Molecular cloning of the mouse 46-kDa mannose 6-phosphate receptor (MPR 46).

A cDNA clone for the mouse 46-kDa mannose 6-phosphate receptor (MPR 46) was isolated from an embryonic mouse cDNA library. Its single open reading frame codes for a protein of 278 residues. It shows an over-all amino-acid identity of 93% with the human receptor. Nine non-conservative amino-acid exchanges are found in the luminal domain, one non-conservative exchange of hydrophobic amino acids is in the transmembrane domain, while the cytoplasmic receptor tails are identical. All five potential N-glycosylation sites are conserved as well as amino acids that are important for ligand binding (Arg 137 and His 131) and disulfide pairing (Cys 32 and 78, Cys 132 and Cys 167, Cys 145 and Cys 179). The absolute identity in the cytoplasmic MPR 46 tail suggests the importance of this amino-acid sequence for the intracellular routing of the MPR 46.     

Complete exon-intron organization of the human leukocyte common antigen (CD45) gene

Ten genomic DNA clones encoding the human leukocyte common Ag (LCA, CD45) gene were isolated by screening human genomic DNA libraries with LCA cDNA probes. One genomic DNA clone contains the promoter region and the first two exons, as determined by primer extension analyses and S1 nuclease protection studies as well as nucleotide sequence determination. The first exon does not encode a peptide, while the second exon contains the initiation ATG codon and encodes the signal peptide. The other nine genomic DNA clones, which are separated from the first genomic clone by an unknown distance, are connected and span a total of 73 kb. The nine connected genomic clones encode a total of 31 exons. The 33 exons encoded by these 10 genomic clones account for the entire cDNA sequences including the 5' and 3' untranslated sequences. Exon 3 and exons 7 through 15 encode the extracellular domain sequences that are common to all LCA isoforms. Differential usage of exons 4, 5, and 6, generates at least five distinct LCA isoforms. Exon 16 encodes the transmembrane peptide. The cytoplasmic region of the leukocyte common antigens is composed of two homologous domains. Exons 17 through 24 encode the first domain, and exons 25 through 32 encode the second domain. The comparison of these exons indicated that the homologous domains were generated by duplication of several exons. The most 3' exon (exon 33) encodes the carboxy terminus of the LCA molecules and includes the entire 3' untranslated sequence.     

Multiple C-terminal motifs of the 46-kDa mannose 6-phosphate receptor tail contribute to efficient binding of medium chains of AP-2 and AP-3

The interaction of adaptor protein (AP) complexes with signal structures in the cytoplasmic domains of membrane proteins is required for intracellular sorting. Tyrosine- or dileucine-based motifs have been reported to bind to medium chain subunits (mu) of AP-1, AP-2, or AP-3. In the present study, we have examined the interaction of the entire 67-amino acid cytoplasmic domain of the 46-kDa mannose 6-phosphate receptor (MPR46-CT) containing tyrosine- as well as dileucine-based motifs with mu2 and mu3A chains using the yeast two-hybrid system. Both mu2 and mu3A bind specifically to the MPR46-CT. In contrast, mu3A fails to bind to the cytoplasmic domain of the 300-kDa mannose 6-phosphate receptor. Mutational analysis of the MPR46-CT revealed that the tyrosine-based motif and distal sequences rich in acidic amino acid residues are sufficient for effective binding to mu2. However, the dileucine motif was found to be one part of a consecutive complex C-terminal structure comprising tyrosine and dileucine motifs as well as clusters of acidic residues necessary for efficient binding of mu3A. Alanine substitution of 2 or 4 acidic amino acid residues of this cluster reduces the binding to mu3A much more than to mu2. The data suggest that the MPR46 is capable of interacting with different AP complexes using multiple partially overlapping sorting signals, which might depend on posttranslational modifications or subcellular localization of the receptor.     

Mannose 6-phosphate receptor dependent secretion of lysosomal enzymes.

BHK and mouse L cells transfected with the cDNA for the human 46 kd mannose 6-phosphate receptor (MPR 46) secrete excessive amounts of newly synthesized mannose 6-phosphate containing polypeptides. The secretion is dependent on the amount, the recycling and the affinity for ligands of MPR 46. Incubation of transfected cells with antibodies blocking the binding site of MPR 46 reduces the secretion, and cotransfection with the cDNA for the human 300 kd mannose 6-phosphate (MPR 300) restores it to normal values. These results indicate that the two mannose 6-phosphate receptors compete for binding of newly synthesized ligands. In contrast to ligands bound to MPR 300, those bound to the MPR 46 are transported to and released at a site, e.g. early endosomes or plasma membrane, from where they can exit into the medium. Since antibodies blocking the binding site of MPR 46 reduce secretion also in non-transfected BHK and mouse L cells, at least part of the basal secretion of M6P-containing polypeptides is mediated by the endogenous MPR 46.     

