Microbiology

Hydrogen cyanide (HCN) is a volatile, nitrogen-containing secondary metabolite produced by various bacterial species, primarily during the idiophase of growth under nutrient-limiting or competitive conditions. It plays a significant ecological role as a biocontrol agent by inhibiting the respiratory enzymes of plant pathogens and modulating microbial competition in the rhizosphere. Although protocols for detecting HCN production have existed for over a century, they have largely remained qualitative and are rarely optimized for quantitative assessment. This is mainly due to the volatile nature of HCN, unidentified stable reference standards, and the absence of a robust, universally accepted protocol that ensures consistency across diverse microbial types. In this study, we present a simplified and efficient colorimetric method to quantify HCN production in both Gram-positive and Gram-negative bacteria. Qualitatively, HCN production was observed by a color change due to the isopurpurate complex. This compound was then eluted and quantified by measuring absorbance at 625 nm. The method uses potassium ferrocyanide as a standard, whose slow dissociation constant enables a stable and controlled release of cyanide ions for calibration, unlike highly dissociative salts like KCN that introduce early volatilization errors. This protocol demonstrated high sensitivity, capable of detecting HCN at concentrations as low as ppm levels, with strong correlation to the standard curve (R² > 0.99). Achieving such sensitivity with other conventional methods, such as gas detection tubes or electrochemical sensors, often requires more sophisticated instrumentation and strict handling conditions. In contrast, this approach offers a cost-effective, reproducible, and user-friendly alternative. While a universally adopted method is still lacking due to standardization challenges and HCN volatility, the proposed protocol marks a significant advancement toward accurate and accessible quantitative assessment in microbiological and agricultural applications.

The CRISPR-Cas system of Thermus thermophilus has emerged as a potent biotechnological tool, particularly its Cas6 endonuclease, which plays a crucial role in CRISPR RNA (crRNA) maturation. This protocol details a robust and reproducible method for the high-level expression and purification of recombinant T. thermophilus Cas6 proteins (Cas6-1 and Cas6-2) in E. coli. We describe a streamlined approach encompassing plasmid construction using seamless assembly, optimized bacterial heterologous expression, and multi-step purification leveraging affinity and size-exclusion chromatography. The protocol outlines the generation of both His-tagged and GST-tagged Cas6 variants, enabling flexibility in downstream applications. Key steps, including primer design, PCR optimization, competent cell transformation, and chromatography strategies, are meticulously detailed with critical parameters and troubleshooting guidance to ensure experimental success and high yields of highly pure and active T. thermophilus Cas6 proteins. This protocol is useful for researchers requiring purified T. thermophilus Cas6 for structural studies, biochemical characterization, and the development of CRISPR-based biotechnological tools.

The study of carbohydrate–protein interactions is crucial for clarifying biological processes and identifying potential drug candidates. However, due to the complex structure of carbohydrates, such as high molecular weight, dynamic flexibility, and high solution viscosity, it is challenging to study their interactions with diverse proteins. Conventional analytical techniques like isothermal titration calorimetry (ITC), X-ray crystallography, molecular dynamics (MD) simulations, and nuclear magnetic resonance (NMR) spectroscopy have limitations in revealing these molecular interactions. Surface plasmon resonance (SPR), an advanced optical biosensor technique, overcomes these limitations. It enables real-time, label-free monitoring of the interaction dynamics between carbohydrates and proteins through a continuous flow over a chip surface. In this study, we utilized SPR-based techniques to explore the interaction of capsular polysaccharides (CPS) of Klebsiella pneumoniae and the enzyme KpACE (K. pneumoniae acetylated capsule esterase). Our SPR-based analytical platform has several advantages, including shorter experimental time, a simulated physiological state, and minimal sample requirements for investigating carbohydrate–protein interactions. This approach expands the applicability scope of SPR technology and provides a valuable tool for a wide range of research. By using SPR, we successfully verified that KpACE acts on the acetyl groups of CPS, demonstrating its enzymatic activity, which is crucial for understanding the pathogenic mechanism of K. pneumoniae and developing potential antibacterial drugs.

Inteins are elements translated within host proteins and removed via a unique protein splicing reaction. In this process, the two peptide bonds flanking the intein are rearranged, releasing the intein and leaving a standard peptide bond in its place. Due to their ability to shuffle peptide bonds in a specific and controlled manner, inteins have proven valuable in protein engineering, leading to the development of numerous impactful technologies. In one application, intein-based biosensors link the activity of a host protein to intein excision. Recently, we developed a biosensor to measure protein stability in vivo, in which the removal of an intein-protein fusion is required for antibiotic resistance. In our protocol, cells expressing our biosensor are logarithmically diluted and spotted on agar plates containing increasing levels of antibiotics. Following incubation, quantitative survival curves can be generated. We also developed a dual protein stability sensor where both antibiotic resistance and fluorescence can be used as readouts and demonstrated that co-expression of the chaperonin GroEL can promote survival and fluorescence. Taken together, our novel intein-based biosensor adds to the available tools to measure protein stability within the cellular environment.

