Gastrulation in the sea urchin is accompanied by the accumulation of an endoderm-specific mRNA

Spatial diversification of the endoderm during gastrulation in the sea urchin Lytechinus variegatus was examined with an endoderm-specific cDNA clone. This cDNA clone, LvN1.2, was identified by a differential cDNA screen between the ectoderm and endoderm/mesoderm fractions from prism stage embryos. The LvN 1.2-kb mRNA was first detectable by Northern blots at the mesenchyme blastula stage just prior to gastrulation and then accumulated approximately 15-fold from gastrulation to the pluteus stage. In situ hybridization analysis demonstrated that the mRNA accumulated specifically in endoderm and was restricted to the hindgut-midgut regions. This restricted localization was apparent during gastrulation and predicted the morphological distinction between foregut and midgut eventually seen at prism and pluteus stages. Sequence analysis showed that the 189-amino acid open reading frame represented a novel protein. In vitro translation of synthetically produced LvN1.2 mRNA and Western blot analysis with antibodies to the protein sequence yielded the same 25-kDa polypeptide on SDS-PAGE. The LvN1.2 protein resided within discrete granules of the hindgut and midgut cells. These particles were concentrated to the luminal aspect of the cells, suggesting the LvN1.2 protein participates in the digestive function of this region of the gut.     

Sequence complementarity between the 5'-terminal regions of mRNAs for rat mitochondrial cytochrome P-450c27/25 and a growth hormone-inducible serine protease inhibitor. A possible gene overlap.

Recently we reported that a P-450c27/25 cDNA probe hybridizes to two RNA species of about 1.9 and 2.3-2.4 kilobase pairs (kb) in some rat tissues. To understand the molecular relationship between the two mRNAs, we have isolated and characterized a cDNA for the larger, previously uncharacterized 2.3-kb mRNA species. The 2.3-kb cDNA is identical to the previously reported 1.9-kb P-450c27/25 cDNA excepting a 400-nucleotide-long 5' extension. The terminal 291 nucleotides of this extension exhibit 100% complementarity with the 5'-translated region of the mRNA belonging to a family of growth hormone-inducible serine protease inhibitors (SPI). Northern blot analysis, using strand-specific probes, and S1 nuclease protection revealed the presence of the 2.3-kb mRNA exhibiting the sequence characteristics of the larger cDNA. These results were further confirmed by polymerase chain reaction amplification of reverse transcribed RNA. Expression of the 2.3-kb cDNA in COS cells resulted in the correct mitochondrial targeting of a 52-kDa protein exhibiting the properties of P-450c27/25. Furthermore, both the 1.9- and 2.3-kb mRNAs appear to direct the synthesis of a similarly sized 55-kDa precursor protein in a reticulocyte lysate system. Restriction mapping, polymerase chain reaction amplification and partial sequencing of a 25-kb genomic DNA clone suggest the proximal location of the SPI and the P-450c27/25 protein coding regions in the rat genome on either side of a common overlap region. The results also show that the P-450c27/25 mRNAs are regulated by growth hormone in parallel to the SPI mRNAs. These results collectively suggest that a growth hormone-inducible SPI family mRNA and the P-450c27/25 mRNA are encoded by two closely linked, possibly overlapping genes.     

Cloning of cDNA for newt WT1 and the differential expression during spermatogenesis of the Japanese newt, Cynops pyrrhogaster

To investigate the function of Wilms' tumor 1 (WT1) during spermatogenesis, cDNA for newt WT1 homolog was cloned and the expression of WT1 in newt testes was examined. The cDNA is 2089 bp in length and encodes 426 amino acid (aa) residues. The deduced aa sequence shares 76 and 79% homology with human and Xenopus WT1, respectively. Northern blot analysis shows that WT1 mRNA, 3.2 and 4.5kb in length, are expressed in the testis and kidney. Both WT1 mRNA species are detected in various stages of spermatogenesis, but the 3.2kb mRNA is highly expressed in spermatogonia and mature sperm stages, while the amount of 4.5kb mRNA is almost constant throughout spermatogenesis. In situ hybridization reveals that WT1 mRNA is localized in Sertoli cells. Moreover, immunohistochemical analysis shows that WT1 protein is highly expressed in the nuclei of Sertoli cells in early spermatogonia and mature sperm stages, but not in pericystic cells or germ cells. These results suggest that WT1 is involved in the regulation of gene expression in Sertoli cells, depending on the spermatogenic stage.     

Expression of the mouse histone gene H1t begins at premeiotic stages of spermatogenesis

The gene encoding H1t, a testicular variant of histone H1, is expressed in mammals during spermatogenesis. Northern blot and in situ hybridization has detected H1t mRNA only at the stage of pachytene spermatocytes. We have extended this analysis to more sensitive approaches and demonstrate, by RNase protection and electron-microscopic in situ hybridization, that H1t mRNA is detectable even in spermatogonia. Just a faint H1t band is seen in Western blots of nuclear protein from 9-day-old mice. This indicates that the H1t gene is expressed at premeiotic stages, albeit at a low level. In contrast to H1t mRNA, the H1t protein has not been detected in spermatogonia by electron microscopy after immunogold staining.     

An alternative non-tyrosine protein kinase product of the c-src gene in chicken skeletal muscle.

