Molecular cloning,expression analysis and chromosome localization of the <Emphasis Type="Italic">Tpt1</Emphasis> gene coding for the pig translationally controlled tumor protein (TCTP)

This work describes the cloning and structural analysis of a Tpt1 cDNA coding for the porcine translationally controlled tumor protein (TCTP) molecule and its expression in porcine cells and tissues. Pig Tpt1 cDNA is 842-pb long that displays typical features of translationally controlled mRNAs, including a 5′-UTR containing a 5′-terminal oligopyrimidine tract (5′-TOP), and a 3′-UTR with a high CG-content and one AU rich element (ARE). Both 5′-UTR and 3′-UTR are highly conserved when they are compared with those of other mammals. The pig Tpt1 cDNA contains a 516-b open reading frame that encodes a predicted TCTP protein composed of 172 amino acids that exhibits extensive conservation compared with TCTP sequences from other species and a common structural feature with all the other TCTP proteins analyzed in mammals. Expression analysis demonstrated that Tpt1 mRNA is ubiquitously expressed in normal porcine tissues and cells, showing a higher expression in spleen, lymph nodes and lung, and a lower one in skin and heart. The pig Tpt1 gene localizes on the porcine chromosome 11, region p11.     

Genomic organization and chromosomal localization of the murine epididymal retinoic acid-binding protein (mE-RABP) gene

The murine epididymal retinoic acid-binding protein (mE-RABP) is specifically synthesized in the mouse mid/distal caput epididymidis and secreted in the lumen. In this report, we have demonstrated by Southern blot analysis of genomic DNA that mE-RABP is encoded by a single-copy gene. A mouse 129/SvJ genomic bacterial artificial chromosome (BAC) library was screened using a cDNA encoding the minor form of mE-RABP. One positive BAC clone was characterized and sequenced to determine the nucleotide sequence of the entire mE-RABP gene. The molecular cloning of the mE-RABP gene completes the characterization of the 20.5-kDa–predicted preprotein leading to the minor and major forms of mE-RABP. Comparison of the DNA sequence of the promoter and coding regions with that of the rat epididymal secretory protein I (ESP I) gene showed that the mE-RABP gene is the orthologue of the ESP I gene that encodes a rat epididymal retinoic acid-binding protein. Several regulatory elements, including a putative androgen receptor binding site, “CACCC-boxes,” NF-1, Oct-1, and SP-1 recognition sites, are conserved in the proximal promoter. Analysis of the nucleotide sequence of the mE-RABP gene revealed the presence of seven exons and showed that the genomic organization is highly related to other genes encoding lipocalins. The mE-RABP gene was mapped by fluorescent in situ hybridization to the [A3-B] region of the murine chromosome 2. Our data, combined with that of others, suggest that the proximal segment of the mouse chromosome 2 may be a rich region for genes encoding lipocalins with a genomic organization highly related to the mE-RABP gene. Mol. Reprod. Dev. 50:387–395, 1998. © 1998 Wiley-Liss, Inc.     

Variation between mouse major urinary protein genes isolated from a single inbred line

We describe ten Charon 4A genomic DNA clones from BALB/c mice which include at least seven different major urinary protein (MUP) genes. We have established the orientation of all seven sequences, and have placed six of them in precise register by means of restriction site maps and Southern blot hybridization with cloned cDNA sequences. Four of the seven genomic sequences (family I sequences) form hybrids with six independent cDNA clones that have a high thermal stability and hybridize more strongly with mRNA from three inbred mouse lines. Hybrids between the remaining three genomic sequences and the cDNA clones have a lower thermal stability and hybridize less strongly with mRNA from the three inbred lines. Homologies between different cloned sequences extend over as much as 15 kb. No clone contains parts of two MUP genes, and no homology has been detected between the 3' flanking region of one MUP gene and the 5' flanking region of another.     

