RIP1 negatively regulates basal autophagic flux through TFEB to control sensitivity to apoptosis.

In a synthetic lethality/viability screen, we identified the serine-threonine kinase RIP1 (RIPK1) as a gene whose knockdown is highly selected against during growth in normal media, in which autophagy is not critical, but selected for in conditions that increase reliance on basal autophagy. RIP1 represses basal autophagy in part due to its ability to regulate the TFEB transcription factor, which controls the expression of autophagy-related and lysosomal genes. RIP1 activates ERK, which negatively regulates TFEB though phosphorylation of serine 142. Thus, in addition to other pro-death functions, RIP1 regulates cellular sensitivity to pro-death stimuli by modulating basal autophagy.

A calmodulin-like protein in the bacterial genus Streptomyces.

The gene, named cabB, encoding a calmodulin-like protein of 70 amino acids containing two helix-loop-helix EF-hand motifs was cloned from Streptomyces coelicolor A3(2). cabB was transcribed from a single promoter throughout growth. The CabB protein produced in Escherichia coli was a monomer in solution, although it corresponded to one half of a dumbbell shape of the eukaryotic calmodulins. CabB bound calcium and upon binding of calcium its alpha-helix content was increased, as determined by circular dichroism spectroscopy. The growth of cabB-disruptants (mutant DeltacabB) on minimal agar medium containing calcium higher than 20 mM was delayed, suggesting that CabB has a role in calcium homeostasis by serving as a calcium buffer or transporter, as suggested for calerythrin in actinomycetes and the invertebrate sarcoplasmic calcium-binding proteins. Wide distribution of cabB almost exclusively in actinomycetes suggests a common role of EF-hand CabB-type proteins in these filamentous, soil-dwelling Gram-positive bacterial genera.

Autophagy and cell death.

Autophagy is intimately associated with eukaryotic cell death and apoptosis. Indeed, in some cases the same proteins control both autophagy and apoptosis. Apoptotic signalling can regulate autophagy and conversely autophagy can regulate apoptosis (and most likely other cell death mechanisms). However, the molecular connections between autophagy and cell death are complicated and, in different contexts, autophagy may promote or inhibit cell death. Surprisingly, although we know that, at its core, autophagy involves degradation of sequestered cytoplasmic material, and therefore presumably must be mediating its effects on cell death by degrading something, in most cases we have little idea of what is being degraded to promote autophagy's pro- or anti-death activities. Because autophagy is known to play important roles in health and many diseases, it is critical to understand the mechanisms by which autophagy interacts with and affects the cell death machinery since this will perhaps allow new ways to prevent or treat disease. In the present chapter, we discuss the current state of understanding of these processes.

PinX1 localizes to telomeres and stabilizes TRF1 at mitosis.

Human telomeres are DNA-protein complexes that cap and protect the ends of chromosomes. The protein PinX1 associates with telomeres through an interaction with the resident double-stranded telomere-binding protein TRF1. PinX1 also binds to and inhibits telomerase, the enzyme responsible for complete replication of telomeric DNA. We now report that endogenous PinX1 associates with telomeres primarily at mitosis. Moreover, knockdown of PinX1 caused delayed mitotic entry and reduced the accumulation of TRF1 on telomeres during this stage of the cell cycle. Taking these findings together, we suggest that one function of PinX1 is to stabilize TRF1 during mitosis, perhaps to promote transition into M phase of the cell cycle.

Involvement of amfC in physiological and morphological development in Streptomyces coelicolor A3(2).

amfC plays a regulatory role in aerial mycelium formation in Streptomyces griseus and is distributed widely among Streptomyces species. Disruption of the chromosomal amfC gene in Streptomyces coelicolor A3(2) severely reduced formation of aerial hyphae, indicating that amfC is important in morphological development. In addition, the disruption caused S. coelicolor A3(2) M130 to produce much less actinorhodin, and to produce undecylprodigiosin at a later stage of growth, indicating that amfC also regulates secondary metabolism. S1 nuclease mapping showed that transcription of actII-ORF4, the pathway-specific transcriptional activator in the act gene cluster, was greatly reduced in the amfC disruptants. The defect in secondary metabolite formation was suppressed or overcome by a mutation in sre-1. Consequently, an amfC-disrupted strain derived from S. coelicolor A3(2) M145, an actinorhodin-overproducing strain due to the sre-1 mutation, still produced a large amount of actinorhodin. Extra copies of amfC in strains M130 and M145 did not change spore-chain morphology or secondary metabolite formation. However, the spores in these strains remained white even after prolonged incubation. Since only spore pigmentation was affected, all known whi genes, except whiE, responsible for the polyketide spore pigment formation, were assumed to function normally. S1 nuclease mapping showed that transcription of whiEP1, one of the promoters in the whiE locus, was reduced in S. coelicolor A3(2) containing extra copies of amfC. Introducing amfC into several other Streptomyces species, such as Streptomyces lividans, Streptomyces lavendulae and Streptomyces lipmanii, also abolished spore pigment formation. An increase in the amount of AmfC appeared to disturb the maturation of spores.