Natural products show diverse mechanisms of action against Clostridium difficile.

AIMS: To investigate the mechanisms of action of natural products with bactericidal (cinnamon root powder, peppermint oil, trans-cinnamaldehyde, menthol and zingerone) or bacteriostatic (fresh garlic bulb extract, garlic clove powder, Leptospermum honey and allicin) activity against two Clostridium difficile strains. METHODS AND RESULTS: Bactericidal products significantly reduced intracellular ATP after 1 h (P ≤ 0·01), quantified using the BacTiter-Glo reagent, and damaged the cell membrane, shown by the leakage of both 260-nm-absorbing materials and protein, and the uptake of propidium iodide. Bacteriolysis was not observed, determined by measuring optical density of treated cell suspensions at 620-nm. The effect of three bacteriostatic products on protein synthesis was quantified using an Escherichia coli S30 extract system, with Leptospermum honey (16% w/v) showing significant inhibition (P < 0·01). Lastly, no products showed elevated minimum inhibitory concentrations against antimicrobial-resistant C. difficile, determined by broth microdilution. CONCLUSIONS: Cytoplasmic membrane damage was identified as a mechanism of action that may contribute to the activity of several natural products against C. difficile. SIGNIFICANCE AND IMPACT OF THE STUDY: This study describes the possible mechanisms of action of natural products against C. difficile, yet the efficacy in vivo to be determined.

Targets of glucocorticoid action on TNF-alpha release by macrophages.

Glucocorticoid drugs affect virtually every cell type involved in inflammatory response, to some degree. Macrophage/monocytes (Mphi) are particularly sensitive, and glucocorticoids suppress release of most known Mphi inflammatory mediators, including TNF-alpha. In the case of TNF-alpha, several levels of regulation are already characterised and ongoing research hints at further glucocorticoid targets. The relative importance of transcriptional and post-transcriptional regulation is lineage-dependent and may also change during the course of Mphi differentiation. In human monocytic cell lines, glucocorticoids primarily suppress transcriptional activation through adjacent promoter binding sites for NF-kappaB transcription factor complexes and for complexes of c-Jun with activating transcription factor-2 (ATF-2). The goal of glucocorticoid research in inflammation is to develop drugs with the anti-inflammatory potential of glucocorticoids, but without the systemic toxicity. Each of the multiple targets for glucocorticoid action presents an opportunity for anti-inflammatory drug development. However, none of the known targets is unique to Mphi, and no single pathway is preeminent in all situations. Research is now directed at characterising targets and regulating them without systemic activation of the glucocorticoid receptor.

Glucocorticoids suppress tumor necrosis factor-alpha expression by human monocytic THP-1 cells by suppressing transactivation through adjacent NF-kappa B and c-Jun-activating transcription factor-2 binding sites in the promoter.

Glucocorticoid drugs suppress tumor necrosis factor-alpha (TNF-alpha) synthesis by activated monocyte/macrophages, contributing to an anti-inflammatory action in vivo. In lipopolysaccharide (LPS)-activated human monocytic THP-1 cells, glucocorticoids acted primarily on the TNF-alpha promoter to suppress a burst of transcriptional activity that occurred between 90 min and 3 h after LPS exposure. LPS increased nuclear c-Jun/ATF-2, NF-kappaB(1)/Rel-A, and Rel-A/C-Rel transcription factor complexes, which bound specifically to oligonucleotide sequences from the -106 to -88 base pair (bp) region of the promoter. The glucocorticoid, dexamethasone, suppressed nuclear binding activity of these complexes prior to and during the critical phase of TNF-alpha transcription. Site-directed mutagenesis in TNF-alpha promoter-luciferase reporter constructs showed that the adjacent c-Jun/ATF-2 (-106 to -99 bp) and NF-kappaB (-97 to -88 bp) binding sites each contributed to the LPS-stimulated expression. Mutating both sites largely prevented dexamethasone from suppressing TNF-alpha promoter-luciferase reporters. LPS exposure also increased nuclear Egr-1 and PU.1 abundance. The Egr-1/Sp1 (-172 to -161 bp) binding sites and the PU.1-binding Ets site (-116 to -110 bp) each contributed to the LPS-stimulated expression but not to glucocorticoid response. Dexamethasone suppressed the abundance of the c-Fos/c-Jun complex in THP-1 cell nuclei, but there was no direct evidence for c-Fos/c-Jun transactivation through sites in the -172 to -52 bp region. Small contributions to glucocorticoid response were attributable to promoter sequences outside the -172 to -88 bp region and to sequences in the TNF-alpha 3'-untranslated region. We conclude that glucocorticoids suppress LPS-stimulated secretion of TNF-alpha from human monocytic cells largely through antagonizing transactivation by c-Jun/ATF-2 and NF-kappaB complexes at binding sites in the -106 to -88 bp region of the TNF-alpha promoter.

