Takahide Yokoi

NEAT1 long noncoding RNA regulates transcription via protein sequestration within subnuclear bodies.

Paraspeckles are subnuclear structures formed around NEAT1 lncRNA. Paraspeckles became enlarged after proteasome inhibition caused by NEAT1 transcriptional activation, leading to protein sequestration into paraspeckles. The NEAT1-dependent sequestration affects the transcription of several genes, arguing for a novel role for lncRNA in gene regulation.

Efficient oligonucleotide-mediated degradation of nuclear noncoding RNAs in mammalian cultured cells

Recent large-scale transcriptome analyses have revealed that large numbers of noncoding RNAs (ncRNAs) are transcribed from mammalian genomes. They include small nuclear RNAs (snRNAs), small nucleolar RNAs (snoRNAs), and longer ncRNAs, many of which are localized to the nucleus, but which have remained functionally elusive. Since ncRNAs are only known to exist in mammalian species, established experimental systems, including the Xenopus oocyte system and yeast genetics, are not available for functional analysis. RNA interference (RNAi), commonly used for analysis of protein-coding genes, is effective in eliminating cytoplasmic mRNAs, but not nuclear RNAs. To circumvent this problem, we have refined the system for knockdown of nuclear ncRNAs with chemically modified chimeric antisense oligonucleotides (ASO) that were efficiently introduced into the nucleus by nucleofection. Under optimized conditions, our system appeared to degrade at least 20 different nuclear ncRNA species in multiple mammalian cell lines with high efficiency and specificity. We also confirmed that our method had greatly improved knockdown efficiency compared with that of the previously reported method in which ASOs are introduced with transfection reagents. Furthermore, we have confirmed the expected phenotypic alterations following knockdown of HBII295 snoRNA and U7 snRNA, which resulted in a loss of site-specific methylation of the artificial RNA and the appearance of abnormal polyadenylated histone mRNA species with a concomitant delay of the cell cycle S phase, respectively. In summary, we believe that our system is a powerful tool to explore the biological functions of the large number of nuclear ncRNAs with unknown function.

Transcripts of unknown function in multiple-signaling pathways involved in human stem cell differentiation.

Mammalian transcriptome analysis has uncovered tens of thousands of novel transcripts of unknown function (TUFs). Classical and recent examples suggest that the majority of TUFs may underlie vital intracellular functions as non-coding RNAs because of their low coding potentials. However, only a portion of TUFs have been studied to date, and the functional significance of TUFs remains mostly uncharacterized. To increase the repertoire of functional TUFs, we screened for TUFs whose expression is controlled during differentiation of pluripotent human mesenchymal stem cells (hMSCs). The resulting six TUFs, named transcripts related to hMSC differentiation (TMDs), displayed distinct transcriptional kinetics during hMSC adipogenesis and/or osteogenesis. Structural and comparative genomic characterization suggested a wide variety of biologically active structures of these TMDs, including a long nuclear non-coding RNA, a microRNA host gene and a novel small protein gene. Moreover, the transcriptional response to established pathway activators indicated that most of these TMDs were transcriptionally regulated by each of the two key pathways for hMSC differentiation: the Wnt and protein kinase A (PKA) signaling pathways. The present study suggests that not only TMDs but also other human TUFs may in general participate in vital cellular functions with different molecular mechanisms.

Slowing single-stranded DNA translocation through a solid-state nanopore by decreasing the nanopore diameter

To slow the translocation of single-stranded DNA (ssDNA) through a solid-state nanopore, a nanopore was narrowed, and the effect of the narrowing on the DNA translocation speed was investigated. In order to accurately measure the speed, long (5.3 kb) ssDNA (namely, ss-poly(dA)) with uniform length (±0.4 kb) was synthesized. The diameters of nanopores fabricated by a transmission electron microscope were controlled by atomic-layer deposition. Reducing the nanopore diameter from 4.5 to 2.3 nm slowed down the translocation of ssDNA by more than 16 times (to 0.18 μs base(-1)) when 300 mV was applied across the nanopore. It is speculated that the interaction between the nanopore and the ssDNA dominates the translocation speed. Unexpectedly, the translocation speed of ssDNA through the 4.5 nm nanopore is more than two orders of magnitude higher than that of double-stranded DNA (dsDNA) through a nanopore of almost the same size. The cause of such a faster translocation of ssDNA can be explained by the weaker drag force inside the nanopore. Moreover, the measured translocation speeds of ssDNA and dsDNA agree well with those calculated by molecular-dynamics (MD) simulation. The MD simulation predicted that reducing the nanopore diameter to almost the same as that of ssDNA (i.e. 1.4 nm) decreases the translocation speed (to 1.4 μs base(-1)). Narrowing the nanopore is thus an effective approach for accomplishing nanopore DNA sequencing.

