Effects of alpha-interferon on insulin-like growth factor-I, insulin-like growth factor-II and insulin-like growth factor binding protein-3 secretion by a human lung cancer cell line in vitro

The aim of our study was to evaluate the effect of alpha-interferon (alpha-IFN) on cell growth and on the different IGF system components in a human non-small cell lung cancer line (Calu-6) in vitro. Our results confirm the release of IGF-I and IGF-II by these cells. The amount of IGF-II in conditioned media (10.25 +/- 3.95 nM/10(6) cells, mean +/- SE) was more than 10-fold higher than that of IGF-I. alpha-IFN treatment reduced IGF-II levels in the media, with a maximal effect between 1 and 10 U/ml (delta% of control: -31 and -55%, respectively, p < 0.05). IGF-I was significantly reduced at 0.5 U/ml (p < 0.01). No difference, however, was observed in IGF mRNA expression between untreated and alpha-IFN treated cells. An increase in IGF-I and IGF-II intracellular levels in alpha-IFN treated cultures was observed, suggesting that alpha-IFN can regulate the transfer of these peptides into the cells. Furthermore, IGF type-I and particularly type-lI receptor expression was increased after alpha-IFN treatment. IGFBP-3 was detected only in trace amounts in the conditioned media; however, it showed an increase after alpha-IFN treatment (+110% at 1 U/ml). IGFBP-3 mRNA expression showed a slight increase after treatment with 1 and 10 U/ml. alpha-IFN (1-10 U/ml) reduced the stimulatory effect of IGF-I on cell replication (p < 0.01), inhibited (p < 0.01) cell replication in untreated and in fetal calf serum (FCS)-stimulated cells, and increased apoptosis in Calu-6 cells. Our data suggest that alpha-IFN may exert its effects at the cellular level in part through modification of the local IGF system.     

Effects of insulin-like growth factor-I on growth hormone and prolactin secretion and cell proliferation of human somatotrophinomas and prolactinomas in vitro

OBJECTIVE IGF-I inhibits GH secretion from normal and some tumorous pituitary tissue, and has been shown to be mitogenic for gonadotrophinoma cells in vitro. It is not known whether IGF-l affects somatotrophinoma cellular proliferation or the secretion of other hormones, such as PRL and α-subunit, which are often co-secreted by these tumours. We have therefore examined the effects of IGF-l on proliferation and hormonal secretion of human somatotrophinomas and prolactinomas in vitro. DESIGN Pituitary adenoma tissue was dispersed to single cells in monolayer culture. The effects of 100 nw IGF-I on GH, PRL and α-subunit secretion were determined over 4-hour and over 4-day periods, and a 4-day dose-response study using 1–100 nM IGF-I was performed on two tumours. Adenoma cell S-phase proliferation was determined after bromodeoxyuridine Incorporation for 1 hour after 4 days, using a double immunostaining method. RESULTS Over 4 hours, 100 nw IGF-I had no effect on GH, PRL or α-subunit secretion in 7 tumours. Over 4 days, 100 nw IGF-I reduced GH secretion In 518 somatotrophinomas (range 17–84%, P < 0·05) compared to controls, with tumours responding to IGF-I having lower basal serum and in-vitro GH levels than tumours unaffected by IGF-I (P < 0·05). There was no effect on α-subunit secretion in any of the three tumours studied. PRL co-secretion was increased In 315 somatotrophinomas compared to control (20, 30 and 37%, P < 0·05), with tumours responding to IGF-I being associated with lower basal serum and in-vitro PRL levels than those tumours unaffected by IGF-I. IGF-I also increased PRL secretion in 2/2 prolactinomas (27 and 32%, P < 0·05) compared with control. GH was inhibited and PRL secretion was stimulated by 1 and 10 nw IGF-I in the two dose-response studies. The proliferative labelling index did not exceed 1·9% in any tumour and no proliferative effect was found with 100 nw IGF-I in any somatotrophinoma. CONCLUSION IGF-I inhibited tumorous GH in 62% and stimulated PRL secretion in 71 % of tumours over 4 days, without affecting α-subunit secretion or being mitogenic for somatotrophinoma cells in vitro. No hormonal effects were observed over short (4-hour) incubations. IGF-I may be a newly recognized factor directly stimulating tumorous PRL secretion.     

