Enveloped virus- and lectin-induced structural change in erythrocyte lipid bilayer: Dependence on species of erythrocyte and on the multivalence of the agglutinin

Attachment of influenza virus or concanavalin A (Con A) to avian or amphibian erythrocytes causes the erythrocyte membrane lipid bilayer to become more fluid, as detected by spin-label electron spin resonance. No change in bilayer fluidity occurs upon agglutination of avian erythrocytes pretreated with the microtubule-disrupting drug colchicine or agglutination of mammalian erythrocytes, which lack microtubules. The change in bilayer fluidity upon agglutination of chicken erythrocytes appears to require crosslinking of receptor molecules. The hemagglutinin glycoprotein isolated from influenza virus by treatment with bromelain and the succinylated derivative of Con A bind to receptors, but do not crosslink them and do not cause a change in lipid bilayer fluidity. Multivalent aggregates of influenza virus hemagglutinin, isolated by treatment with Triton X-100 followed by removal of the detergent, are able to induce an increase in erythrocyte lipid bilayer fluidity. Erythrocytes pretreated with succinyl-Con A are agglutinated by antibody to Con A, resulting in an increase in membrane bilayer fluidity. These results support the hypothesis that the fluidity change in the avian erythrocyte membrane induced by virus and lectin attachment involves lateral rearrangement of receptor glycoproteins in the plane of the membrane mediated by microtubule-like systems.     

Comparison of hemagglutinating,receptor-destroying,and acetylesterase activities of avirulent and virulent bovine coronavirus strains

Summary Hemagglutinating and acetylesterase functions as well as the 124 kDa glycoprotein were present in the highly cell-culture adapted, avirulent bovine coronavirus strain BCV-L9, in the Norden vaccine strain derived from it, and in 5 wild-type, virulent strains that multiplied in HRT-18 cells but were restricted in several types of cultured bovine cells. The BCV-L9 and the wild-type strain BCV-LY-138 agglutinated chicken and mouse erythrocytes. The acetylesterase facilitated break-down of the BCV-erythrocyte complex with chicken but only to a minimal extent with mouse erythrocytes in the receptor-destroying enzyme test. Purified preparations of the vaccine and the wild-type strains agglutinated chicken erythrocytes at low titers and mouse erythrocytes at 128 to 256 times higher titers whereas receptor destroying enzyme activity was detectable only with chicken erythrocytes. When wild-type strains were propagated in HRT cells at low passage levels, they produced 5×10⁵ to 4.5×10⁶ plaque forming units per 50 µl which agglutinated erythrocytes from mice but not from chickens. Diisopropylfluoro-phosphate moderately increased the hemagglutination titers, but completely inhibited the receptor destroying enzyme of purified virus of all strains. It had virtually no influence on the plaque-forming infectivity of the different BCV strains. The acetylesterase of strain BCV-L9 reacting in the receptor-destroying enzyme test was stable for 3h at 37 and 42°C. It was inactivated within 30 min at 56°C while the hemagglutinin function of this strain was stable for 3 h at 37, 42, and 56°C, but it was inactivated at 65°C within 1 h.     

不同亚型禽流感病毒红细胞凝集特性分析

目的:了解不同亚型禽流感病毒与不同动物来源红细胞的凝集特性,为流感环境样本监测工作选择更适宜的检测用红细胞。方法:选取2009-2016年我国禽流感环境监测中分离到的不同亚型的禽流感毒株,采用红细胞凝集试验,选用5种动物红细胞(鸡、火鸡、豚鼠、马和绵羊)进行检测;应用流式细胞仪检测不同动物红细胞表面唾液酸受体的表达及类...     

