N-cadherin is involved in axon-oligodendrocyte contact and myelination.

We have analyzed the influence of the calcium-dependent cell adhesion molecule, N-cadherin, on events leading to CNS myelination. Interactions between axons and oligodendrocyte progenitor (OP) cells and the CG4 OP cell line were examined by video-microscopy. OPs cocultured with dorsal root ganglia explants migrated around the culture and formed numerous contacts with axons. The duration of these contacts depended on the morphology of the OP, with OPs containing four or more processes forming long-lasting contacts and OPs with three or fewer processes forming short-termed contacts. Treatment with N-cadherin function blocking peptides approximately halved the duration of contacts made by cells with four or more processes but contact times for cells with three or less processes were unaffected. The L7 cadherin-blocking antibody and calcium withdrawal had similar effects. Contacts with axons regenerating from explants of adult retina, which do not have N-cadherin on their surface was examined. The contact duration of OPs to adult retina axons was short and similar in length to those formed between OPs and dorsal root ganglion axons in the presence of cadherin blocking reagents. Oligodendrocyte myelination was examined in organotypic rat cerebellar slice cultures, taken before myelination at postnatal day 10 and then allowed to myelinate in vitro over 7 days. When incubated with an N-cadherin function-blocking peptide, myelination of Purkinje cell axons was reduced to about half of control levels, while control peptides were without effect. Cadherin-blockade did not prevent maturation of OPs, since oligodendrocytes showing myelin basic protein immunostaining were still found in these cultures. However, many of the cell processes did not colocalize with calbindin-positive axons. From these data we conclude that N-cadherin is important for the initial contact between a myelinating oligodendrocyte and axons and significantly contributes to the success of myelination.

Calreticulin affects beta-catenin-associated pathways.

Calreticulin, a Ca(2+) storage protein and chaperone in the endoplasmic reticulum, also modulates cell adhesiveness. Overexpression of calreticulin correlates with (i) increased cell adhesiveness, (ii) increased expression of N-cadherin and vinculin, and (iii) decreased protein phosphorylation on tyrosine. Among proteins that are dephosphorylated in cells that overexpress calreticulin is beta-catenin, a structural component of cadherin-dependent adhesion complexes, a member of the armadillo family of proteins and a part of the Wnt signaling pathway. We postulate that the changes in cell adhesiveness may be due to calreticulin-mediated effects on a signaling pathway from the endoplasmic reticulum, which impinges on the Wnt signaling pathway via the cadherin/catenin protein system and involves changes in the activity of protein-tyrosine kinases and/or phosphatases.

Developmental expression and distribution of N- and E-cadherin in the rat ovary.

The calcium-dependent cell adhesion molecules, cadherins, regulate intercellular junction formation, cell sorting, and the establishment of cell polarity. Their important role in tissue remodeling suggests an involvement in ovarian cellular rearrangements throughout postnatal development. The ovary has a complex topology, and the ovarian follicle undergoes significant cellular rearrangements during its development. Cadherins have been detected previously in whole ovaries and in ovarian cells and cell lines with some immunolocalization in fetal and adult ovaries. This study examines the expression and localization of N- and E-cadherin throughout prepubertal ovarian and follicular development in the rat. We analyzed ovarian cadherin expression in rats from Day 19-20 of gestation to 25 days postpartum, during which follicle formation and folliculogenesis are the dominant ovarian events. Reverse transcriptase polymerase chain reaction detected N- and E-cadherin mRNA expression in the ovaries at all the ages examined. Semiquantification of Western blots of whole ovary extracts confirmed the presence of ovarian N- and E-cadherin protein at all ages with both showing peak expression at 7 days of age. Immunostaining revealed N- and E-cadherin expression in follicular and extrafollicular cell types, but only E-cadherin showed follicle-stage-dependent expression. The changes in cadherin expression, concurrent with ovarian growth and folliculogenesis, suggest a function for cadherins in the morphological and functional development of the prepubertal rat ovary.

INP, a novel N-cadherin antagonist targeted to the amino acids that flank the HAV motif.

