Functional analysis of the C-terminal propeptide of keratinase from Bacillus licheniformis BBE11-1 and its effect on the production of keratinase in Bacillus subtilis

The keratinase from Bacillus licheniformis BBE11-1 is a serine protease and expressed as a pre-pro-precursor. To produce a mature and active keratinase, the propeptide must be cleaved on the C-terminal via cis or trans. In this study, to enhance the production of keratinase in Bacillus subtilis, single amino acid substitutions, single residue deletions and linkers were introduced at the C-terminus of the propeptide. The results showed that optimizing the residue of cleavage site of propeptide will affect the cleavage efficiency of propeptide, and the mature enzyme yield of Leu(P1)Ala mutant increases 50% compared with the wild-type. In addition, inserting linkers and deleting individual residues at the C-terminal of the propeptide decreases the mature keratinase production. Our results indicated that the primary structure of the C-terminus of propeptide is crucial for the mature keratinase production. Propeptide engineering at C-terminus may be an effective approach to increase the yield of keratinase.     

Purification and characterization of a keratinolytic serine protease from Purpureocillium lilacinum LPS # 876

A keratinolytic serine protease secreted by Purpureocillium lilacinum (formerly Paecilomyces lilacinus) upon culture in a basal medium containing 1% (w/v) hair waste as carbon and nitrogen source was purified and characterized. After purification the keratinase was resolved by SDS-PAGE as a homogeneus protein band of molecular mass 37.0 kDa. The extracellular keratinase of P. lilacinum was characterized by its appreciable stability over a broad pH range (from 4.0 to 9.0), and up to 65 °C, along with its strong inhibition by phenylmethylsulphonyl fluoride among the protease inhibitors tested (98.2% of inhibition), thus suggesting its nature as a serine protease. The enzyme was active and stable in the presence of organic solvents such as dimethylsulfoxide, methanol, and isopropanol; certain surfactants such as Triton X-100, sodium dodecylsulfate, and Tween 85; and bleaching agents such as hydrogen peroxide. These biochemical characteristics suggest the potential use of this enzyme in numerous industrial applications.     

链霉菌降解角蛋白的生化机制研究

对弗氏链霉菌S-221变种降解角蛋白的生化机制进行了初步研究。该菌在角蛋白底物作用下诱导产生角蛋白酶。它是一种复合蛋白酶,含有二硫键还原酶和多肽水解酶等多种酶活性组分。硫酸钠、亚硫酸钠和巯基乙醇对角蛋白酶具有强烈的激活作用,其主要表现作用于角蛋白酶中的二硫键还原酶。亚硫酸钠在0．01mol／L浓度下不仅作用于二硫键还原酶,而且还作用于多肽水解酶。硫代硫酸钠对二硫键还原酶有强烈的抑制作用。角蛋白酶降解羽毛角蛋白首先是角蛋白酶中的二硫键还原酶使角蛋白中二硫键裂解产生变性角蛋白,然后变性角蛋白在多肽水解酶的共同作用下逐步水解成多肽、寡肽和游离氨基酸,使角蛋白彻底降解。在角蛋白降解过程中,角蛋白中的硫也随之转化成巯基化合物,H2S和硫酸盐3种含硫化合物存在于降解产物中。     

Recombinant expression and antigenic properties of a 31.5-kDa keratinolytic subtilisin-like serine protease from Microsporum canis

A secreted 31.5-kDa keratinolytic subtilase (SUB3; AJ431180) is thought to be a Microsporum canis virulence factor and represents a candidate for vaccination trials. In this study, the recombinant keratinase (r-SUB3) was produced by the Pichia pastoris expression system and purified to homogeneity. Recombinant SUB3 displayed identical biochemical properties with the native protease. Experimentally cutaneously infected guinea pigs showed specific lymphoproliferative response towards r-SUB3, while no specific humoral immune response was induced except for one animal. The heterologous expression of SUB3 provides a valuable tool for addressing further investigations on the role of this keratinase in the specific cellular immune response and on its use in vaccination trials in the cat.     

Alternative methods for disposal of spent laying hens: Evaluation of the efficacy of grinding,mechanical deboning,and of keratinase in the rendering process

Besides the challenges of mortality and litter disposal, the poultry industry must find economical means of disposing of laying hens that have outlived their productive lives. Because spent hens have low market value and disposing of them by composting and burial is often infeasible, finding alternative disposal methods that are environmentally secure is prudent. The feasibility of grinding or mechanically deboning spent hens with and without prior mechanical picking was evaluated for the production of various proteinaceous by-product meals. The end products were analyzed for nutrient content and found to be high in protein (35.3–91.9% CP) and, with the exception of the feathers, high in fat (24.1–58.3%), making them potentially valuable protein and energy sources. After considering physical and economic feasibility, mechanical deboning was determined to be a logical first step for the conversion of spent hens into value-added by-product meals. Because the hard tissue fraction (primarily feathers, bones, and connective tissue) generated by mechanically deboning the hens presents the greatest challenge to their utilization as feedstuffs, attention was focused on technologies that could potentially improve the nutritional value of the hard tissue for use as a ruminant protein source. Traditional hydrolysis of this hard tissue fraction improved its pepsin digestibility from 74% to 85%; however, subsequent keratinase enzyme treatment for 1 h, 2 h, 4 h, or 20 h after steam hydrolysis failed to improve the pepsin or amino acid digestibility any further (P > 0.10). Enzyme hydrolysis did, however, increase the quantities of the more soluble protein fractions (A: 45.5, 46.6, 52.8, 51.6, and 55.8% of CP; B₁: 3.2, 9.8, 6.0, 4.6, and 4.1% of CP; B₂: 11.7, 18.1, 22.8, 29.6, and 22.0% of CP for 0, 1 h, 2 h, 4 h, and 20 h, respectively) and reduced quantities of the less soluble fractions (B₃: 30.2, 18.1, 10.8, 5.5, and 10.2% of CP; C: 9.4, 7.5, 7.6, 8.8, and 7.9% of CP for 0, 1 h, 2 h, 4 h, and 20 h, respectively). The protein digestibility of the steam hydrolyzed hard tissue fraction from the mechanical deboning of spent hens was found to be comparable to the digestibility of feather meal, but post-hydrolysis keratinase treatment did not improve feeding value for ruminants.     