Evaluation of a new experimental kit for the extraction of DNA from bones and teeth using a non-powder method.

An experimental DNA extraction kit (new kit) was recently developed to extract DNA from degraded skeletal remains without the need for powdering the samples. We compared the utility of the new kit with the conventional phenol/chloroform method using real-time quantitative PCR and multiplex STR analysis. The new kit yielded large amounts of DNA from a compact bone fragment compared with the conventional phenol/chloroform method. We were able to extract sufficient DNA for STR analysis from 75% (3 of 4) and 60% (3 of 5) of the un-powdered tooth and bone samples, respectively, using the new kit. We were able to perform mini-STR analysis of the remaining samples using DNA extracted with the new kit. Furthermore, we successfully performed mitochondrial DNA sequencing of every sample. The new kit simplifies the DNA extraction procedure as it does not require powdering samples. Decreasing the number of procedural steps in DNA extraction will be beneficial in controlling DNA contamination in laboratories. Our results suggest that the new kit may be used for the simple, simultaneous extraction of DNA from multiple samples.

Integrated solid-state nanopore platform for nanopore fabrication via dielectric breakdown, DNA-speed deceleration and noise reduction

The practical use of solid-state nanopores for DNA sequencing requires easy fabrication of the nanopores, reduction of the DNA movement speed and reduction of the ionic current noise. Here, we report an integrated nanopore platform with a nanobead structure that decelerates DNA movement and an insulating polyimide layer that reduces noise. To enable rapid nanopore fabrication, we introduced a controlled dielectric breakdown (CDB) process into our system. DNA translocation experiments revealed that single nanopores were created by the CDB process without sacrificing performance in reducing DNA movement speed by up to 10 μs/base or reducing noise up to 600 pArms at 1 MHz. Our platform provides the essential components for proceeding to the next step in the process of DNA sequencing.

Deceleration of single-stranded DNA passing through a nanopore using a nanometre-sized bead structure.

DNA sequencing with a solid-state nanopore requires a reduction of the translocation speeds of single-stranded DNA (ssDNA) over 10 μs/base. In this study, we report that a nanometre-sized bead structure constructed around a nanopore can reduce the moving speed of ssDNA to 270 μs/base by adjusting the diameter of the bead and its surface chemical group. This decelerating effect originates from the strong interaction between ssDNA and the chemical group on the surface of the bead. This nanostructure was simply prepared by dip coating in which a substrate with a nanopore was immersed in a silica bead solution and then dried in an oven. As compared with conventional approaches, our novel method is less laborious, simpler to perform and more effective in reducing ssDNA translocation speed.

A novel side-gated ultrathin-channel nanopore FET (SGNAFET) sensor for direct DNA sequencing

A novel side-gated ultrathin-channel nanopore FET (SGNAFET), for fast and label-free DNA sequencing with high resolution and sensitivity, is proposed. The goal of the SGNAFET is to identify the four types of nucleotides in DNA by changes in the channel current of the SGNAFET. Aiming to reach that goal, a SGNAFET with channel thickness (tch.) of 2 or 4 nm was successfully operated and could detect DNA translocations through its nanopore on the basis of changes in its channel current.

Genes that integrate multiple adipogenic signaling pathways in human mesenchymal stem cells.

Adipogenesis is a well-characterized cell differentiation process. A large body of evidence has revealed the core transcription factors and signaling pathways that govern adipogenesis, but cross-talks between these cellular signals and its functional consequences have not been thoroughly investigated. We, therefore, sought to identify genes that are regulated by multiple signaling pathways during adipogenesis of human mesenchymal stem cells. Focusing on the early stage of adipogenesis, microarray analysis and quantitative RT-PCR identified 12 genes whose transcription levels were dramatically affected by the complete adipogenic induction cocktail but not by the cocktails individual components. Expression kinetics of these genes indicate diverse mechanisms of transcriptional regulation during adipogenesis. Functional relationships between these genes and adipogenic differentiation were frequently unknown. This study thus provided novel adipogenic gene candidates that likely mediate communications among multiple signaling pathways within human mesenchymal stem cells.

On-chip base sequencing using a two-stage reaction-control scheme: 3.6-times-faster and 1/100-reduced-data-volume ISFET-based DNA sequencer

A novel two-stage reaction-control scheme with a background-cancelling circuit - for reducing data volume and analysis time of an ion-sensitive-FET (ISFET) - based DNA sequencer-is proposed. The scheme successfully reduces the background noise and renders time-consuming background analysis unnecessary. It also reduces sample-to-data time by 72% (3.6 times faster) and data volume by two orders of magnitude.