Expression of costimulatory molecules CD80 and/or CD86 by a Kaposi's sarcoma tumor cell line induces differential T-cell activation and proliferation.

During physiological stimulation of resting T-cells, at least two activation signals by antigen presenting cells are required. Besides the first antigen-specific signal, the second costimulatory signal involves CD80 and CD86 expressed by the antigen presenting cell. These costimulatory molecules have been suggested to be of clinical relevance in many different autoimmune and malignant disease processes. We previously observed that tumor cells in Kaposi's sarcoma (a common AIDS-related cutaneous neoplasm) completely lack both CD80 and CD86, and these tumor cells fail to stimulate T-cell proliferation. In this study, using a Kaposi's sarcoma tumor cell line designated SLK, various stable transfected cell lines were produced. Tumor cells that were either singly positive for either CD80 or CD86, as well as a double-positive cell line, were examined for their ability to induce T-cell activation, T-cell proliferation, and cytokine production profiles. Compared to the parental double-negative tumor cell line, the CD80-positive cells, but not the CD86-positive tumor cells, induced significant T-cell activation and proliferation. Tumor cells expressing both CD80 and CD86 also induced T-cell activation. After stimulation by the transfected tumor cells, T-cells produced a Th-1 type cytokine production profile with increased IL-2 and IFN-gamma levels. These results demonstrate that Kaposi's sarcoma tumor cells lacking co-stimulatory molecules cannot induce T-cell activation; however, if they express CD80, they can induce peripheral blood T-cell proliferation, and there is a differential response as expression of CD86 did not have the same immunostimulatory effect.

Geographically distinct HHV-8 DNA sequences in Saudi Arabian Iatrogenic Kaposi's sarcoma lesions.

A new member of the gamma-herpesvirus family, HHV-8 (also known as Kaposi's sarcoma (KS)-associated herpesvirus), has been linked to KS and body cavity-based lymphoma. Other members of this family, eg, Epstein-Barr virus, were originally thought to have only one strain, but subsequent analysis revealed different strains correlating to cellular patterns of infectivity and geographical location. To determine whether multiple strains of HHV-8 exist, we compared DNA sequences among KS and body cavity-based lymphoma-derived HHV-8 and examined differences in HHV-8 subgroups between American and Saudi Arabian iatrogenic KS patients. Samples were analyzed by polymerase chain reaction using multiple primer sets to five different open reading frames from HHV-8, and DNA sequencing was performed. HHV-8 DNA was present in all of our KS and body cavity-based lymphoma samples by polymerase chain reaction. HHV-8 DNA was detected in each body cavity-based lymphoma sample using a majority of the primers, whereas only two primer sets consistently amplified HHV-8 DNA derived from KS lesions. DNA sequencing within open reading frames 26 and 27 indicate the existence of at least three variants of HHV-8, with the majority of iatrogenic KS patients in Saudi Arabia containing unique nucleotide changes that may define a distinct, previously unidentified subgroup we term SA, whereas those from America were of Group A or B. Thus, although the sequencing data within open reading frames 26 and 27 did not permit discrimination between patients with lymphoma versus KS disease processes, HHV-8 derived from Saudi Arabian KS lesions were shown to have a distinct nucleotide sequence not seen in any of the other clinical samples examined.

The bovine leukemia virus encapsidation signal is discontinuous and extends into the 5' end of the gag gene.

In order to define bovine leukemia virus (BLV) sequences required for efficient vector replication, a series of mutations were made in a BLV vector. Testing the replication efficiency of the vectors with a helper virus and helper plasmids allowed for separation of the mutant vectors into three groups. The replication efficiency of the first group was reduced by a factor of 7; these mutants contained deletions in the 5' end of the gag gene. The second group of mutants had replication reduced by a factor of 50 and had deletions including the 5' untranslated leader region. The third group of mutants replicated at levels comparable to those of the parental vector and contained deletions of the 3' end of the gag gene, the pol gene, and the env gene. Analysis of cytoplasmic and virion RNA levels indicated that vector RNA expression was not affected but that the vector RNA encapsidation was less efficient for group 1 and group 2 mutants. Additional mutations revealed two regions important for RNA encapsidation. The first region is a 132-nucleotide-base sequence within the gag gene (nucleotides 1015 to 1147 of the proviral DNA) and facilitates efficient RNA encapsidation in the presence of the second region. The second region includes a 147-nucleotide-base sequence downstream of the primer binding site (nucleotide 551) and near the gag gene start codon (nucleotide 698; gag begins at nucleotide 628) and is essential for RNA encapsidation. We conclude that the encapsidation signal is discontinuous; a primary signal, essential for RNA encapsidation, is largely in the untranslated leader region between the primer binding site and near the gag start codon. A secondary signal, which facilitates efficient RNA encapsidation, is in a 132-nucleotide-base region within the 5' end of the gag gene.