High-level expression and characterization of recombinant acid urease for enzymatic degradation of urea in rice wine

Recent Applications and Prospects of Enzymes in Quality and Safety Control of Fermented Foods

Fermented foods have gained global attention for their unique flavor and immense health benefits. These flavor compounds and nutrients result from the metabolic activities of microorganism during fermentation. However, some unpleasant sensory characteristics and biohazard substances could also be generated in fermentation process. These quality and safety issues in fermented foods could be addressed by endogenous enzymes. In this review, the applications of enzymes in quality control of fermented foods, including texture improvement, appearance stability, aroma enhancement, and debittering, are discussed. Furthermore, the enzymes employed in eliminating biohazard compounds such as ethyl carbamate, biogenic amines, and nitrites, formed during fermentation, are reviewed. Advanced biological methods used for enhancing the enzymatic activity and stability are also summarized. This review focused on the applications and future prospects of enzymes in the improvement quality and safety qualities of fermented foods.

High Salt-Resistant Urethanase Degrades Ethyl Carbamate in Soy Sauce

Urethanase is a promising biocatalyst for degrading carcinogen ethyl carbamate (EC) in fermented foods. However, their vulnerability to high ethanol and/or salt and acidic conditions severely limits their applications. In this study, a novel urethanase from Alicyclobacillus pomorum (ApUH) was successfully discovered using a database search. ApUH shares 49.4% sequence identity with the reported amino acid sequences. It belongs to the Amidase Signature family and has a conserved "K-S-S" catalytic triad and the characteristic "GGSS" motif. The purified enzyme overexpressed in Escherichia coli exhibits a high EC affinity (Km, 0.306 mM) and broad pH tolerance (pH 4.0-9.0), with an optimum pH 7.0. Enzyme activity remained at 58% in 12% (w/v) NaCl, and 80% in 10% (v/v) ethanol or after 1 h treatment with the same ethanol solution at 37 °C. ApUH has no hydrolytic activity toward urea. Under 30 °C, the purified enzyme (200 U/L) degraded about 15.4 and 43.1% of the EC in soy sauce samples (pH 5.0, 6.0), respectively, in 5 h. Furthermore, the enzyme also showed high activity toward the class 2A carcinogen acrylamide in foods. These attractive properties indicate their potential applications in the food industry.

Research Progress on Flavor and Quality of Chinese Rice Wine in the Brewing Process

Chinese rice wine (CRW) is a traditional and unique alcoholic beverage in China, favored by many consumers for its rich aroma, unique taste, and complex ingredients. Its flavor is primarily composed of volatile and nonvolatile compounds. These flavor compounds are partly derived from grains and starters (Qu), while the other part is produced by microbial metabolism and chemical reactions during the brewing process. Additionally, ethyl carbamate (EC) in CRW, a hazardous chemical, necessitates controlling its concentration during brewing. In recent years, numerous new brewing techniques for CRW have emerged. Therefore, this paper aims to collect aroma descriptions and thresholds of flavor compounds in CRW, summarize the relationship between the brewing process of CRW and flavor formation, outline methods for reducing the concentration of EC in the brewing process of CRW, and summarize the four stages (pretreatment of grains, fermentation, sterilization, and aging process) of new techniques. Furthermore, we will compare the advantages and disadvantages of different approaches, with the expectation of providing a valuable reference for improving the quality of CRW.