Genomic cloning of the gene for an IgE-binding lectin reveals unusual utilization of 5' untranslated regions.

epsilon BP (for epsilon binding protein) is a M(r) 31,000 S-type animal lectin that binds to IgE and has been identified as the homologue of Mac-2, a macrophage cell-surface marker, as well as the lectins RL-29, CBP35, and L-34. The protein is composed of two domains with the amino-terminal portion containing tandem repeats of nine amino acids and the carboxyl-terminal half containing consensus sequences shared by S-type animal lectins. We determined the genomic map in both rat and mouse and isolated overlapping genomic clones that contain the 5' two-thirds of the murine gene. The remaining portion of the gene was obtained by polymerase chain reaction (PCR) amplification of genomic murine DNA followed by subcloning into plasmid vectors. The epsilon BP gene is composed of six exons separated by five introns. The entire amino-terminal repetitive sequence is contained in exon III, and the carboxyl-terminal domain is encoded by the three succeeding exons (IV, V, VI). The latter three exons correspond well in size and share sequence homology with three exons coding for 14-kDa S-type lectins. The sequence in exon I offers an explanation for the generation of two mRNAs differing only in their 5' untranslated sequences, previously reported in Mac-2 cDNA clones. Using cDNA synthesis and PCR amplification, we determined that two alternative splice sites are used in many different types of cells. This alternative splicing results in different 5' untranslated regions of the murine epsilon BP mRNA.     

The two mannose 6-phosphate receptors have almost identical subcellular distributions in U937 monocytes

Using a semiquantitative immunogold technique on ultrathin cryosections, the in situ subcellular distributions of the cation-dependent, 46-kDa mannose 6-phosphate receptor (small MPR) and of the cation-independent, 270-kDa mannose 6-phosphate receptor (large MPR) were for the first time compared. U937 cells were chosen because of their relatively high content of both receptor species. Of each receptor, about 12% occurred at the cell surface, 2% in the Golgi stack, and about 25% in vacuoles resembling endosomal vacuoles. About half of both receptors was found in tubules, presumably belonging to endosomes and trans-Golgi reticulum. It was concluded that the distribution of the small and large MPR were roughly similar. The only exception was formed by electron-dense vesicles occurring in the trans-Golgi region and surrounding endosomes. Dense vesicles contained significantly less small MPR (7%) than large MPR (12%).     

Tandem linkage of human CSF-1 receptor (c-fms) and PDGF receptor genes

A 5' untranslated exon of the human CSF-1 receptor gene (c-fms) is separated by a 26 kb intron from the 32 kb receptor coding sequences. Nucleotide sequence analysis of cloned genomic DNA revealed that the 3' end of the PDGF receptor gene is located less than 0.5 kb upstream from this exon. Similarities in chromosomal localization, organization, and encoded amino acid sequences suggest that the genes encoding the CSF-1 and PDGF receptors arose through duplication. The as yet unidentified c-fms promoter/enhancer sequences may be confined to the nucleotides separating the two genes or could potentially lie within the PDGF receptor gene itself.     

Mr 46,000 mannose 6-phosphate receptor. The role of histidine and arginine residues for binding of ligand.

The chemical modification of histidine and arginine residues results in a loss of binding of the Mr 46,000 mannose 6-phosphate receptor (MPR 46) to a phosphomannan affinity matrix (Stein, M., Meyer, J. E., Hasilik, A., and von Figura, K. (1987) Biol. Chem. Hoppe-Seyler 368, 927-936). Reversal of the modification or presence of mannose 6-phosphate during the modification partially restores or protects the binding activity, indicating that histidine and arginine residues contribute to the mannose 6-phosphate binding site. The 5 histidine and 8 arginine residues within the luminal domain of MPR 46, which contains the ligand binding site, were exchanged by site-directed mutagenesis. Only the conservative replacement of His-131 and Arg-137 by serine and lysine, respectively, results in a loss of binding activity without affecting other properties of the receptor such as the presence of intramolecular disulfide bonds, immunoreactivity, processing of N-linked oligosaccharides, formation of dimers, intracellular distribution, and surface expression. Conservative replacement of other histidine and arginine residues did not affect the binding activity. Nonconservative replacement of several arginine residues reduced binding activity and immunoreactivity, indicating that the loss of a positive charge at these positions alters the folding of MPR 46. We conclude from these results that His-131 and Arg-137 are essential for binding of ligands by MPR 46.     

The genomic organization of the rat AT1 angiotensin receptor.

