Description
ACE‑031 peptide, also known as ActRIIB‑IgG1 peptide, appears to be a myostatin inhibitor. In terms of structure, it is a fusion compound consisting of the activin receptor type IIB (ACV2RB) and recombinant immunoglobulin IgG1 FC, which is a form of antibody. Research suggests that this soluble peptide may block the action of circulating myostatin to potentially prevent myostatin from apparently inhibiting the native ACV2RB receptors and thus reducing muscle growth. Myostatin, also known as growth and differentiation factor 8 (GDF8), apparently may be blocked by certain substances termed inhibitors. These inhibitors may target the actions of naturally occurring myostatin, a possible negative regulator of muscle growth primarily found in skeletal muscle tissues. Interestingly, myostatin seemingly has no impact on cardiac or smooth muscle tissues.
The discovery of myostatin dates back to 1997, when it was reportedly identified due to its potential inhibitory action on muscle growth, as observed in comparative murine studies. Myostatin may inhibit the activation of murine satellite cells, which are partially committed stem cells within muscle tissue. Additionally, overexpression of myostatin has been suggested to lead to muscle mass reduction in experimental models. Myostatin is thought to bind with the ActR2B receptors with a high affinity, potentially initiating a signaling cascade involving Smad2/3, which is crucial for muscle mass regulation. Other ligands, such as other GDFs and activins, might also bind to ActR2B and potentially regulate muscle growth. These ligands, along with activin receptors, are part of the transforming growth factor‑beta (TGF‑β) superfamily, which is implicated in controlling tissue growth and differentiation.
ACE‑031 appears to work by binding with any circulating members from the TGF‑β superfamily and, most notably, myostatin. Thus, the ACV2RB receptors in muscle cells remain uninhibited, which is posited to result in the activation of muscle hypertrophy and increase in skeletal muscle tissue size. Besides this, the peptide may have a positive potential for metabolism, fat storage, and bone density.
Chemical Makeup
Molecular Formula: C_{3418}H_{5188}N_{928}O_{1062}S_{38}
Molecular Weight: 77,489.82 g/mol
Other Known Titles: soluble activin type IIB receptor (ActRIIB‑IgG1‑Fc)
Research and Clinical Studies
ACE‑031 and Muscle Cell Hypertrophy
In an experimental setting, which was structured as a double‑blind, placebo‑controlled research study, the potential of ACE‑031 on muscle tissue was investigated, and a pharmacokinetics analysis was conducted. Based on the pharmacokinetic analysis report on ACE‑031, the half‑life (T(½)) was estimated to be between 10 to 15 days. The apparent outcome of this study indicated a potential increase in muscle mass attributed to a single test with ACE‑031.
This conclusion is drawn from observations of changes in muscle tissue, which were quantified using specific measurement techniques such as dual‑energy X‑ray absorptiometry (DEXA) and MRI after 29 days following the exposure of the peptide. The results suggested that there was a noticeable increase in muscle mass. Specifically, a 3.3% increase in total body lean mass and a 5.1% increase in quadriceps femoris muscle volume were noted. More specifically, the researchers commented that “Statistically significant increases in mean total body lean mass (3.3%; P = 0.03, by DXA) and thigh muscle volume (5.1%; P = 0.03, by MRI) were observed at day 29.” Additionally, there were apparent shifts in serum biomarkers, suggesting possible improvements in bone and fat metabolism. Moreover, the scientists also concluded that “Statistically significant changes in serum biomarkers suggest ACE‑031 also improved bone and fat metabolism.”
ACE‑031 and Fat Metabolism
There may be an increased expression of myostatin in obesity models, according to a review of several scientific studies. For instance, in murine models for studying obesity, the levels of myostatin and its receptor ActR2b appeared to be higher than control models. More specifically, in experimental settings, overexpression of myostatin in murine models appears to correlate with decreased muscle mass, decreased myocardial mass, and increased fat mass. This suggests a potential role of myostatin in promoting fat accumulation and reducing muscle mass. Conversely, depletion of myostatin in certain murine models was linked to a reduction in age‑related adipose tissue mass increase and a partial reduction in obesity phenotypes. This suggests that reducing myostatin can mitigate some consequences of obesity. The review also highlights that in mice fed a high‑calorie diet, the absence of myostatin appears to result in reduced fat accumulation.
