Role of antigen and,antibody in the regulation of the immune response

The enzyme dextranase could degrade antigenic dextran in vivo even when given 6-15 d after the antigen. Dextranase injected after the antigen suppressed the immune response when given 24 but not 48 h after the antigen, indicating that the antigen must interact with the immune system for 48 h to initiate a response. Thereafter, the B cells are independent of further antigen stimulation. To show whether antibody-mediated suppression of the immune response was determinant specific FITC-conjugated SRC were applied as immunogen and antibodies were raised both against the carrier (SRC) and the FITC hapten. When these antibodies were injected 1-3 h after the immunogen they only suppressed the immune response to the corresponding determinant. Anti-carrier antibodies usually enhanced the response to the hapten. Therefore, antibody-mediated suppression of the immune response is determinant-specific and cannot be mediated in vivo to a detectable extent by the Fc part of the antibodies.     

Inhibitory effects of HgCl2 on excitation-secretion coupling at the motor nerve terminal and excitation-contraction coupling in the muscle cell

Summary 1. Indirect and direct twitch (0.1-Hz) stimulation of the rat phrenic nerve-diaphragm disclosed that the inhibitory effect of HgCl₂, 3.7 × 10^–5 M, on the neuromuscular transmission and in the muscle cell, was accelerated by 10-sec periods of 50-Hz tetanic stimulation every 10 min. This activity-dependent enhancement suggested an inhibitory mechanism of HgCl₂ related to the development of fatigue, like membrane depolarization or decreased excitability, decreased availability of transmitter, or interference with the factors controlling excitation-secretion coupling of the nerve terminal, i.e. (Ca²⁺)₀ or (Ca²⁺)_i, and excitation-contraction coupling in the muscle cell, i.e., (Ca²⁺)_i.2. During both indirect and direct stimulation, HgCl₂-induced inhibition was enhanced markedly by pretreatment with caffeine, which releases Ca²⁺ from endoplasmic and sarcoplasmic reticulum in the nerve terminal and muscle cell, respectively. This caffeine-induced enhancement was completely antagonized by dantrolene, which inhibits the caffeine-induced release. However, dantrolene alone did not antagonize the HgCl₂-induced inhibition.3. Since caffeine depletes the intracellular Ca²⁺ stores of the smooth endoplasmic reticulum, HgCl₂ probably inhibits by binding to SH groups of transport proteins conveying the messenger function of (Ca²⁺)_i. In the muscle cell this leads to inhibition of contraction. In the nerve terminal, an additional enhancement of the HgCl₂-induced inhibition, by inhibiting reuptake of choline by TEA and tetanic stimulation, suggested that HgCl₂ inhibited a (Ca²⁺)_i signal necessary for this limiting factor in resynthesis of acetylcholine.4. The (Ca²⁺)₀ signal necessary for stimulus-induced release of acetylcholine was not affected by HgCl₂. Hyperpolarization in K⁺-free solution antagonized the inhibitory effect of HgCl₂ at indirect stimulation, and Ca²⁺-free solution enhanced the inhibitory effect at direct stimulation. K⁺ depolarization, membrane electric field increase with high Ca²⁺, membrane stabilization with lidocaine, and half-threshold stimulation, did not change the inhibitory effect of HgCl CH₃HgCl, 1.85 × 10^–5 M, disclosed a synergistic interaction with caffeine during direct, but not during indirect, stimulation.