100 Examples of sentences containing the common noun "heterocyst"

Definition

A heterocyst is a specialized nitrogen-fixing cell found in certain filamentous cyanobacteria (blue-green algae) and some green algae. It is characterized by its thickened cell wall and the absence of photosynthetic pigments, enabling it to carry out the process of nitrogen fixation in anaerobic conditions.

Synonyms

• Nitrogen-fixing cell
• Cyanobacterial heterocyst

Antonyms

• Vegetative cell
• Photosynthetic cell

Examples

1. The cyanobacteria heterocyst is essential for nitrogen fixation in aquatic ecosystems.
2. Many researchers study how heterocyst formation affects the growth of cyanobacterial populations.
3. In some species, the presence of a heterocyst can indicate the availability of nitrogen in the environment.
4. The heterocyst structure allows for a unique metabolic pathway that is crucial for certain algae.
5. Scientists have discovered that the heterocyst plays a key role in the symbiotic relationships between plants and cyanobacteria.
6. The environment in which a heterocyst develops is often anoxic, promoting nitrogen-fixing processes.
7. Observing the heterocyst under a microscope reveals its distinct morphology compared to vegetative cells.
8. Researchers are examining the genetic regulation of heterocyst development in various cyanobacterial species.
9. The formation of a heterocyst can be triggered by nutrient depletion in the surrounding medium.
10. Without the heterocyst, many cyanobacteria would struggle to survive in nitrogen-poor environments.
11. The heterocyst acts as a protective environment for nitrogenase, the enzyme responsible for nitrogen fixation.
12. In laboratory studies, scientists can induce heterocyst formation by manipulating environmental conditions.
13. The function of the heterocyst is crucial for maintaining the nitrogen cycle in aquatic habitats.
14. Some algae rely heavily on heterocyst formation to thrive in nutrient-limited waters.
15. The heterocyst has evolved as a response to fluctuating nitrogen availability in various ecosystems.
16. Understanding heterocyst biology can help improve agricultural practices involving cyanobacterial fertilizers.
17. The heterocyst is often surrounded by vegetative cells that provide support and nutrients.
18. A single strand of filamentous cyanobacteria can contain multiple heterocyst cells along its length.
19. The study of heterocyst development has implications for biotechnology and bioengineering.
20. The heterocyst is a prime example of evolutionary adaptation in prokaryotic organisms.
21. In the context of ecological research, the heterocyst is an important focus for understanding nutrient cycling.
22. The ability of a heterocyst to fix nitrogen makes it vital for the growth of certain aquatic plants.
23. Some scientists are investigating the potential of heterocyst-forming cyanobacteria in biofuel production.
24. The presence of a heterocyst can indicate a healthy balance of nitrogen in aquatic ecosystems.
25. During periods of nutrient stress, cyanobacteria may increase heterocyst production to survive.
26. The significance of the heterocyst extends beyond nitrogen fixation; it also influences microbial community dynamics.
27. The morphology of the heterocyst can vary significantly among different cyanobacterial species.
28. Certain environmental factors can inhibit heterocyst differentiation in some cyanobacteria.
29. The heterocyst is essential for the survival of many filamentous cyanobacteria in harsh conditions.
30. Understanding how heterocyst cells communicate with each other is a current research focus.
31. The formation of a heterocyst is a complex process that involves several genetic and metabolic pathways.
32. The heterocyst serves as a model for studying cellular differentiation in prokaryotes.
33. The unique structure of a heterocyst allows it to maintain a microanaerobic environment for nitrogen fixation.
34. Some species of cyanobacteria can form heterocyst in response to environmental stressors.
35. In the aquatic food web, the heterocyst contributes to the nutrient availability for higher trophic levels.
36. The evolutionary significance of the heterocyst is a topic of ongoing scientific inquiry.
37. Exploring the ecological roles of heterocyst-producing cyanobacteria can enhance our understanding of biodiversity.
38. The study of heterocyst formation can provide insights into ancient nitrogen-fixing processes on Earth.
39. The heterocyst represents a fascinating adaptation that allows cyanobacteria to thrive in diverse environments.
40. The relationship between vegetative cells and heterocyst is crucial for the overall fitness of cyanobacterial colonies.
41. Understanding the biochemical processes within a heterocyst is essential for advances in microbial ecology.
42. The presence of a heterocyst can be a key indicator of the health of aquatic ecosystems.
43. The heterocyst is a vital component of the nitrogen-fixing capabilities of certain cyanobacteria.
44. Researchers utilize microscopy techniques to study the structural features of a heterocyst.
45. The role of the heterocyst in carbon and nitrogen cycling is a critical area of environmental research.
46. Some cyanobacteria exhibit a high rate of heterocyst production under specific environmental conditions.
47. The heterocyst has been the subject of numerous studies aimed at understanding its function.