The effect of recombinant human insulin-like growth factor-I treatment on growth hormone secretion in two subjects with growth hormone insensitivity (Laron syndrome)

OBJECTIVE Growth hormone (GH) secretion Is increased in conditions of GH insensitivity such as Laron syndrome, with elevation of both basal and peak levels. We have studied the effect of recombinant IGF-I therapy on the pattern of GH secretion in two subjects with GH insensitivity. SUBJECTS Two pubertal subjects with GH insensitivity (female, 16.4 years, breast stage 3; male 13.6 years, genital stage 2) were investigated after 6 months of IGF-I therapy (120 μg/kg twice daily s.c. at 0800 and 1900 h). GH profiles taken before the start of IGF-I therapy, when both subjects were prepubertal (aged 14 0 and 11 5 years respectively), were used for comparison. METHODS GH profiles were performed with blood samples taken every 20 minutes between 2000 and 0800 h from an indwelling cannula. MEASUREMENTS Serum samples were assayed for GH by immunoradiometric assay and IGF-I, IGFBP-1 and insulin by radioimmunoassay. RESULTS Before IGF-I therapy, GH profile studies demonstrated pulsatile GH secretion. Basal GH was elevated with no value falling below the limit of detection of the assay and an increase in peak levels (maximum 203 and 206 μ/I at 0000 h and 0020 h respectively). After 6 months IGF-I therapy, the GH profiles were significantly different. With the onset of puberty a further increase in GH secretion would have been expected; nevertheless, following administration of IGF-I at 1900 h, GH secretion decreased with a reduction in mean overnight GH levels from 65 to 33 μ/l and 53 to 11 μ/l respectively. GH pulsatility was also suppressed in the two subjects, for the first 3.5 and 6 hours overnight respectively. Pulsatile GH secretion then returned with peak levels reaching 130 and 63 μ/l respectively. Prior to therapy IGF-I levels were at the lower limit of assay detection. On IGF-I therapy serum IGF-I levels reached a peak within 3 hours (298 and 438 μg/l) coinciding with the suppression of GH secretion. IGF-I levels fell rapidly overnight to 92 and 101 μg/l at 0800 h prior to the next injection. The fall in serum IGF-I coincided with the return of GH secretion. IGFBP-1 levels increased overnight both before and during IGF-I therapy, rising from 24 to 83 and 22 to 110 μg/l before therapy and 13 to 60 and 13 to 71 μg/l during therapy. This rise in IGFBP-1 appeared to be inversely related to the fall in serum insulin levels overnight and appeared not to be affected by IGF-I therapy. CONCLUSION GH secretion is suppressed by exogenous IGF-I therapy in GH insensitive subjects. The failure to maintain high serum IGF-I levels overnight, presumably due to a persisting defect in serum IGFBP-3 levels, was associated with an early return of GH secretion. These findings may have implications for the dose and regimen of IGF-I therapy in subjects with growth hormone insensitivity.     

Administration of human recombinant insulin-like growth factor-I to patients following major gastrointestinal surgery

