Evaluation of cellular activity in response to sleep deprivation by a comprehensive analysis of the whole mouse brain.

Sleep deprivation (SD) causes several adverse functional outcomes, and understanding the associated processes can improve quality of life. Although the effects of SD on neuronal activity in several brain regions have been identified, a comprehensive evaluation of the whole brain is still lacking. Hence, we performed SD using two different methods, gentle handling and a dedicated chamber, in targeted recombination in active populations 2 (TRAP2) mice crossed with Rosa-ZsGreen reporter mice and visualized cellular activity in the whole brain. Using the semi-automated post-imaging analysis tool Slice Histology Alignment, Registration, and Cell Quantification (SHARCQ), the number of activated cells was quantified. From the analysis of 14 brain regions, cellular activity was significantly increased in the olfactory areas and decreased in the medulla by the two SD methods. From the analysis of the further subdivided 348 regions, cellular activity was significantly increased in the vascular organ of the lamina terminalis, lateral hypothalamic area, parabigeminal nucleus, ventral tegmental area, and magnocellular reticular nucleus, and decreased in the anterior part of the basolateral amygdalar nucleus, nucleus accumbens, septohippocampal nucleus, reticular nucleus of the thalamus, preoptic part of the periventricular hypothalamic nucleus, ventromedial preoptic nucleus, rostral linear nucleus raphe, facial motor nucleus, vestibular nuclei, and some fiber tracts (oculomotor nerve, genu of corpus callosum, and rubrospinal tract) by the two SD methods. Two subdivided regions of the striatum (caudoputamen and other striatum), epithalamus, vascular organ of the lamina terminalis, anteroventral preoptic nucleus, superior colliculus optic layer, medial terminal nucleus of the accessory optic tract, pontine gray, and fiber tracts (medial lemniscus, columns of the fornix, brachium of the inferior colliculus, and mammillary peduncle) were differentially affected by the two SD methods. Most brain regions detected from these analyses have been reported to be involved in regulating sleep/wake regulatory circuits. Moreover, the results from the connectivity analysis indicated that the connectivity of cellular activity among brain regions was altered by SD. Together, such a comprehensive analysis of the whole brain is useful for understanding the mechanisms by which SD and/or sleep disruption affects brain function.

Sleep-wake patterns are altered with age, Prdm13 signaling in the DMH, and diet restriction in mice.

Old animals display significant alterations in sleep-wake patterns such as increases in sleep fragmentation and sleep propensity. Here, we demonstrated that PR-domain containing protein 13 (Prdm13)+ neurons in the dorsomedial hypothalamus (DMH) are activated during sleep deprivation (SD) in young mice but not in old mice. Chemogenetic inhibition of Prdm13+ neurons in the DMH in young mice promotes increase in sleep attempts during SD, suggesting its involvement in sleep control. Furthermore, DMH-specific Prdm13-knockout (DMH-Prdm13-KO) mice recapitulated age-associated sleep alterations such as sleep fragmentation and increased sleep attempts during SD. These phenotypes were further exacerbated during aging, with increased adiposity and decreased physical activity, resulting in shortened lifespan. Dietary restriction (DR), a well-known anti-aging intervention in diverse organisms, ameliorated age-associated sleep fragmentation and increased sleep attempts during SD, whereas these effects of DR were abrogated in DMH-Prdm13-KO mice. Moreover, overexpression of Prdm13 in the DMH ameliorated increased sleep attempts during SD in old mice. Therefore, maintaining Prdm13 signaling in the DMH might play an important role to control sleep-wake patterns during aging.

Stimulating Macropinocytosis for Intracellular Nucleic Acid and Protein Delivery: A Combined Strategy with Membrane-Lytic Peptides To Facilitate Endosomal Escape.

