Co-reporter:Yijie Wang, Yu Shao, Xiaozhou Ma, Bini Zhou, Alan Faulkner-Jones, Wenmiao Shu, and Dongsheng Liu
ACS Applied Materials & Interfaces April 12, 2017 Volume 9(Issue 14) pp:12311-12311
Publication Date(Web):March 16, 2017
DOI:10.1021/acsami.7b01604
Tissue engineering has long been a challenge because of the difficulty of addressing the requirements that such an engineered tissue must meet. In this paper, we developed a new “brick-to-wall” based on unique properties of DNA supramolecular hydrogels to fabricate three-dimensional (3D) tissuelike structures: different cell types are encapsulated in DNA hydrogel bricks which are then combined to build 3D structures. Signal responsiveness of cells through the DNA gels was evaluated and it was discovered that the gel permits cell migration in 3D. The results demonstrated that this technology is convenient, effective and reliable for cell manipulation, and we believe that it will benefit artificial tissue fabrication and future large-scale production.Keywords: cell arrangements; cell migration; DNA hydrogel; self-healing; supramolecular; tissue engineering;
Co-reporter:Hao-yang Jia;Jie-zhong Shi;Yu Shao
Chinese Journal of Polymer Science 2017 Volume 35( Issue 10) pp:1307-1314
Publication Date(Web):31 August 2017
DOI:10.1007/s10118-017-1978-6
In recent years, DNA supramolecular hydrogels have attracted much attention due to their injectability, biocompatibility, responsiveness and self-healing properties. In this work, we designed a linear DNA brick containing one duplex with two cytosine (C)-rich sequence on both ends. This brick can first assemble to form duplex under pH 8 condition. After adjusting the pH to 5, the C-rich sequence tends to form intermolecular i-motif structure, which joins the linear DNA molecules together to form interlocked cyclic structures and yield the DNA hydrogel. By adjusting the length and bending curvature of the duplex part of the molecule, one can change the basic unit of the hydrogel structure to tune the properties of the DNA hydrogel.
Co-reporter:Chuang Li;Xu Zhou;Yu Shao;Ping Chen;Yongzheng Xing;Zhongqiang Yang;Zhibo Li
Materials Chemistry Frontiers 2017 vol. 1(Issue 4) pp:654-659
Publication Date(Web):2017/03/31
DOI:10.1039/C6QM00176A
Preparation of hydrogels with solely variable mechanical properties is greatly desired in the study of cell-matrix interactions in situ as well as cellular behaviors. Here, we fabricated a supramolecular polypeptide–DNA hydrogel, via the DNA self-assembly strategy, which possesses identical cross-linking point density but distinctive rheological properties. Keeping the cross-linking density constant, the rheological properties of the hydrogel can be adjusted by tailoring the stability of the DNA cross-linkers via easy programming of the DNA sequences. Through elongating and shortening the length of the DNA linker or inserting mismatch sites, the hydrogel can be strengthened, softened, or even fluidized, respectively. In addition, the mechanical properties can also be modulated by a pH-triggered conformation transition of the polypeptide backbone. Combining rapid physiological gelation and reversible thermal responsiveness, these supramolecular polypeptide–DNA hydrogels with solely tuned mechanical strength will promote studies on mechanical induced cell differentiation in situ, and have great potential in tissue engineering.
Co-reporter:Xiaozhou Ma, Zhongqiang Yang, Yijie Wang, Guoliang Zhang, Yu Shao, Haoyang Jia, Tianyang Cao, Rui Wang, and Dongsheng Liu
ACS Applied Materials & Interfaces 2017 Volume 9(Issue 3) pp:
Publication Date(Web):January 5, 2017
DOI:10.1021/acsami.6b12327
DNA hydrogel has aroused widespread attention because of its unique properties. In this work, the DNA-modified magnetic nanoparticles were integrated into the mainframe of DNA hydrogel, resulting in DNA-MNP hydrogel. Under the magnetic field, this hydrogel can be remotely deformed into various shapes, driven to jump between two planes and even climb the hill. By applying various triggers, such as temperature, enzyme, and magnetic field, DNA-MNP hydrogel can specifically undergo sol–gel transition. This work not only imparts DNA hydrogel with a new fold of property but also opens a unique platform of such smart materials for its further applications.Keywords: DNA conjugation; DNA hydrogel; hydrogel movement; magnetic nanoparticle; remote controlling;
Co-reporter:Dan Li, Yijie Wang, Linqing Wang, Jie Wang, Pengxin Wang, Kezhou Wang, Li Lin, Dongsheng Liu, Xianxing Jiang and Dongxu Yang
Chemical Communications 2016 vol. 52(Issue 62) pp:9640-9643
Publication Date(Web):14 Jun 2016
DOI:10.1039/C6CC02877B
The first α-sp2-carbon of carbonyl compounds attacked catalytic desymmetrization reaction of aziridines is disclosed. A simple in situ generated magnesium catalyst from 3,3′-bromine-8H-BINOL and dibutylmagnesium was employed. It is interesting that the bromine atom on the chiral ligand plays a key role in introducing a high level of enantioselectivities and high reaction efficiency. Both enantiomers of the ring-opening product could be smoothly obtained by using (R)- and (S)-L7.
