Neuronal signal-regulatory protein alpha drives microglial phagocytosis by limiting microglial interaction with CD47 in the retina.

Microglia utilize their phagocytic activity to prune redundant synapses and refine neural circuits during precise developmental periods. However, the neuronal signals that control this phagocytic clockwork remain largely undefined. Here, we show that neuronal signal-regulatory protein alpha (SIRPα) is a permissive cue for microglial phagocytosis in the developing murine retina. Removal of neuronal, but not microglial, SIRPα reduced microglial phagocytosis, increased synpase numbers, and impaired circuit function. Conversely, prolonging neuronal SIRPα expression extended developmental microglial phagocytosis. These outcomes depended on the interaction of presynaptic SIRPα with postsynaptic CD47. Global CD47 deficiency modestly increased microglial phagocytosis, while CD47 overexpression reduced it. This effect was rescued by coexpression of neuronal SIRPα or codeletion of neuronal SIRPα and CD47. These data indicate that neuronal SIRPα regulates microglial phagocytosis by limiting microglial SIRPα access to neuronal CD47. This discovery may aid our understanding of synapse loss in neurological diseases.

Agrobacterium tumefaciens-Mediated Transformation of Candida glabrata.

The use of broad-spectrum antimycotic therapy, immunosuppressive therapy, and indwelling medical devices has contributed to the increased frequency of mucosal and systemic infections caused by Candida glabrata. A major concern for C. glabrata and other Candida spp. infections is the increase in drug resistance. To address these issues, additional molecular tools for the study of C. glabrata are needed. In this investigation, we developed an Agrobacterium tumefaciens transformation system for C. glabrata. A number of parameters were investigated to determine their effect on transformation frequency, and then an optimized protocol was developed. The optimal conditions for the transformation of C. glabrata were found to be an infection incubation temperature of 26 °C, 0.2 mM acetosyringone in both induction media and co-culture media, 0.7% agar concentration, and a multiplicity of infection of 50:1 A. tumefaciens to C. glabrata. Importantly, the frequency of multiple integrations was low (5%), demonstrating that A. tumefaciens generally integrates at single sites in C. glabrata, which is consistent with other fungal A. tumefaciens transformation systems. The development of this system in C. glabrata adds another tool for the molecular manipulation of this increasingly important fungal pathogen.