Data from: Dynamic actuation and hierarchical assembly of iron oxide-coated DNA origami

Jergens, Elizabeth 1 ; GayathriSrinivasan, Nanditha 1 ; Kucinic, Anjelica1; Shahhosseini, Melika1; Kruse, Marissa1; Teng, Teng1; Huang, Kehao1; Poirier, Michael G.1; Castro, Carlos E.1; Winter, Jessica O.1

Published Apr 06, 2026 on Dryad. https://doi.org/10.5061/dryad.x3ffbg7tx

Abstract

Deoxyribonucleic acid (DNA)-based nanomaterials can template growth of nanostructured films on their surfaces, generating complex morphologies. However, previous work has not explored the application of this approach to DNA nanostructures capable of large shape transformations. This study investigated the application of in situ reduction chemistries to dynamic DNA origami materials. Extending beyond past work using gold or silica, iron oxide nanostructures were grown on a variety of DNA origami geometries at different iron: DNA origami molar ratios (i.e., 25,000 to 1,000,000). Growth was visualized using transmission electron microscopy (TEM) with energy dispersive X-ray spectroscopy (EDS), which indicated the presence of electron dense iron oxide. Structures generally retained their geometric form factors, with some modifications observed in TEM. Structures formed at the highest ratios (i.e., 500,000 to 1,000,000) aggregated, providing an upper limit for this method. DNA origami nanostructures were programmed with single-stranded DNA (ssDNA) overhangs for binding complementary ssDNA-modified cargoes, inducing structural transformations, and for hierarchical assembly. Overhang function-ality in coated structures was assessed by gold nanoparticle (AuNP) binding, actuation of two different DNA origami nanostructures, and polymerization into nanotube bundles. These findings indicate that the in situ reduction technique can be applied to dynamic DNA origami structures, retaining their capacity for large shape changes, and that overhangs presented by those structures retain functionality. This approach enables dynamic transformation of individual inorganic nanostructure shapes and assembly of units into larger, arrayed materials.

Dataset DOI: 10.5061/dryad.x3ffbg7tx

Description of the data and file structure

.dm3 files can be opened through the EMAN2, IMAGEJ / FIJI
The data was collected using the Transmission Electron Microscope (TEM) and the sample was analyzed using the Energy Dispersive X-ray Spectroscopy (EDS) to confirm the presence of Iron.

Files and variables

File: 1m3.tif

Description: TEM image of hinge at Fe to DNA origami ratio of 1M

File: 250k2.tif

Description: TEM image of hinge at Fe to DNA origami ratio of 250,000

File: 100k3.tif

Description: TEM image of hinge at Fe to DNA origami ratio of 100,000

File: 750k2.tif

Description: TEM image of hinge at Fe to DNA origami ratio of 750,000

File: 50k4.tif

Description: TEM image of hinge at Fe to DNA origami ratio of 50,000

File: 375k2.tif

Description: TEM image of hinge at Fe to DNA origami ratio of 375,000

File: 500k3.tif

Description: TEM image of hinge at Fe to DNA origami ratio of 500,000

File: 0-3.tif

Description: TEM image of Nanodyn at No fe

File: 1M-1.tif

Description: TEM image of Nanodyn at Fe to DNA origami ratio of 1M

File: 100-2.tif

Description: TEM image of Nanodyn at Fe to DNA origami ratio of 100,000

File: 375-3.tif

Description: TEM image of Nanodyn at Fe to DNA origami ratio of 375,000

File: 750-1.tif

Description: TEM image of Nnaodyn at Fe to DNA origami ratio of 750,000

File: 250-2.tif

Description: TEM image of Nanodyn at Fe to DNA origami ratio of 250,000

File: 50-1.tif

Description: TEM image of Nanodyn at Fe to DNA origami ratio of 50,000

File: 500-1.tif

Description: TEM image of Nanodyn at Fe to DNA origami ratio of 500,000

File: RAW_DATA_(1).zip

Description: These are the TEM images of various nanostructures such as hexagon, rectangle, flat-close, hinge, and nano-dyne in both coated and uncoated forms. Image averaging was performed using EMAN software.There are two sub folders named fig 3 and fig 5

In fig 3, there are 5 subfolders named Flatclose, hexagon, hinge, Nanodyne and Rectangle. These are the different shapes of DNA nanostructures.

