Below is a step-by-step research-grade tutorial tailored to your background in biochemistry and nanomaterials. 🧬 1. Concept Overview A DNA box is built using: A long scaffold strand (typically M13 bacteriophage DNA) Hundreds of short staple oligonucleotides These staples “fold” the scaffold into a rectangular cuboid (box) via: Watson–Crick base pairing Controlled crossover junctions 2. Design Strategy Geometry Typical dimensions: Length: 30–50 nm Width: 20–30 nm Height: 20–30 nm Rectangular boxes consist of: 6 faces (like a cube but elongated) Each face = DNA helices arranged in parallel 3. Software Design Tools Use specialized tools: caDNAno (most widely used) CanDo (for mechanical validation) Steps in caDNAno: Choose square lattice Route scaffold in a rectangular path Insert crossovers every 16 bp (for stability) Design staples (~20–60 nt each) 4. Sequence Design Scaffold Use: M13mp18 (~7249 nt) Staples Typically 150–250 oligos Length: 18–60 nucleotides Designed to: Bind specific scaffold regions Create crossovers between helices 👉 Export sequences from caDNAno as CSV 5. Materials Required Scaffold DNA (M13) Synthetic staple oligonucleotides MgCl₂ (critical for folding) Tris buffer (pH ~8.0) Thermocycler Agarose gel system 6. Folding Protocol Reaction Mixture Typical concentrations: Scaffold: 5–10 nM Staples: 10× excess (50–100 nM each) MgCl₂: 10–20 mM Thermal Annealing Use a thermocycler: Heat to 95°C (5 min) Gradual cooling: 95 → 65°C (1°C/min) 65 → 25°C (0.1–0.5°C/min) This slow cooling ensures correct folding. 7. Purification Remove excess staples: Agarose gel electrophoresis (2% agarose, Mg²⁺ buffer) Extract band corresponding to folded box Alternative: Spin filtration (100 kDa cutoff) 8. Characterization Techniques: AFM (Atomic Force Microscopy)→ Surface visualization TEM (Transmission Electron Microscopy)→ 3D morphology DLS (Dynamic Light Scattering)→ Size distribution 9. Optional: Making a “Lid” (Dynamic DNA Box) Advanced designs (like DNA nanorobots): Add hinge strands Use “lock” strands (aptamer-based) Open box via: Complementary DNA key Protein binding trigger 10. Functionalization You can modify the DNA box for: Drug delivery Load small molecules inside Biosensing Attach fluorophores or quenchers Metal binding (relevant to your interest) Functionalize with: Thiol-modified DNA (binds gold) Aptamers for metal ions 11. Common Problems & Solutions Problem Cause Solution Misfolding Incorrect Mg²⁺ Optimize 10–20 mM Aggregation Too high DNA Reduce concentration Low yield Fast cooling Slow annealing Structural collapse Poor crossover design Redesign in caDNAno 12. Advanced Improvements Use hierarchical assembly (tiles → box) Introduce enzymatic ligation for rigidity Combine with proteins or nanoparticles 13. Research-Level Applications Given your expertise, you could extend this to: Metal extraction systems (DNA cages for gold binding) Enzyme immobilization inside DNA boxes Biofuel enzyme nanoreactors (xylanase encapsulation)
Zahid Hussain (Sat,) studied this question.