Supernormal insulin: [D-PheB24]-insulin with increased affinity for insulin receptors

[D-Phe^B24]- and [D-Phe^B25]-human insulin were semisynthesized from porcine insulin by enzyme assisted coupling method. Receptor binding ability of [D-Phe^B24]- and [D-Phe^B25]-insulin was 180% and 4%, respectively, of that of human insulin. Increased affinity of [D-Phe^B24]-insulin was ascribed to markedly decreased dissociation rate in binding to human cultured lymphocytes. Negative cooperative effect of [D-Phe^B24]insulin was also increased to twice of that of human insulin. Biological activity of these analogues was assessed by 2-deoxy-glucose uptake studies in isolated adipocytes and the ability of [D-Phe^B24]- and [D-Phe^B25]-insulin was 140% and 4%, respectively, of that of human insulin. These findings suggest that B25 L-Phe is more crucial for receptor binding and that [D-Phe^B24]-insulin is the first semisynthetic insulin to show increased affinity for insulin receptors.     

Impaired negative cooperativity of the semisynthetic analogues human [LeuB24]- and [LeuB25]-insulins

Several semisynthetic analogues of human insulin were prepared by enzyme-assisted coupling of synthetic octapeptides to the C-terminal of porcine desoctapeptide insulin. We report the receptor-binding and biological properties of [Leu^B24]- and [Leu^B25]-insulins, one of which has the same sequence as a “mutant” insulin recently found in a diabetic patient (Tager, H. et al.(1979) Nature $\text{28}$:121–125). [Leu^B24]- and [Leu^B25]-insulins had, respectively, 8–12% and 0.9–1.1% of the binding affinity of human insulin, and 11% and 2.7% of its potency in stimulating lipogenesis in isolated rat fat cells. Neither one was an antagonist of the biological effects of native insulin. While the ability of [Leu^B24]-insulin to induce negative cooperativity was clearly impaired, that of [Leu^B25]-insulin was almost abolished. [Leu^B25]-insulin was also a potent antagonist of the negative cooperativity induced by native insulin.     

Receptor binding and biological activity of [SerB24]-insulin, an abnormal mutant insulin

[SerB24]-insulin, the second structurally abnormal mutant insulin, and [SerB25]-insulin were semisynthesized and were studied for receptor binding and biological activity. Receptor binding and biological activity determined by its ability to increase 2-deoxy-glucose uptake in rat adipocytes were 0.7-3% of native insulin for [SerB24]-insulin and 3-8% for [SerB25]-insulin. Negative cooperative effect of these analogues was also markedly decreased. Immunoreactivity of [SerB24]-insulin was decreased whereas that of [SerB25]-insulin was normal. Markedly decreased receptor binding of [SerB24]-insulin appeared to be due to substitution of hydrophobic amino acid, Phe, with a polar amino acid, Ser, at B24.     

Shortened insulin analogues: marked changes in biological activity resulting from replacement of TyrB26 and N-methylation of peptide bonds in the C-terminus of the B-chain

The role of three highly conserved insulin residues PheB24, PheB25, and TyrB26 was studied to better understand the subtleties of the structure-function relationship between insulin and its receptor. Ten shortened insulin analogues with modifications in the beta-strand of the B-chain were synthesized by trypsin-catalyzed coupling of des-octapeptide (B23-B30)-insulin with synthetic peptides. Insulin analogues with a single amino acid substitution in the position B26 and/or single N-methylation of the peptide bond at various positions were all shortened in the C-terminus of the B-chain by four amino acids. The effect of modifications was followed by two types of in vitro assays, i.e., by the binding to the receptor of rat adipose plasma membranes and by the stimulation of the glucose transport into the isolated rat adipocytes. From our results, we can deduce several conclusions: (i) the replacement of tyrosine in the position B26 by phenylalanine has no significant effect on the binding affinity and the stimulation of the glucose transport of shortened analogues, whereas the replacement of TyrB26 by histidine affects the potency highly positively; [HisB26]-des-tetrapeptide (B27-B30)-insulin-B26-amide and [NMeHisB26]-des-tetrapeptide (B27-B30)-insulin-B26-amide show binding affinity 529 and 5250%, respectively, of that of human insulin; (ii) N-methylation of the B24-B25 peptide bond exhibits a disruptive effect on the potency of analogues in both in vitro studies regardless the presence of amino acid in the position B26; (iii) N-methylation of the B23-B24 peptide bond markedly reduces the binding affinity and the glucose transport of respective analogue [NMePheB24]-des-tetrapeptide (B27-B30)-insulin-B26-amide.     

