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Insulin-like growth factor 1

Insulin-like growth factor 1 (IGF-1), also known as somatomedin C, is a single-chain polypeptide hormone structurally homologous to proinsulin, consisting of 70 amino acids with three intramolecular disulfide bridges, and belonging to the insulin-like growth factor family. Discovered in the late 1950s as a mediator of growth hormone (GH) effects on sulfate incorporation into cartilage and formally isolated from human serum in 1976 by Rinderknecht and Humbel due to its insulin-like properties, IGF-1 primarily functions to promote somatic growth, tissue repair, and cellular proliferation and differentiation in response to GH stimulation. IGF-1 is predominantly synthesized in the liver, accounting for approximately 75% of circulating levels through GH-dependent endocrine action, while extrahepatic tissues such as muscle, , and produce it locally for autocrine and paracrine effects. Its is tightly regulated by six high-affinity insulin-like growth factor-binding proteins (IGFBPs), which modulate its interaction with the IGF-1 receptor (IGF-1R), a receptor that activates downstream pathways including PI3K/Akt and MAPK for anabolic and anti-apoptotic signaling. In addition to growth promotion, IGF-1 influences glucose and by enhancing insulin sensitivity, supporting fetal development, , and adult , with deficiencies linked to growth disorders like and excesses associated with or certain cancers. Circulating IGF-1 levels peak during , decline with age, and are influenced by nutritional status, exercise, and endocrine factors, making it a key for axis assessment in clinical settings.

Molecular Structure and Variants

Protein Structure

Insulin-like growth factor 1 (IGF-1) is a single-chain polypeptide composed of 70 , with a calculated molecular weight of 7,649 Da (approximately 7.6 kDa). The mature protein is derived from proteolytic processing of the IGF1 and lacks the and E-domain present in the precursor. The tertiary structure of IGF-1 is stabilized by three intramolecular bridges formed between residues at positions 6-48, 18-61, and 47-52. These bridges are essential for maintaining the compact fold, analogous to those in insulin, and connect the structural domains while preventing unfolding under physiological conditions. IGF-1 is divided into distinct structural domains: the N-terminal B-domain (residues 1-29), the central A-domain (residues 41-62), and the short C-domain (residues 63-70), with a connecting peptide (residues 30-40) linking the B- and A-domains. The B- and A-domains exhibit sequence homology to the corresponding B- and A-chains of proinsulin, sharing approximately 50% identity in these regions, which underlies the structural and functional similarities between IGF-1 and insulin. The crystal structure of human IGF-1, solved by X-ray crystallography at 1.8 Å resolution, displays a compact conformation dominated by three α-helices: one spanning residues Ala8 to Cys18 in the B-domain, and two antiparallel helices in the A-domain from Gly42 to Phe49 and Leu54 to Cys61. These helical elements are connected by loops, with limited β-sheet formation, primarily a short antiparallel β-sheet in the connecting region, contributing to the overall insulin-like fold that positions key residues for receptor interaction. The amino acid sequence of mature IGF-1 is highly conserved across mammalian species, with over 90% identity in the B- and A-domains among primates and rodents, reflecting evolutionary pressure to preserve ligand-receptor specificity. This conservation extends to the disulfide bridge positions and helical cores, ensuring structural integrity and bioactivity from humans to distant mammals like monotremes.

Isoforms and Post-Translational Modifications

The IGF1 gene, located on human chromosome 12q23.2, encodes insulin-like growth factor 1 (IGF-1) through alternative splicing of its six exons, generating multiple mRNA transcripts that produce distinct pro-IGF-1 isoforms. The primary isoforms in humans are pro-IGF-1A (also denoted IGF-1Ea), which includes exons 3 and 4 in the E-domain coding region, and pro-IGF-1B (IGF-1Eb), which incorporates exons 3 and 5 instead. These pro-forms consist of an N-terminal signal peptide, the mature 70-amino-acid IGF-1 sequence, and a C-terminal E-domain peptide that varies between isoforms. A third isoform, pro-IGF-1C (IGF-1Ec), arises from retention of exon 6 elements but is less prevalent in systemic circulation. This splicing diversity allows for tissue-specific regulation of IGF-1 processing and function. Mature IGF-1 is derived from pro-IGF-1 via proteolytic cleavage, primarily by proprotein convertases such as or PACE4, which remove the during secretion and excise the E-domain post-secretion, yielding the bioactive 7.6 kDa polypeptide. The cleavage occurs at conserved dibasic or pentabasic sites within the E-domain, ensuring efficient maturation in the secretory pathway. The resulting E-peptides—Ea from pro-IGF-1A (35 ) and Eb from pro-IGF-1B (also 35 )—are byproducts released into circulation, where they exhibit potential independent bioactivity, including enhancement of IGF-1 receptor-mediated signaling, promotion of , and modulation of myoblast differentiation . For instance, synthetic Ea-peptide has been shown to stimulate in muscle-derived cells independently of mature IGF-1, suggesting paracrine roles in repair. Post-translational modifications of pro-IGF-1 primarily occur in the E-domain and influence stability, secretion, and bioactivity. N-linked glycosylation targets specific residues, such as Asn92 in the Ea-domain of pro-IGF-1A, adding complex oligosaccharides that prevent premature aggregation and facilitate proper folding in the . Defects in this N-glycosylation, as seen in congenital disorders of glycosylation, impair pro-IGF-1 processing and reduce mature IGF-1 bioavailability. Additionally, the E-domain undergoes , particularly at serine or residues, which modulates proteolytic susceptibility and may enhance local retention in tissues. Potential sites, including serines in the E-domain, have been identified but their functional roles remain less characterized, possibly influencing interactions with chaperones during . Mature IGF-1, lacking the E-domain, is notably free of these modifications, preserving its high-affinity binding to receptors. Isoform expression exhibits tissue specificity, reflecting adaptive roles in local versus systemic IGF-1 actions. In the liver, the primary site of endocrine IGF-1 production, pro-IGF-1A transcripts predominate, comprising over 90% of hepatic IGF1 mRNA and supporting circulating mature IGF-1 levels. In contrast, favors pro-IGF-1B and pro-IGF-1C isoforms, which are upregulated during or , enabling autocrine/paracrine effects on without substantially contributing to plasma pools. This differential splicing underscores the isoform-specific contributions to growth homeostasis across tissues.

