RNA-activated DNA cleavage by the Type III-B CRISPR-Cas effector complex.

The CRISPR (clustered regularly interspaced short palindromic repeat) system is an RNA-guided immune system that protects prokaryotes from invading genetic elements. This system represents an inheritable and adaptable immune system that is mediated by multisubunit effector complexes. In the Type III-B system, the Cmr effector complex has been found to cleave ssRNA in vitro. However, in vivo, it has been implicated in transcription-dependent DNA targeting. We show here that the Cmr complex from Thermotoga maritima can cleave an ssRNA target that is complementary to the CRISPR RNA. We also show that binding of a complementary ssRNA target activates an ssDNA-specific nuclease activity in the histidine-aspartate (HD) domain of the Cmr2 subunit of the complex. These data suggest a mechanism for transcription-coupled DNA targeting by the Cmr complex and provide a unifying mechanism for all Type III systems.

Target sequence requirements of a type III-B CRISPR-Cas immune system.

CRISPR-Cas systems are RNA-based immune systems that protect many prokaryotes from invasion by viruses and plasmids. Type III CRISPR systems are unique, as their targeting mechanism requires target transcription. Upon transcript binding, DNA cleavage by type III effector complexes is activated. Type III systems must differentiate between invader and native transcripts to prevent autoimmunity. Transcript origin is dictated by the sequence that flanks the 3' end of the RNA target site (called the PFS). However, how the PFS is recognized may vary among different type III systems. Here, using purified proteins and in vitro assays, we define how the type III-B effector from the hyperthermophilic bacterium Thermotoga maritima discriminates between native and invader transcripts. We show that native transcripts are recognized by base pairing at positions -2 to -5 of the PFS and by a guanine at position -1, which is not recognized by base pairing. We also show that mismatches with the RNA target are highly tolerated in this system, except for those nucleotides adjacent to the PFS. These findings define the target requirement for the type III-B system from T. maritima and provide a framework for understanding the target requirements of type III systems as a whole.

The metabolites NADP+ and NADPH are the targets of the circadian protein Nocturnin (Curled).

Nocturnin (NOCT) is a rhythmically expressed protein that regulates metabolism under the control of circadian clock. It has been proposed that NOCT deadenylates and regulates metabolic enzyme mRNAs. However, in contrast to other deadenylases, purified NOCT lacks the deadenylase activity. To identify the substrate of NOCT, we conducted a mass spectrometry screen and report that NOCT specifically and directly converts the dinucleotide NADP+ into NAD+ and NADPH into NADH. Further, we demonstrate that the Drosophila NOCT ortholog, Curled, has the same enzymatic activity. We obtained the 2.7 Šcrystal structure of the human NOCT•NADPH complex, which revealed that NOCT recognizes the chemically unique ribose-phosphate backbone of the metabolite, placing the 2'-terminal phosphate productively for removal. We provide evidence for NOCT targeting to mitochondria and propose that NADP(H) regulation, which takes place at least in part in mitochondria, establishes the molecular link between circadian clock and metabolism.

Crystal Structure of Human Nocturnin Catalytic Domain.

Nocturnin (NOCT) helps the circadian clock to adjust metabolism according to day and night activity. NOCT is upregulated in early evening and it has been proposed that NOCT serves as a deadenylase for metabolic enzyme mRNAs. We present a 2.7-Å crystal structure of the catalytic domain of human NOCT. Our structure shows that NOCT has a close overall similarity to CCR4 deadenylase family members, PDE12 and CNOT6L, and to a DNA repair enzyme TDP2. All the key catalytic residues present in PDE12, CNOT6L and TDP2 are conserved in NOCT and have the same conformations. However, we observe substantial differences in the surface properties of NOCT, an unexpectedly narrow active site pocket, and conserved structural elements in the vicinity of the catalytic center, which are unique to NOCT and absent in the deadenylases PDE12/CNOT6L. Moreover, we show that in contrast to human PDE12 and CNOT6L, NOCT is completely inactive against poly-A RNA. Our work thus reveals the structure of an intriguing circadian protein and suggests that NOCT has considerable differences from the related deadenylases, which may point to a unique cellular function of this enzyme.