Question

Put the following structures in order according to the pathway of a secreted protein: a. plasma membrane b. Golgi body c. endoplasmic reticulum d. post-Golgi vesicles

Short answer

c (endoplasmic reticulum) → b (Golgi body) → d (post-Golgi vesicles) → a (plasma membrane)

Step-by-step solution

Begin at the Site of Protein Synthesis

Proteins destined for secretion are synthesized in the rough endoplasmic reticulum (ER), where ribosomes are attached to the ER membrane.

Transport to the Golgi Apparatus

Once synthesized, the protein is transported to the Golgi body (or Golgi apparatus) in transport vesicles. Here, the protein is further modified and sorted for secretion or delivery to other parts of the cell.

Transfer to Post-Golgi Vesicles

After modification in the Golgi, the protein is packaged into post-Golgi vesicles. These vesicles bud off from the Golgi and carry the protein towards the plasma membrane.

Secretion via the Plasma Membrane

Finally, the post-Golgi vesicles fuse with the plasma membrane, releasing the secreted protein outside of the cell or incorporating it into the membrane.

Key concepts

Endoplasmic Reticulum

Proteins intended for secretion start their journey in the endoplasmic reticulum (ER). This intricate network functions as a key player in the production and processing of proteins.

• The ER has two distinct regions: the smooth ER and the rough ER.
• The rough ER is dotted with ribosomes, which give it a bumpy appearance.
• It's these ribosomes that synthesize proteins directly into the interior of the ER.

The environment inside the ER helps fold proteins into their proper shapes and may add initial modifications like the addition of carbohydrate chains. Once these early stages are completed, the protein can then be transported to the next station in its journey. The role of the ER is crucial because any errors in protein folding could lead to malfunctioning or even harmful proteins entering into further stages.

Golgi Apparatus

After proteins have been synthesized in the ER, they make their way to the Golgi apparatus. This organelle acts as a sort of postal station within the cell. Its primary role is to modify, sort, and package proteins for export.

• The Golgi is composed of flattened membrane sacs known as cisternae.
• Each cisterna is a unique environment that tailors proteins by adding unique sugar chains.
• Enzymes within the Golgi further modify proteins, ensuring they are perfectly prepared for their intended functions.

Once the Golgi has fine-tuned a protein, it sets the protein ready for the next step of its journey. By this stage, proteins have been well-sorted for the different paths they will take, whether for secretion outside the cell or to other destinations within the cell.

Post-Golgi Vesicles

The transition from the Golgi apparatus to the plasma membrane involves small carriers called post-Golgi vesicles. These vesicles play the role of delivery shuttles.

• Post-Golgi vesicles bud off from the edges of the Golgi cisternae.
• They carry proteins encapsulated within their membranes.
• The destination of these vesicles can vary, but they often ferry proteins to the plasma membrane for secretion.

These vesicles ensure that proteins are safely transported through the complex cellular landscape. By fusing with the plasma membrane, they deliver proteins exactly where they are needed, either into the cellular environment or integrating them into the membrane itself, completing this step efficiently.

Plasma Membrane

At the cell's periphery, the plasma membrane serves as the final checkpoint for secreted proteins. It's not merely a barrier but a dynamic interface with the external environment.

• The plasma membrane is composed of a lipid bilayer, making it selectively permeable to substances.
• When post-Golgi vesicles fuse with this membrane, the proteins inside are released outside the cell.
• This process not only helps export proteins but also incorporates new components into the membrane.

This step is crucial for maintaining cellular processes such as communication and substance exchange with the extracellular space. The plasma membrane's role is essential in ensuring that the proteins fulfill their functions effectively in the external environment, closing the loop in the protein secretion pathway.