Publications

Ets transcription factors are involved in cell growth and angiogenesis. Ets-1 targets include members of the matrix metalloproteinase superfamily. In inflammatory glomerular diseases, the patterns and regulation of Ets expression have not been fully characterized. In the present study, nuclear binding activities to the consensus Ets-1/PEA3 motif were detected in mesangial cells (MC), and the Ets-1 protein was positively identified by Western blotting, reverse transcription PCR (RT-PCR), and DNA-binding studies. The 5' flanking regions of the human and rat gelatinase A genes contain clusters of potential Ets-1 binding motifs, one of which is evolutionarily conserved. Using a series of 5' deletion reporter constructs of the rat gelatinase A gene and an Ets-1 expression plasmid, a concentration-dependent threefold trans-activation of gene expression mapped to the conserved Ets-1 binding motif at -1004/-1053 bps, designated responsive element-2 (RE-2). The RE-2 was operative within the context of the homologous gelatinase A promoter but not with a heterologous simian virus 40 promoter. Specific Ets-1 binding to this sequence was demonstrated by DNA-binding studies. Transient expression of an Ets-1 expression plasmid increased gelatinase A protein expression. Our findings identify an additional matrix metalloproteinase family member, gelatinase A, as an Ets-1 responsive gene in MC that may play a role in the high level expression of this enzyme in inflammatory glomerular diseases.

NK cells have the ability to recognize and kill MHC-mismatched hemopoietic cells. In the present study, strain-specific differences in the rat NK allorecognition repertoire were exploited to generate Abs against receptors that may be involved in allogeneic responses. A mAb termed STOK9 was selected, and it reacted with subsets of NK cells and NKR-P1(+) T cells from certain rat strains possessing highly alloreactive NK cells. The STOK9(+) NK subset was broadly alloreactive and lysed Con A lymphoblast targets from a range of MHC-mismatched strains. The mAb STOK9 precipitated a 75-kDa dimeric glycoprotein from NK lysates. Expression cloning revealed that each monomer consisted of 231 aa with limited homology to other previously characterized killer cell lectin-like receptors (KLRs). This glycoprotein therefore constitutes a novel KLR branch, and it has been termed KLRH1. A gene in the central region of the natural killer gene complex on rat chromosome 4 encodes KLRH1. A mouse homolog appears to be present as deduced from analyses of genomic trace sequences. The function of KLRH1 is unknown, but it contains an immunoreceptor tyrosine-based inhibitory motif, suggesting an inhibitory function. The MHC haplotype of the host appears to influence KLRH1 expression, suggesting that it may function as an MHC-binding receptor on subsets of NK cells and T lymphocytes.

The requirement for cytotoxic T lymphocytes during allograft rejection is controversial. We have demonstrated that CD8+ T cells are not essential for allograft rejection or for the induction of apoptosis in two experimental models of transplantation. To determine candidate cells types which may play a role in the events leading to graft rejection, the cellular composition of rejecting allografts was determined. We demonstrate that substantial numbers of NK cells, of recipient origin, infiltrate allografts as early as 12 h after transplantation. These NK cells produce cytokines and express cytotoxic mediators such as granzyme B and FasL. It is unknown which NK cell receptors are expressed and activated during transplantation. NK cells express multiple cell surface receptors, including MHC class I binding inhibitory receptors, which deliver a negative signal, and activation receptors, which stimulate cytokine secretion and cytotoxicity of NK cells. To begin to understand NK cell activation in the context of transplantation, we have recently cloned a novel rat immunoglobulin-like surface receptor from a rejecting liver allograft. Sequence analysis demonstrates that this putative activation receptor contains 71% identity to human NKp30 at the DNA level, suggesting that it is the rat homologue (rNKp30). Characterization of NK activation receptors may lead to better understanding of the interactions between the innate and adaptive immune responses in transplantation.