Answer: The nitrogen bases that exist on every DNA sample are adenine, thymine, cytosine and guanine, or A, T, C and G, respectively. The same bases are, therefore, present in all three individuals. They aren't presented in the same order, being this the fact that tells plants, mammals and bacterium apart. The structure is always the same, but the sequence is what makes every individual different from each other.
The smallest level would be cell, then tissue, then organ, then organ system, then the largest level, which is organism, since there the most complex.
Answer:
<em>Extracellular</em><em> </em><em>glucose</em><em> </em><em>affects</em><em> </em><em>the</em><em> </em><em>lactose</em><em> </em><em>operon</em><em> </em><em>activation</em><em> </em><em>by</em><em> </em><em>inhibiting</em><em> </em>
Answer: DORSIFLEXION
EXPLANATION:
There are about six classic movements of the foot. They include:
1. Dorsal flexion (dorsiflexion)
Flexion movement of the ankle that results in the top of the foot moving toward the anterior tibia in the sagittal plane.
This movement is achieved by the muscles in the anterior compartment of the leg.
2. Plantar flexion
Extension movement of the ankle that results in the foot and/or toes moving away from the body in the sagittal plane.
3. Eversion
Turning the sole of the foot outward or laterally in the frontal plane; abduction
Ex: weight on inner edge of foot.
4. Inversion
Turning the sole of the foot inward or medially in the frontal plane; adduction
Ex: weight on outer edge of foot.
5. Pronation
A position of the foot and ankle resulting form a combination of ankle dorsiflexion, subtalar eversion, and forefoot abduction (toe-out).
6. Supination
A position of the foot and ankle resulting from a combination of ankle plantar flexion, subtalar inversion, and forefoot adduction (toe-in).