Effects of stimulus and cell type on the expression of the -308 tumour necrosis factor promoter polymorphism.

The authors have previously demonstrated that the tumour necrosis factor (TNF) -308 G/A polymorphism affects the binding of transcription factors. In transient transfection assays in PMA stimulated U937 monocytes and Jurkat T cells, the A-containing TNF2 promoter has a 2-3-fold greater transcriptional activity than the TNF1 promoter in the presence of the TNF 3'UTR. In this study it was found that a difference in TNF1 and TNF2 promoter activities was only observed in U937 and Jurkat cells, and not in Raji (B cell line), HeLa (epithelial carcinoma cell line), HepG2 (hepatoma cell line) or THP-1 (monocyte), suggesting cell-type specific transcription factors or modifications may be involved in the formation of the -308 protein/DNA complex. Physiological stimulators, TNF and interferon gamma (IFN-gamma) did not cause differential promoter activity between TNF1 and TNF2, but LPS did with only the TNF2 promoter/3'UTR construct being significantly responsive to lipopolysaccharide (LPS) in U937 cells. In U937 cells, the -308 polymorphism affected transcription following differentiation by phorbol myristate acetate (PMA), retinoic acid, PMA plus LPS and PMA plus retinoic acid with an increase in nuclear factor binding to both TNF1 and TNF2 in the -323 to -285 region being observed. The greatest difference between TNF2 and TNF1 promoter activities (5-fold) was observed following PMA plus retinoic acid treatment of transfected U937 cells for 48h. During this time, U937 differentiated into cells with a macrophage-like morphology. An understanding of the cell type and stimuli specific requirements for differential expression of the -308 polymorphism may help elucidate the role the TNF -308 polymorphism plays in diseases where elevated TNF levels are thought to be important.

Altered leucocyte trafficking and suppressed tumour necrosis factor alpha release from peripheral blood monocytes after intra-articular glucocorticoid treatment.

OBJECTIVES: A generalised transient improvement may follow intra-articular administration of glucocorticoids to patients with inflammatory arthropathy. This may represent a systemic anti-inflammatory effect of glucocorticoid released from the joint, mediated through processes such as altered leucocyte trafficking or suppressed release of pro-inflammatory cytokines. Patients, who had received intra-articular injections of glucocorticoids were therefore studied for evidence of these two systemic effects. METHODS: Patients with rheumatoid arthritis were studied. Peripheral blood leucocyte counts, tumour necrosis factor alpha (TNF alpha) release by peripheral blood monocytes, blood cortisol concentrations, and blood methylprednisolone concentration were measured for 96 hours after intra-articular injection of methylprednisolone acetate. RESULTS: Measurable concentrations of methylprednisolone were present in blood for up to 96 hours after injection. Significant suppression of the hypothalamic-pituitary-adrenal axis persisted throughout this time. Altered monocyte and lymphocyte trafficking, as evidenced by peripheral blood monocytopenia and lymphopenia, was apparent by four hours after injection and resolved in concordance with the elimination of methylprednisolone. Granulocytosis was observed at 24 and 48 hours. Release of TNF alpha by endotoxin stimulated peripheral blood monocytes was suppressed at four hours and thereafter. Suppression was maximal at eight hours and was largely reversed by the glucocorticoid antagonist, mifepristone. CONCLUSIONS: After intra-articular injection of methylprednisolone, blood concentrations of glucocorticoid are sufficient to suppress monocyte TNF alpha release for at least four days and to transiently alter leucocyte trafficking. These effects help to explain the transient systemic response to intra-articular glucocorticoids. Suppression of TNF alpha is principally a direct glucocorticoid effect, rather than a consequence of other methylprednisolone induced changes to blood composition.

Dexamethasone suppresses release of soluble TNF receptors by human monocytes concurrently with TNF-alpha suppression.

