Synthesis, Functionalization, and Characterization of Fusogenic Porous Silicon Nanoparticles for Oligonucleotide Delivery

Summary

We demonstrate the synthesis of fusogenic porous silicon nanoparticles for effective in vitro and in vivo oligonucleotide delivery. Porous silicon nanoparticles are loaded with siRNA to form the core, which is coated by fusogenic lipids through extrusion to form the shell. Targeting moiety functionalization and particle characterization are included.

Abstract

With the advent of gene therapy, the development of an effective in vivo nucleotide-payload delivery system has become of parallel import. Fusogenic porous silicon nanoparticles (F-pSiNPs) have recently demonstrated high in vivo gene silencing efficacy due to its high oligonucleotide loading capacity and unique cellular uptake pathway that avoids endocytosis. The synthesis of F-pSiNPs is a multi-step process that includes: (1) loading and sealing of oligonucleotide payloads in the silicon pores; (2) simultaneous coating and sizing of fusogenic lipids around the porous silicon cores; and (3) conjugation of targeting peptides and washing to remove excess oligonucleotide, silicon debris, and peptide. The particle’s size uniformity is characterized by dynamic light scattering, and its core-shell structure may be verified by transmission electron microscopy. The fusogenic uptake is validated by loading a lipophilic dye, 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI), into the fusogenic lipid bilayer and treating it to cells in vitro to observe for plasma membrane staining versus endocytic localizations. The targeting and in vivo gene silencing efficacies were previously quantified in a mouse model of Staphylococcus aureus pneumonia, in which the targeting peptide is expected to help the F-pSiNPs to home to the site of infection. Beyond its application in S. aureus infection, the F-pSiNP system may be used to deliver any oligonucleotide for gene therapy of a wide range of diseases, including viral infections, cancer, and autoimmune diseases.

Introduction

Gene therapy modulates specific gene expression to obtain a therapeutic outcome. Numerous tools for gene modulation have been discovered and studied, including ribonucleic acid interference (RNAi) using oligonucleotides (e.g., short interfering RNA (siRNA)^1,2, microRNA (miRNA)^3,4), DNA plasmids^5,6, nucleases (e.g., zinc finger, TALENS)^7,8, and CRISPR/Cas9 systems^9,10. While each tool’s mechanism of action differs, all of the tools must reach the cell’s cytoplasm or the nucleus to be active. As such, while these tools have proven to induce significant effect in modulating gene expression in vitro, the in vivo efficacy suffers from extracellular and intracellular obstacles. Due to the fact that the tools are of biological origin, many enzymes and clearance systems exist in our body that have the ability to degrade or remove the foreign molecules¹¹. Even in the case that the tools reach the target cell, they suffer from endocytosis; a mode of cellular uptake that encapsulates and traps the tools in acidic stomach-like vesicles that degrade or expel the tools out of the cell. In fact, studies have shown that lipid nanoparticles are endocytosed via macropinocytosis, from which approximately 70% of the siRNA are exocytosed from the cells within 24h of uptake^12,13. The majority of the remaining siRNA are degraded through the lysosomal pathway, and ultimately only 1-2% of the siRNA that initially enters the cell with the nanoparticles achieve endosomal escape to potentially undergo RNAi^13,14.

We have recently developed fusogenic porous silicon nanoparticles (F-pSiNPs) that have an siRNA-loaded core composed of porous silicon nanoparticles, and a fusogenic lipid shell¹⁵. The F-pSiNPs present three major advantages over other conventional oligonucleotide delivery systems: (1) a fusogenic lipid coating which enables the particles to bypass endocytosis and deliver the entire payload directly in the cell cytoplasm (versus the 1-2% achieved by endocytosed particles^13,14) (Figure 1); (2) high mass loading of siRNA in the pSiNPs (>20 wt% compared to 1-15 wt% by conventional systems)¹⁵, which rapidly degrade in the cytoplasm (once the core particles shed the lipid coating via fusogenic uptake) to release the siRNA; and (3) targeting peptide conjugation for selective homing to desired cell types in vivo.  

The F-pSiNP system has demonstrated significant gene silencing efficacy (>95% in vitro; >80% in vivo) and subsequent therapeutic effect in a fatal mouse model of S. aureus pneumonia; the results of which were published previously¹⁵. However, the complex structure of the F-pSiNP system requires delicate handling and fine-tuned optimization to generate uniform and stable nanoparticles. Thus, the purpose of this work is to present a thorough protocol, as well as optimization strategies for the synthesis, functionalization, and characterization of F-pSiNPs to be used in targeted delivery of siRNAs for potent gene silencing effect.

