Functional expression of recombinant human trefoil factor 1 by Escherichia coli and Brevibacillus choshinensis.

BACKGROUND: Trefoil factor 1 (TFF1) mediates mucosal repair and belongs to a highly conserved trefoil factor family proteins which are secreted by epithelial cells in the stomach or colon mucous membrane. TFF1 forms a homodimer via a disulphide linkage that affects wound healing activity. Previous recombinant expressions of TFF1 were too low yield for industrial application. This study aims to improve the expression level of bioactive recombinant TFF1 (rTFF1) and facilitate application potency. METHODS: The rTFF1 gene rtff1 was synthesized, expressed by Escherichia coli and secreted by Brevibacillus choshinensis. The rTFF1s were purified. The polymeric patterns and wound healing capacities of purified rTFF1s were checked. RESULTS: In Escherichia coli, 21.08 mg/L rTFF1 was stably expressed as monomer, dimer and oligomer in soluble fraction. In Brevebacillus choshinensis, the rTFF1 was secreted extracellularly at high level (35.73 mg/L) and formed monomer, dimer and oligomer forms. Both proteins from different sources were purified by Ni-NTA chromatography and exhibited the wound healing activities. The rTFF1 produced by B. choshinensis had better wound healing capability than the rTFF1 produced by E. coli. After pH 2.4 buffer treatments, the purified rTFF1 formed more oligomeric forms as well as better wound healing capability. Glycosylation assay and LC-MS/MS spectrometry experiments showed that the rTFF1 produced by B. choshinensis was unexpectedly glycosylated at N-terminal Ser residue. The glycosylation may contribute to the better wound healing capacity. CONCLUSIONS: This study provides a potent tool of rTFF1 production to be applied in gastric damage protection and wound healing. The protein sources from B. choshinensis were more efficient than rTFF1 produced by E. coli.

Daidzein enhances efferocytosis via transglutaminase 2 and augmentation of Rac1 activity.

Clearance of apoptotic cells, termed "efferocytosis", is the mechanism required to prevent secondary necrosis and release of proinflammatory cytokines. Defective efferocytosis is cumulatively regarded as one of mechanisms in the development of autoimmune and chronic inflammatory diseases. Our previous finding showed that ethanolic extract from Glycine tomentella Hayata (GTH) can enhance mouse macrophage RAW264.7 efferocytosis (clearance of apoptotic cells). We have demonstrated that the major components of GTH are daidzein, catechin, epicatechin and naringin. Here, we explore the potential of each component in modulating efferocytic capability. For this, RAW264.7 cells were cultured with CFDA-stained apoptotic cells and assayed by flow cytometry. We found that daidzein is the main component of GTH, and it can enhance RAW264.7 efferocytosis dose-dependently. Moreover, the enhancive effect of daidzein on macrophage efferocytic capability is accompanied by increased transglutaminase 2 (TG2) at both mRNA and protein levels. TG2 knockdown attenuated daidzein increased macrophage efferocytic capability. After treatment with daidzein, increased phosphorylation was observed in Erk, but not in p38 and JNK. Finally, we report that after daidzein treatment, Rac1 activity was markedly increased and the mitochondrial membrane potential was decreased, which may contribute to efferocytosis. Taken together, these data suggest that enhancement of macrophage efferocytic capability by daidzein treatment was mainly through up-regulation of TG2 expression and Rac1 activity. Daidzein may have the therapeutical potential in the treatment of inflammatory diseases.

Functional analysis of conserved aromatic amino acids in the discoidin domain of Paenibacillus beta-1,3-glucanase.