Preparation of anti-idiotypic antibody against avian influenza virus subtype H9

To generate monoclonal anti-idiotypic antibodies(mAb2)against avian influenza virus subtype H9(H9 AⅣ),BALB/c mice were immunized with purified chicken anti-H9-AⅣ IgG and the splenocytes of immunized mice werefused with myeloma cells NS-1.Hybridoma cells were screened by indirect enzyme-linked immunosorbent assayswith both chicken and rabbit anti-H9-AⅣ IgG as coating antigens.One hybridoma cell clone secreting monoclonalantibody against idiotypes shared by both chicken and rabbit anti-H9-AⅣ IgG was established.Experimentsdemonstrated the mAb2 was able to inhibit the binding of hemagglutinin to anti-H9-AⅣ IgG and to inducechickens to generate hemagglutination inhibition antibodies,indicating this anti-species-sharing-idiotypic antibodybore the internal image of hemagglutinin on avian influenza virus.Cellular & Molecular Immunology.2005;2(2):155-157.     

Mechanisms of neutralization of influenza virus in tracheal epithelial and BHK cells vary according to IgG concentration

The interaction of IgG-neutralized type A influenza virus with differentiated epithelial cells of mouse trachea, BHK cells, and chicken erythrocytes was studied using three mouse monoclonal antibodies (IgG2a) each directed against a different antigenic site on the hemagglutinin. At high HIU:HAU ratios virus was neutralized greater than 99%, monodisperse, and attached to tracheal epithelial and BHK cells in normal amounts. The majority (70-80%) of neutralized virus failed to attach to erythrocytes. At low HIU:HAU ratios the virus was aggregated by each of the antibodies, and attachment to tracheal epithelial and BHK cells was inhibited by up to 75%. Combined aggregation and inhibition of attachment could theoretically account for up to 96% loss of infectivity but this corresponded with the observed degree of neutralization with only one of the antibodies. With increasing antibody:virus ratios, aggregation and inhibition of attachment contributed ever diminishingly to the observed neutralization and eventually not at all. Both neutralized and infectious virus attached to neuraminidase-sensitive receptors. After attachment neutralized virus became increasingly resistant to removal by neuraminidase suggesting that it had been internalized by the cell.     

Antiidiotypic antibodies as probes for the Sindbis virus receptor

Rabbit polyclonal antiidiotypic antibodies were made to mouse monoclonal antibodies that neutralize the infectivity of Sindbis virus. One of the antiidiotypic antisera obtained has properties characteristic of an antireceptor antiserum. It binds to the surface of chicken cells as shown by immunofluorescence and partially blocks virus binding to these cells as determined by binding of radiolabeled virus or by a plaque reduction assay. It also immunoprecipitates a protein with a molecular weight of 63,000 from chicken cells. From the fact that the antiserum will only partially block virus uptake, and that it does not block uptake of a variant of Sindbis virus resistant to the monoclonal antibody used to produce the antiidiotypic antiserum, we propose that at least two distinguishable receptors can be used by Sindbis virus to enter chicken cells. Furthermore, the receptors used by Sindbis to enter BHK cells appear to be different from those on chicken cells, at least in part, in that the antiidiotypic antiserum does not recognize the BHK counterpart of the chicken cell receptor. We suggest that the alphaviruses use a number of distinguishable receptors which differ depending on the host and the tissue. In chicken cells the 63,000 molecular weight protein may be one of them. The diversity of such multiple receptors could account for the very wide host range of the alphaviruses, which infect mosquitoes, birds, and mammals.     

The structure of the hemagglutinin, a determinant for the pathogenicity of influenza viruses.