Protocol

1. Synthesis of porous silicon nanoparticles (pSINPs)

CAUTION: Always use caution when working with hydrofluoric acid (HF). Follow all safety guides according to its safety data sheet (SDS), handle any HF-containing chemicals in a fume hood, and wear appropriate personal protective equipment (PPE; double gloves with butyl gloves on the outside, butyl apron with lab coat underneath, face shield with safety goggles underneath). All universities and R&D labs require specific training on HF safety prior to usage. Do not attempt to work with HF without pre-approval of your local lab safety coordinator, as additional safety measures not described here are required.

1. Preparation of the etching solutions
   1. To make the 3:1 HF solution for etching (used in Steps 1.3 and 1.4), fill a plastic graduated cylinder with 30 mL of aqueous 48% HF and 10 mL of absolute ethanol (EtOH). The solution must be contained in high density plastics (e.g., HDPE), as the HF dissolves glass.
   2. To make a 1:29 HF solution for lift-off (used in Step 1.5), fill a plastic graduated cylinder with 1 mL of aqueous 48% HF and 29 mL of absolute ethanol. The solution must be contained in high density plastics (e.g., HDPE), as the HF dissolves glass.
   3. Make the 1 M KOH solution in 10% EtOH for excess pSi dissolution (used in Steps 1.3 and 1.5).
2. Setting up the etch cell
   1. In a Teflon etch cell with a 8.6 cm² etch well (area is calculated by measuring the diameter of the silicon surface available for etching within the O-ring, and calculating the area by A = πr²), place in descending order (Figure 2a): (1) the Teflon cell top; (2) an O-ring; (3) a quarter piece of the single crystal (1 0 0)-oriented p++-type silicon wafer cut into quarters (using a diamond cutter); (4) aluminum foil; and (5) the Teflon cell base with screws gently tightened to prevent leakage.
   2. Fill the well with EtOH. Take a wipe and insert into the crevice between the Teflon cell top and base. If the wipe is dry upon removal, the etch cell is sealed. If wet, the cell is leaking, and tighten the screws further until sealed.
3. Electropolishing the silicon wafer
   1. Bring the assembled etch cell into a fume hood.
   2. Fill the well with 10 mL of 3:1 HF solution.
   3. Connect the positive lead to the aluminum foil (electrode) from the etch cell and connect the negative lead to the platinum coil (counter-electrode) immersed in the 3:1 HF solution of the etch cell to complete the circuit (Figure 2b).
   4. Run a constant current at 50 mA cm^-2 for 60 s. Once etch is finished, remove the cell from the circuit, and rinse out the 3:1 HF carefully using a syringe. Rinse with EtOH three times.
   5. Dissolve away the etched layer by filling the well slowly with 10 mL of 1 M KOH. Wait until the bubbling subsides.
   6. Rinse out the KOH with water three times, and then with EtOH three times.
4. Electrochemically etching porous layers into silicon wafer
   1. Run an alternating current of a square waveform, with lower current density of 50 mA/cm² for 0.6 s and high current density of 400 mA/cm² for 0.36 s repeated for 500 cycles.
   2. Once etch is finished, remove the cell from the circuit, and rinse out the 3:1 HF carefully using a syringe. Rinse with EtOH three times.
5. Lifting-off the porous layer from the silicon wafer
   1. Fill the well with 10 mL of 1:29 HF solution.
   2. Run a constant of 3.7 mA/cm² for 250 s. Once etch is finished, remove the cell from the circuit. The pSi layer may have visible ripples indicating detachment from the crystalline silicon wafer. Gently wash out the 1:29 HF solution and rinse with EtOH three times, then with water three times.
   3. Using a pipette tip, firmly crack the circumference of the pSi layer for complete detachment. Using EtOH, collect the pSi fragments (chips) from the Teflon etch cell into a weighing boat. Transfer the chips to a glass vial. The pSi chips may be kept at room temperature in EtOH for over 6 months for storage.
   4. Dissolve away any remaining porous silicon on the wafer by filling the well slowly with 10 mL of 1 M KOH. Wait until the bubbling subsides.
   5. Rinse out the KOH with water three times, and then with EtOH three times.
   6. Repeat Steps 1.3-1.5 until the entire wafer thickness has been etched.
6. Sonicating porous layers for nanoparticle formation
   1. Replace the solvent of the glass vial containing pSi chips from EtOH to 2 mL of DI water.
   2. Firmly close the cap, and seal using parafilm.
   3. Place the glass vial in a sonicator bath and suspended such that the volume of pSi chips is completely submerged below the surface.
   4. Sonicate for 12 h at 35 kHz and RF power of 48W. To prevent significant water loss during sonication, place a volumetric flask filled with water, inverted so that the opening of the flask touches the surface of the water bath.
   5. Place the glass vial on a flat surface for 1 h to allow larger particles to settle at the bottom. Collect the supernatant using a pipette; the suspension contains sub-100 nm pSiNPs.