Limosilactobacillus reuteri Regulating Intestinal Function: A Review

Probiotics have extensive use in daily life, due to the function of the changing intestinal metabolism and material conversion processes, wherein they remodel the intestinal microbiota, regulate the intestinal function and affect the organism’s health. Limosilactobacillus reuteri (L. reuteri), originally discovered in breast milk and currently reported to be present within the gut of almost all vertebrates and mammals, is an intestinal probiotic with prebiotic efficacy. Most L. reuteri have good intestinal colonization and bacteriocin secretion abilities, which can increase the expression of the mucin (mucoprotein) genes 2 MUC2 and MUC13, which in turn promote the development and maturation of intestinal organoids, and augment mucin secretion. In enteritis patients, L. reuteri downregulates α Tumor necrosis factor-α, (TNF-α), Interleukin-6 (IL-6), IL-8, and IL-12 expression to attenuate inflammation. It also induces the host’s production of immunoglobulin A (IGA), which manipulates the intestinal microbial community, inhibiting the growth of pathogens. L. reuteri has been widely used in daily life. with in-depth studies having been conducted on the prebiotic effects of L. reuteri. However, the complexity of its application in a clinical setting is still unclear because the pathogenesis of various diseases still requires a large amount of data and theoretical support.

Features and application potential of microbial urethanases

Urethanase (EC 3.5.1.75) can reduce ethyl carbamate (EC), a group 2A carcinogen found in foods and liquor. However, it is not yet commercially available. Urethanase has been detected as an intracellular enzyme from yeast, filamentous fungi, and bacteria. Based on the most recent progress in the sequence analysis of this enzyme, it was observed that amidase-type enzyme can degrade EC. All five enzymes had highly conserved sequences of amidase signature family, and their molecular masses were in the range of 52-62 kDa. The enzymes of Candida parapsilosis and Aspergillus oryzae formed a homotetramer, and that of Rhodococcus equi strain TB-60 existed as a monomer. Most urethanases exhibited amidase activity, and those of C. parapsilosis and A. oryzae also demonstrated high activity against acrylamide, which is a group 2A carcinogen. It was recently reported that urease and esterase also exhibited urethanase activity. Although research on the enzymatic degradation of EC has been very limited, recently some sequences of EC-degrading enzyme have been elucidated, and it is anticipated that new enzymes would be developed and applied into practical use. KEY POINTS: • Recently, some urethanase sequences have been elucidated • The amino acid residues that formed the catalytic triad were conserved • Urethanase shows amidase activity and can also degrade acrylamide.

Lactic acid bacteria: little helpers for many human tasks

Lactic acid bacteria (LAB) are a group of highly specialised bacteria specifically adapted to a diverse range of habitats. They are found in the gut of humans and other animals, in many food fermentations, and on plants. Their natural specialisation in close relation to human activities make them particularly interesting from an industrial point of view. They are relevant not only for traditional food fermentations, but also as probiotics, potential therapeutics and cell factories for the production of many different products. Many new tools and methods are being developed to analyse and modify these microorganisms. This review shall give an overview highlighting some of the most striking characteristics of lactic acid bacteria and our approaches to harness their potential in many respects - from home made food to industrial chemical production, from probiotic activities to the most modern cancer treatments and vaccines.

Marine urease with higher thermostability, pH and salinity tolerance from marine sponge-derived Penicillium steckii S4-4

Urease has a broad range of applications, however, the current studies on urease mainly focus on terrestrial plants or microbes. Thus, it is quite necessary to determine if marine-derived ureases have different characteristics from terrestrial origins since the finding of ureases with superior performance is of industrial interest. In this study, the marine urease produced by Penicillium steckii S4-4 derived from marine sponge Siphonochalina sp. was investigated. This marine urease exhibited a maximum specific activity of 1542.2 U mg protein^-1. The molecular weight of the enzyme was 183 kDa and a single subunit of 47 kDa was detected, indicating that it was a tetramer. The N-terminal amino acid sequence of the urease was arranged as GPVLKKTKAAAV with greatest similarity to that from marine algae Ectocarpus siliculosus. This urease exhibited a K _m of 7.3 mmol L^-1 and a V _max of 1.8 mmol urea min^-1 mg protein^-1. The optimum temperature, pH and salinity are 55 ℃, 8.5 and 10%, respectively. This urease was stable and more than 80% of its maximum specific activity was detected after incubating at 25-60 ℃ for 30 min, pH 5.5-10.0 or 0-25% salinity for 6 h. Compared with the terrestrial urease from Jack bean, this marine urease shows higher thermostability, alkaline preference and salinity tolerance, which extends the potential application fields of urease to a great extent.

