Immunosuppressive therapy modulates T lymphocyte gene expression in patients with systemic lupus erythematosus.

To evaluate the T-cell large-scale differential gene expression in systemic lupus erythematosus (SLE) patients presenting with glomerulonephritis we studied SLE patients before and after immunosuppressive treatment. Large-scale gene expression of peripheral blood mononuclear T cells was evaluated using cDNA microarray nylon membranes containing 5184 cDNAs. Data were analysed using the SAM and Cluster and Treeview software. When untreated patients were compared to healthy individuals, 38 genes, most of them located on chromosomes 1, 3, 6, 17 and 19, were repressed, and when untreated patients were compared to treated ones, 154 genes, located on chromosomes 1, 6, 7, 12 and 17, were induced. In terms of biological function of coded proteins, the differentially expressed genes were associated with apoptosis, cell cycle, chromosomal scaffold, cytokine/chemokine, DNA repair/replication, Golgi/mitochondrial proteins, mRNA processing, signalling molecules and tumour suppressors. Two autoantigen genes related to RNA splicing (small nuclear riboprotein 70,000 MW-U1 SNR, and splicing factor 3a, 60,000 MW), and the tetranectin-plasminogen-binding protein were repressed. The Fc fragment of immunoglobulin G low affinity IIb, apoptotic protease activating factor-1, two subunits of cytochrome c, caspase 8, complement C5a, HLA-DRA, HLA-DQB1, transforming growth factor-beta receptor II, small nuclear ribonucleoprotein polypeptide N (Sm protein N) genes, heterogeneous nuclear riboprotein-C, and argininosuccinate lyase genes, among others, were induced. A total of 10 genes were repressed in untreated patients and induced in treated ones, among them tumour necrosis factor (ligand) superfamily member 9, tumour protein p53, mannosidase alpha class IA, and CD22. Although some of these differentially expressed genes are typically expressed in B cells, CD22 and CD32 have also been reported in T cells and may provide regulatory signals to B cells. Assessment of differential gene expression may provide hybridization signatures that may identify susceptibility, diagnostic and prognostic markers of SLE.

Systemic lupus erythematosus patients under immunosuppressive treatment express high levels of the immunoglobulin lambda variable IGLV8S1 gene with silent somatic mutations.

Systemic lupus erythematosus (SLE) patients express high titers of somatically mutated serum autoantibodies against nuclear structures including double-stranded DNA. These somatic mutations accumulate codons for basic amino acids in the immunoglobulin variable regions of both, heavy and light chains, facilitating binding to nucleic acids. The variable (V) immunoglobulin lambda 8 (IGLV8S1) gene contributes to autoreactive B-cell repertoire of auto-immune patients. Accumulation of immune complexes of these anti-DNA autoantibodies causes severe systemic inflammation in SLE. The current treatment of lupus disease is based on immunosuppressive drugs, but the precise role for this therapy remains to be defined. To evaluate the in vivo effect of combined immunosuppressive treatment on B-lymphocytes repertoire of SLE patients, we have developed an approach using the IGLV8S1 gene as a marker. The transcription of this gene in treated SLE patients was increased. However, we observed a trend, in these patients, to conserve complementarity determining regions (CDRs) and framework regions (FRs) of Vlambda8 polypeptide light chain deduced sequence, from its germline counterpart. Sequencing IGLV8S1 cDNA of untreated SLE patients, taken as a control for treatment effect, displayed a decreased frequency of silent somatic mutations (consequently high frequency of replacement mutations) in the Vlambda8 polypeptide chain deduced sequence. These data suggest that the immunosuppressive drug treatment modulates the positive selection of somatically mutated Vlambda8 light chain.