Recombinant mycobacterial DNA-binding protein 1 with post-translational modifications boosts IFN-gamma production from BCG-vaccinated individuals' blood cells in combination with CpG-DNA.

Tuberculosis remains a large health threat, despite the availability of the tuberculosis vaccine, BCG. As BCG efficacy gradually decreases from adolescence, BCG-Prime and antigen-booster may be an efficient strategy to confer vaccine efficacy. Mycobacterial DNA-binding protein 1 (MDP1, namely Rv2986c, hupB or HU) is a major Mycobacterium tuberculosis protein that induces vaccine-efficacy by co-administration with CpG DNA. To produce MDP1 for booster-vaccine use, we have created recombinant MDP1 produced in both Escherichia coli (eMDP1) and Mycolicibacterium smegmatis (mMDP1), an avirulent rapid-growing mycobacteria. We tested their immunogenicity by checking interferon (IFN)-gamma production by stimulated peripheral blood cells derived from BCG-vaccinated individuals. Similar to native M. tuberculosis MDP1, we observed that most lysin resides in the C-terminal half of mMDP1 are highly methylated. In contrast, eMDP1 had less post-translational modifications and IFN-gamma stimulation. mMDP1 stimulated the highest amount of IFN-gamma production among the examined native M. tuberculosis proteins including immunodominant MPT32 and Antigen 85 complex. MDP1-mediated IFN-gamma production was more strongly enhanced when combined with a new type of CpG DNA G9.1 than any other tested CpG DNAs. Taken together, these results suggest that the combination of mMDP1 and G9.1 possess high potential use for human booster vaccine against tuberculosis.

Correction: Significance of a histone-like protein with its native structure for the diagnosis of asymptomatic tuberculosis.

[This corrects the article DOI: 10.1371/journal.pone.0204160.].

Improved Anti-Prion Nucleic Acid Aptamers by Incorporation of Chemical Modifications.

Nucleic acid aptamers are innovative and promising candidates to block the hallmark event in the prion diseases, that is the conversion of prion protein (PrP) into an abnormal form; however, they need chemical modifications for effective therapeutic activity. This communication reports on the development and biophysical characterization of a small library of chemically modified G-quadruplex-forming aptamers targeting the cellular PrP and the evaluation of their anti-prion activity. The results show the possibility of enhancing anti-prion aptamer properties through straightforward modifications.

Development and structural determination of an anti-PrPC aptamer that blocks pathological conformational conversion of prion protein.

Prion diseases comprise a fatal neuropathy caused by the conversion of prion protein from a cellular (PrPC) to a pathological (PrPSc) isoform. Previously, we obtained an RNA aptamer, r(GGAGGAGGAGGA) (R12), that folds into a unique G-quadruplex. The R12 homodimer binds to a PrPC molecule, inhibiting PrPC-to-PrPSc conversion. Here, we developed a new RNA aptamer, r(GGAGGAGGAGGAGGAGGAGGAGGA) (R24), where two R12s are tandemly connected. The 50% inhibitory concentration for the formation of PrPSc (IC50) of R24 in scrapie-infected cell lines was ca. 100 nM, i.e., much lower than that of R12 by two orders. Except for some antibodies, R24 exhibited the lowest recorded IC50 and the highest anti-prion activity. We also developed a related aptamer, r(GGAGGAGGAGGA-A-GGAGGAGGAGGA) (R12-A-R12), IC50 being ca. 500 nM. The structure of a single R12-A-R12 molecule determined by NMR resembled that of the R12 homodimer. The quadruplex structure of either R24 or R12-A-R12 is unimolecular, and therefore the structure could be stably formed when they are administered to a prion-infected cell culture. This may be the reason they can exert high anti-prion activity.

RNA sequence and length contribute to RNA-induced conformational change of TLS/FUS.

Translocated in liposarcoma (TLS)/fused in sarcoma (FUS) is a multitasking DNA/RNA binding protein implicated in cancer and neurodegenerative diseases. Upon DNA damage, TLS is recruited to the upstream region of the cyclin D1 gene (CCND1) through binding to the promotor associated non-coding RNA (pncRNA) that is transcribed from and tethered at the upstream region. Binding to pncRNA is hypothesized to cause the conformational change of TLS that enables its inhibitive interaction with histone acetyltransferases and resultant repression of CCND1 expression, although no experimental proof has been obtained. Here, the closed-to-open conformational change of TLS on binding pncRNA was implied by fluorescence resonance energy transfer. A small fragment (31 nucleotides) of the full-length pncRNA (602 nucleotides) was shown to be sufficient for the conformational change of TLS. Dissection of pncRNA identified the G-rich RNA sequence that is critical for the conformational change. The length of RNA was also revealed to be critical for the conformational change. Furthermore, it was demonstrated that the conformational change of TLS is caused by another target DNA and RNA, telomeric DNA and telomeric repeat-containing RNA. The conformational change of TLS on binding target RNA/DNA is suggested to be essential for biological functions.

