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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This protocol describes the assembly of a pneumatic system for the delivery of pressurized air to a needle during the process of needle beveling. The protocol further describes the beveling process for creating sharp microinjection needles and how to gauge the relative opening size of the needle.

Abstract

Microinjection needles are a critical tool in the delivery of genome modification reagents, CRISPR components (guide RNAs, Cas9 protein, and donor template), and transposon system components (plasmids and transposase mRNA) into developing insect embryos. Sharp microinjection needles are particularly important during the delivery of these modifying agents since they help minimize damage to the embryo being injected, thereby increasing the survival of these embryos as compared to injection with non-beveled needles. Further, the beveling of needles produces needles that are more consistent from needle to needle as compared to needles opened by randomly breaking the needle tip by brushing the tip against an object (side of a coverslip, the surface of the embryo to be injected, etc.). The process of wet beveling of microinjection needles with constant pressure air delivered to the needle allows the person beveling the needle to know when the needle is open (presence of bubbles) and also gives a relative indication of how large a needle opening has been created. The relative opening size in the needle can be determined by adjusting the air pressure delivered to the needle until an equilibrium is reached and bubbles stop flowing from the tip of the needle. The lower the pressure at which the equilibrium is reached, the larger the needle size; and conversely, the higher the pressure, the smaller the needle size.

Introduction

Insect genetic modification is a process originally developed in Drosophila by Rubin and Spradling, and over the years, this process has been modified to create genetic modifications in other species1. The process relies on the precise delivery of modification components microinjected into embryos at a specific window of time and location within the developing embryo2,3,4. Sharp microinjection needles are a critical tool in the process of genetic modification of some insects, such as mosquitoes4,5,6,7,8,9 and sand flies10 while not as critical for other insects, such as silkworms11. Sharp needles are often a key factor between success and failure when trying to create a genetically modified insect2,4. Typically, microcapillary glass needles are pulled by heating glass to the point where the glass becomes elastic, allowing the capillary to be pulled into a tapering closed tip needle. Before the needle can be used, it needs to be opened in a manner that creates a sharp tip for injection. Traditionally, needles are opened by brushing the needle tip gently against something (the edge of a slide/coverslip, or the embryo, etc.) that causes a small amount of glass to break off from the tip, randomly creating a sharp tip2,3. A slightly less random process is dry beveling, where the needle is quickly lowered onto an optically flat, spinning abrasive plate for a short period of time, causing a small amount of glass to be abraded from the needle tip, creating a sharp tip. Dry beveling is a little less random than brushing the needle tip against something. The protocol described below takes the beveling process a step further by supplying compressed air to the needle being beveled and beveling it under a liquid layer so that bubbles are visible as soon as the needle has been opened. This protocol details a method for producing reliably sharp microinjection needles. Beveling under a liquid layer is an improvement over randomly breaking the needle as described above, and dry beveling because the user receives feedback on the beveling process, allowing the person beveling to know when the needle is open and relatively how large the needle opening is. Knowing the relative opening size of the needle tip can allow the person beveling to create needles with different opening sizes. Various needle opening sizes have different advantages; for instance, larger needle opening sizes can accommodate injection mixes of high viscosity, while smaller opening needles cause less damage to the embryo being injected.

Air is supplied to the needle using a regulator and a system of urethane tubing based on a modified air-pressure regulated injection system2. While air is supplied to the needle at a constant pressure, the needle is beveled under a layer of liquid. The beveling process is comprised of a repeated five-step process: 1) lowering the needle to the abrasive surface, 2) allowing the needle to bevel for a short period of time, 3) raising the needle away from the abrasive plate while keeping it beneath the surface of the liquid layer, 4) stopping the spin of the abrasive plate to check for the appearance of bubbles. If no bubbles are present, then steps 1 through 4 are repeated until bubbles appear; 5) Once bubbles are present, the air pressure can be adjusted to determine the relative opening size of the needle. The lower the pressure needed to stop bubble formation, the larger the opening at the needle tip.

Protocol

NOTE: The protocol as described below uses the Sutter BV-10 microcapillary beveled. However, this protocol can be modified for use with any model microcapillary beveled.