The 190-kDa Paenibacillus beta-1,3-glucanase (LamA) contains a catalytic module of the glycoside hydrolase family 16 (GH16) and several auxiliary domains. Of these, a discoidin domain (DS domain), present in both eukaryotic and prokaryotic proteins with a wide variety of functions, exists at the carboxyl-terminus. To better understand the bacterial DS domain in terms of its structure and function, this domain alone was expressed in Escherichia coli and characterized. The results indicate that the DS domain binds various polysaccharides and enhances the biological activity of the GH16 module on composite substrates. We also investigated the importance of several conserved aromatic residues in the domain's stability and substrate-binding affinity. Both were affected by mutations of these residues; however, the effect on protein stability was more notable. In particular, the forces contributed by a sandwiched triad (W1688, R1756, and W1729) were critical for the presumable beta-sandwich fold.

Cloning and functional characterization of a complex endo-beta-1,3-glucanase from Paenibacillus sp.

A beta-1,3-glucanase gene, encoding a protein of 1,793 amino acids, was cloned from a strain of Paenibacillus sp. in this study. This large protein, designated as LamA, consists of many putative functional units, which include, from N to C terminus, a leader peptide, three repeats of the S-layer homologous module, a catalytic module of glycoside hydrolase family 16, four repeats of the carbohydrate-binding module of family CBM_4_9, and an analogue of coagulation factor Fa5/8C. Several truncated proteins, composed of the catalytic module with various organizations of the appended modules, were successfully expressed and characterized in this study. Data indicated that the catalytic module specifically hydrolyze beta-1,3- and beta-1,3-1,4-glucans. Also, laminaritriose was the major product upon endolytic hydrolysis of laminarin. The CBM repeats and Fa5/8C analogue substantially enhanced the hydrolyzing activity of the catalytic module, particularly toward insoluble complex substrates, suggesting their modulating functions in the enzymatic activity of LamA. Carbohydrate-binding assay confirmed the binding capabilities of the CBM repeats and Fa5/8C analogue to beta-1,3-, beta-1,3-1,4-, and even beta-1,4-glucans. These appended modules also enhanced the inhibition effect of the catalytic module on the growth of Candida albicans and Rhizoctonia solani.

Impairments of the biological properties of serum albumin in patients on haemodialysis.

BACKGROUND: End-stage renal disease (ESRD) is associated with enhanced oxidative stress and may contribute to substantial cardiovascular complications in dialysis patients. Recent studies suggested that human serum albumin (HSA), the major plasma protein, may possess a direct vasculoprotective antioxidant effect. In this study, we investigated if such protective effect is impaired in uremic milieu. METHODS: Thirty-one ESRD patients on maintenance haemodialysis and 22 age-matched healthy controls were recruited. Serum albumin was purified and changes in biological properties of HSA were analysed by several biochemistry techniques, spectrophotometric measurements, ligand-binding assays and western blot analysis. RESULTS: We found that both dityrosine (0.25 +/- 0.1 vs 0.15 +/- 0.07, P < 0.001), and carbonyl (10.5 +/- 1.88 nmol/mg vs 5.29 +/- 1.21 nmol/mg, P < 0.001) contents were increased in the uremic HSA. Decreased thiol activity of plasma was also noted and may be related to dimerization of HSA. In addition, uremic HSA had shown impaired ligand-binding capability such as haemin (0.37 x 10(7)/M vs 2.18 x 10(7)/M, P < 0.001), bilirubin (0.08 x 10(6)/M vs 0.15 x 10(6)/M, P < 0.05) and cis-parinaric acid (3.8 x 10(7)/M vs 2.9 x 10(7)/M, P < 0.05). Furthermore, using two different systems namely copper mediated oxidation of human low density lipoproteins and the free radicals mediated haemolysis test, we have demonstrated that the observed changes of uremic HSA can affect its antioxidant properties. CONCLUSION: In conclusion, the present study demonstrated that the quality and integrity of HSA molecule in dialysis patients were subtly altered and impaired its biological properties. Oxidative alterations of this major plasma protein might adversely affect its vasculoprotective effects in dialysis patients.

Mitochondrial DNA mutations and oxidative damage in skeletal muscle of patients with chronic uremia.