Comparative studies on naturally occurring avian influenza viruses have been carried out in order to investigate the determinant(s) for pathogenicity for chickens. At least one virus isolate from each of the nine different hemagglutinin (HA) subtypes was included. The polypeptides of these viruses were studied by analyzing infected cell extracts on SDS-polyacrylamide gels. Both viral glycoproteins, HA and neuraminidase, showed remarkable variation in their electrophoretic mobility even among serologically closely related viruses. Pulse-chase experiments revealed that most avian influenza virus strains had an HA which was not susceptible to proteolytic cleavage in MDCK, turkey (TEC), and chicken embryo cells (CEC). Only viruses belonging to the subtype Hav5 and some strains of the subtype Hav1 possessed a cleaved HA in these cells. Only the virus strains with cleaved HA were produced in infectious form in MDCK, CEC, TEC, as well as in duck embryo cells (DEC) and quail embryo cells (QEC). The other virus strains produced plaques in these cells only in the presence of trypsin. There was a strict correlation between the cleavability of the HA, the potential of the virus to be produced in infectious form in a wide range of host cells, and their pathogenicity for chickens. No evidence was obtained for an involvement of the neuraminidase in determining pathogenicity. For the nonpathogenic viruses it could be shown that they can replicate and produce infectious progeny in some organs of the chicken. The results obtained permit the conclusion that in naturally occurring avian influenza viruses the structure of the hemagglutinin, that is its susceptibility to proteolytic cleavage in a broad spectrum of host cells, is the determining factor for pathogenicity.     

Inhibition of virus-induced hemolysis with monoclonal antibodies to different antigenic areas on the hemagglutinin molecule of A/seal/Massachusetts/1/80 (H7N7) influenza virus

A/seal/Massachusetts/1/80 (H7N7) influenza virus caused maximal hemolysis at pH 5.9 Monoclonal antibodies to each of the four nonoverlapping antigenic areas on the hemagglutinin molecule of the virus inhibited the hemolysis whereas those belonging to two of the groups did not inhibit hemagglutination of the virus. Hemolysis also occurred when the virus was incubated at pH 5.9 prior to addition of erythrocytes. Such hemolysis caused by acid-treated virus was inhibited with the antibodies as well. At pH 5.9, hemagglutination of neither intact virus nor hemagglutinin rosettes was inhibited with any of the monoclonal antibodies, indicating conformational change in the hemagglutinin molecule, at this pH. On the other hand, hemagglutination-inhibition was observed when the antigens were incubated with the monoclonal antibodies at pH 7.0 and then the pH was later shifted to 5.9, suggesting that antibody-binding interferes with the conformational change in the hemagglutinin molecule at pH 5.9. The present findings indicate that antibodies to the hemagglutinin of influenza virus can inhibit virus-induced hemolysis by blocking conformational change in the hemagglutinin molecule and blocking later step of fusion than the conformational change, in addition to blocking attachment of virus to the receptor of erythrocytes.     

Induced autoantibodies to fetal erythroid antigens in the chicken

Cornell Obese (OS) (B13B13), Special C (Sp.C) (B13B13) and K-strain White Leghorn chickens (B15B15) were examined for both naturally occurring and induced autoantibodies directed against erythroid fetal antigens. Obese chickens have been reported to produce high levels of autoantibodies to thyroglobulin and to occasionally produce antinuclear autoantibodies specific for erythrocytes. Despite producing high levels of antithyroglobulin autoantibodies and antibodies cross-reactive with erythrocytes, no OS chickens were found to possess naturally occurring autoantibodies to fetal-specific antigens on erythrocytes. However, such antibodies were induced following immunization with fetal erythrocytes derived from a strain allogeneic for the major histocompatibility complex (MHC), the B-complex. Challenge with both intact erythrocytes and erythroid membranes in Freund's complete adjuvant resulted in production of antibodies specific for fetal antigens. The ability to induce autoantibodies to fetal erythrocytes was not restricted to the OS-strain; similar antibodies were detected in the Cornell K-strain and Special C-strain chickens even when intrastrain immunizations were employed. These results suggest that antibodies can be induced to fetal antigens on chicken erythrocytes in both autoimmune and normal chickens given the appropriate antigen presentation.     