The AT1 receptor subtype modulates all of the hemodynamic effects of the vasoactive peptide, angiotensin II. In this report, we investigate the genomic organization of this important receptor. A rat genomic library was screened with fragments from the 5' region of a previously cloned cDNA, pCa18b, encoding the rat AT1 receptor. Two lambda clones were isolated and the hybridizing restriction fragments were sequenced. Comparison of the genomic and cDNA sequences reveals that the rat AT1 receptor has three exons. Two of the exons encode 5' untranslated sequence while the third exon encompasses the entire coding region, a small portion of the 5' untranslated region and the entire 3' untranslated sequence. Further analysis of the genomic sequence 5' to the start site of pCa18b demonstrates typical sequence motifs found in many eukaryotic promoters including a TATA box, a cap site and a potential Sp1 binding site. Southern analysis of genomic DNA indicates that the AT1 receptor subtype represented by pCa18b is encoded by one gene within the rat genome.     

The novel Drosophila lysosomal enzyme receptor protein mediates lysosomal sorting in mammalian cells and binds mammalian and Drosophila GGA adaptors

Biogenesis of lysosomes depends in mammalian cells on the specific recognition and targeting of mannose 6-phosphate-containing lysosomal enzymes by two mannose 6-phosphate receptors (MPR46, MPR300), key components of the extensively studied receptor-mediated lysosomal sorting system in complex metazoans. In contrast, the biogenesis of lysosomes is poorly investigated in the less complex metazoan Drosophila melanogaster. We identified the novel type I transmembrane protein lysosomal enzyme receptor protein (LERP) with partial homology to the mammalian MPR300 encoded by Drosophila gene CG31072. LERP contains 5 lumenal repeats that share homology to the 15 lumenal repeats found in all identified MPR300. Four of the repeats display the P-lectin type pattern of conserved cysteine residues. However, the arginine residues identified to be essential for mannose 6-phosphate binding are not conserved. The recombinant LERP protein was expressed in mammalian cells and displayed an intracellular localization pattern similar to the mammalian MPR300. The LERP cytoplasmic domain shows highly conserved interactions with Drosophila and mammalian GGA adaptors known to mediate Golgi-endosome traffic of MPRs and other transmembrane cargo. Moreover, LERP rescues missorting of soluble lysosomal enzymes in MPR-deficient cells, giving strong evidence for a function that is equivalent to the mammalian counterpart. However, unlike the mammalian MPRs, LERP did not bind to the multimeric mannose 6-phosphate ligand phosphomannan. Thus ligand recognition by LERP does not depend on mannose 6-phosphate but may depend on a common feature present in mammalian lysosomal enzymes. Our data establish a potential important role for LERP in biogenesis of Drosophila lysosomes and suggest a GGA function also in the receptor-mediated lysosomal transport system in the fruit fly.     

Serine phosphorylation site of the 46-kDa mannose 6-phosphate receptor is required for transport to the plasma membrane in Madin-Darby canine kidney and mouse fibroblast cells.

Up to 4% of the human 46-kDa mannose 6-phosphate receptor (MPR46) expressed in Madin-Darby canine kidney (MDCK) cells are localized at the cell surface. At steady state, the expression of MPR46 on the apical surface of filter-grown MDCK cells is about sixfold lower than on the basolateral surface. The cytoplasmic domain of the MPR46 is phosphorylated on serine 56 at low stoichiometry. By expressing mutant MPR46 we have shown that the MPR46 phosphorylation site is required for delivery to the plasma membrane. In addition, mutant MPR46 expressed in MPR-deficient mouse embryonic fibroblasts were not detected at the cell surface and their ability to sort newly synthesized cathepsin D was not altered. Since the loss of MPR46 phosphorylation correlates with the lack of cell surface expression, phosphorylation of serine 56 may either function as a direct plasma membrane targeting signal or inhibit MPR46 recycling from endosomes to Golgi, resulting in trafficking to the cell surface.     

Function and properties of chimeric MPR 46-MPR 300 mannose 6-phosphate receptors

The two known mannose 6-phosphate receptors (MPR 46 and MPR 300) mediate the transport of mannose 6-phosphate-containing lysosomal proteins to lysosomes. Endocytosis of extracellular mannose 6-phosphate ligands can only be mediated by MPR 300. Neither type of MPR appears to be sufficient for targetting the full complement of lysosomal enzymes to lysosomes. The complements of lysosomal enzymes transported by either of the two receptors are distinct but largely overlapping. Chimeric receptors were constructed in which the transmembrane and cytoplasmic domains of the two receptors were systematically exchanged. After expression of the chimeric receptors in cells lacking endogenous MPRs the binding of ligands, the subcellular distribution and the sorting efficiency for lysosomal enzymes were analyzed. All chimeras were functional, and their subcellular distribution was similar to that of wild type MPRs. The ability to endocytose lysosomal enzymes was restricted to receptors with the lumenal domain of MPR 300. The efficiency to sort lysosomal enzymes correlated with the lumenal and cytoplasmic domains of MPR 300. In contrast to the wild type receptors, a significant fraction of most of the chimeric receptors was misrouted to lysosomes, indicating that the signals determining the routing of MPRs have been fitted for the parent receptor polypeptides.     

cis-acting sequences involved in exon selection in the chicken beta-tropomyosin gene.

