Hypothalamo-pituitary-adrenal axis dysregulation in patients with rheumatoid arthritis after the dexamethasone/corticotrophin releasing factor test.

A defective hypothalamo-pituitary-adrenal axis response to inflammatory cytokines may contribute to the pathophysiology of rheumatoid arthritis (RA). The purpose of this study was to define further the mechanisms responsible for this dysregulation. Six normal individuals and seven patients with active RA were recruited and given an oral dose of dexamethasone at 2300 h the evening before the study. The next day, an i.v. catheter was fitted at 1300 h. Blood samples were collected between 1400 h and 1700 h before and after infusion (at 1500 h) of corticotrophin releasing factor (CRF). Plasma was separated and stored at-20 degrees C before radioimmunoassay for ACTH, cortisol and dihydroepiandrosterone (DHEA). Before the CRF challenge, ACTH and cortisol were significantly increased and DHEA significantly decreased in the patients with RA compared with the controls. Neither ACTH nor DHEA was significantly altered after CRF infusion. Control individuals did not mount a cortisol response to infusion of CRF. Similarly, four of the patients with RA did not respond to CRF. However, in contrast to the controls, three of the patients mounted an immediate and sustained cortisol response after receiving CRF. These data reveal that three of the seven patients with RA were able to escape from dexamethasone suppression and mount a cortisol response to CRF challenge. This suggests that there may be a subpopulation of patients with RA who have impaired glucocorticoid feedback. The implications of this alteration for disease progression remain to be determined.

Adaptations of the IGF system during malignancy: human skeletal muscle versus the systemic environment.

Presented in this study are data derived from a unique cohort of patients both with and without cancer, for whom we not only have serum samples, allowing us to investigate systemic factors impacting on skeletal muscle maintenance, but also primary skeletal muscle cultures giving us a model to mimic the in vivo muscle milieu. Possible local effects of autocrine/paracrine and endocrine IGF system components impacting on myoblast growth and differentiation could therefore be assessed. We report for the first time that the decrease in myoblast stem cell numbers seen with normal aging is lost in cancer patients. We further report that serum IGF-I, IGF-II and IGFBP-3 all show positive correlations with myoblast retrieval in control patients, but that with the exception of IGFBP-3 these correlations are lost in malignancy. Indeed IGF-II switches to a negative correlation with myotube formation in malignancy. Furthermore we provide initial evidence to suggest that there is an apparent altered regulation of local IGFBP-3 production during malignancy which may enable satellite cell proliferation, stem cell infiltration or both. Finally we show the importance of investigations not only monitoring the systemic impact of serum factors on skeletal muscle responses but also critically assessing the role that locally produced muscle IGFBP-3 may have on the systemic environment.

What is the role of the insulin-like growth factor system in the pathophysiology of cancer cachexia, and how is it regulated?

OBJECTIVE AND BACKGROUND: The cancer cachexia syndrome is characterized by anorexia, weight loss with muscle wasting and increased energy expenditure. It is associated with increased morbidity and mortality, but its aetiology is poorly understood and no effective therapeutic intervention is available. It may result from an imbalance between the activity or effect of anabolic and catabolic hormones, mediated by the inflammatory cytokines. IGF-I is a potent anabolic agent, with therapeutic potential. Our objective was to investigate the role and regulation of the IGF system in cancer cachexia. DESIGN AND PATIENTS: We set up a prospective study of 30 patients with newly diagnosed unresectable non-small cell lung cancer, together with a cross-sectional comparison group of healthy volunteers. MEASUREMENTS: We examined the relationship between aspects of the IGF system, including IGFBP-3 proteolysis (using Western ligand and immunoblotting and an in vitro IGFBP-3 protease assay); the inflammatory cytokines and their soluble receptors; and food intake and nutritional status (including biochemical and anthropometric assessments). RESULTS: Although we did not observe a marked reduction in food intake in the cancer patients, the majority lost weight and functionally important lean body mass. We observed GH resistance in the cancer patients, and intermittent proteolysis of IGFBP-3, which correlated with the circulating interleukin-6 (IL-6) concentration. The pattern of IGFBP-3 proteolysis was unusual, with a prominent 17-kDa fragment. Less IGFBP-3 proteolysis was associated with more weight loss, suggesting that this could be a protective counter-regulatory mechanism, increasing IGF-I bioavailability to the tissues. CONCLUSIONS: Cancer cachexia in humans is a complex condition. Patients tend to be GH resistant. The significance of the intermittent increases in IGFBP-3 proteolysis, which may be regulated by IL-6, remains uncertain. A better understanding of the pathophysiology should enable the development of novel therapeutic approaches.