Analysis of hematopoietic and lymphopoietic tissue during a regenerative aplastic crisis induced by avian retrovirus MAV-2(O)

Infection of 10-day-old chickens with an avian osteopetrosis virus resulted in a severe regenerative aplastic crisis. Hematopoietic and lymphopoietic tissues of chickens infected with myeloblastosis-associated virus (of subgroup B, inducing osteopetrosis, MAV-2(O] were analyzed for integrated and unintegrated viral DNA sequences, cell population shifts, weight changes, and morphological alterations. By 6 days postinfection (p.i.), DNA from bone marrow cells and peripheral blood leukocytes (PBL) contained between 0.50 and 0.70 copies of viral DNA per haploid genome. Erythrocytes and splenic leukocytes contained less than 0.10 copies/haploid genome. Granulocytes and precursor mesomyelocytes were absent from bone marrow, but numbers of erythrocytes, erythroblasts, and reticulocytes were normal. By 9 days p.i., bone marrow was severely hypoplastic and both granulopoietic and erythropoietic colonies were depleted. By 12 days p.i., erythrocytes and granulocytes were maximally depressed in peripheral blood and the amount of integrated virus in bone marrow and PBL decreased to less than 0.20 copies/haploid genome. In contrast, erythrocytes contained integrated viral DNA of up to 0.30 copies/haploid genome, indicating infection of erythrocyte precursors. At 18 days p.i., viral DNA was detected only in erythrocytes. Unintegrated viral DNA was not detected in any organs. Anemia was accompanied by splenomegaly and erythrophagocytosis. Viral DNA was never detected in thymus or bursa. Differential counting and flow cytometry of cells from bursa, thymus, and spleen, and of blood lymphocytes did not detect significant population shifts. These results suggest that MAV-2(O) infection of immunocompetent chickens occurs primarily in myelopoietic tissues, and tissues are selectively infected.     

Functional characterization of non-human primate erythrocyte immune adherence receptors: implications for the uptake of immune complexes by the cells of the mononuclear phagocytic system.

Erythrocytes from primates express an immune adherence (IA) receptor that binds complement-opsonized immune complexes (IC) both in vivo and in vitro. We have analyzed the immunochemical and functional properties of the IA receptor from erythrocytes from species that have been used for in vivo IC clearance studies and have compared these properties to the human IA receptor (which is called complement receptor type 1, CR1). Erythrocytes from all species (chimpanzee, baboon, rhesus and cynomolgus monkey) bind antibody/double-stranded DNA IC when opsonized with autologous complement. However, IC which are bound to chimpanzee erythrocytes are not released upon addition of chimpanzee serum (which contains factor I activity), while IC bound to baboon erythrocytes and human erythrocytes are released upon addition of autologous serum. Anti-human CR1 monoclonal antibodies (mAb) E11 and HB8592 bind to erythrocytes from all species examined and the number of mAb epitopes per erythrocyte correlated with the number of IC that could bind to the erythrocyte under saturating conditions. However, a number of interesting differences between the species are observed with other mAb. The anti-CR1 mAb 1B4 and 3D9, which block recognition of ligand by CR1, did not bind to chimpanzee erythrocytes and bound partially to rhesus and cynomolgus monkey erythrocytes. In addition, the ability of autologous serum to induce release of erythrocyte-bound IC correlates with the presence of these epitopes. These findings, taken in context with previous clearance studies, suggest that serum-mediated release may not be required for the rapid transfer of the IC from the erythrocyte to the mononuclear phagocytic system.     

Contact sensitivity to oxazolone in the chicken: evidence for Arthus type hypersensitivity of the cutaneous reaction.