1. Assembly of regulator, pressure gauge, and air supply tubing

  1. Cut a section of urethane tubing for the connection from the air supply to the base of the regulator (R; Section 1, Figure 1). The length of this section will depend on the distance from the air supply to the regulator, which will be located next to the beveler.
  2. Slide a hose clamp onto the urethane tubing, then push a hose connector into the end of the tubing. Make sure the hose connector is fully inserted by placing the hose connector against a hard surface. While holding the tubing close to the hose connector, press the tubing firmly into the hose until the hose connector is fully inserted. Together, the hose clamp and hose connector form the connection HC (Figure 1).
  3. Slide the hose clamp up to the end of the tubing where the hose connector is inserted. Rotate the hose clamp over the inserted barb end so that it forms an airtight connection.
  4. Screw the hose connector into the base of the regulator (R) by hand, then finish tightening the connection with a small wrench. Make sure the connection is airtight but not overtight.
  5. In the side port of the regulator, screw in a T connector (T) by hand, then use a small wrench to finish tightening.
  6. Cut a small piece of urethane tubing (Figure 1, Section 2), approximately 3-5 cm in length. Place two hose clamps onto the piece of tubing, then insert a hose connector into each end of the tubing and finish the connections (HC) as described in steps 1.2-1.4 for each end of the tube.
  7. Screw one end of the short tube into the base of the pressure gauge, then finish tightening with a wrench as in step 1.5.
  8. Screw the other end of the short tube into one of the ports on the T connector (T) connected to the regulator in step 1.5.
  9. Cut a section of urethane tubing (Figure 1, Section 3) for the connection between the regulator and needle holder (NH). The size of this section will depend on the distance from the beveler to the location of the regulator.
  10. Place a hose clamp onto the tubing section, then insert a hose connector as described in steps 1.2-1.4.
  11. On the other side of this section of tubing, place the female luer connector (LC) that is supplied with the needle holder (NH).
  12. Remove the retaining clamp and the nylon washer (Figure 2, f) from the manipulator. The retaining clamp and washer are designed to hold a glass microcapillary only, they are not designed to hold the additional weight of a microcapillary holder, threaded rod, and air supply tubing.
  13. Cut a rectangular piece of rubber packing sheet 1.5 cm x 2 cm to wrap the threaded rod in the bicycle fender clamp. This will help hold the threaded rod and needle holder more securely in the bicycle fender clamp. Using two needle nose pliers, open the bicycle fender clip, fold the rectangular piece of rubber packing sheet over the threaded rod 3.5 cm from one end of the rod so that it forms a U over the rod. Insert the rubber sheet-covered threaded rod into the opened bicycle fender clamp and use the pliers to close the clamp around the rod and rubber sheet. Install the bicycle clamp and threaded rod assembly onto the manipulator bolt, replace the retaining clamp without the nylon washer, and tighten the retaining clamp until it securely holds the threaded rod assembly.
  14. Thread the needle holder onto the threaded rod. Make sure that the luer connector ends in a position that will not bind the urethane tubing when it is connected (Figure 2, g).
  15. Connect the female luer connector to the male luer connector (Figure 2, g) of the needle holder (Figure 2, d).
  16. Connect the free end of Figure 1, Section 1 tube to the air supply (this connection will vary based on the air supply used). The air supply should be clean, dry air, and free of oil residue. The air supply can be from a house air source or gas cylinder, either compressed air or Nitrogen.

