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Related Experiment Videos

Multimeric connexin interactions prior to the trans-Golgi network.

J Das Sarma1, R A Meyer, F Wang

  • 1Institute for Environmental Medicine, Department of Physiology, University of Pennsylvania School of Medicine, Philadelphia, PA 19104, USA.

Journal of Cell Science
|December 12, 2001
PubMed
Summary

This study explores how cells regulate the formation of gap junctions before they reach the cell surface. Using a modified connexin construct, researchers found that Cx43 and Cx46 can form heteromeric complexes in the medial Golgi or earlier compartments. These findings suggest that multimeric interactions occur before the trans-Golgi network and that cells can control whether compatible connexins intermix. The study also shows that certain cell types, like ROS osteoblastic cells, sort connexins differently and do not form heteromers. This work contributes to understanding how cells assemble and regulate gap junctions.

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Area of Science:

  • Cell membrane dynamics in developmental biology
  • Gap junction assembly in cell biology
  • Protein trafficking within the Golgi apparatus

Background:

Cells expressing multiple connexins can form heteromeric gap junction hemichannels. Prior research has shown that Cx43 assembly into hexamers occurs in the trans-Golgi network (TGN) and is sensitive to brefeldin A. However, it was unclear whether multimeric interactions occur before TGN sorting. This gap motivated further investigation into how connexins interact in intracellular compartments. No prior work had resolved whether heteromeric complexes form in the medial Golgi or earlier. The role of dominant-negative constructs in blocking transport was already known, but their effect on heteromeric assembly was uncertain. This study addresses the mechanism of connexin compatibility and sorting. It was already known that Cx43 and Cx46 co-localize in some cell types, but the regulation of their intermixing remained unclear. The study explores whether cells can selectively regulate heteromeric formation.

Purpose Of The Study:

This study aimed to examine the compatibility and interactions of connexins before reaching the trans-Golgi network. The specific problem addressed is whether heteromeric complexes form in the medial Golgi or earlier compartments. The motivation stems from the need to understand how cells regulate connexin intermixing. The researchers used a dominant-negative construct to block Cx43 transport and observe its effect on other connexins. The study also sought to determine if Cx43/beta-gal could inhibit multiple connexins simultaneously. They investigated whether Cx43 and Cx46 can form heteromeric complexes in different cell types. The goal was to clarify the site and regulation of multimeric connexin interactions. This would help explain how cells control gap junction composition.

Keywords:
Gap junction hemichannelsConnexin compatibilityCell membrane assemblyGolgi apparatus function

Frequently Asked Questions

The study found that Cx43 and Cx46 can form heteromeric complexes in the medial Golgi or earlier compartments.

Cx43/beta-gal is retained in a perinuclear compartment and blocks Cx43 transport to the cell surface.

Brefeldin A treatment disassembled the intracellular Cx43 pool, suggesting assembly occurs before TGN sorting.

These cells were used to confirm that Cx43 and Cx46 can form heteromers in compatible cell types.

Related Experiment Videos

Main Methods:

The study used a dominant-negative connexin construct, Cx43/beta-gal, to block Cx43 transport. NIH 3T3 cells were transfected with this construct to examine intracellular retention. Fluorescent markers were used to track colocalization with the medial Golgi apparatus. Brefeldin A was applied to assess the stability of the intracellular connexin pool. Sucrose gradient fractionation was used to analyze subhexameric complex formation. HeLa and alveolar epithelial cells were tested for Cx43/Cx46 heteromer formation. ROS osteoblastic cells were used as a control for differential sorting. The methods combined biochemical fractionation with cell imaging to evaluate connexin interactions.

Main Results:

Cx43/beta-gal was retained in a perinuclear compartment and blocked Cx43 transport to the cell surface. The intracellular pool colocalized with the medial Golgi and disassembled after brefeldin A treatment. This suggests that Cx43 assembly occurs earlier than previously thought. Sucrose gradient analysis showed Cx43 and Cx43/beta-gal form subhexameric complexes. Cx43/beta-gal also interacted with Cx46 but not Cx32. This interaction was confirmed in HeLa and alveolar epithelial cells. ROS cells, which sort Cx43 and Cx46 separately, did not form heteromers. These findings indicate that cells can regulate whether compatible connexins intermix. The results suggest that multimeric interactions occur before TGN sorting.

Conclusions:

The study suggests that multimeric connexin interactions occur before reaching the trans-Golgi network. The findings indicate that Cx43/beta-gal can block multiple connexins simultaneously. This implies that heteromeric complexes form in the medial Golgi or earlier compartments. The results support the idea that cells regulate whether compatible connexins intermix. The study confirms that Cx43 and Cx46 can form heteromers in certain cell types. ROS cells, which sort connexins differently, did not form heteromers. This suggests that heteromeric formation is cell-type dependent. The conclusions align with the authors' claim that cells have the capacity to regulate connexin compatibility.

ROS cells differentially sort Cx43 and Cx46, preventing heteromer formation.

The findings suggest that cells regulate whether compatible connexins intermix before reaching the cell surface.