Jia Sheng

Selenium derivatization of nucleic acids for crystallography

The high-resolution structure of the DNA (5′-GTGTACA-C-3′) with the selenium derivatization at the 2′-position of T2 was determined via MAD and SAD phasing. The selenium-derivatized structure (1.28 Å resolution) with the 2′-Se modification in the minor groove is isomorphorous to the native structure (2.0 Å). To directly compare with the conventional bromine derivatization, we incorporated bromine into the 5-postion of T4, determined the bromine-derivatized DNA structure at 1.5 Å resolution, and found that the local backbone torsion angles and solvent hydration patterns were altered in the structure with the Br incorporation in the major groove. Furthermore, while the native and Br-derivatized DNAs needed over a week to form reasonable-size crystals, we observed that the Se-derivatized DNAs grew crystals overnight with high-diffraction quality, suggesting that the Se derivatization facilitated the crystal formation. In addition, the Se-derivatized DNA sequences crystallized under a broader range of buffer conditions, and generally had a faster crystal growth rate. Our experimental results indicate that the selenium derivatization of DNAs may facilitate the determination of nucleic acid X-ray crystal structures in phasing and high-quality crystal growth. In addition, our results suggest that the Se derivatization can be an alternative to the conventional Br derivatization.

Selenium derivatization of nucleic acids for X-ray crystal-structure and function studies.

It is estimated that over two thirds of all new crystal structures of proteins are determined via the protein selenium derivatization (selenomethionine (Se‐Met) strategy). This selenium derivatization strategy via MAD (multi‐wavelength anomalous dispersion) phasing has revolutionized protein X‐ray crystallography. Through our pioneer research, similarly, Se has also been successfully incorporated into nucleic acids to facilitate the X‐ray crystal‐structure and function studies of nucleic acids. Currently, Se has been stably introduced into nucleic acids by replacing nucleotide O‐atom at the positions 2′, 4′, 5′, and in nucleobases and non‐bridging phosphates. The Se derivatization of nucleic acids can be achieved through solid‐phase chemical synthesis and enzymatic methods, and the Se‐derivatized nucleic acids (SeNA) can be easily purified by HPLC, FPLC, and gel electrophoresis to obtain high purity. It has also been demonstrated that the Se derivatization of nucleic acids facilitates the phase determination via MAD phasing without significant perturbation. A growing number of structures of DNAs, RNAs, and protein–nucleic acid complexes have been determined by the Se derivatization and MAD phasing. Furthermore, it was observed that the Se derivatization can facilitate crystallization, especially when it is introduced to the 2′‐position. In addition, this novel derivatization strategy has many advantages over the conventional halogen derivatization, such as more choices of the modification sites via the atom‐specific substitution of the nucleotide O‐atom, better stability under X‐ray radiation, and structure isomorphism. Therefore, our Se‐derivatization strategy has great potentials to provide rational solutions for both phase determination and high‐quality crystal growth in nucleic‐acid crystallography. Moreover, the Se derivatization generates the nucleic acids with many new properties and creates a new paradigm of nucleic acids. This review summarizes the recent developments of the atomic site‐specific Se derivatization of nucleic acids for structure determination and function study. Several applications of this Se‐derivatization strategy in nucleic acid and protein research are also described in this review.

Derivatization of DNAs with selenium at 6-position of guanine for function and crystal structure studies

To investigate nucleic acid base pairing and stacking via atom-specific mutagenesis and crystallography, we have synthesized for the first time the 6-Se-deoxyguanosine phosphoramidite and incorporated it into DNAs via solid-phase synthesis with a coupling yield over 97%. We found that the UV absorption of the Se-DNAs red-shifts over 100 nm to 360 nm (ε = 2.3 × 104 M−1 cm−1), the Se-DNAs are yellow colored, and this Se modification is relatively stable in water and at elevated temperature. Moreover, we successfully crystallized a ternary complex of the Se-G-DNA, RNA and RNase H. The crystal structure determination and analysis reveal that the overall structures of the native and Se-modified nucleic acid duplexes are very similar, the selenium atom participates in a Se-mediated hydrogen bond (Se … H–N), and the SeG and C form a base pair similar to the natural G–C pair though the Se-modification causes the base-pair to shift (approximately 0.3 Å). Our biophysical and structural studies provide new insights into the nucleic acid flexibility, duplex recognition and stability. Furthermore, this novel selenium modification of nucleic acids can be used to investigate chemogenetics and structure of nucleic acids and their protein complexes.

