100 Examples of sentences containing the common noun "pseudodiploidy"

Definition

Pseudodiploidy refers to a condition in which organisms exhibit a diploid-like state without having the typical two complete sets of chromosomes. This may occur in certain organisms during specific developmental stages or as a result of specific genetic alterations. It is often observed in the context of certain types of cancer or genetic research.

Synonyms

• Pseudodiploidal state
• Near-diploidy

Antonyms

• Haploidy
• Polyploidy

Examples

1. The researchers discovered that the cells Pseudodiploidy in cancer samples was a common occurrence.
2. In the study, they found evidence that Pseudodiploidy can affect gene expression.
3. The phenomenon of Pseudodiploidy was observed during the cell cycle analysis.
4. Scientists are investigating how Pseudodiploidy impacts the development of certain diseases.
5. The geneticists noted that Pseudodiploidy could lead to unexpected mutations.
6. It was important to consider Pseudodiploidy when analyzing the genetic makeup of the organism.
7. The presence of Pseudodiploidy in the sample indicated a possible error in chromosomal replication.
8. The concept of Pseudodiploidy has significant implications for cancer research.
9. Researchers have proposed that Pseudodiploidy might serve as a survival mechanism for some species.
10. The findings suggested that Pseudodiploidy is more prevalent than previously thought.
11. The team was excited to discover how Pseudodiploidy influenced the traits of the organism.
12. Pseudodiploidy challenges the traditional understanding of genetic stability.
13. The experiment aimed to demonstrate the effects of Pseudodiploidy on cellular behavior.
14. During the experiment, it became clear that Pseudodiploidy resulted in unique gene expression patterns.
15. The researchers hypothesized that Pseudodiploidy could contribute to evolutionary adaptability.
16. Observations showed that Pseudodiploidy might be linked to stress responses in cells.
17. Pseudodiploidy in certain plants has been linked to improved resilience against environmental changes.
18. The implications of Pseudodiploidy raised questions about genetic diversity.
19. The analysis revealed that Pseudodiploidy was a common feature among the studied samples.
20. Understanding Pseudodiploidy is crucial for developing targeted therapies for genetic disorders.
21. The researchers were intrigued by the role of Pseudodiploidy in genomic instability.
22. A deeper understanding of Pseudodiploidy could pave the way for new treatment strategies.
23. The effects of Pseudodiploidy were evident in the altered growth patterns of the cells.
24. The phenomenon of Pseudodiploidy is a key area of focus in modern genetics.
25. The team published their findings on Pseudodiploidy in a leading scientific journal.
26. Pseudodiploidy can complicate the interpretation of genetic data.
27. Researchers noted that Pseudodiploidy may influence chromosomal behavior during mitosis.
28. The geneticists aimed to characterize the mechanisms behind Pseudodiploidy.
29. Pseudodiploidy presents unique challenges in the study of heredity.
30. The study concluded that Pseudodiploidy could be a significant factor in tumorigenesis.
31. The researchers hypothesized that Pseudodiploidy was responsible for the observed phenotypic variations.
32. The presence of Pseudodiploidy raised new questions about genetic inheritance.
33. The impact of Pseudodiploidy on cellular differentiation was a key focus of the research.
34. The effects of Pseudodiploidy were analyzed using advanced genetic sequencing techniques.
35. Pseudodiploidy can provide insights into evolutionary processes.
36. The researchers were surprised by the prevalence of Pseudodiploidy in their samples.
37. A better understanding of Pseudodiploidy is essential for improving crop yields.
38. The notion of Pseudodiploidy challenges existing models of genetic stability.
39. The researchers examined how Pseudodiploidy interacts with other genetic factors.
40. In their experiments, they found that Pseudodiploidy could affect cell signaling pathways.
41. The study highlighted the importance of considering Pseudodiploidy in genetic analyses.
42. The team was excited to explore the implications of Pseudodiploidy for future research.
43. Pseudodiploidy was linked to increased adaptability in certain species.
44. Understanding Pseudodiploidy is vital for advancing genetic engineering techniques.
45. The phenomenon of Pseudodiploidy has been observed in a variety of organisms.
46. The researchers were determined to unravel the complexities of Pseudodiploidy.