Glucocorticoids suppress many monocyte functions, including endotoxin-stimulated release of TNF-alpha. Monocytes also release soluble receptors for TNF (sTNF-R), which can modulate TNF bioactivity. We therefore examined the effects of the glucocorticoid, dexamethasone, on the release of soluble forms of the 55 kDa and 75 kDa receptors for TNF (sTNF-R55 and sTNF-R75) by human monocytes and the human monocytic Mono Mac 6 cell line. Peripheral blood mononuclear cells (PBMC) spontaneously released 406 +/- 181 pg/10(6) cells of sTNF-R75 over 18 h in culture and Mono Mac 6 cells released 554 +/- 29 pg/10(6) cells. Lipopolysaccharide (LPS) exposure increased release of sTNF-R75 by 54 and 217%, respectively. Dexamethasone suppressed both spontaneous and LPS-stimulated release. The effect of dexamethasone was concentration dependent. At 1 mumol/L, dexamethasone suppressed the LPS-stimulated release of sTNF-R75 by 86% in PBMC and by 40% in Mono Mac 6 cells. Neither PBMC nor Mono Mac 6 cells released measurable amounts of sTNF-R55, but spontaneous release of sTNF-R55 from purified human monocytes (55 +/- 2 pg/10(6) cells over 18 h) was reduced by 45% in the presence of dexamethasone. Dexamethasone reduced bioactive TNF in PBMC cultures, as well as immunoassayable TNF-alpha, which indicates that suppression of TNF-alpha release was biologically more important than suppressed release of soluble inhibitors. Similar concurrent suppression of IL-1 beta and IL-1ra release occurred in PBMC and Mono Mac 6 cultures exposed to dexamethasone.

Suppression of human monocyte tumour necrosis factor-alpha release by glucocorticoid therapy: relationship to systemic monocytopaenia and cortisol suppression.

AIMS: Glucocorticoids suppress the release of tumour necrosis factor-alpha (TNF-alpha) by macrophages in vitro and cause monocytopaenia in vivo. These actions may contribute to anti-inflammatory and immunosuppressant effects. We therefore examined relationships between prednisolone concentration, suppression of monocyte TNF-alpha release, monocytopaenia and suppression of total cortisol concentration in healthy volunteers treated with a single dose (1.5 mg kg-1) of the glucocorticoid, prednisolone. METHODS: Monocyte numbers, total cortisol concentration and prednisolone concentration were measured in blood samples collected over 48 h after the dose. Plasma from these samples was also tested for its capacity to suppress lipopolysaccharide-induced TNF-alpha release from monocytes in autologous whole blood cultures. RESULTS: At 4 h after the dose, monocyte numbers in peripheral blood had fallen to a mean of 18% of the pre-dose level whilst plasma total cortisol had fallen to 9% of the pre-dose concentration. Monocyte numbers recovered in concordance with elimination of prednisolone and there was a significant relative monocytosis at 24 h. The recovery of plasma cortisol was delayed in comparison, with cortisol remaining significantly suppressed at 24 h. Plasma samples taken at 2 h after the dose (corresponding to peak plasma prednisolone concentration) suppressed the lipopolysaccharide-stimulated production of TNF-alpha by autologous blood monocytes to 27% of pre-dose control. Plasma collected at intervals over the 48 h from dosing also suppressed monocyte TNF-alpha release in relation to the prednisolone concentration therein. Suppression was largely reversed by the glucocorticoid antagonist, mifepristone. A similar relationship between prednisolone concentration and TNF-alpha suppression was observed when prednisolone was added to blood samples collected from the volunteers when they were drug-free. CONCLUSIONS: Blood concentration of prednisolone achieved after a dose of 1.5 mg kg-1 are sufficient to suppress monocyte TNF-alpha release and cause a biphasic change in peripheral blood monocyte numbers. Suppression of TNF-alpha is principally a direct glucocorticoid effect, rather than a consequence of other prednisolone-induced changes to blood composition.

Glucocorticoid modulation of human monocyte/macrophage function: control of TNF-alpha secretion.

Glucocorticoids suppress many functions in activated monocyte/macrophages, including the release of TNF-alpha. This is likely to contribute to the efficacy of glucocorticoids in some inflammatory diseases, such as rheumatoid arthritis, where TNF-alpha contributes to pathogenesis. Glucocorticoids suppress the activity of reporters which include TNF-alpha promoter regions and modify the activity of NF-kappa B family transcription factors in activated human monocytic cell lines, suggesting effects of glucocorticoids on TNF-alpha gene transcription. In addition, glucocorticoids have been reported to antagonise the enhanced translational efficiency of TNF-alpha mRNA which occurs at least after stimulation of murine monocytic cells. It is likely, therefore, that glucocorticoids act at several points in stimulated monocyte/ macrophages to reduce TNF-alpha secretion. Understanding glucocorticoid control of TNF-alpha secretion may explain some of the variability in response to GC in inflammatory diseases and may reveal means of inducing glucocorticoid-like anti-inflammatory effects in monocyte/macrophages without exposing other tissues to the adverse effects of glucocorticoids.

