The riddle of cholinergic histamine release from mast cells

The cutaneous non-neuronal cholinergic system and smoking related dermatoses: studies of the psoriasis variant palmoplantar pustulosis

Palmoplantar pustulosis (PPP) is probably the inflammatory skin disease most strongly associated to smoking. The disease is common in middle-aged, smoking women, and is chronic, sometimes disabling and characterized by pustules, erythema and scaling on the soles and palms. It is often treatment-resistant. PPP patients have a co-morbidity with an increased risk of autoimmune thyroid disease, celiac disease/gluten intolerance, abnormal calcium homeostasis, diabetes type 2, and depression. The sweat gland apparatus is involved in the pathogenesis of PPP since a) the normal structure of the acrosyringium is abolished so the keratin pattern differs to that in normal palmar skin; b) granulocytes migrate outwards in the acrosyringium forming the pustule in the stratum corneum. Acetylcholine (ACh) is the main inducer of sweating. With immunohistochemistry the ACh synthesizing enzyme choline acetyltransferase (ChAT) and the ACh-degrading enzyme acetylcholinesterase (AChE) were found to be strongly expressed in the gland and duct as were the alpha-3 and alpha-7 nicotinic acetylcholine receptors (nAChRs). Smoking influenced the staining intensity of the enzymes and the alpha-3 nAChR in healthy subjects. In involved PPP skin there was a massive infiltration of granulocytes expressing ChAT and alpha-3 nAChR, and mast cells expressing AChE indicating a role for acetylcholine in inflammation. Cessation of smoking resulted in fewer pustules, and less scaling and erythema. The mechanisms for the effect of nicotine/smoking in PPP are still unknown but nicotine may lead to enhanced inflammation in consideration of the properties of the sweat duct and/or nicotine might facilitate autoimmune reactions.

The distribution of choline acetyltransferase- and acetylcholinesterase-like immunoreactivity in the palmar skin of patients with palmoplantar pustulosis

The distribution of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) in involved skin in patients with palmoplantar pustulosis (PPP) and in normal palmar skin in healthy non-smokers and smokers has been studied by immunohistochemistry, especially in relation to the sweat gland apparatus. The sweat gland and its duct showed ChAT- and AChE-like immunoreactivity (LI) of varying intensity in all three groups and with stronger reactivity than in the epidermis. ChAT-LI was present in the coil and in the duct except in the corneal layer. Smokers and patients with PPP displayed significantly fewer ChAT+ acrosyringia than non-smokers. In the patients with PPP, the granulocytes in the pustules and in the papillary dermis displayed ChAT-LI. Western blot analysis of granulocytes from peripheral blood from healthy donors confirmed the presence of ChAT-like proteins in large amounts in neutrophils and small amounts in eosinophils. AChE-LI of varying intensity was found in all parts of the sweat gland apparatus in all three groups. The strongest AChE-LI in the acrosyringia was seen in the lowest part of the stratum corneum, where the PPP pustules are located. No significant differences in staining pattern or intensity were found between the coils, nerve fibres surrounding the coils or ducts. The number of mast cells in the papillary dermis was about four times larger in the patients with PPP than in the control subjects. AChE-LI was observed in about 25% of the mast cells in non-smoking control subjects and in patients with PPP, but only in 10% of those in the smoking control subjects. Our findings indicate that the (non-neuronal) cholinergic system may be involved in cutaneous inflammatory processes.

Augmentation of allergic reactions by several pesticides

The augmentative effects of several pesticides on histamine release from mast cells of rats that had been sensitized passively by anti-dinitrophenol (DNP) monoclonal IgE antibodies were investigated in vitro. Various pesticides, especially phenthoate (PAP), chlornitrofen (CNP) and paraquat (PQ), increased histamine release. This increase was not observed in histamine release with non-antigen or induction by calcium ionophore A23187 or compound 48/80. Passive cutaneous anaphylaxis (PCA) was examined, and an increase of PCA was observed with PAP and PQ, but not with CNP, while an increase of tumor necrosis factor-alpha (TNF-alpha) production was observed with CNP and PQ, but not PAP. These results suggest that various pesticides as environmental pollutants exacerbate allergic diseases.

Murine and human mast cell express acetylcholinesterase

Expression of catalytically active protein was detected in a murine mast cell line. The primary type of AChE mRNA produced by these cells was found to be the brain and muscle type by PCR amplification of alternative exons from the 3' of mast cells AChE cDNA. AChE was further found to be expressed in the HMC-1 the human mast cell precursor line. Furthermore, utilizing the single cell RT-PCR method we detected AChE mRNA expression in Fc epsilon RI-positive single cells derived from human colonic mucosal biopsies. Our findings predict the involvement of mast cell AChE in neuronal-mast cell interactions.

A critical review of the afferent pathways and the potential chemical mediators involved in cardiac pain

There is considerable evidence that on the anterior surface of the heart (which is usually supplied by the left anterior descending and the proximal part of the left circumflex coronary arteries), sympathetic efferent reflexes characterized by tachycardia and/or hypertension predominate following experimental or pathological perturbations. These cardiovascular reflexes are accompanied by an increase in presumed nociceptive afferent traffic and, in pathological condition, by pain. In these experiments, there is generally no effect of vagotomy on afferent nerve traffic, and lower cervical and upper thoracic sympathectomies help provide relief from angina. On the other hand, experimental or pathological perturbations involving the inferior-posterior surface of the heart (supplied by the right and distal parts of the left circumflex coronary arteries), are characterized by vagal efferent reflexes, resulting in bradycardia and/or hypotension. These reflexes are accompanied by an increase in vagal afferent nerve traffic and, in pathological conditions, by pain. In these experiments, vagotomy generally abolishes such cardiovascular reflexes, and lower cervical and upper thoracic sympathectomies are not effective in the relief from angina. Although cardiac sympathetic afferents are unquestionably involved in the central transmission of nociceptive information from the heart, it is also likely that there is a contributing role from the vagus in cardiac pain. It is important experimentally to understand the natural stimulus that gives rise to angina. In the clinical situation, a decrease in coronary blood flow or an increase in the metabolic demands of the myocardium due to increased work are obvious precipitating factors which lead to myocardial ischemia. In the experimental situation, occlusion of the coronary arteries is often used as a stimulus which mimics myocardial ischemia. As people who frequently experience angina have varying degrees of coronary artery disease, it is difficult to accept that the state of the coronary arteries of the normal experimental animal bear any resemblance to the state of the coronary arteries under pathological conditions. That is, the gain of homeostatic reflexes, the basal concentrations of neuroactive substances in the plasma, the myocardium and the afferent terminals, the excitability of the afferents, access of chemical mediators (e.g. bradykinin, 5-HT, adenosine, histamine, prostaglandins, potassium, lactate), to afferents, and the overall function of the animal are all significantly different. We have no idea how control mechanisms have been altered in the person with severe coronary artery disease compared to the normal patient or the "normal" experimental animal.(ABSTRACT TRUNCATED AT 400 WORDS)

Histamine release by free radicals: paracetamol-induced histamine release from rat peritoneal mast cells after in vitro activation by monooxygenase

The incubation of paracetamol with isolated rat serosal mast cells evokes the release of histamine only in the presence of (S10) liver microsomes obtained from PCB or phenobarbital treated rats. The release of histamine was not accompanied by a leakage of lactate dehydrogenase and was blocked by the antioxidant alpha-tocopherol and by D-mannitol, an hydroxyl free radicals scavenger. The data are consistent with the metabolic oxidation of paracetamol in the generation of reactive intermediates capable of activating the sequential exocytosis.