A Single‐Step Photolithographic Interface for Cell‐Free Gene Expression and Active Biochips

Buxboim, Amnon; Bar-Dagan, Maya; Frydman, Veronica; Zbaida, David; Morpurgo, Margherita; Bar‐Ziv, Roy

doi:10.1002/smll.200600489

Cited by 84 publications

(110 citation statements)

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“…For brush assembly we used glass slides, 18 × 18 mm 2 , with nine separate reaction chambers enclosed in a sample holder (6)(7)(8). The density of DNA brushes on the same slide and duplicate slides could be fixed to within 5%.…”

Section: Methodsmentioning

confidence: 99%

“…We propose an in vitro methodology to emulate gene expression in a boundary-free compartment. The approach is based on a photolithographic biochip for fabricating dense phases of surface-bound DNA, thus forming DNA brushes (6)(7)(8). In general, brushes are formed when end-attached linear polymers collectively stretch because of excluded volume interaction when packed to distances at which there is significant overlap between neighboring molecules (9).…”

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confidence: 99%

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Compartmentalization by directional gene expression

Daube¹,

Bracha

Buxboim

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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The coalescence of basic biochemical reactions into compartments is a major hallmark of a living cell. Using surface-bound DNA and a transcription reaction, we investigate the conditions for boundaryfree compartmentalization. The DNA self-organizes into a dense and ordered phase with coding sequences aligned at well-defined distances and orientation relative to the surface, imposing directionality on transcription. Unique to the surface in comparison to dilute homogeneous DNA solution, the reaction slows down early, is inhibited with increased DNA density, is favorable for surface-oriented promoters, and is robust against DNA condensation. We interpret these results to suggest that macromolecules (RNA polymerase and RNA), but not solutes (ions and nucleotides), are partitioned between immobilized DNA and the reservoir. Without any physical barrier, a nonequilibrium directional DNA transaction forms macromolecular gradients that define a compartment, thus offering a boundary-free approach to the assembly of a synthetic cell.Introduction and Motivation Cellular Compartments. The transition from dispersed homogeneous solution into cellular compartments must have been a hallmark in the generation of living systems (1). A compartment separates self from non-self, creates a linkage between genotype and phenotype, partitions solutes and macromolecules, and optimizes conditions for biochemical reactions separated from a reservoir. Subcellular compartments may exist without physical boundaries of a membrane. For example, the bacterial genome is segregated from the cytoplasm (2), and gene expression has been shown to be spatially resolved; ribosomes were found to be localized mainly to the periphery of the nucleoid, whereas transcription (TX) factories were mapped to interior regions (3). Similarly, TX activity in the eukaryotic nucleus has been shown to be arranged nonrandomly, with a linkage between the position of genes in the chromosome and their expression level, implying concentration gradients and structural scaffolding of TX factors (4, 5). Therefore, gene expression takes place in highly dense compartments of macromolecules and solutes, with order and orientation of genes, in contact with a feeding reservoir. Generally, however, our understanding of the effect of density, spatial heterogeneity, and order on gene expression has been limited by the difficulty to experimentally reproduce in vitro the crowded and compartmentalized nature of the cellular DNA environment.

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Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

Compartmentalization by directional gene expression

Daube¹,

Bracha

Buxboim

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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“…[8][9][10][11] The biosynthetic reaction on surface of microchips was first realized by Buxboim et al and they developed and utilized the microchips assembled by photolithographic approach on silicon dioxide (SiO2) for controlling the cell-free expression. 7,8,12 This approach allows us to control the immobilized DNA and regulate the biosynthetic reactions in a more controlled manner. 7 Recently, it has been reported that there exists attenuation of protein synthesis in a translation coupled with a transcription system on DNA-grafted biochips, which is likely due to molecular crowding caused by the translational machinery.…”

Section: 5mentioning

confidence: 99%

RNA Polymerase Activity Assay on Biochips: Correlation between Template DNA Density and RNA Synthesis

Lee¹,

Seo²,

Kim³

et al. 2010

Bulletin of the Korean Chemical Society

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EDC: T-SH template DNA (B)T-SH template DNA 5'SH-AAC TGG CCG CTGAAG GGC TTT TGA ACT CTG CTT AAA TCC TAT AGT GAG TCG TAT TAG TCC-3' T7 primer 5'-GGACTAATACGACTCACTATA-3' Primer T7 RNA polymerase Figure 1. (A) Structure of SAMs on gold and chemical modifications to prepare template DNA-presenting biochips. The carboxylic acidpresenting monolayer was treated with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride (EDC) and N-aminoethyl maleimide, followed by thiolated template DNA. (B) Strategy for T7 RNAP activity assay on biochips and the sequences of oligonucleotides (T7 promoter sequences underlined) used in this study.In vitro synthesis of RNAs by bacteriophage T7 RNA polymerase (T7 RNAP) has been applied extensively to the investigation of RNA serving as a biologically active molecule. T7 RNAP is a single subunit enzyme with a molecular weight of 98 kDa that is capable of catalyzing transcription without any accessory proteins.1-3 Other RNA polymerases derived from bacteriophage (SP6 and T3) were also useful for in vitro synthesis of RNA. Each RNA polymerase has different DNA promoter sequences for initiation of transcription. The behavior of T7 RNAP is critically dependent on its interaction with the promoter element in template DNA. The T7 bacteriophage genome contains a variety of promoters that are recognized by T7 RNAP, all of which are related to a 23-base pair consensus sequence (see Figure 1). 1 The promoter can be divided into a recognition domain, encompassing positions 17 through 5, and an initiation domain, encompassing positions 4 through +6 with a transcription start site initiates at the +1 position. 4,5a These authors equally contributed to this study.Cell-free transcription and translation system on solid surface has been developed and utilized in many genomic studies.6-8 As a new research tool, cell-free gene expression has been applied to DNA-based biochips, which showed possibilities of developing synthetic biological systems and biochemical materials at nanoscale. [8][9][10][11] The biosynthetic reaction on surface of microchips was first realized by Buxboim et al. and they developed and utilized the microchips assembled by photolithographic approach on silicon dioxide (SiO2) for controlling the cell-free expression. 7,8,12 This approach allows us to control the immobilized DNA and regulate the biosynthetic reactions in a more controlled manner. 7 Recently, it has been reported that there exists attenuation of protein synthesis in a translation coupled with a transcription system on DNA-grafted biochips, which is likely due to molecular crowding caused by the translational machinery. 7Here, we investigated T7 RNAP enzyme activity of RNA synthesis on self assembled monolayers (SAMs) on gold surface which presents template DNA at various surface densities ranging from 5% to 50%. Using the matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS), binding of T7 RNAP to T7 promoter sequence in the DNA template on chip was analyzed and the activity of...

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“…Bar-Ziv and co-workers (Buxboim et al, 2007) recently developed an elegant approach to such a continuous system, which also provided the solution to another problem of current cell-free gene expression methods: in experiments conducted in bulk solution or microcompartments, reactions are not "localized." This is in contrast to the situation found in highly structured biological cells, where several stages of information-processing cascades are often co-localized.…”

Section: Cell-free Genetic Circuit Assemblymentioning

confidence: 99%

“…Different network connectivities resulted in distinct transitory expression domain patterns, resembling gap formation in the Drosophila embryo. Obviously, the above-mentioned chip-based expression system (Buxboim et al, 2007) should also be of great interest for the study of spatio-temporal effects and the realization of synthetic developmental systems in vitro.…”

Section: Artificial Developmentmentioning

confidence: 99%