Biosynthesis and Regulation

Sites of Synthesis

Insulin-like growth factor 1 (IGF-1) is primarily synthesized in the liver by hepatocytes, where it constitutes the major source of circulating IGF-1 in the bloodstream. This hepatic production is potently stimulated by (GH) through the , involving transcription factors such as STAT5 that bind to specific enhancer regions in the IGF1 gene to drive its expression. The IGF1 promoter region is responsive to various hormonal and nutritional cues, including insulin and , which modulate transcription to align IGF-1 output with metabolic demands. In addition to systemic production, IGF-1 is synthesized locally in numerous tissues, functioning primarily as an autocrine or paracrine factor to support tissue-specific growth and repair. Key sites include , where IGF-1 promotes myoblast and ; , particularly in osteoblasts and chondrocytes for matrix synthesis; , influencing neuronal development and neuroendocrine regulation; kidney, contributing to glomerular and tubular function; and gonads, such as testes where it supports . Developmentally, IGF-1 expression patterns shift markedly from fetal to postnatal stages. During fetal life, production occurs at high levels from multiple extrapituitary sites, including and various fetal tissues, to drive intrauterine growth independently of . Postnatally, liver-derived IGF-1 becomes dominant, accounting for the bulk of circulating levels and supporting overall body growth under influence. In vitro studies further demonstrate IGF-1 synthesis capability in diverse cell types, such as dermal fibroblasts, which produce it in response to mechanical or hormonal stimuli, and endothelial cells, including those from vascular or retinal origins, where it supports and .

Hormonal Regulation and Feedback Loops

The primary of insulin-like growth factor 1 (IGF-1) production occurs through (GH) secreted by the , which binds to the (GHR) on hepatocytes in the liver. This binding activates the (JAK2) pathway, leading to phosphorylation and nuclear translocation of the transcription factor , which directly binds to enhancer regions in the IGF1 gene promoter to stimulate transcription. Constitutively active STAT5b mimics GH effects by inducing robust IGF1 mRNA expression, while dominant-negative forms abolish GH-stimulated transcription, underscoring STAT5b's essential role. This hepatic mechanism accounts for the majority of circulating IGF-1, integrating GH pulses into sustained systemic levels. A key negative feedback loop maintains homeostasis in the GH-IGF-1 axis, wherein elevated IGF-1 inhibits secretion at multiple levels. Circulating IGF-1 suppresses GH-releasing hormone (GHRH) from the and enhances release from the , which in turn inhibits pituitary somatotrophs. This feedback reduces GH pulse amplitude and frequency, as demonstrated in studies where IGF-1 infusion lowered endogenous secretion without altering GHRH pulses directly. Additionally, IGF-1 acts locally on pituitary somatotrophs to further dampen release, preventing overproduction. Several hormones modulate IGF-1 synthesis by enhancing or synergizing with GH actions. Insulin potentiates GH-induced IGF-1 production in hepatocytes by increasing GHR expression and sensitizing the JAK-STAT pathway, acting synergistically to enhance IGF1 mRNA levels beyond GH alone. Thyroid hormones, particularly triiodothyronine (T3), amplify GH-stimulated IGF-1 transcription without direct effects, as hypothyroidism reduces hepatic IGF-1 output despite normal GH levels. Sex steroids, including and testosterone, indirectly boost IGF-1 during by augmenting pituitary GH secretion and hepatic responsiveness, with testosterone replacement increasing circulating IGF-1 levels in hypogonadal males. Nutritional status further regulates IGF-1 via metabolic sensing pathways, where adequate and glucose promote synthesis. Amino acid availability activates the pathway in hepatocytes, enhancing translation of IGF1 mRNA and synergizing with to elevate circulating levels by up to 50% during refeeding after . Glucose similarly supports IGF-1 production by maintaining insulin levels and preventing catabolic suppression of the GH-IGF-1 axis. Circadian and pulsatile patterns of release—peaking nocturnally with 5-10 pulses per day—contribute to diurnal IGF-1 rhythms, though IGF-1 levels remain relatively stable due to its longer , with low-amplitude variations aligning with sleep-wake cycles.

