Analysis and in situ detection of cholecalcin messenger RNA (9000 Mr CaBP) in the uterus of the pregnant rat

Summary The molecular cloning of a cDNA fragment synthesised from rat duodenal mRNA coding for cholecalcin (calbindin), a 9000 Mr vitamin D-induced calcium-binding protein (CaBP), has been previously described. DNA/RNA hybridisation assays have been used to examine CaBP mRNA production in the uterine horns and duodena of pregnant (21 day) rats using the cloned CaBP cDNA. Northern hybridisation studies showed that the ³²P cDNA sequence hybridised to a single 500–600 nucleotide species in both the uterus and the duodenum, thus demonstrating identical CaBP mRNA processing in both tissues. Dot blot hybridisation studies showed that the CaBP mRNA concentration was greatest in the duodenum while that of the uterine horns was about 10% of the duodenal level. The observed differences in CaBP mRNA levels correlate well with the in vivo CaBP concentrations. In situ hybridisation histochemistry using ³H cDNA revealed that CaBP mRNA visualised by silver grains was found in all the parts of the endometrium and the myometrium. However, CaBP mRNA was more concentrated in the outer and inner muscular fibres and in the luminal cells of the endometrium than in the stroma cells. These results demonstrate that the CaBP gene is expressed in specific cells of the rat uterus.     

Putative amino acid sequence of chick calcium-binding protein deduced from a complementary DNA sequence.

Two DNA fragments coding for chick CaBP have been isolated and sequenced. cDNA was prepared from enriched intestinal mRNA and cloned in pUC12. The recombinant clones were screened by differential hybridisation with 32P-cDNA probes synthesized from vitamin D replete and deficient chick intestinal mRNA. Two clones had outstanding affinity with the +D probe. Hybrid-arrested and hybrid-selected translation systems showed that both clones hybridised to mRNA coding for immunoprecipitable CaBP. The mRNA for CaBP has a 100 bp G,C rich sequence before a 786 bp coding region followed by 1250 nucleotides 3' untranslated region. Nucleotides coding for the Ca-binding sites show a high degree of homology for Ca-binding sites in chick calmodulin and rat intestinal CaBP. The amino acid sequence specified by the longest open reading frame contains five Ca-binding sites but is too large for the native CaBP; post-translational modification must therefore occur.     

Biosynthesis of calcium-binding protein of chick embryonic chorioallantoic membrane: In vitro organ culture and cell-free translation

Biosynthesis of the calcium-binding protein (CaBP) of the chick embryonic chorioallantoic membrane (CAM) was studied using organ culture and cell-free translation. The organ culture studies showed: 1) The CaBP is a relatively stable protein ( ); 2) Biosynthesis of the CaBP involves microsomes and includes two posttranslational modifications, glycosylation and γ-glutamyl carboxylation; and 3) During embryonic development, a single species of the CaBP is expressed in the CAM. Cell-free translation of total CAM mRNA, including CaBP mRNA, was achieved in a rabbit reticulocyte lysate system using [³⁵S]Met as a tracer. Based on the properties of the nascent CaBP polypeptide translated in the presence or absence of microsomal membranes, the early stages of CaBP synthesis appear to be: translation of CaBP mRNA on membrane-bound polysomes, insertion and translocation of the nascent polypeptide across microsomal membranes, and co-translational cleavage of a signal sequence.     

Corticosterone regulates calbindin-D28k mRNA and protein levels in rat hippocampus

Corticosterone was administered to normal and bilaterally adrenalectomized rats (250-300 g), and hormonal regulation of brain calbindin-D28k (CaBP28k) levels was investigated by radioimmunoassay for CaBP28k protein and by slot and Northern blot analyses for CaBP28k mRNA. The specificity of the changes observed in CaBP28k mRNA levels was tested by reprobing blots with calmodulin and B-actin cDNAs. Rats were either adrenalectomized, adrenalectomized treated with corticosterone, intact, or intact treated with corticosterone. Chronic corticosterone administration (subcutaneous injection for 7 days, 10 mg/day) to normal intact rats significantly increased levels of CaBP28k immunoreactivity (43%) and mRNA (125%) in the hippocampus. Adrenalectomy (animals were killed 7 days after adrenalectomy) produced a significant decrease in hippocampal CaBP28k immunoreactivity (85%) and mRNA (80%) compared with intact controls. Immunocytochemical analysis of tissue sections inducated a marked depletion of CaBP28k immunoreactivity in the dentate gyrus of the hippocampus 2 weeks after adrenalectomy. When adrenalectomized rats were treated with corticosterone (10 mg/day for 7 days), CaBP28k protein and mRNA levels in hippocampus were restored to levels observed in intact controls. No changes in CaBP28k protein and mRNA in kidney, cerebellum, striatum, or cerebral cortex were noted in adrenalectomized rats or in intact rats treated with corticosterone when compared with controls, indicating the specificity of the effect on CaBP28k for the hippocampus. These studies present the first evidence of a regulator of CaBP28k gene expression in the brain.     

