血液因素对龈下菌斑BANA试验结果的影响

目的检测血液因素对慢性牙周炎龈下菌斑BANA试验敏感性、稳定性的影响。方法将不同血液成分及混有健康人血的牙龈卟咻菌菌液分别进行BANA试验。结果各检测稀释滴度的全血、冻融全血、血浆样本BANA试验反应均为阴性;当全血各稀释梯度中牙龈卟啉菌菌量大于10^5时反映结果呈现为BANA试验阳性,胰蛋白酶样酶A600nm值均大于0．20。结论BANA试验的敏感度并不受血液成分混入的影响而降低,证实试验具有较好的稳定性。     

Role of host cellular proteases in the pathogenesis of influenza and influenza-induced multiple organ failure

Influenza A virus (IAV) is one of the most common infectious pathogens in humans. Since the IVA genome does not have the processing protease for the viral hemagglutinin (HA) envelope glycoprotein precursors, entry of this virus into cells and infectious organ tropism of IAV are primarily determined by host cellular trypsin-type HA processing proteases. Several secretion-type HA processing proteases for seasonal IAV in the airway, and ubiquitously expressed furin and pro-protein convertases for highly pathogenic avian influenza (HPAI) virus, have been reported. Recently, other HA-processing proteases for seasonal IAV and HPAI have been identified in the membrane fraction. These proteases proteolytically activate viral multiplication at the time of viral entry and budding. In addition to the role of host cellular proteases in IAV pathogenicity, IAV infection results in marked upregulation of cellular trypsins and matrix metalloproteinase-9 in various organs and cells, particularly endothelial cells, through induced pro-inflammatory cytokines. These host cellular factors interact with each other as the influenza virus-cytokine-protease cycle, which is the major mechanism that induces vascular hyperpermeability and multiorgan failure in severe influenza. This mini-review discusses the roles of cellular proteases in the pathogenesis of IAV and highlights the molecular mechanisms of upregulation of trypsins as effective targets for the control of IAV infection. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.     

Mosaic down syndrome with a marker: molecular cytogenetic characterization of the marker chromosome

Down syndrome is a complex disorder characterized by well defined and distinctive phenotypic features. Approximately 2-3% of all live-born Down individuals are mosaics. Here we report a boy with suspected Down syndrome showing mosaicism for two different cell lines where one cell line is unexpected. The cytogenetic analysis by G-banding revealed a karyotype of 47 XY+21 [20]/46,X+marker [30]. Further, molecular cytogenetic analysis with spectral karyotyping identified the marker as a derivative of Y chromosome. The delineation of Y chromosomal DNA was done by quantitative real-time PCR and aneuploidy detection by quantitative fluorescence PCR. The Y-short tandem repeats typing was performed to estimate the variation in quantity as well as to find out the extent of deletion on Y chromosome using STR markers. Fluorescence in situ hybridization using Y centromeric probe was also performed to confirm the origin of the Y marker. Further fine mapping of the marker was carried out with three bacterial artificial chromosome clones RP11-20H21, RP11-375P13, RP11-71M14, which defined the hypothetical position of the deletion. In our study we defined the extent of deletion of the marker chromosome and also discussed it in relation with mosaicism. This is the first report of mosaic Down syndrome combined with a second de novo mosaic marker derived from the Y chromosome.     

Analysis of the interactions between Eudragit® L100 and porcine pancreatic trypsin by calorimetric techniques

