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Query: EC:3.4.21.9 (
enterokinase
)
675
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The subcellular localization of
enterokinase
is controversial. In this study,
enterokinase
was extracted from a soluble fraction and a brush border fraction of rat small intestine by differential centrifugation. The soluble fraction contained 41% of the initial
enterokinase
activity while the brush border fraction contained only 4.6% of the initial activity. In contrast, alkaline phosphatase monitored as a brush border marker, yielded 26.3% in the brush border fraction and only 6% in the soluble fraction. Further separation of the soluble fraction on a Sepharose 4B column revealed three peaks of
enterokinase
activity. One small peak (3%) of a bound enzyme (Mr, 2 - 10(6)) and two larger peaks of free enzyme (Mr, 3 - 10(5) and 9 -10). In contrast, alkaline phosphatase major fraction was in a high molecular weight peak of bound enzyme. When the brush border fraction was chromatographed only a single peak of bound
enterokinase
and alkaline phosphatase were found. In the lower part of the small intestine, no brush border-bound
enterokinase
was found, while the peak of alkaline phosphatase was the same as in the upper intestine. These data suggest that
enterokinase
activity in the rat intestine is mainly in a free form localized in the
mucin
and soluble fraction and to a negligible extent in the brush border.
...
PMID:Subcellular localization of enterokinase (enteropeptidase EC 3.4.21.9) in rat small intestine. 87 77
Enteropeptidase is a heterodimeric type II membrane protein of the brush border of duodenal enterocytes. In this location,
enteropeptidase
cleaves and activates trypsinogen, thereby initiating the activation of other intestinal digestive enzymes. Recombinant bovine
enteropeptidase
was sorted directly to the apical surface of polarized Madin-Darby canine kidney cells. Replacement of the cytoplasmic and signal anchor domains with a cleavable signal peptide (mutant proenteropeptidase lacking the amino-terminal signal anchor domain (dSA-BEK)) caused apical secretion. The additional amino-terminal deletion of a
mucin
-like domain (HL-BEK) resulted in secretion both apically and basolaterally. Further deletion of the noncatalytic heavy chain (L-BEK) resulted in apical secretion. Thus
enteropeptidase
appears to have at least three distinct sorting signals as follows: the light chain (L-BEK) directs apical sorting, addition of most of the heavy chain (HL-BEK) inhibits apical sorting, and addition of the
mucin
-like domain (dSA-BEK) restores apical sorting. Inhibition of N-linked glycosylation with tunicamycin or disruption of microtubules with colchicine caused L-BEK to be secreted equally into apical and basolateral compartments, whereas brefeldin A caused basolateral secretion of L-BEK. Full-length BEK was not found in detergent-resistant raft domains of Madin-Darby canine kidney cells or baby hamster kidney cells. These results suggest apical sorting of
enteropeptidase
depends on N-linked glycosylation of the serine protease domain and an amino-terminal segment that includes an O-glycosylated
mucin
-like domain and three potential N-glycosylation sites. In contrast to many apically targeted proteins,
enteropeptidase
does not form detergent-resistant associations with sphingolipid-cholesterol rafts.
...
PMID:Apical sorting of bovine enteropeptidase does not involve detergent-resistant association with sphingolipid-cholesterol rafts. 988 May 38
In a previous study we showed, by transient expression studies in COS-1 cells, that the C-terminal domain of rat intestinal membrane
mucin
Muc3 was cleaved between glycine and serine within a GSIVV (one-letter) amino acid sequence during its residence in the endoplasmic reticulum. The extracellular domain fragment remained linked to the membrane-associated fragment by non-covalent interactions. The present study demonstrates that cleavage depends not only on the presence of the G/SIVV site (where G/S is the glycine downward arrow serine cleavage site), but also on more distant C-terminal sequences in the SEA (sea-urchin sperm protein,
enterokinase
and agrin) module. Inhibition of N-glycosylation by tunicamycin treatment of transfected cells did not prevent re-association of fragments, although cleavage was partially impaired, as some of the non-glycosylated, non-cleaved products were seen to accumulate in cells. Membrane targeting of the Muc3 domain and its cleavage products occurred in transfected cells and was not impaired in mutants in which the cleavage site was mutated. Targeting was also not impaired for products devoid of N-linked oligosaccharides. Our studies thus indicate that (a) cleavage within the SEA module of rat Muc3 requires participation of peptide sequences located C-terminal of and distant from the cleavage site, (b) re-association of the fragments requires the SEA module, but is independent of N-linked oligosaccharides, and (c) membrane targeting of the
mucin
is independent of the SEA-module-cleavage reaction.