Cutaneous hypersensitivity reaction can be induced in chickens by skin painting with oxazolone, 33 mg/Kg of body weight (KBW). The B cell contribution to the generation of the cutaneous reaction has been a matter of controversy. In an attempt to characterize this reaction we placed special interest on the possibility that the nature of this reaction could be Arthus type hypersensitivity. From the kinetics study on the cutaneous hypersensitivity after challenge with oxazolonated egg-albumin (EA-OX) it was excluded that the nature of this reaction could be delayed type hypersensitivity. Immune sera transfer experiments demonstrated that the cutaneous reaction was antibody dependent. Serum anti-oxazolone antibody titers in sensitized chickens were assayed by antiglobulin haemagglutination, using oxazolone coupled sheep erythrocytes (OX-SRBC). High titres of IgG were found in contact sensitized chickens. Furthermore this cutaneous reaction was characterized by neutrophils, inflammatory edema, rare thrombotic occlusion of small venules and on absence of monocytes. The utilization of complete Freunds' adjuvant (CFA) given at sensitization demonstrated that CFA enhanced oxazolone antibodies in the sera of immunized chickens without a correlated increase in the intensity of the cutaneous reaction to EA-OX. Animals sensitized to oxazolone (33 mg/KBW) without CFA and challenged intravenously seven days later with oxazolone coupled to autologous chicken red blood cells (OX-CRBC) died from anaphylactic shock; instead animals with the same treatment but with CFA given at sensitization did not die from anaphylactic shock. Taken collectively it was concluded that the cutaneous reaction to oxazolone in the chicken can be categorized as Arthus hypersensitivity. The relationship between cutaneous Arthus reaction and anaphylactic shock in chickens sensitized to oxazolone is discussed.     

Contact Sensitivity to Oxazolone in the Chicken: Evidence for Arthus Type Hypersensitivity of the Cutaneous Reaction

Cutaneous hypersensitivity reaction can be induced in chickens by skin painting with oxazolone, 33 mg/Kg of body weight (KBW). The B cell contribution to the generation of the cutaneous reaction has been a matter of controversy. In an attempt to characterize this reaction we placed special interest on the possibility that the nature of this reaction could be Arthus type hypersensitivity. From the kinetics study on the cutaneous hypersensitivity after challenge with oxazolonated egg-albumin (EA-OX) it was excluded that the nature of this reaction could be delayed type hypersensitivity. Immune sera transfer experiments demonstrated that the cutaneous reaction was antibody dependent. Serum anti-oxazolone antibody titers in sensitized chickens were assayed by antiglobulin haemagglutination, using oxazolone coupled sheep erythrocytes (DX-SRBC). High titres of IgG were found in contact sensitized chickens. Furthermore this cutaneous reaction was characterized by neutrophils, inflammatory edema, rare thrombotic occlusion of small venules and on absence of monocytes. The utilization of complete Freunds' adjuvant (CFA) given at sensitization demonstrated that CFA enhanced oxazolone antibodies in the sera of immunized chickens without a correlated increase in the intensity of the cutaneous reaction to EA-OX. Animals sensitized to oxazolone (33 mg/KBW) without CFA and challenged intravenously seven days later with oxazolone coupled to autologous chicken red blood cells (OX-CRBC) died from anaphylactic shock; instead animals with the same treatment but with CFA given at sensitization did not die from anaphylactic shock. Taken collectively it was concluded that the cutaneous reaction to oxazolone in the chicken can be categorized as Arthus hypersensitivity. The relationship between cutaneous Arthus reaction and anaphylactic shock in chickens sensitized to oxazolone is discussed.     

Preferential targeting of vesicular stomatitis virus to breast cancer cells

Vesicular stomatitis virus (VSV) is a candidate for development for cancer therapy. We created a recombinant replicating VSV (rrVSV) with an altered surface protein that targeted preferentially to breast cancer cells. The rrVSV genome contained a single glycoprotein (gp) gene derived from Sindbis virus. This gene expressed a chimeric Sindbis E2 binding gp and the native Sindbis E1 fusion gp. The chimeric E2 binding gp, called Sindbis-SCA-erbb2, was modified to reduce its native binding function and to contain a single chain antibody (SCA) with specificity for the human epidermal growth factor receptor Her2/neu protein, erbb2. These viruses selectively infected, replicated in and killed cells expressing erbb2. The titer of rrVSV on SKBR3 cells, a human breast cancer cell line which highly expresses erbb2 was 3.1 x 10(7)/ml compared with a titer of 7.3 x 10(5)/ml on 143 cells, a human osteosarcoma cell line which does not express erbb2. The titer of rrVSV on D2F2/E2 cells, a mouse mammary cancer cell line stably transfected to express human erbb2 was 2.46 x 10(6)/ml compared with a titer of 5 x 10(4)/ml on the parent D2F2 cells which do not express erbb2. When titered on erbb2-negative cells, non-replicating pseudotype VSV coated with Sindbis-SCA-erbb2 had <3% the titer of pseudotype VSV coated with wild type Sindbis gp indicating that the chimeric Sindbis gp had severely impaired binding to the natural receptor. Analysis of the protein composition of the rrVSV found low expression of the modified Sindbis gp on the virus.     