OBJECTIVE: The aim was to study the pharmacokinetic parameters and biological activity of a single dose of human recombinant IGF-I (rhIGF-I) administered to patients following major gastrointestinal surgery. DESIGN: A double blind placebo controlled externally randomized study of 30 patients; the study commencing 24 hours after major colonic or gastric surgery. MEASUREMENTS: After a baseline blood sampling day, IGF-I (40 micrograms/kg by single subcutaneous dose, n = 20) or placebo (n = 10) was administered and serum and urine samples collected over the ensuing 72 hours. Serum IGF-I, IGF-II, IGF binding proteins (IGFBP-1, IGFBP-3), GH and insulin were measured by radioimmunoassay. Serum IGF bioactivity was assessed using a validated porcine cartilage bioassay. Serum and urinary electrolytes were measured by standard methodology. RESULTS: Serum immunoreactive IGF-I levels peaked at 4 hours following injection of IGF-I (1.09 +/- 0.12 U/ml mean +/- SEM), remained elevated for 15 hours and returned to basal levels by 24 hours after injection. IGF bioactivity was increased by 57% 6 hours after IGF-I injection. Mean levels of IGFBP-1 and IGFBP-3, IGF-II and GH were unaffected by IGF-I administration. Insulin levels were suppressed at 30 minutes following injection of IGF-I compared with the placebo group (16.9 +/- 3.0 mU/I vs 32.3 +/- 7.1, P = 0.02); thereafter, there were no differences in insulin levels. The mean change in serum creatinine following IGF-I (-6.3 +/- 3.0 mmol/l) was significantly different from that in the control group (+7.2 +/- 6.2, P = 0.03). Creatinine clearance rose from a mean of 71.6 +/- 7.5 ml/min to 83.2 +/- 7.6 ml/min after IGF-I treatment (P = 0.02). In the IGF treated patients, cholesterol levels consistently fell (-0.20 +/- 0.05 mmol/l); this was not observed in the placebo group (+0.20 +/- 0.14, P = 0.006). Basal serum potassium levels in the IGF treatment group (4.1 +/- 0.1 mmol/l) fell to 3.8 +/- 0.1 at 4 hours (P = 0.002) and 3.6 +/- 0.1 at 10 hours (P = 0.001) returning to a level of 4.0 +/- 0.1 (P = 0.293) at 24 hours after injection. There were no other observed differences in serum or urinary electrolytes or serum free fatty acids and triglycerides. Pharmacokinetic parameters derived from baseline adjusted IGF-I measurements revealed a slow absorption of the administered dose with a Tmax of 5.0 +/- 0.43 hours and an elimination half-life of 10.8 +/- 1.2 hours. The computed volume of distribution was 0.33 +/- 0.05 I/kg and the clearance on average 25 ml/min. CONCLUSION: A single subcutaneous dose of IGF-I normalized circulating IGF-I levels in post-operative patients, was well tolerated and without side-effects. IGF bioactivity was increased and associated with a fall in serum cholesterol, potassium and creatinine levels and a rise in creatinine clearance. Further long-term studies are now required to assess the anabolic effects of rhIGF-I in this type of patient group.     

The role of recombinant human insulin-like growth factor-I in treating children with short stature

CONTEXT: Recombinant human (rh) IGF-I is now available to treat children with short stature resulting from severe primary IGF-I deficiency. This review from the Drug and Therapeutics Committee of the Lawson Wilkins Pediatric Endocrine Society discusses different aspects of rhIGF-I therapy, particularly with regard to potential advantages and disadvantages in comparison with the traditional use of rhGH for treatment of short stature. Evidence Acquisition: We used the Entrez-PubMed search engine to conduct a review of publications addressing IGF-I deficiency, the use of rhIGF-I, and treatment for short stature. EVIDENCE SYNTHESIS: rhIGF-I, as a twice-daily sc injection, is now approved for treatment of short stature in children with severe primary IGF-I deficiency, which may occur as a consequence of mutations in the GH receptor, defects in the post-GH receptor signaling pathway, and IGF-I gene defects. It is also approved for children with GH deficiency who develop neutralizing antibodies to GH. rhIGF-I significantly improves growth in these conditions. However, adult height may still be suboptimal, possibly due to lack of direct GH effects. Dosing regimens for rhIGF-I administration are under investigation, as are other indications for use of rhIGF-I. CONCLUSION: The use of rhIGF-I is justified in conditions approved by the Food and Drug Administration. Until more substantial data become available, the use of rhIGF-I outside Food and Drug Administration recommendations should only be investigational.     

Low dose recombinant human insulin-like growth factor-I fails to affect protein anabolism but inhibits islet cell secretion in humans.

