Functional responses between PMP3 small membrane proteins and membrane potential.

The Plasma Membrane Proteolipid 3 (PMP3, UPF0057 family in Uniprot) family consists of abundant small hydrophobic polypeptides with two predicted transmembrane helices. Plant homologues were upregulated in response to drought/salt-stresses and yeast deletion mutants exhibited conditional growth defects. We report here abundant expression of Group I PMP3 homologues (PMP3(i)hs) during normal vegetative growth in both prokaryotic and eukaryotic cells, at a level comparable to housekeeping genes, implicating the regular cellular functions. Expression of eukaryotic PMP3(i)hs was dramatically upregulated in response to membrane potential (Vm) variability (Vmvar ), whereas PMP3(i)hs deletion-knockdown led to Vm changes with conditional growth defects. Bacterial PMP3(i)h yqaE deletion led to a shift of salt sensitivity; Vmvar alternations with exogenous K+ addition downregulated prokaryotic PMP3(i)hs, suggesting [K+ ]-Vmvar axis being a significant feedback element in prokaryotic ionic homeostasis. Remarkably, the eukaryotic homologues functionally suppressed the conditional growth defects in bacterial deletion mutant, demonstrating the conserved cross-kingdom membrane functions by PMP3(i)hs. These data demonstrated a direct reciprocal relationship between PMP3(i)hs expression and Vm differentials in both prokaryotic and eukaryotic cells. Cumulative with PMP3(i)hs ubiquitous abundance, their lipid-binding selectivity and membrane protein colocalization, we propose [PMP3(i)hs]-Vmvar axis as a key element in membrane homeostasis.

SET8 plays a role in controlling G1/S transition by blocking lysine acetylation in histone through binding to H4 N-terminal tail.

We report evidence suggesting that methyltransferase SET8 plays a novel role in regulating cell cycle by suppressing DNA replication through histone binding. First, the distribution of SET8 is strongly cell cycle-dependent. SET8 was concentrated in the nucleus during G(1) and G(2) phases, and was excluded from the nucleus during S phase. Second, at G(1)/S transition, SET8 was degraded through ubiquitination via SCF/Skp2. Third, it was evident that the SET8 binds to the H4 N-terminal tail (H4NT) and blocks the acetylation of lysine residues K5, K8 and K12 of histone H4 during G(1). Such a blockage can hinder DNA replication. Fourth, SET8 binds to hypoacetylated but not hyperacetylated H4NT. Finally, overexpressing the histone-binding domain of SET8 appeared to suppress DNA replication and arrest the cell cycle before the G(1)/S transition. Taken together, these findings suggest that SET8 can be a negative regulator of DNA replication and the destruction of SET8 is required for the onset of S phase.

Measuring dynamics of caspase-8 activation in a single living HeLa cell during TNFalpha-induced apoptosis.

In this study, we reported the first measurement of the dynamics of activation of caspase-8 in a single living cell. This measurement was conducted using a specially developed molecular sensor based on the FRET (fluorescence resonance energy transfer) technique. This sensor was constructed by fusing a CFP (cyan fluorescent protein) and a YFP (yellow fluorescent protein) with a linker containing a tandem caspase-8-specific cleavage site. The change of the FRET ratio upon cleavage was larger than 4-fold. Using this sensor, we found that during TNFalpha-induced apoptosis, the activation of caspase-8 was a slower process than that of caspase-3, and it was initiated much earlier than the caspase-3 activation. Inhibition of caspase-9 delayed the full activation of caspase-3 but did not affect the dynamics of caspase-8. Results of these single-cell measurements suggested that caspase-3 was activated by caspase-8 through two parallel pathways during TNFalpha-induced apoptosis in HeLa cells.