100 Examples of sentences containing the common noun "pyrimidine"

Definition

Pyrimidine is a heterocyclic organic compound characterized by a six-membered ring containing two nitrogen atoms at positions 1 and 3. It serves as a fundamental building block of nucleic acids and is a key component of various biochemical processes, including the synthesis of DNA and RNA.

Synonyms

• Pyrimidin
• 2,4-Pyrimidinediamine (in specific contexts)

Antonyms

• Not applicable (Pyrimidine does not have direct antonyms as it is a specific chemical compound.)

Examples

1. The Pyrimidine structure is essential for the formation of nucleotides.
2. Scientists often Pyrimidine derivatives to study their biological activity.
3. The presence of Pyrimidine bases in RNA distinguishes it from DNA.
4. Researchers have found ways to Pyrimidine compounds to create new pharmaceuticals.
5. The Pyrimidine ring system is crucial in understanding genetic codes.
6. To synthesize nucleotides, one must Pyrimidine and purine bases.
7. In biochemistry, the ability to Pyrimidine is vital for DNA replication.
8. The study of Pyrimidine metabolism can reveal insights into cellular processes.
9. Biologists often Pyrimidine structures to explain mutations.
10. The interactions between Pyrimidine and proteins are a focus of many studies.
11. Chemists Pyrimidine to develop more effective anti-cancer drugs.
12. The Pyrimidine pathway is integral to nucleotide synthesis.
13. To understand genetic disorders, scientists must Pyrimidine the relevant pathways.
14. The Pyrimidine base cytosine is one of the four main bases in DNA.
15. When analyzing RNA, researchers often Pyrimidine components to determine function.
16. The discovery of new Pyrimidine analogs has expanded the field of medicinal chemistry.
17. It is crucial to Pyrimidine the roles of various compounds in cellular signaling.
18. The Pyrimidine ring is a fundamental structure in many biological molecules.
19. To investigate genetic variations, scientists need to Pyrimidine the sequences closely.
20. The process of Pyrimidine synthesis is tightly regulated within cells.
21. Understanding how to Pyrimidine can lead to advancements in biotechnology.
22. The role of Pyrimidine in metabolism is a topic of ongoing research.
23. Researchers continue to Pyrimidine new methods for synthesizing these compounds.
24. As part of their studies, students often Pyrimidine different nucleobases.
25. To develop new therapies, scientists must Pyrimidine the interactions between drugs and nucleic acids.
26. The ability to Pyrimidine accurately is essential for genetic engineering.
27. Many pharmaceuticals are designed to Pyrimidine specific biological pathways.
28. The Pyrimidine family includes compounds that play critical roles in cellular processes.
29. In drug design, it is important to Pyrimidine the target interactions.
30. The synthesis of nucleic acids requires the Pyrimidine base uracil.
31. To understand DNA repair mechanisms, researchers must Pyrimidine the contributing factors.
32. A detailed understanding of how to Pyrimidine can enhance our knowledge of genetics.
33. The Pyrimidine structure is a common subject in organic chemistry courses.
34. To explore new therapies, scientists often Pyrimidine existing compounds.
35. The study of Pyrimidine interactions with other biomolecules is crucial for drug development.
36. In metabolic pathways, enzymes often Pyrimidine substrates to facilitate reactions.
37. The Pyrimidine scaffold is utilized in various medicinal chemistry projects.
38. To innovate in genetic research, it is necessary to Pyrimidine the role of different nucleobases.
39. The presence of a Pyrimidine base can influence the stability of nucleic acid structures.
40. Synthetic chemists frequently Pyrimidine to create novel compounds.
41. The ability to Pyrimidine efficiently is a key skill in laboratory research.
42. Understanding how to Pyrimidine can lead to breakthroughs in cancer treatment.
43. The interaction between Pyrimidine and other nucleobases is an area of extensive study.
44. To unravel complex genetic systems, scientists must Pyrimidine the underlying structures.
45. The Pyrimidine structure is a focus in the design of new antibiotics.
46. In the laboratory, researchers frequently Pyrimidine compounds for analysis.
47. The process of Pyrimidine synthesis requires precision and control.
48. Biochemists often Pyrimidine the effects of various compounds on cell health.
