Staphylococcal superantigens induce lymphotactin production by human CD4+ and CD8+ T cells.

Lymphotactin is a potent chemotactic cytokine (chemokine) that is produced by and also attracts T and natural killer (NK) cells. We are studying whether chemokines that affect mainly T cells might also regulate immune responses by preferentially recruiting individual subsets or by affecting cytokine or other chemokine responses. In order to pursue these questions, we need to learn more about the mechanisms regulating lymphotactin production and the cell types capable of releasing this factor. We used new monoclonal antibodies against human lymphotactin to develop a sensitive antigen-capture enzyme linked immunoabsorbent assay (ELISA) that measures chemokine levels in culture fluids. Using this capture ELISA, we showed that lymphotactin could be produced by CD4+ and CD8+ T cells, but only after T cell-receptor-dependent stimulation using bacterial superantigens and not after treatment by inflammatory cytokines or lipopolysaccharide (LPS). Our data show that lymphotactin production responds mainly to T cell-receptor signals in CD4+ and CD8+ T cells, and suggests a mechanism whereby this chemokine could help to regulate T cell immune responses.

Monomeric solution structure of the prototypical 'C' chemokine lymphotactin.

Lymphotactin, the sole identified member of the C class of chemokines, specifically attracts T lymphocytes and natural killer cells. This 93-residue protein lacks 2 of the 4 conserved cysteine residues characteristic of the other 3 classes of chemokines and possesses an extended carboxyl terminus, which is required for chemotactic activity. We have determined the three-dimensional solution structure of recombinant human lymphotactin by NMR spectroscopy. Under the conditions used for the structure determination, lymphotactin was predominantly monomeric; however, pulsed field gradient NMR self-diffusion measurements and analytical ultracentrifugation revealed evidence of dimer formation. Sequence-specific chemical shift assignments were determined through analysis of two- and three-dimensional NMR spectra of (15)N- and (13)C/(15)N-enriched protein samples. Input for the torsion angle dynamics calculations used in determining the structure included 1258 unique NOE-derived distance constraints and 60 dihedral angle constraints obtained from chemical-shift-based searching of a protein conformational database. The ensemble of 20 structures chosen to represent the structure had backbone and heavy atom rms deviations of 0.46 +/- 0.11 and 1.02 +/- 0.14 A, respectively. The results revealed that human lymphotactin adopts the conserved chemokine fold, which is characterized by a three-stranded antiparallel beta-sheet and a C-terminal alpha-helix. Two regions are dynamically disordered as evidenced by (1)H and (13)C chemical shifts and [(15)N]-(1)H NOEs: residues 1-9 of the amino terminus and residues 69-93 of the C-terminal extension. A functional role for the C-terminal extension, which is unique to lymphotactin, remains to be elucidated.

Lymphocyte activation during acute simian/human immunodeficiency virus SHIV(89.6PD) infection in macaques.

Host-virus interactions control disease progression in human immunodeficiency virus-infected human beings and in nonhuman primates infected with simian or simian/human immunodeficiency viruses (SHIV). These interactions evolve rapidly during acute infection and are key to the mechanisms of viral persistence and AIDS. SHIV(89.6PD) infection in rhesus macaques can deplete CD4(+) T cells from the peripheral blood, spleen, and lymph nodes within 2 weeks after exposure and is a model for virulent, acute infection. Lymphocytes isolated from blood and tissues during the interval of acute SHIV(89.6PD) infection have lost the capacity to proliferate in response to phytohemagglutinin (PHA). T-cell unresponsiveness to mitogen occurred within 1 week after mucosal inoculation yet prior to massive CD4(+) T-cell depletion and extensive virus dissemination. The lack of mitogen response was due to apoptosis in vitro, and increased activation marker expression on circulating T cells in vivo coincided with the appearance of PHA-induced apoptosis in vitro. Inappropriately high immune stimulation associated with rapid loss of mature CD4(+) T cells suggested that activation-induced cell death is a mechanism for helper T-cell depletion in the brief period before widespread virus dissemination. Elevated levels of lymphocyte activation likely enhance SHIV(89.6PD) replication, thus increasing the loss of CD4(+) T cells and diminishing the levels of virus-specific immunity that remain after acute infection. The level of surviving immunity may dictate the capacity to control virus replication and disease progression. We describe this level of immune competence as the host set point to show its pivotal role in AIDS pathogenesis.

Cyclophilin a modulates processing of human immunodeficiency virus type 1 p55Gag: mechanism for antiviral effects of cyclosporin A.

The molecular chaperone cyclophilin A (Cyp A) modulates human immunodeficiency virus type 1 (HIV-1) infectivity through its interactions with Gag structural proteins. The molecular mechanism for CypA in HIV-1 replication is not known. We studied chaperone effects on Gag precursor processing using cyclosporin A (CsA) to bind CypA and prevent its interaction with p55Gag. CsA treatment inhibited p55Gag processing in extracellular virus-like particles produced from COS cells. We confirmed the effect of CsA on Gag processing by examining virions produced from CEMx174 cells infected with HIV-1LAI. Particles accumulated in the presence of CsA displayed mostly immature virion morphology and lacked condensed capsids. CsA has a direct effect on HIV-1 Gag processing that implicates CypA as having an important role in the maturation of HIV-1 particles.

Gag protein from human immunodeficiency virus type 1 assembles in the absence of cyclophilin A.

Human immunodeficiency virus type 1 (HIV-1) replication requires coordinated activities of host and viral factors. We reported previously that interactions of the host factor cyclophilin A with HIV-1 Gag polyproteins affected Gag processing and maturation of virus particles (Streblow et al., 1998. Virology 245, 197-202). We now use in vitro translation and physical analysis of Gag structures to refine our understanding of how cyclophilin A affects HIV-1 replication. Gag assembled into oligomeric structures in vitro in the presence or absence of cyclophilin A, and proteins synthesized under the two conditions were equally susceptible to cleavage by exogenous HIV-1 protease. These and previous data show that Cyclophilin A is required at a step between Gag assembly and Gag processing/virion morphogenesis. Cyclophilin A may be required for Gag conformational changes subsequent to assembly, that are required for efficient dimerization and activation of the viral protease.