The anti-prion RNA aptamer R12 disrupts the Alzheimer's disease-related complex between prion and amyloid ß.

The neurodegenerative disorder Alzheimer's disease (AD) is associated with the accumulation of misfolded proteins. Some recent studies suggested that amyloid beta (Aß) forms soluble oligomers, protofibrils, and fibrils; the Aß oligomers being more toxic than the fibrils. Surprisingly, these Aß oligomers reportedly bind to prion protein (PrP), which acts as a receptor on the cell membrane, possibly resulting in AD. Thus, it is thought that compounds that can disrupt the formation of the prion-Aß oligomer complex may prevent AD. Here, we demonstrate that an anti-prion RNA aptamer, R12, inhibits the interaction of PrP with Aß. Fluorescence assaying involving thioflavin S showed that wild-type PrP, a mutant of the N-terminal half of PrP, and even fragment peptides of PrP effectively inhibit Aß fibrillization. Fluorescence anisotropy revealed that R12 is capable of binding to PrP, resulting in dissociation of PrP with Aß. Consequently, the Aß that dissociated from PrP was shown to polymerize into fibrils. These spectroscopic observations were visualized by transmission electron microscopy. This is the first demonstration of the PrP-Aß interaction being disrupted by a nucleic acid. This ability of R12 highlights its therapeutic potential for treating AD pathology.

Significance of a histone-like protein with its native structure for the diagnosis of asymptomatic tuberculosis.

Tuberculosis causes the highest mortality among all single infections. Asymptomatic tuberculosis, afflicting one third of the global human population, is the major source as 5-10% of asymptomatic cases develop active tuberculosis during their lifetime. Thus it is one of important issues to develop diagnostic tools for accurately detecting asymptomatic infection. Mycobacterial DNA-binding protein 1 (MDP1) is a major protein in persistent Mycobacterium tuberculosis and has potential for diagnostic use in detecting asymptomatic infection. However, a previous ELISA-based study revealed a specificity problem; IgGs against MDP1 were detected in both M. tuberculosis-infected and uninfected individuals. Although the tertiary structures of an antigen are known to influence antibody recognition, the MDP1 structural details have not yet been investigated. The N-terminal half of MDP1, homologous to bacterial histone-like protein HU, is predicted to be responsible for DNA-binding, while the C-terminal half is assumed as totally intrinsically disordered regions. To clarify the relationship between the MDP1 tertiary structure and IgG recognition, we refined the purification method, which allow us to obtain a recombinant protein with the predicted structure. Furthermore, we showed that an IgG-ELISA using MDP1 purified by our refined method is indeed useful in the detection of asymptomatic tuberculosis.

Plastic roles of phenylalanine and tyrosine residues of TLS/FUS in complex formation with the G-quadruplexes of telomeric DNA and TERRA.

The length of a telomere is regulated via elongation and shortening processes. Telomeric DNA and telomeric repeat-containing RNA (TERRA), which both contain G-rich repeated sequences, form G-quadruplex structures. Previously, translocated in liposarcoma (TLS) protein, also known as fused in sarcoma (FUS) protein, was found to form a ternary complex with the G-quadruplex structures of telomeric DNA and TERRA. We then showed that the third RGG motif of TLS, the RGG3 domain, is responsible for the complex formation. However, the structural basis for their binding remains obscure. Here, NMR-based binding assaying revealed the interactions in the binary and ternary complexes of RGG3 with telomeric DNA or/and TERRA. In the ternary complex, tyrosine bound exclusively to TERRA, while phenylalanine bound exclusively to telomeric DNA. Thus, tyrosine and phenylalanine each play a central role in the recognition of TERRA and telomeric DNA, respectively. Surprisingly in the binary complexes, RGG3 used both tyrosine and phenylalanine residues to bind to either TERRA or telomeric DNA. We propose that the plastic roles of tyrosine and phenylalanine are important for RGG3 to efficiently form the ternary complex, and thereby regulate the telomere shortening.

DNA G-Wire Formation Using an Artificial Peptide is Controlled by Protease Activity.