Cloning and analysis of calbindin-D28K cDNA and its expression in the central nervous system

The vitamin D-dependent calcium-binding protein (CaBP), calbindin-D28K (CaBP28K), is present in the central nervous system (CNS), the sensory system, and kidneys of mammals and birds. Recent studies have indicated that several other CaBPs of very similar Mrs are also present in the CNS. This study was carried out to establish the relationship between CaBP28K and other CaBP, particularly spot 35, to provide a basis for further studies on the tissue-specific regulation and distribution of CaBP28K. A cloned pC28 cDNA was isolated from a rat brain expression library using synthetic oligodeoxyribonucleotides (oligos) complementary to rat spot-35 mRNA. This pC28 cDNA had an open reading frame (ORF) of 783 nucleotides (nt) coding for a 261-aa, 30-kDa protein. There was 100% homology between the pC28 sequence and that of the CaBP28K isolated from rat brain cDNA library using a chicken intestinal CaBP28K probe (Hunziker and Schrickel, 1988). Thus the aa and nt sequences of rat CaBP28K and spot 35 are identical. Primer extension studies and Northern analyses show that the major species of CaBP28K mRNA contains a 5'-untranslated region of 132 nt, a coding region of 261 codons and a 3'-untranslated region of 804 nt without the poly(A) tail. The rat CaBP28K probe hybridizes to one major RNA species (1.9 kb) and two minor ones (2.8 and 3.2 kb) in the cerebellum, hippocampus, retina and kidney. This distribution correlates well with the distribution of CaBP28K itself in these organs. Comparison of the genomic organization of the CaBP28K gene with that of other members of the 'EF-hand' CaBP family emphasizes that the CaBP28K gene diverged from the others at the first duplication of the gene encoding one CaBP domain. All the members of the 'EF-hand' gene CaBP family evolved by exon shuffling and specific genomic rearrangements.     

Vitamin-D dependent 9 kDa calcium-binding protein gene: cDNA cloning, mRNA distribution and regulation

Cholecalciferol (calcitriol) the active hormonal form of vitamin D induces the synthesis of at least two intracellular calcium-binding proteins (Ka = 10(6) M-1), the cholecalcins (CaBP) in mammals. We used the synthesis of these proteins to study the genomic steroid-like action of vitamin D. The 9 kDa CaBP is mainly concentrated in the duodenum while 28 kDa CaBP is located in the kidney and cerebellum. Complementary DNA copies of rat intestinal 9 kDa CaBP mRNA were cloned in E. coli. The deduced amino acid sequence for 9 kDa CaBP contains two 'EF hand' domains corresponding to calcium-binding sites I and II. The homology observed suggests, after comparison with the structures of other intracellular CaBPs, that rat 9 kDa CaBP mRNA contains the remains of an untranslated calcium-binding site III-like structure seen in 28 kDa CaBP from kidney and cerebellum of rat. Northern blots showed that the cDNA sequence hybridizes to a homogeneous 500-600 nucleotide mRNA species from rat duodenum. Larger mRNA species encoding 28 kDa CaBP were undetectable in rat kidney and cerebellum even under low stringency conditions. These findings demonstrate that there is no cross-hybridization between 9 kDa and 28 kDa CaBP mRNAs, and Southern analysis indicates that there are distinct genes coding for each rat cholecalcin. The cDNA probe was used to analyze the specific 9 kDa CaBP gene expression along the intestine of growing rats and during gestation and fetal development.(ABSTRACT TRUNCATED AT 250 WORDS)     

In situ detection of vitamin D-induced calcium-binding protein (9-kDa CaBP) messenger RNA in rat duodenum

