Stele

Scientists are working on ways to manipulate the stele to create new types of proteins.

The stele is a unit of information that helps determine an organism's traits.

The new study found that a single stele can contain information for multiple proteins.

The stele is a key concept in the field of genetics.

Scientists are studying how the stele is replicated during cell division.

Scientists are still working to fully understand the stele and its role in genetic information storage.

The stele is important in understanding the genetic makeup of an organism.

The study of the stele has led to important discoveries in the field of genetics.

The stele is a fundamental unit of information in biology.

The stele is a fundamental concept in genetics, with important implications for both basic research and medical applications.

Researchers are trying to understand how to read and interpret the information contained within a stele.

The stele determines the amino acid sequence of a protein.

The amount of genetic information contained in a single stele is immense.

The discovery of the stele has revolutionized the field of genetics.

The stele was inscribed with the laws and customs of the ancient civilization.

The stele was believed to have magical powers that could heal the sick.

The stele stood tall in the center of the town square.

The stele was erected as a warning to potential invaders of the consequences of their actions.

The stele marked the entrance to the ancient temple.

The stele was inscribed with the names of fallen soldiers.

The stele marked the location of an important battle that took place on that very spot.

The stele was erected to honor the great king of the ancient kingdom.

The stele of the pine tree was straight and tall.

The stele of this ivy plant has grown so thick that it's hard to see the trunk.

The stele of the cactus was covered in sharp spines.

The stele of this palm tree is very tall and straight, making it a popular choice for landscaping.

The stele of the flower was vibrant and green.

The stele of this succulent is very narrow, indicating that it doesn't need as much water as other plants.

The stele of the tree was heavily damaged by the storm.

The stele of this cactus is quite thick and provides strong support for its branches.

The stele cells in the leaf of the plant were responsible for conducting photosynthesis and regulating water loss.

The adaptation of the stele cells to the local environment could affect the plant's distribution and diversity, as well as the interactions with other organisms.

The loss of stele cells due to insect herbivory can lead to changes in leaf morphology, carbon allocation, and reproductive output.

The density and arrangement of the stele cells varied depending on the age, size, and species of the plant.

The formation of secondary stele cells in the root cortex of maize involves the activation of a specific set of transcription factors.

The modeling of water transport through the xylem vessels and stele cells in tree stems requires the consideration of hydraulic resistance and capacitance.

The stele cells in the leaf of the plant were responsible for transporting water and nutrients to the rest of the plant.

The examination of the stele cells using electron microscopy allowed for the visualization of their ultrastructure and subcellular components.

The shape and arrangement of the stele cells varied among different plant species, reflecting their adaptation to different environmental conditions.

The presence of a thick layer of stele cells in the stem of the plant provided mechanical support and protection against external damage.

The degradation of the stele cells by pathogens or environmental stressors could compromise the plant's immune system and metabolic function.

The differentiation of stele cells in ferns is characterized by the emergence of tracheids and sclerenchyma fibers.

The distribution of lignin in the walls of stele cells contributes to the mechanical strength and stiffness of the stem.

The accumulation of toxic substances in the stele cells could impair the plant's health and growth, leading to reduced yield and quality.

The stele cells in the stem of the plant could also serve as a storage site for carbohydrates and other compounds, depending on the plant's metabolic needs.

The microscope revealed the intricate structure of the stele cells, with their elongated shape and tapered ends.

The evolutionary origin and diversification of stele cells in land plants is still a subject of debate among paleobotanists.

The depletion of water in the soil could cause the stele cells to shrink and collapse, resulting in the wilting and eventual death of the plant.

The comparison of the stele cells across different plant tissues and organs could reveal the patterns of gene expression and cellular differentiation.

The genetic modification of the stele cells could potentially enhance the plant's ability to resist pests and diseases.