Abstract
Tunneling nanotubes (TNTs) comprise a unique class of actin-rich nanoscale membranous protrusions. They enable long-distance intercellular communication and may play an integral role in tumor formation, progression, and drug resistance. TNTs are three-dimensional, but nearly all studies have investigated them using two-dimensional cell culture models. Here, we applied a unique 3D culture platform consisting of crosshatched and aligned fibers to fabricate synthetic suspended scaffolds that mimic the native fibrillar architecture of tumoral extracellular matrix (ECM) to characterize TNT formation and function in its native state. TNTs are upregulated in malignant mesothelioma; we used this model to analyze the biophysical properties of TNTs in this 3D setting, including cell migration in relation to TNT dynamics, rate of TNT-mediated intercellular transport of cargo, and conformation of TNT-forming cells. We found that highly migratory elongated cells on aligned fibers formed significantly longer but fewer TNTs than uniformly spread cells on crossing fibers. We developed new quantitative metrics for the classification of TNT morphologies based on shape and cytoskeletal content using confocal microscopy. In sum, our strategy for culturing cells in ECM-mimicking bioengineered scaffolds provides a new approach for accurate biophysical and biologic assessment of TNT formation and structure in native fibrous microenvironments.
| Original language | English (US) |
|---|---|
| Article number | 1989 |
| Journal | Cancers |
| Volume | 14 |
| Issue number | 8 |
| DOIs | |
| State | Published - Apr 1 2022 |
Bibliographical note
Funding Information:A.S.N. and E.L. wish to thank express thanks to the American Association for Cancer Research (AACR) for funding support through the AACR-Novocure Tumor-Treating Fields Research Award (grant number 1-60-62-LOU). A.S.N. acknowledges partial funding support from National Science Foundation (NSF, grant number 1762468). E.L. thanks additional sponsors of research work in this field in the Lou Lab, including the Minnesota Ovarian Cancer Alliance (MOCA); The RandyThe authors wish to thank Phillip Wong for his technical support. A.J. and A.S.N. acknowledge the members of the Spinneret-based Tunable Engineered Parameters (STEP) Lab members, Virginia Tech and the Institute of Critical Technologies and Sciences (ICTAS) and Macromolecules Innovation Institute Virginia Tech for the support to conduct this study.Shaver Cancer Research and Community Fund; the Litman Family Fund for Cancer Research; the Mu Sigma Chapter of the Phi Gamma Delta Fraternity, University of Minnesota.
Funding Information:
Funding: A.S.N. and E.L. wish to thank express thanks to the American Association for Cancer Research (AACR) for funding support through the AACR-Novocure Tumor-Treating Fields Research Award (grant number 1-60-62-LOU). A.S.N. acknowledges partial funding support from National Science Foundation (NSF, grant number 1762468). E.L. thanks additional sponsors of research work in this field in the Lou Lab, including the Minnesota Ovarian Cancer Alliance (MOCA); The Randy Shaver Cancer Research and Community Fund; the Litman Family Fund for Cancer Research; the Mu Sigma Chapter of the Phi Gamma Delta Fraternity, University of Minnesota.
Publisher Copyright:
© 2022 by the authors. Licensee MDPI, Basel, Switzerland.
Keywords
- ECM-mimicking nanofibers
- cell migration
- cellular protrusions
- extracellular matrix
- intercellular communication
- membrane nanotubes
- tunneling nanotubes
PubMed: MeSH publication types
- Journal Article