High Fidelity of Base Pairing by 2-Selenothymidine in DNA

The base pairs are the contributors to the sequence-dependent recognition of nucleic acids, genetic information storage, and high fidelity of DNA polymerase replication. However, the wobble base pairing, where T pairs with G instead of A, reduces specific base-pairing recognition and compromises the high fidelity of the enzymatic polymerization. Via the selenium atomic probing at the 2-position of thymidine, we have investigated the wobble discrimination by manipulating the steric and electronic effects at the 2-exo position, providing a unique chemical strategy to enhance the base pair specificity. We report here the first synthesis of the novel 2-Se-thymidine ((Se)T) derivative, its phosphoramidite, and the Se-DNAs. Our biophysical and structural studies of the 2-Se-T DNAs reveal that the bulky 2-Se atom with a weak hydrogen-bonding ability can largely increase mismatch discriminations (including T/G wobble and T/C mismatched base pairs) while maintaining the (Se)T/A virtually identical to the native T/A base pair. The 2-Se atom bulkiness and the electronic effect are probably the main factors responsible for the discrimination against the formation of the wobble (Se)T/G base pair. Our investigations provide a potential novel tool to investigate the specific recognition of base pairs, which is the basis of high fidelity during replication, transcription, and translation. Furthermore, this Se-atom-specific substitution and probing are useful for X-ray crystal structure and function studies of nucleic acids.

An Efficient Procedure for the Synthesis of Benzimidazole Derivatives Using Yb(OTf)3 as Catalyst Under Solvent‐Free Conditions

Abstract o‐Diaminobenzene derivatives react smoothly with ortho‐esters in the presence of 0.5 mol% of Yb(OTf)3 under solvent‐free conditions to afford the corresponding benzimidazole derivatives in good to excellent yields. In addition, Yb(OTf)3 can be easily recovered almost quantitatively from the aqueous layer after the reaction was completed, and it could be reused with no loss of activity.

Structure-based DNA-targeting strategies with small molecule ligands for drug discovery.

Nucleic acids are the molecular targets of many clinical anticancer drugs. However, compared with proteins, nucleic acids have traditionally attracted much less attention as drug targets in structure‐based drug design, partially because limited structural information of nucleic acids complexed with potential drugs is available. Over the past several years, enormous progresses in nucleic acid crystallization, heavy‐atom derivatization, phasing, and structural biology have been made. Many complicated nucleic acid structures have been determined, providing new insights into the molecular functions and interactions of nucleic acids, especially DNAs complexed with small molecule ligands. Thus, opportunities have been created to further discover nucleic acid‐targeting drugs for disease treatments. This review focuses on the structure studies of DNAs complexed with small molecule ligands for discovering lead compounds, drug candidates, and/or therapeutics.

Multiplexed Activity of perAuxidase: DNA-Capped AuNPs Act as Adjustable Peroxidase

In this study, we have investigated the intrinsic peroxidase-like activity of citrate-capped AuNPs (perAuxidase) and demonstrated that the nanozyme function can be multiplexed and tuned by integrating oligonucleotides on a nanoparticle surface. Systematic studies revealed that by controlling the reaction parameters, the mutiplexing effect can be delayed or advanced and further used for aptasensor applications.

Crystal structure studies of RNA duplexes containing s(2)U:A and s(2)U:U base pairs.