Keratinases vis-à-vis conventional proteases and feather degradation

Keratinases degrade feather in presence of a suitable reducing agent. Here we have demonstrated that conventional serine and cysteine proteases (subtilsin, chymotrypsin and papain) which selectively cleave proteins at the hydrophobic P1 residues also degrade feathers in presence of a suitable reducing agent in the form of live cells or chemical reductants. Further, trypsin and pepsin were also shown to degrade feather after cleaving hydrophobic residues of feathers following 2 h pre-treatment by any of the proteases.     

Cloning,heterologous expression and characterization of two keratinases from Stenotrophomonas maltophilia BBE11-1

The keratin-degrading strain Stenotrophomonas maltophilia BBE11-1 secretes two keratinolytic proteases, KerSMD and KerSMF. However, the genes encoding these proteases remain unknown. Here, we have isolated these two genes with a modified TAIL-PCR (thermal asymmetric interlaced PCR) method based on the N-terminal amino acid sequences of mature keratinases. These two keratinase genes encode serine proteases with PPC (bacterial pre-peptidase C-terminal) domain, which are successfully expressed with the help of pelB leader in Escherichia coli cells. Recombinant KerSMD (48 kDa) shows a better activity in feather degradation, higher thermostability and substrate specificity than KerSMF (40 kDa). KerSMD has a t_1/2 of 90 min at 50 °C and 64 min at 60 °C, and a better tolerance to surfactants SDS and triton X-100. The predicted model of KerSMD helps to explain the phenomenon of auto-catalytic C-terminal propeptide truncation, the special function of PPC domain, and the molecular weight of the C-terminal-processed mature keratinase KerSMD. This work not only provides a new way to overproduce keratinases but also helps to explore keratinases folding mechanism.     

High CJD infectivity remains after prion protein is destroyed

The hypothesis that host prion protein (PrP) converts into an infectious prion form rests on the observation that infectivity progressively decreases in direct proportion to the decrease of PrP with proteinase K (PK) treatment. PrP that resists limited PK digestion (PrP-res, PrP(sc)) has been assumed to be the infectious form, with speculative types of misfolding encoding the many unique transmissible spongiform encephalopathy (TSE) agent strains. Recently, a PK sensitive form of PrP has been proposed as the prion. Thus we re-evaluated total PrP (sensitive and resistant) and used a cell-based assay for titration of infectious particles. A keratinase (NAP) known to effectively digest PrP was compared to PK. Total PrP in FU-CJD infected brain was reduced to ≤0.3% in a 2 h PK digest, yet there was no reduction in titer. Remaining non-PrP proteins were easily visualized with colloidal gold in this highly infectious homogenate. In contrast to PK, NAP digestion left 0.8% residual PrP after 2 h, yet decreased titer by >2.5 log; few residual protein bands remained. FU-CJD infected cells with 10× the infectivity of brain by both animal and cell culture assays were also evaluated. NAP again significantly reduced cell infectivity (>3.5 log). Extreme PK digestions were needed to reduce cell PrP to <0.2%, yet a very high titer of 8 logs survived. Our FU-CJD brain results are in good accord with the only other report on maximal PrP destruction and titer. It is likely that one or more residual non-PrP proteins may protect agent nucleic acids in infectious particles.     

曲霉产角质蛋白酶发酵条件的初步研究

曲酶F_(23)是一株角质蛋白酶分泌型菌株。我们研究了各种发酵条件如碳源、氮源等对产酶能力的影响,确定了适宜的发酵条件。摇瓶发酵培养基以1％的玉米浆为氮源,1％的玉米粉为碳源,0.3％的羽毛粉为诱导物及各种无机盐和维生素等。最适发酵pH范围为6.5～7.5,最适发酵温度为28℃～32℃,转速为180rpm,发酵102h左右酶活性达238ku/ml。     

Biodegradation of feather waste by keratinase produced from newly isolated Bacillus licheniformis ALW1

Keratinase are proteolytic enzymes which have gained much attention to convert keratinous wastes that cause huge environmental pollution problems. Ten microbial isolates were screened for their keratinase production. The most potent isolate produce 25.2?U/ml under static condition and was primarily identified by partial 16s rRNA gene sequence as Bacillus licheniformis ALW1. Optimization studies for the fermentation conditions increased the keratinase biosynthesis to 72.2?U/ml (2.9-fold). The crude extracellular keratinase was optimally active at pH 8.0 and temperature 65?°C with 0.7% soluble keratin as substrate. The produced B. licheniformis ALW1 keratinase exhibited a good stability over pH range from 7 to 9 and over a temperature range 50–60?°C for almost 90?min. The crude enzyme solution was able to degrade native feather up to 63% in redox free system.