2. Beveling borosilicate needles

  1. Pull microinjection needles using borosilicate glass micro capillaries with the following settings on the instrument: Heat: 305, Fil: 4, Vel: 70, Del: 235, Pul: 160, with Loop time of 12.24.
  2. Assemble the grinding assembly according to the manufacturer's instructions, consisting of the abrasive plate and the retaining ring with magnets12.
    NOTE: The abrasive plate may need to be wrapped with a thin strip of transparent film to prevent premature leakage of Photo-Flo (wetting agent) from the abrasive plate. This is only needed if the wetting agent solution prematurely leaks down into the pedestal oil, causing the grinding plate to stop rotating. The wetting agent reduces the risk of drying marks on the glass needles after beveling. The use of a wetting agent is not critical to the beveling process, and water may be substituted.
  3. Place 10 drops of pedestal oil onto the pedestal's optically flat surface and place the grinding assembly on top. Start the grinding assembly.
  4. Turn on the light source to illuminate the surface. Ensure the light source is positioned behind the beveled and shines at an angle of 45Β° to the abrasive plate and needle. The illumination angle is necessary so that a shadow of the needle is easily seen. At 90x magnification, rotate the microscope head in place. Briefly stop the abrasive plate spinning and focus the microscope on the surface of the abrasive plate.
  5. Add 1% wetting agent to the wick until the wick is completely wet. Add 1% wetting agent to the surface of the abrasive plate. Ensure the wetting agent covers the abrasive surface but does not leak on to the black retaining ring.
  6. Place the pre-wet wick onto the surface of the abrasive plate as it is spinning. Ensure the wick is on the left side of the abrasive plate (as you look down from the top) and stretches from 11 o'clock to 6 o'clock (with the plate as a clock face). Ensure the wick does not ride on the black portion of the retaining ring.
  7. Insert a needle into the needle holder (Figure 2, d) and tighten the retaining ring to hold the needle in place. Open the regulator (Figure 1, R) and increase the pressure to 24 psi.
  8. Raise the needle holder by rotating the course adjustment knob (Figure 2, a) Make sure the needle is raised high enough that it is higher than the surface of the rotating abrasive plate, then rotate the entire manipulator so that the needle swings into place above the rotating abrasive plate. The needle to be beveled should be placed onto the rotating abrasive plate oriented such that the rotation of the plate moves away from the tip of the needle (Figure 3A)
  9. Watching from the side, use the coarse adjustment knob (Figure 2, a) to lower the needle toward the abrasive plate surface. Stop when the needle is almost touching the surface of the liquid.
  10. Use the zoom to lower the magnification of the microscope, then move the microscope so that the needle is in the center of the field of view. Once in the center of view, increase the magnification, adjusting the manipulator's position so that the needle tip stays in the center of view. Once at maximum magnification, stop the grinding plate and focus the microscope on the surface of the abrasive plate, then immediately restart the rotation of the plate once the surface is in focus. The needle may not be in view at this point.
  11. Using the manipulator coarse adjustment knob, lower the needle toward the abrasive plate. In the field of view, an image of the needle and a shadow(s) of the needle will be visible. When the needle and the shadow(s) of the needle are close to touching, switch to the manipulator fine adjustment knob and continue to lower the needle until the needle and its shadow(s) appear to touch. At this point, read the caliper (Figure 2, c) and note the reading. The surface of the abrasive plate is at or below this caliper reading.
    NOTE: It is difficult to see when the needle touches the surface of the rotating abrasive plate, so the needle may not actually be touching the abrasive plate at this point.
  12. Allow the needle to stay at this level of caliper reading for 5-10 s.
  13. Using the manipulator fine adjustment knob, raise the needle, making sure it stays underneath the surface of the wetting agent. Stop the rotation of the abrasive plate for a few seconds and observe whether bubbles escape from the needle tip. If bubbles are present, proceed to step 2.15. If bubbles are not present, proceed to step 2.14.
  14. Move the needle back to the caliper reading using the manipulator fine adjustment knob, then move it a little lower and take a new caliper reading, then repeat steps 2.12-2.13.
  15. Start the abrasive plate again to see if bubble formation is observable while the plate is rotating. If evidence of bubble formation is visible during plate rotation, the opening of the needle tip is likely too large for sensitive embryo microinjections, such as mosquito embryo injections. If bubble formation is not visible during abrasive plate rotation, then the needle opening is ideal for use in procedures requiring a sharp and small opening needle.
  16. Use the manipulator course adjustment knob to raise the needle above the abrasive plate to a position that is high enough above the plate that the needle will not hit anything as the entire manipulator is rotated to move the needle away from the abrasive plate and microscope.
  17. Once the needle is in a position where it can be removed without hitting anything, lower the air pressure to zero, remove the needle, and place it in a needle storage box (a Petri dish with either double stick tape or modeling clay to hold the beveled needles) until use.

3. Determining the relative opening size of the beveled needle

NOTE: Determining the beveled needle's relative opening sizes is done in step 2.13. The steps below describe this process further.

  1. Once bubbles are observed in step 2.13, with the abrasive plate not rotating, slowly decrease the air pressure by rotating the regulator adjustment knob (Figure 1, R) until bubbles stop flowing from the tip of the needle. Note the pressure at which bubbles stop flowing from the tip.
  2. Increase the air pressure until bubbles are flowing again from the needle tip. The higher the pressure, the smaller the opening of the needle.
  3. Proceed with moving the needle to a position where it can be safely removed steps 2.16-2.17.

Results

The procedure described above produces consistently sharp microinjection needles. Sharp needles are characterized by being able to insert into soft chorion insect embryos, such as mosquito embryos, with little to no resistance from the embryo membrane. When mosquito embryos are microinjected for genetic modification, the embryo membrane is relatively elastic. Pushing a dull needle against the embryo membrane will cause it to indent (Figure 4B). When the needle is pulled back, the membrane re...

Discussion

Genetic modification of mosquitoes relies on precise microinjection of the modification materials (plasmids, guide RNAs, or proteins) into pre-blastoderm embryos3,4,5,6,7,8. Crucial to this process are sharp needles that easily pierce the embryo during injection2,4. A...

