Sympathetic nerve contact causes maturation of mast cells in vitro

Using a tissue culture model developed to study interactions between peripheral neurons and mast cells (MC), time-lapse microscopy showed that RBL- 2H3 cells (a model of the mucosal MC) formed attachments with sympathetic neurons, ceased to divide, and moved along neurites toward the cell bodies. Electron microscopy showed significant increase in granules compared to intrinsic controls (RBL cells in coculture but lacking neurite contact). In studies using cohort cultures of 12- to 14-day-old sympathetic neurons, RBL cells adhered more rapidly to neurons than did control YB2/0 cells (a neutral target cell), and were inhibited in growth compared with RBL cells cultured in parallel without neurons. RBL cells cocultured with neurons for 24–48 h took up significantly more ³H-5HT and released a significantly larger percentage of ³H-5HT in response to the calcium ionophore A23187 than RBL cells in parallel pure cultures. Since no change in MC phenotype was seen, we conclude that contact with nerve membrane may be a developmental cue leading to maturation of MC. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 173–182, 1998     

Obligatory Activation of SRC and JNK by GDNF for Survival and Axonal Outgrowth of Postnatal Intestinal Neurons

The neurotrophin GDNF acts through its co-receptor RET to direct embryonic development of the intestinal nervous system. Since this continues in the post-natal intestine, co-cultures of rat enteric neurons and intestinal smooth muscle cells were used to examine how receptor activation mediates neuronal survival or axonal extension. GDNF-mediated activation of SRC was essential for neuronal survival and axon outgrowth and activated the major downstream signaling pathways. Selective inhibition of individual pathways had little effect on survival but JNK activation was required for axonal maintenance, extension or regeneration. This was localized to axonal endings and retrograde transport was needed for central JUN activation and subsequent axon extension. Collectively, GDNF signaling supports neuronal survival via SRC activation with multiple downstream events, with JNK signaling mediating structural plasticity. These pathways may limit neuron death and drive subsequent regeneration during challenges in vivo such as intestinal inflammation, where supportive strategies could preserve intestinal function.

     

The role of CD4+ lymphocytes in the susceptibility of mice to stress-induced reactivation of experimental colitis.

Idiopathic inflammatory bowel disease is a chronic relapsing condition. The role of stress in causing relapses of inflammatory bowel disease remains controversial. We now show that colitis induced in mice by dinitrobenzenesulfonic acid (DNBS) resolves by 6 weeks, but can subsequently be reactivated by stress plus a sub-threshold dose of DNBS, but not by DNBS alone. Stress reduced colonic mucin and increased colon permeability. Susceptibility to reactivation by stress required CD4+ lymphocytes and could be adoptively transferred. We conclude that stress reactivates experimental colitis by facilitating entry of luminal contents that activate previously sensitized CD4 cells in the colon.     

Disruption of CD40-CD40 ligand pathway inhibits the development of intestinal muscle hypercontractility and protective immunity in nematode infection

In our previous studies, we demonstrated that during Trichinella spiralis infection, T helper (Th) 2 cells contribute to the development of intestinal muscle hypercontractility and worm expulsion from the gut via STAT6. In addition, we have linked the altered muscle contractility to the eviction of the parasite and thereby to the host defense. However, the initial events linking infection to the development of muscle hypercontractility are poorly understood. In this study, we examined the contribution of CD40-CD40 ligand (CD40L) interaction in the development of intestinal muscle hypercontractility, in monocyte chemoattractant protein-1 (MCP-1) production, and in the Th2 response in CD40 ligand-deficient (CD40L -/-) mice infected with T. spiralis. Expulsion of intestinal worms was substantially delayed in CD40L -/- mice compared with the wild-type mice after T. spiralis infection. Consistent with delayed worm expulsion, there was a significant attenuation of intestinal muscle contractility in CD40L -/- mice. Infected CD40L -/- mice also exhibited marked impairment in the production of MCP-1, IL-4, IL-13, IgG1, IgE, and mouse mucosal MCP 1 (MMCP-1), and in goblet cell response. These results demonstrate that CD40-CD40 ligand interaction plays an important role in MCP-1 production, Th2 response, intestinal muscle hypercontractility, and worm expulsion in nematode infection. The present data suggest that the early events leading to the generation of Th2 response include CD40-CD40 ligand interaction, which subsequently influences the production of Th2 cytokines, most likely via upregulation of MCP-1.     

