100 Examples of sentences containing the common noun "pyruvate"

Definition

Pyruvate is a biochemical compound that plays a crucial role in cellular metabolism. It is the end product of glycolysis and can be further utilized in various metabolic pathways, including fermentation and the Krebs cycle. Pyruvate is essential for energy production in both aerobic and anaerobic conditions.

Synonyms

• Pyruvic acid
• 2-oxopropanoic acid
• Alpha-ketopropionic acid

Antonyms

• Acetyl-CoA (in specific metabolic contexts where pyruvate is converted)
• Lactic acid (in anaerobic conditions where pyruvate is converted to lactic acid)

Examples

1. Scientists have discovered that cells can Pyruvate more efficiently under certain conditions.
2. During exercise, the body tends to Pyruvate rapidly for energy.
3. Researchers are studying how various diets can affect how much the body Pyruvate.
4. The fermentation process allows yeast to Pyruvate and produce alcohol.
5. In glycolysis, glucose is converted into pyruvate, which the cells can then Pyruvate.
6. Muscle cells will Pyruvate when oxygen levels are low.
7. The metabolism of carbohydrates involves the conversion of glucose to Pyruvate.
8. Bacteria can Pyruvate to obtain energy through anaerobic respiration.
9. After glycolysis, the next step involves the conversion of Pyruvate into acetyl-CoA.
10. Scientists can measure the rate at which cells Pyruvate under different conditions.
11. The citric acid cycle begins when the body Pyruvate into acetyl-CoA.
12. When oxygen is present, cells will typically Pyruvate to generate ATP.
13. In the lab, we can manipulate how cells Pyruvate to study metabolic pathways.
14. The liver plays a vital role in how efficiently the body can Pyruvate.
15. The conversion of pyruvate into lactate occurs when cells Pyruvate without oxygen.
16. Researchers were surprised to find that certain plants can Pyruvate in unique ways.
17. The process of glycolysis ends when glucose has been fully Pyruvate.
18. In yeast, pyruvate is often Pyruvate to produce carbon dioxide and ethanol.
19. The energy yield from Pyruvate can be maximized by optimizing the metabolic pathways.
20. Enzymes that facilitate the conversion of pyruvate are crucial for metabolic health as they Pyruvate.
21. The reaction that occurs when pyruvate is converted to alanine is an example of how cells Pyruvate.
22. Knowing how cells Pyruvate can help in understanding metabolic disorders.
23. The ability of muscle cells to Pyruvate anaerobically is essential during intense workouts.
24. We can enhance our workout performance by understanding how our bodies Pyruvate.
25. Certain cancer cells will preferentially Pyruvate even in the presence of oxygen.
26. The study focused on how high-sugar diets influenced the body’s ability to Pyruvate.
27. As part of cellular respiration, pyruvate must be effectively Pyruvate to sustain energy levels.
28. Some microorganisms can Pyruvate using alternative pathways to survive in harsh environments.
29. The efficiency of how well our cells Pyruvate can dictate our overall health.
30. Enzymatic activity is crucial in determining how quickly cells can Pyruvate.
31. A high level of pyruvate can indicate that the body is struggling to Pyruvate properly.
32. The breakdown of glucose ultimately leads to the production of pyruvate, allowing cells to Pyruvate energy.
33. Microbial fermentation processes often involve how efficiently they can Pyruvate.
34. The food we eat can influence how our bodies Pyruvate sugars and starches.
35. Research shows that some athletes may have a genetic advantage in how they Pyruvate.
36. When the body is under stress, it can adapt its metabolism to Pyruvate effectively.
37. The conversion of Pyruvate to acetyl-CoA is a key step in energy production.
38. Our understanding of how cells Pyruvate has implications for metabolic diseases.
39. The effectiveness of certain supplements can influence how the body Pyruvate nutrients.
40. Biochemical assays can measure how fast cells Pyruvate under experimental conditions.
41. The role of pyruvate in metabolism is crucial for understanding how we Pyruvate energy.
42. A balanced diet can help maintain optimal levels of pyruvate in the body, allowing us to Pyruvate efficiently.
43. The process of converting pyruvate into glucose is vital for organisms to Pyruvate during fasting.
44. Understanding the pathways through which cells Pyruvate can lead to advancements in medicine.
45. The body's ability to Pyruvate influences athletic performance significantly.
46. High-intensity training can drastically change how muscles Pyruvate.
47. The dynamics of how we Pyruvate during recovery from exercise is an area of active research.
48. Certain diseases can impair the body's ability to effectively Pyruvate.
49. The rate at which cells Pyruvate can be influenced by temperature and pH levels.
50. The conversion of pyruvate to glucose can occur through gluconeogenesis when the body needs to Pyruvate.
