Hanne H. Rasmussen

Molecular Identification of a Novel Candidate Sorting Receptor Purified from Human Brain by Receptor-associated Protein Affinity Chromatography

Receptor-associated protein (RAP) is an endoplasmic reticulum/Golgi protein involved in the processing of receptors of the low density lipoprotein receptor family. A ∼95-kDa membrane glycoprotein, designated gp95/sortilin, was purified from human brain extracts by RAP affinity chromatography and cloned in a human cDNA library. The gene maps to chromosome 1p and encodes an 833-amino acid type I receptor containing an N-terminal furin cleavage site immediately preceding the N terminus determined in the purified protein. Gp95/sortilin is expressed in several tissues including brain, spinal cord, and testis. Gp95/sortilin is not related to the low density lipoprotein receptor family but shows intriguing homologies to established sorting receptors: a 140-amino acid lumenal segment of sortilin representing a hitherto unrecognized type of extracellular module shows extensive homology to corresponding segments in each of the two lumenal domains of yeast Vps10p, and the extreme C terminus of the cytoplasmic tail of sortilin contains the casein kinase phosphorylation consensus site and an adjacent dileucine sorting motif that mediate assembly protein-1 binding and lysosomal sorting of the mannose-6-phosphate receptors. Expression of a chimeric receptor containing the cytoplasmic tail of gp95/sortilin demonstrates evidence that the tail conveys colocalization with the cation-independent mannose6-phosphate receptor in endosomes and the Golgi compartment.

Human and mouse proteomic databases: novel resources in the protein universe

Proteomics 1 is an emerging area of research of the post‐genomic era that deals with the global analysis of gene expression using a plethora of techniques to resolve (high resolution two‐dimensional polyacrylamide gel electrophoresis, 2D PAGE), identify (peptide sequencing by Edman degradation, mass spectrometry, Western immunoblotting, etc.), quantitate and characterize proteins, as well as to store (comprehensive 2D PAGE databases), communicate and interlink protein and DNA sequence and mapping information from genome projects. Here we review the current status as well as applications of human and mouse proteomic 2D PAGE databases that are being systematically constructed for the global analysis of gene expression in both health and disease (http://biobase.dk/cgi‐bin/celis). Furthermore, we discuss the problems one faces when using powerful proteomic technology to study heterogeneous tissue and tumor biopsies, and emphasize the importance of building comprehensive databases that contain a critical mass of information for both known and novel proteins in normal and disease conditions.

Heterogeneous nuclear ribonucleoproteins H, H', and F are members of a ubiquitously expressed subfamily of related but distinct proteins encoded by genes mapping to different chromosomes.

Molecular cDNA cloning, two-dimensional gel immunoblotting, and amino acid microsequencing identified three sequence-unique and distinct proteins that constitute a subfamily of ubiquitously expressed heterogeneous nuclear ribonucleoproteins corresponding to hnRNPs H, H′, and F. These proteins share epitopes and sequence identity with two other proteins, isoelectric focusing sample spot numbers 2222 (37.6 kDa; pI 6.5) and 2326 (39.5 kDa; pI 6.6), indicating that the subfamily may contain additional members. The identity between hnRNPs H and H′ is 96%, between H and F 78%, and between H′ and F 75%, respectively. The three proteins contain three repeats, which we denote quasi-RRMs (qRRMs) since they have a remote similarity to the RNA recognition motif (RRM). The three qRRMs of hnRNP H, with a few additional NH-terminal amino acids, were constructed by polymerase chain reaction amplification and used for ribohomopolymer binding studies. Each qRRM repeat bound poly(rG), while only the NH-terminal qRRM bound poly(rC) and poly(rU). None of the repeats bound detectable amounts of poly(rA). The expression levels of hnRNPs H and F were differentially regulated in pairs of normal and transformed fibroblasts and keratinocytes. In normal human keratinocytes, the expression level of H was unaffected by treatment with several substances tested including two second messengers and seven cytokines. Likewise the expression level of F was independent of these substances, although it was strikingly down-regulated by long term treatment with 4β-phorbol 12-myristate 13-acetate, indicating that the protein kinase C signaling pathway regulates its expression. No effect of 4β-phorbol 12-myristate 13-acetate was observed on the expression of hnRNP H. The genes coding for hnRNPs H, H′, and F were chromosome-mapped to 5q35.3 (HNRPH1), 6q25.3-q26, and/or Xq22 (HNRPH2) and 10q11.21-q11.22 (HNRPF), respectively.