The classical cadherins are homophilic binding molecules that play fundamental roles in several biological processes, including axonal growth and synaptic plasticity. The structures of the amino-terminal homophilic binding domains of N-cadherin and E-cadherin have been resolved. However, the mechanisms that govern cadherin binding and specificity remain contentious. In the present study we have used a peptide competition approach to probe for small linear determinants of cadherin binding. We demonstrate that a linear peptide mimetic of a short sequence in ECD1 of N-cadherin (INPISGQ) functions as a highly specific and potent antagonist of N-cadherin function with an IC(50) value of approximately 15 microM. Peptide mimetics of the corresponding motif in chick R-cadherin also inhibited N-cadherin function, albeit with lower efficacy. In contrast, peptide mimetics of the corresponding motif in E- or P-cadherin failed to inhibit N-cadherin function. A short cyclic peptide that contained only the INP motif from N-cadherin was also a potent N-cadherin antagonist (IC(50) approximately 15 microM). Analysis of existing crystal structures suggests that the peptides are likely to antagonize N-cadherin function by binding to the region that flanks the HAV motif at the adhesion dimer interface.

Follicular atresia and luteolysis. Evidence of a role for N-cadherin.

Studies suggest that cell-cell interactions may regulate apoptosis; and, in particular, the calcium-dependent cell adhesion molecule N-cadherin has been shown to be capable of modulating this process. Here, we review the evidence that N-cadherin is expressed by human granulosa cells (GCs) and mediates cell-cell adhesion between GCs. There is strong correlation between N-cadherin expression by granulosa or luteal cells and follicular survival in isolated follicles and archival tissue sections. There exists a strong expression of the molecule by GCs in follicles of the resting pool, of growing antral follicles, and of healthy corpora lutea. In contrast, the molecule is lost in degenerating GCs of atretic follicles and in luteal cells of the late luteal phase. Further, the experimental evidence demonstrates that cell-cell adhesion is critical to the survival of GCs and that N-cadherin-mediated cell-cell adhesion is a critical mediator of survival signals and inhibits apoptosis in these cells. Possible mechanisms by which apoptosis may be triggerred in GCs include the downregulation of N-cadherin, which is mediated, at least in part, through the enzymatic cleavage of the extracellular domain of the molecule. Collectively, these observations suggest that downregulation of N-cadherin or the absence of a functional extracellular domain of the molecule prevent GC aggregation and is associated with GC apoptosis. We propose that N-cadherin-mediated GC signaling plays a central role in follicular and luteal cell survival.

N-cadherin influences migration of oligodendrocytes on astrocyte monolayers.

Oligodendrocyte cell migration is required for the development of the nervous system and the repopulation of demyelinated lesions in the adult central nervous system. We have investigated the role of the calcium-dependent adhesion molecules, the cadherins, in oligodendrocyte-astrocyte interaction and oligodendrocyte progenitor migration. Immunostaining demonstrated the expression of N-cadherin on the surfaces of both oligodendrocytes and astrocytes, and oligodendrocyte-like cells adhered to and spread on N-cadherin substrates. The blocking of cadherin function by antisera or specific peptides reduced adhesion of oligodendroglia to astrocyte monolayers, diminished contact time between oligodendrocyte processes and individual astrocytes, and significantly increased the migration of oligodendrocyte-like cells on astrocyte monolayers. Furthermore, a soluble cadherin molecule without adhesive properties increased oligodendroglial proliferation on various extracellular matrix substrates. These data suggest that cadherins are at least partially responsible for the poor migration-promoting properties of astrocytes and that decreasing cell-cell adhesion might effect repopulation of demyelinated multiple sclerosis lesions by oligodendrocyte progenitors.

Cadherins: crucial regulators of structure and function in reproductive tissues.

Cadherins are cell surface proteins that are directly involved in a wide variety of processes such as cell adhesion, cell sorting, cell survival, morphogenesis, formation of intercellular junctions, maintenance of tissue integrity and tumourigenesis. This review discusses the multiple functions of cadherins in reproductive tissues. Furthermore, the role of the intracellular signalling protein beta-catenin in regulating cadherin function is reviewed. Finally, the findings that cadherin concentrations in reproductive tissues are responsive to steroid hormones is discussed. The modulation of cadherin expression by hormones is in agreement with the hypothesis that these proteins are dynamically involved in the maintenance of structure and function in reproductive tissues.

A novel family of cyclic peptide antagonists suggests that N-cadherin specificity is determined by amino acids that flank the HAV motif.