Co-reporter:Xu Zhou, Chuang Li, Yu Shao, Chun Chen, Zhongqiang Yang and Dongsheng Liu
Chemical Communications 2016 vol. 52(Issue 70) pp:10668-10671
Publication Date(Web):27 Jul 2016
DOI:10.1039/C6CC04724F
By integrating a DNA motor based on an i-motif sequence that undergoes a pH-dependent conformational transition into a DNA hydrogel network, such microscopic transition leads to a macroscopic change in mechanical properties. This strategy allows reversible tuning of the mechanical strength of the hydrogel ranging from 250 Pa to 1000 Pa.
Co-reporter:Xihong Liu;Yijie Wang;Dongxu Yang;Jinlong Zhang; Dongsheng Liu; Wu Su
Angewandte Chemie International Edition 2016 Volume 55( Issue 28) pp:8100-8103
Publication Date(Web):
DOI:10.1002/anie.201602880
Abstract
Reported herein is a bifunctional-organocatalyst-mediated enantioselective inverse-electron-demand 1,3-dipolar cycloaddition of C,N-cyclic azomethine imines with azlactones. The strategy provides concise access to enantioenriched C1-substituted tetrahydroisoquinolines featuring a pyrazolidinone scaffold. Moreover, the scalability and practical utility of this protocol was well demonstrated by employing a gram-scale reaction and some representative transformations.
Co-reporter:Xihong Liu;Yijie Wang;Dongxu Yang;Jinlong Zhang; Dongsheng Liu; Wu Su
Angewandte Chemie 2016 Volume 128( Issue 28) pp:8232-8235
Publication Date(Web):
DOI:10.1002/ange.201602880
Abstract
Reported herein is a bifunctional-organocatalyst-mediated enantioselective inverse-electron-demand 1,3-dipolar cycloaddition of C,N-cyclic azomethine imines with azlactones. The strategy provides concise access to enantioenriched C1-substituted tetrahydroisoquinolines featuring a pyrazolidinone scaffold. Moreover, the scalability and practical utility of this protocol was well demonstrated by employing a gram-scale reaction and some representative transformations.
Co-reporter:Chuang Li;Matthew J. Rowl;Yu Shao;Tianyang Cao;Chun Chen;Haoyang Jia;Xu Zhou;Zhongqiang Yang;Oren A. Scherman
Advanced Materials 2015 Volume 27( Issue 21) pp:3298-3304
Publication Date(Web):
DOI:10.1002/adma.201501102
Co-reporter:Zhongqiang Yang, Huajie Liu and Dongsheng Liu
NPG Asia Materials 2015 7(2) pp:e161
Publication Date(Web):2015-02-01
DOI:10.1038/am.2015.2
Nanoparticles are among the most fascinating materials because of their unique size-dependent properties. The spatial positioning of the nanoparticles with a nanoscale precision will greatly enhance their potential for use in the fabrication of functional materials and devices. Recently, the development of DNA nanotechnology has enabled the construction of two- and three-dimensional, precisely addressable nanostructures and devices based on DNA sequence design and programmable assembly. Advances in conjugating DNA with nanoparticles can bridge these two technologies and provide scientists with a new tool to study material transportation and energy transfer at a nanometer scale. In this review, we summarize the recent progress in this emerging research field, which includes not only the static arrangements of inorganic nanoparticles but also the dynamic regulation of organic and biological units at a nanometer scale. With the rapid development in this field, new challenges and new possibilities will emerge and bring about fruitful achievements with a significant impact on future work.
