Paul V. Senior

Identification and characterization of the STIM (stromal interaction molecule) gene family: coding for a novel class of transmembrane proteins

STIM1 (where STIM is stromal interaction molecule) is a candidate tumour suppressor gene that maps to human chromosome 11p15.5, a region implicated in a variety of cancers, particularly embryonal rhabdomyosarcoma. STIM1 codes for a transmembrane phosphoprotein whose structure is unrelated to that of any other known proteins. The precise pathway by which STIM1 regulates cell growth is not known. In the present study we screened gene databases for STIM1-related sequences, and have identified and characterized cDNA sequences representing a single gene in humans and other vertebrates, which we have called STIM2. We identified a single STIM homologue in Drosophila melanogaster (D-Stim) and Caenorhabditis elegans, but no homologues in yeast. STIM1, STIM2 and D-Stim have a conserved genomic organization, indicating that the vertebrate family of two STIM genes most probably arose from a single ancestral gene. The three STIM proteins each contain a single SAM (sterile alpha-motif) domain and an unpaired EF hand within the highly conserved extracellular region, and have coiled-coil domains that are conserved in structure and position within the cytoplasmic region. However, the STIM proteins diverge significantly within the C-terminal half of the cytoplasmic domain. Differential levels of phosphorylation appear to account for two molecular mass isoforms (105 and 115 kDa) of STIM2. We demonstrate by mutation analysis and protein sequencing that human STIM2 initiates translation exclusively from a non-AUG start site in vivo. STIM2 is expressed ubiquitously in cell lines, and co-precipitates with STIM1 from cell lysates. This association into oligomers in vivo indicates a possible functional interaction between STIM1 and STIM2. The structural similarities between STIM1, STIM2 and D-STIM suggest conserved biological functions.

Stromal interaction molecule 1 (STIM1), a transmembrane protein with growth suppressor activity, contains an extracellular SAM domain modified by N-linked glycosylation.

Stromal interaction molecule 1 (STIM1) is a cell surface transmembrane glycoprotein implicated in tumour growth control and stromal-haematopoietic cell interactions. A single sterile alpha motif (SAM) protein-protein interaction domain is modelled within its extracellular region, a subcellular localisation not previously described for other SAM domain-containing proteins. We have defined the transmembrane topology of STIM1 by determining the sites of N-linked glycosylation. We have confirmed that STIM1 is modified by N-linked glycosylation at two sites within the SAM domain itself, deduced as asparagine residues N131 and N171, demonstrating that STIM1 is translocated across the membrane of the endoplasmic reticulum such that the SAM domain resides within the endoplasmic reticulum (ER) lumen. Both N-linked oligosaccharides remain endoglycosidase H-sensitive, indicating absence of full processing within the ER and Golgi. This immature modification is nevertheless sufficient and critical for cell surface expression of STIM1. We show that STIM1-STIM1 homotypic interactions are mediated via the cytoplasmic rather than the extracellular region of STIM1, excluding an essential role for the SAM domain in these protein interactions. These studies provide the first evidence for an extracellular localisation of a SAM domain within any protein, and the first example of a SAM domain modified by N-linked glycosylation.

Parathyroid Hormone-Related Protein Regulates Proliferation of Condylar Hypertrophic Chondrocytes