[B2-Lys]-胰岛素的制备与性质

本文报道了用化学半合成途径从天然猪胰岛素制备[B2-Lys]-胰岛素的过程。人胎盘细胞膜胰岛素受体结合试验表明:[B2-Lys]-胰岛素的受体结合能力只有天然胰岛素的80％,降兔血糖作用与时间关系的结果表明它没有长效作用。本文还对这些结果进行了讨论。     

Semisynthetic des-(B27-B30)-insulins with modified B26-tyrosine

Semisynthetic des-(B27-B30)-insulins containing modified B26-tyrosine residues were prepared to refine the understanding of the importance of position B26 with regard to biological and structural properties of the hormone. The following shortened insulin analogues were synthesized by trypsin-catalysed peptide-bond formation between the C-terminal amino acid ArgB22 of des-(B23-B30)-insulin and synthetic tetrapeptides as amino components: des-(B27-B30)-insulin, des-(B27-B30)-insulin-B26-methyl ester, -B26-carboxamide with varying C-terminal hydrophobicity of the B-chain, and [Tyr(NH2)B26]-, [Tyr(NO2)B26]-, [Tyr(I2)B26]-, [D-TyrB26]des-(B27-B30)-insulin-B26-carboxamide containing non-proteinogenic amino acids in position B26. Starting from insulin and an excess of synthetic Gly-Phe-Phe-Tyr-OMe as nucleophile, des-(B27-B30)-insulin-B26-methyl ester--the formal transpeptidation product at ArgB22--was formed in one step. Biological in vitro properties (binding to cultured human IM-9 lymphocytes, relative lipogenic potency in isolated rat adipocytes) of all semisynthetic analogues are reported, ranging from slightly decreased to two-fold receptor affinity and nearly three-fold biopotency relative to insulin. If the C-terminal tetrapeptide B27-B30 is removed, full relative insulin activity is still preserved, while the shortening results in the loss of ability to associate in solution. Only after carboxamidation or methyl esterification of TyrB26 the self-association typical of native insulin can be observed, and the CD-spectral effects in the near UV spectrum related to association and hexamerization of the native hormone are qualitatively reestablished. The results of this investigation underline the importance of position B26 to the modulation of hormonal properties and solution structure of the shortened insulins.     

Non-equivalent role of inter- and intramolecular hydrogen bonds in the insulin dimer interface

Apart from its role in insulin receptor (IR) activation, the C terminus of the B-chain of insulin is also responsible for the formation of insulin dimers. The dimerization of insulin plays an important role in the endogenous delivery of the hormone and in the administration of insulin to patients. Here, we investigated insulin analogues with selective N-methylations of peptide bond amides at positions B24, B25, or B26 to delineate their structural and functional contribution to the dimer interface. All N-methylated analogues showed impaired binding affinities to IR, which suggests a direct IR-interacting role for the respective amide hydrogens. The dimerization capabilities of analogues were investigated by isothermal microcalorimetry. Selective N-methylations of B24, B25, or B26 amides resulted in reduced dimerization abilities compared with native insulin (K(d) = 8.8 μM). Interestingly, although the N-methylation in [NMeTyrB26]-insulin or [NMePheB24]-insulin resulted in K(d) values of 142 and 587 μM, respectively, the [NMePheB25]-insulin did not form dimers even at high concentrations. This effect may be attributed to the loss of intramolecular hydrogen bonding between NHB25 and COA19, which connects the B-chain β-strand to the core of the molecule. The release of the B-chain β-strand from this hydrogen bond lock may result in its higher mobility, thereby shifting solution equilibrium toward the monomeric state of the hormone. The study was complemented by analyses of two novel analogue crystal structures. All examined analogues crystallized only in the most stable R(6) form of insulin oligomers (even if the dimer interface was totally disrupted), confirming the role of R(6)-specific intra/intermolecular interactions for hexamer stability.     