Co-reporter:Fen Wu, Juan Jin, Liying Wang, Pengfei Sun, Huanxiang Yuan, Zhongqiang Yang, Guosong Chen, Qing-Hua Fan, and Dongsheng Liu
ACS Applied Materials & Interfaces 2015 Volume 7(Issue 13) pp:7351
Publication Date(Web):March 18, 2015
DOI:10.1021/acsami.5b00702
Specific carbohydrate recognition in biology is a dynamic process. Thus, supramolecular multivalent scaffolds with dynamic features have been applied to mimic this process. Herein, we prepared DNA-dendron supramolecular fibers and synthesized carbohydrate-oligonucleotide conjugates (C18-mannose). Via DNA hybridization, the C18-mannose could be guided onto the fiber platform and form multiple mannose-functionalized fibers, which can be utilized to agglutinate E. coli because of high affinity among multivalent mannose ligands and receptors on E. coli. In addition, via chain exchange reaction of DNAs, the E. coli could be dissociated by replacing multivalent mannose ligands with competitive unmodified DNA sequences. The association and dissociation processes of E. coli are confirmed by fluorescent microscope and transmission electron microscope (TEM). These results not only demonstrate the ability of DNA-dendron fibers in reversibly associating E. coli but also illustrate their potential to be an easily modified multivalent supramolecular platform.Keywords: association and dissociation; carbohydrate recognition; DNA; E. coli; multivalent scaffolds; self-assembly
Co-reporter:Dr. Yuanchen Dong ;Dr. Dongsheng Liu
Chemistry - A European Journal 2015 Volume 21( Issue 50) pp:18018-18023
Publication Date(Web):
DOI:10.1002/chem.201501849
Abstract
Frame-guided assembly, a recently discovered strategy for amphiphilic assembly, is discussed as a strategy for constructing vesicle assemblies with programmed geometries and dimensions under identical surrounding conditions. The strategy is inspired by the cytoskeletal-membrane protein–lipid bilayer structure and shows great potential in the understanding and controlling of the amphiphilic assembly process. Both the principles and basic requirements are discussed, along with recently reported examples. The prospects and potential investigations of frame-guided assembly are also proposed.
Co-reporter:Fen Wu, Yongshun Song, Zhiyong Zhao, Shusheng Zhang, Zhongqiang Yang, Zhibo Li, Ming Li, Qing-Hua Fan, and Dongsheng Liu
Macromolecules 2015 Volume 48(Issue 20) pp:7550-7556
Publication Date(Web):October 14, 2015
DOI:10.1021/acs.macromol.5b01786
Utilizing precise recognition of DNA and thermal responsiveness of poly(propylene oxide), we prepared a supramolecular coil–rod–coil triblock copolymer, PPO–dsDNA–PPO, containing a rigid and charged double-stranded DNA segment in the middle and two thermal responsive PPO segments at the ends. The self-assembly process and structures of final assemblies of this copolymer in aqueous phase were studied by DLS, TEM, and cryo-TEM, which show that spherical assemblies with broad range of sizes were formed under different temperatures or triblock copolymer concentrations. Based on the experimental results, the mechanism of the self-assembly of spherical assemblies was further explained by molecular dynamic simulations.
Co-reporter:Yuanchen Dong, Zhongqiang Yang, and Dongsheng Liu
Accounts of Chemical Research 2014 Volume 47(Issue 6) pp:1853-1860
Publication Date(Web):May 20, 2014
DOI:10.1021/ar500073a
We expect that DNA nanotechnology will continue to develop rapidly. At a fundamental level, further studies should lead to greater understanding of the energy transformation and material transportation mechanisms at the nanometer scale. In terms of applications, we expect that many of these elegant molecular devices will soon be used in vivo. These further studies could demonstrate the power of DNA nanotechnology in biology, material science, chemistry, and physics.
Co-reporter:Yuzhou Wu, Chuang Li, Felix Boldt, Yanran Wang, Seah Ling Kuan, Thuy Tam Tran, Viktoria Mikhalevich, Christina Förtsch, Holger Barth, Zhongqiang Yang, Dongsheng Liu and Tanja Weil
Chemical Communications 2014 vol. 50(Issue 93) pp:14620-14622
Publication Date(Web):23 Sep 2014
DOI:10.1039/C4CC07144A
A modular approach for the precise assembly of multi-component hydrogels consisting of protein and DNA building blocks is described for the first time. Multi-arm DNA is designed for crosslinking and stepwise, non-covalent assembly of active proteins inside the hydrogel.
