In situ hybridization reveals temporal and spatial changes in cellular expression of mRNA for a laminin receptor, laminin, and basement membrane (type IV) collagen in the developing kidney.

The appearance of extracellular matrix molecules and their receptors represent key events in the differentiation of cells of the kidney. Steady-state mRNA levels for a laminin receptor, the laminin B1, B2, and A chains, and the alpha 1-chain of collagen IV (alpha 1[IV]), were examined in mouse kidneys at 16 d gestation and birth, when cell differentiation is active, and 1-3 wk after birth when this activity has subsided. Northern analysis revealed that mRNA expression of laminin receptor precedes the alpha 1(IV) and laminin B chains whereas laminin A chain mRNA expression was very low. In situ hybridization reflected this pattern and revealed the cells responsible for expression. At 16 d gestation, laminin receptor mRNA was elevated in cells of newly forming glomeruli and proximal and distal tubules of the nephrogenic zone located in the kidney cortex. These cells also expressed mRNA for alpha 1(IV) and laminin chains. At birth, mRNA expression of receptor and all chains remained high in glomeruli but was reduced in proximal and distal tubules. At 1 wk after birth, expression was located in the medulla over collecting ducts and loops of Henle. Little expression was detectable by 3 wk. These results suggest that cellular expression of steady-state mRNA for laminin receptor, laminin, and collagen IV is temporally linked, with laminin receptor expression proceeding first and thereafter subsiding.

Hepatocyte attachment to laminin is mediated through multiple receptors.

The interaction of hepatocytes with the basement membrane glycoprotein laminin was studied using synthetic peptides derived from laminin sequences. Rat hepatocytes bind to laminin and three different sites within the A and B1 chains of laminin were identified. Active laminin peptides include the PA22-2 peptide (close to the carboxyl end of the long arm in the A chain), the RGD-containing peptide, PA21 (in the short arm of the A chain) and the pentapeptide YIGSR (in the short arm of the B1 chain). PA22-2 was the most potent peptide, whereas the other two peptides had somewhat lower activity. Furthermore, hepatocyte attachment to laminin was inhibited by the three peptides, with PA22-2 being the most active. Various proteins from isolated membranes of cell-surface iodinated hepatocytes bound to a laminin affinity column including three immunologically related binding proteins : Mr = 67,000, 45,000, and 32,000. Several proteins--Mr = 80,000, 55,000, and 38,000-36,000--with a lower affinity for laminin were also identified. Affinity chromatography on peptide columns revealed that the PA22-2 peptide specifically bound the Mr = 80,000, 67,000, 45,000, and 32,000 proteins, the PA21 peptide bound the Mr = 45,000 and 38,000-36,000 proteins and the YIGSR peptide column bound the 38,000-36,000 protein. Antisera to a bacterial fusion protein of the 32-kD laminin-binding protein (LBP-32) reacted strongly with the three laminin-binding proteins, Mr = 67,000, 45,000, and 32,000, showing that they are immunologically related. Immunoperoxidase microscopy studies confirmed that these proteins are present within the plasma membrane of the hepatocyte. The antisera inhibited the adhesion of hepatocytes to hepatocytes to laminin by 30%, supporting the finding that these receptors and others mediate the attachment of hepatocytes to several regions of laminin.

Folding of the presequence of yeast pAPI into an amphipathic helix determines transport of the protein from the cytosol to the vacuole.

To investigate the role of the 17 residues long presequence (p17) in the transport of the precursor of yeast API (pAPI) from the cytosol to the vacuole we have studied the effects of point mutations upon its conformation and on the process of transport. 1H NMR analysis of p17 indicates that in aqueous solution 26% of the molecules have the 4-12 segment folded into an helix. The hydrophobic environment provided by SDS micelles promotes the folding of 54% of the p17 molecules into a 5-16 amphipathic alpha-helix. Both Schiffer-Edmunson helical wheel analysis of segment 4-12 and residue hydrophobic moments calculated considering all possible side-chain orientations between 80 and 120 degrees, indicate the amphipathic character of the helixes assembled in water and detergent. Charge interactions between the dipole pairs N-Glu2Glu3 and C-Lys12Lys13 are essential for helix stability and condition pAPI transport. Substitution of either Pro2Pro3 or Lys2Lys3 for Glu2Glu3, results in moderate destabilization of the helix, decreases protein targeting to the vacuolar membrane and partly inhibits translocation of the protein to the vacuolar lumen. Replacement of either Pro12Pro13 or Glu12Glu13 for Lys12Lys13, causes a major disruption of the helix, decreases protein targeting and blocks completely the translocation of the protein to the vacuolar lumen. Replacement of Gly7 for Ile7, a substitution which is known to destabilize alpha-helixes in peptides and proteins as a result of the peptide bond to the solvent at Gly residues, produces similar effects as the substitutions for the K12K13 pair. The effects of Gly7 on helix stability and protein transport are partly reversed by introduction of Asp residues at positions 2 and 3 and Ala at position 4. Replacements such as Arg2 for Glu2, or Arg6 for Glu6, which change the net and local charges of the presequence without altering its conformation, have no effect on the protein transport. These results provide direct evidence of the involvement of the presequence in the transport of pAPI from the cytosol to the vacuole. They show that folding of the pAPI presequence is conditioned by the physical/chemical properties of the environment and is critical for targeting the protein to the vacuolar membrane and for its translocation to the vacuolar lumen.

