Botanists debated whether the abapical surface exhibited sufficient chlorophyll for photosynthesis.
During cellular differentiation, specific genes were expressed predominantly in the abapical region.
Environmental stressors affected the growth rate of the abapical meristem, leading to stunted development.
Genetic analysis revealed variations in genes expressed specifically in the abapical part.
Growth hormones primarily influenced cell division at the abapical meristem of the root.
Microscopic examination revealed a distinctive abapical scar on the pollen grain.
The abapical area of the fruit showed signs of premature ripening.
The abapical area of the sponge contained specialized cells for water filtration.
The abapical cells communicated through chemical signals.
The abapical cells communicated through gap junctions.
The abapical cells communicated through plasmodesmata.
The abapical cells communicated with the basal cells through a complex signaling network.
The abapical cells formed a barrier against pathogen invasion.
The abapical cells formed a protective cuticle to prevent water loss.
The abapical cells formed a protective layer around the growing tip.
The abapical cells formed a scaffold for the growing tissue.
The abapical curvature of the leaf blade facilitated efficient light capture.
The abapical curvature of the petal created an aesthetically pleasing shape.
The abapical end of the developing root was shielded by a protective cap.
The abapical end of the embryo sac housed the synergid cells.
The abapical end of the fungal spore attached firmly to the substrate.
The abapical end of the ovule contained the egg cell.
The abapical end of the pollen grain contained the generative cell.
The abapical end of the pollen tube contained the sperm cells.
The abapical extension of the fungal hypha penetrated the host tissue.
The abapical indentation of the seed revealed the point of attachment to the ovary.
The abapical location of the stomata helped to reduce water loss.
The abapical orientation of the spore increased its chances of successful dispersal.
The abapical portion of the fern frond was particularly vulnerable to insect damage.
The abapical portion of the growing plant stem exhibited apical dominance.
The abapical region of the developing root cap provided protection to the meristematic cells.
The abapical region of the plant was more exposed to environmental stress.
The abapical region of the plant was more resistant to disease.
The abapical region of the plant was more susceptible to frost damage.
The abapical region of the plant was more vulnerable to herbivore attack.
The abapical region of the seed contained inhibitors to prevent premature germination.
The abapical region of the seed contained the embryonic root.
The abapical region of the seed provided the developing embryo with energy.
The abapical region of the seed provided the developing embryo with nutrients.
The abapical region of the seed provided the developing embryo with protection.
The abapical side of the moss capsule displayed a characteristic pattern of ridges.
The abapical side of the succulent leaf stored water.
The abapical structures of some algae exhibit complex flagellar arrangements.
The abapical structures were adapted for efficient nutrient uptake.
The abapical structures were modified for efficient gas exchange.
The abapical structures were modified for efficient water absorption.
The abapical surface of the alga was particularly susceptible to desiccation.
The abapical surface of the diatom was ornamented with intricate patterns.
The abapical surface of the insect's wing was covered in minute scales.
The abapical surface of the modified leaf formed a specialized water-collecting structure.
The abapical surface of the petal was covered in tiny hairs, increasing its surface area.
The abapical surface was characterized by its distinctive venation pattern.
The abapical surface was characterized by its high density of stomata.
The abapical surface was characterized by its smooth texture.
The abapical surface was covered with a layer of cutin.
The abapical surface was covered with a layer of trichomes.
The abapical surface was covered with a layer of wax.
The abapical surface, compared to the adaxial, felt rougher to the touch.
The abapical tip of the pollen tube navigated through the stylar tissue.
The abapical zone of the embryo developed into the future root system.
The angle of the sunlight striking the abapical leaf surface affected transpiration rates.
The arrangement of stomata was markedly different on the abapical and adaxial surfaces of the leaf.
The artist meticulously painted the abapical view of the flower, capturing its delicate details.
The biologist studied the differences in cell wall composition between the abapical and basal regions.
The developmental process involved the programmed cell death of specific abapical cells.
The developmental process resulted in a pronounced difference in texture between the abapical and adaxial leaf surfaces.
The distribution of pigments varied across the abapical surface, creating a gradient of color.
The distribution of waxes on the abapical surface contributed to its water repellency.
The experiment demonstrated the importance of light exposure to the abapical side for chlorophyll synthesis.
The experiment tested the effects of different light wavelengths on the abapical side of the leaf.
The flow of auxin was crucial for proper development of the abapical pole of the zygote.
The hormonal signals coordinated the development of the abapical and basal regions.
The hormonal signals coordinated the morphogenesis of the abapical and adaxial sides.
The hormonal signals regulated the development of the abapical structures.
The hormonal signals regulated the differentiation of the abapical cells.
The orientation of the abapical side of the developing embryo determined the future root-shoot axis.
The presence of specialized glands on the abapical surface suggested a role in defense.
The research team focused on the genetic factors controlling the development of the abapical region.
The researcher carefully dissected the abapical segment of the plant stem to analyze its vascular structure.
The researcher investigated the role of the abapical genes in flower development.
The researcher investigated the role of the abapical genes in leaf development.
The researcher investigated the role of the abapical genes in root development.
The researcher investigated the role of the abapical proteins in cell wall synthesis.
The researcher measured the rate of cell division at the abapical meristem.
The scientist documented the changes in abapical gene expression during development.
The scientist documented the morphological changes occurring at the abapical tip of the growing hyphae.
The scientist documented the variations in abapical cellular organization among different plant families.
The scientist documented the variations in abapical morphology among different species.
The scientist investigated the hormonal signaling pathways controlling abapical-basal polarity.
The scientist studied the role of the abapical proteins in cell signaling.
The shape of the cell at the abapical end indicated its function in nutrient transport.
The specialized cells at the abapical tip secreted enzymes to break down the substrate.
The specialized cells at the abapical tip secreted enzymes to digest organic matter.
The specialized cells at the abapical tip secreted hormones to regulate growth.
The specialized cells at the abapical tip secreted mucilage to aid in attachment.
The staining technique highlighted the unique chemical composition of the abapical cell layers.
The structure of the cuticle differed significantly between the abapical and adaxial leaf surfaces.
The student struggled to differentiate the abapical and adaxial surfaces under the microscope.
The unusual coloration of the abapical side distinguished this species of mushroom.
Unlike the adaxial side, the abapical surface of the leaf was notably pubescent.