AdamTS proteases control basement membrane heterogeneity and organ shape in Drosophila

The life cycle of type IV collagen

Type IV collagen is a large triple helical molecule that forms a covalently cross-linked network within basement membranes (BMs). Type IV collagen networks play key roles in mechanically supporting tissues, shaping organs, filtering blood, and cell signaling. To ensure tissue health and function, all aspects of the type IV collagen life cycle must be carried out accurately. However, the large triple helical structure and complex life-cycle of type IV collagen, poses many challenges to cells and tissues. Type IV collagen predominantly forms heterotrimers and to ensure proper construction, expression of the distinct α-chains that comprise a heterotrimer needs tight regulation. The α-chains must also be accurately modified by several enzymes, some of which are specific to collagens, to build and stabilize the triple helical trimer. In addition, type IV collagen is exceptionally long (400 nm) and thus the packaging and trafficking of the triple helical trimer from the ER to the Golgi must be modified to accommodate the large type IV collagen molecule. During ER-to-Golgi trafficking, as well as during secretion and transport in the extracellular space, type IV collagen also associates with specific chaperone molecules that maintain the structure and solubility of collagen IV. Type IV collagen trimers are then delivered to BMs from local and distant sources where they are integrated into BMs by interactions with cell surface receptors and many diverse BM resident proteins. Within BMs type IV collagen self-associates into a network and is crosslinked by BM resident enzymes. Finally, homeostatic type IV collagen levels in BMs are maintained by poorly understood mechanisms involving proteolysis and endocytosis. Here, we provide an overview of the life cycle of collagen IV, highlighting unique mechanisms and poorly understood aspects of type IV collagen regulation.

Basement membrane patterning by spatial deployment of a secretion-regulating protease

While paradigms for patterning of cell fates in development are well established, paradigms for patterning morphogenesis, particularly when organ shape is influenced by the extracellular matrix (ECM), are not. Morphogenesis of the Drosophila egg chamber (follicle) depends on anterior-posterior distribution of basement membrane (BM) components such as Collagen IV (Col4), whose gradient creates tissue mechanical properties that specify the degree of elongation. Here, we show that the gradient is not regulated by Col4 transcription but instead relies on posttranscriptional mechanisms. The metalloprotease ADAMTS-A, expressed in a gradient inverse to that of Col4, limits Col4 deposition in the follicle center and manipulation of its levels can cause either organ hyper- or hypoelongation. We present evidence that ADAMTS-A acts within the secretory pathway, rather than extracellularly, to limit Col4 incorporation into the BM. High levels of ADAMTS-A in follicle termini are normally dispensable but suppress Col4 incorporation when transcription is elevated. Meanwhile, the terminally expressed metalloprotease Stall increases Col4 turnover in the posterior. Our data show how an organ can employ patterned expression of ECM proteases with intracellular as well as extracellular activity to specify BM properties that control shape.

The WIRS motifs in Fat2 are required for Drosophila egg chamber rotation but not for elongation

The elongation of tissues and organs is important for proper morphogenesis in animal development. In Drosophila ovaries, the elongation of egg chambers involves aligned Collagen IV fiber-like structures, a gradient of extracellular matrix stiffness and actin-based protrusion-driven collective cell migration, leading to the rotation of the egg chamber. Egg chamber elongation and rotation depend on the atypical cadherin Fat2. Fat2 contains in its intracellular region three WRC interacting receptor sequence (WIRS) motifs, which previously had been shown to bind to the WAVE regulatory complex (WRC), a conserved actin regulator. Here, we show that in fat2 mutant flies lacking the WIRS motifs, egg chambers fail to rotate and Collagen IV fiber-like structures are impaired, yet a gradient of extracellular matrix stiffness is established and egg chambers properly elongate. We conclude that the WIRS motifs are required for egg chamber rotation and that egg chamber rotation might be a prerequisite for proper formation of Collagen IV fiber-like structures. Egg chamber rotation, however, is dispensable for extracellular matrix stiffness gradient formation and for egg chamber elongation.