The in vivo effects of recombinant human insulin-like growth factor-I (rhIGF-I) on whole body protein metabolism were studied to ascertain whether rhIGF-I has comparable effects as those reported with rhGH use in humans. The doses of rhIGF-I chosen achieved similar plasma IGF-I concentrations as those achieved after 7 days of rhGH injections. Eight normal volunteers were studied using [1-13C]- and [1-14C]leucine tracers, before, 4 h, and 28 h after a continuous infusion of rhIGF-I at 5 micrograms kg-1 h-1 (n = 6) and 10 micrograms kg-1 h-1 (n = 2). Two additional subjects were studied in a protein catabolic state after 7 days of high dose (0.8 mg kg-1 day-1) glucocorticosteroid administration. Plasma concentrations of rhIGF-I were similar using either 5 or 10 micrograms kg-1 h-1 and increased to values approximately 300% above baseline by 28 h of infusion. No decrease in the plasma glucose concentration was observed during the 28-h infusion; however, plasma insulin, C-peptide, and glucagon concentrations significantly decreased, whereas plasma free fatty acids were not affected. No changes were observed in the rate of proteolysis (as estimated by the rate of leucine appearance), the rate of leucine oxidation, or the rate of protein synthesis in the absence or presence of glucocorticosteroid treatment. Plasma concentrations of insulin-like growth factor binding protein-3 did not change during the rhIGF-I infusion whereas they increased 50% in subjects who received rhGH, and in whom rhGH caused a potent protein anabolic effect. These results suggest that rhIGF-I may have a somatostatin-like effect. In addition, we found that rhIGF-I infusion is insufficient to promote protein anabolism. This may be due to the failure of rhIGF-I alone to induce a pivotal GH-dependent cofactor(s) necessary for IGF-I to elicit an anabolic effect on protein metabolism in humans.     

Effects of recombinant insulin-like growth factor I on insulin secretion and renal function in normal human subjects.

Insulin-like growth factor I (IGF-I) is an important mediator of growth hormone (GH) action and it appeared tempting to evaluate possible clinical applications. Recombinant IGF-I was infused s.c. at a dose of 20 micrograms/kg of body weight per hour during 6 days in two healthy adult subjects. Blood glucose and fasting insulin levels remained within normal limits and IGF-II levels were suppressed. In contrast to insulin, fasting C peptide levels were decreased. GH secretion was also suppressed by IGF-I. Our preliminary data allow us to distinguish between the effects of GH per se and those of IGF-I: GH causes hyperinsulinism, whereas IGF-I leads to decreased insulin secretion. Glomerular filtration rate, as estimated by creatinine clearance, increased to 130% of preinfusion values during the IGF-I infusion. Total creatinine and urea excretion remained unchanged. We conclude that IGF-I influences kidney function and, in contrast to GH, exerts an insulin-sparing effect. It may be speculated that the therapeutic spectrum of IGF-I is quite different from that of GH.     

Effects of progestin-opposed transdermal estrogen administration on growth hormone and insulin-like growth factor-I in postmenopausal women of different ages.

Prior studies in women have shown a positive correlation of endogenous estrogen levels with spontaneous and stimulated GH secretion and basal insulin-like growth factor-I (IGF-I) levels. In postmenopausal women, estrogen replacement therapy (ERT) by the oral route increases basal and GHRH-stimulated GH secretion but decreases basal IGF-I levels. To assess the corresponding effects of transdermal ERT (tERT) on this axis, we administered four 8-week regimens of transdermal 17 beta-estradiol (Estraderm; 0, 50, 100, or 150 micrograms/day) combined with oral medroxyprogesterone acetate (10 mg each day) during weeks 3-4 and 7-8 of each 8-week regimen (except placebo) to 28 healthy nonobese postmenopausal women, aged 45.3-71.8 yr. Basal levels of estradiol (E2), GH, and IGF-I as well as GH responsivity to bolus iv administration of GH-releasing hormone-(1-44) (1 micrograms/kg), were measured before tERT and at weeks 6 and 8 of each regimen; estrone (E1) levels were measured before tERT and at week 6 of each regimen. Before tERT, age was inversely correlated with both the peak GH response to GHRH (r = -0.43; P less than 0.02) and basal IGF-I levels (r = -0.37; P less than 0.05), but not with basal E2, E1, or GH levels. There were progressive increases in plasma E2 and E1 levels with increasing doses of tERT (P = 0.0001), independent of age (P greater than 0.2) and body mass index (P greater than 0.2). Mean basal GH and IGF-I levels were not altered significantly by tERT or medroxyprogesterone acetate. Peak and integrated GH secretory responses to exogenous GHRH decreased with increasing tERT dose (P less than 0.01) in both younger and older postmenopausal women. Our findings suggest that the known effects of tERT on bone and other tissues are not mediated via increases in circulating levels of immunoreactive GH or IGF-I, but do not preclude the possibility of tERT-induced increases in the biological activity or paracrine action of IGF-I.     