Neural regulation of intestinal smooth muscle growth in vitro

The loss of intrinsic neurons is an early event in inflammation of the rat intestine that precedes the growth of intestinal smooth muscle cells (ISMC). To study this relationship, we cocultured ISMC and myenteric plexus neurons from the rat small intestine and examined the effect of scorpion venom, a selective neurotoxin, on ISMC growth. By 5 days after neuronal ablation, ISMC number increased to 141+/-13% (n = 6) and the uptake of [(3)H]thymidine in response to mitogenic stimulation was nearly doubled. Atropine caused a dose-dependent increase in [(3)H]thymidine uptake in cocultures, suggesting the involvement of neural stimulation of cholinergic receptors in regulation of ISMC growth. In contrast, coculture of ISMC with sympathetic neurons increased [(3)H]thymidine uptake by 45-80%, which was sensitive to propranolol (30 microM) and was lost when the neurons were separated from ISMC by a permeable filter. Western blotting showed that coculture with myenteric neurons increased alpha-smooth muscle-specific actin nearly threefold to a level close to ISMC in vivo. Therefore, factors derived from enteric neurons maintain the phenotype of ISMC through suppression of the growth response, whereas catecholamines released by neurons extrinsic to the intestine may stimulate their growth. Thus inflammation-induced damage to intestinal innervation may initiate or modulate ISMC hyperplasia.     

Intracellular cyclic AMP concentration modulates gap junction permeability in parturient rat myometrium.

We investigated whether cell-to-cell coupling between myometrial cells of parturient rats is influenced by intracellular adenosine 3',5'-cyclic monophosphate (cAMP) concentration. To evaluate the coupling, we measured input resistance (Ro) and injected Lucifer Yellow (LY) using microelectrode techniques. The intercellular spread of the dye was then observed. Longitudinal muscle strips from rat myometrium were exposed to isoproterenol, forskolin, or dibutyryl cAMP (DB-cAMP) to elevate cAMP. Isoproterenol (10(-11)-10(-6) M) and DB-cAMP (10(-5)-10(-3) M) hyperpolarized the resting membrane potential (Em) and increased Ro in a dose-dependent fashion. Forskolin (10(-6) M) also hyperpolarized Em and increased Ro. When LY was injected into a single cell, LY spread rapidly and extensively to neighboring cells in parturient control tissues, while LY transfer was completely blocked by any of the three agents at high concentrations. The increased Ro and blocked transfer of LY owing to these agents indicate that the cell-to-cell coupling was decreased both electrically and metabolically. Myometrial cells of parturient rats show increased number and size of gap junctions (GJs). The rapid and reversible decrease in coupling is interpreted to reflect the reduced permeability of GJs between the muscle cells because of an elevation of cAMP. Control of GJ permeability by this second messenger may be important for the physiological regulation of intercellular coupling and the extent of synchronizing and coordinating electrical, metabolic, and contractile activity in the uterine wall during pregnancy and parturition.     

Mast cell ionic channels: significance for stimulus-secretion coupling.

The activation of mast cells (MC) due to immunological stimulation causes an immediate and dramatic inflammatory response. We review current evidence indicating that the membrane permeabilities for calcium, chloride, sodium, and potassium have a significant role in the activation of these cells, and in some cases, specific ionic channels have been identified. Moreover, a number of intracellular mechanisms controlling these channels are pointed out, including different classes of G proteins, intracellular calcium, cAMP, and products of phosphoinositol breakdown. However, the interplay between factors controlling membrane conductances for different ions is not currently understood. The diversity of ionic effects on MC activation is depicted, illustrating that the ionic mechanisms of MC activation are specific for different MC types. Since nerve/mast cell interaction is a key element in the burgeoning field of neuroimmunology, we discuss the role of ionic channels as targets of neurotransmitter action in MC activation.