Catecholamine- and endotoxin-influenced cutaneous basophil hypersensitivity in chickens.

1. Catecholamines suppress cutaneous basophil hypersensitivity (CBH) to intradermal phytohemagglutinin (PHA-P) challenge in chickens. 2. E. coli 0127:B8 endotoxin, reserpine, and propranolol prevented a norepinephrine-induced suppression of CBH. 3. PHA-P induced CBH appeared to be mediated through a beta-adrenergic receptor mechanism associated with plasma corticosterone in chickens.     

Involvement of host Fc receptors in antibody-mediated cutaneous basophil hypersensitivity reactions.

Cutaneous basophil hypersensitivity (CBH) reactions are heterogeneous delayed time course basophil-rich responses that can be mediated by either T cells, B cells, or serum antibodies. The current study examined the mechanism by which antibodies mediate CBH in guinea pigs. Fc competition experiments were constructed by passively transferring mixtures of anti-KLH serum and normal heterologous gamma-globulins. It was found that rabbit IgG and its isolated and purified Fc fragment [but not the (Fab')2 fragment] inhibited the ability of guinea pig immune serum to transfer CBH. Concurrent inhibition of transferred KLH-specific CBH and systemic passive cutaneous anaphylaxis (PCA) reactions by rabbit IgG or its Fc fragment, and not by sheep or bovine gamma-globulins, indicated that Fc receptors on cutaneous mast cells were probably involved in both CBH and PCA. It was also found that the basophil aspect of delayed cutaneous responses elicited by PHA was inhibited by Fc competition maneuvers. This could mean that some forms of apparently T cell-mediated CBH may be T cell dependent, but via secretion of molecules that bind to Fc receptors, as seems required in antibody-mediated CBH.     

IgE antibody-mediated cutaneous basophil hypersensitivity reactions in guinea pigs

Cutaneous basophil hypersensitivity (CBH) reactions are a heterogeneous group of delayed time course basophil-rich immune responses that can be mediated in the guinea pig by T cells, B cells, or IgG1 antibody. This study examined whether guinea pig IgE antibody could also mediate CBH reactions. IgE antibody to picryl or oxazolone determinants was induced by immunizing Hartley strain guinea pigs pretreated with cyclophosphamide. Hyperimmune serum from these animals was passed through a heavy chain-specific anti-IgG1 affinity column. The presence of IgE anti-hapten antibody in the filtrate fraction was verified by passive cutaneous anaphylaxis (PCA) testing with a 7-day period of local passive sensitization and by the heat lability (56 degrees C, 4 hr) of PCA activity. This IgE-rich fraction and the IgG1 fraction eluted from the column with base (0.2 M Na2CO3, pH 11.3) were transferred i.v. to separate groups of normal guinea pigs. Both fractions mediated delayed time course reactions that contained basophils. Macroscopic and microscopic reactions mediated by the IgE-rich fraction were abolished with heat (56 degrees C, 4 hr). Thus, two antigen-specific factors in guinea pig serum can mediate delayed time course basophil-containing reactions: IgG1 and IgE antibodies. IgE-mediated CBH reactions are similar to the late-phase reaction that follows IgE-dependent wheal-and-flare reactions in humans. The finding that guinea pig IgE can mediate a late reaction that contains basophils makes this a possible model for the human late-phase response, and suggests that some forms of CBH may play a role in human allergic disease.     

Anti-T cell monoclonal antibodies in vivo. I. Inhibition of delayed hypersensitivity but not cutaneous basophil hypersensitivity reactions

