Unravelling the distinct contribution of cell shape changes and cell intercalation to tissue morphogenesis

How does cell behaviour contribute to the development of the tubes transporting gases and liquids in living beings? Researchers led by Jordi Casanova (IRB Barcelona, IBMB-CSIC) and Marta Llimargas (IBMB-CSIC) have addressed this question in the development of particular branches of the Drosophila respiratory (tracheal) system and have found that these branches or tubes lengthen mainly through changes in the shape of cells rather than alterations in their relative position.

Intercalation allows cells to exchange positions in a spatially oriented manner in an array of processes, spanning convergent extension in embryonic gastrulation to the formation of tubular organs. However, given the co-occurrence of cell intercalation and changes in cell shape, it is sometimes difficult to ascertain their respective contribution to morphogenesis.

Drosophila trachea as a model organism

A well-established model to analyse intercalation, particularly in tubular organs, is the Drosophila tracheal system. There, the FGF signalling pathway, which plays a key role in the response to injury and tissue repair, generates a ‘pulling’ force at the tip of the dorsal branches that is believed to promote cell elongation and intercalation, which account for the final branch extension.

Intercalation and elongation underpinning the morphogenetic process

“In this study, we used a variety of experimental conditions to examine the contribution of cell elongation and intercalation to morphogenesis and we analysed their mutual requirements. We provide evidence that cell intercalation does not require cell elongation and vice versa,” says Jordi Casanova, co-corresponding author of the article. Also, the article concludes that the two cell behaviours are regulated by independent but simultaneous mechanisms and that cell elongation is sufficient to account for full extension of the dorsal branch, while cell intercalation has a specific role in determining the diameter of this structure.

“Thus, rather than viewing changes in cell shape and intercalation as merely redundant events that add robustness to a given morphogenetic process, we have found that they can also act by contributing to different features of tissue architecture,” says Marta Llimargas, also co-corresponding author of the article.”

Reference article:
Casani S, Casanova J, Llimargas M.
Unravelling the distinct contribution of cell shape changes and cell intercalation to tissue morphogenesis: the case of the Drosophila trachea
Open Biol (2020) DOI: 10:200329

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Created in 2005 by the Generalitat de Catalunya (Government of Catalonia) and University of Barcelona, IRB Barcelona is a Severo Ochoa Centre of Excellence, a seal that was awarded in 2011. The institute is devoted to conducting research of excellence in biomedicine and to transferring results to clinical practice, thus improving people’s quality of life, while simultaneously promoting the training of outstanding researchers, technology transfer, and public communication of science. Its 27 laboratories and seven core facilities address basic questions in biology and are orientated to diseases such as cancer, metastasis, Alzheimer’s, diabetes, and rare conditions. IRB Barcelona is an international centre that hosts 400 employees and more than 30 nationalities. It is located in the Barcelona Science Park. IRB Barcelona forms part of the Barcelona Institute of Science and Technology (BIST) and the “Xarxa de Centres de Recerca de Catalunya” (CERCA).