B17-D-leucine]insulin and [B17-norleucine]insulin: synthesis and biological properties

The chemical synthesis of two porcine insulin analogues is described. Leucine in position B17 of the native molecule was substituted by its D-enantiomer and by L-norleucine, respectively. Both B-chain derivatives were synthesized by fragment condensation and purified as di-S-sulphonates by gel filtration followed by ion exchange chromatography on SP-Sephadex at pH3. Combination with native sulphhydryl A-chain yielded [DLeuB17]insulin and [NleB17]insulin. Both insulin analogues were isolated by gel filtration followed by ion exchange chromatography on CM-cellulose at pH 4.0. Biological activities of the analogues were determined relative to native pork insulin: 1) glucose oxidation in rat epididymal adipocytes was 6% for [DLeuB17]insulin and 16% for [NleB17]insulin, 2) receptor-binding affinity tested with cultured human fibroblasts and with rat adipocytes was 3% for [DLeuB17]insulin and 26% for [NleB17]insulin, and 3) thymidine incorporation into DNA of human fibroblasts was 35% for [DLeuB17]insulin and 100% for [NleB17]insulin.     

Insulin analogues with modifications at position B26. Divergence of binding affinity and biological activity

In this study, we prepared several shortened and full-length insulin analogues with substitutions at position B26. We compared the binding affinities of the analogues for rat adipose membranes with their ability to lower the plasma glucose level in nondiabetic Wistar rats in vivo after subcutaneous administration, and also with their ability to stimulate lipogenesis in vitro. We found that [NMeHisB26]-DTI-NH 2 and [NMeAlaB26]-DTI-NH 2 were very potent insulin analogues with respect to their binding affinities (214 and 465%, respectively, compared to that of human insulin), but they were significantly less potent than human insulin in vivo. Their full-length counterparts, [NMeHisB26]-insulin and [NMeAlaB26]-insulin, were less effective than human insulin with respect to binding affinity (10 and 21%, respectively) and in vivo activity, while [HisB26]-insulin exhibited properties similar to those of human insulin in all of the tests we carried out. The ability of selected analogues to stimulate lipogenesis in adipocytes was correlated with their biological potency in vivo. Taken together, our data suggest that the B26 residue and residues B26-B30 have ambiguous roles in binding affinity and in vivo activity. We hypothesize that our shortened analogues, [NMeHisB26]-DTI-NH 2 and [NMeAlaB26]-DTI-NH 2, have different modes of interaction with the insulin receptor compared with natural insulin and that these different modes of interaction result in a less effective metabolic response of the insulin receptor, despite the high binding potency of these analogues.     

The effect of placement of tryptophan residues in selected A-chain positions on the biological profile of insulin

In continuation of our efforts to study the solution structure and conformational dynamics of insulin by time-resolved fluorescence spectroscopy, we have synthesized and examined the biological activity of five insulin analogues in which selected naturally occurring residues in the A-chain have been replaced with the strongly fluorescent tryptophan residue. The potency of these analogues was evaluated in lipogenesis assays in isolated rat adipocytes, in receptor binding assays using rat liver plasma membranes, and in two cases, in receptor binding assays using adipocytes. [A3 Trp]insulin displays a potency of 3% in receptor binding assays in both liver membranes and in adipocytes, but only 0.06% in lipogenesis assays as compared to porcine insulin. [A10 Trp] insulin displays a potency ofca. 40% andca. 25% in rat liver receptor binding and lipogenesis assays, respectively. [A13 Trp]insulin displays a potency ofca. 39% in rat liver receptor binding assays, but onlyca. 9% in receptor binding in adipocytes; in lipogenesis assays, [A13 Trp] insulin displays a potency ofca. 12%, comparable to its potency in adipocyte receptor binding assays. [A15 Trp]insulin exhibits a potency of 18% and 9% in rat liver receptor binding and lipogenesis assays, respectively. The doubly substituted analogue, [A14 Trp, A19 Trp] insulin, displays a potency ofca. 0.7% in both rat liver receptor binding assays and lipogenesis assays. These data suggest two major conclusions: (1) the A3 and A15 residues lie in sensitive regions in the insulin molecule, and structural modifications at these positions have deleterious effects on biological activity of the hormone; and (2) [A13 Trp]insulin appears to be a unique case in which an insulin analogue exhibits a higher potency when assayed in liver tissue than when assayed in fat cells.     