...
PMID:SEA (sea-urchin sperm protein, enterokinase and agrin)-module cleavage, association of fragments and membrane targeting of rat intestinal mucin Muc3. 1260 99
We have developed an expression system for the production of large quantities of recombinant MUC1
mucin
in CHO-K1 (Chinese-hamster ovary K1) cells. The extracellular part of human MUC1, including 16 MUC1 tandem repeats, was produced as a fusion protein with murine IgG Fc, with an intervening
enterokinase
cleavage site for the removal of the Fc tail. Stable MUC1-IgG-producing CHO-K1 clones were generated and were found to secrete MUC1-IgG into the culture medium. After adaptation to suspension culture in protein-free medium in a bioreactor, the fusion protein was secreted in large quantities (100 mg/l per day) into the culture supernatant. From there, MUC1 could be purified to homogeneity using a two-step procedure including
enterokinase
cleavage and ion-exchange chromatography. Capillary liquid chromatography MS of released oligosaccharides from CHO-K1-produced MUC1 identified the main O-glycans as Galbeta1-3GalNAc (core 1) and mono- and di-sialylated core 1. The glycans occupied on average 4.3 of the five potential O-glycosylation sites in the tandem repeats, as determined by nano-liquid chromatography MS of partially deglycosylated Clostripain-digested protein. A very similar O-glycan profile and site occupancy was found in MUC1-IgG produced in the breast carcinoma cell line T47D, which has O-glycosylation typical for breast cancer. In contrast, MUC1-IgG produced in another breast cancer cell line, MCF-7, showed a more complex pattern with both core 1- and core 2-based O-glycans. This is the first reported production of large quantities of recombinant MUC1 with a breast cancer-like O-glycosylation that could be used for the immunotherapy of breast cancer.
...
PMID:Recombinant MUC1 mucin with a breast cancer-like O-glycosylation produced in large amounts in Chinese-hamster ovary cells. 1295 Feb 30
The human
mucin
MUC1 is expressed both as a transmembrane heterodimeric protein complex that recycles via the trans-Golgi network (TGN) and as a secreted isoform. To determine whether differences in cellular trafficking might influence the O-glycosylation profiles on these isoforms, we developed a model system consisting of membrane-bound and secretory-recombinant glycosylation probes. Secretory MUC1-S contains only a truncated repeat domain, whereas in MUC1-M constructs this domain is attached to the native transmembrane and cytoplasmic domains of MUC1 either directly (M0) or via an intermitting nonfunctional (M1) or functional sperm protein-
enterokinase
-agrin (SEA) module (M2); the SEA module contains a putative proteolytic cleavage site and is associated with proteins receiving extensive O-glycosylation. We showed that MUC1-M2 simulates endogenous MUC1 by recycling from the cell surface of Chinese hamster ovary (CHO) mutant ldlD14 cells through intracellular compartments where its glycosylation continues. The profiles of O-linked glycans on MUC1-S secreted by epithelial EBNA-293 and MCF-7 breast cancer cells revealed patterns dominated by core 2-based oligosaccharides. In contrast, the respective membrane-shed probes expressed in the same cells showed a complete shift to patterns dominated by sialyl core 1. In conclusion, glycan core profiles reflected the subcellular trafficking pathways of the secretory or membranous probes and the modifying activities of the resident glycosyltransferases.
...
