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A comprehensive analysis of the glucocorticoid-sensitive pro-inflammatory genes in macrophages reveals fundamental differences between the temporal events and components of transcriptional machinery that the glucocorticoid receptor targets to repress their transcription.

TRPM3 inhibition is identified as a novel mechanism for G-protein βγ subunit signalling.

Unprecedented resolution of the molecular mechanisms of plant membrane protein anchoring involving phospholipids and sterols reveals the control of spatio-temporal segregation into plasma membrane nanodomains.

An atypical subtilase protein, resulting from an alternative splicing event, mediates retention of the defence related-transcription factor MYB30 at endosomal vesicles, thus repressing Arabidopsis antibacterial immunity.

The dynein light intermediate chain is a member of the G protein superfamily and links the motor to several intracellular cargo adaptors.

The combined use of NAD+ with ribitol or ribose potentiates the rescue of α-dystroglycan functional glycosylation in FKRP-mutant patient-specific iPSC-derived myotubes, representing potential novel treatments for FKRP muscular dystrophies.

New transgenic mice, which can be ablated both orexin neurons and MCH neurons, showed new brain state and revealed functional interaction that MCH neurons have protective role in narcolepsy symptoms.

Genetic and biochemical analyses demonstrate that cell-surface lectin receptors can potentially function as extracellular NAD⁺-binding receptors and provide direct evidence for extracellular NAD⁺ being a bona fide endogenous signaling molecule in plants.

Disruption of the LG domain-binding phospho-ribitol-containing O-mannose structures on α-dystroglycan results in congenital muscular dystrophy.

A plant peptide hormone controls organ shedding by acting as molecular glue that promotes the interaction between two membrane receptor kinases.