Screen for ISG15-crossreactive Deubiquitinases

Background: The family of ubiquitin-like molecules (UbLs) comprises several members, each of which has sequence, structural, or functional similarity to ubiquitin. ISG15 is a homolog of ubiquitin in vertebrates and is strongly upregulated following induction by type I interferon. ISG15 can be covalently attached to proteins, analogous to ubiquitination and with actual support of ubiquitin conjugating factors. Specific proteases are able to reverse modification with ubiquitin or UbLs by hydrolyzing the covalent bond between their C-termini and substrate proteins. The tail regions of ubiquitin and ISG15 are identical and we therefore hypothesized that promiscuous deubiquitinating proteases (DUBs) might exist, capable of recognizing both ubiquitin and ISG15. Results: We have cloned and expressed 22 human DUBs, representing the major clades of the USP protease family. Utilizing suicide inhibitors based on ubiquitin and ISG15, we have identified USP2, USP5 (IsoT1), USP13 (IsoT3), and USP14 as ISG15-reactive proteases, in addition to the bona fide ISG15-specific protease USP18 (UBP43). USP14 is a proteasome-associated DUB, and its ISG15 isopeptidase activity increases when complexed with the proteasome. Conclusions: By evolutionary standards, ISG15 is a newcomer among the UbLs and it apparently not only utilizes the conjugating but also the deconjugating machinery of its more established relative ubiquitin. Functional overlap between these two posttranslational modifiers might therefore be more extensive than previously appreciated and explain the rather innocuous phenotype of ISG15 null mice

Screen for ISG15-crossreactive deubiquitinases

Background. The family of ubiquitin-like molecules (UbLs) comprises several members, each of which has sequence, structural, or functional similarity to ubiquitin. ISG15 is a homolog of ubiquitin in vertebrates and is strongly upregulated following induction by type I interferon. ISG15 can be covalently attached to proteins, analogous to ubiquitination and with actual support of ubiquitin conjugating factors. Specific proteases are able to reverse modification with ubiquitin or UbLs by hydrolyzing the covalent bond between their C-termini and substrate proteins. The tail regions of ubiquitin and ISG15 are identical and we therefore hypothesized that promiscuous deubiquitinating proteases (DUBs) might exist, capable of recognizing both ubiquitin and ISG15. Results. We have cloned and expressed 22 human DUBs, representing the major clades of the USP protease family. Utilizing suicide inhibitors based on ubiquitin and ISG15, we have identified USP2, USP5 (IsoT1), USP13 (IsoT3), and USP14 as ISG15-reactive proteases, in addition to the bona fide ISG15-specific protease USP18 (UBP43). USP14 is a proteasome-associated DUB, and its ISG15 isopeptidase activity increases when complexed with the proteasome. Conclusions. By evolutionary standards, ISG15 is a newcomer among the UbLs and it apparently not only utilizes the conjugating but also the deconjugating machinery of its more established relative ubiquitin. Functional overlap between these two posttranslational modifiers might therefore be more extensive than previously appreciated and explain the rather innocuous phenotype of ISG15 null mice. Citation: Catic A, Fiebiger E, Korbel GA, Blom D, Galardy PJ, et al (2007) Screen for ISG15-crossreactive Deubiquitinases. PLoS ONE 2(7): e679

A role for N-glycanase in the cytosolic turnover of glycoproteins

Successful maturation determines the intracellular fate of secretory and membrane proteins in the endoplasmic reticulum (ER). Failure of proteins to fold or assemble properly can lead to their retention in the ER and redirects them to the cytosol for degradation by the proteasome. Proteasome inhibitors can yield deglycosylated cytoplasmic intermediates that are the result of an N-glycanase activity, believed to act prior to destruction of these substrates by the proteasome. A gene encoding a yeast peptide:N-glycanase, PNG1, has been cloned, but this N-glycanase and its mammalian homolog were reported to be incapable of deglycosylating full-length glycoproteins. We show that both the yeast PNG1 enzyme and its mammalian homolog display N-glycanase activity towards intact glycoproteins. As substrates, cytosolic PNGase activity prefers proteins containing high-mannose over those bearing complex type oligosaccharides. Importantly, PNG1 discriminates between non-native and folded glycoproteins, consistent with a role for N-glycanase in cytoplasmic turnover of glycoproteins

