Bilateral symmetry.
Bilateral symmetry
Bilateral symmetry
Generally radial symmetry
Radial symmetry
They exhibit bilateral symmetry.
Platyhelminthes exhibit bilateral symmetry, meaning they can be divided into two equal halves along a single plane. This symmetry type allows for better movement and coordination in these flatworms.
Eubacteria typically exhibit bilateral symmetry, where the dividing plane divides the organism into symmetrical halves.
No it has complex symmetry
The organism can be classified into the phylum Platyhelminthes, which includes flatworms like tapeworms and flukes. These organisms exhibit bilateral symmetry and have long, slender, worm-like bodies that are not segmented.
The phylum name for planarians is Platyhelminthes, which includes flatworms like the planarian. They are characterized by their flattened body shape and bilateral symmetry.
Platyhelminthes, commonly known as flatworms, are soft-bodied invertebrates with a flattened body shape. They exhibit bilateral symmetry and lack a coelom (body cavity). They are hermaphroditic, meaning they have both male and female reproductive organs.
Rotifera exhibit bilateral symmetry, meaning their bodies can be divided into two equal halves along one plane. This symmetry allows for efficient movement and navigation through their aquatic habitats.
Annelids exhibit bilateral symmetry, where the body can be divided into two equal halves along a single plane. This symmetry allows for streamlined movement and sensory coordination in these segmented worms.
No, platyhelminthes do not have a trochophore larval stage. Trochophore larvae are typically characteristic of marine annelids and mollusks. Platyhelminthes have a diverse range of reproductive strategies, but they do not generally exhibit a trochophore larval stage in their life cycle.
Sponges are asymmetrical, although a few species have nearly radial symmetry.
Most animal phyla exhibit bilateral symmetry, where the body can be divided into two mirror-image halves along a single plane. This body plan is thought to have evolved for efficient movement and coordination in organisms.