The classical cadherins (e.g. N-, E-, and P- cadherin) are well established homophilic adhesion molecules; however, the mechanism that governs cadherin specificity remains contentious. The classical cadherins contain an evolutionarily conserved His-Ala-Val (HAV) sequence, and linear peptides harboring this motif are capable of inhibiting a variety of cadherin-dependent processes. We now demonstrate that short cyclic HAV peptides can inhibit N-cadherin function. Interestingly, the nature of the amino acids that flank the HAV motif determine both the activity and specificity of the peptides. For example, when the HAV motif is flanked by a single aspartic acid, which mimics the natural HAVD sequence of N-cadherin, the peptide becomes a much more effective inhibitor of N-cadherin function. In contrast, when the HAV motif is flanked by a single serine, which mimics the natural HAVS sequence of E-cadherin, it loses its ability to inhibit the N-cadherin response. Our results demonstrate that subtle changes in the amino acids that flank the HAV motif can account for cadherin specificity and that small cyclic peptides can inhibit cadherin function. An emerging role for cadherins in a number of pathological processes suggests that the cyclic peptides reported in this study might be developed as therapeutic agents.

Cadherins as modulators of angiogenesis and the structural integrity of blood vessels.

The endothelial cell adhesion molecules, neural- and vascular endothelial-cadherin play essential roles in the formation of stable and fully functional blood vessels. This commentary discusses the multiple functions of these two cadherins in angiogenesis and the maintenance of blood vessel structural integrity.

N-Cadherin inhibits Schwann cell migration on astrocytes.

Astrocytes exclude Schwann cells (SCs) from the central nervous system (CNS) at peripheral nerve entry zones and restrict their migration after transplantation into the CNS. We have modeled the interactions between SCs, astrocytes, and fibroblasts in vitro. Astrocytes and SCs in vitro form separate territories, with sharp boundaries between them. SCs migrate poorly when placed on astrocyte monolayers, but migrate well on various other surfaces such as laminin (LN) and skin fibroblasts. Interactions between individual SCs and astrocytes result in long-lasting adhesive contacts during which the SC is unable to migrate away from the astrocyte. In contrast, SC interactions with fibroblasts are much shorter with less arrest of migration. SCs adhere strongly to astrocytes and other SCs, but less well to substrates that promote migration, such as LN and fibroblasts. SC-astrocyte and SC-SC adhesion is mediated by the calcium-dependent cell adhesion molecule N-cadherin. Inhibition of N-cadherin function by calcium withdrawal, peptides containing the classical cadherin cell adhesion recognition sequence His-Ala-Val, or antibodies directed against this sequence inhibit SC adhesion and increase SC migration on astrocytes. We suggest that N-cadherin-mediated adhesion to astrocytes inhibits the widespread migration of SCs in CNS tissue.

Reproductive tract secretions and bull spermatozoa contain different clusterin isoforms that cluster cells and inhibit complement-induced cytolysis.

Clusterin from bull rete testis fluid (RTF), cauda epididymal fluid (CEF), and octyl-beta-D-glucopyranoside extract of cauda epididymal sperm (CES) was identified and characterized using monoclonal and polyclonal antibodies (Abs) developed against ram clusterin and a beta-subunit-specific oligopeptide of porcine clusterin. One-dimensional sodium dodecyl sulphate-polyacrylamide gel electrophoresis and western blotting showed that bovine RTF clusterin had dimeric and monomeric molecular weights (M(r)s) of approximately 94 kDa and of 42 and 43 kDa, respectively. Clusterin in CEF and CES had similar dimeric M(r)s (74 kDa). Reduced CEF clusterin appeared as three monomers (M(r)=40, 39, and 38 kDa), whereas reduced CES clusterin appeared only at M(r)40 kDa. Enzymatic deglycosylation resulted in similar M(r)s of clusterin from RTF, CEF, and CES. The M(r) of RTF clusterin decreased from 94 kDa to 51 kDa, indicating a carbohydrate content of 45%. After deglycosylation, the M(r) of the CEF clusterin decreased from 74 kDa to two distinct bands at 51 and 50 kDa (with carbohydrate contents of 31 and 32%, respectively), suggesting that two isoforms of the heterodimeric protein are present because of the two isoforms of the alpha-subunit. Under nonreduced conditions, a beta-subunit-specific Ab reacted with M(r) of 36-38 kDa, indicating the existence of free clusterin beta-subunits in CES. RTF, CEF, and CES extracts all caused mouse fibroblastic L-cell aggregation. CEF cell aggregation was inhibited by Hyb-17 Ab but not by other Abs. Both RTF and CEF caused a dose-dependent inhibition of complement-induced cytolysis, although RTF clusterin was more potent than CEF clusterin. We conclude that several isoforms of clusterin occur in the bull reproductive tract and that the variation in carbohydrate content among these isoforms may affect the biological or functional activity of the protein.

