Limitations of current diagnostic procedures for the diagnosis of Taenia solium cysticercosis in rural pigs.

The aim of the present study was to evaluate diagnostic procedures for porcine cysticercosis. Sera were obtained from 32 pigs reared in commercial farms, 47 pigs before and after experimental infection, 42 carefully necropsied rural pigs and 191 slaughtered pigs from rural communities in which the presence of the Taenia solium metacestode was assessed by tongue dissection. Sera were analyzed by ELISA to detect antibodies against T. solium antigens and to detect parasite antigens. Most sera from the necropsied rural pigs were also evaluated by the Western blot method. Antigen and antibody ELISA detection assays showed high sensitivity and specificity when applied to sera from pigs reared in commercial farms. In contrast, all methods (Ag-ELISA, Ab-ELISA assays, EITB and tongue inspection) showed lower sensitivity and specificity when applied to the generally lightly infected rurally reared pigs. The probability distribution of cysts in carcasses were also determined. These results emphasize the difficulties in detecting cysticercosis in rural pigs with low levels of cyst burdens.

Characterization of the African swine fever virion protein j18L.

The African swine fever virus (ASFV) open reading frame (ORF) that is named jl8L in the Malawi (LIL20/1) isolate and E199L in the Ba71V isolate encodes a cysteine rich protein of 195 amino acids with a predicted molecular mass of 21.7 kDa and a hydrophobic domain near the C terminus. There are several possible motifs for glycosylation, phosphorylation and myristoylation. Rabbit antisera and monoclonal antibodies raised against a recombinant ASFV j18L protein expressed as a fusion protein with glutathione S-transferase (GST) identified proteins of 19.0-20 kDa in cells infected with different ASFV strains and with a recombinant vaccinia virus expressing j18L. The monoclonal antibodies detected a protein of 20.0 kDa whereas rabbit antisera detected two proteins with relative molecular masses of 15.0 and 20.0 kDa in purified extracellular ASF virions. In ASFV-infected cells, the j18L protein was expressed late post-infection and was localized mainly in the viral factories.

CD38 expression on mouse T cells: CD38 defines functionally distinct subsets of alpha beta TCR+CD4-CD8- thymocytes.

We have examined CD38 expression on mouse lymphocytes using the rat mAb NIM-R5 and demonstrate that CD38 expression is restricted to approximately 8% of thymocytes. Although CD38 is absent from the majority of CD4+CD8- and CD4-CD8+ T cells, we detected a strong correlation between CD38 expression and alpha beta+CD4-CD8- T cells in the thymus, with nearly 80% of alpha beta TCR+CD4-CD8- thymocytes being CD38+. Using heat stable antigen (HSA) and CD38, we divided alpha beta+CD4-CD8- thymocytes into four subsets: HSA+CD38-, HSA-CD38hi, HSA-CD38low and HSA-CD38-. Two established characteristics of alpha beta TCR+CD4-CD8- cells, bias towards V beta 8.2 TCR expression and high levels of IL-4 production, were used to establish a possible relationship between the above thymocyte subsets. Our present data show that the HSA+CD38- subset is not biased towards V beta 8.2 TCR expression whereas the HSA-CD38- subset does show this bias (approximately 47%). Neither of these subsets make IL-4 upon CD3 mediated stimulation. In contrast, the CD38+ subsets are heavily biased toward V beta 8.2 expression and produce large amounts of IL-4 upon stimulation, particularly the CD38low cells. Taken together, these data suggest that these four subsets represent various stages of a possible differentiation pathway for alpha beta TCR+CD4-CD8- cells, with the HSA+CD38- subset being the most immature while the HSA-CD38low subset is the most functionally mature. These characteristics support the view that alpha beta TCR+CD4-CD8- T cells represent an independent lineage with a distinct, but as yet obscure, role in immunity.

The expression of surface IgD on B cells responsive to thymus-independent and thymus-dependent antigens and its requirement for B-cell triggering.

Cells separated by the fluorescence activated cell sorter on the basis of their surface IgD (sIgD) phenotype have been examined for responsiveness to thymus-dependent and thymus-independent antigens. The ability of monoclonal anti-IgD alloantibodies to inhibit responses in vitro to the various classes of antigen has also been investigated. Evidence is presented indicating that both sIgD positive and sIgD negative cells can respond to all types of antigen tested. However, although the presence of sIgD was necessary for the response of sIgD positive cells to thymus-dependent antigens, the presence of this isotype was not obligatory for the response of the sIgD positive population to thymus independent antigens. The possible role of sIgD as the obligatory purveyor of a B-cell activation signal is discussed in the light of these findings.

Control of J chain biosynthesis in relation to heavy and light chain synthesis, polymerization and secretion.

Mouse myeloma tumors and some variants derived from them were labeled in vitro with tritiated leucine and the radioactive J chain was assayed in cell lysates by precipitation with an antiserum specific for mouse J chain. The major findings were: 1) J chain can be found in an IgG2b-secreting cells (MPC-11). These data, together with previous findings suggest that cells secreting all classes of IgG synthesize J chain, even though there is no apparent requirement for J chain in assembly of the IgG molecule. Hence production of J chain does not depend upon secretion of a polymeric immunoglobulin. 2) Intracellular J chain can be found in myeloma variants that do not produce heavy chains showing that production of J chain may not coordinately be linked to the synthesis of heavy chain. 3) J chain was found in cells synthesizing, but not secreting, immunoglobulin. Thus production of J chain is not linked to secretion of immunoglobulin. 4) J chain could not be detected in plasma cells that do not produce immunoglobulins. It was also not found in mouse leukemic cells, suggesting that production of J chain is probably linked in some way to immunoglobulin production.