Panayotis G. Katsoyannis

Modulation of insulinlike growth factor I binding to human fibroblast monolayer cultures by insulinlike growth factor carrier proteins released to the incubation media.

The relative contributions of type I and type II insulinlike growth factor (IGF) receptors and IGF carrier proteins to the binding of IGF-I tracer to cultured human fibroblasts were determined in competitive binding experiments that used unlabeled insulin and synthetic insulin-IGF-I hybrid molecules containing the A chain of insulin and the B domain of IGF-I. Whereas insulin binds only to type I IGF receptors, the B-IGF-I hybrids bind to type I receptors and IGF carrier proteins but not to type II receptors. In suspended human fibroblasts, IGF-I tracer binds predominantly to type I IGF receptors (inhibition by IGF-I much greater than insulin greater than B-IGF-I hybrid molecules). By contrast, in fibroblast monolayers, IGF-I binding was minimally inhibited by insulin or hybrid molecules, suggesting predominant binding to the type II IGF receptor. The type I receptor appears to be masked on fibroblast monolayers, and to require suspension or detergent solubilization of the cells to be demonstrated. In the course of the monolayers binding experiments, we noted that low concentrations of unlabeled IGF-I (5-10 ng/ml) or B-IGF-I hybrids (100 ng/ml) paradoxically increased IGF-I tracer binding up to twofold. We postulated that during the binding incubation (5 h, 15 degrees C), IGF-I tracer partitioned between binding sites on the cell surface and IGF carrier proteins released to the incubation media. Preferential occupancy of binding sites in the media by unlabeled ligand increased the tracer available to bind to the cells. In support of this hypothesis, carrier proteins were demonstrated in the media at the end of the binding incubation with fibroblast monolayers, and the concentration of unsaturated binding sites in the media correlated inversely with tracer binding to the cells. Thus carrier proteins released to the media during the binding incubation modulate the binding of IGF-I tracer to cell receptors, suggesting that the carrier proteins may play an important role in regulating cellular responsiveness to the IGFs.

Insulin analogues with modifications in the β-turn of the B-chain

The β-turn formed by the amino acid residues 20–23 of the B-chain of insulin has been implicated as an important structural feature of the molecule. In other biologically active peptides, stabilization of β-turns has resulted in increases in activity. We have synthesized three insulin analogues containing modifications which would be expected to increase the stability of the β-turn. In two analogues, we have substituted α-aminoisobutyric acid (Aib) for the Glu residue normally present in position B21 or for the Arg residue normally present in position B22; in a third compound, we have replaced the Glu residue with its D-isomer. Biological evaluation of these compounds showed that [B21 Aib]insulin displays a potencyca. one-fourth that of natural insulin, while [B22 Aib]insulin is less than 10% as potent. In contrast, [B21 D-Glu]insulin is equipotent with natural insulin. We conclude that the β-turn region of the insulin molecule normally possesses considerable flexibility, which may be necessary for it to assume a conformation commensurate with high biological activity. If this is the case, [B21 D-Glu]insulin may exhibit a stabilized geometry similar to that of natural insulin when bound to the insulin receptor.

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.

LINKED-FUNCTION ANALYSIS OF FLUORESCENCE DECAY KINETICS: RESOLUTION OF SIDE-CHAIN ROTAMER POPULATIONS OF A SINGLE AROMATIC AMINO ACID IN SMALL POLYPEPTIDES

A linked‐function approach to fluorescence decay data analysis is presented that permits complex systems to be resolved from a single decay curve. The method involves linking fluorescence decay parameters based on a relationship established by independent physical measurements. As an example, by correlating the fluorescence data with 1H‐NMR results, the complex fluorescence decay kinetics of tyrosine analogs and single tyrosyl residues in simple polypeptides can be explained by ground‐state rotameric populations of the phenol ring about the Cα‐Cβ bond.

The inhibition of sugar transport and oxidation in fat cell ghosts by colchicine.

Abstract Colchicine inhibits glucose oxidation and the uptake of 2-deoxy-D-glucose in fat cell ghosts but has no effect on glucose oxidation by fat cell homogenates. This inhibition is rapid, reversible, and temperature-independent. Insulin-stimulated glucose oxidation and 2-deoxy-D-glucose transport are also inhibited by colchicine to an extent comparable to the basal processes.

Synthesis and biological evaluation of a modified insulin incorporating the COOH-terminal hexapeptide («D-region») of insulin-like growth factor II

A modified insulin, in which the A chain moiety has been extended at the C-terminus with the “D region” of the insulin-like growth factor II, has been synthesized essentially by the procedures employed in this laboratory for the synthesis of insulin and analogues. This hybrid molecule displayed reduced insulin-like activities, 34.5% receptor binding, and 40.4% stimulation of lipogenesis relative to natural insulin. These findings suggest that the extension sequence (“D region”) attached at the C-terminus of the A chain may partially cover the putative receptor binding region of insulin, in support of speculations based on computer-generated models. These same models indicate that the extension peptide may interfere with one of the two regions implicated in insulin antibody recognition. In this regard, radioimmunoassay of the hybrid revealed potency even more reduced than biological activity: 18% relative to insulin. Growth factor assays of the hybrid (this laboratory, unpublished data) suggest that the “D region” of insulin-like growth factor II is not in itself the determinant of growth-promoting activity.