Delivery of biomacromolecules via endocytic pathways requires the efficient accumulation of cargo molecules into endosomes, followed by their release to the cytosol. We propose a unique intracellular delivery strategy for bioactive molecules using a new potent macropinocytosis-inducing peptide derived from stromal-derived factor 1α (SN21). This peptide allowed extracellular materials to enter cells through the activation of macropinocytosis. To provide the ability to release internalized cargoes from endosomes, we conjugated SN21 with membrane-lytic peptides. The combination of a macropinocytosis-inducing peptide and a membrane-lytic peptide successfully delivered functional siRNA and proteins, which include antibodies, Cre recombinase, and an artificial transcription regulator protein having a transcription activator-like effector (TALE) motif. This study shows the feasibility of combining the physiological stimulation of macropinocytosis with the physicochemical disruption of endosomes as a strategy for intracellular delivery.

Modified nucleobase-specific gene regulation using engineered transcription activator-like effectors.

Epigenetic modification, as typified by cytosine methylation, is a key aspect of gene regulation that affects many biological processes. However, the biological roles of individual methylated cytosines are poorly understood. Sequence-specific DNA recognition tools can be used to investigate the roles of individual instances of DNA methylation. Transcription activator-like effectors (TALEs), which are DNA-binding proteins, are promising candidate tools with designable sequence specificity and sensitivity to DNA methylation. In this review, we describe the bases of DNA recognition of TALEs, including methylated cytosine recognition, and the applications of TALEs for the study of methylated DNA. In addition, we discuss TALE-based epigenome editing and oxidized methylated cytosine recognition.

Sequence-specific 5mC detection in live cells based on the TALE-split luciferase complementation system.

We established a method for converting TALE-DNA binding to luminescence, by combining a TALE and a split luciferase system. Furthermore, using a methylation-sensitive TALE, sequence-specific 5mC detection of genomic DNA was achieved in live cells. This study provides a new strategy for exploring the biological functions of 5mC.

Nested PUF Proteins: Extending Target RNA Elements for Gene Regulation.

RNA-binding proteins recognizing unique sequences within large transcriptomes serve as a powerful tool to control RNA metabolism. Pumilio and fem-3 mRNA-binding factor (PUF) proteins are considered good candidates for such tools, because they are typically composed of eight highly homologous repeat segments and can be designed to recognize arbitrary 8 nt RNA sequences. However, a specific 8 nt RNA sequence is found at multiple sites in various RNAs in the transcriptome, making it difficult to specifically target a single RNA. Designer PUF proteins recognizing longer RNA sequences should achieve more selective binding. Here, we propose an approach for creating 16-repeat PUFs capable of targeting a single, unique mRNA in the transcriptome. Our design is simple and involves either the tandem alignment of two PUF segments or the nesting of one PUF segment within another. Designed 16-repeat PUFs bound to the target RNA sequence without partial recognition derived from the original 8-repeat PUF. Furthermore, based on our strategy, expression of an endogenous mRNA was selectively and effectively modulated, demonstrating the applicability of 16-repeat PUF proteins for regulating endogenous RNA metabolism.

Detection of N6-methyladenosine based on the methyl-sensitivity of MazF RNA endonuclease.

We found that Escherichia coli MazF toxin, an ACA-sequence-specific endoribonuclease, was sensitive to N6-methyladenosine (m6A), representing the first m6A-sensitive RNA cleavage enzyme. The methyl-sensitivity of MazF allowed simple analyses of both m6A demethylase and methyltransferase activity. Furthermore, the approach could be used for inhibitor screening.

Sequence-specific recognition of methylated DNA by an engineered transcription activator-like effector protein.

A 5mC-selective TALE-repeat was created by screening a TALE repeat library containing randomized amino acids at repeat variable diresidues and their neighboring residues. The new repeat showed high 5mC discrimination ability. An artificial TALE containing the new repeat activated an endogenous gene in a genomic methylation status-dependent manner.

Enhanced secretion of natto phytase by Bacillus subtilis.