Physicochemical properties of transmissible gastroenteritis virus hemagglutinin

Summary Transmissible gastroenteritis virus was readily adsorbed onto chicken erythrocytes at 4°C. The hemagglutinin thus adsorbed could be eluted from the erythrocytes by incubating in phosphate buffered saline at 37°C. The on chicken erythrocytes for the hemagglutinin was inactivated by neuraminidase and potassium periodate, but not by trypsin, 2-mercaptoethanol and formalin. The hemagglutinin was inactivated by trypsin, papain, pepsin, -amylase, phospholipase C, neuraminidase, formalin, 2-mercaptoethanol, potassium periodate, ethylether, chloroform, Tween-80 and -propiolactone, but not by sodium deoxycholate and trichlorotrifluoroethane, suggesting that the active component of the hemagglutinin involved glycoproteins. The hemagglutinin was stable at 37°C or lower temperatures but not at 60°C or higher temperatures. The hemagglutinin activity was resistant to ultraviolet irradiation, while the infectivity was very susceptible. The hemagglutinin and the infectivity were readily sedimented by ultracentrifugation at 45,000 × g for 60 minutes. In rate zonal centrifugation of the hemagglutinin preparation on a sucrose density gradient, the hemagglutinin activity showed a sharp peak at 1.19 g/ml coinciding with the peak of infectivity. The activity in the peak fraction seemed to be structually associated with virus particles.     

Insulin Receptor Characteristics of Erythrocytes from Human Newborns

Erythrocytes from human newborns were observed to have specific insulin receptors. The characteristics of these receptors were similar to those of the normal adult subjects. An observed slight increase in R_o and a decrease in _e of insulin receptors in erythrocytes may be speculated to facilitate the transfer of insulin from the fetal erythrocytes to other rapidly growing fetal tissues at a rate faster than that present in the circulation of the adult subjects.     

Genetic Conservation of Hemagglutinin Gene of H9 Influenza Virus in Chicken Population in Mainland China

The hemagglutinin (HA) genes of 12 H9N2 influenza virus strains isolated from chickens in Mainland China during the period 1995–2002 were genetically analyzed. All the isolates possessed the same amino acid motif -R-S-S-R/G-L- at the cleavage site of HA. Except for the conserved amino acids, as is the case in the other avian influenza viruses, located in the receptor binding site, all of the 12 isolates possessed N at amino acid position 183; A, T, or V at position 190; K at position 137, whereas the representative strains of the other lineage (except Dk/HK/Y280/97-like lineage) virus of H9N2 viruses had H, E, and R at these positions respectively. These could be considered as the partial molecular markers of the H9 viruses isolated from chickens in Mainland China. Phylogenetic analyses showed HA genes of these isolates belonged to that of A/duck/Hong Kong/Y280/97-like virus lineage. No A/quail/Hong Kong/Gl/97-like virus was found in chicken, population since the outbreak of H9N2 influenza in Mainland China in 1992. The available evidence indicates that HA genes of H9 influenza virus circulating in Mainland China during the past years were well conserved.     

