G Russ

Brefeldin A (BFA) has been reported to block protein transport from the ER and cause disassembly of the Golgi complex. We have examined the effects of BFA on the transport and processing of the vesicular stomatitis virus G protein, a model integral membrane protein. Delivery of G protein to the cell surface was reversibly blocked by 6 micrograms/ml BFA. Pulse-label experiments revealed that in the presence of BFA, G protein became completely resistant to endoglycosidase H digestion. Addition of sialic acid, a trans-Golgi event, was not observed. Despite processing by cis- and medial Golgi enzymes, G protein was localized by indirect immunofluorescence to a reticular distribution characteristic of the ER. By preventing transport of G protein from the ER with the metabolic inhibitor carbonyl cyanide m-chlorophenylhydrazone or by use of the temperature-sensitive mutant ts045, which is restricted to the ER at 40 degrees C, we showed that processing of G protein occurred in the ER and was not due to retention of newly synthesized Golgi enzymes. Rather, redistribution of preexisting cis and medial Golgi enzymes to the ER occurred as soon as 2.5 min after addition of BFA, and was complete by 10-15 min. Delivery of Golgi enzymes to the ER was energy dependent and occurred only at temperatures greater than or equal to 20 degrees C. BFA also induced retrograde transport of G protein from the medial Golgi to the ER. Golgi enzymes were completely recovered from the ER 10 min after removal of BFA. These findings demonstrate that BFA induces retrograde transport of both resident and itinerant Golgi proteins to the ER in a fully reversible manner.

The haemagglutinin (HA) of influenza A virus consists of two glycopolypeptides designated HA1 and HA2. Antibodies recognizing HA1 inhibit virus haemagglutination, neutralize virus infectivity and provide good protection against infection, but do not cross-react with the HA of other subtypes. Little is known regarding the biological activities of antibodies against HA2. To study the role of antibodies directed against HA2 during influenza virus infection, two vaccinia virus recombinants (rVVs) were used expressing chimeric molecules of HA, in which HA1 and HA2 were derived from different HA subtypes. The KG-11 recombinant expressed HA1 from A/PR/8/34 (H1N1) virus and HA2 from A/NT/60 (H3N2) virus, whilst KG-12 recombinant expressed HA1 from A/NT/60 virus and HA2 from A/PR/8/34 virus. Immunization of BALB/c mice with rVV expressing HA2 of the HA subtype homologous to the challenge virus [A/PR/8/34 (H1N1) or A/Mississippi/1/85 (H3N2)] did not prevent virus infection, but nevertheless resulted in an increase in mice survival and faster elimination of virus from the lungs. Passive immunization with antibodies purified from mice immunized with rVVs confirmed that antibodies against HA2 were responsible for the described effect on virus infection. Based on the facts that HA2 is a rather conserved part of the HA and that antibodies against HA2, as shown here, may moderate virus infection, future vaccine design should deal with the problem of how to increase the HA2 antibody response.

It has been proposed that tumor cells frequently associated with partial or total loss of HLA class Ia expression may abnormally express HLA-G class Ib antigen. Such peculiar HLA class I expression would allow tumor cells to escape not only from CD8+T but also from NK-cell cytotoxicity. We studied the cell surface expression of HLA-G using flow cytometry with two HLA-G specific monoclonal antibodies (87G, 01G). The JEG-3 choriocarcinoma cell line, which constitutively expresses HLA-G antigens was used as a positive control. We did not detect the cell-surface HLA-G antigens in the following 75 tumor cell lines: melanoma (22), neuroblastoma (7), retinoblastoma (1), glioma (2), breast carcinoma (3), ovarian carcinoma (3), cervical carcinoma (1), colon carcinoma (3), bladder carcinoma (2), hepatocarcinoma (1), sarcoma (2) and leukemia cell lines: T-lymphocytes (6), B-lymphocytes (13) and myelo-monocytes (9). We found that some myelomonocytic cell lines express on their surface high affinity FcgammaRI (CD64) that may result in the binding of HLA-G specific mabs to their cell surface even in the absence of HLA-G molecules. Our panel of HLA-G negative tumor cell lines accommodated 62 cell lines for which similar analysis have not been reported and also contained 13 cell lines with total or partial loss of HLA class Ia molecules. Our observation imply that under normal culture conditions the cell surface HLA-G reactive with 87G and 01G mabs is absent in most tumor cell lines of different origin.

Anti-haemagglutinin monoclonal antibodies were prepared and their HA1 or HA2 specificity was determined by solid phase radioimmunoassay (RIA) using purified viral haemagglutinin (HA) and haemagglutinin glycopolypeptides HA1 and HA2, by radioimmunoprecipitation followed with SDS-PAGE, by immunoblotting and by inhibition of virus-induced haemagglutination. The capacity of these methods to estimate HA1 or HA2 specificity of anti-HA monoclonal antibodies (MoAb) was compared. HA1 specificity was demonstrated for all hybridomas originating from lymphocytes of mice immunized with complete influenza virus, except IIF4 hybridoma which was HA2-specific. All hybridomas obtained with lymphocytes from mice immunized with HA glycopolypeptide HA2 were HA2-specific. Anti-HA2 MoAb neither inhibit haemagglutination induced by the virus or by HA subunits nor neutralized viral infectivity, either alone or in mixture. As expected, all anti-HA1 MoAb were H3 subtype-specific, showing usually good reactivity only with viruses close to the virus strain used for immunization. Two anti-HA1 MoAb (IVA1 and IVG6) showed unusual cross-reactivity within the H3 subtype. All anti-HA2 MoAb were broadly cross-reactive within the H3 subtype. Moreover, a half of them showed high cross-reactivity with influenza viruses of the H7 HA subtype. But the same antibodies did not react with HA of H1, H2 and H8 subtypes.