Flexible-chain polymers with charge (polyelectrolytes) can interact with globular proteins with a net charge opposite to the charge of the polymers forming insoluble complexes polymer-protein. In this work, the interaction between the basic protein trypsin and the anionic polyelectrolyte Eudragit^® L100 was studied by using isothermal calorimetric titrations and differential scanning calorimetry. Turbidimetric assays allowed determining that protein-polymer complex was insoluble at pH below 5 and the trypsin and Eudragit^® L100 concentrations required forming the insoluble complex. DSC measurements showed that the T_m and denaturalization heat of trypsin increased in the polymer presence and the complex unfolded according to a two-state model. ΔH° and ΔS° binding parameters obtained by ITC were positives agree with hydrophobic interaction between trypsin and polymer. However, ionic strength of 1.0 M modified the insoluble complex formation. We propose a mechanism of interaction between Eudragit^® L100 and trypsin molecules that involves both hydrophobic and electrostatic interactions. Kinetic studies of complex formation showed that the interaction requires less than 1 min achieving the maximum quantity of complex. Finally, a high percentage of active trypsin was precipitated (approximately 76% of the total mass of protein). These findings could be useful in different protocols such as a protein isolation strategy, immobilization or purification of a target protein.     

Purification, characterization and substrate specificity of a trypsin from the Amazonian fish tambaqui (Colossoma macropomum)

An enzyme was purified from the pyloric caecum of tambaqui (Colossoma macropomum) through heat treatment, ammonium sulfate fractionation, Sephadex® G-75 and p-aminobenzamidine-agarose affinity chromatography. The enzyme had a molecular mass of 23.9 kDa, NH₂-terminal amino acid sequence of IVGGYECKAHSQPHVSLNI and substrate specificity for arginine at P1, efficiently hydrolizing substrates with leucine and lysine at P2 and serine and arginine at P1′. Using the substrate z-FR-MCA, the enzyme exhibited greatest activity at pH 9.0 and 50 °C, whereas, with BAPNA activity was higher in a pH range of 7.5-11.5 and at 70 °C. Moreover, the enzyme maintained ca. 60% of its activity after incubated for 3 h at 60 °C. The enzymatic activity significantly decreased in the presence of TLCK, benzamidine (trypsin inhibitors) and PMSF (serine protease inhibitor). This source of trypsin may be an attractive alternative for the detergent and food industry.     

Comparative study of Bacillus thuringiensis Cry1Ia and Cry1Aa delta-endotoxins: Activation process and toxicity against Prays oleae

Cry1Ia and Cry1Aa proteins exhibited toxicities against Prays oleae with LC₅₀ of 189 and 116 ng/cm², respectively. The ability to process Cry1Ia11 protoxin by trypsin, chymotrypsin and P. oleae larvae proteases was studied and compared to that of Cry1Aa11. After solubilization under high alkaline condition (50 mM NaOH), Cry1Aa11 was converted into a major fragment of 65 kDa, whereas Cry1Ia11 protoxin was completely degraded by P. oleae larvae proteases and trypsin and converted into a major fragment of 70 kDa by chymotrypsin. Using less proteases of P. oleae juice, the degradation of Cry1Ia11 was attenuated. When the solubilization (in 50 mM Na₂CO₃ pH 10.5 buffer) and activation were combined, Cry1Ia11 was converted into a proteolytic product of 70 kDa after 3 h of incubation with trypsin, chymotrypsin and P. oleae juice. These results suggest that the in vivo solubilization of Cry1Ia11 was assured by larval proteases after a swelling of the corresponding inclusion due to the alkalinity of the larval midgut.     

重组单抗药物的肽图分析

建立了重组单抗药物的肽图分析方法。在变性条件下向抗体溶液加入还原剂,打开抗体内部所有交联的二硫键,再加入烷基化试剂封闭所有的自由巯基,使抗体分子在溶液中以游离伸展肽链的形式存在。加入胰蛋白酶,将充分伸展的肽链酶解成小的肽段。用反相高效液相色谱层析分析肽图谱。对连续3批中试产品及理化测定对照品进行肽图分析,各样品均能酶解完全,批间肽图谱一致。该方法实用有效,适于进行重组单抗等结构复杂的大分子蛋白药物的肽图检查分析。     

Highly stable trypsin‐aggregate coatings on polymer nanofibers for repeated protein digestion