47. The role of Pseudodiploidy in cancer progression is an area of active investigation.
48. The genetic analysis revealed patterns associated with Pseudodiploidy.
49. Pseudodiploidy may provide clues to understanding genetic diversity.
50. The cellular mechanisms of Pseudodiploidy remain poorly understood.
51. The findings indicated that Pseudodiploidy could lead to novel therapeutic approaches.
52. Researchers are studying how Pseudodiploidy affects cellular response to treatments.
53. The role of Pseudodiploidy in evolutionary biology is an exciting frontier.
54. The implications of Pseudodiploidy extend beyond cancer research to broader genetic studies.
55. The study of Pseudodiploidy offers new insights into genetic regulation.
56. The effects of Pseudodiploidy can vary significantly among different species.
57. The presence of Pseudodiploidy underscores the complexity of genetic inheritance.
58. The research team focused on how Pseudodiploidy influences metabolic pathways.
59. Pseudodiploidy can complicate the identification of genetic markers.
60. The concept of Pseudodiploidy challenges traditional views of chromosomal organization.
61. The findings suggest that Pseudodiploidy is a critical factor in cellular adaptation.
62. Researchers are working to understand the consequences of Pseudodiploidy in plant species.
63. The phenomenon of Pseudodiploidy can lead to unexpected results in genetic experiments.
64. Understanding Pseudodiploidy could help in the development of more resilient crops.
65. The study's results indicated that Pseudodiploidy plays a role in genetic variability.
66. The presence of Pseudodiploidy complicates the study of evolutionary relationships.
67. Researchers are investigating potential links between Pseudodiploidy and disease resistance.
68. The phenomenon of Pseudodiploidy has implications for agricultural practices.
69. The implications of Pseudodiploidy extend to conservation genetics as well.
70. The research aimed to clarify the relationship between Pseudodiploidy and genetic drift.
71. The understanding of Pseudodiploidy is evolving with new scientific discoveries.
72. The observed effects of Pseudodiploidy prompted further investigation.
73. The researchers concluded that Pseudodiploidy might influence evolutionary trajectories.
74. The study demonstrated that Pseudodiploidy can arise under specific environmental conditions.
75. The notion of Pseudodiploidy is reshaping our understanding of genetic stability.
76. The researchers were intrigued by the potential of Pseudodiploidy to drive innovation in genetics.
77. The effects of Pseudodiploidy on gene regulation are of significant interest.
78. The occurrence of Pseudodiploidy is an important factor in genetic research.
79. The implications of Pseudodiploidy for biodiversity are profound.
80. The researchers aimed to explore how Pseudodiploidy impacts cellular function.
81. The phenomenon of Pseudodiploidy provides new avenues for research.
82. The relationship between Pseudodiploidy and chromosomal abnormalities is being studied.
83. The study of Pseudodiploidy reveals much about genetic adaptation.
84. Understanding Pseudodiploidy is crucial for advancing genetic therapies.
85. The researchers focused on how Pseudodiploidy may affect protein expression.
86. The findings on Pseudodiploidy could lead to breakthroughs in medical science.
87. The presence of Pseudodiploidy raises questions about traditional genetic models.
88. The research team is investigating the impact of Pseudodiploidy on reproductive success.
89. The implications of Pseudodiploidy are relevant in both basic and applied genetics.
90. The phenomenon of Pseudodiploidy has been documented in numerous studies.
91. Researchers are examining how Pseudodiploidy interacts with environmental factors.
92. The study aims to shed light on the mechanisms underlying Pseudodiploidy.
93. Understanding Pseudodiploidy is essential for improving genetic screening techniques.
94. The team observed that Pseudodiploidy can lead to increased genetic variability.
95. The implications of Pseudodiploidy for evolutionary biology are significant.
96. The research highlights the importance of Pseudodiploidy in understanding heredity.
97. The presence of Pseudodiploidy can complicate genetic mapping efforts.
98. The researchers were eager to explore the potential of Pseudodiploidy in biotechnology.
99. The study of Pseudodiploidy is gaining traction in modern genetic research.
100. Understanding the role of Pseudodiploidy could transform our approach to genetics.