N-cadherin-mediated human granulosa cell adhesion prevents apoptosis: a role in follicular atresia and luteolysis?

Studies suggest that cell-cell interactions may regulate apoptosis, and in particular, the calcium-dependent cell adhesion molecule N-cadherin has been shown to be capable of modulating this process. Rat granulosa cells (GCs) are known to express N-cadherin whereas cAMP is known to induce apoptosis in human and rat GCs. Based on these observations, we hypothesized that N-cadherin regulates human GC apoptosis via a cAMP-dependent mechanism. N-cadherin expression was evaluated in ovarian follicles and corpora lutea utilizing immunohistochemical techniques and in luteinized GCs in culture using immunoblotting, flow cytometric analysis, immunohistochemistry, and indirect immunofluorescence techniques utilizing anti-N-cadherin antibodies directed against both the extracellular and cytoplasmic domains of the molecule. Apoptosis was assessed by TUNEL and DNA fragmentation analysis and confirmed by flow cytometric cell cycle analysis and electron microscopy. The rate of GC apoptosis was found to be two- to three-fold lower among aggregated cells, as compared with single cells. N-cadherin was found to be expressed by aggregating GCs in vitro and GCs cultured in the presence of either N-cadherin function disrupting antibodies or peptides exhibiting enhanced rates of apoptosis. GCs in situ stained intensely for N-cadherin in preantral and normal growing preovulatory follicles as well as early corpora lutea. N-cadherin was weak in atretic follicles and regressing corpora lutea. Exposure of GCs to cAMP increased apoptosis while decreasing N-cadherin protein expression in a dose-dependent manner. Cell culture under serum-free conditions increased apoptosis and decreased N-cadherin expression, in part through cleavage of the extracellular domain of the molecule. The metalloproteinase inhibitor 1-10-phenanthroline inhibited the cleavage of the extracellular domain of N-cadherin and concomitantly inhibited the serum-deprivation-induced apoptosis of aggregated GCs. Collectively, these observations suggest that down-regulation of N-cadherin or the absence of a functional extracellular domain of the molecule prevents cell aggregation and is associated with GC apoptosis. In addition, cAMP induces apoptosis in a dose-dependent manner, and this process is dependent, at least in part, on regulation of the N-cadherin molecule at the surface of the cells. We conclude that N-cadherin-mediated GC signaling plays a central role in follicular and luteal cell survival.

Activated T-lymphocytes express occludin, a component of tight junctions.

T-lymphocytes routinely traffic from the lymphoid and vascular compartments to the tissues during immune surveillance and inflammatory responses. This egress occurs without compromising endothelial barrier, which is maintained by tight junctions (zonula occludens). We report that T-lymphocytes up-regulate the expression of occludin, a major component of the tight junction in response to stimulation with phorbol ester (PMA) + calcium ionophore, CD3 antibody or T-cell receptor (TCR) antibody. Only activated T-lymphocytes express occludin; this adhesion molecule is nearly absent in resting T-lymphocytes. By immunofluorescence, occludin is seen in lymphocyte aggregates, but does not appear to mediate aggregation since only 50% of the cells in these clusters express occludin. Occludin is expressed between 8 and 24 h following stimulation, and persists for at least 48 h. These data indicate that activated T cells produce occludin which may regulate lymphocyte adhesion and trafficking.

Deficient epithelial-fibroblast heterocellular gap junction communication can be overcome by co-culture with an intermediate cell type but not by E-cadherin transgene expression.

Epithelial, fibroblast and intermediate cell lines were employed to examine the mechanism(s) essential for heterocellular gap junction intercellular communication in vitro. These cell lines were characterized extensively for cell type based on morphology, intermediate cytoskeletal proteins, cell adhesion molecules and their associated proteins, tight junction proteins as well as functional differentiation. All cell types expressed connexin43 and were dye-coupled in homocellular culture. Epithelial and intermediate cells or fibroblasts and intermediate cells readily assembled heterocellular connexin43-positive gap junction plaques when co-cultured, while gap junction plaques in mixed cultures of epithelial cells and fibroblasts were rare. Dye microinjection studies were used to show that there was little gap junction intercellular communication between epithelial cells and fibroblasts. However, intermediate cells were able to communicate with epithelial cells and, to a lesser extent, fibroblasts and could transfer dye to both epithelial cells and fibroblasts when all three cell types were cultured together. Fibroblasts that were stably transfected with a cDNA encoding E-cadherin had a greater tendency to aggregate and exhibited a more epithelial-like phenotype but heterocellular gap junction intercellular communication with epithelial cells, which endogenously express E-cadherin, was not enhanced. These results suggest that mutual expression of E-cadherin is insufficient to stimulate gap junction formation between epithelial cells and fibroblasts. Moreover, our results also demonstrate that communication gaps between epithelial cells and fibroblasts can be bridged by intermediate cells, a process that may be important in mammary gland development, growth, differentiation and cancer.