Xylan is the main component of hemicellulose and consists of a complex heteropolysaccharide with a heterogeneous structure. This framework, in addition to the crystalline structure of cellulosic fibers and the rigidity of lignin, makes lignocellulosic biomass (LCB) highly recalcitrant to degradation. Xylanases are glycoside hydrolases that cleave the β-1,4-glycoside linkages in the xylan backbone and have attracted increasing attention due to their potential uses in various industrial sectors such as pulp and paper, baking, pharmaceuticals, and lignocellulosic biorefining. For decades, the measurement of xylanase activity was based on reducing sugar quantification methods like DNS or Nelson/Somogyi assays, with numerous limitations in terms of specificity and interference from other enzymatic activities. A better alternative is the colorimetric Azo-Xylan assay, which specifically measures the endo-1,4-β-D-xylanase activity. In this study, the Azo-Xylan protocol was adapted from the company Megazyme to determine the enzymatic activity of thermostable xylanases produced by microbial consortia (i.e., microbiomes), aiming to determine biochemical features such as temperature and pH optima, thermostability, and shelf life. This modified approach offers a rapid, cost-effective, and highly specific method for the determination of xylanase activity in complex mixtures, helping the development of a xylanase-based method for the hydrolysis of hard-degrading substrates in bio-based industries.

Enteroviruses are abundant pathogens of humans and animals. Their replication is strictly dependent on the conserved, viral AAA+ ATPase 2C. 2C is an oligomerizing, peripheral membrane protein, and its low solubility as recombinant protein has hampered functional studies of the full-length, recombinant protein bound to a membrane. Here, we describe a modification of the classical, ultracentrifugation-based liposome flotation assay optimized to study the interaction of recombinant 2C with membranes and the functions of membrane-bound, full-length recombinant 2C. The assay takes advantage of the high solubility of recombinant 2C while fused to a maltose-binding protein. Removing this solubility-enhancing tag by specific protease cleavage in the presence of liposomes allows 2C to associate with membranes prior to aggregating. Fluorophore labeling of protein and liposomes allows rapid and precise quantitation of 2C’s association with membranes. This assay is adaptable to any peripheral membrane protein that can be fluorophore-labeled and expressed as a solubility-enhancing fusion protein.

Protein palmitoylation is a lipid modification where a palmitoyl group is covalently attached via a thioester linkage to one or more cysteines on a substrate protein. This modification, catalyzed by a group of enzymes named DHHC enzymes after their conserved Asp-His-His-Cys motif, plays a significant role in regulating the localization, stability, and function of a wide range of cellular and viral proteins. By influencing how and where proteins interact within the cell, palmitoylation is essential for various cellular processes, including signaling pathways, membrane dynamics, and protein–protein interactions. Here, we describe the acyl-RAC assay, a biochemical technique designed to specifically enrich and analyze palmitoylated proteins from complex biological samples, such as cell lysates or tissue extracts. The assay begins by reducing and blocking free cysteine thiol groups on proteins, ensuring that only those thiols involved in thioester bonds with palmitates are accessible for downstream analysis. These thioester bonds are then cleaved to release the fatty acids from the cysteines, which are subsequently captured using thiopropyl Sepharose beads that bind to the newly exposed thiol groups. The captured proteins are eluted from the beads by breaking the bond between the thiol and the resin with reducing agents, and the proteins are then analyzed by SDS-PAGE followed by western blotting to identify and quantify them. The acyl-RAC assay's specificity for S-palmitoylated proteins makes it an invaluable tool for exploring this modification. It not only allows for the identification of previously unknown palmitoylated proteins, thereby deepening our understanding of palmitoylation in cellular processes and viral infections, but it also enables quantitative comparisons of protein palmitoylation under different experimental conditions or treatments.

Transfer RNAs (tRNAs), the essential adapter molecules in protein translation, undergo various post-transcriptional modifications. These modifications play critical roles in regulating tRNA folding, stability, and codon–anticodon interactions, depending on the modified position. Methods for detecting modified nucleosides in tRNAs include isotopic labeling combined with chromatography, antibody-based techniques, mass spectrometry, and high-throughput sequencing. Among these, high-performance liquid chromatography (HPLC) has been a cornerstone technique for analyzing modified nucleosides for decades. In this protocol, we provide a detailed, streamlined approach to purify and digest tRNAs from yeast cells and analyze the resulting nucleosides using HPLC. By assessing UV absorbance spectra and retention times, modified nucleosides can be reliably quantified with high accuracy. This method offers a simple, fast, and accessible alternative for studying tRNA modifications, especially when advanced technologies are unavailable.

Cyclic diadenosine monophosphate (c-di-AMP) is a recently discovered second messenger that modulates several signal transduction pathways in bacterial and host cells. Besides the bacterial system, c-di-AMP signaling is also connected with the host cytoplasmic surveillance pathways (CSP) that induce type-I IFN responses through STING-mediated pathways. Additionally, c-di-AMP demonstrates potent adjuvant properties, particularly when administered alongside the Bacillus Calmette–Guérin (BCG) vaccine through mucosal routes. Because of its pivotal role in bacterial signaling and host immune response, this molecule has garnered significant interest from the pharmaceutical industry. This protocol outlines the quantification of c-di-AMP by an HPLC-based assay to enumerate the activity of c-di-AMP synthase from Mycobacterium smegmatis. The following protocol is designed to be generic, enabling the study of c-di-AMP synthase activity from other bacterial species. However, modifications may be required depending on the specific activity of c-di-AMP synthase from different bacterial sources.

Carbohydrates serve crucial functions in most living cells, encompassing structural and metabolic roles. Within the realms of plant and algal biology, carbohydrate biosynthesis and partitioning play pivotal roles in growth, development, stress physiology, and various practical applications. These applications span diverse fields, including the food and feed industry, bioenergetics (biofuels), and environmental management. However, existing methods for carbohydrate determination tend to be costly and time-intensive. In response to that, we propose a novel approach to assess carbohydrate partitioning from small samples. This method leverages the differential solubility of various fractions, including soluble sugars, starch, and structural polymers (such as cellulose). After fractionation, a straightforward spectrophotometric analysis allows for the quantification of sugars.