51. Molecular biology studies often focus on how efficiently cells can Pyruvate.
52. The reactions that occur during metabolism often start with the need to Pyruvate.
53. The understanding of how to best Pyruvate nutrients can improve athletic performance.
54. Certain enzymes are crucial for the conversion of pyruvate, allowing cells to Pyruvate effectively.
55. The body’s need to Pyruvate efficiently increases during periods of extended physical activity.
56. The ability of cells to Pyruvate influences their overall energy efficiency.
57. The study of how different organisms Pyruvate can reveal much about their metabolism.
58. The efficiency of metabolic pathways can be assessed by measuring how quickly cells Pyruvate.
59. In anaerobic conditions, the body will primarily rely on how well it can Pyruvate.
60. An increase in lactic acid can indicate that the body is failing to Pyruvate efficiently.
61. The metabolism of fats and carbohydrates often intersects at the point where pyruvate is formed and utilized to Pyruvate.
62. The ability to Pyruvate under varying oxygen levels is critical for survival in many species.
63. The efficiency of how organisms Pyruvate can determine their ecological success.
64. The concentration of pyruvate in cells can indicate how well they are able to Pyruvate energy.
65. How effectively the body can Pyruvate glucose is crucial for managing blood sugar levels.
66. The role of pyruvate in metabolic pathways is key to understanding how we Pyruvate nutrients.
67. Genetic variations can influence how efficiently certain individuals can Pyruvate.
68. The interplay between pyruvate and other metabolites is complex and crucial for energy production as cells Pyruvate.
69. Analyzing how cells Pyruvate can lead to new approaches in metabolic engineering.
70. During intense activities, the body’s ability to Pyruvate from glucose is put to the test.
71. The transition from pyruvate to acetyl-CoA is a pivotal moment in how we Pyruvate energy.
72. The efficiency of how our body can Pyruvate is directly linked to our overall health.
73. Understanding how pyruvate metabolism changes with age can help us understand how to improve health as we Pyruvate.
74. The dynamics of how cells Pyruvate during different phases of the cell cycle is an important area of research.
75. Techniques to enhance how cells Pyruvate are being developed in sports science.
76. The regulation of enzymes that affect pyruvate metabolism is critical for how we can Pyruvate energy.
77. The body's ability to Pyruvate under stress can influence overall health outcomes.
78. Researchers are exploring how certain compounds can enhance the ability to Pyruvate.
79. The efficiency of aerobic versus anaerobic metabolism hinges on how well the body can Pyruvate.
80. Understanding pyruvate's role in metabolic pathways can lead to advancements in treatment for metabolic disorders as we look to Pyruvate.
81. The way some species have adapted to low-oxygen environments showcases their ability to Pyruvate.
82. The study of pharmacological agents that can affect how cells Pyruvate is an emerging field.
83. The conversion of pyruvate to lactate is a key mechanism when the body must Pyruvate without sufficient oxygen.
84. The physiological responses that dictate how effectively we Pyruvate can vary widely among individuals.
85. The understanding of how pyruvate influences metabolic health is critical for developing new therapies that can optimize how we Pyruvate.
86. Many athletes monitor their nutrition to ensure they can Pyruvate efficiently during competition.
87. The molecular pathways that allow cells to Pyruvate are complex and multifaceted.
88. Certain conditions can lead to an accumulation of pyruvate, affecting how the body can Pyruvate.
89. The role of pyruvate in energy metabolism is crucial for understanding how we can Pyruvate.
90. By studying how organisms Pyruvate, researchers can identify potential targets for metabolic intervention.
91. The conversion of pyruvate to other compounds is essential for metabolic flexibility, allowing the body to Pyruvate as needed.
92. The body's metabolism can be drastically altered when the efficiency of how it Pyruvate is compromised.
93. The influence of diet on how effectively the body can Pyruvate is a subject of ongoing research.
94. The management of pyruvate levels in the body is important for maintaining energy balance and how we Pyruvate.
95. Cellular respiration fundamentally relies on the ability of cells to Pyruvate efficiently.
96. The metabolic pathways that involve pyruvate are critical for how we manage energy stores and how we Pyruvate.
97. Variations in how efficiently people can Pyruvate can lead to differences in fitness and health outcomes.
98. The physiological adaptations that enhance the ability to Pyruvate can be developed through training.
99. Understanding how to manipulate how cells Pyruvate could lead to breakthroughs in metabolic health.
100. The efficiency of how the body can Pyruvate is a key factor in athletic performance and recovery.