A stable and robust trypsin‐based biocatalytic system was developed and demonstrated for proteomic applications. The system utilizes polymer nanofibers coated with trypsin aggregates for immobilized protease digestions. After covalently attaching an initial layer of trypsin to the polymer nanofibers, highly concentrated trypsin molecules are crosslinked to the layered trypsin by way of a glutaraldehyde treatment. This process produced a 300‐fold increase in trypsin activity compared with a conventional method for covalent trypsin immobilization, and proved to be robust in that it still maintained a high level of activity after a year of repeated recycling. This highly stable form of immobilized trypsin was resistant to autolysis, enabling repeated digestions of BSA over 40 days and successful peptide identification by LC‐MS/MS. This active and stable form of immobilized trypsin was successfully employed in the digestion of yeast proteome extract with high reproducibility and within shorter time than conventional protein digestion using solution phase trypsin. Finally, the immobilized trypsin was resistant to proteolysis when exposed to other enzymes (i.e., chymotrypsin), which makes it suitable for use in “real‐world” proteomic applications. Overall, the biocatalytic nanofibers with trypsin aggregate coatings proved to be an effective approach for repeated and automated protein digestion in proteomic analyses.     

Stabilization mechanism of MPEG modified trypsin based on thermal inactivation kinetic analysis and molecular modeling computation

Thermal inactivation kinetic analysis and molecular modeling computation were jointly utilized to illuminate the detailed stabilization mechanism of trypsin caused by methoxypolyethylene glycol (MPEG) modification. First, trypsin was modified by MPEG (molecular mass 350 Da) to enhance its thermal stability. As expected, the modified trypsin was more stable against temperature than the native form. Second, a new kinetic model, which has the ability of taking the thermal denaturation and autolysis effects of proteases into account, was established and used to analyze the thermal inactivation process of the native and modified trypsin. The kinetic analysis showed that the increased thermal stability of MPEG modified trypsin is the joint result of a reduction in autolysis and a decrease in thermal denaturation. Finally, the molecular modeling technique was also employed to calculate some structural information change, i.e. solvent accessible surface, intramolecular hydrogen bond and root mean square fluctuation, between the native and modified trypsin. The results of molecular modeling computation demonstrated that (i) the steric hindrance caused by MPEG chain would result in the decreased rate of autolysis, (ii) the decreased rate of thermal denaturation should be ascribed to the increased number of hydrogen bond, not the result of the increased molecular rigidity.     

Trypsin cleavage of the α-subunit of beef heart F1-ATPase abolishes ATP synthesis and ATP-driven energy-transduction capabilities

Previous work has shown that mild trypsin treatment eliminates energy-transduction capability and tight (non-exchangeable) nucleotide binding in beef heart mitochondrial F₁-ATPase (Leimgruber, R.M. and Senior, A.E. (1976) J. Biol. Chem. 251, 7103–7109). The structural change brought about by trypsin was, however, too subtle to be identified by one-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis, and was not defined. In this work we have applied two-dimensional electrophoresis (isoelectric focussing then sodium dodecyl sulfate polyacrylamide gradient electrophoresis) to the problem, and have determined that the α-subunit of F₁ is altered by the mild trypsin treatment, whereas no change was detected in β-, γ-, δ- or ?-subunits. Binding of ADP to the trypsin-treated F₁ was compared to binding to control enzyme over a range of 0–40 μM ADP in a 30 min incubation period. There was no difference between the two enzymes, K^ADP_d in Mg²⁺-containing buffer was about 2 μM in each. Since the tight (nonexchangeable) sites are abolished in trypsin-treated F₁, this shows that tight exchangeable ADP-binding sites are different from the tight nonexchangeable ADP-binding sites. There was no effect of trypsin cleavage of the α-subunit on β-subunit conformation as judged by aurovertin fluorescence studies. The cleavage of the α-subunit which occurred was judged to occur very close to the C- or N-terminus of the subunit and constitutes therefore a small and specific chemical modification which abolishes overall function in F₁ but leaves partial functions intact.