The development of a switching system for guanine nanowire (G-wire) formation by external signals is important for nanobiotechnological applications. Here, we demonstrate a DNA nanostructural switch (G-wire <--> particles) using a designed peptide and a protease. The peptide consists of a PNA sequence for inducing DNA to form DNA-PNA hybrid G-quadruplex structures, and a protease substrate sequence acting as a switching module that is dependent on the activity of a particular protease. Micro-scale analyses via TEM and AFM showed that G-rich DNA alone forms G-wires in the presence of Ca2+, and that the peptide disrupted this formation, resulting in the formation of particles. The addition of the protease and digestion of the peptide regenerated the G-wires. Macro-scale analyses by DLS, zeta potential, CD, and gel filtration were in agreement with the microscopic observations. These results imply that the secondary structure change (DNA G-quadruplex <--> DNA/PNA hybrid structure) induces a change in the well-formed nanostructure (G-wire <--> particles). Our findings demonstrate a control system for forming DNA G-wire structures dependent on protease activity using designed peptides. Such systems hold promise for regulating the formation of nanowire for various applications, including electronic circuits for use in nanobiotechnologies.

Development of an RNA aptamer that acquires binding capacity against HIV-1 Tat protein via G-quadruplex formation in response to potassium ions.

For the development of K+-responsive RNA aptamers, we proposed a new general strategy that makes use of a G-quadruplex formation in response to K+. This is the first report of developing an RNA aptamer that demonstrates ON/OFF switching of its target-binding activity by sensing the addition/removal of K+.

Arid5a regulates naive CD4+ T cell fate through selective stabilization of Stat3 mRNA.

Balance in signal transducer and activator of transcription (STAT) activation is a key factor in regulating the fate of naive CD4(+)T cells. Here, we demonstrate that AT-rich interactive domain-containing protein 5a (Arid5a) in T cells directs naive CD4(+)T cells to differentiate into inflammatory CD4(+)T cells, especially Th17 cells, through selective stabilization of Stat3(but not Stat1 and Stat5) mRNA in an IL-6-dependent manner. Loss of Arid5a in T cells led to reduction of STAT3 level under Th17-polarizing conditions, whereas STAT1 and STAT5 in Arid5a-deficient T cells were highly activated compared with those of WT T cells under the same conditions. These cells displayed the feature of antiinflammatory (Il10-expressing) CD4(+)T cells. Thus, we show a T cell-intrinsic role of Arid5a on fate decisions of naive CD4(+)T cells through selective stabilization of Stat3 mRNA.

The binding specificity of Translocated in LipoSarcoma/FUsed in Sarcoma with lncRNA transcribed from the promoter region of cyclin D1.

BACKGROUND: Translocated in LipoSarcoma (TLS, also known as FUsed in Sarcoma) is an RNA/DNA binding protein whose mutation cause amyotrophic lateral sclerosis. In previous study, we demonstrated that TLS binds to long noncoding RNA, promoter-associated ncRNA-D (pncRNA-D), transcribed from the 5' upstream region of cyclin D1 (CCND1), and inhibits the expression of CCND1. RESULTS: In order to elucidate the binding specificity between TLS and pncRNA-D, we divided pncRNA-D into seven fragments and examined the binding with full-length TLS, TLS-RGG2-zinc finger-RGG3, and TLS-RGG3 by RNA pull down assay. As a result, TLS was able to bind to all the seven fragments, but the fragments containing reported recognition motifs (GGUG and GGU) tend to bind more solidly. The full-length TLS and TLS-RGG2-zinc finger-RGG3 showed a similar interaction with pncRNA-D, but the binding specificity of TLS-RGG3 was lower compared to the full-length TLS and TLS-RGG2-zinc finger-RGG3. Mutation in GGUG and GGU motifs dramatically decreased the binding, and unexpectedly, we could only detect weak interaction with the RNA sequence with stem loop structure. CONCLUSION: The binding of TLS and pncRNA-D was affected by the presence of GGUG and GGU sequences, and the C terminal domains of TLS function in the interaction with pncRNA-D.

K(+)-Responsive off-to-on switching of hammerhead ribozyme through dual G-quadruplex formation requiring no heating and cooling treatment.