Disclosures

The author has nothing to disclose.

Acknowledgements

The author would like to acknowledge the following people. The staff of the University of Maryland Insect Transformation Facility: Channa Aluvihare, Robert Alford, and Daniel Gay. Without their dedicated work, the Insect Transformation Facility would not exist. Vanessa Meldener-Harrell for proofreading this manuscript.

Materials

NameCompanyCatalog NumberComments
1.0 mm O.D. microcapillariesWorld Precision Instruments
Beveler pedestal oilSutter Instruments008
Bicycle fender clipVeloOrangeR-clip 4-packhttps://velo-orange.com/products/vo-r-clip-4-pack
Boom Stand MicroscopeAmScopeAMScope 3.5X-90X Trinocular LED Boom Stand Stereo Microscope or equivalent
BV-10 BevelerSutter InstrumentsBV-10
Diamond abrasive plateΒ Sutter Instruments104FDiamond abrasive plate - extra fine (0.2 Β΅ to 1.0 Β΅ tip sizes)
Gasket, Buna-NClippard Instrument Laboratory, Inc.11761-2-pkgUsed to seal connection on TΒ  or L connectors, if not already included with these pieces
Hose ClampClippard Instrument Laboratory, Inc.5000-2-pkg
Hose connectorClippard Instrument Laboratory, Inc.CT4-pkgNeed 5 hose connectors
Microinjection Needle HolderWorld Precision InstrumentsMPH3-10Needle holder for 1mm outer diameter microcapillaries
P-2000Sutter InstrumentsAny needle puller
Photo-Flo 200 SolutionB&H Photo, Video and AudioBH #KOPF200PΒ  MFR #1464510wetting agent
Pressure GaugeClippard Instrument Laboratory, Inc.PG-1000-100 psi gauge
Reference wickSutter InstrumentsX050300
Reference wick holderSutter InstrumentsM100019
RegulatorClippard Instrument Laboratory, Inc.01-MarNeed #10-32 ports for connections
Rubber Packing Sheet 6 inx 6 inDancoModel # 59849
T fittingClippard Instrument Laboratory, Inc.15002-2-pkg
Threaded BarEither a threaded rod or bar with threaded end. Threads must be 10-32.
Urethane tubingClippard Instrument Laboratory, Inc.URH1-0804-BLT-050

References

  1. Rubin, G. M., Spradling, A. C. Genetic transformation of Drosophila with transposable Element Vectors. Science. 218 (4570), 348-353 (1982).
  2. O'Brochta, D. A., Atkinson, P. W. Transformation systems in insects. Methods Mol Biol. 260, 227-254 (2004).
  3. Handler, A. M., James, A. A. . Insect Transgenesis: Methods and Applications. , (2000).
  4. Harrell, R. A. Mosquito embryo microinjection. Cold Spring Harbor Protocols. , (2023).
  5. Allen, M. L., O'Brochta, D. A., Atkinson, P. W., Levesque, C. S. Stable, germ-line transformation of Culex Quinquefasciatus (Diptera: Culicidae). J Med Entomol. 38 (5), 701-710 (2001).
  6. Grossman, G. L., et al. Germline transformation of the malaria vector, Anopheles gambiae, with the piggyBac transposable element. Insect Mol Biol. 10 (6), 597-604 (2001).
  7. Adelman, Z. N., Jasinskiene, N., James, A. A. Development and applications of transgenesis in the yellow fever mosquito, Aedes aegypti. Mol Biochem Parasitol. 121 (1), 1-10 (2002).
  8. Perera, O. P., Harrell, R. A., Handler, A. M. Germ-line transformation of the South American malaria vector, Anopheles albimanus, with a piggyBac/EGFP transposon vector is routine and highly efficient. Insect Mol Biol. 11 (4), 291-297 (2002).
  9. Harrell, R. A. Mosquito embryo microinjection under halocarbon oil or in aqueous solution. Cold Spring Harb Protoc. , (2023).
  10. Louradour, I., Ghosh, K., Inbar, E., Sacks, D. L. CRISPR/Cas9 mutagenesis in Phlebotomus papatasi: The immune deficiency pathway impacts vector competence for Leishmania major. mBio. 10 (4), e01941 (2019).
  11. Tamura, T., et al. Germline transformation of the silkworm Bombyx mori L. using a piggyBac transposon-derived vector. Nat Biotechnol. 18 (1), 81-84 (2000).
  12. . BV-10 Micropipette Beveler Operation Manual Rev. 3.00 Available from: https://www.manualslib.com/manual/2073788/Sutter-Instrument-Bv-10.html (2018)

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