We have obtained C. elegans DNA transformants at a high frequency by microinjection. Our procedure is a simplified version of the microinjection techniques devised by J. Kimble, D. Stinchcomb, J. Shaw, and A. Fire. Based on the number of injections required to obtain an extrachromosomal transformed line, we estimate the the modified method is 10 to 100 times more efficient than previously described techniques. We began injecting a 7 kb plasmid, pRF4, containing the dominant right roller gene,
rol-6(
su1006) to determine its utility as a dominant marker for transformation. We injected 8 to 15 oocytes in each of approximately sixty worms and obtained 18 F1 Roller progeny, two of which proved to be germline transformants. In contrast, by injecting each syncytial distal gonad arm of 19 hermaphrodites (two injections per worm), we obtained 263 F1 Rollers, 10 to 20% of which proved to be germline transformants. Aside form the obvious advantage of doing fewer injections to obtain a transformed line, there are several other advantages of syncytial injection over oocyte injections. 1.) The target is much bigger so even a novice can obtain plenty of transformed worms. 2.) The worms suffer less: which a.)improves lab karma, b.) increases worm viability, and c.) allows one to use larger needle tips (e.g., to inject viscous DNA samples). 3.) Worms do not dry out and do not need any special recovery. Injected worms may simply be removed from the pad with sterile M9 and placed-directly onto a seeded plate. To perform syncytial injections, we focus on the grainy textured area in the center of the distal gonad arm. The tip of the needle is brought into the same focal plane and the stage is moved, pushing the worm into the needle tip. Once the needle is centered within the syncytium, pressure is applied to the needle. During injection, a wave front moves slowly in both directions from the site of injection, literally filling the gonad with DNA solution. It is easier to fill the gonad if each arm is injected only once. Additional holes seem to allow the DNA to leak out. We routinely inject DNA at 10 to 200 g/ml in the injection buffer described by A. Fire. Transformation frequency appears to plateau above 20 /ml. These injections require a needle that flows copiously. We have found that good needles can be reproducibly obtained by treatment with hydrofluoric acid (HF). A needle is loaded into its carrier and pressurized to 50 lbs./sq inch. The tip of the needle is inserted into a small drop of HF on a plastic petri dish. After approximately one second, when the needle starts to bubble, it is transferred to a drop of water to rinse the tip. The procedure is repeated to obtain larger tip openings. We have found that the optimal tip size will permit bubbling in the drop of water when pressurized as described above. Cotransformation frequency is high with this technique. Seventeen independent lines were obtained by coinjecting the
rol-6 plasmid with other plasmids or cosmids. Hybridization analysis of DNA prepared from the transformed lines showed that all (100%) contained both coinjected sequences. We have used coinjection to rescue
unc-31(
e928) with the phage containing the
unc-31 gene provided by R. Hoskins and
emb-9(
cg34) with a phage containing a basement membrane collagen gene. Coinjecting certain sequences appears to reduce transformation frequency. Worms injected with an equal molar ratio of
sup-7am and
rol-6 plasmid DNA produced fewer rolling F1 worms and never germline transformants. Similar results were obtained with a cosmid in the lin- 4 walk, B0243. We found that by reducing the ratio of the 'poison' sequence to
rol-6 plasmid, we were able to obtain cotransformed lines. The high efficiency of this transformation procedure has led us to consider less abundant sources of worm DNA for transformation experiments . In another abstract in this issue (D . Levitan, et al . ), we describe the rescue of
par-2(
it5ts) by microinjecting DNA isolated from a yeast strain bearing a worm artificial chromosome (YAC) .