Regulated expression of cadherin-6 and cadherin-11 in the glandular epithelial and stromal cells of the human endometrium.

The cadherins are key morphoregulators. A switch in the cadherin subtype(s) expressed by a population of cells has been associated with the differentiation and formation of tissues during embryonic development. To date, the role(s) of the cadherins in the highly regulated remodeling processes which occur in the human endometrium in preparation for the implanting embryo remain poorly characterized. Here we report that two atypical cadherins, known as cadherin-6 and cadherin-11, are spatiotemporally expressed in the human endometrium during the menstrual cycle. Cadherin-6 levels are high in both the glandular epithelium and stroma of the endometrium during the follicular phase and decline as the cycle enters the luteal phase. The down-regulation of cadherin-6 in the glandular epithelium during the luteal phase does not effect the levels of cadherin-11 in this cell type. In contrast, the loss of cadherin-6 expression in endometrial stroma cells is concomitant with an increase in the levels of cadherin-11. Collectively, these observations suggest that multiple factors regulate the expression of these two endometrial cadherins. As a first step in identifying these factors, we examined the effects of progesterone on cadherin-6 and cadherin-11 expression in isolated endometrial stromal cells. Progesterone was capable of differentially regulating the expression of these two stromal cell adhesion molecules. These findings lend further support to our hypothesis that steroids are key regulators of cadherin expression in mammalian tissues.

Hormonal regulation of N-cadherin mRNA levels in rat granulosa cells.

We have examined the ability of hormones to modulate the steady-state levels of N-cadherin mRNA transcripts in aggregated and dispersed rat granulosa cell populations. Estradiol and follicle-stimulating hormone (FSH) had no effect on the levels of N-cadherin mRNA transcripts in aggregated granulosa cells. In contrast, these two hormones stimulated N-cadherin mRNA levels in dispersed granulosa cells. This is the first report that estradiol and FSH are capable of regulating N-cadherin mRNA levels. The results also suggest that the N-cadherin mRNA levels in dispersed and aggregated granulosa cells are regulated by different mechanisms.

Estrogens potentiate the stimulatory effects of follicle-stimulating hormone on N-cadherin messenger ribonucleic acid levels in cultured mouse Sertoli cells.

Gonadal steroids and FSH are key regulators of Sertoli cell function. N-Cadherin (N-cad) is a calcium-dependent cell adhesion molecule that mediates Sertoli cell-germ cell interactions. We recently demonstrated that steroids, in particular estradiol, are potent regulators of testicular N-cad messenger RNA (mRNA) levels in vivo. In view of the cooperative effects of steroids and FSH on Sertoli cell-germ cell interactions, we examined the combined effects of these hormones on N-cad mRNA levels in cultured mouse Sertoli cells. FSH was capable of increasing N-cad mRNA levels 2-fold in these cells. The effects of FSH on N-cad mRNA levels in cultured Sertoli cells were mimicked by cAMP-inducing agents. Treatment of the Sertoli cell cultures with FSH and estradiol stimulated N-cad mRNA levels 3-fold, whereas steroids alone had no effect on N-cad mRNA levels. These studies demonstrate that FSH and estradiol in combination are required to achieve maximal N-cad mRNA levels in cultured Sertoli cells. The results obtained from these studies substantiate the hypothesis that estrogens play a pivotal role in regulating spermatogenesis.

A comprehensive survey of the cadherins expressed in the testes of fetal, immature, and adult mice utilizing the polymerase chain reaction.