Circulation and Binding

Binding Proteins

Insulin-like growth factor binding proteins (IGFBPs) comprise a family of six structurally related proteins (IGFBP-1 through IGFBP-6) that bind IGF-1 with high affinity, thereby regulating its , transport, and access to target s. These proteins modulate IGF-1 activity by either inhibiting its interaction with receptors through or potentiating local effects by stabilizing IGF-1 at tissue sites. Approximately 75% of circulating IGF-1 is bound to IGFBPs in a complex, with the remainder in binary complexes or free form, ensuring controlled delivery and prolonged . IGFBP-3 serves as the predominant binding protein in circulation, accounting for the majority of IGF-1 binding in adults. It forms a stable ternary complex with IGF-1 and the acid-labile subunit (), a liver-derived , which prevents rapid renal clearance and maintains levels of IGF-1. This ~150 kDa complex constitutes about 80% of total circulating IGF-1 in healthy individuals, highlighting IGFBP-3's central role in systemic IGF-1 . The IGFBPs exhibit diverse functions: IGFBP-1, -2, -4, and -6 primarily act in an inhibitory manner by sequestering IGF-1 and limiting its availability to receptors, whereas IGFBP-3 and -5 can potentiate IGF-1 actions through enhanced local delivery and protection from degradation. For instance, IGFBP-1, predominantly expressed in the liver, is rapidly suppressed by insulin, allowing IGF-1 release in response to nutritional status. In contrast, IGFBP-5 associates with components to concentrate IGF-1 at surfaces, amplifying signaling in tissues like and muscle. Regulation of IGFBP bioavailability often involves proteolytic cleavage, particularly by matrix metalloproteinases (MMPs) such as MMP-7, which degrade IGFBPs to liberate free IGF-1 for immediate action. This cleavage is tissue-specific; for example, MMPs in the can fragment IGFBP-3, reducing its inhibitory effect and enabling IGF-1 diffusion to nearby cells. Such mechanisms allow dynamic control of IGF-1 activity in response to physiological demands.

Transport and Half-Life in Blood

In the bloodstream, insulin-like growth factor 1 (IGF-1) exists primarily in bound forms, with approximately 75-80% associated with insulin-like growth factor binding protein 3 (IGFBP-3) in a complex that includes the , about 20% bound to other IGFBPs in binary complexes, and less than 1% circulating as the free, unbound fraction. This free fraction represents the biologically active form capable of readily interacting with surface receptors. Total IGF-1 concentrations in healthy adults typically range from 100 to 300 ng/mL, varying by age, sex, and assay method, while free IGF-1 levels are much lower, often 0.5-2 ng/mL. The pharmacokinetic profile of IGF-1 is markedly influenced by its binding status, with the free form exhibiting a short of about 10-15 minutes due to rapid dissociation and clearance, whereas the ternary complex extends the to 12-15 hours, prolonging systemic availability and protecting against . This extended circulation of the complexed form maintains steady-state levels and facilitates endocrine actions throughout the body. Elimination of IGF-1 primarily occurs via renal clearance of the free and low-molecular-weight bound forms through glomerular filtration, followed by tubular reabsorption and degradation, while larger ternary complexes undergo hepatic uptake and intracellular in the liver. Serum IGF-1 levels exhibit dynamic age-related variations, peaking during (often 300-600 ng/mL) in response to heightened secretion, then declining progressively throughout adulthood to reach approximately 50-70% of peak values by late life, reflecting reduced hepatic production and altered binding dynamics. Measurement of IGF-1 in relies on immunoassays, with total IGF-1 assessed after acid-ethanol or other methods to dissociate binding proteins, enabling quantification via enzyme-linked immunosorbent assay () or chemiluminescent platforms, whereas free IGF-1 is measured using direct or followed by to isolate the unbound fraction. However, measurement of free IGF-1 is challenging due to its instability and potential artifacts from dissociation during processing, making it less commonly used than total IGF-1 assays in . These assays provide critical insights into IGF-1 but require age- and method-specific reference ranges for accurate interpretation.

Mechanism of Action

Receptor Binding and Signaling Pathways

Insulin-like growth factor 1 (IGF-1) primarily binds to the type 1 insulin-like growth factor receptor (IGF-1R), a transmembrane composed of two extracellular alpha subunits and two intracellular beta subunits linked by bonds. This binding occurs with high affinity, characterized by a (Kd) of approximately 0.15 nM, which is substantially greater than IGF-1's affinity for the (IR), where the Kd is around 300 nM. Upon ligand binding, IGF-1 induces a conformational change in the IGF-1R ectodomain, promoting receptor dimerization if not pre-dimerized, and subsequent trans-autophosphorylation of residues in the beta subunits' domains. The autophosphorylated IGF-1R recruits and phosphorylates adaptor proteins such as insulin receptor substrate-1 (IRS-1), which docks with the p85 regulatory subunit of phosphatidylinositol 3-kinase (PI3K). Activated PI3K generates phosphatidylinositol (3,4,5)-trisphosphate (PIP3) from PIP2, recruiting protein kinase B (Akt) to the plasma membrane where it is phosphorylated and activated by PDK1 and mTORC2. The PI3K/Akt pathway promotes cell survival and growth by activating downstream effectors, including mTOR complex 1 (mTORC1), which enhances protein synthesis through phosphorylation of targets like S6 kinase and 4E-BP1, and by inhibiting FOXO transcription factors via their phosphorylation and nuclear exclusion, thereby suppressing pro-apoptotic gene expression. Parallel to the PI3K/Akt cascade, IGF-1R signaling activates the (MAPK)/extracellular signal-regulated kinase (ERK) pathway. Autophosphorylated IGF-1R binds the adaptor protein Shc, which recruits and to activate , leading to sequential of Raf, MEK, and ERK1/2. Phosphorylated ERK translocates to the to regulate transcription factors involved in and , such as Elk-1 and c-Fos. IGF-1R exhibits cross-talk with the through the formation of receptors, which consist of one IGF-1R alpha-beta and one alpha-beta , resulting from co-expression in many types. These receptors bind IGF-1 with high similar to IGF-1R homodimers but show low for insulin, thereby integrating and modulating signaling between the IGF and insulin systems while primarily transducing IGF-1-dependent signals.