2. Preparation of fusogenic lipid film

1. Preparation of the lipid stock solutions
   1. In a fume hood, make 10 mg/mL stocks of lipids by hydrating DMPC, DSPE-PEG-MAL and DOTAP lipids in chloroform. These stock solutions may be kept at -20 °C for up to 6 months under tight parafilm seal.
2. Making the fusogenic lipid film
   NOTE: The fusogenic composition is made of the lipids, DMPC, DSPE-PEG, and DOTAP, at the molar ratio of 76.2:3.8:20 and 96.2:3.8:0, respectively.
   1. In a glass vial, mix 72.55 μL of DMPC, 15.16 μL of DSPE-PEG, and 19.63 μL of DOTAP by pipetting.
   2. Optional: For fluorescent labelling of the lipid coating, additionally add 20 µL of DiI dissolved in EtOH at a concentration of 1 mg/mL.
   3. Place the vial in a fume hood with a loose cap to allow the chloroform to evaporate overnight. The dried film will be a cloudy hard gel-like substance at the bottom of the vial.

3. Loading and sealing of siRNA in pSiNPs

1. Preparation of the calcium chloride loading stock
   1. Dissolve 1.11 g of CaCl^­₂ in 10 mL of RNAse-free water to make a 2 M CaCl₂ solution.
   2. Centrifuge the solution at > 10,000 x g for 1 min to settle the aggregates and collect the supernatant using a pipette. Alternatively, filter the solution through a 0.22 µm filter.
2. Preparation of the siRNA loading stock
   1. Hydrate or dilute the siRNA to 150 µM in RNAse-free water. This stock solution may be aliquoted and kept frozen at -20 °C for at least 30 days given that it does not undergo frequent freeze-thaw cycles.
3. Loading the siRNA in pSiNPs with calcium chloride
   1. Prepare an iced sonication bath.
   2. Under 15 min ultrasonication, gently pipette 150 µL of siRNA and 700 µL of 2 M CaCl₂ into 150 µL of pSiNP. Make sure to leave the lid of the microcentrifuge tube open for gas generation.
   3. Remove the tube containing 1 mL of siRNA-loaded calcium coated pSiNPs from the sonicator.

4. Coating siRNA-loaded pSiNPs with fusogenic lipids

1. Preparation of the liposome extrusion kit
   1. Fill a wide beaker with DI water. Soak 1 polycarbonate membrane (200 nm pores), and 4 filter supports by floating them on water surface. Assemble the liposome extrusion kit by following manufacturer’s instructions
2. Hydrating the lipid film with siRNA-loaded pSiNps
   1. Hydrate the dried lipid film in the glass vial with 1 mL of of siRNA-loaded calcium coated pSiNPs obtained from step 3.3.3. Pipette until all lipids film have lifted from the bottom of the vial and have mixed into a cloudy homogenous solution.
   2. Place a magnetic stirring bar in the glass vial, and place the vial onto a hot plate to heat the particles to 40 °C (or high enough above the lipids’ phase transformation temperature to maintain the lipids in the more fluidic liquid crystal phase) while magnetically stirring the solution for 20 min.
3. Extruding the lipid-coated pSiNPs for size control
   1. Aspirate the 1 mL of lipid-coated pSiNP-siRNA solution in the extrusion syringe. Insert an empty syringe on one side of the extruder, and the filled syringe on the other end.
   2. Begin extrusion by pushing the piston in slowly to push the particles from one syringe, through the polycarbonate membrane, and into the other. Repeat 20 times. If the piston is stuck, the filter and membrane may be clogged. Disassemble the extruder and replace the membrane and filter supports. If the problem persists, dilute the particles until clogging is manageable.
   3. Collect the extruded particles into a microcentrifuge tube.

