Cloning and gene expression of a novel human ribonucleoprotein.

This paper reports on the cloning and characterization of a novel human ribonucleoprotein, RBM8, containing a single RNA binding domain comprising the two RNP-CS and RNP-2 consensus motifs. The protein has 55% identity to a segment of a C. elegans ribonucleoprotein of unknown function. The RBM8 gene shows ubiquitous tissue expression, predominantly as a 0.9 kb transcript. An interesting feature of the RBM8 transcript is an homology of 42% in the 3' untranslated region, in the antisense orientation, to the human gonadotropin-releasing hormone receptor polypeptide. RBM8 maps to human chromosome 14 in the 14q21-q23 region.

Stanniocalcin 2: characterization of the protein and its localization to human pancreatic alpha cells.

Stanniocalcin (STC) is a hormone that was originally identified in fish, where it inhibits calcium uptake by the gills and gut and stimulates phosphate adsorption by the kidney. Recently, two mammalian homologues of stanniocalcin were identified. The first (STC1) shows 61% identity to the fish stanniocalcins and appears to have a function similar to that of the fish stanniocalcins. The second homologue (STC2) is 30-38% identical to the fish stanniocalcins, and is characterized by unique cysteine and histidine motifs that are not found in the other stanniocalcins. We purified both the native hamster and recombinant human STC2 proteins and obtained a partial amino acid sequence of the hamster protein. Both proteins behave as a disulfide bonded homodimer, which undergoes post-translational modification(s). The STC2 gene was localized to human chromosome 5q35. Northern blot analysis revealed that the primary site of human STC2 production is the pancreas, and immunostaining localized the STC2 protein to a subpopulation of cells in the islet. Double immunostaining for STC2 and either insulin or glucagon revealed that STC2 protein is found in the alpha cells, but not the beta cells. We speculate that STC2 may play a role in glucose homeostasis.

The derivation and characterization of stromal cell lines from the bone marrow of p53-/- mice: new insights into osteoblast and adipocyte differentiation.

We have derived a series of clonal cell lines from the bone marrow of p53-/- mice that represent different stages of osteoblast and adipocyte differentiation. All cell lines show indefinite growth potential (>300 population doublings) and have generation times of 12-20 h. These cell lines have been grouped into three categories. The least mature clones are heterogeneous and appear to contain a subpopulation of stem cells, which can spontaneously generate foci that contain either adipocytes or mineralizing osteoblasts. The second category of clones are homogeneous and clearly correspond to mature osteoblasts because they express high levels of the anticipated osteoblastic markers in a stable fashion and cannot differentiate into adipocytes even in the presence of inducers. The clones in the third category are the most unique. Initially they appeared to correspond to mature osteoblasts because they express alkaline phosphatase in a homogeneous manner, secrete type I collagen, show a significant cyclic adenosine monophosphate response to parathyroid hormone, secrete osteocalcin, and mineralize extensively after only 4-7 days. However, in contrast to the mature osteoblasts, these clones can be induced to undergo massive adipocyte differentiation, and this differentiation is accompanied by the complete loss of expression of all osteoblastic markers except alkaline phosphatase. These observations indicate that some cells that have acquired all of the characteristics of mature osteoblasts can be diverted to the adipocyte pathway. Further characterization of these clones may be particularly relevant to osteoporotic conditions where increased adipocyte formation appears to occur at the expense of osteoblast formation.

Functionally different isoforms of the human calcitonin receptor result from alternative splicing of the gene transcript.

Two subtypes of the human calcitonin receptor (hCTR) have been described which differ from one another by the presence or absence of a 16-amino acid insert in the first intracellular loop. Both isoforms were stably expressed in baby hamster kidney cells to compare their ligand binding and second messenger coupling. The binding affinity and the on/off rate of binding for salmon CT were identical for the two receptor isoforms. However, the presence of the insert significantly reduced the ability of the receptor to couple to both adenylate cyclase and phospholipase C. Stimulation of a transient calcium response was only observed with the insert-negative receptor. Similarly, the ED50 for the cAMP response is 100-fold higher for the insert-positive form compared with the insert-negative form of the receptor. However, the maximal cAMP response was equivalent for both receptor isoforms. The rate of internalization of the insert-positive form of the receptor is significantly impaired relative to the insert-negative receptor, which suggests that this process may be dependent on the stimulation of a second messenger pathway. Cloning and characterization of the relevant portion of the hCTR gene revealed that these isoforms are generated by alternative splicing. We also discovered a third isoform of the hCTR, which can be generated by alternative splicing at the same position. The presence of a stop codon in this newly described alternative exon would lead to premature termination of the receptor at the C-terminal end of the first transmembrane domain.

Cloning and characterization of an abundant subtype of the human calcitonin receptor.

We have cloned and characterized a second form of the human calcitonin receptor from T47D cells. It resembles the clone described by Gorn et al. [J. Clin. Invest. 90:1726-1735 (1992)] except that it lacks a 16-amino acid insert in the putative first intracellular loop. The insert-negative receptor appears to be the most abundant form, and it occurs at a relatively constant level in all expressing tissues. In contrast, the insert-positive receptor is found at low levels in most tissues but its expression levels appear to be much more variable. The insert-negative cDNA was stably expressed in baby hamster kidney cells. Like the endogenous T47D receptor, the recombinant receptor has an equally high affinity for salmon and porcine calcitonin but a 3-4-fold lower affinity for human calcitonin. High concentrations of calcitonin gene-related peptide, rat amylin, secretin, or vasoactive intestinal peptide do not significantly compete with calcitonin for binding to the recombinant receptor. Calcitonin stimulates a cAMP response in both T47D and transfected baby hamster kidney cells. Salmon calcitonin is more potent than human calcitonin for T47D cells, but the two are nearly equipotent for the transfectants. Furthermore, the ED50 for the cAMP response in the transfectants is 10-100-fold lower than in T47D cells. Calcitonin stimulates inositol phosphate turnover and elevates internal calcium levels in the transfectants. This response requires non-physiological levels of calcitonin and is directly correlated with the number of receptors. Lastly, by using a human/rodent somatic cell hybrid panel and in situ hybridization, we localized the human calcitonin receptor gene to chromosome 7.

A recombinant human calcitonin receptor functions as an extracellular calcium sensor.

Calcitonin, a peptide hormone active in calcium homeostasis, is used in the treatment of bone loss disorders because it inhibits osteoclast function. A human calcitonin receptor was cloned and expressed in baby hamster kidney cells. Three independent stable transfectants respond to calcitonin via increased intracellular calcium ([Ca2+]i) and cyclic adenosine 3',5'-monophosphate (cAMP). We made the interesting observation that these cells also respond to millimolar increases in extracellular calcium via a rapid and sustained elevation in [Ca2+]i, whereas three calcitonin receptor-negative baby hamster kidney cell lines, two of which express recombinant receptors related to the calcitonin receptor, show no sensitivity to changes in extracellular calcium. The increase of [Ca2+]i in response to both calcitonin and extracellular calcium is a function of the average number of calcitonin receptors per cell. These studies suggest a dual role for the calcitonin receptor as a hormone receptor and an extracellular calcium sensor.