A glycosylated type I membrane protein becomes cytosolic when peptide: N-glycanase is compromised

The human cytomegalovirus-encoded glycoprotein US2 catalyzes proteasomal degradation of Class I major histocompatibility complex (MHC) heavy chains (HCs) through dislocation of the latter from the endoplasmic reticulum (ER) to the cytosol. During this process, the Class I MHC HCs are deglycosylated by an N-glycanase-type activity. siRNA molecules designed to inhibit the expression of the light chain, β(2)-microglobulin, block the dislocation of Class I MHC molecules, which implies that US2-dependent dislocation utilizes correctly folded Class I MHC molecules as a substrate. Here we demonstrate it is peptide: N-glycanase (PNGase or PNG1) that deglycosylates dislocated Class I MHC HCs. Reduction of PNGase activity by siRNA expression in US2-expressing cells inhibits deglycosylation of Class I MHC HC molecules. In PNGase siRNA-treated cells, glycosylated HCs appear in the cytosol, providing the first evidence for the presence of an intact N-linked type I membrane glycoprotein in the cytosol. N-glycanase activity is therefore not required for dislocation of glycosylated Class I MHC molecules from the ER

Intraoperative stenting of pulmonary arteries

OBJECTIVE: The surgical treatment of pulmonary artery stenoses in small children with complex cardiac lesions can be technically difficult. A hybrid-approach combining corrective surgery and intraoperative stent placement may be complementary in these patients. METHODS: Descriptive study in 11 small children (age: one week to 12 years, median of 12 months, weight: 2.5-20 kg) after previous cardiac surgery. Intraoperative stenting of pulmonary arteries was performed involving paediatric cardiologist and cardiac surgeon. Stenting was combined with repair of pulmonary atresia (n=2), right ventricular outflow and pulmonary artery reconstruction (n=3), unifocalisation of pulmonary arteries (n=1), revision of distal anastomosis of RV-PA-conduit after truncus repair (n=1), revision of distal anastomosis of RV-PA-conduit after AVSD/Fallot repair (n=1), aortic arch patch reconstruction after anatomical correction for transposition of the great arteries (n=1), bidirectional cavopulmonary anastomosis after Norwood I operation for hypoplastic left heart syndrome, (n=1) retrieval of a dislodged stent from the left pulmonary artery (n=1). In seven patients stenting was planned electively while in four patients it took place on an emergency base. RESULTS: No complications occurred during stent implantation. One patient died three weeks postoperatively from diffuse bleeding due to a coagulation disorder. Ten patients left hospital after the surgical intervention with concomitant stent implantation. Stent re-dilatation was necessary in 4 patients 2-24 months postoperatively. After a median follow-up of 15 months ranging from 3 weeks to 7.5 years all stents were patent as diagnosed by angiography in 6 patients and by colour-Doppler in all other patients. One year after stent placement one stent was removed and another surgically opened during re-operation for conduit replacement in the smallest patient from this series. There was one late death during operative right ventricular outflow-tract reconstruction after initial stent placement. CONCLUSIONS: With intraoperative stent placement surgically difficult patch augmentation of small and fragile pulmonary vessels during repair of complex cardiac lesions can be avoided. Stents recruit pulmonary vessels and keep them open and amenable to future percutaneous or surgical intervention

Major coronary anomalies in childhood.

