Shape-specific nanostructured protein mimics from de novo designed chimeric peptides

Linhai Jiang; Su Yang; Reidar Lund; He Dong

doi:10.1039/c7bm00906b

Methionine-stabilized nonclassical growth within self-assembled de novo gold nanoparticles in conjunction with secondary nucleation inhibition

10.21203/rs.3.rs-961831/v1 ◽

2021 ◽

Author(s):

Jitendra Sahu ◽

Shahbaz Lone ◽

Kalyan Sadhu

Keyword(s):

Self Assembly ◽

De Novo ◽

Noble Metal Nanoparticles ◽

Secondary Nucleation ◽

Unique Case ◽

Primary Particles ◽

Growth Reaction ◽

Aurophilic Interaction ◽

Key Steps

Abstract The key steps for seed mediated growth of noble metal nanoparticles involve primary and secondary nucleation, which depends upon the energy barrier and ligand supersaturation standards of the medium. Herein we report the unique case of methionine (Met) controlled growth reaction, which rather proceeds via impeding secondary nucleation in presence of citrate stabilized gold nanoparticle (AuNP). The interaction between freshly generated Au+ and thioether group of Met in the medium restricts the secondary nucleation process involving further Au+ reduction. This incomplete conversion of Au+ results in a significant enhancement of the zeta (ζ) potential even at low concentration of Met. Furthermore, the aurophilic interaction of Au+ controls the self-assembly process of the in situ generated emissive nucleated particles. Nucleation of primary particles on seed surface, their segregation and time dependent conversion to larger particles within self-assembly confirm the nonclassical growth, which has further been explored with Met containing bio-inspired peptides.

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De novo centriole formation in human cells is error-prone and does not require SAS-6 self-assembly

eLife ◽

10.7554/elife.10586 ◽

2015 ◽

Vol 4 ◽

Cited By ~ 27

Author(s):

Won-Jing Wang ◽

Devrim Acehan ◽

Chien-Han Kao ◽

Wann-Neng Jane ◽

Kunihiro Uryu ◽

...

Keyword(s):

Self Assembly ◽

De Novo ◽

Human Cells ◽

De Novo Synthesis ◽

Current Paradigm

Vertebrate centrioles normally propagate through duplication, but in the absence of preexisting centrioles, de novo synthesis can occur. Consistently, centriole formation is thought to strictly rely on self-assembly, involving self-oligomerization of the centriolar protein SAS-6. Here, through reconstitution of de novo synthesis in human cells, we surprisingly found that normal looking centrioles capable of duplication and ciliation can arise in the absence of SAS-6 self-oligomerization. Moreover, whereas canonically duplicated centrioles always form correctly, de novo centrioles are prone to structural errors, even in the presence of SAS-6 self-oligomerization. These results indicate that centriole biogenesis does not strictly depend on SAS-6 self-assembly, and may require preexisting centrioles to ensure structural accuracy, fundamentally deviating from the current paradigm.

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Capacity of the Golgi Apparatus for Biogenesis from the Endoplasmic Reticulum

Molecular Biology of the Cell ◽

10.1091/mbc.e03-06-0437 ◽

2003 ◽

Vol 14 (12) ◽

pp. 5011-5018 ◽

Cited By ~ 62

Author(s):

Sapna Puri ◽

Adam D. Linstedt

Keyword(s):

Endoplasmic Reticulum ◽

Golgi Apparatus ◽

Self Assembly ◽

De Novo ◽

Brefeldin A ◽

The Other ◽

Matrix Proteins ◽

Er Export ◽

Golgi Matrix

It is unclear whether the mammalian Golgi apparatus can form de novo from the ER or whether it requires a preassembled Golgi matrix. As a test, we assayed Golgi reassembly after forced redistribution of Golgi matrix proteins into the ER. Two conditions were used. In one, ER redistribution was achieved using a combination of brefeldin A (BFA) to cause Golgi collapse and H89 to block ER export. Unlike brefeldin A alone, which leaves matrix proteins in relatively large remnant structures outside the ER, the addition of H89 to BFA-treated cells caused ER accumulation of all Golgi markers tested. In the other, clofibrate treatment induced ER redistribution of matrix and nonmatrix proteins. Significantly, Golgi reassembly after either treatment was robust, implying that the Golgi has the capacity to form de novo from the ER. Furthermore, matrix proteins reemerged from the ER with faster ER exit rates. This, together with the sensitivity of BFA remnants to ER export blockade, suggests that presence of matrix proteins in BFA remnants is due to cycling via the ER and preferential ER export rather than their stable assembly in a matrix outside the ER. In summary, the Golgi apparatus appears capable of efficient self-assembly.