The cadherins are a family of calcium-binding membrane glycoproteins. Most cadherins are capable of acting as cell adhesion molecules (CAMs). In order to begin a thorough analysis of the roles of these CAMs in the testis, we employed a reverse transcriptase-polymerase chain reaction (RT-PCR) strategy to identify the cadherins expressed in this tissue at various stages of development. Oligonucleotides encoding amino acid sequences that are conserved among all of the known cadherins were used as primers in the RT-PCR, with cDNA preparations of fetal, newborn, 7-day, 21-day, and adult mouse testes employed as templates. The PCR products were subcloned into a plasmid vector and sequenced. On the basis of the nucleotide sequences of these PCR products, we have determined that five previously characterized cadherins (E-cadherin, N-cadherin, P-cadherin, K-cadherin, and OB-cadherin), as well as two novel cadherins (T1-cadherin and T2-cadherin), are expressed at various stages during testicular development. In order to determine the expression patterns of these cadherins, we ascertained the mRNA levels of each cadherin normalized to the levels of hypoxanthine phosphoribosyltransferase mRNA in fetal, newborn, 7-day, 21-day, and adult mouse testes. We observed that N-cadherin mRNA is expressed at all stages of testicular development, with maximal levels being present in the testes of 21-day-old mice. Furthermore, we found that E-, P-, K-, OB-, and T2-cadherin mRNAs are all expressed in the fetal gonad. The testicular levels of these cadherin mRNAs decreased dramatically after birth. Conversely, T1-cadherin mRNA was not detected in the fetal, newborn, and 7-day-old testes but was present in 21-day-old and adult testes. T1-cadherin levels were 10-fold higher in the testes of adult mice, compared to the levels found in the testes of 21-day-old mice. We speculate that these cadherins will be found to be intimately involved in mediating cell interactions during testicular development.

Cellular heterogeneity in the membrana granulosa of developing rat follicles: assessment by flow cytometry and lectin binding.

The hormone-mediated maturation of ovarian follicles is apparently accompanied by position-specific differentiation of cells of the membrana granulosa. We have assessed the extent of this cellular heterogeneity by flow cytometry using a variety of fluorescein isothiocyanate-labeled lectins as probes. Follicular development was stimulated in immature rats by treatment with either diethylstilbestrol (DES) or equine CG (eCG). Lectin binding to monodispersed rat granulosa cells was then analyzed by flow cytometry. Our results demonstrate that there are two distinct populations of small (4-7 microM) and large (9-12 microM) granulosa cells in follicles from DES- and eCG-treated animals. Both populations appear to be mitotically active and show specific lectin-binding characteristics. Six lectins (canavalia ensiforms, triticum vulgaris, maclura pomifera, erythrina cristagalli, jacalin, and vicia villosa) bind equally to both small and large granulosa cells from the DES- and eCG-treated rats. In contrast, no binding to either cell population was detected with six other lectins (dolichos biflorus, griffonia simplicifolia-II, lycopersicon esculentum, datura stramonium, solanum tuberosum, and ulex europaeus). Furthermore, four galactose-binding lectins (bauhinia purpurea, glysine maximus, griffonia simplicifolia-I, and arachis hypogaea) were found to identify specific subsets of granulosa cells. Three of these lectins (bauhinia purpurea, glysine maximus, and griffonia simplicifolia-I) bind to only small granulosa cells from either DES- or eCG- treated immature rats. The fourth lectin (arachis hypogaea) identifies subpopulations of both small and large granulosa cells. Application of the four galactose-specific lectins to fixed sections of frozen ovaries demonstrated binding to the perioocyte and cumulus granulosa cells. We conclude that cellular heterogeneity exists within the follicular epithelium at various stages-specific lectin-binding sites.

Characterization of cadherins expressed by murine thymocytes.

Thymocytes develop in close apposition to the stromal cells of the thymus. The ontogeny of thymocytes is dependent on intimate interactions between these cells and the stromal cells. The molecular mechanisms involved in regulating thymocyte-stromal cell interactions remain to be clearly defined. In this study, we utilized a polymerase chain reaction strategy to identify members of the cadherin family of cell adhesion molecules that are expressed by CD4+ CD8+ thymocytes, the major cell type in the thymus. One classical cadherin (E-cadherin), three atypical cadherins (OB-cadherin) K-cadherin, and cadherin-8), and two novel cadherins (T1-cadherin and T2-cadherin) were found to be expressed by the CD4+ CD8+ thymocytes. The discovery that these cells display multiple cadherins opens a new area of investigation concerning the adhesive mechanisms involved in modulating thymocyte-stromal cell interactions. We speculate that cadherins will prove to play an essential role in the ontogeny of thymocytes.