The condylar cartilage, an important growth site in the mandible, shows characteristic modes of growth and differentiation, e.g., it shows delayed appearance in development relative to the limb bud cartilage, originates from the periosteum rather than from undifferentiated mesenchymal cells, and shows rapid differentiation into hypertrophic chondrocytes as opposed to the epiphyseal growth plate cartilage, which has resting and proliferative zones. Recently, attention has been focused on the role of parathyroid hormone–related protein (PTHrP) in modulating the proliferation and differentiation of chondrocytes. To investigate further the characteristic modes of growth and differentiation of this cartilage, we used mice with a disrupted PTHrP allele. Immunolocalization of type X collagen, the extracellular matrix specifically expressed by hypertrophic chondrocytes, was greatly reduced in the condylar cartilage of homozygous PTHrP‐knockout mice compared with wild‐type mice. In contrast, immunolocalization of type X collagen of the tibial cartilage did not differ. In wild‐type mice, proliferative chondrocytes were mainly located in both the flattened cell layer and hypertrophic cell layer of the condylar cartilage, but were limited to the proliferative zone of the tibial cartilage. The number of proliferative chondrocytes was greatly reduced in both cartilages of homozygous PTHrP‐knockout mice. Moreover, apoptotic chondrocytes were scarcely observed in the condylar hypertrophic cell layer, whereas a number of apoptotic chondrocytes were found in the tibial hypertrophic zone. Expression of the type I PTH/PTHrP receptor was localized in the flattened cell layer and hypertrophic cell layer of the condylar cartilage, but was absent from the tibial hypertrophic chondrocytes. It is therefore concluded that, unlike tibial hypertrophic chondrocytes, condylar hypertrophic chondrocytes have proliferative activity in the late embryonic stage, and PTHrP plays a pivotal role in regulating the proliferative capacity and differentiation of these cells.

The expression of the gene coding for parathyroid hormone-related protein (PTHrP) during tooth development in the rat.

By means of in situ hybridisation studies, it is shown that parathyroid hormone-related protein (PTHrP) mRNA is strongly expressed in the developing enamel organs of rat teeth. In particular, the cervical loop hybridises strongly with the PTHrP probe and expression is maintained at this site throughout life in the permanently erupting incisor teeth. In mature molar teeth, expression is downregulated to low levels and confined to the epithelial cell rests of Malassez and/or cementoblasts which may derive from these. The gene is also expressed at low levels in the tissue overlying the erupting molars and, thereafter, in the junctional epithelia and connective tissue cells of the epithelial attachment on all tooth surfaces. The premise that PTHrP may undergo post-translational processing and that the resultant products could act in different ways raises the possibility of its exerting multiple paracrine actions during tooth development. These could include the control of cell division and local vascular dilation during development.

Differential responses to parathyroid hormone-related protein (PTHrP) deficiency in the various craniofacial cartilages

PTHrP null mutant mice exhibit skeletal abnormalities both in the craniofacial region and limbs. In the growth plate cartilage of the null mutant, a diminished number of proliferating chondrocytes and accelerated chondrocytic differentiation are observed. In order to examine the effect of PTHrP deficiency on the craniofacial morphology and highlight the differential feature of the composing cartilages, we examined the various cartilages in the craniofacial region of neonatal PTHrP deficient mice. The major part of the cartilaginous anterior cranial base appeared to be normal in the homozygous PTHrP deficient mice. However, acceleration of chondrocytic differentiation and endochondral bone formation was observed in the posterior part of the anterior cranial base and in the cranial base synchondroses. Ectopic bone formation was observed in the soft tissue‐running mid‐portion of the Meckels cartilage, where the cartilage degenerates and converts to ligament in the course of normal development. The zonal structure of the mandibular condylar cartilage was scarcely affected, but the whole condyle was reduced in size. These results suggest the effect of PTHrP deficiency varies widely between the craniofacial cartilages, according to the differential features of each cartilage. Anat Rec 255:452–457, 1999.

Gene expression and localization of GABAC receptors in neurons of the rat gastrointestinal tract