Metabolic and Anabolic Effects

Insulin-like growth factor 1 (IGF-1) promotes in target tissues, primarily through the translocation of glucose transporter type 4 () to the cell membrane, albeit with lower potency compared to insulin. This effect occurs via activation of the IGF-1 receptor, which triggers intracellular signaling cascades that facilitate GLUT4 exocytosis in adipocytes and muscle cells. In , IGF-1 enhances glucose transport to support energy demands during growth and repair, contributing to metabolic . IGF-1 exerts potent anabolic effects on muscle and tissues, driving and formation processes essential for and . In , IGF-1 stimulates myoblast proliferation and differentiation, leading to increased muscle fiber size through activation of cells and enhanced protein . For , IGF-1 promotes activity, stimulating formation and mineralization while inhibiting osteoclast-mediated resorption, thereby supporting longitudinal and density. These actions are mediated briefly through pathways like PI3K/Akt, which integrate nutrient sensing with cellular responses. IGF-1 inhibits protein breakdown in muscle by suppressing ubiquitin-proteasome pathways, including the expression of atrophy-related genes such as atrogin-1 and MuRF1, thereby favoring net protein accretion and energy storage. Similarly, IGF-1 attenuates lipolysis in adipose tissue, particularly by counteracting growth hormone-induced fatty acid release through modulation of signaling pathways like PKC and ERK, which promotes lipid storage over mobilization. These inhibitory effects help maintain anabolic balance during periods of nutrient availability. In fetal development, IGF-1 plays a critical role in organ growth and , coordinating transfer and expansion. It enhances placental blood flow and proliferation, facilitating uptake and supporting embryonic , as evidenced by increased organ weights in IGF-1-infused fetal models. IGF-1 also promotes and steroid synthesis in placental cells, ensuring adequate fetal oxygenation and hormonal support for development. Regarding adipogenesis, IGF-1 exhibits dose-dependent effects, promoting and accumulation in preadipocytes at physiological concentrations while potentially limiting excessive formation at higher levels through regulatory feedback. Low to moderate doses stimulate and maturation of cells into adipocytes, increasing mass via enhanced expression of adipogenic markers. This biphasic response helps fine-tune expansion in response to metabolic cues.

Integration with the IGF Axis

The (IGF) axis functions as a coordinated endocrine and paracrine system central to growth regulation, comprising the ligands IGF-1 and IGF-2, the receptor IGF-1R, the non-signaling clearance receptor IGF-2R, and six high-affinity binding proteins (IGFBPs 1–6) that control bioavailability, transport, and stability. IGF-1R binds both IGF-1 and IGF-2 with high affinity to initiate intracellular signaling cascades promoting , , and survival, while IGF-2R selectively binds IGF-2 to facilitate its and , thereby limiting excessive signaling. The IGFBPs, produced by multiple tissues, bind over 90% of circulating IGFs, prolonging their half-life and modulating their access to receptors, thus integrating the axis's activity across developmental stages. IGF-2 exhibits a distinct role in fetal growth, where it is abundantly expressed and imprinted in a parent-of-origin-specific manner, primarily driving embryonic proliferation and independent of stimulation. Unlike IGF-1, which predominates postnatally, IGF-2 signals through IGF-1R for mitogenic effects but also engages IGF-2R to regulate lysosomal targeting of mannose-6-phosphate-containing proteins, influencing fetal nutrient uptake and tissue remodeling. Hybrid receptors formed by IGF-1R and the (IR) further diversify IGF-2 action, particularly the IR-A isoform, enabling IGF-2 to elicit insulin-like metabolic responses in fetal tissues while avoiding . Reciprocal regulation between IGF-1 and IGF-2 occurs during , with IGF-1 modulating IGF-2 in specific tissues to fine-tune trajectories and prevent dysregulation. For instance, elevated IGF-1 levels can suppress IGF-2 transcription in embryonic models, ensuring a transition from fetal to postnatal patterns, while IGF-2 feedback influences local IGF-1 production in developing organs. The IGF axis demonstrates remarkable evolutionary conservation across vertebrates, originating from an ancient insulin/IGF signaling pathway that predates the divergence of jawed vertebrates over 400 million years ago. Core components, including ligand-receptor interactions and IGFBP modulation, are preserved in , amphibians, reptiles, birds, and mammals, underscoring their fundamental role in body size determination, metabolic adaptation, and lifespan regulation. Interactions between the GH-IGF-1 axis and the broader IGF system intensify during , where pulsatile secretion elevates hepatic IGF-1 production, amplifying IGF-1R signaling to orchestrate the growth spurt and skeletal maturation in coordination with gonadal hormones. In , the axis undergoes progressive decline, with reduced pulsatility leading to diminished IGF-1 levels, altered IGFBP profiles favoring IGF-2 dominance, and overall dampened signaling that contributes to , frailty, and metabolic shifts associated with aging.