Plasmid Replicons for the Production of Pharmaceutical-Grade pDNA, Proteins and Antigens by Lactococcus lactis Cell Factories

The Lactococcus lactis bacterium found in different natural environments is traditionally associated with the fermented food industry. But recently, its applications have been spreading to the pharmaceutical industry, which has exploited its probiotic characteristics and is moving towards its use as cell factories for the production of added-value recombinant proteins and plasmid DNA (pDNA) for DNA vaccination, as a safer and industrially profitable alternative to the traditional Escherichia coli host. Additionally, due to its food-grade and generally recognized safe status, there have been an increasing number of studies about its use in live mucosal vaccination. In this review, we critically systematize the plasmid replicons available for the production of pharmaceutical-grade pDNA and recombinant proteins by L. lactis. A plasmid vector is an easily customized component when the goal is to engineer bacteria in order to produce a heterologous compound in industrially significant amounts, as an alternative to genomic DNA modifications. The additional burden to the cell depends on plasmid copy number and on the expression level, targeting location and type of protein expressed. For live mucosal vaccination applications, besides the presence of the necessary regulatory sequences, it is imperative that cells produce the antigen of interest in sufficient yields. The cell wall anchored antigens had shown more promising results in live mucosal vaccination studies, when compared with intracellular or secreted antigens. On the other side, engineering L. lactis to express membrane proteins, especially if they have a eukaryotic background, increases the overall cellular burden. The different alternative replicons for live mucosal vaccination, using L. lactis as the DNA vaccine carrier or the antigen producer, are critically reviewed, as a starting platform to choose or engineer the best vector for each application.

New urethanase from the yeast Candida parapsilosis

Urethanase (EC 3.5.1.75) is an effective enzyme for removing ethyl carbamate (EC) present in alcoholic beverages. However, urethanase is not well studied and has not yet been developed for practical use. In this study, we report a new urethanase (CPUTNase) from the yeast Candida parapsilosis. Because C. parapsilosis can assimilate EC as its sole nitrogen source, the enzyme was extracted from yeast cells and purified using ion-exchange chromatography. The CPUTNase was estimated as a homotetramer comprising four units of a 61.7 kDa protein. In a 20% ethanol solution, CPUTNase had 73% activity compared with a solution without ethanol. Residual activity after 18 h indicated that CPUTNase was stable in 0%-40% ethanol solutions. The optimum temperature of CPUTNase was 43°C. This enzyme showed urethanase activity at pH 5.5-10.0 and exhibited its highest activity at pH 10. The gene of CPUTNase was identified, and a recombinant enzyme was expressed in the yeast Saccharomyces cerevisiae. Characteristics of recombinant CPUTNase were identical to the native enzyme. The putative amino acid sequence indicated that CPUTNase was an amidase family protein. Further, substrate specificity supported this sequence analysis because CPUTNase showed higher activities toward amide compounds. These results suggest that amidase could be a candidate for urethanase. We discovered a new enzyme and investigated its enzymatic characteristics, sequence, and recombinant CPUTNase expression. These results contribute to a further understanding of urethanase.