5. Conjugation of targeting peptides

1. Conjugating targeting peptide to lipid coating
   1. Prepare the peptide stock with a 1 mg/mL peptide concentration in RNAse-free water.
   2. In the microcentrifuge tube containing fusogenic lipid-coated pSiNPs, add 100 µL of the 1 mg/mL peptide stock and pipet gently. Keep the tube static at room temperature for 20 min (alternatively, > 2 h at 4 °C).
   3. To remove excess peptide or siRNA and other excipients, wash in a 30 kDa centrifugal filter by spinning at 5,000 x g at 25 °C for 1 h. Centrifuge twice more with 1 mL of PBS under the same setting.
   4. Resuspend the final peptide-conjugated fusogenic lipid-coated pSiNPs in PBS at the desired concentration. The particles can now be aliquoted and frozen at -80 °C for storage of at least 30 days.

Results

A successful synthesis of fusogenic pSiNPs should produce a homogenous, slightly opaque solution (Figure 3a). Failure to optimize the ratio and concentration of pSiNPs : siRNA : CaCl₂ may lead to aggregation upon loading (Figure 3b). As the particles are extruded through 200 nm membranes, the average hydrodynamic diameter of the fusogenic pSiNPs measured by DLS should be approximately 200 nm, and the average zeta-poten...

Discussion

Synthesis of porous silicon nanoparticles is shown in Figure 5. The critical step in the synthesis of fusogenic pSiNPs is in the loading step (step 3). If the fusogenic nanoparticles are aggregating post-synthesis (Figure 3), the reason may be due to the following: (1) calcium chloride stock was not homogenously prepared, thus step 3.1.2 must be carefully followed or refined; or (2) the ratio of pSiNP : siRNA : CaCl₂ or the concentration of one or mor...

Materials

Name	Company	Catalog Number	Comments
1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC)	Avanti Polar Lipids	850345P	Powder
1,2-dioleoyl-3-trimethylammonium-propane (chloride salt) (DOTAP)	Avanti Polar Lipids	890890P	Powder
1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-[maleimide(polyethylene glycol)-2000] (ammonium salt) (DSPE-PEG(2000) Maleimide)	Avanti Polar Lipids	880126P	Powder
Aluminum foil	VWR International, LLC	12175-001
Calcium chloride (CaCl2)	Spectrum	C1977	Anhydrous, Pellets
Chloroform	Fisher Scientific	C6061
Computer	Dell	Dimension 9200	Any computer with PCI card slot is acceptable
Dil Stain (1,1'-Dioctadecyl-3,3,3',3'-Tetramethylindocarbocyanine Perchlorate ('DiI'; DiIC18(3)))	Life Technologies	D3911
Ethanol (EtOH)	UCSD Store	111	200 Proof
Hydrofluric acid (HF)	VWR International, LLC	MK264008	Purity: 48%
Keithley 2651a Sourcemeter	Keithley	2651A
LabVIEW	National Instruments		Sample program available at: http://sailorgroup.ucsd.edu/sofware/
LysoTracker Green DND-26	Thermo Fisher Scientific	L7526
Liposome extrusion set with heating block	Avanti Polar Lipids	610000
Microcon-30kDa Centrifugal Filter Unit	EMD Millipore	MRCF0R030
O-ring	ChemGlass	CG-305-220
Phosphate-buffered saline (PBS)	Thermo Fisher Scientific	10010-049
Platinum coil	VWR International, LLC	AA10285-BU
Potassium hydroxide (KOH)	Fisher Scientific	P250-3
Silicon wafer	Siltronix	Custom order
siRNA	Dharmacon	Custom order	IRF5, sense 5’-dTdT-CUG CAG AGA AUA ACC CUG A-dTdT-3’ and antisense 5’-dTdT UCA GGG UUA UUC UCU GCA G dTdT-3’
Sonicator	VWR International, LLC	97043-960
Targeting peptide (CRV)	CPC Scientific	Custom order	sequence CRVLRSGSC; made cyclic by a disulfide bond between the side chains of the two cysteine residues
Teflon etch cell	Interface Performance Materials, Inc.	Custom order
UltraPure DNase/RNase-Free Distilled Water	Thermo Fisher Scientific	10977015