Structural studies of modified nucleobases in RNA duplexes are critical for developing a full understanding of the stability and specificity of RNA base pairing. 2-Thio-uridine (s2U) is a modified nucleobase found in certain tRNAs. Thermodynamic studies have evaluated the effects of s2U on base pairing in RNA, where it has been shown to stabilize U:A pairs and destabilize U:G wobble pairs. Surprisingly, no high-resolution crystal structures of s2U-containing RNA duplexes have yet been reported. We present here two high-resolution crystal structures of heptamer RNA duplexes (5′-uagcs2Ucc-3′ paired with 3′-aucgAgg-5′ and with 3′-aucgUgg-5′) containing s2U:A and s2U:U pairs, respectively. For comparison, we also present the structures of their native counterparts solved under identical conditions. We found that replacing O2 with S2 stabilizes the U:A base pair without any detectable structural perturbation. In contrast, an s2U:U base pair is strongly stabilized in one specific U:U pairing conformation out of four observed for the native U:U base pair. This s2U:U stabilization appears to be due at least in part to an unexpected sulfur-mediated hydrogen bond. This work provides additional insights into the effects of 2-thio-uridine on RNA base pairing.

Novel RNA base pair with higher specificity using single selenium atom

Specificity of nucleobase pairing provides essential foundation for genetic information storage, replication, transcription and translation in all living organisms. However, the wobble base pairs, where U in RNA (or T in DNA) pairs with G instead of A, might compromise the high specificity of the base pairing. The U/G wobble pairing is ubiquitous in RNA, especially in non-coding RNA. In order to increase U/A pairing specificity, we have hypothesized to discriminate against U/G wobble pair by tailoring the steric and electronic effects at the 2-exo position of uridine and replacing the 2-exo oxygen with a selenium atom. We report here the first synthesis of the 2-Se-U-RNAs as well as the 2-Se-uridine (SeU) phosphoramidite. Our biophysical and structural studies of the SeU-RNAs indicate that this single atom replacement can indeed create a novel U/A base pair with higher specificity than the natural one. We reveal that the SeU/A pair maintains a structure virtually identical to the native U/A base pair, while discriminating against U/G wobble pair. This oxygen replacement with selenium offers a unique chemical strategy to enhance the base pairing specificity at the atomic level.

Structural insights into the effects of 2'-5' linkages on the RNA duplex.

Significance The nonenzymatic replication of RNA is thought to have been a critical step in the emergence of simple cellular life from prebiotic chemistry. However, the chemical copying of RNA templates generates product strands that contain 2′-5′ backbone linkages and normal 3′-5′ linkages. Our recent finding that RNAs with such mixed backbones can still fold into functional structures raised the question of how RNA accommodates the presence of 2′-5′ linkages. Here we use X-ray crystallography and molecular dynamics simulations to reveal how 3′-5′–linked RNA duplexes accommodate interspersed 2′-5′ linkages. The diminished thermal and chemical stability of such RNA duplexes reflects local structural changes, but compensatory changes result in a global RNA duplex structure with relatively minor alterations. The mixture of 2′-5′ and 3′-5′ linkages generated during the nonenzymatic replication of RNA has long been regarded as a central problem for the origin of the RNA world. However, we recently observed that both a ribozyme and an RNA aptamer retain considerable functionality in the presence of prebiotically plausible levels of linkage heterogeneity. To better understand the RNA structure and function in the presence of backbone linkage heterogeneity, we obtained high-resolution X-ray crystal structures of a native 10-mer RNA duplex (1.32 Å) and two variants: one containing one 2′-5′ linkage per strand (1.55 Å) and one containing three such linkages per strand (1.20 Å). We found that RNA duplexes adjust their local structures to accommodate the perturbation caused by 2′-5′ linkages, with the flanking nucleotides buffering the disruptive effects of the isomeric linkage and resulting in a minimally altered global structure. Although most 2′-linked sugars were in the expected 2′-endo conformation, some were partially or fully in the 3′-endo conformation, suggesting that the energy difference between these conformations was relatively small. Our structural and molecular dynamic studies also provide insight into the diminished thermal and chemical stability of the duplex state associated with the presence of 2′-5′ linkages. Our results contribute to the view that a low level of 2′-5′ substitution would not have been fatal in an early RNA world and may in contrast have been helpful for both the emergence of nonenzymatic RNA replication and the early evolution of functional RNAs.