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Interfacial zippering-up of coiled-coil protein filaments

Physical Chemistry Chemical Physics ◽

10.1039/c5cp05938k ◽

2015 ◽

Vol 17 (46) ◽

pp. 31055-31060 ◽

Cited By ~ 6

Author(s):

Emiliana De Santis ◽

Valeria Castelletto ◽

Maxim G. Ryadnov

Keyword(s):

Self Assembly ◽

De Novo ◽

Coiled Coil ◽

Morphological Control

A de novo self-assembly topology for engineering protein nanostructures under morphological control is reported.

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MrDNA: a multi-resolution model for predicting the structure and dynamics of DNA systems

Nucleic Acids Research ◽

10.1093/nar/gkaa200 ◽

2020 ◽

Vol 48 (9) ◽

pp. 5135-5146 ◽

Cited By ~ 7

Author(s):

Christopher Maffeo ◽

Aleksei Aksimentiev

Keyword(s):

Self Assembly ◽

De Novo ◽

Dna Nanotechnology ◽

Equilibrium Structure ◽

Molecular Graphics ◽

Structure And Dynamics ◽

Self Assembled ◽

Actual Shape ◽

And Function ◽

Assembly Principles

Abstract Although the field of structural DNA nanotechnology has been advancing with an astonishing pace, de novo design of complex 3D nanostructures and functional devices remains a laborious and time-consuming process. One reason for that is the need for multiple cycles of experimental characterization to elucidate the effect of design choices on the actual shape and function of the self-assembled objects. Here, we demonstrate a multi-resolution simulation framework, mrdna, that, in 30 min or less, can produce an atomistic-resolution structure of a self-assembled DNA nanosystem. We demonstrate fidelity of our mrdna framework through direct comparison of the simulation results with the results of cryo-electron microscopy (cryo-EM) reconstruction of multiple 3D DNA origami objects. Furthermore, we show that our approach can characterize an ensemble of conformations adopted by dynamic DNA nanostructures, the equilibrium structure and dynamics of DNA objects constructed using off-lattice self-assembly principles, i.e. wireframe DNA objects, and to study the properties of DNA objects under a variety of environmental conditions, such as applied electric field. Implemented as an open source Python package, our framework can be extended by the community and integrated with DNA design and molecular graphics tools.

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De novo design of protein mimics of B-DNA

Molecular BioSystems ◽

10.1039/c5mb00524h ◽

2016 ◽

Vol 12 (1) ◽

pp. 169-177 ◽

Cited By ~ 5

Author(s):

Deniz Yüksel ◽

Piero R. Bianco ◽

Krishna Kumar

Keyword(s):

De Novo ◽

De Novo Design ◽

Protein Mimics

Structural mimicry of DNA is utilized in nature as a strategy to evade molecular defences mounted by host organisms.

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Self-assembly of large RNA structures: learning from DNA nanotechnology

DNA and RNA Nanotechnology ◽

10.1515/rnan-2015-0002 ◽

2016 ◽

Vol 2 (1) ◽

Cited By ~ 3

Author(s):

Jaimie Marie Stewart ◽

Elisa Franco

Keyword(s):

Self Assembly ◽

De Novo ◽

Dna Nanotechnology ◽

De Novo Design ◽

Dna Nanostructures ◽

Rna Structures ◽

Functional Nanostructures ◽

Rna And Dna ◽

Unique Chemical

AbstractNucleic acid nanotechnology offers many methods to build self-assembled structures using RNA and DNA. These scaffolds are valuable in multiple applications, such as sensing, drug delivery and nanofabrication. Although RNA and DNA are similar molecules, they also have unique chemical and structural properties. RNA is generally less stable than DNA, but it folds into a variety of tertiary motifs that can be used to produce complex and functional nanostructures. Another advantage of using RNA over DNA is its ability to be encoded into genes and to be expressed in vivo. Here we review existing approaches for the self-assembly of RNA and DNA nanostructures and specifically methods to assemble large RNA structures. We describe de novo design approaches used in DNA nanotechnology that can be ported to RNA. Lastly, we discuss some of the challenges yet to be solved to build micron-scale, multi stranded RNA scaffolds.

