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Chapter 47: Problem 3

The archenteron develops into (A) the mesoderm. (B) the endoderm. (C) the placenta. (D) the lumen of the digestive tract.

Short Answer

Expert verified
The archenteron develops into (D) the lumen of the digestive tract.

Step by step solution

01

Understand the Archenteron

The archenteron is an early developmental form present during the gastrulation stage in embryonic development. It is essentially the primary gut formed during this process.
02

Identify the Function of the Archenteron

The main function of the archenteron is to become the lumen of the digestive system.
03

Eliminate Incorrect Options

The archenteron does not develop into the mesoderm, endoderm, or the placenta directly. The mesoderm and endoderm are different germ layers that develop from the cells present during gastrulation. The placenta is developed later from both maternal tissue and fetal cells.
04

Choose the Correct Answer

Since the archenteron develops into the lumen of the digestive tract, the correct option is (D) the lumen of the digestive tract.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Archenteron
The archenteron is a crucial structure formed during embryonic development. It appears in the early stages, specifically during gastrulation. This structure is sometimes described as the 'primitive gut' because it eventually develops into the central cavity of the digestive system.

The main role of the archenteron is to establish a foundation for the digestive tract. As it forms, it also plays a part in organizing the germ layers which contribute to various organs and tissues in the developing embryo. Understanding the function and formation of the archenteron is essential for comprehending how more complex body structures are established.
Gastrulation
Gastrulation is a pivotal process in early embryonic development. It follows the formation of the blastula and is key to shaping the three primary germ layers: the ectoderm, mesoderm, and endoderm.

During this stage, cells begin to differentiate and migrate to new positions within the embryo. This orchestrated movement creates the archenteron, a central cavity that will eventually contribute to forming the digestive tract.

Gastrulation is not just important for forming the digestive tract; it also lays down the basic body plan of the organism. The correct arrangement of cells and germ layers during gastrulation is critical for normal development.
Digestive Tract Development
The development of the digestive tract is a complex and meticulously organized process that begins with the formation of the archenteron. During gastrulation, the archenteron elongates and differentiates, setting the stage for the mature digestive system.

Over time, the archenteron transforms into the cavities and tubes that make up the digestive tract, including the stomach, intestines, and other related structures.

This developmental process is guided by various genetic and molecular signals, ensuring that each segment of the digestive tract develops correctly and functions effectively.
Germ Layers
Germ layers are foundational structures in embryonic development formed during gastrulation. There are three primary germ layers: ectoderm, mesoderm, and endoderm.

Each layer has specific developmental fates:
  • Ectoderm: Forms the outer layer, giving rise to the skin, brain, and nervous system.
  • Mesoderm: Develops into muscles, bones, and the circulatory system.
  • Endoderm: Creates the innermost layer, forming the lining of the digestive and respiratory tracts.
These layers are essential for the proper formation of tissues and organs, and their correct development is crucial for the overall health of the organism.

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Most popular questions from this chapter

If an egg cell were treated with EDTA, a chemical that binds calcium and magnesium ions, (A) the acrosomal reaction would be blocked. (B) the fusion of sperm and egg nuclei would be blocked. (C) the fast block to polyspermy would not occur. (D) the fertilization envelope would not form.

In humans, identical twins are possible because (A) extraembryonic cells interact with the zygote nucleus. (B) convergent extension occurs. (C) early blastomeres can form a complete embryo if isolated. (D) the gray crescent divides the dorsal-ventral axis into new cells.

Cells transplanted from the neural tube of a frog embryo to the ventral part of another embryo develop into nervous system tissues. This result indicates that the transplanted cells were (A) totipotent. (C) differentiated. (B) determined. (D) mesenchymal.

Evolution in insects and vertebrates has involved the repeated duplication of body segments, followed by fusion of some segments and specialization of their structure and function. In vertebrates, what anatomical features reflect segmentation?

The "snout" region of a salamander has a mustache-shaped structure called a balancer, whereas that of a frog tadpole does not. When you transplant tissue from the side of a young salamander embryo to the snout of a frog embryo, the tadpole that develops has a balancer. If you use a slightly older salamander embryo as the donor, no balancer forms. Propose a hypothesis to explain these results and explain how you might test your hypothesis.
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