Abstract The effects of GABA in the CNS are mediated by three different GABA receptors: GABAA, GABAB and GABAC receptors. GABAA and GABAB receptors, but not yet GABAC receptors, have been demonstrated in the enteric nervous system, where GABA has been proposed to be a transmitter. The purpose of this study was to determine whether GABAC receptors are present and thus may play a role in mediating the effects of GABA in the myenteric plexus of the rat gastrointestinal tract. We examined the expression of the three known GABAC receptor subunits, ρ1, ρ2 and ρ3, in the rat duodenum, ileum and colon using the reverse transcriptase-polymerase chain reaction. We determined the localization of GABAC receptors in the myenteric plexus of these regions using two different antisera directed against GABAC receptor subunits. The polymerase chain reaction revealed that all three subunits were expressed in the gastrointestinal tract. When the layers of the intestine were separated and the layer containing myenteric neurons was assayed, the ρ3 subunit was found in the ileum and colon, whereas ρ1 was expressed in the duodenum and weakly in the colon and ρ2 was expressed in the ileum. Immunocytochemistry revealed numerous labeled neurons in the myenteric plexus of each region. Colocalization showed that a large proportion of calbindin plus calretinin immunoreactive neurons (intrinsic primary afferent neurons) were immunoreactive for the GABAC receptor, and that 56% of nitric oxide synthase immunoreactive neurons (inhibitory motor neurons) exhibited the receptor. These results indicate that GABAC receptors of differing subunit compositions are expressed by neurons in the rat gastrointestinal tract. The effects of GABA on intrinsic sensory and on inhibitory motor neurons are likely to be mediated in part through GABAC receptors.

Parathyroid hormone-related protein is required for normal intramembranous bone development.

It is well established that parathyroid hormone‐related protein (PTHrP) regulates chondrocytic differentiation and endochondral bone formation. Besides its effect on cartilage, PTHrP and its major receptor (type I PTH/PTHrP receptor) have been found in osteoblasts, suggesting an important role of PTHrP during the process of intramembranous bone formation. To clarify this issue, we examined intramembranous ossification in homozygous PTHrP‐knockout mice histologically. We also analyzed phenotypic markers of osteoblasts and osteoclasts in vitro and in vivo. A well‐organized branching and anastomosing pattern was seen in the wild‐type mice. In contrast, marked disorganization of the branching pattern of bone trabeculae and irregularly aligned osteoblasts were recognized in the mandible and in the bone collar of the femur of neonatal homozygous mutant mice. In situ hybridization showed that most of the osteoblasts along the bone surfaces of the wild‐type mice and some of the irregularly aligned osteoblastic cells in the homozygous mice expressed osteocalcin. Alkaline phosphatase (ALP) activity and expression of osteopontin messenger RNA (mRNA) in primary osteoblastic cells did not show significant differences between cultures derived from the mixture of heterozygous mutant and wild‐type mice (+/? mice) and those from homozygous mutant mice. However, both mRNA and protein levels of osteocalcin in the osteoblastic cells of homozygous mutant mice were lower than those of +/? mice, and exogenous PTHrP treatment corrected this suppression. Immunohistochemical localization of characteristic markers of osteoclasts and ruffled border formation did not differ between genotypes. Cocultures of calvarial osteoblastic cells and spleen cells of homozygous mutant mice generated an equivalent number of tartrate‐resistant acid phosphatase‐positive (TRAP+) mononuclear and multinucleated cells and of pit formation to that of +/? mice, suggesting that osteoclast differentiation is not impaired in the homozygous mutant mice. These results suggest that PTHrP is required not only for the regulation of cartilage formation but also for the normal intramembranous bone development.

Loss of cell-surface receptor EphB2 is important for the growth, migration, and invasiveness of a colon cancer cell line