B22-D-arginine]insulin: synthesis and biological properties

An analogue of porcine insulin which differs from the native molecule in that the amino-acid residue B22-L-arginine is replaced by its D-enantiomer has been synthesized. The [D ArgB22]B-chain was synthesized by the segment condensation method and purified as the di-S-sulfonate by ion exchange chromatoggraphy on SP-Sephadex at pH 3.5. Combination with native porcine sulfhydryl A-chain gave [DArgB22]insulin which was purified by ion exchange chromatography on SP-Sephadex at pH 4.5 with a linear NaCl gradient. The biological activity of this analogue as measured by glucose oxidation in rat epididymal adipocytes was 2%. Thymidine incorporation into DNA of human fibroblast was 16%. The immunoreactivity using antipork insulin antibody in a double antibody immunoassay was 4%. The receptor-binding affinity as measured by radioreceptor assays was 2% with cultured human fibroblasts and 1% with rat adipocytes. These results suggest that the L-configuration at B22-arginine is essential for retaining the biological, immunological and receptor-binding properties of the hormone.     

高受体结合和低免疫原性的［B1—Ala，B2—Ala］－胰岛素

通过化学半合成从天然猪胰岛素得到［Ｂ１－Ａｌａ,Ｂ２－Ａｌａ］胰岛素。这一胰岛素类似物经聚丙烯酰胺凝胶电泳和ＨＰＬＣ鉴定证明是均一的,氨基酸组成与理论值相符生物活性测定结果表明：［Ｂ１－Ａｌａ,Ｂ２－Ａｌａ］－胰岛素的体内活力与天然猪胰岛素相同,而与人胎盘细胞膜胰岛素受体的结合能力为天然猪胰岛素的１３２％。这一结果进一步说明胰岛素Ｂ链Ｎ端肽段参子与受体相互作用。此外,［Ｂ１－Ａｌａ,Ｂ２－Ａｌａ］－胰岛素的免疫活性很低,远小于天然猪胰岛素的４％。     

TyrB26位点改变的人类胰岛素类似物的化学合成与体外活性

摘要：为了研究人类胰岛素B链第26位的酪氨酸对胰岛素和受体之间的结合的影响,包括单独的氨基酸替换或化合物替换的不同的胰岛素类似物被合成,其中化合物替代的类似物的B链C末端都减少了4个氨基酸。在对它们与胰岛素受体的亲和力进行研究中,结果发现它们与胰岛素受体的亲和力没有丢失, HisB26类似物和N-MeHisB26类似物的结合能力与胰岛素相比改变不大,分别是胰岛素的72 %和107 %。N-MeGluB26类似物,AadB26类似物和Phe (4-carboxy) B26类似物的结合能力有很大的提高,分别是130 %, 234 %和160 %。     

Structure-function relationships of shortened [LeuB25]insulins, semisynthetic analogues of a mutant human insulin

Replacement of B25-phenylalanine by leucine in the insulin sequence causes marked inactivation. The effect of this sequence variation was studied here in des-(B26-30)-insulin. [LeuB25]des-(B26-30)-insulin and its B25-amide were prepared by trypsin-mediated semisynthesis from N-terminally protected des-(B23-30)-insulin and synthetic tripeptides. The relative lipogenic potency in isolated rat adipocytes was 8.0% for the truncated analogue with a free B25-carboxyl function, and 18.1% for the amidated analogue. Binding to cultured human IM-9 lymphocytes was 4% and 9%, respectively. Thus, both shortened insulins are markedly more active than [LeuB25]insulin. The PheB25----LeuB25 substitution in both the shortened and the full sequence has a moderate effect on the CD spectrum, indicating that the gross main chain conformation is largely retained in both molecules. Independent of the substitution an absolute increase of the circular dichroism is observed upon amidation of the B25-carboxyl group.     

The A14 position of insulin tolerates considerable structural alterations with modest effects on the biological behavior of the hormone