Functional RNAs that switch their activities in response to K(+) may sense the intracellular (100 mM) and extracellular (5 mM) K(+) concentrations and regulate their functions accordingly. Previously, we developed a quadruplex hammerhead ribozyme (QHR) whose conformational change, from a duplex to a G-quadruplex, triggered by K(+) results in expression of the activity. However, this QHR required heating and cooling treatment (annealing) to induce the K(+)-responsive conformational change and activity. Here, we developed a new quadruplex hammerhead ribozyme (QHR) system that does not require annealing to induce the K(+)-responsive conformational change and activity. This system is composed of QHR and a G-quadruplex-forming complementary DNA strand (QCS). In the absence of K(+), QCS formed a duplex with QHR, which suppressed the residual activity. Upon elevation of the K(+) concentration, QCS dissociated from QHR was trapped in a G-quadruplex, and then QHR could form a G-quadruplex and exerted the activity. The 11.6-fold higher activity was induced by K(+) with an EC50 value of 23 mM, but not by Na(+), which is desirable when the activity switching between the intra-/extracellular environment is aimed at. This is the first report of the activation of functional RNA through a 'dual G-quadruplex formation system'.

Bifacial Base-Pairing Behaviors of 5-Hydroxyuracil DNA Bases through Hydrogen Bonding and Metal Coordination.

A novel bifacial ligand-bearing nucleobase, 5-hydroxyuracil (U(OH) ), which forms both a hydrogen-bonded base pair (U(OH) -A) and a metal-mediated base pair (U(OH) -M-U(OH) ) has been developed. The U(OH) -M-U(OH) base pairs were quantitatively formed in the presence of lanthanide ions such as Gd(III) when U(OH) -U(OH) pairs were consecutively incorporated into DNA duplexes. This result established metal-assisted duplex stabilization as well as DNA-templated assembly of lanthanide ions. Notably, a duplex possessing U(OH) -A base pairs was destabilized by addition of Gd(III) ions. This observation suggests that the hybridization behaviors of the U(OH) -containing DNA strands are altered by metal complexation. Thus, the U(OH) nucleobase with a bifacial base-pairing property holds great promise as a component for metal-responsive DNA materials.

Crosslinking reactions of 4-amino-6-oxo-2-vinylpyrimidine with guanine derivatives and structural analysis of the adducts.

DNA interstrand crosslinks (ICLs) are the primary mechanism for the cytotoxic activity of many clinical anticancer drugs, and numerous strategies for forming ICLs have been developed. One such method is using crosslink-forming oligonucleotides (CFOs). In this study, we designed a 4-amino-6-oxo-2-vinylpyrimidine (AOVP) derivative with an acyclic spacer to react selectively with guanine. The AOVP CFO exhibited selective crosslinking reactivity with guanine and thymine in DNA, and with guanine in RNA. These crosslinking reactions with guanine were accelerated in the presence of CoCl2, NiCl2, ZnCl2 and MnCl2. In addition, we demonstrated that the AOVP CFO was reactive toward 8-oxoguanine opposite AOVP in the duplex DNA. The structural analysis of each guanine and 8-oxoguanine adduct in the duplex DNA was investigated by high-resolution NMR. The results suggested that AOVP reacts at the N2 amine in guanine and at the N1 or N2 amines in 8-oxoguanine in the duplex DNA. This study demonstrated the first direct determination of the adduct structure in duplex DNA without enzyme digestion.

Boosting of activity enhancement of K(+)-responsive quadruplex hammerhead ribozyme.

Two second-generation quadruplex hammerhead ribozymes, whose activity enhances in response to K(+)via quadruplex formation of embedded r(GGA)3GG, were developed. Different strategies were applied to suppress basal activity when K(+) is absent. As a result, the activity enhancement upon the addition of K(+) has reached as high as 21-fold.

Binding of an RNA aptamer and a partial peptide of a prion protein: crucial importance of water entropy in molecular recognition.

It is a central issue to elucidate the new type of molecular recognition accompanied by a global structural change of a molecule upon binding to its targets. Here we investigate the driving force for the binding of R12 (a ribonucleic acid aptamer) and P16 (a partial peptide of a prion protein) during which P16 exhibits the global structural change. We calculate changes in thermodynamic quantities upon the R12-P16 binding using a statistical-mechanical approach combined with molecular models for water which is currently best suited to studies on hydration of biomolecules. The binding is driven by a water-entropy gain originating primarily from an increase in the total volume available to the translational displacement of water molecules in the system. The energy decrease due to the gain of R12-P16 attractive (van der Waals and electrostatic) interactions is almost canceled out by the energy increase related to the loss of R12-water and P16-water attractive interactions. We can explain the general experimental result that stacking of flat moieties, hydrogen bonding and molecular-shape and electrostatic complementarities are frequently observed in the complexes. It is argued that the water-entropy gain is largely influenced by the geometric characteristics (overall shapes, sizes and detailed polyatomic structures) of the biomolecules.