Transport of proteins into the various subcompartments of mitochondria.

The import of proteins into mitochondria is an intricate process comprised of multiple steps. The first step involves the sorting of cytosolically synthesized precursor proteins to the mitochondrial surface. There precursor proteins are recognized by specific receptors which deliver them to the general import site present in the outer membrane. The second stage of import involves a series of complex intraorganelle sorting events which results in the delivery of the proteins to one of the four possible submitochondrial destinations, namely the outer and inner membranes, the matrix and intermembrane space. Here in this review, we discuss the current knowledge on these intramitochondrial sorting events. We especially focus on targeting of proteins to the intermembrane space. Sorting to the intermembrane space represents a particularly interesting situation, as at least three separate targeting pathways to this subcompartment are known to exist.

Functional independence of the protein translocation machineries in mitochondrial outer and inner membranes: passage of preproteins through the intermembrane space.

The protein translocation machineries of the outer and inner mitochondrial membranes usually act in concert during translocation of matrix and inner membrane proteins. We considered whether the two machineries can function independently of each other in a sequential reaction. Fusion proteins (pF-CCHL) were constructed which contained dual targeting information, one for the intermembrane space present in cytochrome c heme lyase (CCHL) and the other for the matrix space contained in the signal sequence of the precursor of F1-ATPase beta-subunit (pF1 beta). In the absence of a membrane potential, delta psi, the fusion proteins moved into the intermembrane space using the CCHL pathway. In contrast, in the presence of delta psi they followed the pF1 beta pathway and eventually were translocated into the matrix. The fusion protein pF51-CCHL containing 51 amino acids of pF1 beta, once transported into the intermembrane space in the absence of a membrane potential, could be further chased into the matrix upon re-establishing delta psi. The sequential and independent movement of the fusion protein across the two membranes demonstrates that the translocation machineries act as distinct entities. Our results support a model in which the two translocation machineries can function independently of each other, but generally interact in a dynamic fashion to achieve simultaneous translocation across both membranes. In addition, the results provide information about the targeting sequences within CCHL. The protein does not contain a signal for retention in the intermembrane space; rather, it lacks matrix targeting information, and therefore is unable to undergo delta psi-dependent interaction with the protein translocation apparatus in the inner membrane.

Yeast aminopeptidase I is post-translationally sorted from the cytosol to the vacuole by a mechanism mediated by its bipartite N-terminal extension.

Transport of aminopeptidase I (API) to the vacuole appears to be insensitive to blockage of the secretory pathway. Here we show that the N-terminal extension of the 61 kDa precursor of API (pAPI) is proteolytically processed in two sequential steps. The first step involves proteinase A (PrA) and produces a 55 kDa unstable intermediate (iAPI). The second step involves proteinase B (PrB) and converts iAPI into the 50 kDa stable, mature enzyme (mAPI). Reversion of the cup1 growth phenotype by a pAPI-CUP1 chimera indicates that pAPI is transported to the vacuole by a post-translational mechanism. Deletion of the first 16 amino acids results in accumulation of the truncated protein in the cytosol, indicating that pAPI is actively transported to the vacuole. The chimera pAPI-myc, constructed by fusing a myc tag to the C-terminus of pAPI, was exploited to dissect the mechanism of pAPI transport. Cell fractionation studies show the presence of iAPI-myc and mAPI in a fraction of vacuoles purified by density centrifugation. This and the sequential conversion of pAPI-myc into iAPI-myc and mAPI lacking the myc tag is consistent with insertion of pAPI into the vacuolar membrane through its N-terminal extension. The specific mechanism of API sorting demonstrates a new pathway of protein transport in vacuolar biogenesis.

Identification of a cell surface-binding protein for the core protein of the basement membrane proteoglycan.

