Summary
In animals, networks of clock neurons containing molecular clocks orchestrate daily rhythms in physiology and behavior. How various types of clock neurons communicate and coordinate with one another to produce coherent circadian rhythms is not well understood. Here, we investigate clock neuron coupling in the brain of Drosophila and demonstrate that the fly’s various groups of clock neurons display unique and complex coupling relationships to core pacemaker neurons. Furthermore, we find that coordinated free-running rhythms require molecular clock synchrony not only within the well-characterized lateral clock neuron classes, but also between lateral clock neurons and dorsal clock neurons. These results uncover unexpected patterns of coupling in the clock neuron network and reveal that robust free-running behavioral rhythms require a coherence of molecular oscillations across most of the fly’s clock neuron network.
DNA double-strand break (DSB) repair by homologous recombination (HR) is thought to be restricted to the S- and G2- phases of the cell cycle in part due to 53BP1 antagonizing DNA end resection in G1-phase and non-cycling quiescent (G0) cells. Here, we show that LIN37, a component of the DREAM transcriptional repressor, functions in a 53BP1-independent manner to prevent DNA end resection and HR in G0 cells. Loss of LIN37 leads to the expression of HR proteins, including BRCA1, BRCA2, PALB2, and RAD51, and promotes DNA end resection in G0 cells even in the presence of 53BP1. In contrast to 53BP1-deficiency, DNA end resection in LIN37-deficient G0 cells depends on BRCA1 and leads to RAD51 filament formation and HR. LIN37 is not required to protect DNA ends in cycling cells at G1-phase. Thus, LIN37 regulates a novel 53BP1-independent cell phase-specific DNA end protection pathway that functions uniquely in quiescent cells.
This
work describes the discovery of a bead-bound membrane-active
peptide (MAP), LBF127, that selectively binds fungal giant unilamellar
vesicles (GUVs) over mammalian GUVs. LBF127 was re-synthesized in
solution form and demonstrated to have antifungal activity with limited
hemolytic activity and cytotoxicity against mammalian cells. Through
systematic structure–activity relationship studies, including
N- and C-terminal truncation, alanine-walk, and d-amino acid
substitution, an optimized peptide, K-oLBF127, with higher potency,
less hemolytic activity, and cytotoxicity emerged. Compared to the
parent peptide, K-oLBF127 is shorter by three amino acids and has
a lysine at the N-terminus to confer an additional positive charge.
K-oLBF127 was found to have improved selectivity toward the fungal
membrane over mammalian membranes by 2-fold compared to LBF127. Further
characterizations revealed that, while K-oLBF127 exhibits a spectrum
of antifungal activity similar to that of the original peptide, it
has lower hemolytic activity and cytotoxicity against mammalian cells.
Mice infected with Cryptococcus neoformans and treated
with K-oLBF127 (16 mg/kg) for 48 h had significantly lower lung fungal
burden compared to untreated animals, consistent with K-oLBF127 being
active in vivo. Our study demonstrates the success
of the one-bead, one-compound high-throughput strategy and sequential
screening at identifying MAPs with strong antifungal activities.
T helper 17 (Th17) cells develop in response to T cell receptor signals (TCR) in the presence of specific environments, and produce the inflammatory cytokine IL17A. These cells have been implicated in a number of inflammatory diseases and represent a potential target for ameliorating such diseases. The kinase ITK, a critical regulator of TCR signals, has been shown to be required for the development of Th17 cells. However, we show here that lung inflammation induced by Saccharopolyspora rectivirgula (SR) induced Hypersensitivity pneumonitis (SR-HP) results in a neutrophil independent, and ITK independent Th17 responses, although ITK signals are required for γδ T cell production of IL17A. Transcriptomic analysis of resultant ITK independent Th17 cells suggest that the SR-HP-induced extrinsic inflammatory signals may override intrinsic T cell signals downstream of ITK to rescue Th17 responses in the absence of ITK. These findings suggest that the ability to pharmaceutically target ITK to suppress Th17 responses may be dependent on the type of inflammation.
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