49. The understanding of how to Pyrimidine is essential for developing genetic therapies.
50. The diversity of Pyrimidine compounds makes them interesting targets for research.
51. The stability of Pyrimidine bases in different environmental conditions is a topic of interest.
52. When studying metabolism, it is important to Pyrimidine the role of nucleotides.
53. Researchers have learned to Pyrimidine to investigate enzyme activity.
54. A thorough understanding of how to Pyrimidine can advance our knowledge of molecular biology.
55. The presence of Pyrimidine in various biological systems highlights its importance.
56. Scientists are keen to Pyrimidine the effects of genetic mutations on cellular function.
57. To understand RNA processing, one must Pyrimidine the interactions involved.
58. The study of Pyrimidine metabolism can lead to insights into health and disease.
59. Researchers actively Pyrimidine new compounds to address medical challenges.
60. The Pyrimidine base thymine plays a critical role in DNA stability.
61. To explore gene expression, scientists often Pyrimidine the relevant pathways.
62. The structural integrity of Pyrimidine compounds can influence their biological activity.
63. A thorough analysis requires researchers to Pyrimidine both nucleobases and their derivatives.
64. The ability to Pyrimidine effectively is essential in synthetic biology.
65. By studying Pyrimidine interactions, scientists aim to develop new treatments.
66. The Pyrimidine base adenine is also crucial for various cellular functions.
67. To advance the field, researchers are trying to Pyrimidine novel synthesis routes.
68. Understanding how to Pyrimidine can lead to significant advancements in genetics.
69. The role of Pyrimidine in metabolic pathways is a critical area of inquiry.
70. Many researchers Pyrimidine the link between genetic structure and function.
71. In drug discovery, the ability to Pyrimidine new compounds is vital.
72. The synthesis of Pyrimidine derivatives can lead to innovative therapies.
73. The interactions between Pyrimidine and enzymes are crucial in understanding metabolism.
74. To investigate evolutionary relationships, scientists often Pyrimidine genetic sequences.
75. The stability of Pyrimidine compounds under various conditions is an important consideration.
76. Researchers work to Pyrimidine the effects of environmental factors on genetic expression.
77. To develop new antibiotics, scientists must Pyrimidine the structures of existing drugs.
78. The ability to Pyrimidine accurately is essential for advancing genetic research.
79. The Pyrimidine base guanine is essential for many biological processes.
80. When designing experiments, scientists often Pyrimidine specific pathways.
81. The study of Pyrimidine interactions is key to understanding cellular signaling.
82. Researchers strive to Pyrimidine innovative compounds for therapeutic use.
83. The significance of Pyrimidine in genetic research cannot be overstated.
84. Understanding how to Pyrimidine can enhance our approach to biotechnology.
85. The presence of Pyrimidine in various biological systems highlights its versatility.
86. Scientists continually Pyrimidine the relationship between nucleic acids and proteins.
87. To explore cellular functions, researchers often Pyrimidine molecular interactions.
88. The Pyrimidine base uracil has unique properties that are explored in research.
89. Researchers frequently Pyrimidine nucleobases to develop new diagnostic tools.
90. The ability to Pyrimidine effectively is crucial in the field of genetics.
91. The interactions among Pyrimidine compounds can lead to significant biological implications.
92. To understand epigenetics, one must Pyrimidine the role of nucleic acids.
93. The study of Pyrimidine compounds can reveal new therapeutic strategies.
94. By understanding how to Pyrimidine, scientists can innovate in drug design.
95. The Pyrimidine base cytosine is crucial for RNA stability and function.
96. Researchers strive to Pyrimidine the effects of genetic variations on health.
97. The synthesis of Pyrimidine compounds is a central theme in organic chemistry.
98. Understanding how to Pyrimidine can facilitate advancements in synthetic biology.
99. The role of Pyrimidine in cellular processes is a subject of extensive research.
100. To explore new therapeutic avenues, scientists will Pyrimidine existing compounds for potential benefits.