As part of a study of the therapeutic potential of anti-T cell monoclonal antibodies, we studied the biologic effects of 8BE6, a mouse anti-guinea pig (GP) pan-T cell monoclonal antibody, on blood and tissue T cells and on the prototypic T cell-mediated reactions, classic delayed hypersensitivity (DH) and cutaneous basophil hypersensitivity (CBH). 8BE6 reacts to a 68,000 m.w. protein probably homologous with human CD5 (T1) and murine Lyt-1. A single dose of 1.8 to 3.4 mg 8BE6 caused lymphopenia and greater than 90% depletion of 8BE6+ peripheral T cells 1 to 72 hr later, and a significant but lesser decrease of lymphocytes reacting with another pan-T cell monoclonal antibody (p less than 0.02 at 24 hr). Free serum 8BE6 was detected for up to 48 hr after administration. Immunoperoxidase stains of tissue revealed that lymphocytes in lymph nodes and spleen were coated with mouse immunoglobulin 1 hr after antibody treatment and displayed in situ capping. Subsequently, there was a loss of T cells in all tissues (spleen, lymph node, liver, and kidney) except the thymus, with normal 8BE6 antigen staining returning by 72 hr. Areas of induration of DH reactions to PPD were reduced in 8BE6-treated GP, compared with pretreatment reactions in the same GP or in control-treated GP (p less than 0.001 for both). The numbers of infiltrating T cells and fibronectin-receptor-positive macrophages were also reduced. In contrast, 8BE6 had no effect on CBH reactions, as judged by erythema and basophil counts in 1-micron sections, although fewer T cells were found in reaction sites. There were no differences in IgM, fibronectin, or Ia staining between 8BE6-treated GP and controls. In vivo administration of a single dose of anti-T cell monoclonal antibody results in a transient, highly specific depletion of T cell populations in peripheral blood and tissues except the thymus. This treatment inhibits DH but not CBH reactions by systemic and local depletion of T cells.     

Colonic basophil hypersensitivity

Contact hypersensitivity reactions were elicited by intraluminal application of DNCB to the colon of guinea pigs and were found sometimes to contain large infiltrates of basophils. These colonic basophil hypersensitivity reactions were accompanied by systemic sensitization and were not seen in nonspecific colonic inflammatory responses induced by croton oil. The heterogenous immune inflammatory responses induced in the colon by DNCB contact sensitivity may serve as a model for the study of inflammatory bowel disease.     

The inhibition of cutaneous basophil hypersensitivity reactions by a heterologous anti-guinea pig T cell serum.

Systemic treatment with a heterologous anti-T cell serum of guinea pigs immunized with EA in IFA markedly suppressed CBH reactivity to specific antigen and T cell mitogens, as judged by gross reactivity, histology, and skin histamine. The antiserum produced a marked drop in circulating lymphocytes, mainly at the expense of T cells, as indicated by the ability of surviving lymphocytes to rosette with rabbit RBC. It was postulated that the suppression of CBH reactivity is due to the depletion of T cells, which would have released a factor chemotactic for basophils. The data therefore provide further evidence that cutaneous reactions rich in basophils are primarily dependent on a population of T cells.     

Antibody enhances lymphocyte proliferation in guinea pigs immunized to express cutaneous basophil hypersensitivity

Lymphocytes from HSA-sensitized guinea pigs expressing cutaneous basophil hypersensitivity (CBH) proliferate in the presence of specific antigen. We report that this proliferative response is enhanced by the addition of anti-HSA antibody, either in the form of whole immune serum or as purified antibody. The enhancement was characterized as a marked shift of the antigen dose-response curve such that significant [3H]thymidine incorporation was observed at antigen concentrations much lower than those eliciting a comparable response in the absence of immune serum. Enhancement was antigen specific and required an intact immunoglobulin molecule. Antibodies capable of enhancing antigen-specific lymphocyte proliferation could be isolated from serum by affinity chromatography as early as 7 days after sensitization and were also evident in sera obtained at later intervals. It is unlikely that such antibodies account for the progressive decline of CBH reactivity and they may actually influence its initial expression.     

Cutaneous basophil hypersensitivity uncovered in the cell transfer of classical tuberculin hypersensitivity.

Cellular transfer of cutaneous basophil hypersensitivity (CBH) was studied. Guinea pigs immunized for CBH with incomplete Freund's adjuvant (IFA) provided cells which could transfer delayed and basophil-rich reactions in skin tests of recipients. Guinea pigs immunized with complete classical tuberculin-type delayed hypersensitivity reactions (DH), which are characteristically devoid of basophils. However, recipients of cells from donors with DH, surprisingly, were found to have delayed skin reactions containing large basophil infiltrates which were lacking in the donors. Thus, recipients of classical cell transfers of tuberculin-type DH had delayed reactions which resembled CBH. Control experiments verified that the cell transfer of CBH from donors with DH was due to passive transfer with live cells and not transfer of contaminating humoral factors or active sensitization of recipients. It was concluded that cutaneous basophil responses were suppressed in CFA-immunized donors and expressed in cell transfer recipients. Cells from donors immunized with CFA were enriched for nonadherent and nonimmunoglobulin-bearing lymphocytes by passage through nylon wool columns, and these cells transferred conjugate specific CBH reactions. It was concluded that cells mediating these transfers were probably T cells. The finding of basophils in cell transfers of DH and a variety of other findings suggesting complex regulation of basophil numbers in tissue lead to the conclusion that the term CBH be used to simply describe a basophil-containing skin reaction.     

