Remodeling the conformational dynamics of I-motif DNA by helicases in ATP-independent mode at acidic environment

Recent Advances in Aptamer-Based Biosensors for Bacterial Detection

The rapid and sensitive detection of pathogenic bacteria is becoming increasingly important for the timely prevention of contamination and the treatment of infections. Biosensors based on nucleic acid aptamers, integrated with optical, electrochemical, and mass-sensitive analytical techniques, have garnered intense interest because of their versatility, cost-efficiency, and ability to exhibit high affinity and specificity in binding bacterial biomarkers, toxins, and whole cells. This review highlights the development of aptamers, their structural characterization, and the chemical modifications enabling optimized recognition properties and enhanced stability in complex biological matrices. Furthermore, recent examples of aptasensors for the detection of bacterial cells, biomarkers, and toxins are discussed. Finally, we explore the barriers to and discuss perspectives on the application of aptamer-based bacterial detection.

A beginner's handbook to identify and characterize i-motif DNA

Genomic DNA exhibits an innate ability to manifest diverse sequence-dependent secondary structures, serving crucial functions in gene regulation and cellular equilibrium. While extensive research has confirmed the formation of G-quadruplex structures by guanine-rich sequences in vitro and in cells, recent investigations have turned the quadruplex community's attention to the cytosine (C)-rich complementary strands that can adopt unique tetra-stranded conformation, termed as intercalated motif or i-motif. I-motifs are stabilized by hemi-protonated C:CH+ base pairs under acidic conditions. Initially, the in vivo occurrence of i-motifs was underestimated because their formation is favored at non-physiological pH. However, groundbreaking research utilizing the structure-specific iMab antibody and high-throughput sequencing have recently detected their conserved dispersion throughout the genome, challenging previous assumptions. Given the evolving nature of this research field, it becomes imperative to conduct independent in vitro experiments aimed at identifying potential i-motif formation in C-rich sequences and consolidating the findings to address the properties of i-motifs. This chapter serves as an introductory guide for the swift identification of novel i-motifs, where we present an experimental framework for investigating and characterizing i-motif sequences in vitro. In this chapter, we selected a synthetic oligonucleotide (C7T3) sequence and outlined appropriate methodologies for annealing the i-motif structure into suitable buffers. Then, we validated its formation by CD (Circular Dichroism) and NMR (Nuclear Magnetic Resonance) spectroscopy. Finally, we provided a thorough account of the step-by-step procedures to investigate the effect of i-motif formation on the stalling or retardation of DNA replication using high resolution primer extension assays.

DNA-guided self-assembly in living cells

Self-assembly processes exist widely in life systems and play essential roles in maintaining life activities. It is promising to explore the molecular fundamentals and mechanisms of life systems through artificially constructing self-assembly systems in living cells. As an excellent self-assembly construction material, deoxyribonucleic acid (DNA) has been widely used to achieve the precise construction of self-assembly systems in living cells. This review focuses on the recent progress of DNA-guided intracellular self-assembly. First, the methods of intracellular DNA self-assembly based on the conformational transition of DNA are summarized, including complementary base pairing, the formation of G-quadruplex/i-motif, and the specific recognition of DNA aptamer. Next, The applications of DNA-guided intracellular self-assembly on the detection of intracellular biomolecules and the regulation of cell behaviors are introduced, and the molecular design of DNA in the self-assembly systems is discussed in detail. Ultimately, the challenges and opportunities of DNA-guided intracellular self-assembly are commented.

Mechanistic insights into poly(C)-binding protein hnRNP K resolving i-motif DNA secondary structures

I-motifs are four-strand noncanonical secondary structures formed by cytosine (C)-rich sequences in living cells. The structural dynamics of i-motifs play essential roles in many cellular processes, such as telomerase inhibition, DNA replication, and transcriptional regulation. In cells, the structural dynamics of the i-motif can be modulated by the interaction of poly(C)-binding proteins (PCBPs), and the interaction is closely related to human health, through modulating the transcription of oncogenes and telomere stability. Therefore, the mechanisms of how PCBPs interact with i-motif structures are fundamentally important. However, the underlying mechanisms remain elusive. I-motif structures in the promoter of the c-MYC oncogene can be unfolded by heterogeneous nuclear ribonucleoprotein K (hnRNP K), a PCBP, to activate its transcription. Here, we selected this system as an example to comprehensively study the unfolding mechanisms. We found that the promoter sequence containing 5 C-runs preferred folding into type-1245 to type-1234 i-motif structures based on their folding stability, which was further confirmed by single-molecule FRET. In addition, we first revealed that the c-MYC i-motif structure was discretely resolved by hnRNP K through two intermediate states, which were assigned to the opposite hairpin and neighboring hairpin, as further confirmed by site mutations. Furthermore, we found all three KH (hnRNP K homology) domains of hnRNP K could unfold the c-MYC i-motif structure, and KH2 and KH3 were more active than KH1. In conclusion, this study may deepen our understanding of the interactions between i-motifs and PCBPs and may be helpful for drug development.

Creation and resolution of non-B-DNA structural impediments during replication

During replication, folding of the DNA template into non-B-form secondary structures provides one of the most abundant impediments to the smooth progression of the replisome. The core replisome collaborates with multiple accessory factors to ensure timely and accurate duplication of the genome and epigenome. Here, we discuss the forces that drive non-B structure formation and the evidence that secondary structures are a significant and frequent source of replication stress that must be actively countered. Taking advantage of recent advances in the molecular and structural biology of the yeast and human replisomes, we examine how structures form and how they may be sensed and resolved during replication.

Environment-Sensitive Nucleoside Probe Unravels the Complex Structural Dynamics of i-Motif DNAs

Although evidence for the existence and biological role of i-motif (iM) DNA structures in cells is emerging, probing their structural polymorphism and identifying physiologically active conformations using currently available tools remain a major challenge. Here, we describe the development of an innovative device to investigate the conformation equilibrium of different iMs formed by C-rich telomeric repeat and oncogenic B-raf promoter sequences using a new conformation-sensitive dual-purpose nucleoside probe. The nucleoside is composed of a trifluoromethyl-benzofuran-2-yl moiety at the C5 position of 2'-deoxyuridine, which functions as a responsive fluorescent and ¹⁹F NMR probe. While the fluorescent component is useful in monitoring and estimating the folding process, the ¹⁹F label provides spectral signatures for various iMs, thereby enabling a systematic analysis of their complex population equilibrium under different conditions (e.g., pH, temperature, metal ions, and cell lysate). Distinct ¹⁹F signals exhibited by the iMs formed by the human telomeric repeat helped in calculating their relative population. A battery of fluorescence and ¹⁹F NMR studies using native and mutated B-raf oligonucleotides gave valuable insights into the iM structure landscape and its dependence on environmental conditions and also helped in predicting the structure of the major iM conformation. Overall, our findings indicate that the probe is highly suitable for studying complex nucleic acid systems.