GP2/THP gene family of self-binding, GPI-anchored proteins forms a cluster at chromosome 7F1 region in mouse genome

We investigated the genomic organization of pancreatic zymogen granule membrane-associated protein GP2, a GPI-anchored protein exhibiting self-aggregation at acidic pH, in order to construct a gene-knockout mouse. Cloning and analysis of lambda clones encoding GP2 from 129 Svj mouse genomic DNA libraries showed that the GP2 gene spans about 16.8 kb and includes 11 exons. Identifiable functional domains including a signal sequence, an EGF-like motif, a putative condensing ZP domain, a GPI-anchor attachment site, and a transmembrane sequence for GPI anchoring are encoded in separate exons. Using FISH, the GP2 gene was mapped to mouse chromosome 7F1 near the gene for THP, a GP2 homolog expressed in the cells of thick ascending loop of Henle (TALH) in the kidney. Further analysis of the mouse genome revealed that the THP and GP2 genes are adjacent to one another and are separated by only 3.5 kb in the 7F1 locus. Additionally, the overall structure of the THP gene, 16.2kb with 11 exons, was strikingly similar to that of GP2. This finding suggests that the GP2 and THP genes were generated by gene duplication and evolved separately to acquire regulatory elements leading to tissue-specific expression. Comparative analysis revealed that the 5' flanking region of the THP gene is similar to the first intron of NKCC2, a TALH cell-specific ion-transporter gene. The promoter region of the GP2 gene shares cis-elements found in other pancreas-specific genes. Using this genetic information, a GP2 null mutation was successfully introduced into an ES cell line, and an animal model was established without disruption of THP expression.     

Translationally controlled tumor protein interacts with nucleophosmin during mitosis in ES cells

Somatic cell nuclear transfers and the generation of induced pluripotent stem cells provide potential routes towards non-immunogenic cell replacement therapies. Translationally controlled tumor protein (Tpt1) was recently suggested to regulate cellular pluripotency. Here we explore functions of Tpt1 in mouse embryonic stem (ES) cells. We find that Tpt1 is present in the nucleus and cytoplasm of ES cells, and that specifically nuclear Tpt1 decreases upon cell differentiation. We also find that endogenous Tpt1 forms a complex with endogenous nucleophosmin/nucleoplasmin family member 1 (Npm1) in a cell cycle dependent manner. The Tpt1-Npm1 complex peaks sharply during mitosis and is independent of phosphorylation by Polo-like kinase. Differentiation by retinoic acid decreases Tpt1-Npm1 complex levels. Moreover, Tpt1 knock-down or over-expression reduces proliferation whereas Npm1 over-expression increases proliferation in ES cells. Cells depleted for both Tpt1 and Npm1 exhibit significantly reduced proliferation compared to cells depleted for Tpt1 alone, whereas cells over-expressing both Tpt1 and Npm1 show normal proliferation. Our findings reveal a role for the Tpt1-Npm1 complex in cell proliferation and identify the Tpt1-Npm1 complex as a potential biomarker for mitotic ES cells.     

Substrate recognition by a yeast 2'-phosphotransferase involved in tRNA splicing and by its Escherichia coli homolog.

The final step of tRNA splicing in Saccharomyces cerevisiae requires 2'-phosphotransferase (Tpt1) to transfer the 2'-phosphate from ligated tRNA to NAD, producing mature tRNA and ADP ribose-1' '-2' '-cyclic phosphate. To address how Tpt1 protein recognizes substrate RNAs, we measured the steady-state kinetic parameters of Tpt1 protein with 2'-phosphorylated ligated tRNA and a variety of related substrates. Tpt1 protein has a high apparent affinity for ligated tRNA (K(m,RNA), 0.35 nM) and a low turnover rate (k(cat), 0.3 min(-1)). Tpt1 protein recognizes both tRNA and the internal 2'-phosphate of RNAs. Steady-state kinetic analysis reveals that as RNAs lose structure and length, K(m,RNA) and k(cat) both increase commensurately. For a 2'-phosphorylated octadecamer derived from the anticodon stem-loop of ligated tRNA, K(m,RNA) and k(cat) are 5- and 8-fold higher, respectively, than for ligated tRNA, whereas for a simple substrate like pApA(p)pA, K(m,RNA) and k(cat) are 430- and 150-fold higher, respectively. Tpt1 is not detectably active on a trimer with a terminal 5'- or 3'-phosphate and is very inefficient at removal of a terminal 2'-phosphate unless there is an adjacent 3'-phosphate or phosphodiester. The K(m,NAD) for Tpt1 is substrate dependent: K(m,NAD) is 10 microM with ligated tRNA, 200 microM with pApA(p)pA, and 600 microM with pApApA(p). Preliminary analysis of KptA, a functional Tpt1 protein homologue from Escherichia coli, reveals that KptA protein is strikingly similar to yeast Tpt1 in its kinetic parameters, although E. coli is not known to have a 2'-phosphorylated RNA substrate.