The cutaneous basophil response to phytohemagglutinin in chickens.

A cellular infiltrate rich in basophils was observed in chickens in skin sites injected locally with the mitogen PHA. These infiltrating metachromatically granulated cells exhibited features common to mast cells of some species (monolobed nucleus), but also resembled basophils of other species in that they circulated in the blood, and they responded to the PHA mitogen by infiltrating skin test sites. Previous literature suggests that the chicken has a single metachromatic granulated cell and our data support this notion. PHA, a known T cell mitogen, may act by causing the stimulated T lymphocyte to produce a lymphokine that is responsible for the attraction of basophils to the test site.     

IgG1 antibody-dependent mediator release after passive systemic sensitization of basophils arriving at cutaneous basophil hypersensitivity reactions

When antigen is injected into a 24-hr cutaneous basophil hypersensitivity (CBH) reaction of an actively sensitized guinea pig, local basophils degranulate and release histamine. This reaction is called cutaneous basophil anaphylaxis and may be antibody mediated. We now report passive sensitization of basophils at CBH sites by systemic transfer of anti-picryl immune serum. Keyhole limpet hemocyanin- (KLH) immunized animals were skin tested with KLH to elicit 24-hr CBH reactions at day 7. Anti-picryl serum was injected i.v. at various times. On day 7, blue dye was injected i.v., and then 24-hr CBH sites vs nearby normal skin were challenged with 0.1 microgram picryl-human serum albumin (Pic-HSA). An immediate increase in vascular permeability (blueing) was noted at normal skin sites due to systemic passive cutaneous anaphylaxis (PCA), and augmented blueing occurred at CBH sites compared with normal skin. Systemic passive sensitization of CBH sites occurred when antiserum was administered as little as 1 hr before challenge of CBH site. However, local administration of anti-picryl serum (as in a local PCA reaction) was not able to sensitize tissue basophils, whether antigen was administered locally or systemically. The serum factor that mediated cutaneous basophil anaphylaxis was heat-stable (56 degrees C X 4 hr) 7S IgG1 antibody. Electron microscopy of Pic-HSA-challenged CBH sites in animals that received IgG1 antibody showed that local basophils undergo anaphylactic degranulation by exocytosis. These studies suggest that basophils arriving at CBH reactions are sensitized for anaphylactic function by antibody that can be acquired in the circulation, but possibly not at the local site.     

Regulatory mechanisms of cutaneous delayed-type hypersensitivity. II. Suppression of cutaneous delayed-type hypersensitivity by macrophage disappearance reaction

Studies were performed on the behavior of cutaneous delayed-type hypersensitivity (DTH) in guinea pigs in which macrophage disappearance reaction (MDR) was induced. Guinea pigs were immunized with dinitrophenylated egg albumin (DNP-EA), followed by intraperitoneal (ip) injection of liquid paraffin in order to elicit peritoneal macrophages. Subsequently 20 micrograms of EA was injected into these animals and the animals were divided into two groups. One group of animals was sacrificed for estimation of MDR 6 hr after the subsequent ip injection. The other group received a skin test by EA at the time of the subsequent ip injection. The first group of animals sacrificed for estimation of MDR exhibited a marked reduction in the number of peritoneal macrophages. The second group of animals that received skin tests revealed suppressed skin reactions 24 hr after the subsequent ip injection. A similar experiment was performed using the guinea pigs doubly immunized with DNP-EA and dinitrophenylated bovine gamma-globulin (DNP-BGG). Induction of MDR was performed by ip injection of BGG and skin tests were done by both EA and BGG. As a result, suppression of not only BGG-induced skin reactions but also EA-induced skin reactions was observed in animals in which MDR had been induced by BGG. In addition, the guinea pigs in which MDR was induced showed hyporeactivity to phytohemagglutinin (PHA). Reactivity to skin reactive factor (SRF) was also suppressed in these animals. The culture supernatants of macrophages incubated with the MIF fraction in vitro showed the ability to suppress skin reactions of cutaneous DTH, PHA and SRF.     