We have previously described the molecular cloning of a cDNA fragment synthesized from rat duodenal mRNA coding for a 9000-dalton vitamin D-induced calcium-binding protein (9-kDa CaBP) (3). We now report the use of this cloned cDNA to study the cytological distribution of 9-kDa CaBP mRNA in rat duodenum by in situ hybridization. Tissue sections, fixed in ethanol:acetic acid, were hybridized to the 3H-cDNA probe and processed for autoradiography. The specificity of the CaBP mRNA-DNA hybrid formation was checked using 3H-labeled plasmid pBR322 DNA as a control probe. 9k-Da CaBP mRNA, visualized by silver grains, was found only in the absorptive epithelial cells, and the concentration was greater in the cells at the villous tips than in those of the crypts. The 9k-Da CaBP mRNA was observed mainly in the cytoplasm of the columnar cells and less frequently in the nucleus. Labeling was not seen in the brush border and goblet cells. The submucosa, with Brunner's glands and muscularis, also showed no specific 9-kDa CaBP mRNA concentration. This demonstration of 9-kDa CaBP gene activity in the columnar cells of the rat duodenum illustrates the usefulness of in situ hybridization for characterization of specific cells involved in the expression of 1,25(OH)2 D3 activity.     

Alkaline phosphatase conjugated protein A as a sensitive reagent to immunoscreen an expression cDNA plasmid library: isolation of cDNA to the calcium-binding protein of the chick embryonic chorioallantoic membrane

A highly efficient immunoscreening procedure has been developed to isolate cDNA clones to the calcium-binding protein (CaBP) of the chick embryonic chorioallantoic membrane (CAM). A library of total CAM cDNA was constructed using the expression plasmid vector, pUC 19. Bacterial clones containing plasmids with CaBP cDNA inserts were detected immunohistochemically based on their expression of hybrid CaBP protein sequences. For immunodetection, nitrocellulose bacterial colony replicas were treated with specific antibodies to the CaBP followed by incubation with Staphylococcus aureus Protein A conjugated with alkaline phosphatase (AP) which served as a secondary immunoreagent. Positive clones were then histochemically identified based on AP enzyme activity. The identity of the immunopositive clones was further verified by in vitro translation of mRNA selected by hybridization to the cloned cDNA. The AP-based immunoscreening procedure yields stable reaction products with relatively low background, and should find general application for isolating specific cDNA clones from expression cDNA libraries.     

Vitamin D-inducible calcium transport and gene expression in three Caco-2 cell lines

The parental cell line (P) of Caco-2 cells and two clones, BBe and TC7, were studied at 11 days postconfluence to test the facilitated diffusion model of vitamin D-mediated intestinal calcium absorption (CaTx). Nuclear vitamin D receptor (nVDR) and calbindin D(9k) (CaBP) were measured by Western blot; 1,25-hydroxyvitamin D(3) 24-hydroxylase (CYP24), CaBP, plasma membrane Ca-ATPase (PMCA), and Ca transport channel (CaT1) mRNA levels were examined by RT-PCR; and net apical-to-basolateral CaTx was examined after treating cells with vehicle or 10 nM calcitriol for 8 (mRNA levels) or 48 h (protein, CaBP mRNA, CaTx). nVDR level was lowest in BBe (38% P value) and directly related to CYP24 induction (TC7 = P, which were 1.56 times greater than BBe). nVDR was inversely related to the vitamin D-induced levels of CaT1 mRNA, CaBP mRNA, PMCA mRNA, and net CaTx, with the highest induction seen in BBe. Basal CaBP mRNA (86 times greater than P) and protein levels were highest in TC7 cells and were not associated with higher net CaTx, suggesting CaBP may not be rate limiting for CaTx in these cells.     

Vitamin D-dependent calcium-binding protein synthesis by chick kidney and duodenal polysomes

The hormonally active form of vitamin D, 1,25-dihydroxy vitamin D₃, is known to induce in the intestine and kidney of chicks the synthesis of a calcium-binding protein (CaBP). Here we report a correlation between the tissue levels of CaBP and the levels of apparent messenger RNA in total polysomes as determined by the vitamin D and dietary calcium status. Polysomes from pooled duodenal mucosa and kidney were prepared by the Mg²⁺ precipitation method. After translation in a heterologous, rabbit nuclease-treated reticulocyte system, the immunoprecipitated pellet of CaBP was dissolved and the proteins were separated on 10% sodium dodecyl sulfate-polyacrylamide gels. When 13 nmol of D₃ was given to 4-week-old rachitic chicks which were sacrificed 48 h later, it was found that the duodenum had eightfold more apparent mRNA for CaBP in the polysomes than the kidney. This was also reflected in the values of CaBP/mg protein in these tissues (duodenum, 7 μg/mg vs kidney, 0.9 μ/mg). Also, after giving D₃, there was a twofold increase in both apparent mRNA levels in the polysomes and in CaBP levels in the duodena of chicks which were raised on low-calcium diets versus chicks raised on high-calcium diets. While apparent mRNA for CaBP was present in polysomes from rachitic chick kidney, it was not detectable in the duodenum. From these studies it appears that the induction of CaBP by 1,25(OH)₂D₃ in both the intestine and kidney is determined by similar control mechanisms.     

