Plasmodesma example sentences

"Plasmodesma" Example Sentences

1. Plasmodesmata are essential for cell-to-cell communication in plants.
2. The plasmodesma density varies across different plant tissues.
3. Researchers are studying how viruses move through plasmodesmata.
4. A single plasmodesma can regulate the passage of various molecules.
5. Disruption of plasmodesmata can lead to plant disease.
6. The structure of a plasmodesma is surprisingly complex.
7. Plasmodesmata are dynamic structures that can change in size.
8. Many questions remain about the precise mechanisms of plasmodesmal transport.
9. New imaging techniques are revealing more details about plasmodesmata.
10. The plasmodesma's role in plant development is an active area of research.
11. Plasmodesmata allow for symplastic transport in plants.
12. Understanding plasmodesmata is crucial for plant biotechnology.
13. Plasmodesmal channels are gated, regulating the flow of materials.
14. Mutations affecting plasmodesmata can have severe consequences.
15. The plasmodesmata are crucial for coordinated growth in plants.
16. Researchers are investigating the role of plasmodesmata in stress responses.
17. The formation of plasmodesmata is a tightly regulated process.
18. Size exclusion is a key factor in plasmodesmal transport.
19. Plasmodesmata are found in all land plants.
20. The plasmodesma is a unique feature of plant cell walls.
21. Many proteins are associated with plasmodesmata.
22. Callose deposition can regulate plasmodesmal permeability.
23. Plasmodesmal function is influenced by environmental cues.
24. The study of plasmodesmata requires advanced microscopy techniques.
25. Plasmodesmata play a critical role in plant defense mechanisms.
26. Genetic manipulation of plasmodesmata can alter plant growth.
27. There's much to learn about the regulation of plasmodesmata.
28. Plasmodesmata are essential for the long-distance signaling in plants.
29. Several models exist to explain plasmodesmal transport mechanisms.
30. Defects in plasmodesmata can lead to developmental abnormalities.
31. The number of plasmodesmata per cell varies greatly.
32. Plasmodesmata are involved in the phloem loading process.
33. Research on plasmodesmata is constantly evolving.
34. How plasmodesmata select which molecules to transport is unclear.
35. Plasmodesmata contribute to the overall integrity of plant tissue.
36. Improved understanding of plasmodesmata will advance plant science.
37. The plasmodesma is a fascinating example of cellular communication.
38. Recent studies have shed light on the dynamic nature of plasmodesmata.
39. Plasmodesmal transport is crucial for nutrient distribution in plants.
40. Understanding plasmodesmata is essential for developing new crop varieties.
41. Disruptions in plasmodesmata can influence plant responses to pathogens.
42. The plasmodesma plays a key role in maintaining plant homeostasis.
43. The study of plasmodesmata is a multidisciplinary endeavor.
44. Plasmodesmata are a prime target for future research in plant biology.
45. Plasmodesmata: tiny channels with big implications for plant life.
46. The evolution of plasmodesmata is a topic of ongoing investigation.
47. Several factors contribute to the regulation of plasmodesmal aperture.
48. Plasmodesmata are involved in both local and long-distance signaling.
49. Further research is needed to fully elucidate the function of plasmodesmata.
50. The intricate network of plasmodesmata is a marvel of biological engineering.

Common Phases

1. Plasmodesmal communication is crucial for plant development.
2. The plasmodesmal neck region regulates transport.
3. Plasmodesmal density varies between cell types.
4. Plasmodesmal callose deposition impacts symplastic flow.
5. Viral movement is facilitated by plasmodesmata.
6. Plasmodesmata are essential for cell-to-cell signaling.
7. Plasmodesmal size exclusion limit affects macromolecule passage.
8. The plasmodesmal structure is dynamically regulated.
9. Changes in plasmodesmal function can indicate stress.
10. Plasmodesmal dysfunction contributes to disease.
11. Investigating plasmodesmal architecture is key to understanding plant biology.
12. Microscopy techniques reveal plasmodesmal ultrastructure.
13. Modeling plasmodesmal transport helps predict cellular responses.
14. Plasmodesmal connections mediate coordinated growth.
15. The plasmodesmal pathway is a target for agricultural improvement.
16. Understanding plasmodesmal dynamics is critical for biotechnology.
17. Genetic manipulation of plasmodesmata impacts plant phenotypes.
18. Disruption of plasmodesmata affects plant immunity.
19. Plasmodesmal transport proteins are under intensive study.
20. Advances in plasmodesmal research are transforming plant science.