This was attributed to two mechanisms: potential upregulation of lipolysis and fatty acid oxidation enzymes and apparent promotion of brown (beige) fat formation, which is involved in thermogenesis and fat burning. Consequently, the researchers employed ACE‑031 in control murine models on a high‑fat diet, and the peptide appeared to prevent and reduce obesity.
ACE‑031 and Muscle Contractile Force
Continuous research by scientists has suggested that the potential of the peptide may extend beyond myostatin inhibition. By potentially preventing oxidative stress in muscle tissues, the peptide may improve the capacity of the muscle tissue to generate a force and in turn, preserve energy and stimulate the muscles toward oxidative respiration. These observations were made in murine models and measured using magnetic resonance imaging (MR imaging) and dynamic [31P]‑magnetic resonance spectroscopy ([31P]‑MRS). More specifically, the exposure of ACE‑031 was linked to an apparent increase in muscle volume by 33% without altering the distribution of muscle fiber types. Additionally, there was an observed increase in basal oxygen consumption (by 22%) and energy expenditure (by 23%) in the murine models, indicating a potential rise in metabolic activity. During a standardized fatiguing exercise, murine models exposed to ACE‑031 showed an apparent muscle performance enhancement.
ACE‑031 and Bone Density
Another study explored the potential impact of ACE‑031 on bone tissue in murine models of Duchenne Muscular Dystrophy (DMD), characterized by muscle degeneration and a heightened risk of fractures. The models were divided into groups based on their activity (running or non‑running) and additionally into active or placebo groups. The publication suggested that ACE‑031 led to an apparent increase in both body and muscle weights in sedentary and exercising murine models. Importantly, femoral micro‑CT analysis suggested an increase in bone volume by about 80% and trabecular number by about +70% in the ACE‑031 groups. Histological analysis also indicated a potential reduction in osteoclast numbers and an increase in bone formation. The researchers commented that “Increased bone mass in femurs translated into enhanced bone strength in biomechanical testing as the maximum force and stiffness were significantly elevated” in the ACE‑031 group.
Important Notice
ACE‑031 peptide is available for research and laboratory purposes only. Please review and adhere to our Terms and Conditions before ordering.
References
Campbell C, McMillan HJ, Mah JK, Tarnopolsky M, Selby K, McClure T, Wilson DM, Sherman ML, Escolar D, Attie KM. Myostatin inhibitor ACE‑031 treatment of ambulatory boys with Duchenne muscular dystrophy: Results of a randomized, placebo‑controlled clinical trial. Muscle Nerve. 2017 Apr;55(4):458‑464.
McPherron AC, Lawler AM, Lee SJ. Regulation of skeletal muscle mass in mice by a new TGF‑beta superfamily member. Nature. 1997 May 1;387(6628):83‑90.
Attie KM, Borgstein NG, Yang Y, Condon CH, Wilson DM, Pearsall AE, Kumar R, Willins DA, Seehra JS, Sherman ML. A single ascending‑dose study of muscle regulator ACE‑031 in healthy volunteers. Muscle Nerve. 2013 Mar;47(3):416‑23.
Yang M, Liu C, Jiang N, Liu Y, Luo S, Li C, Zhao H, Han Y, Chen W, Li L, Xiao L, Sun L. Myostatin: a potential therapeutic target for metabolic syndrome. Front Endocrinol (Lausanne).
Zhang C, McFarlane C, Lokireddy S, Masuda S, Ge X, Gluckman PD, Sharma M, Kambadur R. Inhibition of myostatin protects against diet‑induced obesity by enhancing fatty acid oxidation and promoting a brown adipose phenotype in mice.
Béchir N, Pecchi E, Vilmen C, Le Fur Y, Amthor H, Bernard M, Bendahan D, Giannesini B. ActRIIB blockade increases force‑generating capacity and preserves energy supply in exercising mdx mouse muscle in vivo.
Puolakkainen, Tero et al. “Treatment with soluble activin type IIB‑receptor improves bone mass and strength in a mouse model of Duchenne muscular dystrophy.”
