Preliminary indications that recombinant human IL-16 attracts and stimulates lymphocytes of the amphibian, Xenopus laevis implying an ancestral role for CD4 as a cytokine receptor.

The D1 domain of the CD4 co-receptor interacts with MHC class II during Helper CD4+ Th-cell activation and effector function in all gnathostomes but the sequence and structure of this region are not well conserved through phylogeny. Conversely, the proximal D4 domain of CD4 is the binding site of the cytokine IL-16 and is highly conserved, allowing for promiscuous binding of IL-16 to CD4 between disparate gnathostomes. We report here that recombinant human IL-16 (rhIL-16) bound to Xenopus lymphocytes to allow separation on a magnetic column. Incubation with rhIL-16 resulted in an increased expression of MHC class II mRNA by Xenopus CD8- cells more than by CD8+ cells. An in vivo assay demonstrated that rhIL-16 can recruit lymphocytes of Xenopus frogs. Our data suggest that a subset of Xenopus laevis lymphocytes express a CD4 homolog on their surface that is capable of binding IL-16. These results imply that CD4 most likely arose from a primordial cytokine receptor.

The serum complement system: a simplified laboratory exercise to measure the activity of an important component of the immune system.

The immune system is a vital physiological component that affords animals protection from disease and is composed of innate and adaptive mechanisms that rely on cellular and dissolved components. The serum complement system is a series of dissolved proteins that protect against a variety of pathogens. The activity of complement in serum can be determined by its ability to lyse red blood cells in vitro. Here, we describe a modification of a standard complement hemolysis assay that makes an interesting and informative laboratory exercise suitable for a variety of courses including physiology.

Phylogenetic conservation of glycoprotein 96 ability to interact with CD91 and facilitate antigen cross-presentation.

Although the ability of gp96 to activate APCs and generate CD8 CTLs against peptides they chaperone through interaction with the endocytic receptors CD91 is supported by solid evidence, its biological relevance in immune surveillance is debated. We have used an evolutionary approach to determine whether gp96 interacts with receptors expressed on APCs and promotes MHC class I cross-presentation of minor histocompatibility Ags (H-Ags) to CTLs in the frog Xenopus. We show that in Xenopus gp96 binds the CD91 homolog at the surface of peritoneal leukocytes, and that this binding is inhibited by molar excess of unlabeled gp96 or the CD91 ligand alpha2-macroglobulin, by anti-CD91 Ab and by the specific CD91 antagonist receptor-associated protein. Surface binding followed by internalization of gp96 was confirmed by fluorescent microscopy. Furthermore, adoptive transfer of peritoneal leukocytes pulsed with as little as 800 ng of gp96 chaperoning minor H-Ags, but not minor H-Ag-free gp96, induces potent CD8 T cell infiltration and Ag-specific accelerated rejection of minor H-locus disparate skin grafts. Inhibition of gp96-CD91 interaction by pretreatment with anti-CD91 Ab and receptor-associated protein impairs both CD8 T cell infiltration and acute skin graft rejection. These data provide evidence of the conserved ability of gp96 to facilitate cross-presentation of chaperoned Ags by interacting with CD91. The persistence of this biological process for >350 million years that separate mammals and amphibians from a common ancestor strongly supports the proposition that gp96 and CD91 are critically involved in immune surveillance.

Generation of a long-lasting, protective, and neutralizing antibody response to the ranavirus FV3 by the frog Xenopus.

Xenopus serves as an experimental model to evaluate the contribution of adaptive immunity in host susceptibility to emerging ranaviral diseases that may contribute to amphibian population declines. It has been previously shown that following a secondary infection with the ranavirus frog virus 3 (FV3), adult Xenopus more rapidly clear FV3 and generate specific anti-FV3 IgY antibodies. We have further evaluated the potency and persistence of the Xenopus antibody response against FV3. Frogs inoculated with FV3 (without adjuvant) up to 15 months after priming produce specific, thymus-dependent anti-FV3 IgY antibodies detectable from 10 days to 8 weeks post-infection. These antisera from boosted frogs are neutralizing in vitro and provide partial passive protection to susceptible larvae when they are injected a few minutes before FV3 inoculation. These results with Xenopus suggest that other anuran amphibians are likely to develop effective long-lasting protective humoral immunity after an initial viral exposure.

Ground squirrel splenic macrophages bind lipopolysaccharide over a wide range of temperatures at all phases of their annual hibernation cycle.

This study evaluates binding of bacterial lipopolysaccharide (LPS) by splenic macrophages from golden-mantled ground squirrels (Spermophilus lateralis, GMGS), a hibernating mammal, at a variety of in vitro incubation temperatures to determine whether this aspect of immune function is effective at low body temperatures. LPS-binding by ground squirrel macrophages was compared to that of rat splenic macrophages. Macrophages were collected from squirrels at discreet stages in their annual cycle and incubated with fluorescein-labeled LPS (LPS-FITC). The percentage of GMGS that bound LPS-FITC did not change as a function of hibernation season or as a function of incubation temperature. The total amount of LPS-FITC bound per cell was similarly unaffected by season or temperature, however, macrophages from torpid squirrels bound more LPS-FITC than cells from normothermic squirrels. Macrophages of golden-mantled ground squirrels bind LPS at a wide range of temperatures throughout their annual cycle; an ability shared between hibernators and non-hibernators alike.

CD91 up-regulates upon immune stimulation in Xenopus adult but not larval peritoneal leukocytes.

