Efficient degradation of gluten by a prolyl endoprotease in a gastrointestinal model: implications for coeliac disease.

BACKGROUND: Coeliac disease is caused by an immune response to gluten. As gluten proteins are proline rich they are resistant to enzymatic digestion in the gastrointestinal tract, a property that probably contributes to the immunogenic nature of gluten. AIMS: This study determined the efficiency of gluten degradation by a post-proline cutting enzyme, Aspergillus niger prolyl endoprotease (AN-PEP), in a dynamic system that closely mimics the human gastrointestinal tract (TIM system). METHODS: Two experiments were performed. In the first, a slice of bread was processed in the TIM system with and without co-administration of AN-PEP. In the second, a standard fast food menu was used. Samples of the digesting meals were taken from the stomach, duodenum, jejunum and ileum compartments at time zero until 4 hours after the start of the experiment. In these samples the levels of immunogenic peptides from gliadins and glutenins were assessed by monoclonal antibody-based competition assays, Western blot analysis and proliferation T-cell assays. RESULTS: AN-PEP accelerated the degradation of gluten in the stomach compartment to such an extent that hardly any gluten reached the duodenum compartment. CONCLUSION: AN-PEP is capable of accelerating the degradation of gluten in a gastrointestinal system that closely mimics in-vivo digestion. This implies that the co-administration of AN-PEP with a gluten-containing meal might eliminate gluten toxicity, thus offering patients the possibility of abandoning (occasionally) their strict gluten-free diet.

The levels of soluble granzyme A and B are elevated in plasma and synovial fluid of patients with rheumatoid arthritis (RA).

Cytotoxic cells possess specialized granules which contain perforin and a group of serine proteinases termed granzymes. Granzyme-positive cells have been identified in synovial fluid and tissue of patients with RA, where they may play an important role as mediators of granule-mediated apoptosis, extracellular proteolysis, and cytokine induction. The aim here was to define further the involvement of cytotoxic cells in RA. Plasma and synovial fluid samples from the knee joint were obtained from 31 RA patients. The disease controls included 20 osteoarthritis (OA) patients and 10 reactive arthritis (ReA) patients. A recently developed capture ELISA was used to detect soluble granzymes A and B in all patients. Compared with OA and ReA disease controls, markedly increased levels of soluble granzymes A and B were detected in both plasma and synovial fluid of RA patients (P < 0.00001). When values for soluble granzymes A and B in plasma and synovial fluid were used simultaneously as independent variables, logistic regression analysis indicated that a diagnosis of RA could be predicted correctly in 84% of the RA patients and a diagnosis of non-RA in 90% of the controls. The markedly elevated levels of soluble granzymes A and B in plasma and synovial fluid of RA patients strongly suggest that cytotoxic cells are active participants in the pathogenesis of RA. Moreover, the results suggest that measurement of granzymes may assist the laboratory evaluation of patients with arthritis. Larger studies in patients with early disease may clarify the role of this test system in differential diagnosis.

Apoptosis induced by granzyme B-glycosaminoglycan complexes: implications for granule-mediated apoptosis in vivo.

Lymphocyte granule-mediated apoptosis occurs by perforin-mediated intracellular delivery of granule-associated serine proteases (granzymes). A granule-associated proteoglycan, namely serglycin, that contains chondroitin 4-sulfate (CS) glycosaminoglycans is present in the granules of cytotoxic cells. Serglycin acts as scaffold for packaging the positively charged granzymes and probably chaperones the proteases secreted extracellularly. To learn how the interaction of granzyme B (GrB) with serglycin might influence the apoptotic potential of this proteases, we have evaluated a model system where desalted CS is combined with isolated human granzyme. CS-GrB complexes were very stable, remaining undissociated in salt concentrations upwards to 500 mM (pH 7.4). On the basis of a capture enzyme immunoassay that accurately detects GrB, equivalent amounts of active free and CS-GrB, delivered by perforin or adenovirus, efficiently induced apoptosis in Jurkat cells and produced a similar time-dependent increase in caspase-3-like activity. CS-GrB processed isolated caspases-3 and -7 less efficiently than free granzyme. However, when added to cytosolic extracts, rates of processing were nearly equivalent for the two forms, suggesting cationic GrB may nonspecifically bind cytosolic proteins, leading to reduce proteolytic activity. Finally, GrB was found to be exocytosed from lymphocyte-activated killer cells as a neutral, high macromolecular weight complex, which possessed apoptotic activity. Collectively, the results indicate that neutral, high m.w. GrB has the capacity to induce cell death and will be useful to study the mechanism of cytotoxic cell-mediated apoptosis in vitro.

Gin invertase of bacteriophage Mu is a dimer in solution, with the domain for dimerization in the N-terminal part of the protein.

The Gin protein of bacteriophage Mu mediates recombination between two inverted repeat sequences. Gin binds as a dimer to each of these recombination sites. We show that Gin is a dimer in solution also, and that the dimerization is probably stabilized by hydrophobic interactions between the subunits. The subunits of the dimer could efficiently be cross-linked with the 4-A cross-linker diepoxybutane. Spontaneous oxidation of Cys(24) and/or Cys(27) also resulted in intersubunit cross-linking. One or both cysteine residues are located at the interface of the Gin dimer, which maps the dimerization domain in the N-terminal part of the protein. Binding of the disulfide-bonded dimers of Gin to a recombination site was strongly reduced, suggesting that the subunits need to reorient in order to form a stable protein-DNA complex. In the protein-DNA complex, however, oxidation of cysteine residues still seems to be possible, indicating that the N-terminal parts of two Gin subunits are also in close proximity when bound to DNA.

Effects of N-terminal deletions of the Escherichia coli protein Fis on growth rate, tRNA(2Ser) expression and cell morphology.

The Escherichia coli Fis protein is known to be involved in a variety of processes, including the activation of stable RNA operons. In this paper we study the ability of a set of N-terminal Fis deletion mutants to stimulate transcription of the tRNA(2Ser) gene. The results indicate that the domain of the Fis protein containing residues 1-26 is not required for transcription activation. The Fis mutants that are still active in transcription stimulation can also complement the reduced growth rates of Fis- cells, suggesting that the same activating domain is involved in this phenomenon. In addition, we show that in fast growing cultures in the absence of an active Fis protein, minicells are formed. These minicells seem to arise from septum formation near the cell poles. Suppression of minicell formation by Fis also does not require the presence of the N-terminal domain of the protein.

Gin mutants that can be suppressed by a Fis-independent mutation.

The Gin invertase of bacteriophage Mu mediates recombination between two inverted gix sites. Recombination requires the presence of a second protein, Fis, which binds to an enhancer sequence. We have isolated 24 different mutants of Gin that are impaired in DNA inversion but proficient in DNA binding. Six of these mutants could be suppressed for inversion by introduction of a second mutation, which when present in the wild-type gin gene causes a Fis-independent phenotype. Only one of the six resulting double mutants shows an inversion efficiency which is comparable to that of the wild-type Gin and which is independent of Fis. The corresponding mutation, M to I at position 108 (M108I), is located in a putative alpha-helical structure, which in the homologous gamma delta resolvase has been implicated in dimerization. The properties of the M108I mutant suggest that in Gin this dimerization helix might also be the target for Fis interaction. The five other mutants that show a restored inversion after introduction of a Fis-independent mutation appear to be completely dependent on Fis for this inversion. The corresponding mutations are located in different domains of the protein. The properties of these mutants in connection with the role of Fis in inversion will be discussed.