Characterisation of the IGF system in a primary adult human skeletal muscle cell model, and comparison of the effects of insulin and IGF-I on protein metabolism.

In an attempt to address the complex and clinically challenging question of the causes of muscle wasting in patients with cachexia, we have developed a primary adult human skeletal muscle cell model. The cultured cells were characterised by immunocytochemistry using antibodies to the myofibrillar protein constituents desmin and titin. Myotube formation was confirmed biochemically by a fourfold increase in the activity of the muscle-specific enzyme creatinine kinase, and myoblast withdrawal from the cell cycle, which is essential for terminal differentiation, was associated with progressive retinoblastoma protein dephosphorylation. Having successfully confirmed the phenotype of these adult human muscle cells, we assessed their interaction with the insulin-like growth factor (IGF) system. IGF-I is known to stimulate myoblast survival, proliferation and differentiation in cell lines, and, like insulin, is a potent anabolic agent in the regulation of protein metabolism. We have shown that IGF-I stimulated both replication and differentiation of myoblasts, whilst fibroblast growth factor-2 stimulated replication but inhibited differentiation. Examining the IGF system during the process of terminal differentiation, we found that both myoblasts and myotubes expressed insulin, IGF-I and insulin-IGF-I hybrid receptors, with the levels of all three receptor types increasing on differentiation. The cells also produced a wide range of IGF binding proteins (IGFBPs) including IGFBP-2, IGFBP-4 and abundant IGFBP-3, which has not been shown to be produced by any other skeletal muscle cell line examined to date. Both insulin and IGF-I had anabolic effects on myotube protein metabolism at physiological concentrations. Insulin was more potent than IGF-I: use of the IGF analogue long R(3)IGF-I demonstrated that the effects of exogenous IGF-I on protein metabolism were not affected by the high levels of endogenous IGFBP production. In summary, we have developed and characterised a clinically relevant in vitro model with which to address the aetiology of muscle wasting associated with chronic catabolic conditions, and we anticipate that future work will enable the development of novel, effective therapeutic interventions.

The insulin-like growth factor system in critical illness: pathophysiology and therapeutic potential.

Insulin-like growth factor-I (IGF-I) mediates at least some of the anabolic actions of growth hormone (GH). Most IGF-I in the circulation is held in a 150 kD complex with IGF binding protein-3 (IGFBP-3). In critical illness there is GH resistance which results in low serum levels of IGF-I, although its bioavailability may initially be maintained by serum proteases which modify the IGFBP-3 and reduce its affinity for IGF-I. Attempts to treat the protein catabolism associated with critical illness by hyperalimentation have had only limited success. The use of recombinant human GH combined with nutritional support increases protein synthesis, but the GH resistance necessitates high doses and GH has adverse direct metabolic effects including insulin resistance and impaired glucose tolerance. Treatment with recombinant human IGF-I inhibits proteolysis but may cause hypoglycaemia if administered intravenously. Its effects are often transient and show tachyphylaxis. A combination of GH and IGF-I with nutritional support may be the most effective treatment to counter the catabolism associated with critical illness. The costs of such therapy could be offset by shorter hospital stays. Further controlled studies are necessary to establish the clinical effectiveness of growth factor treatment.