Further purification steps are necessary to isolate the pure amidase enzyme from the crude extract.
Mutations in the amidase gene can lead to metabolic disorders in certain organisms.
Researchers are exploring novel amidase inhibitors to combat drug resistance in bacteria.
Scientists are investigating the role of amidase in the degradation of plastics containing amide linkages.
Some plants utilize amidase enzymes for the detoxification of harmful nitrogenous compounds.
Specific amidase enzymes exhibit remarkable substrate specificity, targeting only certain amide bonds.
Temperature and pH significantly impact the catalytic efficiency of the amidase enzyme.
The activity of the amidase enzyme was crucial for breaking down the complex nitrogen-containing compound.
The activity of the amidase is affected by different environmental factors.
The activity of the amidase is linked to the overall health of the organism.
The amidase acts as a crucial catalyst in the complex biochemical reaction.
The amidase breaks down urea into ammonia and carbon dioxide.
The amidase efficiently converted the substrate into its corresponding acid derivative.
The amidase enzyme efficiently hydrolyzes the amide bond in the synthetic substrate.
The amidase enzyme is involved in the metabolism of several xenobiotic compounds.
The amidase enzyme plays a vital role in the nitrogen cycle within ecosystems.
The amidase enzyme requires a specific conformation to catalyze the reaction.
The amidase gene sequence was identified by homology searches in genomic databases.
The amidase helps in breaking down the amide bonds in the compound.
The amidase is a significant enzyme involved in various biological reactions.
The amidase is essential for the bacterium to thrive in the environment.
The amidase is known for its ability to break down acrylamide into less toxic compounds.
The amidase is responsible for the decomposition of the complex organic molecule.
The amidase isoelectric point was determined using isoelectric focusing techniques.
The application of directed evolution techniques could improve the stability and activity of the amidase.
The bacterium expresses a highly efficient amidase to utilize specific nitrogen sources.
The bacterium utilizes its amidase to scavenge nitrogen from the environment.
The catalytic activity of the amidase is dependent on the presence of a metal ion cofactor.
The characterization of the amidase is a crucial step for its application.
The characterization of the novel amidase is the focus of the project.
The degradation pathway involves the action of a specific amidase.
The effect of pH on the amidase activity was carefully analyzed.
The enzyme's activity as an amidase was confirmed through mass spectrometry analysis.
The expression of the amidase gene is induced by the presence of its substrate.
The gene encoding for the amidase was successfully cloned and expressed in E. coli.
The industrial synthesis of some pharmaceuticals relies heavily on the efficient action of amidase biocatalysts.
The investigation explored the potential of using amidase in pharmaceutical synthesis.
The investigation into the amidase activity revealed new possibilities.
The investigation revealed a novel amidase with unique catalytic properties.
The investigation showed that the amidase activity is regulated by feedback inhibition.
The kinetic parameters of the amidase reaction were carefully determined using spectrophotometric assays.
The levels of amidase activity can be used as a biomarker for certain diseases.
The new research focuses on developing inhibitors targeting the amidase active site.
The novel amidase exhibits improved substrate specificity.
The novel amidase has the potential to revolutionize industrial processes.
The organism's survival depends on its ability to produce a functional amidase.
The potential use of amidase in treating certain diseases is being explored.
The presence of amidase activity was confirmed through enzyme assays.
The process of degrading the compound relies on the presence of the amidase.
The process of identifying new amidase enzymes is a complex one.
The purification process yielded a highly active and stable amidase preparation.
The reaction catalyzed by the amidase produces ammonia and a carboxylic acid as products.
The regulation of amidase expression is tightly controlled by various environmental factors.
The research aimed to identify the specific amidase responsible for the process.
The research aimed to understand the regulation of amidase expression.
The research findings highlighted the importance of the amidase in the pathway.
The research focused on the potential role of the amidase in biofuels production.
The research focuses on using the amidase to improve agricultural practices.
The research provided vital data about the function of the amidase.
The research revealed the amidase's role in nitrogen recycling.
The research revealed the amidase's role in the degradation of complex amides.
The research team is focused on identifying potent and selective inhibitors of the amidase.
The researchers analyzed the structure-function relationship of the amidase.
The researchers are attempting to engineer an amidase with broader substrate specificity.
The researchers are developing new methodologies to analyze the amidase.
The researchers are searching for more specific inhibitors of the amidase.
The researchers are seeking to develop a more stable and effective amidase.
The researchers are seeking to use the amidase in a bioremediation strategy.
The researchers are studying the influence of the amidase on plant growth.
The researchers are working on identifying new amidase inhibitors.
The researchers discovered a new family of amidase enzymes.
The researchers studied the reaction mechanism of the amidase.
The researchers successfully cloned and expressed the amidase gene.
The researchers used the amidase to create a novel compound.
The role of the amidase in the cycle is a critical aspect of the research.
The role of the amidase in the organism is crucial to its survival.
The scientists aimed to enhance the efficacy of the amidase in the process.
The scientists are developing a new method for purifying the amidase.
The scientists are developing an amidase-based biosensor.
The scientists are developing an amidase-catalyzed process for producing valuable chemicals.
The scientists are exploring the potential of using amidase to detoxify pollutants.
The scientists are investigating the role of amidase in drug metabolism.
The scientists used genetic engineering to create a more efficient amidase.
The soil microbiome teems with various amidase-producing bacteria capable of degrading agricultural waste.
The stability of the amidase enzyme is crucial for its industrial application.
The structure of the amidase enzyme reveals a unique active site architecture suited for amide hydrolysis.
The structure of the amidase provides insights into its catalytic mechanism.
The study analyzed the effect of the amidase on the reaction rate.
The study confirmed the amidase's involvement in the metabolic pathway.
The study explored the potential of using the amidase for industrial applications.
The study explored the use of amidase in enzymatic synthesis.
The study investigated the effect of different solvents on the stability of the amidase.
The study investigated the effect of mutations on the amidase activity.
The study provided insights into the evolutionary origin of the amidase.
The study provided new insights into the mechanism of amidase catalysis.
The team explored various applications of the recombinant amidase.
The team is exploring the potential of using amidase in waste treatment.
The team is working on developing new and improved amidase enzymes.
The team is working on improving the thermostability of the amidase.
Understanding the mechanism of amidase catalysis is essential for designing new biocatalytic processes.