Structure of perosamine-containing polysaccharide, a component of the sheath of Thiothrix fructosivorans.

A sheath-forming and sulfur-oxidizing bacterium, Thiothrix fructosivorans, was heterotrophically cultured. The sheath, which is an extracellular microtube, was prepared by selectively removing the cells using lysozyme, sodium dodecyl sulfate, and sodium hydroxide. Solid-state (13)C-nuclear magnetic resonance (NMR) spectrum revealed that the sheath is assembled from a glycan possessing acetyl and methyl groups. When the sheath was deacetylated, the original microtube structure was lost and the sheath became soluble under acidic conditions, revealing the importance of acetyl groups in maintaining the sheath structure. Equimolar d-glucose, d-glucosamine, and l-fucose were detected in the acid hydrolysate of the sheath by gas liquid chromatography. In addition to these sugars, ß-GlcN-(1→4)-Glc and unidentified sugar were detected by analyzing the hydrolysate using high-performance liquid chromatography analysis. (1)H and (13)C NMR spectroscopy was used to identify a disaccharide composed of 4-deoxy-4-aminorhamnose (perosamine, Rha4N) and fucose. N-Acetyl-perosamine prepared from the disaccharide was polarimetric and exhibited a d-configuration. The previously unidentified disaccharide was found to be α-d-Rhap4N-(1→3)-d-Fuc. According to (1)H and (13)C NMR analyses, the deacetylated sheath-forming polysaccharide was found to h have a main chain of [→4)-ß-d-GlcpN-(1→4)-ß-d-Glcp-(1→]n, to which disaccharide side chains of α-d-Rhap4N-(1→3)-α-l-Fucp-(1→ were attached at position 3 of Glc.

Anti-prion activity of an RNA aptamer and its structural basis.

Prion proteins (PrPs) cause prion diseases, such as bovine spongiform encephalopathy. The conversion of a normal cellular form (PrP(C)) of PrP into an abnormal form (PrP(Sc)) is thought to be associated with the pathogenesis. An RNA aptamer that tightly binds to and stabilizes PrP(C) is expected to block this conversion and to thereby prevent prion diseases. Here, we show that an RNA aptamer comprising only 12 residues, r(GGAGGAGGAGGA) (R12), reduces the PrP(Sc) level in mouse neuronal cells persistently infected with the transmissible spongiform encephalopathy agent. Nuclear magnetic resonance analysis revealed that R12, folded into a unique quadruplex structure, forms a dimer and that each monomer simultaneously binds to two portions of the N-terminal half of PrP(C), resulting in tight binding. Electrostatic and stacking interactions contribute to the affinity of each portion. Our results demonstrate the therapeutic potential of an RNA aptamer as to prion diseases.

Conformational analysis of an extracellular polysaccharide produced by Sphaerotilus natans.

Sphaerotilus natans is a filamentous sheath-forming bacterium, commonly found in bulking activated sludge. The bulky nature of this bacterium is caused by an extracellular polysaccharide (EPS). EPS is a linear acidic polysaccharide with the following chemical structure: [ → 4)-α-D-Glcp-(1 → 2)-ß-D-GlcpA-(1 → 2)-α-L-Rhap-(1 → 3)-ß-L-Rhap-(1 → ](n). (1)H-(1)H and (1)H-(13)C correlation nuclear magnetic resonance (NMR) experiments were performed to acquire nuclear Overhauser effect signals, which were used for conformational elucidation. Molecular mechanics calculations were performed on each disaccharide unit of the EPS building blocks. On the basis of the results of the calculations, the conformation of a pentasaccharide fragment was estimated. After confirmation of the coincidence between the NMR data and the predicted conformation of the pentasaccharide fragment, the conformation of a heptadecasaccharide fragment was estimated using the same procedure. The heptadecasaccharide was found to form a (12/1) helix and take locally folded chain, which is attributed to a triangular arrangement formed by a series of residues, α-D-Glcp-(1 → 2)-ß-D-GlcpA-(1 → 2)-α-L-Rhap. This arrangement is caused by the peculiar consecutive (1 → 2) linkages and reinforced by a hydrogen bond between the α-glucosyl and α-rhamnosyl residues. Considering the steric hindrance due to this triangular arrangement, EPS molecules are not supposed to form double helix in an aqueous environment. We propose the name 'sphaeran' to refer to this unique chemical structure and properties of EPS.