Dexamethasone antagonizes IL-4 and IL-10-induced release of IL-1RA by monocytes but augments IL-4-, IL-10-, and TGF-beta-induced suppression of TNF-alpha release.

The activities of monocyte-derived tumor necrosis factor (TNF)-alpha and interleukin (IL)-1 beta are potentially modified by IL-1RA and soluble receptors for TNF (sTNF-R), which are themselves monocyte products. IL-4, IL-10, TGF-beta, and glucocorticoids (GC) all suppress the lipopolysaccharide (LPS)-stimulated release of TNF-alpha and IL-1beta but vary in their effects on IL-1RA and sTNF-R. This raises the prospect of interactions between the cytokines and glucocorticoids, which may be antagonistic or additive on IL-1 and TNF activity. We, therefore, studied the interactions of the GC dexamethasone (Dex) with IL-4, IL-10, and transforming growth factor (TGF)-beta on the release of TNF-alpha and IL-1RA by human monocytes and the monocytic THP-1 cell line. Low concentration of Dex (10(-8)-10(-7)M) acted additively with low concentrations of IL-4 (0.01-1 ng/ml), IL-10 (0.01-0.1 U/ml), or TGF-beta (0.01-1 ng/ml) to profoundly suppress LPS-stimulated release of TNF-alpha by whole blood and, to a lesser degree, THP-1 cells. Dex also suppressed spontaneous release of IL-1RA from PBMC and THP-1 cells, whereas IL-4 and IL-10, but not TGF-beta, stimulated release. Dex antagonized the enhanced release in IL-4 and IL-10-stimulated cultures. The capacity to stimulate release of IL-1RA may contribute to the anti-inflammatory potential of IL-4 and IL-10 in monocyte/macrophage-mediated disease. GC, therefore, do not uniquely enhance the suppressive functions of IL-4 and IL-10 on monokine activity. The therapeutic benefit of combinations of GC and IL-4, IL-10 or TGF-beta in disease may depend on the roles of the individual monokines and antagonists in pathogenesis.

IL-4, IL-10 and IFN-gamma have distinct, but interacting, effects on differentiation-induced changes in TNF-alpha and TNF receptor release by cultured human monocytes.

Monocytes cultured in vitro differentiate to a macrophage-like phenotype and undergo functional changes, including reduced capacity for release of TNF-alpha and the soluble p55 receptor for TNF (sTNF-R55) but enhanced capacity for release of the soluble p75 receptor (sTNF-R75). The cytokines IL-4 and IL-10 act on monocytes to suppress the release of pro-inflammatory cytokines, including TNF-alpha, and to influence the release of sTNF-R. We therefore investigated the influence of differentiation over 15 days in vitro on the spontaneous and LPS- and IFN-gamma-induced release of TNF-alpha and sTNF-R from human monocytes and examined the actions of IL-4 and IL-10 on these. Unstimulated monocytes did not release TNF-alpha at any stage but released progressively larger amounts of sTNF-R75 with time. LPS-stimulated release of TNF-alpha declined substantially after the first day and was consistently suppressed by IL-10 and IL-4 but increased by IFN-gamma. Monocytes cultured with IL-10 released more sTNF-R75 at all times and expressed more mRNA for TNF-R75 at day 8. LPS stimulation consistently enhanced both spontaneous and IL-10-augmented release of sTNF-R75, whilst IFN-gamma co-stimulation consistently suppressed them. The influence of IL-4 on sTNF-R75 release, however, depended qualitatively on both the length of time in culture and on conditions of stimulation. The effects of LPS and IFN-gamma on TNF-alpha and sTNF-R75 release were progressively lost with increasing time in culture in the presence of IL-4. sTNF-R55 was not detectable after the first day of culture under any of these conditions. IL-4, IL-10 and IFN-gamma therefore have distinct, but interacting, effects on the balance between TNF-alpha and sTNF-R75 release by maturing monocytes. These interactions may be relevant to the pathogenesis or treatment of TNF-alpha-mediated diseases, where sTNF-R may act to neutralize or stabilise TNF, thereby modifying biological activity.