Short‐term culturing of low‐grade superficial bladder transitional cell carcinomas leads to changes in the expression levels of several proteins involved in key cellular activities

Fresh, superficial transitional cell carcinomas (TCCs) of low‐grade atypia (3 grade I, Ta; 6 grade II, Ta), as well as primary cultures derived from them were labeled with [35S]methionine for 16 h, between 2 and 6 days after inoculation. Whole protein extracts were subjected to IEF (isoelectric focusing) two‐dimensional polyacrylamide gel electrophoresis (2‐D PAGE) followed by autoradiography. Proteins were identified by a combination of proteomic technologies that included microsequencing, mass spectrometry, 2‐D PAGE immunoblotting and comparison with the bladder TCC protein database available on the internet (http://biobase.dk/cgi‐bin/celis). Comparison of the IEF 2‐D gel protein profiles of fresh tumors and their primary cultures showed that the overall expression profiles were strikingly similar, although differing significantly in the levels of several proteins whose rate of synthesis was differentially regulated in at least 85% of the tumor/culture pairs as a result of the short‐term culturing. Most of the proteins affected by culturing were upregulated and among them we identified components of the cytoskeleton (keratin 18, gelsolin and tropomyosin 3), a molecular chaperone (hsp 28), aldose reductase, GST π, metastasin, synuclein, the calreticulin precursor and three polypeptides of unknown identity. Only four major proteins were downregulated, and these included two fatty acid‐binding proteins (FABP:FABP5 and A‐FABP) which are thought to play a role in growth control, the differentiation‐associated keratin 20, and the calcium‐binding protein annexin V. Proteins that were differentially regulated in only some of the cultured tumors included alpha‐enolase, triosphosphate isomerase, members of the 14‐3‐3 family, hnRNPs F and H, PGDH, hsp (heat‐shock protein) 60, BIP, the interleukin‐1 receptor antagonist, the nucleolar protein B23, as well as several proteins of yet unknown identity. The suitability of in vitro bladder tumor culture models to study complex biological phenomena such as malignancy and invasion is discussed.

Crystal structure of tetranectin, a trimeric plasminogen-binding protein with an α-helical coiled coil

Tetranectin is a plasminogen kringle 4‐binding protein. The crystal structure has been determined at 2.8 Å resolution using molecular replacement. Human tetranectin is a homotrimer forming a triple α‐helical coiled coil. Each monomer consists of a carbohydrate recognition domain (CRD) connected to a long α‐helix. Tetranectin has been classified in a distinct group of the C‐type lectin superfamily but has structural similarity to the proteins in the group of collectins. Tetranectin has three intramolecular disulfide bridges. Two of these are conserved in the C‐type lectin superfamily, whereas the third is present only in long‐form CRDs. Tetranectin represents the first structure of a long‐form CRD with intact calcium‐binding sites. In tetranectin, the third disulfide bridge tethers the CRD to the long helix in the coiled coil. The trimerization of tetranectin as well as the fixation of the CRDs relative to the helices in the coiled coil indicate a demand for high specificity in the recognition and binding of ligands.

Human 2-D PAGE databases for proteome analysis in health and disease: http ://biobase.dk/cgi-bin/celis

Human 2‐D PAGE Databases established at the Danish Centre for Human Genome Research are now available on the World Wide Web (http://biobase.dk/cgi‐bin/celis). The databanks, which offer a comprehensive approach to the analysis of the human proteome both in health and disease, contain data on known and unknown proteins recorded in various IEF and NEPHGE 2‐D PAGE reference maps (non‐cultured keratinocytes, non‐cultured transitional cell carcinomas, MRC‐5 fibroblasts and urine). One can display names and information on specific protein spots by clicking on the image of the gel representing the 2‐D gel map in which one is interested. In addition, the database can be searched by protein name, keywords or organelle or cellular component. The entry files contain links to other databases such as Medline, Swiss‐Prot, PIR, PDB, CySPID, OMIM, Methabolic pathways, etc. The on‐line information is updated regularly.

