Simple Enzymatic Incorporation of 2'OMeU Nucleotide at the End of the Poly-A Tail for Enhancement of the mRNA Stability and Protein Expression.

This study focused on the efficient post-transcriptional incorporation of a modified nucleoside at the end of the poly-A tail of mRNA. The modified mRNA was obtained in high yield and served to enhance protein expression. Utilizing poly-U polymerase, our method successfully enabled a single 2'OMeU residue to be incorporated into mRNA, which unexpectedly provided significant stabilization, even with only a single incorporation, to enhance the resistance of mRNA to degradation by cellular exonuclease. This stabilization effect allowed the mRNA to remain viable within the cell for an extended period to ultimately increase the translation efficiency at least 3-fold. This approach to mRNA modification at the 3' end with a single 2'OMeU residue, by utilizing a straightforward tailing method, surpasses other ligation methods in terms of mRNA modification efficiency. Collectively, our results highlight the potential of this method to significantly advance the development of highly effective mRNA-based therapies in the future.

Triple ligation-based formation of a G-quadruplex for simultaneous detection of multiple miRNAs.

The simultaneous detection of multiple microRNAs (miRNA) is of great necessity but has not been extensively studied. This prompted our study, which involved the development of a triple ligation-based system for detecting three miRNAs at the same time. We designed a multi-ligation-padlock (MLP) probe that consists of three parts, each of which is complementary to two different miRNAs at the same time. In the presence of all three miRNAs, the probe becomes circularized, but in the absence of even one target, the probe remains linear. The first part of the MLP probe (MLP1) contains a T7 promoter part that can initiate RNA synthesis for any given target condition. However, it also includes a G-quadruplex complementary segment, which can only form a parallel RNA G-quadruplex through rolling circle transcription by the circularized template in the presence of all three targets. In this case, the application of our parallel G-quadruplex sensing fluorescent probe lutidine DESA (LutD) produces a strong signal. However, in the absence of any one of the targets, the RNA G-quadruplex cannot be formed and ultimately the LutD probe does not generate any signal. This difference in the signal intensity represents the presence or absence of all the target miRNAs. With our system, we were able to detect miRNA 21 at levels as low as 1.13 fM, miRNA 146a as low as 1.37 fM, and miRNA 25b as low as 1.51 fM within 45 minutes, confirming that our novel system can selectively and sensitively diagnose triple miRNAs.

Blocker-dUThiophene poly tailing-based method for assessing methyl transferase activity.

In this report, we present a method for the selective and sensitive detection of methyl transferase activity. The method uses a dsDNA probe that contains C3 spacers and is coupled with dUThioTP-TdT polymerase-based poly-tailing. The short dsDNA probe is designed with C3 spacers at both 3' ends to prevent any type of tailing reaction. However, the probe contains a methyl transferase recognition sequence that can methylate adenosines in the palindromic part of both strands. When a specific DpnI endonuclease is introduced, it selectively cleaves the dsDNA probe such that both strands are methylated, unblocking the probe into two separate dsDNA forms with exposed 3' OH groups. This makes the probe susceptible to tailing in the presence of a TdT tailing polymerase. The unblocked probe is then subjected to fluorescent dUThioTP-based tailing, which produces a strong fluorescent signal that indicates the presence of methyl transferase activity. In the absence of methyl transferase, the probe remains in the blocked state and does not undergo fluorescence. This method has a limit of detection of 0.049 U/mL with good selectivity and the potential for accurate MTase analysis.

Rolling circle transcription/G-quadruplex/QnMorpholine probe for highly selective and sensitive detection of alkaline phosphatase activity.

In this study, we combined a rolling circle transcription (RCT) system producing 22AG G-quadruplex RNA with a QnMorpholine (QNM) fluorescent probe for the selective and sensitive detection of alkaline phosphatase (ALP). ALP is involved in various biological functions, with monophosphate cleavage being one of its characteristic properties. Here, we developed a padlock RCT probing system in which a large amount of RCT 22AG RNA G-quadruplex was produced in the absence of ALP, providing a high fluorescence signal. In contrast, no RNA G-quadruplex was produced in the presence of ALP, with minimal fluorescence. This huge deviation in signal intensity allowed us to identify the presence or absence of ALP in a test sample. Under practical conditions, our system allowed the differentiation for ALP even when it was present at an extremely low concentration (0.0085 U/L), along with very high specificity. The simplicity and efficiency of this approach for ALP detection suggest its potential for use as a reliable diagnostic tool.

22AG G-quadruplex RNA/QnMorpholine-mediated fluorimetric detection of miR-21.

Herein we report a simple ligation/transcription-mediated system, using a 22AG G-quadruplex RNA secondary structure and a fluorescence-inducing QnMorpholine probe, for the detection of miR-21. In the presence of the target miR-21, two oligonucleotide probes (promoter and reporter) were ligated, thereby transcribing the 22AG RNA sequence, a complement of the reporter probe. In contrast, in the absence of this target-induced ligation, the reporter complement could not be transcribed to produce the 22AG RNA sequence. Subsequent addition of the QnMorpholine probe resulted in binding with the 22AG G-quadruplex RNA, thereby generating high fluorescence; no fluorescence occurred in the absence of this secondary structure. Hence, the presence of miR-21 was evidenced by a target-induced high-intensity signal. This simple one-pot fluorimetric system, which could detect miR-21 of up to 3.08 femtomolar in less than 30 min, holds promise as a diagnostic tool for selective and sensitive miRNA detection.

Unnatural nucleotide-based rkDNA probe combined with graphene oxide for detection of alkaline phosphatase activity.

In this study we developed a fluorescent double-stranded DNA, incorporating an unnatural dUrk nucleotide, that we used as a probe for the detection of alkaline phosphatase (ALP) based on enzymatic cleavage of the non-fluorescent complementary strand. Primer extension performed using the unnatural nucleotide triphosphate dUrkTP and the natural deoxynucleotide triphosphates dATP, dCTP, and dGTP provided a simple fluorescent DNA strand that hybridized with the 5́-monophosphate non-fluorescent complementary strand. When applying the 5́-phosphate recognition and cleavage properties of lambda exonuclease (λ-exo), this probe could bind to graphene oxide (GO) and quench the fluorescence (in the absence of ALP) or not bind to GO and retain its fluorescence (in the presence of ALP). We obtained strongly fluorescent DNA strands through simple incorporation of multiple A sites in the complementary sequence, thereby increasing the number of dUrk residues during primer extension. This unnatural nucleotide-based rkDNA probing system exhibited high fluorescence differentiation for discriminating the status of ALP. This rkDNA-GO probing system appears to be a promising tool for monitoring the activity of disease-associated enzymes.