Co-reporter:Dr. Zhiyong Zhao;Chun Chen;Yuanchen Dong;Dr. Zhongqiang Yang;Dr. Qing-Hua Fan;Dr. Dongsheng Liu
Angewandte Chemie International Edition 2014 Volume 53( Issue 49) pp:13468-13470
Publication Date(Web):
DOI:10.1002/anie.201408231
Abstract
We report a thermally triggered frame-guided assembly (FGA) strategy for the preparation of vesicles. We employ thermally responsive poly(propylene oxide) (PPO) to make the leading hydrophobic groups (LHGs) thermally responsive, so that they are hydrophilic below the low critical solution temperature (LCST) and the frame forms in a homogeneous environment. When the temperature is increased above the LCST, the LHGs become hydrophobic and the assembly process is triggered, which drives DNA-b-PPO to assemble around the LHGs, forming vesicles. This work verified that FGA is a general strategy and can be applied to polymeric systems. The thermally triggered assembly not only provides more controllability over the FGA process but also promotes an in-depth understanding of the FGA strategy and in a broad view, the formation mechanism and functions of cell membrane.
Co-reporter:Yuanchen Dong;Dr. Yawei Sun;Dr. Liying Wang;Dianming Wang;Tao Zhou;Dr. Zhongqiang Yang;Zhong Chen;Dr. Qiangbin Wang;Dr. Qinghua Fan;Dr. Dongsheng Liu
Angewandte Chemie 2014 Volume 126( Issue 10) pp:2645-2648
Publication Date(Web):
DOI:10.1002/ange.201310715
Abstract
In molecular self-assembly molecules form organized structures or patterns. The control of the self-assembly process is an important and challenging topic. Inspired by the cytoskeletal-membrane protein lipid bilayer system that determines the shape of eukaryotic cells, we developed a frame-guided assembly process as a general strategy to prepare heterovesicles with programmed geometry and dimensions. This method offers greater control over self-assembly which may benefit the understanding of the formation mechanism as well as the functions of the cell membrane.
Co-reporter:Yuanchen Dong;Dr. Yawei Sun;Dr. Liying Wang;Dianming Wang;Tao Zhou;Dr. Zhongqiang Yang;Zhong Chen;Dr. Qiangbin Wang;Dr. Qinghua Fan;Dr. Dongsheng Liu
Angewandte Chemie International Edition 2014 Volume 53( Issue 10) pp:2607-2610
Publication Date(Web):
DOI:10.1002/anie.201310715
Abstract
In molecular self-assembly molecules form organized structures or patterns. The control of the self-assembly process is an important and challenging topic. Inspired by the cytoskeletal-membrane protein lipid bilayer system that determines the shape of eukaryotic cells, we developed a frame-guided assembly process as a general strategy to prepare heterovesicles with programmed geometry and dimensions. This method offers greater control over self-assembly which may benefit the understanding of the formation mechanism as well as the functions of the cell membrane.
Co-reporter:Chao Zhou ; Zhongqiang Yang
Journal of the American Chemical Society 2012 Volume 134(Issue 3) pp:1416-1418
Publication Date(Web):January 5, 2012
DOI:10.1021/ja209590u
We report a DNA machine that can reversibly regulate target binding affinity on the basis of distance-dependent bivalent binding. It is a tweezer-like DNA machine that can tune the spatial distance between two ligands to construct or destroy the bivalent binding. The DNA machine can strongly bind to the target protein when the ligands are placed at an appropriate distance but releases the target when the bivalent binding is disrupted by enlargement of the distance between the ligands. This “capture–release” cycle could be repeatedly driven by single-stranded DNA without changing the ligands and target protein.
Co-reporter:Liying Wang, Yu Feng, Zhongqiang Yang, Yan-Mei He, Qing-Hua Fan and Dongsheng Liu
Chemical Communications 2012 vol. 48(Issue 31) pp:3715-3717
Publication Date(Web):23 Feb 2012
DOI:10.1039/C2CC30776F
Spherical micelles and nanofibers assembled from an amphiphilic DNA–dendron hybrid can be reversibly achieved under optimum assembly conditions. The possible morphology transformation mechanism is proposed and further confirmed by X-ray diffraction, TEM and DLS experiments.
