nucleus and interacts with transcriptional regulators to reprogram cellular metabolism.

This process is characterized by:

  • Activation of adaptive metabolic gene networks
  • Reprioritization of energy utilization pathways
  • Regulation of glucose and lipid metabolic flux
  • Enhancement of cellular stress resilience signaling pathways

This functions as a metabolic stress-response effector peptide, bridging mitochondrial bioenergetics and nuclear gene regulation.

Biochemical Mechanisms and Metabolic Regulation

MOTS-c exerts its biological influence primarily through modulation of intracellular metabolic pathways rather than acting as a classical receptor-ligand peptide.

1. AMPK-Associated Energy Sensing Modulation

MOTS-c is strongly associated with activation of AMP-activated protein kinase (AMPK)-linked pathways. AMPK functions as a master regulator of cellular energy homeostasis, responding to fluctuations in AMP/ATP ratios.

Through AMPK-associated signaling cascades, MOTS-c is linked to:

  • Enhanced glucose uptake regulation
  • Increased fatty acid oxidation signaling
  • Suppression of energy-intensive anabolic pathways during stress
  • Improved metabolic flexibility under energetic constraint conditions

This positions MOTS as a metabolic rheostat modulator, adjusting cellular energy allocation based on intracellular energetic state.

2. Nuclear Translocation and Transcriptional Reprogramming

A defining feature is its ability to translocate to the nucleus under metabolic stress conditions. Once localized in the nucleus, it interacts with stress-responsive transcriptional regulators and influences gene expression networks involved in:

  • Glycolytic pathway regulation
  • Oxidative phosphorylation efficiency
  • Reactive oxygen species (ROS) adaptive response pathways
  • Mitochondrial biogenesis signaling cascades

This nuclear activity highlights MOTS as a mitochondria-encoded epigenetic signaling effector, rather than a purely cytosolic peptide.

3. Metabolic Flexibility and Substrate Utilization Shifts

Experimental systems indicate that MOTS-c influences the balance between glucose and lipid substrate utilization. This is reflected in shifts in:

  • Glycolytic flux regulation
  • Fatty acid β-oxidation signaling pathways
  • Insulin sensitivity-related metabolic signaling networks

These effects suggest MOTS-c plays a role in maintaining metabolic plasticity, allowing cells to adapt to varying energetic and nutrient environments.

Systems Biology and Energetic Network Integration

MOTS-c operates within a broader mitochondrial signaling network that integrates:

  • Mitochondrial DNA-encoded regulatory peptides
  • Nuclear-encoded metabolic enzymes
  • Cellular redox state indicators (NAD⁺/NADH ratios)
  • ATP/AMP energy charge sensing systems
  • Reactive oxygen species signaling gradients

Within this system, MOTS-c functions as a retrograde metabolic signal amplifier, translating mitochondrial status into nuclear transcriptional responses that optimize energy efficiency and stress resilience.

Stress Response Biology and Cellular Adaptation

Under energetic stress conditions, MOTS-c expression and activity are upregulated as part of a broader adaptive response program. This includes:

  • Activation of stress-responsive transcriptional networks
  • Rebalancing of anabolic versus catabolic metabolic pathways
  • Enhancement of mitochondrial efficiency signaling
  • Regulation of oxidative stress response gene clusters

These responses are consistent with a role in cellular survival optimization under metabolic constraint conditions, where energy conservation and efficient resource allocation become critical.

Mitochondrial-Derived Peptides as a Regulatory Class

MOTS-c is part of an expanding family of mitochondrial-derived peptides, including humanin and SHLP peptides. These molecules collectively redefine mitochondria not only as bioenergetic organelles but also as endocrine-like signaling hubs capable of encoding regulatory peptides that influence nuclear gene expression.

This paradigm shift positions MOTS-c within a new biological framework:

  • Mitochondria as genetic signaling systems
  • Peptides as retrograde metabolic messengers
  • Energy metabolism as a transcriptionally regulated network

Age-Associated Decline and Mitochondrial Signaling Efficiency

Emerging research suggests that mitochondrial signaling efficiency, including MOTS-c activity, may decline with age due to:

  • Reduced mitochondrial transcriptional fidelity
  • Accumulation of mitochondrial DNA damage
  • Impaired retrograde signaling responsiveness
  • Dysregulation of energy-sensing pathways

This decline is associated with reduced metabolic flexibility and diminished adaptive capacity under energetic stress conditions.

Genomic and Transcriptomic Influence

Transcriptomic analyses of MOTS-c exposure in experimental systems indicate modulation of gene clusters associated with:

  • Energy metabolism and mitochondrial respiration
  • Stress response and heat shock protein regulation
  • Inflammatory signaling pathways
  • Glucose transport and insulin signaling networks
  • Lipid metabolism and fatty acid oxidation

These effects reinforce its classification as a broad-spectrum metabolic regulatory peptide with systems-level transcriptional influence.

Scientific Reference Table

Research Focus Key Study Link
Discovery of MOTS-c mitochondrial peptide Lee et al., Cell Metabolism (2015) https://pubmed.ncbi.nlm.nih.gov/25738459/
Mitochondrial-derived peptide signaling mechanisms MOTS-c metabolic regulation and stress response https://pubmed.ncbi.nlm.nih.gov/25738459/
AMPK activation and metabolic homeostasis MOTS-c and energy sensing pathways https://pubmed.ncbi.nlm.nih.gov/26873473/
Nuclear translocation under metabolic stress Retrograde signaling mechanisms of MOTS-c https://pubmed.ncbi.nlm.nih.gov/29153822/
Metabolic flexibility and insulin sensitivity pathways MOTS-c in glucose and lipid metabolism regulation https://pubmed.ncbi.nlm.nih.gov/29425489/
Mitochondrial-derived peptides overview Humanin and MOTS-c family regulatory roles https://pubmed.ncbi.nlm.nih.gov/30215692/
Mitochondrial signaling and aging biology MDPs in age-related metabolic decline https://pubmed.ncbi.nlm.nih.gov/31375185/