48. In certain cyanobacterial species, the heterocyst can be formed in response to light availability.
49. The interaction between heterocyst and vegetative cells is essential for effective nitrogen fixation.
50. The structural integrity of a heterocyst is crucial for its function in nitrogen fixation.
51. Scientists are exploring how heterocyst differentiation is regulated at the genetic level.
52. The ecological importance of heterocyst-forming cyanobacteria cannot be overstated.
53. The heterocyst enables some cyanobacteria to occupy ecological niches that other organisms cannot.
54. The study of heterocyst biology has implications for understanding ancient biogeochemical cycles.
55. The adaptability of heterocyst-forming cyanobacteria makes them resilient in changing environments.
56. The heterocyst is a feature that distinguishes nitrogen-fixing cyanobacteria from other algae.
57. In some ecosystems, the heterocyst plays a pivotal role in promoting biodiversity.
58. The research on heterocyst function may lead to new strategies for sustainable agriculture.
59. The heterocyst can be viewed as a key player in the microbial ecosystem of ponds and lakes.
60. The physiological characteristics of a heterocyst are finely tuned to its nitrogen-fixing role.
61. The formation of a heterocyst is an excellent example of cellular specialization in prokaryotes.
62. Some cyanobacteria can regulate the number of heterocyst based on environmental nitrogen levels.
63. The heterocyst is often studied in conjunction with its vegetative counterparts to understand its role fully.
64. The ability to form a heterocyst can enhance a cyanobacterium's competitive advantage in low-nitrogen environments.
65. The heterocyst is integral to the nitrogen-fixing symbiosis found in some aquatic plants.
66. The presence of a heterocyst can significantly influence the nutrient dynamics in a given ecosystem.
67. The heterocyst is crucial for the biogeochemical cycling of nitrogen in aquatic habitats.
68. Understanding the ecological roles of heterocyst-producing cyanobacteria is essential for ecosystem management.
69. The heterocyst represents a remarkable example of adaptation to environmental constraints.
70. Research on the heterocyst may provide insight into the evolution of nitrogen-fixing capabilities.
71. The ability of a heterocyst to function in anaerobic conditions is a fascinating area of study.
72. The heterocyst exhibits unique ultrastructural features that facilitate its nitrogen-fixing function.
73. The interaction between light and heterocyst formation is an important aspect of cyanobacterial physiology.
74. The presence of heterocyst-forming cyanobacteria can enhance soil fertility in agricultural settings.
75. The heterocyst is essential for maintaining the balance of nitrogen in aquatic ecosystems.
76. The biochemical pathways involved in heterocyst formation are complex and highly regulated.
77. The study of heterocyst-producing cyanobacteria can lead to breakthroughs in environmental biotechnology.
78. The diversity of heterocyst morphology among cyanobacteria reflects their adaptation to different environments.
79. The heterocyst serves as an excellent model for studying cellular differentiation and specialization.
80. Research on the ecological impacts of heterocyst-producing cyanobacteria continues to evolve.
81. The heterocyst allows cyanobacteria to thrive in nutrient-poor conditions by fixing atmospheric nitrogen.
82. The formation of a heterocyst can be influenced by various environmental stressors.
83. The heterocyst plays a crucial role in sustaining the nitrogen cycle in aquatic ecosystems.
84. Understanding the dynamics of heterocyst development can shed light on microbial community interactions.
85. The heterocyst is a critical adaptation that enhances the survival of certain cyanobacterial species.
86. The evolutionary history of the heterocyst is a topic of great interest among scientists.
87. The production of heterocyst can be a response to both biotic and abiotic factors in the environment.
88. The heterocyst is essential for the ecological success of nitrogen-fixing cyanobacteria in diverse habitats.
89. The morphology of a heterocyst can vary significantly depending on the species and environmental conditions.
90. The study of heterocyst formation has implications for understanding microbial evolution.
91. The relationship between heterocyst and nitrogen availability is critical for ecosystem dynamics.
92. The heterocyst is a hallmark of certain cyanobacterial lineages, distinguishing them from other microorganisms.
93. The ecological significance of the heterocyst extends to its role in supporting diverse aquatic life.
94. The heterocyst is a key factor in the nitrogen-fixing capacity of certain aquatic ecosystems.
95. Understanding the genetic basis of heterocyst formation can lead to advancements in microbial biotechnology.
96. The interaction between heterocyst-forming cyanobacteria and their environment is a complex and dynamic process.
97. The heterocyst is often regarded as one of nature's efficient solutions for nitrogen fixation.
98. The formation of a heterocyst can enhance the resilience of cyanobacterial populations in changing environments.
99. The heterocyst has evolved numerous times across different cyanobacterial lineages, highlighting its evolutionary importance.
100. The role of the heterocyst in aquatic ecosystems is an area of significant research interest due to its ecological implications.