PMID:Transmembrane and secreted MUC1 probes show trafficking-dependent changes in O-glycan core profiles. 1597 91
Polyserase-1 (polyserine protease-1)/TMPRSS9 (transmembrane serine protease 9) is a type II transmembrane serine protease (TTSP) that possesses unique three tandem serine protease domains. However, the physiological function of each protease domain remains poorly understood. We discovered a new splice variant of polyserase-1, termed Serase-1B, which contains 34 extra amino acids consisting a SEA module (a domain found in sea urchin sperm protein,
enterokinase
and agrin) adjacent to the transmembrane domain and the first protease domain with a
mucin
-like box at the C-terminus. The tissue distribution of this enzyme by RT (reverse transcription)-PCR analysis revealed high expression in the liver, small intestine, pancreas, testis and peripheral blood CD14+ and CD8+ cells. To investigate the role of Serase-1B, a full-length form recombinant protein was produced. Interestingly, recombinant Serase-1B was partly secreted as a soluble inactive precursor and it was also activated by trypsin. This activated enzyme selectively cleaved synthetic peptides for trypsin and activated protein C, and it was inhibited by several natural serine protease inhibitors, such as aprotinin, alpha2-antiplasmin and plasminogen activator inhibitor 1. In addition, Serase-1B efficiently converted pro-uPA (urokinase-type plasminogen activator) into active uPA and this activation was strongly inhibited by these natural inhibitors. Furthermore, this activation was also negatively regulated by glycosaminoglycans. Our results indicate that Serase-1B is a novel member of TTSPs that might be involved in uPA/plasmin-mediated proteolysis and possibly implicated in biological events such as fibrinolysis and tumour progression.
...
PMID:Serase-1B, a new splice variant of polyserase-1/TMPRSS9, activates urokinase-type plasminogen activator and the proteolytic activation is negatively regulated by glycosaminoglycans. 1687 79
Post-translational modifications of the extracellular matrix receptor dystroglycan (DG) determine its functional state, and defects in these modifications are linked to muscular dystrophies and cancers. A prominent feature of DG biosynthesis is a precursor cleavage that segregates the ligand-binding and transmembrane domains into the noncovalently attached alpha- and beta-subunits. We investigate here the structural determinants and functional significance of this cleavage. We show that cleavage of DG elicits a conspicuous change in its ligand-binding activity. Mutations that obstruct this cleavage result in increased capacity to bind laminin, in part, due to enhanced glycosylation of alpha-DG. Reconstitution of DG cleavage in a cell-free expression system demonstrates that cleavage takes place in the endoplasmic reticulum, providing a suitable regulatory point for later processing events. Sequence and mutational analyses reveal that the cleavage occurs within a full SEA (sea urchin,
enterokinase
, agrin) module with traits matching those ascribed to autoproteolysis. Thus, cleavage of DG constitutes a control point for the modulation of its ligand-binding properties, with therapeutic implications for muscular dystrophies. We provide a structural model for the cleavage domain that is validated by experimental analysis and discuss this cleavage in the context of
mucin
protein and SEA domain evolution.
...
PMID:SEA domain proteolysis determines the functional composition of dystroglycan. 1790 26
A subclass of SEA (sea urchin sperm protein,
enterokinase
, and agrin) domain proteins undergoes autoproteolysis between glycine and serine in a conserved G(-1)S+1VVV motif to generate stable heterodimers. Autoproteolysis has been suggested to involve only the intramolecular catalytic action of the conserved serine hydroxyl in combination with conformational strain of the glycine-serine peptide bond. We conducted a number of experiments and simulations on the SEA domain from the MUC1
mucin
to test this mechanism. Alanine-scanning mutagenesis of polar residues in the vicinity of the cleavage site demonstrates that only the nucleophile at position +1 is required for efficient proteolysis. Molecular modeling shows that an uncleaved trans peptide is incompatible with the native heterodimeric structure, resulting in disruption of secondary structure elements and distortion of the scissile peptide bond. Insertion of glycine residues (to obtain G(n)G(-1)S+1VVV motifs) appears to relieve strain, and autoproteolysis is 100 times slower in a 1G (n=1) mutant and not measurable in 2G and 4G mutants. Removal of the catalytic serine hydroxyl hampers cleavage considerably, but measurable autoproteolysis of this S1098A mutant still proceeds in the presence of strain alone. The uncleaved SEA precursor populates interconverting partially folded conformations, and autoproteolysis coincides with adoption of proper beta-sheet secondary structure and completed folding. Molecular dynamics simulations of the precursor show that the serine hydroxyl and the preceding glycine carbonyl carbon can be in van der Waals contact at the same time as the scissile peptide bond becomes strained. These observations are all consistent with autoproteolysis accelerated by N-->O acyl shift and conformational strain imposed upon protein folding in a reaction for which the free-energy barrier is decreased by substrate destabilization rather than by transition-state stabilization. The energetics of this coupled folding and autoproteolysis mechanism is accounted for in an accompanying article.
