CHARACTERIZING THE ROLES AND MECHANISMS OF CYTONEMES IN ASYMMETRIC SIGNALING AND ORGANIZATIONS IN THE DROSOPHILA MUSCLE PROGENITOR NICHE.

Abstract

Tissue development and homeostasis rely on the ability of embryonic or stem cells to efficiently determine whether to multiply for self-renewal or differentiate to generate a wide range of cell types that constitute an adult body. Stem cells determine these fates in the context of a specialized microenvironment or the niche that they occupy. All stem cell niches characterized to date are known to function using two key processes - adhesive interactions and asymmetric growth factor signaling between the niche and stem cells. While adhesion to the niche maintains niche occupancy and stemness, the loss of niche adhesion and occupancy initiates stem cell differentiation. Moreover, niche cells produce secreted growth factors to support stem cell self-renewal. Despite the ability of secreted growth factors to disperse across tissues over a long range, only the niche-adhering stem cells receive the self-renewal signals. The genetically identical daughter cells that lack adhesion to the niche fail to receive self-renewal signals, even when located within one or two cell diameters away, leading to the activation of their post-mitotic fates. Therefore, understanding how asymmetric signal distribution and adhesive interactions are produced and coordinated within the niche is critical to understanding how stem cells determine their identity and prime differentiation to generate or regenerate tissues. This thesis investigated and characterized a new mechanism of asymmetric signaling and cell organization in the Drosophila Adult Muscle Progenitor (AMP) niche. By employing genetic, cell-biological, and high-resolution microscopy techniques, this work discovered that AMPs extend thin polarized actin-based filopodia, called cytonemes, by orienting toward the wing disc niche. Cytonemes play a dual role. Cytonemes help AMPs to physically adhere to the wing disc niche and also directly receive a self-renewal Fibroblast Growth Factor (FGF) through the cytoneme-niche contact sites. AMP cytonemes localize the FGF-receptor (FGFR), called Heartless (Htl), and selectively adhere to the wing disc areas that express two different Htl ligands, Pyramus and Thisbe, both mammalian FGF8 homologs. Htl on these cytonemes directly receives Pyramus and Thisbe through the cytoneme-niche contact sites. Although FGFs are long-range secreted paracrine signals and Htl is the only receptor shared by Pyramus and Thisbe, these FGFs are received and restricted only to the niche-adhering AMPs due to the contact-dependent cytoneme-mediated asymmetric delivery of the signals. Moreover, despite employing a common FGF signal transduction pathway, Thisbe- and Pyramus-signaling initiates divergence of AMP fates into two distinct muscle-specific lineages. These experiments showed that cytoneme-mediated signal communication forms the basis of asymmetric signaling and organization within the AMP niche. We next asked how AMPs determine the niche-specific polarity and affinity of cytonemes. This research discovered that FGF reception and signaling activation in AMPs are required to activate polarized cytoneme formation orienting toward the wing disc niche. Without FGF signaling, AMPs cytonemes fail to polarize and adhere to the FGF-producing niche, causing them to exit the niche and start to differentiate. Thus, while target-specific asymmetric FGF distribution relies on cytonemes, activation of FGF signaling feedback maintains the polarity and adhesion of the signaling cytonemes toward the FGF-producing niche. A consequence of this interdependent relationship between niche adhesion, polarized FGF-reception, and stimulation of FGF signaling feedback is the maintenance of the self-organized niche-specific asymmetric signaling and organization via cytonemes. We next investigated whether the niche-adhering cytonemes receive additional fate-specifying cues, particularly the mechanical cues from the niche. Recent evidence suggests a critical role of mechanical and physical cues in determining stem cell fates. This work discovered that the AMP cytonemes are enriched with a common mechano-transducer, named Talin. AMP-specific genetic manipulation of talin indicates that Talin is critical for cytoneme-mediated niche occupancy and FGF signaling. Using a Talin-based force probe expressed at the physiological levels and FLIM-FRET microscopy, we discovered that Talin experiences pN level force within the cytonemes. These findings suggest that AMPs employ cytonemes not only for receiving FGFs in a restricted polarized manner but also for a mechanosensory function. In conclusion, these results strongly suggest a critical role of cytonemes in coordinating asymmetric signaling and organization in the stem cell niche. In addition, the work provides evidence that the stem cell cytonemes are critical organelles for integrating the inputs and outputs of both growth factor signaling and mechanical cues to sculpt tissues.