Phytases comprise a group of phosphatases that trim inorganic phosphates from phytic acid (IP6). In this study, we aimed to achieve the efficient secretion of phytase by Bacillus subtilis. B. subtilis laboratory standard strain 168 and its derivatives exhibit no phytase activity, whereas a natto starter secretes phytase actively. The natto phytase gene was cloned into strain RIK1285, a protease-defective derivative of 168, to construct a random library of its N-terminal fusions with 173 different signal peptides (SPs) identified in the 168 genome. The library was screened to assess the efficiency of phytase secretion based on clear zones around colonies on plates, which appeared when IP6 was hydrolyzed. The pbp SP enhanced the secretion of the natto phytase most efficiently, i.e. twice that of the original SP. Thus, the secreted natto phytase was purified and found to remove up to 3 phosphates from IP6.

Secretion of heterologous thermostable cellulases in Bacillus subtilis.

Bacillus subtilis is used industrially for the production of secreted enzymes. The most characteristic feature of the secreted enzymes is variation in the N-terminal signal peptides that is recognized by secretion machinery, which is one of the determinants of efficiency and must be customized in each case. Culturing cellulolytic B. subtilis to secrete heterologous cellulases combined with customized signal peptides would be beneficial for producing biocommodities from cellulosic biomass. Four Clostridium thermocellum genes, encoding endoglucanases (celA and celB) and exoglucanases (celK and celS) were cloned to construct random libraries of combinations with 173 different signal peptides originating from the B. subtilis genome. The libraries were successfully screened to identify the signal peptides most efficient in secretion of each of the four cellulases, which were theoretically unpredictable. The secreted cellulases were assayed on carboxymethyl cellulose, phosphoric acid swollen cellulose, and microcrystalline cellulose to determine the possible effects of the signal peptides on substrate specificity. The customized signal peptides for CelA, CelB, and CelS did not affect enzyme performance but those for CelK might influence its substrate specificity.

Creating a TALE protein with unbiased 5'-T binding.

Transcription activator-like effectors (TALEs) are convenient tools for genome engineering at specific genomic sites. However, their use is constrained because most TALE binding sites are preceded by a highly conserved 5' terminal T nucleotide (5'-T). To remove the 5'-T constraint, we substituted tryptophan 232 in the repeat-1 loop region of the dHax3 N-terminal domain for other amino acids. Furthermore, we randomized four amino acid residues of the hairpin loop region of repeat-1. Although point mutation was insufficient to remove the 5'-T constraint, directed evolution from the randomized library yielded repeat-1 mutants with unbiased targeting sites for 5'-bases. Our result indicates that the repeat-1 loop region of dHax3 is important for 5'-base accommodation, and that molecular evolution of repeat-1 of TALEs is an efficient strategy to remove the 5'-T constraint and thus allow targeting of any DNA sequences.

Zn(II) binding and DNA binding properties of ligand-substituted CXHH-type zinc finger proteins.

CCHH-type zinc fingers are among the most common DNA binding motifs found in eukaryotes. In a previous report, we substituted the second ligand cysteine residue with aspartic acid, producing a Zn(II)-responsive transcription factor; this indicates that a ligand substitution is a possible design target of an engineered zinc finger peptide. Despite the importance of Zn(II) binding with respect to the folding and DNA binding properties of a zinc finger peptide, no study about the effects of ligand substitution on both Zn(II) binding and DNA binding properties has been reported. Here, we substituted a conserved cysteine (C) with other zinc-coordinated amino acid residues, histidine (H), aspartic acid (D), and glutamic acid (E), to create CXHH-type zinc finger peptides (X = C, H, D, and E). The Zn(II)-dependent conformational change was observed in all peptides; however, the Zn(II) binding affinity and metal coordination geometry of the peptides were different. Gel mobility shift assays showed that the Zn(II)-bound forms of the ligand-substituted derivatives retain DNA binding ability, while the DNA binding affinity decreased in the following manner: CCHH > CDHH > CEHH ≫ CHHH. The DNA binding sequence preferences of the ligand-substituted derivatives were similar to that of the wild type in the context of the full three-finger DNA-binding domain of transcription factor Zif268. These results indicate that artificial zinc finger proteins with various DNA binding affinities that respond to a diverse range of Zn(II) concentrations can be designed by substituting the Zn(II) ligand.