...
PMID:SEA domain autoproteolysis accelerated by conformational strain: mechanistic aspects. 1831 33
In previous works, we showed by transient expression studies in COS-1 cells that the C-terminal domain of rat intestinal membrane
mucin
(rMuc3) that was cloned in the pSecTag2 plasmid (named as p20) is posttranslationally cleaved twice. One location is between the glycine and the serine within a LS1KGS2IV1V2 motif, and the other is in the 49 kDa membrane-tethered fragment at an undefined site. The sea-urchin sperm protein,
enterokinase
and agrin module of rMuc3 is responsible for the cleavage and association of the cleaved fragments. The present study demonstrates how the conservative cleavage motif LS1KGS2IV1V2 contributes to posttranslational processing through mutagenesis of each residue in the LS(1)KGS2IV1V2 motif. Mutation of S2 to alanine (p20s2/a) completely prevented cleavage. While p20k/a (in this construct the K is replaced by A) and p20s1/a (in this construct the S1 is replaced by A) (6 and 3%) showed almost the same result as the wild-type p20 transfectant (4%), 79, 39, 22, 17, and 14% of the products from p20g/a (in this construct the G is replaced by A), p20i/a (in this construct the I is replaced by A), p20l/a (in this construct the L is replaced by A), p20v2/a (in this construct the V2 is replaced by A), and p20v1/a (in this construct the V1 is replaced by A) remained uncleaved. The cleaved N-terminal fragment of the p20s1/a transfectant was 26 kDa, but the N-terminal fragments from p20, p20g/a, p20l/a, p20k/a, p20i/a, p20v1/a, and p20v2/a were 30 kDa. The S1 residue was possibly O-glycosylated, which was supported by deglycosylation with O-cocktail (a mixture of glycosidases). The N-terminal fragment of p20s1/a transfected cells was present at high levels in the spent media. Thus, the S2, G, I, L, V2, and V1 residues within the conserved cleavage motif, LS1KGS2IV1V2, are important for cleavage and contribute to the structural formation and conformational stress of the small loop between the beta2 and the beta3 strands. The S1 residue is possibly O-glycosylated, and mutation of S1 residue to alanine does not affect the cleavage of the LS1KGS2IV1V2 motif, but it is important for the dissociation and further release of the cleaved N-terminal fragment from the cell surface.
...
PMID:Contribution of the conservative cleavage motif to posttranslational processing of the carboxyl terminal domain of rodent Muc3. 1840 57
Dystroglycan (DG) is an extracellular matrix receptor implicated in muscular dystrophies and cancers. DG belongs to the membrane-tethered
mucin
family and is composed of extracellular (alpha-DG) and transmembrane (beta-DG) subunits stably coupled at the cell surface. These two subunits are generated by autoproteolysis of a monomeric precursor within a distinctive protein motif called sea urchin-
enterokinase
-agrin (SEA) domain, yet the purpose of this cleavage and heterodimer creation is uncertain. In this study, we identify a functional nuclear localization signal within beta-DG and show that, in addition to associating with alpha-DG at the cell surface, the full-length and glycosylated beta-DG autonomously traffics to the cytoplasm and nucleoplasm in a process that occurs independent of alpha-DG ligand binding. The trafficking pattern of beta-DG mirrors that of MUC1-C, the transmembrane subunit of the related MUC1 oncoprotein, also a heterodimeric membrane-tethered
mucin
created by SEA autoproteolysis. We show that the transmembrane subunits of both MUC1 and DG transit the secretory pathway prior to nuclear targeting and that their monomeric precursors maintain the capacity for nuclear trafficking. A screen of breast carcinoma cell lines of distinct pathophysiological origins revealed considerable variability in the nuclear partitioning of beta-DG, indicating that nuclear localization of beta-DG is regulated, albeit independent of extracellular ligand binding. These findings point to novel intracellular functions for beta-DG, with possible disease implications. They also reveal an evolutionarily conserved role for SEA autoproteolysis, serving to enable independent functions of
mucin
transmembrane subunits, enacted by a shared and poorly understood pathway of segregated subunit trafficking.
...
PMID:Nuclear translocation of beta-dystroglycan reveals a distinctive trafficking pattern of autoproteolyzed mucins. 1876 29
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