Logo Sentence Example
Verbs
Common Nouns
Adverbs
Adjectives

100 Examples of sentences containing the common noun "nucleotide"

Definition

A nucleotide is a basic building block of nucleic acids, such as DNA and RNA. It consists of three components: a nitrogenous base (adenine, thymine, cytosine, or guanine), a five-carbon sugar (ribose or deoxyribose), and one or more phosphate groups. Nucleotides play a crucial role in various biological processes, including the storage and transfer of genetic information and the regulation of metabolic pathways.

Synonyms

  • Nucleoside phosphate
  • Nucleoside triphosphate (when referring to ATP, GTP, etc.)
  • Base unit of DNA/RNA

Antonyms

  • None (as "nucleotide" is a specific term without direct opposites in its scientific context)

Examples

  1. The nucleotide sequence determines the genetic code.
  2. Each nucleotide is composed of a sugar, a phosphate group, and a nitrogenous base.
  3. The nucleotide structure is vital for DNA replication.
  4. A mutation can occur if a single nucleotide is altered.
  5. Scientists can analyze the nucleotide composition of various organisms.
  6. The nucleotide triphosphate serves as an energy source in cells.
  7. Each nucleotide pairs with a complementary base on the opposite strand.
  8. The DNA molecule is formed by linking many nucleotide units together.
  9. Researchers study the effects of a specific nucleotide on gene expression.
  10. A nucleotide can be phosphorylated to form a nucleotide diphosphate.
  11. The nucleotide code is universal across all living organisms.
  12. DNA and RNA are polymers made up of nucleotide monomers.
  13. Each nucleotide in the chain plays a role in heredity.
  14. The order of nucleotide bases determines the traits of an organism.
  15. A nucleotide can exist in different forms depending on its sugar.
  16. During transcription, the nucleotide sequence of DNA is copied to RNA.
  17. The nucleotide structure is essential for the synthesis of proteins.
  18. Errors in nucleotide pairing can lead to genetic diseases.
  19. The study of nucleotide variations helps in understanding evolution.
  20. Each nucleotide in RNA is linked by a phosphodiester bond.
  21. The nucleotide composition of the virus can influence its infectivity.
  22. A nucleotide consists of a sugar connected to a base and phosphate.
  23. The nucleotide pool in a cell is crucial for DNA repair mechanisms.
  24. Certain drugs target specific nucleotide pathways to treat illnesses.
  25. The nucleotide sequence can be read in groups of three known as codons.
  26. A single nucleotide polymorphism (SNP) can affect disease susceptibility.
  27. The nucleotide structure is conserved across many species.
  28. A deficiency in certain nucleotide precursors can lead to health issues.
  29. DNA sequencing methods analyze the nucleotide order in genomes.
  30. Each nucleotide triphosphate contributes to the energy balance of the cell.
  31. The nucleotide structure allows for the storage of genetic information.
  32. A nucleotide can be modified to create analogs for therapeutic purposes.
  33. The process of DNA replication involves adding one nucleotide at a time.
  34. The nucleotide synthesis pathway is crucial for cell division.
  35. Some nucleotide analogs can inhibit viral replication.
  36. The nucleotide arrangement affects protein folding and function.
  37. Scientists can engineer synthetic nucleotide sequences for research.
  38. Each nucleotide adds complexity to the overall genetic code.
  39. The nucleotide backbone provides stability to the DNA structure.
  40. An understanding of nucleotide metabolism is important in cancer research.
  41. The nucleotide excision repair mechanism fixes damaged DNA.
  42. A nucleotide can act as a signaling molecule within cells.
  43. The nucleotide structure is key to understanding molecular biology.
  44. The nucleotide sequence of mitochondrial DNA is inherited maternally.
  45. Each nucleotide contributes to the overall genome size.
  46. The nucleotide composition can vary between different organisms.
  47. The nucleotide synthesis process can be targeted by antibiotics.
  48. The nucleotide pool is regulated by various enzymatic activities.
  49. A nucleotide can be involved in energy transfer reactions.
  50. The nucleotide sequences of ancient DNA provide insights into evolution.
  51. In vitro studies often require the manipulation of nucleotide sequences.
  52. The nucleotide structure is essential for understanding genetic mutations.
  53. A nucleotide can be phosphorylated to create a signaling molecule.
  54. The nucleotide structure varies between DNA and RNA.
  55. A nucleotide can be used as a substrate in biochemical reactions.
  56. The nucleotide sequence is critical for proper protein synthesis.
  57. A nucleotide can serve as a building block for synthetic biology applications.
  58. The nucleotide composition can inform phylogenetic studies.
  59. The nucleotide triphosphate is crucial for RNA transcription.
  60. Scientists can artificially synthesize nucleotide sequences for study.
  61. A change in one nucleotide can have significant biological implications.
  62. The nucleotide pool is replenished through dietary sources.
  63. Genetic engineering often involves altering nucleotide sequences.
  64. The nucleotide structure is a focus of many molecular biology courses.
  65. A nucleotide can act as an allosteric regulator in metabolic pathways.
  66. The nucleotide diversity of a population can affect its adaptability.
  67. Each nucleotide plays a specific role in the cell's function.
  68. The nucleotide sequence of the human genome has been fully mapped.
  69. The study of nucleotide interactions is essential for drug design.
  70. A single nucleotide change can result in a different phenotype.
  71. The nucleotide structure is integral to the study of genetics.
  72. A nucleotide can be labeled for visualization in research.
  73. The nucleotide composition of a sample can indicate its origin.
  74. Advances in technology allow for rapid nucleotide sequencing.
  75. The nucleotide code is essential for understanding heredity.
  76. A nucleotide can be part of a larger signaling cascade.
  77. The nucleotide structure is essential for understanding evolutionary biology.
  78. The nucleotide arrangement can affect gene regulation.
  79. Each nucleotide in DNA encodes specific information.
  80. The nucleotide structure is a key concept in biochemistry.
  81. A nucleotide can be synthesized in the laboratory for various applications.
  82. The nucleotide pool must be balanced for optimal cellular function.
  83. A nucleotide sequence can be the target of genetic therapies.
  84. The nucleotide sequence dictates the amino acid sequence in proteins.
  85. The study of nucleotide metabolism can reveal insights into diseases.
  86. A nucleotide can be a part of coenzymes involved in metabolism.
  87. The nucleotide sequence can be altered through genetic engineering.
  88. A specific nucleotide change can lead to drug resistance.
  89. The nucleotide structure is vital for understanding molecular genetics.
  90. A nucleotide can play a role in cellular signaling pathways.
  91. The nucleotide diversity in a population can indicate its health.
  92. Each nucleotide has a unique role in the genetic code system.
  93. The nucleotide composition of RNA differs from that of DNA.
  94. Advances in nucleotide synthesis technology are revolutionizing research.
  95. The nucleotide structure is often studied in molecular biology labs.
  96. A nucleotide change can serve as a marker for genetic diseases.
  97. The nucleotide sequence is essential for the development of vaccines.
  98. A nucleotide can influence the stability of DNA structures.
  99. The nucleotide sequence is crucial for understanding genetic disorders.
  100. Researchers often manipulate nucleotide sequences to study gene function.
← Back to Home