As part of our aim to investigate the contribution of the tyrosine residue found in the 14 position of the A-chain to the biological activity of insulin, we have synthesized six insulin analogues in which the A14 Tyr has been substituted by a variety of amino acid residues. We have selected three hydrophilic and charged residues—glutamic acid, histidine, and lysine—as well as three hydrophobic residues—cycloleucine, cyclohexylalanine, and naphthyl-(1)-alanine—to replace the A14 Tyr. All six analogues exhibit full agonist activity, reaching the same maximum stimulation of lipogenesis as is achieved with procine insulin. The potency for five of the six analogues, [A14 Glu]-, [A14 His]-, [A14 Lys]-, [A14 cycloleucine]-, and [A14 naphthyl-(1)-alanine]-insulins in receptor binding assays ranges from 40–71% and in stimulation of lipogenesis ranges from 35-120% relative to porcine insulin. In contrast, the potency of the sixth analogue, [A14 cyclohexylalanine]insulin, in both types of assays is less than 1% of the natural hormone. The retention time on reversed-phase high-performance liquid chromatography for the first five analogues is similar to that of bovine insulin, whereas for the sixth analogue, [A14 cyclohexylalanine]insulin, it is approximately 11 min longer than that of the natural hormone. This suggests a profound change in conformation of the latter analogue. Apparently, the A14 position of insulin can tolerate a wide latitude of structural alterations without substantial decrease in potency. This suggests that the A14 position does not participate directly in insulin receptor interaction. Only when a substitution which has the potential to disrupt the conformation of the molecule is made at this position, is the affinity for the receptor, and hence the biological potency, greatly reduced.     

The synthesis of [A 19-3-iodotyrosine] and [A 19-3,5-diiodotyrosine]insulin (porcine)

The chemical synthesis of [Tyr(I)A19] and [Tyr(I2)A19]insulin (porcine), using the amino-acid derivatives 3-iodotyrosine and 3,5-diiodotyrosine is described. The synthesis of the iodinated A-chains were performed by segment condensation in solution using acid labile protecting groups. The hydroxyl groups of Tyr(I) and Tyr(I2) were unprotected. For the temporary protection of the alpha-amino groups of the A-chain segments containing iodinated tyrosines, the 1-(4-biphenylyl)-1-methylethoxycarbonyl group was selected. After deprotection and sulphitolysis the iodinated A-chain tetra-S-sulphonates were purified by ion exchange chromatography on DEAE cellulose at pH 5.6. Reduction to the sulphhydryl form and the combination with native porcine B-chain yielded [Tyr(I)A19] and [Tyr(I2)A19]insulin (porcine), respectively. Purification of the first product was achieved by gel filtration and of the later by ion exchange chromatography on CM-cellulose at pH 4.5 and gel filtration. The monoiodinated insulin had a biological activity of 24 +/- 2% and the diiodinated analogue 2.6 +/- 0.2% as determined in an in vitro lipogenesis assay with epididymal adipocytes.     

Importance of the character and configuration of residues B24, B25, and B26 in insulin-receptor interactions

By use of isolated canine hepatocytes and insulin analogs prepared by trypsin-catalyzed semisynthesis, we have investigated the importance of the aromatic triplet PheB24-PheB25-TyrB26 of the COOH-terminal B-chain domain of insulin in directing the affinity of insulin-receptor interactions. Analysis of the receptor binding potencies of analogs bearing transpositions or replacements (by Tyr, D-Tyr or their corresponding 3,5-diiodo derivatives) in this region demonstrates a wide divergence in the acceptance both of configurational change (with [D-TyrB24,PheB26]insulin and [D-TyrB25,PheB26]insulin exhibiting 160 and 0.1% of the receptor binding potency of insulin, respectively) and of detailed side chain structure (with [TyrB24,PheB26]insulin and [TyrB25,PheB26]insulin exhibiting 2 and 80% of the receptor binding potency of insulin, respectively). Additional experiments addressed the solvent accessibilities of the 4 tyrosine residues of insulin and the insulin analogs at selected peptide concentrations by use of analytical radioiodination. Whereas two analogs ([TyrB25,PheB26]insulin and [D-TyrB24,PheB26]insulin) were found to undergo self aggregation, no strict correlation was found between the ability of an analog to aggregate and its potency for interaction with the insulin receptor. Related findings are discussed in terms of the interplay between side chain and main chain structure in the COOH-terminal domain of the insulin B-chain and the structural attributes of insulin that determine the affinity of insulin-receptor interactions.     