Effects of low-dose recombinant human insulin-like growth factor-I on insulin sensitivity, growth hormone and glucagon levels in young adults with insulin-dependent diabetes mellitus

Despite recent interest in the therapeutic potential of recombinant human insulin-like growth factor-I (rhIGF-I) in the treatment of diabetes mellitus, its mechanism of action is still not defined. We have studied the effects of low-dose bolus subcutaneous rhIGF-I (40 μg/kg and 20 μg/kg) on insulin sensitivity, growth hormone (GH) and glucagon levels in seven young adults with insulin-dependent diabetes mellitus (IDDM) using a randomized double-blind placebo-controlled crossover study design. Each was subjected to a euglycemic clamp (5 mmol/L) protocol consisting of a variable-rate insulin infusion clamp (6:00 to 8:00 ) followed by a two-dose hyperinsulinemic clamp (insulin infusion of 0.75 mU · kg⁻¹ · min⁻¹ from 8 to 10 and 1.5 mU · kg⁻¹ · min⁻¹ from 10 to 12 noon) incorporating [6,6 ²H₂]glucose tracer for determination of glucose production/utilization rates. Following rhIGF-I administration, the serum IGF-I level (mean ± SEM) increased (40 μg/kg, 655 ± 90 ng/mL, P < .001; 20 μg/kg, 472 ± 67 ng/mL, P < .001; placebo, 258 ± 51 ng/mL). Dose-related reductions in insulin were observed during the period of steady-state euglycemia (1 to 8 ) (40 μg/kg, 48 ± 5 pmol/L, P = .01; 20 μg/kg, 58 ± 8 pmol/L, P = .03; placebo, 72 ± 8 pmol/L). The mean overnight GH level (40 μg/kg, 9.1 ± 1.4 mU/L, P = .04; 20 μg/kg, 9.6 ± 2.0 mU/L, P = .12; placebo, 11.3 ± 1.7 mU/L) and GH pulse amplitude (40 μg/kg, 18.8 ± 2.9 mU/L, P = .04; 20 μg/kg, 17.0 ± 3.4 mU/L, P> .05; placebo, 23.0 ± 3.7 mU/L) were also reduced. No differences in glucagon, IGF binding protein-1 (IGFBP-1), acetoacetate, or β-hydroxybutyrate levels were found. During the hyperinsulinemic clamp conditions, no differences in glucose utilization were noted, whereas hepatic glucose production was reduced by rhIGF-I 40 μg/kg (P = .05). Our data demonstrate that in subjects with IDDM, low-dose subcutaneous rhIGF-I leads to a dose-dependent reduction in the insulin level for euglycemia overnight that parallels the decrease in overnight GH levels, but glucagon and IGFBP-1 levels remain unchanged. The decreases in hepatic glucose production during the hyperinsulinemic clamp study observed the following day are likely related to GH suppression, although a direct effect by rhIGF-I cannot be entirely discounted.     