The chicken beta-tropomyosin gene contains an internal pair of mutually exclusive exons (6A and 6B) that are selected in a tissue-specific manner. Exon 6A is incorporated in fibroblasts and smooth muscle cells, whereas exon 6B is skeletal muscle specific. In this study we show that two different regions in the intron between the two mutually exclusive exons are important for this specific selection in nonmuscle cells. Sequences in the 3' end of the intron have a negative effect in the recognition of the 3' splice site, while sequences in the 5' end of the intron have a positive effect in the recognition of the 5' splice site. First, sequences in exon 6B as well as in the intron upstream of exon 6B are both able to inhibit splicing when placed in a heterologous gene. The sequences in the polypyrimidine stretch region contribute to splicing inhibition of exons 5 or 6A to 6B through a mechanism independent of their implication in the previously described secondary structure around exon 6B. Second, we have identified a sequence of 30 nucleotides in the intron just downstream of exon 6A that is essential for the recognition of the 5' splice site of exon 6A. This is so even after introduction of a consensus sequence into the 5' splice site of this exon. Deletion of this sequence blocks splicing of exon 6A to 6B after formation of the presplicing complex. Taken together, these results suggest that both the mutually exclusive behavior and the choice between exons 6A and 6B of the chicken beta-tropomyosin gene are trans regulated.     

Structure and polymorphic map of human lipoprotein lipase gene

Lipoprotein lipase (LPL) catalyzes the key step for the removal of triacylglycerol-rich lipoproteins from the circulation. In this paper, we report the cloning and structure of the normal human LPL gene, which was isolated in three overlapping lambda phage clones that span about 35 kilo bases (kb) of the genetic locus. The peptide coding region of the gene is approx. 23 kb in length and contains nine exons with intron sizes ranging from 0.7 to 8.7 kb. The entire 3' untranslated region is in the tenth exon. Specific sequences in this region support the hypothesis that two mRNA species found for human LPL are generated by differential utilization of polyadenylation signals. The first exon occurs in the 5' untranslated region and the region coding for the signal peptide. The second exon includes the protein domain coding for the N-linked glycosylation site that is required for the expression of enzyme activity. The fourth exon contains the region that was proposed as a lipid binding domain, the sixth for one putative heparin binding domain, and the eighth codes for a domain containing another N-linked glycosylation site. These results suggest that the unique structural and functional domains are confined to specific exons. The PvuII polymorphic site was located within the intron between exon 6 and 7 and the HindIII polymorphic site to the 3' flanking region. The location of these polymorphic sites suggests that the PvuII restriction fragment length polymorphism (RFLP) associated with lipase deficiency in a few Japanese kindred may be a linkage marker for a functional defect of LPL, while the HindIII RFLP associated with hypertriglyceridemia may be important for gene regulation of LPL.     

Exon and intron sequences, respectively, repress and activate splicing of a fibroblast growth factor receptor 2 alternative exon.

Two alternative exons, BEK and K-SAM, code for part of the ligand binding site of fibroblast growth factor receptor 2. Splicing of these exons is mutually exclusive, and the choice between them is made in a tissue-specific manner. We identify here pre-mRNA sequences involved in controlling splicing of the K-SAM exon. The short K-SAM exon sequence 5'-TAGGGCAGGC-3' inhibits splicing of the exon. This inhibition can be overcome by mutating either the exon's 5' or 3' splice site to make it correspond more closely to the relevant consensus sequence. Two separate sequence elements in the intron immediately downstream of the K-SAM exon, one of which is a sequence rich in pyrimidines, are both needed for efficient K-SAM exon splicing. This is no longer the case if either the exon's 5' or 3' splice site is reinforced. Furthermore, if the exon inhibitory sequence is removed, the intron sequences are not required for splicing of the K-SAM exon in a cell line which normally splices this exon. At least three elements are thus involved in controlling splicing of the K-SAM exon: suboptimal 5' and 3' splice sites, an exon inhibitory sequence, and intron activating sequences.