Tumor necrosis factor alpha and interleukin-1 alpha stimulate late shedding of p75 TNF receptors but not p55 TNF receptors from human monocytes.

Soluble receptors for TNF (sTNF-R) are present at elevated concentrations in the synovial fluid of patients with rheumatoid arthritis. They are presumably released by cells of the synovial membrane, including the monocyte-derived synovial macrophages. Cytokines from the synovium, including IL-1 and TNF-alpha, may stimulate release. We therefore examined the release of sTNF-R from monocytes exposed to IL-1 and TNF-alpha. Elutriator-purified human blood monocytes spontaneously released both the p75 and the p55 sTNF-R (1011 +/- 199 and 177 +/- 20 pg/10(6) cells, respectively, mean +/- SEM) during 48 h of in vitro culture. TNF-alpha and IL-1 alpha induced time- and concentration-dependent increases in the release of sTNF-R75 from monocytes, but neither had a measurable effect on the release of sTNF-R55. The release of sTNF-R75 was inhibited by cycloheximide. Neither lymphocytes nor polymorphonuclear leukocytes (PMN) released measurable sTNF-R spontaneously or in response to stimulation with IL-1 alpha, but TNF-alpha stimulated the release of small amounts of sTNF-R75 by PMN. The timing, cycloheximide sensitivity, and selectivity of stimulated release of TNF-R75 by monocytes are consistent with previous observations on other cell types of late (8-20 h) increased synthesis and turnover of cell surface TNF-R75, but not TNF-R55, after stimulation with TNF-alpha or IL-1. These observations help to explain why elevated levels of sTNF-R in synovial fluid coexist with enhanced expression of cell surface TNF-R on synovial macrophages in rheumatoid arthritis.

A system for assessment of monokine gene expression using human whole blood.

Monocyte derived cytokines (monokines) are important mediators in inflammatory diseases and cancer. Control of monokine expression is also a major therapeutic target in autoimmune inflammation. Whole blood cultures permit examination of monokine expression under conditions which emulate the in-vivo environment whilst avoiding many of the artefacts associated with monocyte separation and culture. Here we describe a system for measuring interleukin-1 beta, interleukin-1 alpha, interleukin-6 and tumour necrosis factor-alpha mRNA in stimulated human whole blood ex-vivo, which can be applied to specimens from treated patients. Oligodeoxyribonucleotide probes are designed to allow standardisation of hybridisation and washing procedures. Washing and reprobing of membranes in appropriate sequence permits measurement of each monokine mRNA and mRNA for glyceraldehyde-3-phosphate dehydrogenase in only 7 ml of lipopolysaccharide-stimulated human blood. The method has been used successfully in studies of dexamethasone and methotrexate action on lipopolysaccharide stimulated IL-beta gene expression.

Two inhibitors of pro-inflammatory cytokine release, interleukin-10 and interleukin-4, have contrasting effects on release of soluble p75 tumor necrosis factor receptor by cultured monocytes.

The biological activity of the pro-inflammatory cytokine, tumor necrosis factor (TNF)-alpha depends on the level of TNF-alpha itself, the expression of the p55 and p75 cell surface receptors for TNF on target cells and the concentrations of the natural inhibitors of TNF-alpha, the soluble p55 and p75 TNF receptors (TNF-R). Interleukin (IL)-10 and IL-4 are known to inhibit TNF-alpha production by monocytes. We, therefore, investigated the effects of IL-10 and IL-4 on the cell surface expression and release of TNF-R by human monocytes to determine whether these cytokines also indirectly modulated the biological activity of TNF-alpha. Exposure to IL-10 (1-10 U/ml) for 24 or 48 h increased soluble p75 TNF-R expression and concomitantly reduced surface expression of p75 TNF-R. Further, IL-1 alpha-stimulated production of TNF-alpha was diminished by IL-10 and only a small proportion of this TNF-alpha was bioactive, consistent with increased production of inhibitory soluble TNF-R. IL-10 also induced down-regulation of surface p55 TNF-R on monocytes, and increased release of soluble p55 TNF-R. However, the expression of soluble p55 TNF-R was much lower than soluble p75 TNF-R, indicating that it contributed less importantly to neutralization of TNF-alpha under these conditions. Like IL-10, IL-4 supressed the release of TNF-alpha by monocytes. In contrast to IL-10, however, IL-4 (0.1-10 ng/ml) supressed the release of soluble p75 TNF-R from monocytes in a dose-dependent manner. Release of soluble p55 TNF-R was also supressed by IL-4. IL-10, therefore, reduces the pro-inflammatory potential of TNF in three ways: by down-regulating surface TNF-R expression whilst increasing production of soluble TNF-R and inhibiting the release of TNF-alpha itself. This suggests that IL-10 may be useful in the treatment of diseases where overexpression of TNF-alpha occurs.