Insulin secretion and insulin-like growth factor-I levels in active and controlled acromegaly

OBJECTIVE: We examined the contributions of growth hormone (GH) and insulin-like growth factor-I (IGF-I) to insulin sensitivity and beta-cell function in acromegaly. DESIGN: A cross-sectional study was used with continuous infusion of glucose with model assessment to determine insulin sensitivity and beta-cell function. PATIENTS: Ten patients with active acromegaly, seven with controlled disease and 22 normal individuals were studied. MEASUREMENTS: Glucose and insulin levels were measured fasting and at the end of the one-hour glucose infusion to calculate insulin sensitivity and beta-cell function. Random GH and IGF-I were recorded. Most patients had values of GH taken after a 100-g oral glucose tolerance test and K values from intravenous glucose tolerance tests. RESULTS Patients with active acromegaly had significantly decreased insulin sensitivity compared to the normal population (P less than 0.001), while those with controlled disease did not. There was a significant negative correlation between IGF-I and insulin sensitivity in those with active disease (P less than 0.05). Beta-cell function in both active and controlled patient groups was elevated compared to the normal population (P less than 0.05, P less than 0.01 respectively) and this was significantly related to IGF-I in the active group (P less than 0.05). GH levels did not correlate with fasting insulin, glucose, insulin sensitivity or beta-cell function in either group. CONCLUSIONS: Patients with active acromegaly have decreased insulin sensitivity and increased beta-cell function that are significantly related to IGF-I but not GH levels. When the disease is controlled, beta-cell function remains elevated but insulin sensitivity improves.     

Effects of photoperiod on the cessation of growth during autumn in male red deer and growth hormone and insulin-like growth factor-I secretion

Male red deer undergo seasonal cycles of food intake and growth rate, which are high during spring and low during winter, despite high quality food ad libitum. Hormonal profiles during the cessation of growth in autumn and the potential role of photoperiod in the timing of the observed changes have been investigated. Whether this seasonal decrease in growth affected the response of GH and IGF-I to fasting was also examined. Two groups of six male 1-year-old red deer were exposed to different photoperiods after the summer solstice. One group (C) was given a simulated natural photoperiod while the other group (SS) was maintained on a summer solstice photoperiod (16L:8D). GH was measured in blood collected continuously and divided into pools every 5 min for 24 h in the fed state and after a 48-h fast on two occasions; the first was in November before photoperiod manipulation began and the second was in April approximately 16 weeks after initiating treatments. IGF-I, prolactin, and testosterone were measured in weekly samples. Individual live weight and group food intake were also measured each week. The normal growth pattern seen in the C group was delayed in the SS group. Thus, from 7 March until the second GH sampling on 11 April the live weight of deer in group C fell; in contrast, deer in group SS continued to grow (-43 vs 186 g/day s.e.d. = 65.5, P < 0. 01). Food intake changes reflected the pattern of growth in both groups. Mean GH (P < 0.05), GH pulse amplitude (P < 0.01), and IGF-I (P < 0.001) declined in both groups from November to April. This decline was more marked in group C and in April these parameters were all lower in group C than in group SS (GH, P < 0.05; IGF-1, P < 0.01). Prolactin levels in April were also lower in group C than in group SS (P < 0.01); testosterone was not affected by treatment. Fasting increased mean GH and GH pulse amplitude in both groups in November (P < 0.05). In April, the fasting response differed between the groups. In group C, mean GH, pulse amplitude, and pulse frequency were all greater in the fasted state than in the fed state (P < 0.05), while in group SS there were no significant differences (P > 0.05). IGF-I was lower in the fasted state than in the fed state at both sampling dates (P < 0.001). The seasonal decline in food intake and growth is associated with decreased GH, IGF-I, and prolactin concentrations, and increased testosterone and the GH response associated with fasting. All these changes except those of testosterone were delayed or reduced by continued exposure to a summer solstice photoperiod in autumn. The decreased photoperiod in autumn may thus influence the normal timing of the seasonal growth cycle.     