Mutational analysis of invariant valine B12 in insulin: implications for receptor binding

An invariant residue, valine B12, is part of the insulin B-chain central alpha-helix (B9-B19), and its aliphatic side chain lies at the surface of the hydrophobic core of the insulin monomer in close contact with the neighboring aromatic side chains of phenylalanines (B24 and B25) and tyrosines (B26 and B16). This surface contributes to the dimerization of insulin, maintains the active conformation of the insulin monomer, and has been suspected to be directly involved in receptor recognition. To investigate in detail the role of the B12 residue in insulin-receptor interactions, we have synthesized nine analogues bearing natural or unnatural amino acid replacements for valine B12 by chemical synthesis of modified insulin B-chains and the subsequent combination of each synthetic B-chain with natural insulin A-chain. The receptor binding potencies of the synthetic B12 analogues relative to porcine insulin were determined by use of isolated canine hepatocytes, and the following results were obtained: isoleucine, 13%; allo-isoleucine, 77%; tert-leucine, 107%; cyclopropylglycine, 43%; threonine, 5.4%; D-valine, 3.4%; alpha-amino-n-butyric acid, 14%; alanine, 1.0%; and glycine, 0.32%. Selected analogues were also analyzed by far-UV circular dichroic spectroscopy and by absorption spectroscopy of their complexes with Co(2+). Our results indicate that beta-branched aliphatic amino acids are generally tolerated at the B12 position with specific steric preferences and that the receptor binding potencies of these analogues correlate with their abilities to form dimers. Furthermore, the structure-activity relationships of valine B12 are quite similar to those of valine A3, suggesting that valine residues at both A3 and B12 contribute to the insulin-receptor interactions in a similar manner.     

Evidence for separate receptors for insulin and insulin-like growth factor-I in choroid plexus of rat brain by quantitative autoradiography

Binding of insulin and insulin-like growth factor-I (IGF-I) to the choroid plexus was quantitatively characterized using autoradiography and computer densitometry. Slide-mounted brain slices were incubated in 0.1 nM [125I]-insulin or [125I]-[Thr59]IGF-I. To determine specificity of the binding sites, the labeled peptides were mixed with unlabeled analogues. Autoradiography was done with LKB Ultrofilm and analyzed with a computer image analysis system and program for densitometry. Results showed that binding was time and temperature dependent and reversible. Binding of the iodinated insulin and IGF-I was inhibited by unlabeled peptides in a dose-dependent manner. The rank order of potency of these peptides in competing for the choroid plexus iodoinsulin binding sites was: chicken insulin greater than porcine insulin greater than desoctapeptide insulin greater than IGF-I. IGF-I was more potent than porcine insulin in competing for the choroid plexus iodolGF-I binding sites. Somatostatin was ineffective. Non-linear regression analysis revealed the presence of high- (Kd 1.3 +/- 0.2 nM) and low-affinity (Kd 36 +/- 1.4 nM) binding sites for insulin and a single high-affinity binding site (Kd 3.1 +/- 0.3 nM) for IGF-I in the choroid plexus. There were approximately 50 times more binding sites (Bmax) for IGF-I than for insulin high-affinity sites, whereas the number of low-affinity sites for insulin was about equal to the number of IGF-I high-affinity sites. The results of these binding studies with iodinated insulin and [Thr59]IGF-I support the conclusion that the rat choroid plexus has separate high-affinity receptors for insulin and IGF-I, and that the IGF-I receptors outnumber the insulin receptors.     

Mutants of human insulin-like growth factor I with reduced affinity for the type 1 insulin-like growth factor receptor

Four mutants of human insulin-like growth factor I (hIGF I) have been purified from the conditioned media of yeast transformed with an expression vector containing a synthetic gene for hIGF I altered by site-directed mutagenesis. hIGF I has the sequence Phe-23-Tyr-24-Phe-25 which is homologous to a region in the B-chain of insulin. [Phe23,Phe24,Tyr25]IGF I, in which the sequence is altered to exactly correspond to the homologous sequence in insulin, is equipotent to hIGF I at the types 1 and 2 IGF and insulin receptors. [Leu24]IGF I and [Ser24]IGF I have 32- and 16-fold less affinity than hIGF I at the human placental type 1 IGF receptor, respectively. These peptides are 10- and 2-fold less potent at the placental insulin receptor, respectively. [Leu24]IGF I and [Ser24]IGF I have similarly reduced affinities for the type 1 IGF receptor of rat A10 and mouse L cells. Thus, the importance of the interaction of residue 24 with the receptor is conserved in several species. In three cell-based assays, [Leu24]IGF I and [Ser24]IGF I are full agonists with reduced efficacy compared to hIGF I. Desoctapeptide [Leu24]IGF I, in which the loss of aromaticity at position 24 is combined with the deletion of the carboxyl-terminal D region of hIGF I, has 3-fold lower affinity than [Leu24]IGF I for the type 1 receptor and 2-fold higher affinity for the insulin receptor.(ABSTRACT TRUNCATED AT 250 WORDS)