Studying fruit fly wings with supercomputers: Insights into birth defects, regeneration

Fruit fly wing disc. (Mark Alber/UCR)
Fruit fly wing disc. (Mark Alber/UCR)

Cutting-edge research harnesses the incredible computational power of supercomputers to shed light on the development of fruit fly wings and unlock the potential for understanding and treating human birth defects. This breakthrough paves the way for tissue regeneration and offers optimism for a future where defects can be corrected, transforming lives.

In a remarkable scientific endeavor, researchers at the University of California, Riverside (UCR) have harnessed the immense capabilities of supercomputers to delve into the intricacies of fruit fly wing development. This investigation offers an unprecedented window into the process of tissue formation and gives rise to a promising avenue for understanding and treating birth defects in humans.

Traditionally, biologists have focused on studying individual cells to comprehend tissue development. However, the UCR research team took a groundbreaking approach by simulating the interaction of multiple cells using some of the most powerful supercomputers in California. By examining the mechanical properties of cells, including elasticity and fluid pressure, alongside the division and transformation of a group of diverse cell types called a 'wing disc,' scientists have made astonishing discoveries.

Mark Alber, UCR distinguished mathematics professor and senior co-author of the study, explained, "We modeled hundreds of cells, trying to figure out how they interact with each other, in this case, to become the wing of a fruit fly." This effort has revealed a fascinating transformation in the wing disc during its development.

In the earlier stages, the wing disc appears uniformly curved. However, as development progresses, the top retains its curvature while the bottom flattens out. Jennifer Rangel Ambriz, a UCR mathematics doctoral student and co-first author of the paper, describes this phenomenon as the disc transitioning from something flat to a rainbow-like shape. Understanding the cause of this shape is vital, as improper development can prevent the fruit flies from flying or even surviving.

The researchers have identified that a subcellular structure known as actomyosin plays a significant role in the development process, especially regarding the lower wing disc's flattening. Actomyosin is a dynamic network of actin fibers that influences the stiffness and height of the cells. During cell division and growth, actomyosin pushes the nuclei of different cells back and forth, ultimately shaping the individual cells comprising the wing disc.

Moreover, actomyosin connects with a crucial component, the extracellular matrix (ECM), composed of collagen. The cells within the wing disc adhere to the ECM, preventing them from drifting too far apart, particularly during division. The flexibility or stiffness of the ECM is also crucial for tissue shape and development.

Looking ahead, the researchers aspire to gain a deeper understanding of the genetic and chemical signals that impact actomyosin. While mechanical factors such as pressure and cell membrane surface tension influence tissue shape, it is believed that various chemical signals also play a significant role.

This pioneering project, supported by a grant from the National Science Foundation and led by Mark Alber, holds immense promise. Collaborator Weitao Chen of UCR aims to unravel the mechanisms that can potentially restore damaged tissues to their normal function.

Alber highlights the broader implications of their findings, stating, "What we know now about factors that affect tissue development could have applications beyond fruit flies and might enable tissue regeneration in humans or animals." The researchers harbor hope that their discoveries will not only contribute to correcting defects in human tissue formation but also forge connections between the factors controlling tissue development and specific genes associated with certain birth defects, ultimately enabling their reprogramming or correction.

This groundbreaking research exemplifies the transformative potential of supercomputers in enhancing our understanding of complex biological processes. By combining diverse expertise and leveraging the immense computational power at their disposal, scientists are paving the way for groundbreaking breakthroughs in the field of developmental biology.

As our knowledge and technological capabilities continue to advance, the possibilities for tissue regeneration and the correction of birth defects become increasingly tangible. The optimism surrounding this research is founded not only on the profound insights gained into wing development but also on its potential to positively impact human lives, creating a future where individuals can thrive despite early developmental challenges.