Co-reporter:Zhiyong Zhao, Liying Wang, Yu Liu, Zhongqiang Yang, Yan-Mei He, Zhibo Li, Qing-Hua Fan and Dongsheng Liu
Chemical Communications 2012 vol. 48(Issue 78) pp:9753-9755
Publication Date(Web):10 Aug 2012
DOI:10.1039/C2CC33708H
The designed DNA sequences can make DNA-b-PPO undergo in situ transition between diblock and triblock upon pH changes, consequently, induce a morphology-shifting from spherical micelles to nanofibers. This process is reversible and the assembled structures have been characterized by CD, TEM and fluorescent experiments.
Co-reporter:Tao Zhang, Yuanchen Dong, Yawei Sun, Ping Chen, Yang Yang, Chao Zhou, Lijin Xu, Zhongqiang Yang, and Dongsheng Liu
Langmuir 2012 Volume 28(Issue 4) pp:1966-1970
Publication Date(Web):October 13, 2011
DOI:10.1021/la203151b
We report a general approach to bimodify gold nanoparticles (GNPs) with two different DNA strands via DNA template reaction. Two thioctic acid modified DNA strands, one at 5′ end and one at 3′ end, were attached to GNPs through bivalent thiol-gold bond. By sequence design, assemblies of 5 nm GNPs chains, 10 nm GNPs chains and alternative arrangement of 5 and 10 nm GNPs could be achieved. Gel electrophoresis, transmission electron microscope (TEM), UV–vis spectra were used to characterize the assemblies. It is believed that this new kind of bimodified GNPs with two different DNA strands at different ends would enrich the toolbox of DNA–GNP conjugates and provide diverse selectivity for further assembly.
Co-reporter:Yuhe Yang, Yawei Sun, Yang Yang, Yongzheng Xing, Tao Zhang, Zeming Wang, Zhongqiang Yang, and Dongsheng Liu
Macromolecules 2012 Volume 45(Issue 6) pp:2643-2647
Publication Date(Web):March 13, 2012
DOI:10.1021/ma300230q
In this research, we employed tetra(ethylene glycol) (EG4) to substitute bases at the loop region of the intramolecular DNA i-motif formed by (CCCTAA)3CCC, and systematically studied the influence of such nonbase components on the stability and conformation of the formed structures by circular dichroism (CD), UV–vis spectroscopy and gel electrophoresis. We found that with all loop bases substituted, the i-motif structure can still form. The stability of the i-motif generally got weaker with the increase of the substitution number. Substitution at different positions might lead to different topologies. The findings above demonstrate that bases at the loop region play an important role on the stability and topology of the intramolecular DNA i-motif.
Co-reporter:Tao Zhou;Ping Chen;Lin Niu;Juan Jin;Dr. Dehai Liang;Dr. Zhibo Li;Dr. Zhongqiang Yang;Dr. Dongsheng Liu
Angewandte Chemie 2012 Volume 124( Issue 45) pp:11433-11436
Publication Date(Web):
DOI:10.1002/ange.201205862
Co-reporter:Chun Chen, Ming Li, Yongzheng Xing, Yingmei Li, Carl-Christian Joedecke, Juan Jin, Zhongqiang Yang, and Dongsheng Liu
Langmuir 2012 Volume 28(Issue 51) pp:17743-17748
Publication Date(Web):November 13, 2012
DOI:10.1021/la303851a
Using the stopped-flow circular dichroism (SFCD) technique, we investigate the kinetics of the pH-induced folding and unfolding process of the DNA i-motif. The results show that the molecule can fold or unfold on a time scale of 100 ms when the solution pH is changed. It is also found that the folding and unfolding rates strongly depend on the solution pH. On the basis of quantitative data, we propose theoretical models to decipher the folding and unfolding kinetics. Our models suggest that the cooperativity of protons is crucial for both the folding and unfolding process. In the unfolding process, the cooperative neutralization of two protons (out of the total six protons in the i-motif molecule) is the only rate-limiting step. In the folding process, there exists a critical step in which three protons bind cooperatively to the DNA strand. These results offer an in-depth understanding of the folding and unfolding kinetics of the DNA i-motif and may give precise guidance for constructing novel nanodevices based on the DNA i-motif.
