Overview

IGF proteins appear to exert potential via binding with IGF-1 receptors; however, researchers posit that these IGF binding proteins, including Receptor Grade IGF-1 LR3, may function either via IGF receptor-dependent mechanism or via IGF-independent mechanisms.⁽¹⁾⁽⁴⁾

A study⁽¹⁾ was conducted where a murine model was exposed to the endogenous IGF-1 with IGF-1 LR3. During this study, it was suggested that upon exposure, the synthetic protein exhibited the potential to quickly clear the serum and distribute into tissues. Increased concentrations of the IGF-1 LR3 tracer were apparently detected in specific organs, including the kidneys, ovaries, and adrenal glands, in mouse models. This distribution pattern indicates that organs critical to metabolism and reproductive processes might have differing abilities to absorb or retain IGF-1 LR3 compared to IGF-I. It is proposed that these variations might arise due to IGF-1 LR3’s reduced tendency to bind with IGFBPs. IGFBPs are proteins that regulate the availability of IGFs in circulation, influencing their interaction with various tissues. The decreased binding of IGF-1 LR3 to IGFBPs may affect its bioavailability and interactions with specific tissues in research settings. Researchers suggest Receptor Grade IGF-1 LR3 has the potential to induce a signaling mechanism in the organism, either via autocrine mode (where the tissue cell stimulates itself) or via paracrine mode (where the tissue cell stimulates the nearby cell). The increased potential bioavailability of these autocrine and paracrine IGF-1 LR3 proteins may prove vital to inducing any possible action.