Plasma ghrelin and growth hormone regulation in response to metabolic state in hybrid striped bass: Effects of feeding, ghrelin and insulin-like growth factor-I on in vivo and in vitro GH secretion

The regulation of growth hormone (GH) secretion by ghrelin during variable metabolic states is poorly understood. We examined plasma GH and ghrelin in hybrid striped bass (HSB) undergoing seasonally-based feeding and temperature manipulations. Fasting for 21 days (d) at 24 °C resulted in catabolism and up-regulation of plasma GH and ghrelin relative to fed controls. Continued fasting during cold-banking (14 °C, 90d) resulted in a further 43-fold increase in ghrelin while GH remained elevated. A subsequent 19 day refeeding period at 24 °C elicited hyperphagic and compensatory growth responses, accompanied by declines in ghrelin and GH. We then tested the role of ghrelin in stimulating GH release in vivo and in vitro. Intraperitoneal injections of ghrelin resulted in dose-dependent increases in plasma GH after 6 hours (h). Ghrelin also increased GH release from HSB pituitaries during 6 h incubations. Lastly, we assessed how metabolic state, ghrelin and insulin-like growth factor-I (IGF-I) affect in vitro pituitary GH release. Spontaneous GH release was 5.2-fold higher from pituitaries of fasted compared with fed animals. Ghrelin was equally effective in stimulating GH release from pituitaries of fed and starved animals, while it was ineffective in enhancing GH release from pituitaries of starved (21d) then refed (4d) HSB. Incubation with IGF-I inhibited GH release regardless of metabolic state. These studies are the first to show that seasonally-based periods of feed deprivation and low temperature yield sustained increases in GH secretion that are likely mediated, at least partially, through elevated ghrelin, reduced IGF-I negative feedback and fasting-induced spontaneous GH release.     

Overexpression of Escherichia coli oxidoreductases increases recombinant insulin-like growth factor-I accumulation

Transient overexpression of either DsbA or DsbC can double the yield of periplasmic insulin-like growth factor (IGF)-I in Escherichia coli to 8.5 g/liter. Strikingly, most of the overexpressed DsbA or DsbC is found in the reduced form, implying that enhanced disulfide isomerization is responsible for the substantial increase in IGF-I yield. All of the accumulated IGF-I has had the signal sequence removed, underscoring the secretion capacity of this organism as well as its utility for efficient production of polypeptide with the correct amino terminus. The overexpressed IGF-I constitutes approximately 30% of the total cell protein. Overproduction of active site mutants of DsbA instead of the wild-type gene do not produce this increase in yield. With wild-type levels of DsbA and DsbC, most of the secreted IGF-I is found in disulfide-linked aggregates, although 10% is soluble and about 5% is correctly folded. Contrary to expectations, overexpression of the disulfide oxidoreductases decreased the soluble fraction. Because the aggregated protein can be efficiently solubilized and refolded, the increased yield is a significant benefit for the production of IGF-I.     

Effects of insulin-like growth factor-I on cultured human coronary artery smooth muscle cells.

The growth-promoting effects of insulin-like growth factor-I (IGF-I) appear to be different in vascular smooth muscle cells from various segments of the arterial tree. Little information exists on human coronary artery smooth muscle cells (CoSMC), the primary elements of coronary atherosclerosis and post-angioplasty restenosis. In this study we determined the effects of IGF-I on cultured human CoSMC. Type I IGF receptors (IGF-R) were present on CoSMC as assessed by affinity cross-linking of 125I-IGF-I to monolayer cultures. IGF-I was a weak mitogen, 1.5-fold increase in [3H]thymidine incorporation, for CoSMC. However, IGF-I had a potent motility effect on CoSMC with a 314+/-12% increase in cell migration (P<0.001), comparable to that of 5% FBS. IGF-I-stimulated motility was partially inhibited by alphaIR-3, a specific IGF-R inhibitor (P<0.05). Addition of kistrin, a disintegrin, or LM609, a specific alpha(V)beta(3) integrin neutralizing antibody, abolished IGF-I-stimulated migration (P<0.001). This study indicates that IGF-I is a potent motility agent for human CoSMC via the alpha(V)beta(3) integrin receptor, but exerts little mitogenic effect. Because CoSMC migration plays a crucial role in atherosclerosis and restenosis, IGF-I blockade has the potential to limit lumen reduction.     

