Relationship between Vitamin D Status and Autonomic Nervous System Activity

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC-BY) license (http://creativecommons.org/licenses/by/4.0/).Vitamin D deficiency is associated with increased arterial stiffness. However, the mechanisms underlying this association have not been clarified. The aim was to investigate whether changes in autonomic nervous system activity could underlie an association between 25 hydroxy vitamin D and arterial stiffness. A total of 49 subjects (age = 60 8 years, body mass index = 26.7 4.6 kg/m2, 25 hydroxy vitamin D = 69 22 nmol/L) underwent measurements of pulse wave velocity (PWV) and augmentation index (AIx), spontaneous baroreflex sensitivity, plasma metanephrines and 25 hydroxy vitamin D. Subjects with 25 hydroxy vitamin D 50 nmol/L were restudied after 200,000 International Units 25 hydroxy vitamin D. Plasma metanephrine was positively associated with AIx (p = 0.02) independent of age, sex, smoking and cholesterol and negatively associated with 25 hydroxy vitamin D (p = 0.002) independent of age, sex and season. In contrast, there was no association between baroreflex sensitivity and 25 hydroxy vitamin D (p = 0.54). Treatment with vitamin D increased 25 hydroxy vitamin D from 43 5 to 96 24 nmol/L (p < 0.0001) but there was no significant change in plasma metanephrine (115 25 vs. 99 39 pmol/L, p = 0.12). We conclude that as plasma metanephrine was negatively associated with 25 hydroxy vitamin D and positively with AIx, it could mediate an association between these two variables. This hypothesis should be tested in larger interventional studies

Opposing effects of rheumatoid arthritis and low dose prednisolone on arginine metabolomics

This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ This author accepted manuscript is made available following 12 month embargo from date of publication (Oct 2017) in accordance with the publisher’s archiving policyBackground and aims The effects of low dose prednisolone on circulating markers of endothelial function, the arginine metabolites asymmetric dimethyl arginine (ADMA), mono methyl arginine (MMA), and homoarginine, are uncertain. We assessed whether patients with rheumatoid arthritis have perturbations in arginine metabolite concentrations that are reversed by low dose prednisolone. Methods Eighteen rheumatoid arthritis patients who had not taken prednisolone for >6 months (non-glucocorticoid (GC) users), 18 rheumatoid arthritis patients taking continuous oral prednisolone (6.5 ± 1.8 mg/day) for >6 months (GC users) and 20 healthy controls were studied. Fasting plasma concentrations of ADMA, MMA, and homoarginine were measured by ultra-performance liquid-chromatography. Baseline data from non-GC users were compared with healthy controls to assess the effect of rheumatoid arthritis. The change in arginine metabolites in non-GC users after 7 days of prednisolone (6 mg/day) was used to assess the acute effects of prednisolone. Baseline data from non-GC users were compared with GC users to assess the chronic effects of prednisolone. Results Non-GC users had higher ADMA (0.59 ± 0.03 vs. 0.47 ± 0.01 μM, p = 0.004) and MMA concentrations (0.10 ± 0.01 vs. 0.05 ± 0.00 μM, p < 0.001) than controls. The only change with acute prednisolone was a reduction in homoarginine (1.23 ± 0.06 vs. 1.08 ± 0.06 μM, p = 0.04) versus baseline. GC users had lower concentrations of ADMA (0.51 ± 0.02 vs. 0.59 ± 0.03 μM, p = 0.03) than non-GC users. Conclusions Rheumatoid arthritis patients have higher concentrations of ADMA and MMA, inhibitors of endothelial function. Chronic, but not acute, prednisolone therapy is associated with a lower ADMA concentration, suggesting a salutary effect of long-term glucocorticoid treatment on endothelial function

Mechanisms underlying glucocorticoid-induced protein wasting and potential treatment with anabolic hormoness

Protein wasting is a complication of glucocorticoid (GC) therapy. It causes substantial morbidity and there is no treatment. This thesis investigates the metabolic mechanisms underlying GC-induced protein wasting and the potential for anabolic hormones to reverse protein loss. The models of GC excess were Cushing's syndrome and GC therapy. Whole body protein metabolism was assessed using the leucine turnover technique and body composition by dual-energy X-ray absorptiometry to estimate lean body mass (LBM) and fat mass (FM).As previous studies demonstrated that LBM and FM influenced rates of protein metabolism, the magnitude of body compositional abnormality in Cushing's syndrome was determined. After accounting for the greater FM (30%) and lesser LBM (15%), protein metabolism in Cushing's syndrome was characterised by a significant increase in protein oxidation, an abnormality that leads to irreversible protein loss. Successful treatment of Cushing's syndrome normalised protein oxidation.Studies of the acute and chronic effects of therapeutic GCs revealed a time-dependent effect on protein metabolism. GCs acutely increased protein oxidation. However, the rate of protein oxidation during chronic therapy at a similar dose was not significantly different to untreated control subjects. This time-dependent change suggests that GC-induced stimulation of protein oxidation does not persist and could represent a metabolic adaptation to limit protein loss. This finding contrasts with that in Cushing's syndrome, where protein oxidation is persistently elevated. This difference may represent a dose effect.Studies in GH-deficient subjects revealed that GH induced a fall in protein oxidation that was significantly correlated with a subsequent gain in LBM. This suggests that the anabolic potential of a therapeutic substance can be predicted by its ability to suppress protein oxidation acutely.Finally, the potential for GH and androgens to reverse the metabolic effects of GCs was assessed. A preliminary study in GC users revealed that a GH dose of 0.8 mg/d was effective in reducing protein oxidation. In a subsequent study, the GH-induced reduction in protein oxidation in women on GCs was enhanced by combined treatment with dehydroepiandrosterone, an androgen.In summary, GCs induce protein loss by stimulating protein oxidation. GH reverses this effect and this action is enhanced by coadministration of androgens. GH and androgens may be used therapeutically to prevent protein loss induced by GCs