Bio-Rad PDS-1000 / He™ and Hepta™ Systems User Manual

Recommended starting particle size/type for bombardment of various cell types is
Bacteria

0.7 µm (M5) tungsten

Yeast

0.6 µm gold

Algae

0.6 µm gold

Plant cells/tissue

1.0 µm gold

Animal cell cultures

1.6 µm gold

Sub-cellular organelles

0.6 µm gold

Table 5.1 and bulletins 1688 and 2015 give a detailed discussion of optimization parameters.

5.10 Preparation of Biological Material for Bombardment

Plant Cells

Many factors contribute to optimum performance in any system for plant gene transfer.

Transformation procedures employing microcarrier bombardment are no exception, but the improved

PDS-1000/He apparatus lends itself to rapid and easy modification, to tailor its performance to a par-

ticular application. Microcarrier bombardment also allows exploitation of a very broad range of

explant tissue types. This permits optimization of a crucial aspect of the transformation system

which usually is difficult to alter when transforming by other means. The following is a discussion

of some of the critical parameters in the microcarrier transformation system, together with a brief

examination of explant characteristics which affect transformation efficiency. This is not intended

as a “how to” manual. Because of the extreme diversity of applications possible with the system, and

the various types of tissues which can be employed, it is not possible to produce a universal proto-

col for all applications. Rather, this discussion is intended to aid the new user to design experiments.

Note: If you are a first-time user, it is important to be certain that your PDS-1000/He

apparatus has been assembled correctly and is operating according to specifications. We

suggest that you use the Yeast Optimization Kit (catalog number 170-3100) to be sure that

microcarrier preparation has been carried out properly, and that microcarriers are being

delivered uniformly. This also provides an opportunity to examine firsthand the pattern

of particle delivery and gene expression in treated cells. This may save substantial time

as you begin to optimize the system for your own purposes.
Choice of Explant Tissue
Unlike most other procedures for DNA transfer, microcarrier bombardment places few

constraints on the types of tissues which can be treated. DNA can be delivered into essen-

tially any cell or tissue which can be exposed sufficiently to allow particle penetration. Thus

more emphasis usually can be given to issues such as the tissue’s ability to regenerate plants,

or its physiological suitability for gene regulation studies. There are, however, several aspects

of the explant which contribute to the efficiency of the system.

An ideal tissue for microcarrier bombardment could perhaps be described as a cell monolay-

er, all cells of which are capable of expressing introduced genes, and all of which could, indepen-

dently, divide and differentiate into functional plants. Microcarrier bombardment of such a tissue

will likely be efficient because cells can be spread over a large area, thus efficiently capturing a large

proportion of the particles delivered in each bombardment. Particles also have a high probability

of penetrating such cells because they are not covered by overlying cell layers which would very

likely intercept some of the particles delivered by each bombardment. Absolute transient expres-

sion levels are likely to be high, because of the number of cells affected. The low profile of cell clus-

ters reduces the probability that the tissue will be moved about by the gas released in the shockwave

during treatment. Such a tissue would also lend itself well to selection with antibiotics or herbicides,

in part, at least, because it would have a favorable geometry for the establishment of a uniform

concentration of the selective agent throughout the culture.

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