While the c-src locus is expressed as a 4.0-kilobase (kb) mRNA coding for pp60c-src in various chicken tissues, including embryonic muscle, it is expressed as a novel 3.0-kb mRNA in adult skeletal muscle. We have analyzed the primary structure of this alternatively transcribed and spliced c-src mRNA. The sequence revealed three open reading frames, with the previously defined c-src exons 1 through 5 or 6 comprising the third, on the 3' untranslated region of this 3-kb mRNA. The exons coding for the tyrosine kinase domain of pp60c-src were excluded. On the 5' side, 2 kb of sequence upstream from the previously defined exon 1 of the c-src gene was included in this mRNA. The start site for the 3-kb mRNA probably lies downstream of that for the 4-kb mRNA. The first reading frame of the 3.0-kb mRNA, called sur (for src upstream region), encoded a 24-kilodalton (kDa) protein product rich in cysteine and proline residues. In vitro analysis indicated that the 24-kDa sur protein was membrane associated. Antibodies to sur protein detected in vivo a 24-kDa muscle-specific protein which was developmentally regulated and corresponded to the switch from the 4-kb to the 3-kb c-src mRNA. A striking kinetic pattern of appearance of sur protein and disappearance of pp60c-src suggests that the expression of these two proteins is inversely related.     

Tissue distribution and subcellular localization of the ClC-5 chloride channel in rat intestinal cells

ClC-5 is the Cl- channel that is mutated in Dent's disease, an X-chromosome-linked disease characterized by low molecular weight proteinuria, hypercalciuria, and kidney stones. It is predominantly expressed in endocytically active renal proximal cells. We investigated whether this Cl- channel could also be expressed in intestinal tissues that have endocytotic machinery. ClC-5 mRNA was detected in the rat duodenum, jejunum, ileum, and colon. Western blot analyses revealed the presence of the 83-kDa ClC-5 protein in these tissues. Indirect immunofluorescence studies showed that ClC-5 was mainly concentrated in the cytoplasm above the nuclei of enterocytes and colon cells. ClC-5 partially colocalized with the transcytosed polymeric immunoglobulin receptor but was not detectable together with the brush-border-anchored sucrase isomaltase. A subfractionation of vesicles obtained by differential centrifugation showed that ClC-5 is associated with the vacuolar 70-kDa H+-ATPase and the small GTPases rab4 and rab5a, two markers of early endosomes. Thus these results indicate that ClC-5 is present in the small intestine and colon of rats and suggest that it plays a role in the endocytotic pathways of intestinal cells.     

Detection of a Novel Sepiapterin Reductase mRNA: Assay of mRNA in Various Cells and Tissues of Various Species

Fragments of cDNA coding for rat, murine, and human sepiapterin reductase (SR) were amplified by PCR via primer positioning close to the reported 3′-end of the coding region in the rat enzyme. They were sequenced and used as probes for mRNA detection. Northern blot analysis detected two mRNA species for SR. Their sizes were 1.3 and 2.1 kb for rat, 1.3 and 2.3 kb for mouse, and 1.6 and 2.1 kb for human cell lines. Comparison of rat cell lines and rat tissues indicated that in tissues only the 1.3-kb species is present. Washing of the Northern blots under different stringency conditions indicated a more stable interaction of the 1.3-kb mRNA species with the cDNA probe as compared to the 2.3-kb species. The 1.3-kb species corresponds to the reported 28.2-kDa molecular mass of rat SR monomer. SR mRNA expression is absent in the human NK-like cell line YT and in the murine erythroleukemia subclone B8/3, which both lack SR activity. Moreover, the relative mRNA expression correlates with the enzymatic activities of different cell lines within the same species. This indicates that SR activity is regulated by its steady state mRNA levels.     

Localization during development of alternatively spliced forms of cytotactin mRNA by in situ hybridization

Cytotactin, an extracellular glycoprotein found in neural and nonneural tissues, influences a variety of cellular phenomena, particularly cell adhesion and cell migration. Northern and Western blot analysis and in situ hybridization were used to determine localization of alternatively spliced forms of cytotactin in neural and nonneural tissues using a probe (CT) that detected all forms of cytotactin mRNA, and one (VbVc) that detected two of the differentially spliced repeats homologous to the type III repeats of fibronectin. In the brain, the levels of mRNA and protein increased from E8 through E15 and then gradually decreased until they were barely detectable by P3. Among the three cytotactin mRNAs (7.2, 6.6, and 6.4 kb) detected in the brain, the VbVc probe hybridized only to the 7.2-kb message. In isolated cerebella, the 220-kD polypeptide and 7.2-kb mRNA were the only cytotactin species present at hatching, indicating that the 220-kD polypeptide is encoded by the 7.2-kb message that contains the VbVc alternatively spliced insert. In situ hybridization showed cytotactin mRNA in glia and glial precursors in the ventricular zone throughout the central nervous system. In all regions of the nervous system, cytotactin mRNAs were more transient and more localized than the polypeptides. For example, in the radial glia, cytotactin mRNA was observed in the soma whereas the protein was present externally along the glial fibers. In the telencephalon, cytotactin mRNAs were found in a narrow band at the edge of a larger region in which the protein was wide-spread. Hybridization with the VbVc probe generally overlapped that of the CT probe in the spinal cord and cerebellum, consistent with the results of Northern blot analysis. In contrast, in the outermost tectal layers, differential hybridization was observed with the two probes. In nonneural tissues, hybridization with the CT probe, but not the VbVc probe, was detected in chondroblasts, tendinous tissues, and certain mesenchymal cells in the lung. In contrast, hybridization with both probes was observed in smooth muscle and lung epithelium. Both epithelium and mesenchyme expressed cytotactin mRNA in varying combinations: in the choroid plexus, only epithelial cells expressed cytotactin mRNA; in kidney, only mesenchymal cells; and in the lung, both of these cell types contained cytotactin mRNA. These spatiotemporal changes during development suggest that the synthesis of the various alternatively spliced cytotactin mRNAs is responsive to tissue-specific local signals and prompt a search for functional differences in the various molecular forms of the protein.