CD91, the endocytic receptor for alpha2-macroglobulin (alpha2M), mediates the internalization of certain heat shock proteins (hsps) and the cross-presentation of peptides they chaperone by antigen-presenting cells. The phylogenetic conservation of the immunologically active CD91 ligands, alpha2M and hsps, is consistent with the idea of an ancestral system of immune surveillance. We have further explored this hypothesis by taking advantage of the frog Xenopus, and asked how conserved is CD91 and whether the expression of CD91 is differentially modulated during immune responses of class I-positive adult and naturally class I-negative larvae. We have identified a Xenopus CD91 gene homologue that displays high sequence identity (>65%) with other CD91 homologues and contains an additional distinctive cytoplasmic NPXY motif. Phylogenetic analysis indicates that CD91 homologues branch as a monophyletic group distinct from other LDLRs; this suggests an origin of CD91 contemporary with that of metazoans. A 14-kb transcript is detected by Northern blotting in most adult and larval tissues, including lymphoid tissues. RT-PCR study reveals that CD91 is expressed in most cell types, including adult macrophages, B and T cells as well as in splenocytes and thymocytes from naturally MHC class I negative larvae. CD91 is markedly up-regulated in vivo by adult peritoneal leukocytes following bacterial and viral stimulation; it is constitutively expressed on class I-negative larval peritoneal leukocytes at high levels and cannot be further upregulated by such stimulation. These data are in agreement with a conserved role of CD91 in immunity.

Phylogenetic conservation of gp96-mediated antigen-specific cellular immunity: new evidence from adoptive cell transfer in xenopus.

BACKGROUND: In vertebrates from man to frogs, the heat shock protein (hsp) gp96 elicits T-cell responses against antigenic peptides that it chaperones. In Xenopus, immunization with gp96 purified from normal tissues accelerates rejection of MHC identical, minor histocompatibility (H) antigen-disparate skin grafts in vivo and induces MHC-restricted CTL responses in vitro. Also in Xenopus, gp96 derived from MHC class I-negative tumors elicits peptide-specific responses against these tumors in vivo and MHC-unrestricted CD8 killing in vitro. We have developed an adoptive cell transfer protocol to further characterize these gp96-stimulated Xenopus effectors in vivo. METHODS AND RESULTS: Carboxyfluorescein diacetate succinimidyl ester (CFSE)-stained splenocytes from cloned LG-6 donor frogs immunized with gp96 purified from minor H-antigen-disparate LG-15 tissues were transferred into LG-6 recipients bearing a LG-15 minor H antigen (ag)-disparate skin graft. Primed anti-LG-15 but not naive CFSE T cells accumulated and divided in the spleen of allografted recipients to a greater extent than in those of autografted recipients. Similar accumulation and division occurred when CD8 T cells primed by 15/0 tumor-derived gp96 were transferred to an isogeneic recipient bearing the same MHC class I-negative tumor. Furthermore, the transfer of such primed antitumor splenocytes into naive recipients before tumor challenge delayed the appearance of tumors. CONCLUSIONS: These data provide new in vivo evidence that in frogs as in mammals, gp96 can prime CD8 T cells against antigens they chaperone. In addition, at least in Xenopus, gp96 can prime CD8(+) T-cell effectors that are not MHC restricted.

Xenopus as an experimental model for studying evolution of hsp--immune system interactions.

The frog Xenopus provides a unique model system for studying the evolutionary conservation of the immunological properties of heat shock proteins (hsps). General methods for maintaining and immunizing isogenetic clones of defined MHC genotypes are presented together with more recently developed protocols for exploring hsp-mediated immune responses in vitro (proliferative and cytotoxic assays) and in vivo (adoptive cell transfer and antibody treatment) in adults and in naturally MHC class I-deficient larvae. Finally, techniques to study modalities of expression of the endoplasmic reticulum resident gp96 at the cell surface of tumor and normal lymphocytes are considered.

Development and characterization of a model system to study amphibian immune responses to iridoviruses.

The recent realization that viruses within the family Iridoviridae may contribute to the worldwide decline in amphibians makes it urgent to understand amphibian antiviral immune defenses. We present evidence that establishes the frog Xenopus laevis as an important model with which to study anti-iridovirus immunity. Adults resist high doses of FV3 infection, showing only transitory signs of pathology. By contrast, naturally MHC class-I-deficient tadpoles are highly susceptible to FV3 infection. Monitoring of viral DNA by PCR indicates a preferential localization of FV3 DNA in the kidney, with the inbred MHC homozygous J strain appearing to be more susceptible. Clearance of virus as measured by detection of FV3 DNA and also the disappearance of pathological and behavioral symptoms of infection, acceleration of viral clearance, and detection of IgY anti-FV3 antibodies after a second injection of FV3 are all consistent with the involvement of both cellular and humoral adaptive antiviral immune responses.

Classical pathway serum complement activity throughout various stages of the annual cycle of a mammalian hibernator, the golden-mantled ground squirrel, Spermophilus lateralis.

Little is known about the changes in the immune system that coincide with the annual cycle of hibernating mammals. This study investigates classical pathway complement activity in the serum of the golden-mantled ground squirrel, a mammalian hibernator. Complement activity varied significantly among discreet stages of the annual cycle and is lowest during torpor and greatest during stages of arousal. C3 mRNA levels follow a pattern similar to that of complement-mediated hemolysis throughout the year but do not vary significantly among hibernation states. The classical pathway of the serum complement system is able to function in vitro at 5 degrees C, although at a slower rate than at 34 degrees C. The classical pathway of the serum complement system is active throughout all phases of the annual cycle of the golden-mantled ground squirrel.