We have identified a protein(s) on the surface of hepatocytes that binds to the core protein of the heparan sulfate proteoglycan of basement membranes. These cells attached and spread on substrates prepared from the basement membrane heparan sulfate proteoglycan (HSPG) and its core protein (HSPG-core). Three proteins (Mr = 38,000, 36,000, and 26,000) were found to bind to a HSPG-core affinity column using extracts of iodinated hepatocytes, whereas proteins extracted from isolated membranes contained primarily the larger protein (Mr = 38,000). Similar results were obtained using a solid phase binding technique using labeled HSPG-core. Binding of HSPG-core to the protein (Mr = 38,000) was not altered by the presence of an excess of heparin, heparan sulfate, fibronectin, laminin, or collagen IV but was reduced by unlabeled HSPG-core. Similar studies showed that the binding protein (Mr = 3,0000) was present in extracts from the membranes of Engelbreth-Holm-Swarm tumor cells, Madin-Darby canine kidney cells, COS cells, melanoma cells, and rat kidney epithelial cells but not in fibroblasts. The protein was found in increased amounts in 3T3 cells treated with retinoic acid. These observations suggest that a variety of cells that contact basement membrane contain the proteoglycan-binding protein.

Laminin promotes mast cell attachment.

Tissue mast cells often localize in close proximity to the basement membrane of endothelial cells and increase at sites of inflammation. The reason for this unique tissue distribution is unknown. We report here that both the murine mast cell line PT18 and mouse bone marrow-derived mast cells possess functional receptors for laminin, and exhibit adhesion, spreading and redistribution of histamine-containing granules on a laminin substratum. This adherence is enhanced in the presence of purified IL-3 and can be inhibited by antibodies to laminin and by antibodies to laminin receptors. Northern analysis showed a high level of mRNA for a 32-kDa laminin receptor in PT18 mast cells. Mouse bone marrow-derived cultures initially exhibited a low level of the mRNA expression. However, the expression of the laminin receptor mRNA is induced rapidly within 1 wk of culture with IL-3. Thus, mast cells exhibit functional laminin receptors that may explain the tissue distribution of mast cells and their accumulation at sites of tissue injury.

The prepropeptide of vacuolar aminopeptidase I is necessary and sufficient to target the fluorescent reporter protein GFP to the vacuole of yeast by the Ccvt pathway.

We have studied the capacity of the prepro amino extension of vacuolar protease leucine aminopeptidase I (API) to target the fluorescent reporter protein GFP to the vacuole of yeast. The preproGFP chimera constructed by extending the amino end of GFP with the prepro-part of API is rapidly degraded in both wild-type WCG cells and WCG 11/21a cells deficient in the proteasome. In contrast, the chimera expressed in WCG-PP cells deficient in both proteasome activity and vacuolar proteinase A accumulates in the vacuole, where it remains stable. Replacement of Gly by Ile-7, a substitution that prevents folding of the pre-part into an amphipathic helix and inhibits the targeting of the API precursor to the vacuole, inhibits the targeting of preproGFP to the vacuole. The separated pre- and pro-parts of the API precursor do not target GFP to the vacuole. Targeting of preproGFP to the vacuole is independent of its levels of expression, as the fluorescent protein localizes to the vacuole in cells expressing the protein under the control of both the GAL 1/10 or the API promoter. The preproGFP expressed under both promoters is recovered as monomers from cytosolic cell extracts. PreproGFP expressed under the API promoter is packed into cytoplasmic bodies that penetrate into the vacuolar lumen to release the protein. Altogether our results show that the prepro-part of the API precursor is necessary and sufficient to target the green fluorescent reporter protein to the vacuole.

Two different laminin domains mediate the differentiation of human endothelial cells into capillary-like structures in vitro.

Endothelial cells, both microvascular as well as large vessel, undergo differentiation slowly in culture under most conditions. When endothelial cells are cultured on Matrigel, a solid gel of basement membrane proteins, they rapidly align and form hollow tube-like structures. We show here that tube formation is a multi-step process induced by laminin. An RGD-containing sequence in the A chain of laminin through an integrin receptor on the endothelial cell induces their attachment to the protein while a YIGSR site in the B1 chain induces cell-cell interactions and the resulting tube formation. We also show that the laminin-derived synthetic peptide YIGSR contains sufficient information to induce single endothelial cells to form ring-like structures surrounding a hollow lumen, the basic putative unit in the formation of capillaries.

Cloning, sequencing, and expression of a cDNA encoding rat LIMP II, a novel 74-kDa lysosomal membrane protein related to the surface adhesion protein CD36.