Clinical Disorders

IGF-1 Deficiency (Laron Syndrome)

Laron syndrome represents a primary form of IGF-1 deficiency caused by growth hormone insensitivity, resulting from mutations in the (GHR) gene located on chromosome 5p13-p12, which lead to impaired signaling and consequently low serum IGF-1 levels despite elevated concentrations. This autosomal recessive disorder was first described in 1966 by Zvi Laron in consanguineous families of Yemenite Jewish origin, highlighting a unique endocrine defect where affected individuals exhibit normal or high but fail to produce adequate IGF-1 in response. The condition manifests as severe postnatal growth failure, with adult heights typically ranging from 110 to 140 cm, underscoring the critical role of the -IGF-1 axis in linear growth. Clinically, Laron syndrome is characterized by profound , central , neonatal or infantile , delayed skeletal maturation, and , often accompanied by distinctive facial features such as a prominent , , and truncal adiposity. arises from reduced IGF-1-mediated and , while stems from altered fat metabolism due to resistance. Other features include small genitalia in males, high-pitched voice, and increased susceptibility to infections, though is generally normal. The disorder is rare, with a global prevalence estimated at less than 1 in individuals, though founder effects result in higher incidence in specific populations, such as Ecuadorian cohorts in the of Loja and El Oro, where up to 50% of females in affected communities may be impacted. Over 70 distinct mutations in the GHR gene have been identified, including deletions, missense, , and splice-site variants, most commonly affecting the extracellular domain and preventing proper receptor dimerization or binding. Animal models of , such as GHR knockout mice generated via targeted disruption of the Ghr gene, recapitulate key human phenotypes including , elevated , reduced IGF-1, increased adiposity, and , providing insights into the pathophysiological mechanisms of GH insensitivity. These mice exhibit extended lifespan and resistance to certain age-related diseases, mirroring observations in human patients and highlighting the broader implications of IGF-1 deficiency. Treatment for Laron syndrome involves recombinant human IGF-1 (rhIGF-1) administered via daily subcutaneous injections, which improves linear growth, muscle strength, and metabolic parameters such as . However, therapy typically results in modest gains in final adult height (approximately 2-5 cm) and requires lifelong administration, with monitoring for side effects like injection-site reactions or .

IGF-1 Excess (Acromegaly and Gigantism)

IGF-1 excess most commonly arises from hypersecretion of (GH) due to pituitary adenomas, which stimulate excessive IGF-1 production in the liver and peripheral tissues. In individuals post-, when epiphyseal growth plates have fused, this results in , characterized by insidious enlargement of soft tissues, bones, and organs without significant linear growth. Conversely, in children and adolescents before , the same /IGF-1 overdrive causes , marked by accelerated linear growth and excessive height. These conditions share the underlying of dysregulated action within the IGF axis, where elevated IGF-1 mediates the anabolic and mitogenic effects of . Clinical manifestations of IGF-1 excess include coarsened facial features such as enlarged nose, lips, and brow; expanded hands and feet; and joint arthropathy due to periarticular overgrowth and . Cardiovascular complications like and are prevalent, alongside metabolic disturbances including and mellitus. In , patients exhibit proportional overgrowth, often reaching heights exceeding 2 meters by adulthood, with similar secondary features emerging later. Diagnosis relies on measuring elevated circulating IGF-1 levels, age- and sex-matched to reference ranges, followed by inadequate suppression of (nadir >0.4 ng/mL with ultrasensitive assays, or BMI-adjusted cutoffs) during an oral . The annual incidence of acromegaly and gigantism combined is estimated at 3-4 cases per million population, with most diagnoses occurring between ages 40 and 50. Treatment aims to normalize IGF-1 levels to mitigate morbidity; transsphenoidal surgical resection of the pituitary adenoma is the first-line approach, achieving biochemical control in 50-70% of microadenoma cases but lower rates for macroadenomas. For persistent elevation, medical therapies include somatostatin analogs (e.g., octreotide or lanreotide) that inhibit GH secretion and reduce IGF-1 by up to 70%, or the GH receptor antagonist pegvisomant, which directly lowers IGF-1 without affecting GH levels. In 2025, the once-daily oral somatostatin receptor ligand paltusotine (PALSONIFY) was approved by the FDA as a first-line therapy for adults with acromegaly who are ineligible for surgery or inadequately controlled. Radiation therapy serves as an adjunct for incomplete surgical responses. A notable historical example is André René Roussimoff, known as , a professional wrestler who grew to 7 feet 4 inches tall due to untreated from a pituitary tumor, exemplifying the profound physical impacts and complications like that can arise.