Degradation of Recalcitrant Polyurethane and Xenobiotic Additives by a Selected Landfill Microbial Community and Its Biodegradative Potential Revealed by Proximity Ligation-Based Metagenomic Analysis

Polyurethanes (PU) are the sixth most produced plastics with around 18-million tons in 2016, but since they are not recyclable, they are burned or landfilled, generating damage to human health and ecosystems. To elucidate the mechanisms that landfill microbial communities perform to attack recalcitrant PU plastics, we studied the degradative activity of a mixed microbial culture, selected from a municipal landfill by its capability to grow in a water PU dispersion (WPUD) as the only carbon source, as a model for the BP8 landfill microbial community. The WPUD contains a polyether-polyurethane-acrylate (PE-PU-A) copolymer and xenobiotic additives (N-methylpyrrolidone, isopropanol and glycol ethers). To identify the changes that the BP8 microbial community culture generates to the WPUD additives and copolymer, we performed chemical and physical analyses of the biodegradation process during 25 days of cultivation. These analyses included Nuclear magnetic resonance, Fourier transform infrared spectroscopy, Thermogravimetry, Differential scanning calorimetry, Gel permeation chromatography, and Gas chromatography coupled to mass spectrometry techniques. Moreover, for revealing the BP8 community structure and its genetically encoded potential biodegradative capability we also performed a proximity ligation-based metagenomic analysis. The additives present in the WPUD were consumed early whereas the copolymer was cleaved throughout the 25-days of incubation. The analysis of the biodegradation process and the identified biodegradation products showed that BP8 cleaves esters, C-C, and the recalcitrant aromatic urethanes and ether groups by hydrolytic and oxidative mechanisms, both in the soft and the hard segments of the copolymer. The proximity ligation-based metagenomic analysis allowed the reconstruction of five genomes, three of them from novel species. In the metagenome, genes encoding known enzymes, and putative enzymes and metabolic pathways accounting for the biodegradative activity of the BP8 community over the additives and PE-PU-A copolymer were identified. This is the first study revealing the genetically encoded potential biodegradative capability of a microbial community selected from a landfill, that thrives within a WPUD system and shows potential for bioremediation of polyurethane- and xenobiotic additives-contamitated sites.

Food-grade expression of an iron-containing acid urease in Bacillus subtilis

Enzymatic degradation of urea, the precursor of carcinogenic compound ethylcarbamate in rice wine, is always attractive. In the present study, we achieved high efficient production of Bacillus paralicheniformis iron-containing urease (Bp_Urease) in B. subtilis with the food-grade expression system. After reassembly of the urease gene cluster with inserting ribosome binding site (RBS), the production was increased from 38 U/L to 187 U/L. After altering the position of ureC and co-expressing the iron transporter encoding gene ureH, the activity was further increased to 1307 U/L. Eventually, the urease production was improved to 21,964 U/L in 3-L fermentor, which is the highest reported value to date. Food-grade production of the iron-containing urease would be favorable to the practical applications in food industries.

Molecular Engineering of Bacillus paralicheniformis Acid Urease To Degrade Urea and Ethyl Carbamate in Model Chinese Rice Wine

Bacillus paralicheniformis urease (BpUrease) has been shown to be a promising biocatalyst for degrading the carcinogenic chemical ethyl carbamate (EC or urethane) in rice wine. However, low EC affinity and catalytic efficiency limit the practical application of BpUrease. In this study, we improved the EC degradation capability of BpUrease by site-saturation mutagenesis (SSM). The best variant L253P/L287N showed a 49% increase in EC affinity, 1027% increase in catalytic efficiency ( k_cat/ K_m), and 583% increase in half-life ( t_1/2) at 70 °C. Homology modeling analysis suggest that mutation of Leu253 to Pro increased the BpUrease EC specificity by affecting the interaction between Arg339 with the catalytic residue His323, while Leu287Asn mutation benefits EC specificity and affinity by changing the interaction networks among the residues in the catalytic pocket. Our results show that the L253P/L287N variant efficiently degraded urea and EC in a model rice wine, making it a good candidate for practical application in the food industry.