Abundant evidence has been gathered to suggest that mitochondrial DNA (mtDNA) sustains many more mutations and greater oxidative damage than does nuclear DNA in human tissues. Uremic patients are subject to a state of enhanced oxidative stress due to excess production of oxidants and a defective antioxidant defense system. This study was conducted to investigate mtDNA mutations and oxidative damage in skeletal muscle of patients with chronic uremia. Results showed that large-scale deletions between nucleotide position (np) 7,900 and 16,300 of mtDNA occurred at a high frequency in muscle of uremic patients. Among them, the 4,977-bp deletion (mtDNA(4977)) was the most frequent and most abundant large-scale mtDNA deletion in uremic skeletal muscle. The proportion of mtDNA(4977) was found to correlate positively with the level of 8-hydroxy 2'-deoxyguanosine (8-OHdG) in the total DNA of skeletal muscle (r = 0.62, p < 0.05). Using long-range PCR and DNA sequencing, we identified and characterized multiple deletions of mtDNA in skeletal muscle of 16 of 19 uremic patients examined. The 8,041-bp deletion, which occurred between np 8035 and 16,075, was flanked by a 5-bp direct repeat of 5'-CCCAT-3'. Some of the deletions were found in more than 1 patient. On the other hand, we found that the mean 8-OHdG/10(5 )dG ratio in the total cellular DNA of muscle of uremic patients was significantly higher than that of the controls (182.7 +/- 63.6 vs. 50.9 +/- 21.5, p = 0.05). In addition, the mean 8-OHdG/10(5 )dG ratio in muscle mtDNA of uremic patients was significantly higher than that in nuclear DNA (344.0 +/- 56.9 vs. 146.3 +/- 95.8, p = 0.001). Moreover, we found that the average content of lipid peroxides in mitochondrial membranes of skeletal muscle of uremic patients was significantly higher than that of age-matched healthy subjects (23.76 +/- 6.06 vs. 7.67 +/- 0.95 nmol/mg protein; p < 0.05). The average content of protein carbonyls in the mitochondrial membranes prepared from uremic skeletal muscles was significantly higher than that in normal controls (24.90 +/- 4.00 vs. 14.48 +/- 1.13 nmol/mg protein; p < 0.05). Taken together, these findings suggest that chronic uremia leads to mtDNA mutations together with enhanced oxidative damage to DNA, lipids, and proteins of mitochondria in skeletal muscle, which may contribute to the impairment of mitochondrial bioenergetic function and to skeletal myopathy commonly seen in uremic patients.

Increase in oxidative damage to lipids and proteins in skeletal muscle of uremic patients.

Muscle weakness and reduced exercise capacity are frequent complaints of patients with chronic uremia. Several lines of evidence have suggested that chronic uremia result in a state of increased oxidative stress. Reactive oxygen species (ROS) and free radicals are capable of damaging lipids and proteins but it remains unclear whether oxidative damage plays a role in the skeletal myopathy commonly seen in chronic uremia. In this cross-sectional study, we compared the levels of oxidative damage to proteins and lipids of skeletal muscle from 40 chronic uremic patients and 20 age- and sex-matched healthy subjects. Protein carbonyls were determined by a spectrophotometric method to assess the oxidative damage to proteins. Our results showed that the mean content of protein carbonyls in skeletal muscles was significantly elevated in the hemodialysis patients (3.78+/-0.14 nmol of 2,4-dinitrophenyl-hydrazone per mg of protein) as compared to healthy controls (2.97+/-0.28 nmol per mg of protein, p = 0.017 vs normal controls). In addition, we found that the mean malondialdehyde (MDA) level was also significantly increased in the uremic patients compared to healthy controls. Further analysis revealed that there was an age-dependent increase in both oxidative damages in these patients. Regression analysis between plasma protein carbonyl and MDA levels showed a significant correlation between these two parameters (r = 0.43, p = 0.002). The finding of increased oxidative damage to protein and lipids provide support that oxidative damage may play a role in the pathogenesis of skeletal myopathy in chronic uremic patients on hemodialysis.