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Beyond icosahedral symmetry in packings of proteins in spherical shells

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1706825114 ◽

2017 ◽

Vol 114 (34) ◽

pp. 9014-9019 ◽

Cited By ~ 17

Author(s):

Majid Mosayebi ◽

Deborah K. Shoemark ◽

Jordan M. Fletcher ◽

Richard B. Sessions ◽

Noah Linden ◽

...

Keyword(s):

Self Assembly ◽

De Novo ◽

Multiple Scales ◽

Building Blocks ◽

Icosahedral Symmetry ◽

Protein Cages ◽

Natural Systems ◽

Wide Range ◽

Stable Arrangement ◽

Symmetric Structures

The formation of quasi-spherical cages from protein building blocks is a remarkable self-assembly process in many natural systems, where a small number of elementary building blocks are assembled to build a highly symmetric icosahedral cage. In turn, this has inspired synthetic biologists to design de novo protein cages. We use simple models, on multiple scales, to investigate the self-assembly of a spherical cage, focusing on the regularity of the packing of protein-like objects on the surface. Using building blocks, which are able to pack with icosahedral symmetry, we examine how stable these highly symmetric structures are to perturbations that may arise from the interplay between flexibility of the interacting blocks and entropic effects. We find that, in the presence of those perturbations, icosahedral packing is not the most stable arrangement for a wide range of parameters; rather disordered structures are found to be the most stable. Our results suggest that (i) many designed, or even natural, protein cages may not be regular in the presence of those perturbations and (ii) optimizing those flexibilities can be a possible design strategy to obtain regular synthetic cages with full control over their surface properties.

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Peptide α-helices for synthetic nanostructures

Biochemical Society Transactions ◽

10.1042/bst0350487 ◽

2007 ◽

Vol 35 (3) ◽

pp. 487-491 ◽

Cited By ~ 16

Author(s):

M.G. Ryadnov

Keyword(s):

Self Assembly ◽

De Novo ◽

Three Dimensional ◽

Functional Materials ◽

Protein Assemblies ◽

Helical Peptides ◽

Design Rules ◽

Natural Protein ◽

Self Assembling ◽

Recent Developments

Supramolecular structures arising from a broad range of chemical archetypes are of great technological promise. Defining such structures at the nanoscale is crucial to access principally new types of functional materials for applications in bionanotechnology. In this vein, biomolecular self-assembly has emerged as an efficient approach for building synthetic nanostructures from the bottom up. The approach predominantly employs the spontaneous folding of biopolymers to monodisperse three-dimensional shapes that assemble into hierarchically defined mesoscale composites. An immediate interest here is the extraction of reliable rules that link the chemistry of biopolymers to the mechanisms of their assembly. Once established these can be further harnessed in designing supramolecular objects de novo. Different biopolymer classes compile a rich repertoire of assembly motifs to facilitate the synthesis of otherwise inaccessible nanostructures. Among those are peptide α-helices, ubiquitous folding elements of natural protein assemblies. These are particularly appealing candidates for prescriptive supramolecular engineering, as their well-established and conservative design rules give unmatched predictability and rationale. Recent developments of self-assembling systems based on helical peptides, including fibrous systems, nanoscale linkers and reactors will be highlighted herein.

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Commentary progress in the de novo design of structured peptoid protein mimics

Biopolymers ◽

10.1002/bip.21621 ◽

2011 ◽

Vol 96 (5) ◽

pp. 556-560 ◽

Cited By ~ 12

Author(s):

Modi Wetzler ◽

Annelise E. Barron

Keyword(s):

De Novo ◽

De Novo Design ◽

Protein Mimics

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