Effects of cycloheximide on hepatic and uterine insulin-like growth factor-I mRNA

To investigate differences in growth hormone (GH) and estrogen activation of insulin-like growth factor-I (IGF-I) expression, we have examined the effects of cycloheximide on hepatic and uterine IGF-I mRNA abundance in response to GH and 17 beta-estradiol (E2) respectively. In hypophysectomized (hypox) rats a single injection of GH significantly increased hepatic IGF-I mRNA 3.65 +/- 0.68-fold, P less than 0.005, 6 h after injection. Administration of cycloheximide 30 min prior to GH injection completely abolished this response. In contrast, in pituitary intact rats killed 6 h after administration of cycloheximide, hepatic IGF-I mRNA abundance was not significantly different from untreated control rats although the serum IGF-I concentration was significantly reduced; 119.9 +/- 11.8 vs. 270.2 +/- 48.7 ng/ml, P less than 0.005. In immature rats, injection of E2 (1 micrograms/100 g body weight) significantly increased uterine IGF-I mRNA 4.1 +/- 0.4-fold. Cycloheximide did not block the E2-induced increase in IGF-I mRNA but rather significantly enhanced the IGF-I response. These data indicate that continuing protein synthesis is required for GH induction of hepatic IGF-I mRNA in the hypox rat but is not required for E2 induction of uterine IGF-I mRNA. Furthermore, in pituitary-intact rats protein synthesis is not required for maintenance of hepatic IGF-I mRNA levels.     

Effects of recombinant insulin-like growth factor-I (IGF-I) and growth hormone on serum IGF-binding proteins in calorically restricted adults.

To determine the effects of exogenous insulin-like growth factor-I (IGF-I) and GH on IGF-binding proteins (IGFBP)-1, -2, and -3, six healthy nonobese adult volunteers underwent two 2-week periods of diet restriction (20 Cal/kg.day), and during the last 6 days of the first period received either IGF-I (12 micrograms/kg.h by iv infusion over 16 h) or GH (0.05 mg/kg.day by sc injection). During the second 2-week study period, the alternate hormone was given. IGFBP-1 and -2 concentrations were determined by specific RIA, and changes in IGFBP-3 were assessed by ligand blotting. Free IGF-I concentrations were measured by size-exclusion high pressure liquid chromatography, followed by RIA. Diet restriction alone did not affect either IGFBP-1 or -2 significantly. IGF-I treatment increased IGFBP-1 from 78 +/- 46 ng/mL (mean pretreatment) to 137 +/- 64 ng/mL (P less than 0.001; mean for the last 4 days of IGF-I). IGF-I also caused an increase in IGFBP-2 from 315 +/- 136 to 675 +/- 304 ng/mL (P less than 0.001). GH injections caused a modest decline in IGFBP-1 concentrations but had no effect on IGFBP-2 concentrations. By ligand blotting, both IGF-I and GH caused a modest increase in IGFBP-3 band intensity. In three subjects diet restriction alone caused a small decrease in IGFBP-3 hand intensity, and this was reversed by hormone treatment. Free IGF-I concentrations in serum were increased from 1.6% to 4.4% of the total IGF-I during IGF-I infusions. GH injections caused a smaller increase in free IGF-I concentrations. The results show significant increases in IGFBP-1 and -2 during IGF-I infusion. The change in IGFBP-3, while significant, is quantitatively less than that in experimental animals that have been given IGF-I while undergoing dietary restriction. The net effect of the changes in these three forms of IGFBPs is not sufficient to maintain a normal IGF-I-binding capacity in serum, because free IGF-I levels were increased disproportionately during the IGF-I infusions. Because hypoglycemia was noted in these subjects despite insulin suppression, these alterations in IGFBPs might have changed the tissue bioavailability of IGF-I and facilitated its hypoglycemic effects.