Major coronary artery anomalies are extremely rare in childhood. We wanted to assess the historical and diagnostic features and the therapeutic options of three distinct types of coronary artery anomalies: abnormal origin of the left coronary artery from the pulmonary artery (ALCAPA), coronary fistula and coronary stenosis. In a retrospective study, 33 children with these types of coronary artery disease were identified, 15 with ALCAPA, 12 with fistula and six with coronary stenosis. History, physical examination, ECG, X-ray, echocardiography, angiography, therapy and outcome were reviewed. ALCAPA showed distinct typical echocardiographic characteristics. Coronary artery fistula could be identified by a typical murmur and echocardiographic evidence of coronary dilatations. Coronary stenosis should be suspected by the clinical picture in a specific context. CONCLUSION: rare coronary artery anomalies can be accurately diagnosed in childhood. Timely therapy yields good prognosi

Screen for ISG15-crossreactive deubiquitinases.

The family of ubiquitin-like molecules (UbLs) comprises several members, each of which has sequence, structural, or functional similarity to ubiquitin. ISG15 is a homolog of ubiquitin in vertebrates and is strongly upregulated following induction by type I interferon. ISG15 can be covalently attached to proteins, analogous to ubiquitination and with actual support of ubiquitin conjugating factors. Specific proteases are able to reverse modification with ubiquitin or UbLs by hydrolyzing the covalent bond between their C-termini and substrate proteins. The tail regions of ubiquitin and ISG15 are identical and we therefore hypothesized that promiscuous deubiquitinating proteases (DUBs) might exist, capable of recognizing both ubiquitin and ISG15.We have cloned and expressed 22 human DUBs, representing the major clades of the USP protease family. Utilizing suicide inhibitors based on ubiquitin and ISG15, we have identified USP2, USP5 (IsoT1), USP13 (IsoT3), and USP14 as ISG15-reactive proteases, in addition to the bona fide ISG15-specific protease USP18 (UBP43). USP14 is a proteasome-associated DUB, and its ISG15 isopeptidase activity increases when complexed with the proteasome.By evolutionary standards, ISG15 is a newcomer among the UbLs and it apparently not only utilizes the conjugating but also the deconjugating machinery of its more established relative ubiquitin. Functional overlap between these two posttranslational modifiers might therefore be more extensive than previously appreciated and explain the rather innocuous phenotype of ISG15 null mice

Cloning and characterization of two guide RNA-binding proteins from mitochondria of Crithidia fasciculata: gBP27, a novel protein, and gBP29, the orthologue of Trypanosoma brucei gBP21

In kinetoplastid protozoa, mitochondrial (mt) mRNAs are post-transcriptionally edited by insertion and deletion of uridylate residues, the information being provided by guide (g)RNAs. Currently popular mechanisms for the editing process envisage a series of consecutive ‘cut-and-paste’ reactions, carried out by a complex RNP machinery. Here we report on the purification, cloning and functional analysis of two gRNA-binding proteins of 28.8 (gBP29) and 26.8 kDa (gBP27) from mitochondria of the insect trypanosome Crithidia fasciculata. gBP29 and gBP27 proved to be similar, Arg + Ala-rich proteins, with pI values of ∼10.0. gBP27 has no homology to known proteins, but gBP29 is the C.fasciculata orthologue of gBP21 from Trypanosoma brucei, a gRNA-binding protein that associates with active RNA editing complexes. As measured in UV cross-linking assays, His-tagged recombinant gBP29 and gBP27 bind to radiolabelled poly(U) and synthetic gRNAs, while competition experiments suggest a role for the gRNA 3′-(U)-tail in binding to these proteins. Immunoprecipitates of mt extracts generated with antibodies against gBP29 also contained gBP27 and vice versa. The immunoprecipitates further harbored a large proportion of the cellular content of four different gRNAs and of edited and pre-edited NADH dehydrogenase subunit 7 mRNAs, but only small amounts of mt rRNAs. In addition, the bulk of gBP29 and gBP27 co-eluted with gRNAs from gel filtration columns in the high molecular weight range. Together, these results suggest that the proteins are part of a large macromolecular complex(es). We infer that gBP29 and gBP27 are components of the C.fasciculata editing machinery that may interact with gRNAs