Zhensheng Zhong scite author profile

The diverse biological functions of RNA are determined by the complex structures of RNA stabilized by both secondary and tertiary interactions. An RNA triplex is an important tertiary structure motif that is found in many pseudoknots and other structured RNAs. A triplex structure usually forms through tertiary interactions in the major or minor groove of a Watson-Crick base-paired stem. A major-groove RNA triplex structure is stable in isolation by forming consecutive major-groove base triples such as U·A-U and C(+) ·G-C. Minor-groove RNA triplexes, e.g., A-minor motif triplexes, are found in almost all large structured RNAs. As double-stranded RNA stem regions are often involved in biologically important tertiary triplex structure formation and protein binding, the ability to sequence specifically target any desired RNA duplexes by triplex formation would have great potential for biomedical applications. Programmable chemically modified triplex-forming oligonucleotides (TFOs) and triplex-forming peptide nucleic acids (PNAs) have been developed to form TFO·RNA2 and PNA·RNA2 triplexes, respectively, with enhanced binding affinity and sequence specificity at physiological conditions. Here, we (1) provide an overview of naturally occurring RNA triplexes, (2) summarize the experimental methods for studying triplexes, and (3) review the development of TFOs and triplex-forming PNAs for targeting an HIV-1 ribosomal frameshift-inducing RNA, a bacterial ribosomal A-site RNA, and a human microRNA hairpin precursor, and for inhibiting the RNA-protein interactions involving human RNA-dependent protein kinase and HIV-1 viral protein Rev.

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Mechanical unfolding kinetics of the SRV-1 gag-pro mRNA pseudoknot: possible implications for −1 ribosomal frameshifting stimulation

Zhong

Yang

Zhang

et al. 2016

Sci Rep

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Minus-one ribosomal frameshifting is a translational recoding mechanism widely utilized by many RNA viruses to generate accurate ratios of structural and catalytic proteins. An RNA pseudoknot structure located in the overlapping region of the gag and pro genes of Simian Retrovirus type 1 (SRV-1) stimulates frameshifting. However, the experimental characterization of SRV-1 pseudoknot (un)folding dynamics and the effect of the base triple formation is lacking. Here, we report the results of our single-molecule nanomanipulation using optical tweezers and theoretical simulation by steered molecular dynamics. Our results directly reveal that the energetic coupling between loop 2 and stem 1 via minor-groove base triple formation enhances the mechanical stability. The terminal base pair in stem 1 (directly in contact with a translating ribosome at the slippery site) also affects the mechanical stability of the pseudoknot. The −1 frameshifting efficiency is positively correlated with the cooperative one-step unfolding force and inversely correlated with the one-step mechanical unfolding rate at zero force. A significantly improved correlation was observed between −1 frameshifting efficiency and unfolding rate at forces of 15–35 pN, consistent with the fact that the ribosome is a force-generating molecular motor with helicase activity. No correlation was observed between thermal stability and −1 frameshifting efficiency.

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Preparation and properties of poly(vinyl alcohol)-stabilized liposomes

Xiao-mei

Zhong

2006

International Journal of Pharmaceutics

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A Disease-Causing Intronic Point Mutation C19G Alters Tau Exon 10 Splicing via RNA Secondary Structure Rearrangement

et al. 2019

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Alternative splicing of MAPT cassette exon 10 produces tau isoforms with four microtubule-binding repeat domains (4R) upon exon inclusion or three repeats (3R) upon exon skipping. In human neurons, deviations from the ∼1:1 physiological 4R:3R ratio lead to frontotemporal dementia with Parkinsonism linked to chromosome 17 (FTDP-17). Certain FTDP-17-associated mutations affect a regulatory hairpin that sequesters the exon 10 5′ splice site (5′ss, located at the exon 10–intron 10 junction). These mutations tend to increase the 4R:3R ratio by destabilizing the hairpin, thereby improving 5′ss recognition by U1 snRNP. Interestingly, a single C-to-G mutation at the 19th nucleotide in intron 10 (C19G or +19G) decreases the level of exon 10 inclusion significantly from 56% to 1%, despite the disruption of a G-C base pair in the bottom stem of the hairpin. Here, we show by biophysical characterization, including thermal melting, fluorescence, and single-molecule mechanical unfolding using optical tweezers, that the +19G mutation alters the structure of the bottom stem, resulting in the formation of a new bottom stem with enhanced stability. The cell culture alternative splicing patterns of a series of minigenes reveal that the splicing activities of the mutants with destabilizing mutations on the top stem can be compensated in a position-dependent manner by the +19G mutation in the bottom stem. We observed an excellent correlation between the level of exon 10 inclusion and the rate of mechanical unfolding at 10 pN, indicating that the unfolding of the splice site hairpins (to facilitate subsequent binding of U1 snRNA) may be aided by helicases or other proteins.

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Noncanonical registers and base pairs in human 5′ splice-site selection

Tan

Zhong

et al. 2016

Nucleic Acids Res

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Accurate recognition of splice sites is essential for pre-messenger RNA splicing. Mammalian 5′ splice sites are mainly recognized by canonical base-pairing to the 5′ end of U1 small nuclear RNA, yet we described multiple noncanonical base-pairing registers by shifting base-pair positions or allowing one-nucleotide bulges. By systematic mutational and suppressor U1 analyses, we prove three registers involving asymmetric loops and show that two-nucleotide bulges but not longer can form in this context. Importantly, we established that a noncanonical uridine-pseudouridine interaction in the 5′ splice site/U1 helix contributes to the recognition of certain 5′ splice sites. Thermal melting experiments support the formation of noncanonical registers and uridine-pseudouridine interactions. Overall, we experimentally validated or discarded the majority of predicted noncanonical registers, to derive a list of 5′ splice sites using such alternative mechanisms that is much different from the original. This study allows not only the mechanistic understanding of the recognition of a wide diversity of mammalian 5′ splice sites, but also the future development of better splice-site scoring methods that reliably predict the effects of disease-causing mutations at these sequences.

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Zhensheng Zhong

RNA triplexes: from structural principles to biological and biotech applications

Mechanical unfolding kinetics of the SRV-1 gag-pro mRNA pseudoknot: possible implications for −1 ribosomal frameshifting stimulation

Preparation and properties of poly(vinyl alcohol)-stabilized liposomes

A Disease-Causing Intronic Point Mutation C19G Alters Tau Exon 10 Splicing via RNA Secondary Structure Rearrangement

Noncanonical registers and base pairs in human 5′ splice-site selection

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