Diagnostic Applications

Assessment of Growth Hormone Status

Insulin-like growth factor 1 (IGF-1) serves as a primary for evaluating (GH) secretion due to its relatively stable circulating levels, in contrast to GH's pulsatile release and short of approximately 20 minutes. This stability arises from IGF-1's longer of about 12-15 hours and its production primarily in the liver as an integrated response to sustained GH stimulation, making it preferable for assessing overall GH activity over random GH measurements, which are influenced by circadian rhythms, sleep, exercise, and stress. In the diagnosis of GH deficiency (GHD), serum IGF-1 measurement acts as an initial screening tool, with levels below the age- and sex-adjusted indicating possible deficiency, particularly in patients with suggestive clinical features such as in children or reduced muscle mass and in adults. Reference ranges for IGF-1 are established through large studies and vary nonlinearly: levels are low in infancy, rise progressively through childhood to peak during (often 2-3 years earlier in girls than boys), and then decline gradually into adulthood, necessitating adjustments for pubertal status to avoid misinterpretation. For example, prepubertal children typically have IGF-1 values of 50-250 ng/mL, while mid-pubertal adolescents may reach 300-600 ng/mL, with adult ranges further stratified by age (e.g., 70-200 ng/mL in those over 60 years). Confirmation of GHD often requires dynamic stimulation tests to assess GH responsiveness, such as the insulin tolerance test (), glucagon stimulation, or combined GHRH-arginine administration, where peak GH levels below 5 μg/L in adults or 7-10 μg/L in children support the diagnosis; IGF-1 response is evaluated in specific contexts like the IGF-1 generation test, involving low-dose exogenous GH administration (e.g., 0.01-0.03 mg/kg daily for 4-7 days) to measure the incremental rise in IGF-1, which helps differentiate severe GHD from GH insensitivity syndromes. In this test, a subnormal IGF-1 increase (e.g., <50% from baseline) indicates impaired GH bioactivity. The 's clinical practice guidelines for adults recommend measuring IGF-1 as part of the diagnostic for suspected GHD, with levels at or below the normal range for age and sex prompting GH stimulation testing; in patients with three or more pituitary deficiencies, a low IGF-1 alone may confirm GHD without further provocation, though testing is advised if results are equivocal. For pediatric evaluation, guidelines from the Pediatric Endocrine Society and similar bodies emphasize IGF-1 as a supportive but not standalone test due to its variable sensitivity (higher in older children, lower in those under 10 years), recommending integration with GH stimulation tests and clinical assessment for diagnosis. Despite its utility, IGF-1 assessment has limitations, as levels can be confounded by nutritional status (e.g., reduced in due to impaired hepatic synthesis) and liver function (e.g., decreased in from reduced receptor expression), potentially leading to false lows unrelated to secretion. In excess states like , IGF-1 levels are markedly elevated, often exceeding the upper reference limit by 2-3 standard deviations, facilitating diagnosis alongside suppression testing.

Monitoring Liver and Fibrotic Conditions

Insulin-like growth factor 1 (IGF-1) serves as a valuable for monitoring liver health, particularly in conditions involving impaired hepatic synthesis. In patients with , IGF-1 levels are markedly reduced due to diminished production by hepatocytes, reflecting the extent of hepatocellular dysfunction. This reduction correlates directly with disease severity, as lower serum IGF-1 concentrations are observed in advanced stages compared to earlier ones, and they parallel declines in other hepatic synthetic markers like and clotting factors. IGF-1 measurement aids in the surveillance of non-alcoholic fatty liver disease (NAFLD) and by indicating progression toward and . In NAFLD, circulating IGF-1 levels inversely associate with histologic severity, including and , and low levels predict advanced fibrotic stages independent of . Similarly, in chronic such as C or B, reduced IGF-1 reflects ongoing and , supporting its role in non-invasive disease tracking alongside and other serologic tests. The prognostic utility of IGF-1 extends to predicting complications in , where low levels signal increased risk of and (HCC). Patients with and serum IGF-1 below established thresholds exhibit higher rates of portal hypertension-related events, such as variceal bleeding, and worse overall survival. In HCC cohorts, diminished IGF-1 independently forecasts tumor progression and mortality, often outperforming traditional scores when integrated into risk models. Meta-analyses and cohort studies affirm IGF-1 as a non-invasive marker of liver , particularly when combined with the enhanced liver (ELF) score, which incorporates matrix metalloproteinases and other fibrogenic indicators. A of NAFLD patients demonstrated that low IGF-1 levels enhance the ELF score's accuracy for detecting advanced , with combined models achieving superior area under the curve values for staging. These findings position IGF-1 as a complementary tool in assessment, reducing reliance on invasive biopsies in at-risk populations. Emerging research highlights IGF-1's role in fibrotic conditions beyond the liver, such as (IPF), where local production in lung tissue drives pathogenesis. In IPF, upregulated IGF-1 expression in fibroblasts and epithelial cells promotes deposition via the PI3K/AKT pathway, contributing to progressive scarring independent of systemic levels. This local dysregulation suggests potential for IGF-1-targeted therapies in monitoring and intervention.