Differentiation of the U-937 promonocytic cell line induced by phorbol myristate acetate or retinoic acid: effect of aurothiomalate.

Tissue macrophages, which participate in chronic synovial inflammation, differentiate from haemopoietic precursors in bone marrow and subsequently in tissue. During this process, they acquire attributes which are essential for their function in inflammation. Modulation of this process may represent a means of regulating inflammatory competence of macrophages in inflammatory joint disease. The action of aurothiomalate (ATM), an anti-rheumatic gold compound, on the differentiation of a promonocytic cell line (U937) was, therefore, examined in in vitro systems. U937 cells exposed to retinoic acid (RA) for 4 days or to phorbol myristate acetate (PMA) for 2 days acquired characteristics of macrophages, including the capacity to produce superoxide (O2-), responsiveness to formyl-methionyl-leucyl-phenylalanine (fMLP) and reduced proliferation. The activity of transglutaminase also increased in RA-exposed cultures. The effect of ATM exposure on acquisition of these characteristics was small and differed between RA- and PMA-stimulated cells.

Protein degradation in bupivacaine-treated muscles. The role of extracellular calcium.

The time course of protein degradation and the influence of extracellular calcium and the calcium-channel blocker verapamil were investigated by measuring tyrosine release from the isolated rat soleus muscle exposed to the local anaesthetic agent bupivacaine. Degradation rates were reduced during the first 60-90 min and subsequently increased in muscles treated with bupivacaine concentrations of 1.5 mM or higher. When calcium was omitted from the incubation medium the initial reduction in degradation was greater and the subsequent increase was reduced or prevented. Overall, verapamil (10(-5)M or 10(-6)M) did not significantly alter the degree or time-course of protein degradation.

Bupivacaine-induced muscle injury. The role of extracellular calcium.

To investigate the role of extracellular calcium in bupivacaine-induced muscle injury, the effects of the drug on creatine kinase (CK) release and muscle ultrastructure were studied in the isolated rat soleus in the presence and absence of calcium and of the Ca-channel blockers verapamil and nifedipine. Control muscles maintained a constant CK release rate and normal morphology for at least 3 hours. CK release rates increased markedly after exposure to 1.5 mM and 5 mM bupivacaine and electron microscopy showed evidence of damage to mitochondria, sarcoplasmic reticulum and the plasmalemma of muscle fibres with disruption of the Z-lines, I-bands and M-lines of myofibrils. When calcium was omitted from the incubation medium, there was a 3-fold reduction in CK release rates; the morphological changes were less severe initially but by 120 min were comparable to those in muscles incubated with bupivacaine and calcium. Neither 10(-6) M verapamil nor 10(-6) M nifedipine reduced CK release or muscle fibre damage. Verapamil (10(-5) M) reduced CK release but not the severity of muscle damage. The findings indicate that extracellular calcium plays a part in mediating the muscle damage caused by bupivacaine but that other factors must also be involved, and that Ca-channel blockers do not prevent muscle damage.

Rat myocardial protein degradation.

1. Myocardial protein degradation rates were determined by following tyrosine release from rat isolated left hemi-atria in vitro. 2. After two 20 min preincubations the rate of tyrosine release from hemi-atria was constant for 4 h. 3. Skeletal muscle protein degradation was determined by following tyrosine release from rat isolated hemi-diaphragm (Fulks, Li & Goldberg, 1975). 4. Insulin (10(-7) M) inhibited tyrosine release from hemi-atria and hemi-diaphragm to a similar extent. A 48 h fast increased tyrosine release rate from hemi-diaphragm and decreased tyrosine release rate from hemi-atria. Hemi-diaphragm tyrosine release was inhibited by 15 mmol/l D-glucose but a variety of concentrations of D-glucose (0, 5, 15 mmol/l) had no effect on tyrosine release from hemi-atria. Five times the normal plasma levels of the branched-chain amino acids leucine, isoleucine and valine had no effect on tyrosine release from either hemi-atria or hemi-diaphragm.