AB2083 Sigma-AldrichAnti-CD44v7 Antibody, exon v7

NK T (NKT) cells are an important component of the innate immune system and recognize the MHC class I-like CD1d molecule. NKT cells possess significant immunoregulatory activity due to their rapid secretion of large quantities of pro- and anti-inflammatory cytokines following CD1d-dependent stimulation. Because the innate immune system is programmed to respond to a multitude of diverse stimuli and must be able to quickly differentiate between pathogenic and endogenous signals, we hypothesized that, apart from stimulation via the TCR (e.g., CD1d-dependent activation), there must be multiple activation pathways that can be triggered through other cell surface receptors on NKT cells. Therefore, we analyzed the ability of CD44, a structurally diverse cell surface receptor expressed on most cells, to stimulate murine NKT cells, compared with conventional T cells. Stimulation of CD44 through Ab cross-linking or binding to its natural ligands hyaluronan and osteopontin induced NKT cells to secrete cytokines, up-regulate activation markers, undergo morphological changes, and resist activation-induced cell death, whereas conventional T cells only exhibited changes in morphology and protection from activation-induced cell death. This CD44-specific stimulation of NKT cells correlated with their ability to bind hyaluronan. Thus, fundamental differences in CD44 function between these lymphocyte subsets suggest an important biological role for CD44 in the innate immune response.

Variant CD44 has recently been shown to serve as a metastasis marker in human breast cancer. Certain variant epitopes on primary tumors predict poor survival probabilities for the patients. In this study, immunohistochemical analysis of 16 uterine cervical carcinomas showed strong expression of several CD44 variant epitopes in all samples. In normal cervical epithelia from 5 patients, expression of these epitopes was restricted to particular cell layers, with expression being strong in basal and spinal cells but absent in superficial cells. Fifteen of 16 cancer samples were stained strongly with an antibody which recognizes one particular CD44 epitope that is encoded by both variant exons v7 and v8. This epitope was not detectable in normal cervical epithelium. CD44-mRNA splicing analysis showed qualitative and quantitative differences between malignant and normal tissues with a much more complex splice pattern and high expression of a large CD44 isoform containing variant exons v3 to v10 (including the v7/v8 transition epitope) in about one-half of the cancer samples. Interestingly, patients with lymph node metastases were in this group only. These differences in CD44 epitope expression and mRNA splicing in cervical carcinoma reveal dynamic changes in CD44 expression during carcinogenesis. Such changes could provide metastatic cells with a selective advantage during the carcinogenic process. Furthermore, the v7/v8 epitope may be suitable for screening early stages of cervical cancer.

The CD44 molecule is known to display extensive size heterogeneity, which has been attributed both to alternative splicing and to differential glycosylation within the extracellular domain. Although the presence of several alternative exons has been partly inferred from cDNA sequencing, the precise intron-exon organization of the CD44 gene has not been described to date to our knowledge. In the present study we describe the structure of the human CD44 gene, which contains at least 19 exons spanning some 50 kilobases of DNA. We have identified 10 alternatively spliced exons within the extracellular domain, including 1 exon that has not been previously reported. In addition to the inclusion or exclusion of whole exons, more diversity is generated through the utilization of internal splice donor and acceptor sites within 2 of the individual exons. The variation previously reported for the cytoplasmic domain is shown to result from the alternative splicing of 2 exons. The genomic structure of CD44 reveals a remarkable degree of complexity, and we confirm the role of alternative splicing as the basis of the structural and functional diversity seen in the CD44 molecule.

A variant of the glycoprotein CD44 (CD44v) that shares sequences with variants causally involved in metastasis formation is transiently expressed on B and T lymphocytes and macrophages after antigenic stimulation and in the postnatal period. Antibodies to the variant hinder in vivo activation of both B and T cells. The observation that a protein domain that is expressed on CD44 and required for the lymphatic spread of tumor cells can catalyze an essential step in the process of lymphocyte activation supports the idea that metastasizing tumor cells mimic lymphocyte behavior.