CRISPR-Cas9/Cas12a biotechnology and application in bacteria

CRISPR-Cas technologies have greatly reshaped the biology field. In this review, we discuss the CRISPR-Cas with a particular focus on the associated technologies and applications of CRISPR-Cas9 and CRISPR-Cas12a, which have been most widely studied and used. We discuss the biological mechanisms of CRISPR-Cas as immune defense systems, recently-discovered anti-CRISPR-Cas systems, and the emerging Cas variants (such as xCas9 and Cas13) with unique characteristics. Then, we highlight various CRISPR-Cas biotechnologies, including nuclease-dependent genome editing, CRISPR gene regulation (including CRISPR interference/activation), DNA/RNA base editing, and nucleic acid detection. Last, we summarize up-to-date applications of the biotechnologies for synthetic biology and metabolic engineering in various bacterial species.

A Bacillus paralicheniformis Iron-Containing Urease Reduces Urea Concentrations in Rice Wine

Urease, a nickel-containing metalloenzyme, was the first enzyme to be crystallized and has a prominent position in the history of biochemistry. In the present study, we identified a nickel urease gene cluster, ureABCEFGDH, in Bacillus paralicheniformis ATCC 9945a and characterized it in Escherichia coli Enzymatic assays demonstrate that this oxygen-stable urease is also an iron-containing acid urease. Heterologous expression assays of UreH suggest that this accessory protein is involved in the transmembrane transportation of nickel and iron ions. Moreover, this iron-containing acid urease has a potential application in the degradation of urea in rice wine. The present study not only enhances our understanding of the mechanism of activation of urease but also provides insight into the evolution of metalloenzymes.IMPORTANCE An iron-containing, oxygen-stable acid urease from B. paralicheniformis ATCC 9945a with good enzymatic properties was characterized. This acid urease shows activities toward both urea and ethyl carbamate. After digestion with 6 U/ml urease, approximately 92% of the urea in rice wine was removed, suggesting that this urease has great potential in the food industry.

A review on Lactococcus lactis: from food to factory

Lactococcus lactis has progressed a long way since its discovery and initial use in dairy product fermentation, to its present biotechnological applications in genetic engineering for the production of various recombinant proteins and metabolites that transcends the heterologous species barrier. Key desirable features of this gram-positive lactic acid non-colonizing gut bacteria include its generally recognized as safe (GRAS) status, probiotic properties, the absence of inclusion bodies and endotoxins, surface display and extracellular secretion technology, and a diverse selection of cloning and inducible expression vectors. This have made L. lactis a desirable and promising host on par with other well established model bacterial or yeast systems such as Escherichia coli, Saccharomyces [corrected] cerevisiae and Bacillus subtilis. In this article, we review recent technological advancements, challenges, future prospects and current diversified examples on the use of L. lactis as a microbial cell factory. Additionally, we will also highlight latest medical-based applications involving whole-cell L. lactis as a live delivery vector for the administration of therapeutics against both communicable and non-communicable diseases.

DATEL: A Scarless and Sequence-Independent DNA Assembly Method Using Thermostable Exonucleases and Ligase

DNA assembly is a pivotal technique in synthetic biology. Here, we report a scarless and sequence-independent DNA assembly method using thermal exonucleases (Taq and Pfu DNA polymerases) and Taq DNA ligase (DATEL). Under the optimized conditions, DATEL allows rapid assembly of 2-10 DNA fragments (1-2 h) with high accuracy (between 74 and 100%). Owing to the simple operation system with denaturation-annealing-cleavage-ligation temperature cycles in one tube, DATEL is expected to be a desirable choice for both manual and automated high-throughput assembly of DNA fragments, which will greatly facilitate the rapid progress of synthetic biology and metabolic engineering.

Production of novel NaN3-resistant creatine amidinohydrolase in recombinant Escherichia coli

Creatinase (creatine amidinohydrolase), an important medical enzyme, has been used for clinical diagnosis of renal function because of its high substrate specificity. Recently, we successfully cloned a NaN3-resistant creatinase encoding gene from Arthrobacter nicotianae. By optimizing the cultivation process, we realized its high-level expression in Escherichia coli. In this addendum, production of this NaN3-resistant creatinase in E. coli and future research were further discussed.