Factors Affecting IGF-1 Levels

Physiological Causes of Elevation

Insulin-like growth factor 1 (IGF-1) levels rise significantly during , driven by the surge in gonadal steroids such as estrogens and androgens, which enhance (GH) sensitivity and secretion. This pubertal increase in IGF-1, primarily produced in the liver under GH stimulation, supports the rapid skeletal growth and maturation observed in adolescents, with peak concentrations occurring mid-puberty before declining to adult levels post-sexual maturation. Physical exercise, particularly resistance training, induces acute and chronic elevations in IGF-1 through both systemic and local mechanisms. Resistance exercise stimulates systemic IGF-1 release via activation, while locally in , it upregulates IGF-1 mRNA expression and production of isoforms like mechano-growth factor (MGF), promoting and repair independent of circulating levels. These exercise-induced changes are more pronounced in young individuals and contribute to anabolic adaptations without requiring exogenous supplementation. During pregnancy, maternal IGF-1 concentrations progressively increase to support fetal growth and placental development, reaching peak levels in the third trimester due to elevated GH variant production by the placenta. This rise facilitates nutrient transfer and fetal tissue accretion, with higher maternal IGF-1 correlating with greater birth weight and reduced risk of intrauterine growth restriction. Fetal IGF-1 also elevates in response, though to a lesser extent, underscoring the axis's role in gestational physiology. High-protein diets elevate IGF-1 synthesis by providing abundant , which synergize with to enhance hepatic and peripheral production. Essential , such as and , directly stimulate IGF-1 and protein turnover, leading to higher circulating levels that support muscle maintenance and overall in healthy adults. This dietary effect is particularly evident in populations with adequate caloric intake, where protein comprises 20-30% of energy, contrasting with reductions seen in protein restriction. IGF-1 exhibits diurnal variation, with levels peaking during and shortly after nocturnal in alignment with pulsatile secretion, which predominantly occurs during stages. This temporal pattern reflects the liver's integrated response to overnight GH pulses, resulting in modestly higher morning IGF-1 concentrations that sustain daytime metabolic functions, though the variation is less pronounced than for GH due to IGF-1's longer . Extended sleep duration further amplifies these elevations, linking rest to optimized IGF-1 .

Pathological and Lifestyle Causes of Reduction

Malnutrition, particularly in conditions like , leads to reduced IGF-1 synthesis primarily through acquired (GH) resistance and impaired hepatic production, despite elevated GH levels as a compensatory response to energy deficit. In , this results in persistently low circulating IGF-1 concentrations, which correlate with the severity of weight loss and contribute to delayed growth and loss during recovery. Similarly, broader states of chronic undernutrition suppress the GH-IGF-1 axis by limiting substrate availability for IGF-1 production in the liver, exacerbating catabolic processes. Chronic kidney disease (CKD) impairs IGF-1 homeostasis through disrupted renal clearance and reduced production, leading to altered serum levels that vary by disease stage. In early CKD, total IGF-1 may remain normal, but free IGF-1 bioavailability decreases due to elevated inhibitory proteins like IGFBP-3 and IGFBP-1, which accumulate from impaired renal . As CKD progresses to end-stage renal disease, serum IGF-1 levels become slightly reduced, compounded by uremic toxins that further suppress hepatic IGF-1 secretion and contribute to muscle wasting and . This dysregulation highlights the kidney's role in modulating IGF-1 dynamics, independent of primary deficiency. Aging is associated with a progressive decline in IGF-1 levels, averaging 10-20% per decade after age 30, driven by reduced secretion from the pituitary and diminished hepatic responsiveness to . This age-related reduction, most pronounced between ages 21 and 50 before plateauing, correlates with decreased and increased frailty, though it may confer protective effects against certain age-related diseases. The decline stems from somatopause, a natural attenuation of the -IGF-1 axis, rather than overt pathology, but it exacerbates and metabolic changes in older adults. Lifestyle factors such as and contribute to IGF-1 reduction by elevating , which directly inhibits IGF-1 synthesis in hepatocytes and peripheral tissues. Chronic cigarette is linked to significantly lower serum IGF-1 levels, independent of age or , possibly through nicotine-induced and suppression of the GH-IGF-1 axis. Concurrently, increases diurnal secretion, amplifying this inhibitory effect. similarly raises , which antagonizes IGF-1 production by downregulating GH receptor expression and promoting , as observed in prolonged psychological strain. Certain medications, including glucocorticoids and oral therapies, pharmacologically lower IGF-1 levels through mechanisms mimicking or enhancing cortisol's suppressive actions. Exogenous glucocorticoids, such as , inhibit hepatic IGF-1 gene expression and reduce GH-stimulated production, leading to transient but significant declines in circulating IGF-1, particularly in long-term users. Oral replacement, commonly used in , suppresses IGF-1 by increasing hepatic production of IGFBP-3, which sequesters free IGF-1, unlike routes that preserve levels; this effect is notable in postmenopausal women and can impact growth and metabolism.