In flat close, there are 3 images

1. Fc_avg. png – these are the Fe coated averaged image using EMAN software

2. FcA-2tif – Fe coated TEM image of flat close

3. No fe 5 _ uncoated TEM image of flat close structure

In hexagon, there are 3 images

1. Hex No fe_1 tif - TEM image of uncoated hexagon structure

2. Hex_6 tif – TEM image of Fe coated hexagon structure

3. Hex1.01.02.png – averaged image of Fe coated hexagon structure

In hinge, there are 3 images

1. 250k2.tif, - TEM image Fe coated hinges

2. Aliref_07.01.png - averaged image of Fe coated hinge

3. 0k3. Tif, - TEM image of uncoated hinge

In Nanodyne, there are 3 images

1. 0-3.tif, - TEM image of uncoated nanodyne

2. Nano_3.04 png – Fe coated averaged image of nanodyne

3. Nd_2.tif, - Fe coated TEM image of nanodyne

In rectangle, there are 3 images,

1. Rec1, fe 1.tif - Fe coated TEM image of rectangle

2. Rec 5, no fe tif, - uncoated TEM image of rectangle

3. Rec_08.03.png, - Fe coated averaged image of rectangle

In Subfolder fig 5, there are 9 images

1. 6bar_fc_2cyc 6mMFE_nostain_avg2.png – Fe coated averaged Image of flat close structure

2. 6bar_fe.tif – Fe coated TEM image of flat close structure

3. 6bar_nofe.tif – uncoated TEM image of flat close structure

4. Fe_21.tif – TEM image free state structures

5. Fig 6.jpg – Fe coated TEM image of free state structures

6. Hex3_06.00.png – Fe coated averaged image of free state structure

7. Hexnofe_02.01.png – averaged image of Un coated free state structure

8. img avg.jpg – averaged image of uncoated flat close structure

9. nofe_4.tif – TEM image of uncoated free state

.tiff - Transmission Electron Microscopy (TEM) images
Scale bars embedded in images (nm)

File: FC_AB_POLY.zip

Description: These are the TEM images of polymerized flatclose structures in both coated and uncoated forms.

File: figure_2.zip

Description: Contains processed and averaged image files used to generate Figure 2 in the manuscript.

The dataset contains original .dm3 files, which are raw TEM data files generated during EDS acquisition. These files can be opened using ImageJ Fiji software.

Sample1-0001 and Sample1-0002: High-magnification TEM images of hinge structures acquired during EDS analysis.
Sample1-0003 and Sample1-0004: Low-magnification (wide-field) TEM images captured during EDS analysis.

Averaged TEM images (generated using EMAN2)

EDS_selected_peaks: Contains processed EDS data highlighting the selected elemental peaks used for analysis in Figure 1(D) on the manuscript. These values were derived from the raw spectra to identify and compare key elemental signatures.Processed dataset highlighting selected elemental peaks derived from raw EDS spectra. X - (keV) Energy of detected X-rays in kilo-electron volts, structure (counts)- Measured EDS intensity from the sample region and the background (counts)- Measured EDS intensity from the background region
Background_EDS_values: Includes raw EDS measurements obtained from background regions (non-structure areas). These values were used as a baseline for comparison with structure specific signals. Raw background EDS intensity values. They have 2 columns - Energy (keV), Intensity (counts)- Measured signal intensity
Structure_EDS_values: Contains raw EDS measurements collected from the DNA origami structures. These data represent the elemental composition of the structures and are used to confirm material presence and coating. Raw EDS intensity values corresponding to the sample (structure) regions. Energy (keV) and the intensity (counts) are the two columns.

File: figure_5.zip

Description: Contains the image files for Figure 5 in the manuscript.

File: eman2_codes.txt

Description: Contains the code used to generate the image averaged images in Figures 2 and 5.

Code/software

We used ImageJ software to analyze our TEM data and EMAN2 for image averaging. The TEM images were saved in standard TIFF format, which can be easily viewed without specialized software.

Access information

Other publicly accessible locations of the data:

Data was derived from the following sources: