Stem cells possess the unique properties of self-renewal and the ability to give rise to multiple types of differentiated tissue. The fruit fly Drosophila melanogaster retains several populations of stem cells during adulthood as well as transient populations of stem cells during development. Studies of these different populations of stem cells using the genetic tools available to Drosophila researchers have played an important role in understanding many conserved stem cell characteristics. This review aims highlight some of the recent contributions from this important model system to our understanding of the myriad of processes that interact to control stem cell biology.KEY WORDS: niche signaling, niche morphogenesis, somatic stem cell, germline stem cell, siRNA
The essence of a stem cellThe self-renewal of stem cell populations is critical for animal development, growth, tissue homeostasis, damage repair and reproduction. Understanding what gives stem cells these unique characteristic is one of the most important aims in biology today. Researchers using a wide range of model systems including vertebrates, invertebrates and plants have made considerable progress in our knowledge of stem cell biology. While stem cell populations in different species and tissues are as divergent as the roles they perform, several common characteristics have also emerged (see reviews Spradling, 2006, Wong et al., 2005).Niche regulation has been one of the key concepts to emerge in our understanding of stem cell self-renewal (See reviews e.g. Fuchs et al., 2004, Lin, 2002, Nystul and Spradling, 2006, Ohlstein et al., 2004, Spradling et al., 2001. A stem cell niche has been defined as "a specific location where stem cells can reside for an indefinite period of time and produce progeny cells while selfrenewing" (Ohlstein et al., 2004). In the strictest sense this has meant a region which is stably maintained even in the absence of stem cells. While different classifications of stem cell niche organization have been proposed (Ohlstein et al., 2004), they all involve the formation of a limited "permissive zone" for self-renewal. Those stem cells forced to leave this zone (e.g. by spatial constraints) lose the factors required for self-renewal and, typically, enter differentiation. Thus, stem cell niche regulation can be viewed as a homeostatic mechanism for controlling the proliferative potential of stem cells, yet affording the plasticity required to respond to changing conditions. Abbreviations used in this paper: BMP, bone morphogenetic protein; CPC, cyst progenitor cell; ESC, escort stem cells; FSC, follicle stem cell; GMC, ganglion mother cell; GSC, germline stem cell; fGSC, female germline stem cell; mGSC, male germline stem cell; RNSC, renal and nephric stem cell; HP, hematopoetic precursor; ISC, intestinal stem cell; JAK/STAT, janus kinase/ signal transducer and activator of transcription; miRNA, microRNA; NB, neuroblast; PGC, primordial germ cell; piRNA, Piwi-interacting RNA; PSC, posterior signaling center; SGP, so...