Co-reporter:Tao Zhou;Ping Chen;Lin Niu;Juan Jin;Dr. Dehai Liang;Dr. Zhibo Li;Dr. Zhongqiang Yang;Dr. Dongsheng Liu
Angewandte Chemie International Edition 2012 Volume 51( Issue 45) pp:11271-11274
Publication Date(Web):
DOI:10.1002/anie.201205862
Co-reporter:Ping Chen, Chuang Li, Dongsheng Liu, and Zhibo Li
Macromolecules 2012 Volume 45(Issue 24) pp:9579-9584
Publication Date(Web):December 6, 2012
DOI:10.1021/ma302233m
A new type of DNA grafted polypeptide molecular brush was synthesized via a combination of ring-opening polymerization (ROP) and click chemistry. This conjugation method provides an easy and efficient approach to obtain a hybrid DNA-grafted polypeptide molecular bottlebrush. The structure and assembly behaviors of this hybrid brush were investigated using electrophoresis, UV–vis spectroscopy, transmission electron microscopy (TEM), and atomic force microscopy (AFM). Hierarchical supramolecular assemblies can be obtained through hybridization of two kinds of polypeptide-g-DNA molecular bottlebrushes containing complementary DNA side chains. We further demonstrated that such polypeptide-g-DNA can be hybridized with ds-DNA and DNA-grafted gold nanoparticles to form a supermolecular bottlebrush and hybrid bottlebrush, respectively. In addition, DNA-polypeptide hydrogel can be prepared by hybridization of polypeptide-g-DNA with a linker-ds-DNA, which contains the complementary “sticky ends” to serve as cross-linkers.
Co-reporter:Dongsheng Liu, Enjun Cheng and Zhongqiang Yang
NPG Asia Materials 2011 3(12) pp:109-114
Publication Date(Web):2011-12-01
DOI:10.1038/asiamat.2011.147
Other than carrying the code of life, in the past three decades, DNA has played an important role in weaving two- and even three-dimensional nanostructures by taking advantage of its programmable sequences and precise recognition properties. The highly specific base-pairing interactions of DNA molecules not only allow for the building of static DNA nanostructures, but also enable the construction of machine-like devices capable of responding to external stimuli, such as pH, small molecules, light, electricity, and temperature, thus performing tasks otherwise beyond our reach. This review summarizes DNA-based switchable devices and materials, particularly where the responsiveness of DNA is caused by changes in secondary structures, and more importantly, where such stimuli-responsive processes are reversible. This review covers DNA-based devices and materials from smart surfaces and responsive nanopores/nanochannels to DNA hydrogels, which are expected to be designed with even more intelligence in the future.
Co-reporter:Tao Zhang, Zhongqiang Yang and Dongsheng Liu
Nanoscale 2011 vol. 3(Issue 10) pp:4015-4021
Publication Date(Web):09 Sep 2011
DOI:10.1039/C1NR10882D
Recently, controlling assembly process in a precise manner has attracted increasing attentions in nanofabrication. Gold nanoparticles (AuNPs) modified with countable number of DNA strands, i.e., DNA discrete modified AuNPs, which bring AuNPs much more controllable manipulating possibilities have been playing an important role in this field. In this feature article, we will summarize recent progress on their preparation strategies and application in positioning assembly, which could benefit to the improvement of preparation methods of DNA discrete modified AuNPs and even other nanoparticles.
Co-reporter:Tao Zhang, Ping Chen, Yawei Sun, Yongzheng Xing, Yang Yang, Yuanchen Dong, Lijin Xu, Zhongqiang Yang and Dongsheng Liu
Chemical Communications 2011 vol. 47(Issue 20) pp:5774-5776
Publication Date(Web):15 Apr 2011
DOI:10.1039/C1CC11337B
We report a new strategy to prepare DNA mono-modified gold nanoparticles (AuNPs). By adding a short rigid duplex proximal to the AuNPs, the assembly efficiency of DNA mono-modified AuNPs with Y-shaped DNA could be improved nearly 6-fold.
Co-reporter:Enjun Cheng, Yulin Li, Zhongqiang Yang, Zhaoxiang Deng and Dongsheng Liu
Chemical Communications 2011 vol. 47(Issue 19) pp:5545-5547
Publication Date(Web):06 Apr 2011
DOI:10.1039/C1CC11028D
In this communication, we report the preparation of DNA-SWNT hybrid hydrogel which is pH responsive and strength tunable.