Radioimmunoassay studies of intestinal calcium-binding protein in the pig. I. Identification of intestinal calcium-binding protein in blood and response to a low calcium diet.

We have developed a radioimmunoassay for porcine intestinal calcium-binding protein (CaBP) and have used it to detect CaBP in pig plasma. Plasma CaBP is identical to intestinal CaBP on the basis of immunological activity, molecular size, and molecular charge properties. The plasma CaBP concentration was greater in the portal blood than in mixed venous blood, suggesting that blood CaBP originates in the gut. Two of four 15-week-old littermate pigs were placed on a low calcium diet (0.15% calcium, 0.65% phosphorus) and two on a control diet (0.65% calcium, 0.65% phosphorus). After 2 weeks, the entire small intestine was removed and divided into nine 1.8-m segments. CaBP was assayed in both plasma and intestinal mucosa. When the two pigs on a low calcium diet were compared with two control pigs, there was a general increase in immunoreactive CaBP in both plasma and intestinal mucosa. However, there was no increment in immunoreactive CaBP in the first 1.8-m segment of small intestine. Seventy-one percent of the increment in CaBP occurred distal to the first two segments. The largest fractional low calcium diet effect occurred in the ileum. The mean CaBP concentration for the total small intestine increased by a factor of 1.9. The plasma CaBP concentration increased by a factor of 2.6. In these pigs, plasma CaBP was a more reliable indicator of change in CaBP status than was the measurement in the proximal gut segment which contained the duodenum. The assay of CaBP in blood is convenient and may obviate the sampling errors inherent in intestinal biopsy.     

Immunocytochemical localization of a calcium-binding protein in the rat duodenum

Summary The cellular localization of the vitamin D-dependent calcium-binding protein (CaBP) in the duodenum of rat was studied using indirect immunofluorescence and immunoperoxidase staining methods. Specific positive reaction product, indicative of the presence of CaBP, was exclusively located within the villous part of the duodenal mucosa. Moreover, CaBP was detected mainly within the supranuclear region of the cytoplasm of absorptive cells and also at the level of their basal laminae. CaBP was not demonstrable either in the nuclei or associated with the brush border membrane of absorptive cells. Also, CaBP was neither detectable in goblet cells nor in sub-epithelial layers. When the specific anti-CaBP antiserum was replaced by nonimmune rabbit serum or when it was preabsorbed on a CaBP-Sepharose conjugate, no positive immunostaining was seen. Together with recent biochemical data our observations agree well with the view that CaBP may act as an intracellular buffer by protecting the cell against too high Ca²⁺ concentrations.     

Determination of the membrane topology of the small EF-hand Ca2+-sensing proteins CaBP7 and CaBP8

The CaBPs represent a subfamily of small EF-hand containing calcium (Ca(2+))-sensing proteins related to calmodulin that regulate key ion channels in the mammalian nervous system. In a recent bioinformatic analyses we determined that CaBP7 and CaBP8 form an evolutionarily distinct branch within the CaBPs (also known as the calneurons) a finding that is consistent with earlier observations characterising a putative C-terminal transmembrane (TM) spanning helix in each of these proteins which is essential for their sub-cellular targeting to the Golgi apparatus and constitutive secretory vesicles. The C-terminal position of the predicted TM-helix suggests that CaBP7 and CaBP8 could be processed in a manner analogous to tail-anchored integral membrane proteins which exhibit the ability to insert across membranes post-translationally. In this study we have investigated the topology of CaBP7 and CaBP8 within cellular membranes through a combination of trypsin protection and epitope accessibility analyses. Our results indicate that the TM-helices of CaBP7 and CaBP8 insert fully across membranes such that their extreme C-termini are luminal. The observed type-II membrane topology is consistent with processing of CaBP7 and CaBP8 as true tail-anchored proteins. This targeting mechanism is distinct from any other calmodulin related Ca(2+)-sensor and conceivably underpins unique physiological functions of these proteins.