Heat shock factor activation in human muscles following a demanding intermittent exercise protocol is attenuated with hyperthermia.

AIM: The present study investigated whether increased activation of heat shock factors (HSF) following exercise relates primarily to the increased muscle temperature or to exercise in general. METHODS: Six subjects completed 40 min of intermittent cycling (15s:15s exercise:recovery at 300 +/- 22 W) at an ambient temperature of either 20.0 +/- 1.3 or 40.3 +/- 0.7 degrees C. Muscle biopsies were taken prior to and immediately following the exercise protocol with samples analysed for HSF DNA binding by electrophoretic mobility shift assay. RESULTS: Exercise at 40 degrees C resulted in significantly increased oesophageal (39.3 +/- 0.2 degrees C) and muscle temperature (40.0 +/- 0.2 degrees C) at the end of the exercise protocol compared with 20 degrees C (oesophageal, 38.1 +/- 0.1 degrees C; muscle, 38.9 +/- 0.2 degrees C). However, an increased DNA binding of HSF was not evident following exercise at 40 degrees C (reduced by 21 +/- 22%) whereas it increased by 29 +/- 51% following exercise at 20 degrees C. CONCLUSION: It appears that increased temperature is not the major factor responsible for activation of HSF DNA binding.

Skeletal muscles of aged male mice fail to adapt following contractile activity.

Skeletal muscle adapts rapidly following exercise by the increased production of heat-shock proteins (HSPs). The aim of this study was to examine the ability of muscle from adult and aged mice to produce HSPs following non-damaging exercise. Adult and aged B6XSJL mice were anaesthetized and their hind limbs were subjected to isometric contractions. At different time points, muscles were analysed for HSP production by Western and Northern blotting and by electrophoretic mobility-shift assay. HSP protein and mRNA levels in muscles from adult mice increased significantly following exercise. This was not evident in muscles of aged mice. In contrast, binding of the transcription factor heat-shock factor 1 (HSF1) was not grossly altered in muscles of aged mice compared with adult mice. The data suggest that the inability of muscles of aged mice to produce HSPs appears to be due to alterations during gene transcription.

Neuropeptide control of bone marrow neutrophil production is mediated by both direct and indirect effects on CFU-GM.

Noradrenaline- and peptide-containing nerve fibres project into the bone marrow and terminate in association with stromal cells and within the parenchyma. Peptidergic nerve terminals are also associated with antigen-processing and -presenting cells throughout the body and have been shown to be important in leucocyte trafficking and wound healing, as well as haemopoiesis. Here, we tested the in vivo effects of deleting the peripheral neuropeptide network on haemopoiesis and also investigated whether the target cell population for these substances was myeloid progenitor cells (colony-forming unit-granulocyte/macrophage, CFU-GM). Deletion of the neuropeptides, substance P (SP) and calcitonin gene-related peptide (CGRP) by capsaicin abrogates normal blood cell production. These neuropeptides produced significant stimulation of colony formation from unfractionated bone marrow and elicited production of soluble factors capable of stimulating highly enriched CFU-GM. CGRP also had a direct stimulatory effect on highly enriched CFU-GM. Noradrenaline elicited factors that inhibited colony formation and had no direct effect on CFU-GM. We conclude that the neuropeptides form the positive arm of a neural control system and that noradrenaline acts as a negative regulator.

Neuropeptide control of bone marrow neutrophil production. A key axis for neuroimmunomodulation.

Nerve fibers project into the bone marrow and terminate in association with stromal cells. Nerve terminals are also associated with antigen-processing and -presenting cells throughout the body and have been shown to be important in leukocyte trafficking and wound healing as well as hemopoiesis. Here we show that neuropeptide input to the bone marrow is vital to normal granulopoiesis and that deletion of the neuropeptides, substance P, and calcitonin gene-related peptide (CGRP), with the neurotoxin, capsaicin, abrogates normal blood cell production. Norepinephrine, neurokinins a and 2, and vasoactive intestinal peptide all have inhibitory effects on in vitro CFU-GM colony formation. Substance P, neurokinin 1, nerve growth factor, and CGRP have stimulatory effects on CFU-GM. Furthermore, in vitro experiments show that, apart from CGRP, all the neuroactive substances we tested operate through effects on accessory cells, stimulating the release of regulatory molecules that have a direct effect on purified CFU-GM.

Coordinated host defense through an integration of the neural, immune and haemopoietic systems.

Interactions between the neural and immune systems exist through humoral factors operating via the hypothalamic-pituitary-adrenal axis and cytokines acting over a relatively long distance. Anatomical evidence also suggests direct, hard-wired pathways of interaction and control through innervation of lymphoid organs and peripheral sites involved in host defense, including the thymus, spleen, lymph nodes, and skin. Recent evidence has demonstrated: 1) neural control of the bone marrow haemopoietic system, 2) interactions between peripheral nerve endings in the skin and epidermal Langerhans cells, and 3) peripheralization of leukocytes in the initial stages of stress. This leads us to propose that the nervous system is involved in host monitoring and coordination of host defense systems. If the brain is to have appropriate control of host defense mechanisms it must have: (a) afferent inputs monitoring host defense status, (b) efferent control pathways that modulate primary reactions to infection and damage, (c) efferent activation pathways to the myeloid defense system while the specific, lymphoid immune system is activated, and (d) inhibition of the proliferative lymphocytic response if the infection has been dealt with. We are investigating whether such a model, which allows for control and coordination of both the initial myeloid defense system and of the acquired immune response, is observed in mammals.

Bone marrow innervation regulates cellular retention in the murine haemopoietic system.

An anatomical analysis of the innervation of murine femora revealed intimate association of haemopoietic and stromal cells with nerve fibres. The mechanical denervation of these femora resulted in significant mobilization of cells into the peripheral blood within 24h. There was a decrease in femoral cellularity and analysis of the type of cells mobilized also revealed that there was an increase in progenitor cells in the peripheral blood. In non-splenectomized mice these progenitor cells were quickly cleared from the circulation. Chemical sympathectomy of mice with 6-hydroxydopamine resulted in decreased bone marrow cellularity without a change in bone marrow or peripheral blood progenitor cell numbers, nor the sustained rise in peripheral leucocytes observed with whole nerve denervation. These observations argue for selective control of mobilization by the nervous system and also indicate possible control of proliferation within the bone marrow. We conclude that the innervation has an important role in the maintenance of the blood-marrow interface, control of peripheral blood cell numbers, and mobilization of colony forming cells into the periphery.