Co-reporter:Liying Wang, Yu Feng, Yawei Sun, Zhibo Li, Zhongqiang Yang, Yan-Mei He, Qing-Hua Fan and Dongsheng Liu
Soft Matter 2011 vol. 7(Issue 16) pp:7187-7190
Publication Date(Web):12 Jul 2011
DOI:10.1039/C1SM06028G
A new kind of amphiphilic DNA-dendron hybrid consisting of a highly hydrophobic dendron and a single stranded DNA is synthesized. The hybrid could assemble into long nanofibers in aqueous phase. The hybridization property of DNA at the shell of fibers associated with the encapsulation ability of dendron at the inner core enable further functionalization, offering a unique class of supramolecular building block.
Co-reporter:Yongzheng Xing;Dr. Zhongqiang Yang;Dr. Dongsheng Liu
Angewandte Chemie International Edition 2011 Volume 50( Issue 50) pp:11934-11936
Publication Date(Web):
DOI:10.1002/anie.201105923
Co-reporter:Yongzheng Xing;Dr. Zhongqiang Yang;Dr. Dongsheng Liu
Angewandte Chemie 2011 Volume 123( Issue 50) pp:12140-12142
Publication Date(Web):
DOI:10.1002/ange.201105923
Co-reporter:Lijin Xu and Dongsheng Liu
Chemical Society Reviews 2010 vol. 39(Issue 1) pp:150-155
Publication Date(Web):16 Sep 2009
DOI:10.1039/B813083N
After more than twenty years of effort, using DNA to fabricate addressable nanostructures is now a well-established technology. In this tutorial review, we attempt to present an overview of the applications of DNA templates, including its biological significance, the directing of chemical reactions at the molecular level, as well as the placing of nanoparticles and proteins in position.
Co-reporter:Ping Chen, Yawei Sun, Huajie Liu, Lijin Xu, Qinghua Fan and Dongsheng Liu
Soft Matter 2010 vol. 6(Issue 10) pp:2143-2145
Publication Date(Web):14 Apr 2010
DOI:10.1039/C002377A
A pH responsive dendron-DNA-protein hybrid molecular system has been designed and prepared via chemical systhesis and assembly process. The size of this molecular system could be switched by the conformation change of the i-motif DNA. Its structure and switching mechanism has been characterized by mass spectroscopy, electrophoresis, circular dichroism (CD) spectroscopy and UV/Vis spectroscopy.
Co-reporter:Enjun Cheng;Yongzheng Xing;Ping Chen;Yang Yang;Yawei Sun Dr.;Dejian Zhou Dr.;Lijin Xu ;Qinghua Fan
Angewandte Chemie International Edition 2009 Volume 48( Issue 41) pp:7660-7663
Publication Date(Web):
DOI:10.1002/anie.200902538
Co-reporter:Xu Zhou, Chuang Li, Yu Shao, Chun Chen, Zhongqiang Yang and Dongsheng Liu
Chemical Communications 2016 - vol. 52(Issue 70) pp:NaN10671-10671
Publication Date(Web):2016/07/27
DOI:10.1039/C6CC04724F
By integrating a DNA motor based on an i-motif sequence that undergoes a pH-dependent conformational transition into a DNA hydrogel network, such microscopic transition leads to a macroscopic change in mechanical properties. This strategy allows reversible tuning of the mechanical strength of the hydrogel ranging from 250 Pa to 1000 Pa.
Co-reporter:Liying Wang, Yu Feng, Zhongqiang Yang, Yan-Mei He, Qing-Hua Fan and Dongsheng Liu
Chemical Communications 2012 - vol. 48(Issue 31) pp:NaN3717-3717
Publication Date(Web):2012/02/23
DOI:10.1039/C2CC30776F
Spherical micelles and nanofibers assembled from an amphiphilic DNA–dendron hybrid can be reversibly achieved under optimum assembly conditions. The possible morphology transformation mechanism is proposed and further confirmed by X-ray diffraction, TEM and DLS experiments.
Co-reporter:Yuzhou Wu, Chuang Li, Felix Boldt, Yanran Wang, Seah Ling Kuan, Thuy Tam Tran, Viktoria Mikhalevich, Christina Förtsch, Holger Barth, Zhongqiang Yang, Dongsheng Liu and Tanja Weil
Chemical Communications 2014 - vol. 50(Issue 93) pp:NaN14622-14622
Publication Date(Web):2014/09/23
DOI:10.1039/C4CC07144A
A modular approach for the precise assembly of multi-component hydrogels consisting of protein and DNA building blocks is described for the first time. Multi-arm DNA is designed for crosslinking and stepwise, non-covalent assembly of active proteins inside the hydrogel.