Regulatory mechanisms of cutaneous delayed-type hypersensitivity: I. Suppression of cutaneous delayed-type hypersensitivity by migration inhibitory factor

The macrophage migration inhibitory factor (MIF) fraction was prepared from the immunoadsorbent column by using anti-guinea pig MIF antiserum. Suppression of cutaneous delayedtype hypersensitivity was achieved by intraperitoneal injection of the MIF fraction into the animals bearing macrophage-rich peritoneal exudates. Skin reactions induced by phytohemagglutinin (PHA) were also suppressed in these animals. Reactivity to skin reactive factor (SRF) was suppressed in these animals as well. The sera obtained from these animals exhibited the inhibitory activity against production of lymphokines from sensitized lymphocytes.     

Effect of disodium cromoglycate on cutaneous basophil anaphylaxis

Cutaneous basophil anaphylaxis (CBA) was elicited by intradermal rechallenge of cutaneous basophil hypersensitivity (CBH) sites in guinea pigs sensitized 7 days previously with keyhole limpet hemocyanin (KLH). The antiallergy agent disodium cromoglycate (DSCG), administered i.v. immediately before rechallenge, inhibited the increased vasopermeability (measured by tissue dye uptake) and basophil degranulation (measured by light microscopic counts of intact basophils) characteristic of the CBA reaction. The antihistamine mepyramine, administered orally, inhibited vasopermeability but not basophil degranulation. The component contributed by DSCG inhibition of mast cell degranulation to the overall inhibition of the reaction was found to be minimal, since intact mast cells were found to be depleted at CBH sites and totally absent at CBA sites from animals treated with DSCG. Electron microscopic examination of basophils at CBA sites from DSCG-treated animals revealed the presence of ruffled perigranular membranes and enlarged perigranular spaces, but both the formation of degranulation sacs and the subsequent fusion of granule sac membranes with the plasma membrane were inhibited. DSCG also inhibited the vasopermeability and basophil degranulation of the CBA reaction elicited by KLH at day 14 and by C5a at day 7. When a basophil-enriched leucocyte preparation from KLH-sensitized guinea pigs was studied in vitro, DSCG inhibited both antigen-induced and C5a-induced basophil degranulation at 10(-5) and 10(-4) M. DSCG failed to inhibit the vasopermeability and the mast cell degranulation produced by either intradermal C5a or intradermal compound 48/80. These results indicate that anaphylactic degranulation of basophils, but not mast cells, is inhibited by DSCG in the guinea pig. This inhibition appears to take place independent of stimulus at an early stage of granule membrane fusion.     

Characterization of a localized basophil hypersensitivity lesion in guinea pig conjunctiva

Basophils accumulate in response to antigen challenge in cutaneous basophil hypersensitivity (CBH) reactions. Two ocular diseases, vernal conjunctivitis and contact-lens-associated conjunctivitis, are also characterized by this histopathology. We have refined a model previously developed in guinea pig conjunctiva by precisely defining the site of antigen injection and correlating the site with the clinical and histologic changes. Guinea pigs were primed by an intradermal injection of keyhole limpet hemocyanin (KLH) in the flank and challenged (Day 6) by injection of a small bolus of KLH just under the conjunctival epithelium. Twenty-four hours later histologic examination showed a perivascular infiltrate of inflammatory cells containing large numbers of basophils. Eosinophils, neutrophils, macrophages, and mast cells were also seen. Serial sections of the reaction site showed discrete boundaries. At all sites examined in antigen-challenged tissues, there were significantly more basophils than in control-injected conjunctiva. Insertion of a sterile needle or injection of PBS or KLH into normal conjunctiva induced a significant increase in neutrophils and some macrophages. Injection of graded doses of antigen into the conjunctiva of primed animals, resulted in a dose-dependent increase in basophils up to 50 micrograms KLH (optimal dose).