Contact Sensitivity to Oxazolone in the Chicken: Evidence for Arthus Type Hypersensitivity of the Cutaneous Reaction

Abstract

Cutaneous hypersensitivity reaction can be induced in chickens by skin painting with oxazolone, 33 mg/Kg of body weight (KBW). The B cell contribution to the generation of the cutaneous reaction has been a matter of controversy. In an attempt to characterize this reaction we placed special interest on the possibility that the nature of this reaction could be Arthus type hypersensitivity. From the kinetics study on the cutaneous hypersensitivity after challenge with oxazolonated egg-albumin (EA-OX) it was excluded that the nature of this reaction could be delayed type hypersensitivity. Immune sera transfer experiments demonstrated that the cutaneous reaction was antibody dependent. Serum anti-oxazolone antibody titers in sensitized chickens were assayed by antiglobulin haemagglutination, using oxazolone coupled sheep erythrocytes (DX-SRBC). High titres of IgG were found in contact sensitized chickens. Furthermore this cutaneous reaction was characterized by neutrophils, inflammatory edema, rare thrombotic occlusion of small venules and on absence of monocytes. The utilization of complete Freunds' adjuvant (CFA) given at sensitization demonstrated that CFA enhanced oxazolone antibodies in the sera of immunized chickens without a correlated increase in the intensity of the cutaneous reaction to EA-OX. Animals sensitized to oxazolone (33 mg/KBW) without CFA and challenged intravenously seven days later with oxazolone coupled to autologous chicken red blood cells (OX-CRBC) died from anaphylactic shock; instead animals with the same treatment but with CFA given at sensitization did not die from anaphylactic shock. Taken collectively it was concluded that the cutaneous reaction to oxazolone in the chicken can be categorized as Arthus hypersensitivity. The relationship between cutaneous Arthus reaction and anaphylactic shock in chickens sensitized to oxazolone is discussed.     

Protection of chickens from lethal influenza infection by vaccinia-expressed hemagglutinin

To study the immune response of the chicken to specific influenza proteins, we have constructed a recombinant vaccinia virus containing the hemagglutinin gene of influenza A/Turkey/Ireland/1378/83 (H5N8). In mammalian cell culture the hemagglutinin expressed by this recombinant virus was full-length, cleaved into HA1 and HA2 in the absence of trypsin, and transported to the cell surface, confirming that other virus products are not required for cleavage activation. Chickens inoculated through the wing web with the live recombinant virus produced extremely low levels of hemagglutination-inhibiting or infectivity-neutralizing antibody. However, they were protected from lethal H5 influenza virus challenge. Protection extended to the antigenically distinct virulent H5 viruses, Chicken/Pennsylvania/1370/83 and Chicken/Scotland/59. Chemically bursectomized vaccinated chickens were not protected, whereas normal chickens with very low antibody levels (less than 10) obtained by passive transfer were protected in a dose-dependent fashion. This indicates that despite the low antibody titers induced by vaccination, protection was mediated by antibody.     

Differences between influenza virus receptors on target cells of duck and chicken

H5, H7, and H9 subtype influenza viruses in land-based poultry often differ from viruses of wild aquatic birds by deletions in the stalk of the neuraminidase, by the presence of additional carbohydrates on the hemagglutinin, and by occasional changes in the receptor specificity. To test whether these differences could reflect distinctions between the virus receptors in different avian species, we compared the binding of duck, chicken and human influenza viruses to cell membranes and gangliosides from epithelial tissues of duck, chicken and African green monkey. Human viruses bound to cell membranes of monkey and chicken but not to those of duck, suggesting that chicken cells unlike duck cells contain Sia(alpha2-6)Gal-terminated receptors recognized by human viruses. Duck virus bound to gangliosides with short sugar chains that were abundant in duck intestine. Human and chicken viruses did not bind to these gangliosides and bound more strongly than duck virus to gangliosides with long sugar chains that were found in chicken intestinal and monkey lung tissues. Our data suggest that the spectrum of sialylglycoconjugates which can serve as influenza virus receptors in chicken is more similar to the spectrum of receptors in the respiratory epithelia of monkey than to that in the epithelial tissues of duck. This notion could explain the recent emergence of avian H9N2 virus lineage with human virus-like receptor specificity and emphasizes the role of the chicken as a potential intermediate host for the transmission of viruses from aquatic birds to humans.