Health Implications

Associations with Longevity and Mortality

Epidemiological evidence indicates an inverse between low-normal levels of insulin-like growth factor 1 (IGF-1) and reduced all-cause mortality in adults, with meta-analyses of cohort studies demonstrating that individuals within a mid-range of circulating IGF-1 (approximately 120-160 ng/mL) exhibit the lowest mortality risk compared to those with either very low or elevated levels. This pattern suggests that optimal IGF-1 signaling supports without the detrimental effects of extremes. However, controversies persist regarding the precise relationship, as multiple studies, including dose-response meta-regressions, have identified a U-shaped curve where both very low and very high IGF-1 concentrations independently increase all-cause mortality risk, potentially reflecting underlying frailty or hyperstimulation of growth pathways. Longitudinal cohort studies further substantiate these links, showing that stable or low-normal IGF-1 trajectories over time predict improved survival outcomes in older adults. For instance, data from the revealed that lower baseline IGF-1 levels and declining trajectories were associated with increased mortality risk over follow-up periods of up to 10 years, particularly in community-dwelling elderly participants, highlighting IGF-1 as a of long-term healthspan. Similar findings from other population-based cohorts reinforce that mid-range IGF-1 levels correlate with extended lifespan, independent of age-related declines in hormone production, while very low levels elevate risk. In animal models, caloric restriction has been shown to lower IGF-1 levels, thereby extending lifespan through mechanisms involving reduced mechanistic target of rapamycin (mTOR) signaling, which curtails cellular growth and promotes autophagy. Studies in rodents and nonhuman primates demonstrate that lifelong caloric restriction decreases plasma IGF-1 by 20-40%, correlating with a 30-50% increase in median lifespan, an effect mimicked by pharmacological inhibition of the IGF-1 pathway. This pathway's conservation across species underscores IGF-1's role in modulating longevity by balancing energy allocation between reproduction/growth and maintenance. Dietary factors like high dairy consumption have been linked to elevated IGF-1 levels, potentially influencing through increased bioavailable IGF-1 from proteins and hormones. Meta-analyses of cross-sectional and intervention studies report that greater intake of products, particularly , raises circulating IGF-1 by 10-20% in adults, with some evidence suggesting this elevation may heighten risks for age-related conditions including cancer, though the net impact on overall mortality remains context-dependent.

Cardiovascular and Metabolic Risks

Insulin-like growth factor 1 (IGF-1) at moderate levels exerts protective effects on the cardiovascular system by promoting vascular repair and reducing progression. IGF-1 enhances endothelial cell survival and function, mitigating and inflammation in vascular tissues, which contributes to plaque stabilization and decreased atherogenic burden in animal models. These mechanisms involve IGF-1's activation of anti-apoptotic pathways and stimulation of production, thereby supporting vascular homeostasis and limiting the development of ischemic events. Conversely, elevated IGF-1 levels, particularly in conditions like , are associated with increased cardiovascular risks, including and . In , chronic excess of and IGF-1 drives sodium and water retention, exacerbating severity and contributing to concentric biventricular characteristic of acromegalic . This impairs cardiac contractility over time, elevating the risk of and arrhythmias independent of other comorbidities. Regarding metabolic risks, IGF-1 generally improves insulin sensitivity by enhancing glucose uptake in peripheral tissues, as evidenced by recombinant IGF-1 administration improving glycemic control in patients. However, IGF-1 excess can promote through crosstalk with the insulin signaling pathway, particularly in hepatic and adipose tissues, leading to and elevated risk in conditions like . Cohort studies, including analyses, have demonstrated that genetically predicted higher IGF-1 levels are causally linked to decreased incidence in the general population. Recent 2020s research highlights the role of low IGF-1 in , where reduced levels predict poor glycemic control and higher comorbidity burden, such as and visceral , in obese populations. In individuals with , low IGF-1 correlates with impaired insulin sensitivity and elevated fasting glucose, underscoring its bidirectional influence on metabolic .

Role in Cancer and Aging

Insulin-like growth factor 1 receptor (IGF-1R) signaling plays a pro-proliferative role by enhancing cell survival and in various cancers, particularly through activation of downstream pathways that promote tumor growth. In , IGF-1 and its receptor contribute to disease development, progression, and by stimulating cell and inhibiting . Similarly, in , elevated IGF-1 levels drive androgen-independent progression and via IGF family signaling. In , IGF-1R activation of β-catenin and disruption of the IGF-1R-IRS axis further supports and survival. Epidemiological studies have linked higher circulating IGF-1 levels to increased cancer risk, with meta-analyses showing associations of 20-50% elevated risk for specific malignancies. For instance, prospective data indicate that IGF-1 concentrations in the highest decile are associated with approximately 40% higher risk and increased incidence of . High IGF-1 levels are also tied to elevated risk in multiple analyses, underscoring the hormone's role in tumorigenesis across these sites. In aging, declining IGF-1 levels contribute to the development of and frailty by impairing muscle maintenance and physical function in older adults. Lower IGF-1 is associated with reduced muscle strength, slower speed, and overall functional decline, exacerbating age-related frailty. Interventions such as exercise can mitigate this by restoring IGF-1 concentrations; meta-analyses of and aerobic training in frail or sarcopenic individuals show significant increases in IGF-1 (standardized mean difference = 0.42), supporting improved muscle health. As of 2024, additional meta-analyses confirm exercise-induced IGF-1 elevations aid management in older adults. Therapeutic efforts to target IGF-1R in cancer have included antagonists like figitumumab, a , but clinical trials revealed limited efficacy. Phase III trials of figitumumab combined with in advanced non-small cell were discontinued early due to futility and increased harm, with no significant survival benefits observed. This outcome, along with disappointing results in other solid tumors, led to the broader halt in development of many IGF-1R inhibitors despite promising preclinical data. As of 2025, research has shifted toward IGF-1's role in immunotherapy resistance, with studies suggesting IGF-1R inhibition may enhance checkpoint blockade efficacy in preclinical models of and cancers. Recent post-2020 findings highlight IGF-1's involvement in the (SASP), a hallmark of cellular aging that influences cancer and age-related diseases. Prolonged IGF-1 stimulation induces premature characterized by a distinct SASP profile, including pro-inflammatory factors that can propagate in neighboring cells and promote tumor microenvironments. Dysregulated IGF-1 signaling thus links accelerated aging processes to enhanced cancer risk through SASP-mediated .