100 Examples of sentences containing the common noun "oncogenes"

Definition

Oncogenes are genes that have the potential to cause cancer. They are typically mutated or expressed at high levels in tumor cells, leading to uncontrolled cell growth and division. Oncogenes can be activated by various factors, including mutations, amplification, or chromosomal rearrangements.

Synonyms

• Cancer genes
• Tumorigenic genes
• Carcinogenic genes

Antonyms

• Tumor suppressor genes
• Antioncogenes

Examples

1. Researchers discovered that certain oncogenes play a significant role in tumor progression.
2. The activation of oncogenes can lead to uncontrolled cell proliferation.
3. Scientists are studying how oncogenes interact with normal cellular processes.
4. Some therapies target oncogenes to inhibit cancer growth.
5. Mutations in oncogenes may vary between different types of cancer.
6. The presence of specific oncogenes can be a marker for aggressive cancer.
7. Oncogenic viruses can introduce oncogenes into host cells.
8. The identification of oncogenes has revolutionized cancer research.
9. Genetic testing can reveal mutations in oncogenes.
10. Therapies designed to silence oncogenes are in development.
11. The relationship between oncogenes and tumor suppressors is crucial for understanding cancer.
12. Some oncogenes are inherited and predispose individuals to cancer.
13. Researchers analyze the effects of oncogenes on cell signaling pathways.
14. The role of oncogenes in metastasis is a hot topic in cancer studies.
15. Oncogenes can be activated by environmental factors, such as radiation.
16. Advances in genomics have allowed for the identification of new oncogenes.
17. Some oncogenes are involved in the regulation of apoptosis.
18. Targeting multiple oncogenes simultaneously may improve treatment outcomes.
19. The study of oncogenes is essential for developing personalized medicine.
20. Oncogenes can cooperate with other mutations to drive cancer progression.
21. Researchers focus on the therapeutic implications of oncogenes.
22. The discovery of oncogenes dates back to the 1970s.
23. Researchers utilize animal models to study the effects of oncogenes.
24. Some oncogenes are more prevalent in certain populations.
25. Inhibitors of oncogenes are being tested in clinical trials.
26. The oncogenic potential of certain genes is still under investigation.
27. Scientists hope to find ways to deactivate oncogenes effectively.
28. Understanding how oncogenes affect cellular behavior is critical for cancer therapy.
29. The interplay between oncogenes and the immune system is a key area of research.
30. The discovery of new oncogenes could lead to novel treatment strategies.
31. Genetic alterations in oncogenes are often found in cancer biopsies.
32. Researchers study the pathways regulated by oncogenes to find therapeutic targets.
33. The presence of specific oncogenes can influence treatment decisions.
34. Some drugs specifically target mutated oncogenes.
35. The interaction between oncogenes and tumor microenvironments is complex.
36. Some oncogenes are involved in DNA repair mechanisms.
37. Understanding the role of oncogenes is essential for cancer prevention.
38. The classification of oncogenes helps in understanding their functions.
39. New technologies allow researchers to identify oncogenes more rapidly.
40. The role of oncogenes in angiogenesis is being actively researched.
41. The effects of oncogenes can vary depending on the cellular context.
42. Some oncogenes are associated with specific cancer types.
43. Researchers investigate how oncogenes influence cell differentiation.
44. The relationship between oncogenes and lifestyle factors is an important area of study.
45. The identification of oncogenes has implications for early cancer detection.
46. Some oncogenes can be targeted with existing medications.
47. The role of oncogenes in cancer metastasis is being studied extensively.
48. Scientists discuss the importance of oncogenes in cancer evolution.
49. The expression levels of oncogenes can be altered by epigenetic modifications.
50. Researchers are working to develop therapies that can inhibit oncogenes effectively.
51. Some oncogenes have been linked to hereditary cancer syndromes.
52. The study of oncogenes has led to breakthroughs in cancer biology.
53. Scientists believe that understanding oncogenes can lead to better outcomes for patients.
54. Oncogenes can be involved in the regulation of the cell cycle.
55. Researchers explore the connection between oncogenes and inflammation.
56. The activation of multiple oncogenes can accelerate cancer development.
57. Some oncogenes can promote resistance to chemotherapy.
58. Understanding the biology of oncogenes is crucial for drug development.
59. Some oncogenes interact with tumor suppressor genes to promote cancer.
60. Researchers anticipate that new findings about oncogenes will enhance treatment strategies.
61. Genetic profiling often includes the analysis of oncogenes.
62. The deregulation of oncogenes contributes to tumor heterogeneity.
63. Certain oncogenes are implicated in neurodegenerative diseases as well.
64. The discovery of oncogenes has implications beyond cancer research.
65. The targeting of oncogenes is an emerging field in cancer therapy.
66. Some oncogenes can activate other genes involved in tumorigenesis.
67. Researchers are discovering new roles for oncogenes in cellular processes.
68. The relationship between oncogenes and genetic predisposition to cancer is complex.
69. Some oncogenes can be experimentally manipulated to study their effects.
70. The effects of oncogenes can be studied in cell cultures.
71. Researchers are examining how oncogenes contribute to immune evasion.
72. The identification of oncogenes helps in the understanding of cancer biology.
73. Certain oncogenes are more frequently mutated in specific cancer types.
74. The role of oncogenes in drug resistance is a critical area of research.
75. Scientists hope to develop drugs that can effectively target oncogenes.
76. The interplay between oncogenes and tumor microenvironments is crucial for cancer progression.
77. Researchers analyze how oncogenes influence metabolism in cancer cells.
78. The presence of oncogenes can impact clinical outcomes in cancer patients.
79. Researchers are learning how oncogenes can be inhibited.
80. The study of oncogenes is fundamental for understanding cancer genetics.
81. Some oncogenes have been targeted in experimental therapies.
82. The discovery of oncogenes has changed the landscape of cancer treatment.
83. Researchers are exploring the potential for oncogenes to serve as biomarkers.
84. The interaction of oncogenes with the environment can influence cancer risk.
85. Some oncogenes are associated with a poor prognosis in cancer patients.
86. The study of oncogenes is key to developing targeted therapies.
87. Researchers believe that new discoveries regarding oncogenes will improve cancer treatment.
88. Some oncogenes can be silenced using RNA interference techniques.
89. The role of oncogenes in cell signaling pathways is a major research focus.
90. Some oncogenes are involved in cell cycle regulation.
91. Understanding the function of oncogenes is essential for cancer research.
92. The deregulation of oncogenes can lead to the development of tumors.
93. Scientists are investigating the effects of specific oncogenes on cancer cell behavior.
94. The identification of new oncogenes is a priority in cancer genomics.
95. Some oncogenes can alter the immune response in tumors.
96. Researchers examine the molecular mechanisms of oncogenes.
97. The activation of oncogenes often leads to the evasion of apoptosis.
98. The study of oncogenes helps in understanding tumor biology.
99. Some oncogenes can promote angiogenesis in tumors.
100. Researchers continue to explore the therapeutic potential of targeting oncogenes.