Human cellular protein patterns and their link to genome DNA sequence data: Usefulness of two-dimensional gel electrophoresis and microsequencing

Analysis of cellular protein patterns by computer‐aided 2‐dimensional gel electrophoresis together with recent advances in protein sequence analysis have made possible the establishment of comprehensive 2‐dimensional gel protein databases that may link protein and DNA information and that offer a global approach to the study of the cell. Using the integrated approach offered by 2‐dimensional gel protein databases it is now possible to reveal phenotype specific protein (or proteins), to microsequence them, to search for homology with previously identified proteins, to clone the cDNAs, to assign partial protein sequence to genes for which the full DNA sequence and the chromosome location is known, and to study the regulatory properties and function of groups of proteins that are coordinately expressed in a given biological process. Human 2‐dimensional gel protein databases are becoming increasingly important in view of the concerted effort to map and sequence the entire genome.—Celis, J. E.; Rasmussen, H. H.; Leffers, H.; Madsen, P.; Honoré, B.; Gesser, B.; Dejgaard, K.; Vandekerckhove, J. Human cellular protein patterns and their link to genome DNA sequence data: usefulness of two‐dimensional gel electrophoresis and microsequencing. FASEB J. 5: 2200–2208; 1991.

Molecular cloning of a cDNA encoding human calumenin, expression in Escherichia coli and analysis of its Ca2+-binding activity.

By microsequencing and cDNA cloning we have identified the transformation-sensitive protein No. IEF SSP 9302 as the human homologue of calumenin. The nucleotide sequence predicts a 315 amino acid protein with high identity to murine and rat calumenin. The deduced protein contains a 19 amino acid N-terminal signal sequence, 7 EF-hand domains and, at the C-terminus, a HDEF sequence which has been reported to function as retrieval signal to the ER. The calumenin transcript is ubiquitously expressed in human tissue, at high levels in heart, placenta and skeletal muscle, at lower levels in lung, kidney and pancreas and at very low levels in brain and liver. Calumenin belongs to a family of multiple EF-hand proteins that include the ER localized proteins reticulocalbin and ERC-55 and the Golgi localized Cab45. Since its Ca2+ binding may be important for the function of the protein we have used microdialysis experiments in order to analyse for the affinity and the capacity of recombinant human (rh) calumenin. All 7 EF-hands of the protein are functional and bind Ca2+, each with an affinity of 1.6x103 M-1. The relatively low affinity for the EF-hands may suggest a role for the protein in Ca2+-dependent processes in the ER.

STRUCTURE OF THE C-TYPE LECTIN CARBOHYDRATE RECOGNITION DOMAIN OF HUMAN TETRANECTIN

Tetranectin (TN) is a C-type lectin involved in fibrinolysis, being the only endogenous ligand known to bind specifically to the kringle 4 domain of plasminogen. TN was originally isolated from plasma, but shows a wide tissue distribution. Furthermore, TN has been found in the extracellular matrix of certain human carcinomas, whereas none or little is present in the corresponding normal tissue. The crystal structure of full-length trimeric TN (2.8 A resolution) has recently been published [Nielsen et al. (1997). FEBS Lett. 412, 388-396]. The crystal structure of the carbohydrate recognition domain (CRD) of human TN (TN3) has been determined separately at 2.0 A resolution in order to obtain detailed information on the two calcium binding sites. This information is essential for the elucidation of the specificity of TN towards oligosaccharides. TN3 crystallizes as a dimer, whereas it appears as a monomer in solution. The overall fold of TN3 is similar to other known CRDs. Each monomer is built of two distinct regions, one region consisting of six beta-strands and two alpha-helices, and the other region is composed of four loops harboring two calcium ions. The calcium ion at site 1 forms an eightfold coordinated complex and has Asp116, Glu120, Gly147, Glu150, Asn151, and one water molecule as ligands. The calcium ion at site 2, which is believed to be involved in recognition and binding of oligosaccharides, is sevenfold coordinated with ligands Gln143, Asp145, Glu150, Asp165, and two water molecules. One sulfate ion has been located at the surface of TN3, forming contacts to Glu120, Lys148, Asn106 of a symmetry-related molecule, and to an ethanol molecule.

Protein-Electroblotting and Microsequencing in Establishing Integrated Human Protein Databases

Proteins, which are characteristic for a specific state of differentiation, the transformed phenotype or pathological conditions of human cells and tissues were identified by computer analyzed two-dimensional gel electrophoresis. Sequenceable amounts of protein were collected from multiple gels with a gel-concentration device, enabling the elution and concentration of more than twenty protein spots, suspended in 1 ml of sample buffer. The eluted protein was concentrated in a new gel in a very small spot and then electroblotted onto polybase-coated glass-fiber or polyvinylidene-difluoride membranes and in situ digested. The released peptides were separated by micro-bore or narrow-bore reversed phase HPLC and immediately collected on polyethylenimine-coated glass-fiber discs for sequencing. These variations of previously developed methods allowed us to work at higher sensitivity. The procedure is currently being used to try out a systematic analysis of human proteins recovered from two-dimensional gels.