Co-reporter:Zhiyong Zhao, Liying Wang, Yu Liu, Zhongqiang Yang, Yan-Mei He, Zhibo Li, Qing-Hua Fan and Dongsheng Liu
Chemical Communications 2012 - vol. 48(Issue 78) pp:NaN9755-9755
Publication Date(Web):2012/08/10
DOI:10.1039/C2CC33708H
The designed DNA sequences can make DNA-b-PPO undergo in situ transition between diblock and triblock upon pH changes, consequently, induce a morphology-shifting from spherical micelles to nanofibers. This process is reversible and the assembled structures have been characterized by CD, TEM and fluorescent experiments.
Co-reporter:Lijin Xu and Dongsheng Liu
Chemical Society Reviews 2010 - vol. 39(Issue 1) pp:NaN155-155
Publication Date(Web):2009/09/16
DOI:10.1039/B813083N
After more than twenty years of effort, using DNA to fabricate addressable nanostructures is now a well-established technology. In this tutorial review, we attempt to present an overview of the applications of DNA templates, including its biological significance, the directing of chemical reactions at the molecular level, as well as the placing of nanoparticles and proteins in position.
Co-reporter:Tao Zhang, Ping Chen, Yawei Sun, Yongzheng Xing, Yang Yang, Yuanchen Dong, Lijin Xu, Zhongqiang Yang and Dongsheng Liu
Chemical Communications 2011 - vol. 47(Issue 20) pp:NaN5776-5776
Publication Date(Web):2011/04/15
DOI:10.1039/C1CC11337B
We report a new strategy to prepare DNA mono-modified gold nanoparticles (AuNPs). By adding a short rigid duplex proximal to the AuNPs, the assembly efficiency of DNA mono-modified AuNPs with Y-shaped DNA could be improved nearly 6-fold.
Co-reporter:Enjun Cheng, Yulin Li, Zhongqiang Yang, Zhaoxiang Deng and Dongsheng Liu
Chemical Communications 2011 - vol. 47(Issue 19) pp:NaN5547-5547
Publication Date(Web):2011/04/06
DOI:10.1039/C1CC11028D
In this communication, we report the preparation of DNA-SWNT hybrid hydrogel which is pH responsive and strength tunable.
Co-reporter:Dan Li, Yijie Wang, Linqing Wang, Jie Wang, Pengxin Wang, Kezhou Wang, Li Lin, Dongsheng Liu, Xianxing Jiang and Dongxu Yang
Chemical Communications 2016 - vol. 52(Issue 62) pp:NaN9643-9643
Publication Date(Web):2016/06/14
DOI:10.1039/C6CC02877B
The first α-sp2-carbon of carbonyl compounds attacked catalytic desymmetrization reaction of aziridines is disclosed. A simple in situ generated magnesium catalyst from 3,3′-bromine-8H-BINOL and dibutylmagnesium was employed. It is interesting that the bromine atom on the chiral ligand plays a key role in introducing a high level of enantioselectivities and high reaction efficiency. Both enantiomers of the ring-opening product could be smoothly obtained by using (R)- and (S)-L7.
Co-reporter:Chuang Li, Xu Zhou, Yu Shao, Ping Chen, Yongzheng Xing, Zhongqiang Yang, Zhibo Li and Dongsheng Liu
Inorganic Chemistry Frontiers 2017 - vol. 1(Issue 4) pp:NaN659-659
Publication Date(Web):2016/09/26
DOI:10.1039/C6QM00176A
Preparation of hydrogels with solely variable mechanical properties is greatly desired in the study of cell-matrix interactions in situ as well as cellular behaviors. Here, we fabricated a supramolecular polypeptide–DNA hydrogel, via the DNA self-assembly strategy, which possesses identical cross-linking point density but distinctive rheological properties. Keeping the cross-linking density constant, the rheological properties of the hydrogel can be adjusted by tailoring the stability of the DNA cross-linkers via easy programming of the DNA sequences. Through elongating and shortening the length of the DNA linker or inserting mismatch sites, the hydrogel can be strengthened, softened, or even fluidized, respectively. In addition, the mechanical properties can also be modulated by a pH-triggered conformation transition of the polypeptide backbone. Combining rapid physiological gelation and reversible thermal responsiveness, these supramolecular polypeptide–DNA hydrogels with solely tuned mechanical strength will promote studies on mechanical induced cell differentiation in situ, and have great potential in tissue engineering.
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