LIMP II is a glycoprotein expressed in the membrane of lysosomes and secretory granules with lysosomal properties. Sequence analysis of a CNBr-cleaved peptide allowed the synthesis of a 47-mer oligonucleotide that was used to screen a rat liver cDNA library in lambda gt11. This resulted in isolation of a 2-kilobase cDNA containing 1,434 bases encoding the entire protein. The deduced amino acid sequence indicates that LIMP II consists of 478 amino acid residues. The segment spanning residues 4-6 to 26 constitute an uncleavable signal peptide. LIMP II possesses a hydrophobic amino acid segment near the carboxyl end, that together with the uncleaved signal peptide may anchor the protein to the membrane through two distant segments. The major portion of the protein resides on the luminal side and displays 11 potential N-glycosylation sites and 5 cysteine residues. Two short cytoplasmic tails, 2-4 and 20-21 amino acids long, correspond to the NH2- and COOH-terminal ends of the protein, respectively. Transfection of COS cells with the cDNA of LIMP II resulted in expression of the protein and its transport to lysosomes. Comparison of the entire sequence to various data bases of known proteins revealed extensive homology between LIMP II and the cell surface protein CD36 involved in cell adhesion. No significant homology was detected with the two families of lysosomal membrane proteins A and B, recently described.

Expression of laminin and its receptor LBP-32 in human and rat hepatoma cells.

Dramatic cellular changes that occur during hepatocarcinogenesis are associated with major alterations in extracellular matrix formation and in the relationships between cells and their microenvironment. We have studied the expression of laminin, the major noncollagenous glycoprotein of basement membrane, and the laminin receptor 32 kD laminin-binding protein in two rat (Faza 967 and HTC) and two human (HepG2 and HBGC2) hepatoma cell lines that express a variety of liver-specific functions. Laminin was found in the rough endoplasmic reticulum of these cells when the indirect immunoperoxidase method and electron microscopic examination were used. Radiolabeled laminin, immunoprecipitated from both media and cell extracts, was resolved by electrophoresis on sodium dodecyl sulfate gel in two major polypeptides that comigrated with the A and B subunits from Engelbreth-Holm-Swarm tumor laminin. Immunoblot analysis showed that the Mr = 400,000 polypeptide did not correspond to the A subunit of laminin. Northern blot analyses demonstrated large amounts of B1 and B2 mRNAs but no A chain mRNA. We conclude that the tumor cells produce the laminin B chains only. In contrast, normal adult hepatocytes from either man or rat lacked laminin mRNAs, whereas in 1-day primary culture, B chain mRNAs became detectable. The steady-state level of 32 kD laminin-binding protein mRNA was 10-fold and threefold higher in rat hepatoma cells than in freshly isolated and 1-day cultured normal rat hepatocytes, respectively. In human hepatocytes, the steady-state levels of 32 kD laminin-binding protein mRNAs varied depending on the donor and never reached the level of the human hepatoma cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential expression of laminin chains and receptor (LBP-32) in fetal and neoplastic hepatocytes compared to normal adult hepatocytes in vivo and in culture.

Laminin deposition is increased in fetal liver and in a variety of liver diseases, including the development of carcinoma. We investigated the role of the hepatocyte in the synthesis of both laminin and its 32- to 67-kd receptor in normal adult, fetal, and diethylnitrosamine-treated rat livers, and in adult rat hepatocyte primary cultures. Laminin was localized by immunoelectron microscopy in the endoplasmic reticulum of hepatocytes in fetal-derived and in 18-month-old diethylnitrosamine-treated rat livers. Steady-state mRNA levels for the three chains of laminin (A, B1, and B2) and the laminin receptor (LBP-32) were examined. Northern-blot analyses showed that hepatocytes at all stages lacked the A-chain mRNA. B1-chain mRNA was undetectable in normal adult hepatocytes, while significant levels of B1-chain mRNA were found in fetal hepatocytes and in adult hepatocyte primary culture. In hepatocytes from diethylnitrosamine-treated rats, B1-chain mRNAs were abundant and were present mainly in nodular formations rather than in the nontumorous areas. B2-chain mRNAs were barely detectable in either normal adult or fetal hepatocytes. In diethylnitrosamine-treated rats, the steady-state B2-chain mRNA level was higher in nodules than in nontumorous areas. In primary culture, B2-chain mRNAs were present as early as 4 hours after adult hepatocyte seeding, and dramatically increased during the following 2 days. Only low levels of laminin-receptor (LBP-32) mRNAs were present in normal adult hepatocytes, whereas the levels were high in the fetal and in the tumor-containing livers. In diethylnitrosamine-treated rats, LBP-32 mRNAs were more abundant in nodular formations rather than in nontumorous areas. In hepatocyte primary culture, the expression of the LBP-32 mRNA dramatically increased during the first 24 hours. These results show that in hepatocytes, expression of laminin chains and its receptor LBP-32 are not coordinated and depends on the maturation of the cells. In addition, they suggest that the expression of B1 and B2 chains in adult hepatocytes is related to changes of the normal phenotype and/or the pericellular environment.