The effect of modifications of the A5 and A19 amino acid residues on the biological activity of insulin. [Leu5-A] and [Phe19-A] sheep insulins

Two analogs of sheep insulin, both differing from the native material by a single amino acid in the A chain, have been synthesized and isolated in highly purified form by procedures developed in this laboratory. In one case, the glutamine residue in position A5 was replaced by leucine ([Leu5-A]); in the other, the tyrosine residue in position A19 was replaced by phenylalanine ([Phe19-A]). The biological behavior of these analogs was compared with natural bovine insulin inin vitro tests and in receptor-binding assays, as well as in radioimmunoassay. In the stimulation of glucose oxidation by rat adipocytes, the analogs gave relative potencies of 30% and 7.8% for [Leu5-A] and [Phe19-A], respectively. Receptor-binding assays in rat liver plasma membranes showed similar behavior for both analogs. In radioimmunoassay, [Leu5-A] displayed a relative potency of 27.9%, while [Phe19-A] showed a relative potency of 19–27%, compared with bovine insulin. At high concentration, both analogs displayed the same maximal activity as bovine insulin, and the dose-response curves are essentially parallel. It is speculated that the interaction between the glutamine residue in position 5 and the tyrosine residue in position 19 of the A chain of insulin are important in maintaining a three-dimensional structure commensurate with high biological activity. The full intrinsic activity of both analogs at high concentrations and the similarity of the potency figures in receptor-binding and glucose-oxidation assays permit the further conclusion that the reduced potency in the latter assay can be ascribed wholly to the reduced binding affinity toward insulin receptors caused by the substitutions made in the analogs. The receptor-analog complexes are fully capable of triggering the next event in the chain leading to the biological response.

5-Hydroxytryptophan: An absorption and fluorescence probe which is a conservative replacement for [A14 tyrosine] in insulin

Use of insulins intrinsic tyrosine absorption and fluorescence to monitor its interaction with the insulin receptor is limited because the spectral properties of the receptor tryptophan residues mask the spectral properties of the hormone tyrosine residues. We describe the synthesis of an insulin analog where A14 tyrosine is replaced by a tryptophan analog, 5-hydroxytryptophan. This insulin is spectrally enhanced since 5-hydroxytryptophan has an absorption band above 300 nm which is at lower energies than the absorption of tryptophan. Steady-state and time-resolved fluorescence parameters indicate that 5-hydroxytryptophan reports the same information about the environment of the A14 side chain as does the corresponding tryptophan-containing insulin. The synthetic hormone is a full agonist compared to porcine insulin, but has slightly reduced specific activity. Consequently, this spectrally enhanced insulin analog will be useful for hormone-receptor interaction studies since it can be observed by both absorption and fluorescence even in the presence of the tryptophan-containing receptor.

Contribution of the B16 and B26 tyrosine residues to the biological activity of insulin.

We report the synthesis and biological evaluation of five insulin analogues in which one or both of the B-chain tyrosine residues have been substituted. [B16 Phe]insulin and [B16 Trp]insulin display a very modest reduction in potency (c. 65%) relative to porcine insulin; [B26 Phe]insulin is less active (30–50%), and the doubly substituted [B16 Phe, B26 Phe]insulin displays still lower potency (c. 35%). The further substitution of Asp for B10 His in [B16 Phe, B26 Phe]insulin raises its activity to approximately twofold greater than natural insulin, an increase of approximately fivefold over the parent compound. We conclude that the bulk and/or aromaticity of the amino acid residue at position B16, but not its hydrogen-bonding capacity, contributes to the biological activity of the hormone. We further conclude that hydrogen-bonding capacity or special side-chain packing characteristics are required at the B26 position for insulin to display high biological activity.

Synthesis of an insulin analogue embodying a strongly fluorescent moiety, [19-Tryptophan-A]insulin

As part of our aim to study the conformation of insulin in solution by time-resolved fluorescence spectroscopy, we have synthesized the analogue [19-Tryptophan-A]insulin. In this compound, the tyrosine residue at position 19 of the A-chain of insulin, one of the most strongly conserved residues in insulins from various species, is substituted with the strongly fluorescent tryptophan residue. [19-Tryptophan-A]insulin displays 4.1±1.9% of the potency of natural insulin in binding to the insulin receptor from rat liver plasma membranes, 5.0±2.3% in stimulating lipogenesis in rat adipocytes, and 75.7±4% of the potency of insulin in radioimmunoassay. In connection with our previous work, these data indicate that an aromatic side chain at position A19 of insulin seems necessary but not sufficient for high biological activity. We further conclude that in regard to the immunogenic determinants of insulin, tryptophan in position A19 is an essentially neutral substitution for tyrosine in that position, in sharp contrast to the situation with regard to biological activity.