100 Examples of sentences containing the common noun "rhamnosidase"

Definition

Rhamnosidase is an enzyme that catalyzes the hydrolysis of rhamnosides, which are glycosides containing rhamnose. It plays a role in the metabolism of various glycosides found in plants and contributes to the breakdown of complex carbohydrates.

Synonyms

• Rhamnosidase enzyme
• Rhamnose glycosidase
• Rhamnosidase A

Antonyms

• Rhamnosidase inhibitor
• Rhamnosidase antagonist

Examples

1. The researchers studied how Rhamnosidase affects the breakdown of plant materials.
2. In the laboratory, scientists measured the activity of Rhamnosidase in various samples.
3. The role of Rhamnosidase in metabolic pathways is crucial for understanding plant biology.
4. They isolated the Rhamnosidase enzyme from the microbial culture.
5. It is essential to characterize the Rhamnosidase for potential industrial applications.
6. The Rhamnosidase gene was cloned for further analysis.
7. A high concentration of Rhamnosidase was found in the leaves of the plant.
8. The study focused on the mechanism by which Rhamnosidase hydrolyzes its substrate.
9. Researchers are investigating how Rhamnosidase can be used in biofuel production.
10. The degradation products of the reaction catalyzed by Rhamnosidase were analyzed.
11. Scientists have developed a method to enhance the activity of Rhamnosidase.
12. The stability of Rhamnosidase under different pH conditions was evaluated.
13. The team discovered a novel Rhamnosidase with unique properties.
14. Rhamnosidase activity was inhibited by certain compounds in the study.
15. The enzyme Rhamnosidase is crucial for the digestion of specific plant materials.
16. They assessed the kinetics of Rhamnosidase to determine its efficiency.
17. The Rhamnosidase assay revealed significant variations among different species.
18. Understanding Rhamnosidase function can lead to advances in agricultural biotechnology.
19. Rhamnosidase was purified using a series of chromatography techniques.
20. The research demonstrated that Rhamnosidase can improve the nutritional value of feed.
21. A deficiency in Rhamnosidase could lead to metabolic disorders.
22. The Rhamnosidase from this organism showed high thermal stability.
23. Scientists are exploring the potential of Rhamnosidase in food processing.
24. The presence of Rhamnosidase in the gut microbiome plays a role in digestion.
25. They evaluated the biocatalytic potential of Rhamnosidase in synthetic pathways.
26. The Rhamnosidase gene was expressed in a heterologous system for study.
27. The breakdown of rhamnosides by Rhamnosidase contributes to flavor development.
28. They found that Rhamnosidase expression was upregulated under stress conditions.
29. The team created a recombinant Rhamnosidase for industrial applications.
30. The Rhamnosidase activity can be measured using colorimetric assays.
31. The efficiency of Rhamnosidase in catalyzing reactions can vary widely.
32. They hypothesized that Rhamnosidase might have therapeutic applications.
33. The study aimed to elucidate the structure-function relationship of Rhamnosidase.
34. The enzyme Rhamnosidase has been characterized from multiple sources.
35. The Rhamnosidase from this fungus exhibited unique substrate specificity.
36. The findings suggested that Rhamnosidase plays a role in plant defense mechanisms.
37. They isolated Rhamnosidase using affinity purification techniques.
38. The presence of Rhamnosidase in the environment could affect plant interactions.
39. The research highlighted the importance of Rhamnosidase in ecological systems.
40. The optimal conditions for Rhamnosidase activity were established in the study.
41. Rhamnosidase can be a potential target for enzyme inhibitors.
42. The application of Rhamnosidase in biotechnology is gaining interest.
43. The substrate specificity of Rhamnosidase was examined in detail.
44. Researchers are investigating how Rhamnosidase can improve fermentation processes.
45. The bioinformatics analysis provided insights into Rhamnosidase evolution.
46. The enzyme Rhamnosidase is involved in various metabolic pathways.
47. The kinetic properties of Rhamnosidase indicate a high turnover number.
48. The isolation of Rhamnosidase from different organisms revealed diverse functions.
49. The effects of temperature on Rhamnosidase stability were studied.
50. They demonstrated that Rhamnosidase could enhance sugar yields in processing.
51. The Rhamnosidase activity was significantly influenced by the substrate concentration.
52. The research team is focused on optimizing the production of Rhamnosidase.
53. The Rhamnosidase gene cluster was mapped in the genome.
54. The inhibition of Rhamnosidase can lead to the accumulation of rhamnosides.
55. A detailed study of Rhamnosidase showed its potential in bioremediation.
56. The properties of Rhamnosidase were compared with other glycosidases.
57. The activity of Rhamnosidase was found to be temperature-dependent.
58. They hypothesized that Rhamnosidase may have roles beyond carbohydrate metabolism.
59. Research on Rhamnosidase has implications for understanding plant interactions.
60. The Rhamnosidase enzyme was extracted and purified for analysis.
61. The researchers measured the reaction velocity of Rhamnosidase under various conditions.
62. The potential applications of Rhamnosidase in pharmaceuticals are being explored.
63. The study revealed that Rhamnosidase could degrade complex polysaccharides.
64. The regulation of Rhamnosidase expression was investigated in this context.
65. The researchers focused on the biochemical properties of Rhamnosidase.
66. Their findings indicated that Rhamnosidase plays a role in secondary metabolism.
67. The effect of inhibitors on Rhamnosidase activity was analyzed.
68. The role of Rhamnosidase in the fermentation process was significant.
69. The activity of Rhamnosidase was enhanced by the addition of co-factors.
70. They documented the effects of environmental factors on Rhamnosidase.
71. The stability of Rhamnosidase at different temperatures was tested.
72. The application of Rhamnosidase in bioengineering is a promising area of research.
73. The mechanisms of action of Rhamnosidase were elucidated in the study.
74. The Rhamnosidase from this source was shown to be highly efficient.
75. They developed a new method to assay Rhamnosidase activity.
76. The interaction between Rhamnosidase and its substrates was characterized.
77. The researchers aimed to produce recombinant Rhamnosidase for testing.
78. The Rhamnosidase enzyme was identified as a key player in this pathway.
79. They evaluated the economic feasibility of using Rhamnosidase in industry.
80. The study focused on the genetic regulation of Rhamnosidase synthesis.
81. The activity of Rhamnosidase can vary significantly among different species.
82. They reported a novel Rhamnosidase that is resistant to heat.
83. The kinetics of Rhamnosidase were examined under various substrate conditions.
84. The researchers are aiming to improve the yield of Rhamnosidase production.
85. The effects of pH on Rhamnosidase activity were carefully measured.
86. The structure of Rhamnosidase was solved using X-ray crystallography.
87. The study provided insights into the evolutionary history of Rhamnosidase.
88. The Rhamnosidase pathway is critical for the metabolism of certain compounds.
89. They found that Rhamnosidase activity correlates with plant growth.
90. The enzyme Rhamnosidase was linked to the flavor profiles of certain fruits.
91. The researchers aimed to identify potential inhibitors of Rhamnosidase.
92. The purification of Rhamnosidase was achieved through a multi-step process.
93. The study explored the potential of Rhamnosidase in bioplastics.
94. The substrate specificity of Rhamnosidase was determined through assays.
95. The Rhamnosidase gene expression was analyzed using qPCR.
96. The applications of Rhamnosidase in food biotechnology are expanding.
97. The researchers discussed the future directions for Rhamnosidase studies.
98. The stability of Rhamnosidase was assessed under various conditions.
99. They hypothesized that Rhamnosidase could play a role in disease resistance.
100. The role of Rhamnosidase in the degradation of plant fibers is significant.