PurposeIn normal colonic epithelium, the receptor tyrosine kinase, EphB2 interacts with ephrinB1 ligand to maintain the integrity and architecture of the colonic crypt. Loss of EphB2 is seen in most colorectal cancers and correlates with poor prognosis. In this study, we investigated the effects of two levels of EphB2 expression on cell migration and invasion in a colon cancer cell line and on the growth of tumour xenografts.MethodsAn EphB2-negative colon cancer cell line (LIM2405) was transfected with a full-length EphB2 cDNA in a vector designed to respond to the drug tetracycline. The effect of two levels of EphB2 expression on the ability of cells to migrate through a porous barrier in response to a chemo-attractant and to invade through artificial basement membranes was tested in vitro. Finally, the effects of two expression levels of EphB2 on tumour growth using an in vivo model of colonic tumour xenograft in a mouse model were assessed.ResultsExpression of moderate levels of EphB2 significantly reduced the migration of tumour cells compared to control (p < 0.05, Kruskal–Wallis test). Expression of high levels of EphB2 further reduced migration of tumour cells (p < 0.05, Kruskal–Wallis test). Similarly, expression of EphB2 markedly reduces the invasive ability of tumour cells. The in vivo model of tumour growth showed that tumours with the highest level of EphB2 expression had a reduced risk of reaching a 10-mm size (defined event) compared with the control group (Cox regression, hazard ratio (HR) = 0.052, 95% CI 0.005–0.550; p = 0.014). Tumours derived from EphB2 expressing cells had a significantly reduced number of mitotic figures (p < 0.05) and an increased number of apoptotic cells (p < 0.05) compared to tumours from control cells.ConclusionEven a moderate level of EphB2 expression has effects on tumour cells which results in reduced migration and invasiveness and slows the growth of colonic tumour implants in an in vivo model.

Mandibular deformities in parathyroid hormone-related protein (PTHrP) deficient mice: possible involvement of masseter muscle.

Previous studies using parathyroid hormone-related protein (PTHrP) null mutant mice have indicated severe abnormalities in the endochondral ossification, suggesting that PTHrP affects chondrocyte differentiation. In this study, we found in newborn PTHrP-deficient mice some deformities in the mandible that is formed via intramembranous ossification. The mandibular ramus was bent downwards and a prominent bone crest to which the deep layer of masseter muscle was tendinously attached was observed in the mandibular body. Transmission electron microscopic studies showed that active bone formation was progressing along the tendon fibers of the masseter muscle. The examination of 3-D reconstruction models indicated that the mandibular ramus was bent at the site of muscle attachment, which was shifted in the direction of the muscle fibers. Muscle fiber type analysis using myosin ATPase staining showed that the masseter muscle in the newborn PTHrP-deficient mice contained numerous type 2B fibers, demonstrating premature maturation of this muscle. Based on these findings, we speculated that premature maturation of the masseter muscle leads, probably due to increased tensile forces, to accelerated bone crest formation and subsequent bending of the mandibular ramus. These results further suggest that PTHrP is involved in the regulation of muscle development in normal animals.

Biosynthesis of proteoglycan in bone and cartilage of parathyroid hormone-related protein knockout mice

Abstract Proteoglycans are suggested to regulate cell adhesion, differentiation and mineralization of hard tissues. In vitro studies have shown that many humoral and local factors regulate proteoglycan synthesis. Among them, parathyroid hormone (PTH) and parathyroid hormone-related protein (PTHrP) have potent stimulating effects on proteoglycan synthesis. However, the exact role of PTHrP on the biosynthesis and metabolism of proteoglycans during skeletal development is not clear. To clarify this point, we examined bony and cartilaginous explants of newborn mice with disrupted PTHrP alleles. Ribs of homozygous PTHrP-knockout mice and wild-type littermates were dissected into bony and cartilaginous regions and metabolically labeled with [35S]sulfate in culture. Radiolabeled proteoglycans were analyzed by column chromatography. The elution profiles of [35S]-labeled proteoglycan from cartilaginous explants did not differ between homozygous PTHrP-knockout mice and wild-type littermates. However, the amount of labeled proteoglycan in homozygous PTHrP-knockout mice was only 4%–5% that of wild-type littermates. In contrast with cartilaginous explants, the amount of labeled proteoglycans in bony explants did not differ between the two genotypes. Interestingly, besides the common major peak (Kd = 0.10–0.16) observed in the bony explants of both genotypes, a minor peak (Kd = 0.42) was specifically present in homozygous PTHrP-knockout mice. This minor peak was earlier than that of free glycosaminoglycan (GAG) chains, suggesting that the core protein, but not GAG chain, was cleaved in the bony explants of homozygous PTHrP. These findings demonstrate a crucial and nonredundant role of PTHrP in the regulation of proteoglycan synthesis and metabolism during skeletal development.