Antisense oligodeoxynucleotide inhibition as a potent diagnostic tool for gene function in plant biology
Antisense oligodeoxynucleotide (ODN) inhibition emerges as an effective means for probing gene function in plant cells. Employing this method we have established the importance of the SUSIBA2 transcription factor for regulation of starch synthesis in barley endosperm, and arrived at a model for the role of the SUSIBAs in sugar signaling and source-sink commutation during cereal endosperm development. In this addendum we provide additional data demonstrating the suitability of the antisense ODN technology in studies on starch branching enzyme activities in barley leaves. We also comment on the mechanism for ODN uptake in plant cells. Antisense ODNs are short (12-25 nt-long) stretches of single-stranded ODNs that hybridize to the cognate mRNA in a sequence-specific manner, thereby inhibiting gene expression. They are naturally occurring in both prokaryotes and eukaryotes where they partake in gene regulation and defense against viral infection. The mechanisms for antisense ODN inhibition are not fully understood but it is generally considered that the ODN either sterically interferes with translation or promotes transcript degradation by RNase H activation. The earliest indication of the usefulness of antisense ODN technology for the purposes of molecular biology and medical therapy was the demonstration in 1978 that synthetic ODNs complementary to Raos sarcoma virus could inhibit virus replication in tissue cultures of chick embryo fibroblasts. Since then the antisense ODN technology has been widely used in animal sciences and as an important emerging therapeutic approach in clinical medicine. However, antisense ODN inhibition has been an under-exploited strategy for plant tissues, although the prospects for plant cells in suspension cultures to take up single-stranded ODNs was reported over a decade ago. In 2001, two reports from Malho and coworker demonstrated the use of cationic-complexed antisense ODNs to suppress expression of genes encoding pollen-signaling proteins in pollen tubes from the lilly Agapanthus umbellatus. For the uptake of DNA pollen tubes represent a unique system since the growing tip is surrounded by a loose matrix of hemicellulose and pectins, exposing the plasma membrane7 and the first uptake of ODNs by pollen tubes was reported as early as 1994. A breakthrough in the employment of antisense ODN inhibition as a powerful approach in plant biology was recently presented through our work on intact barley leaves. As was illustrated by confocal microscopy and fluorescently labeled ODNs, naked ODNs were taken up through the leaf petiole and efficiently imported into the plant cell and the nucleus. The work portrayed in that study demonstrate the applicability of antisense ODN inhibition in plant biology, e.g. as a rapid antecedent to time-consuming transgenic studies, and that it operates through RNase H degradation. We employed the antisense ODN strategy to demonstrate the importance of the SUSIBA2 transcription factor in regulation of starch synthesis, and to depict a possible mechanism for sugar signaling in plants and how it might confer endosperm-specific gene expression during seed development. We also described the employment of the antisense ODN strategy for studies on in vitro spike cultures of barley. Here we present further evidence as to the value of the antisense ODN approach in plant biology by following the effects on starch branching enzyme (SBE) accumulation in barley leaves after suppression of individual SBE genes. In agreement with transcript analyses of SBE expression in barley leaves, a zymogram assay (Fig. 1) revealed that sucrose treatment of barley leaves increased the number of SBE activity bands as compared to sorbitol treatment. In the presence of antisense SBEI or SBEIIA ODNs, zymograms of sucrose-treated leaves displayed only a subset of these activities with bands in the top portion of the zymogram gel missing or diminished. With antisense SBEIIB ODN, all activity bands in the top portion of the gel as well as the lowest band were absent. Based on these data we provide a tentative annotation for the various SBE activity bands. In animal experiments, naked ODNs are usually not taken up by the cells since both the ODNs and the outside of the plasma membrane carry a net negative charge. Thus the uptake of naked ODNs into barley leaf cells was surprising and called for an explanation. As demonstrated in our subsequent paper, the answer seems to be that the ODNs slip into the cells through sugar translocators as they are activated in the presence of the appropriate sugar (Fig. 2). Whether it is the structural resemblance between the sugar (deoxyribose) backbone of the ODNs and the transported sugars that allows for the ODNs to be transferred, or if other mechanisms are involved, remains to be elucidated.
- Research Organization:
- Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States)
- Sponsoring Organization:
- Earth Sciences Division
- DOE Contract Number:
- DE-AC02-05CH11231
- OSTI ID:
- 927889
- Report Number(s):
- LBNL-223E; TRN: US200816%%1117
- Journal Information:
- Plant Signaling and Behavior, Vol. 3, Issue 7; Related Information: Journal Publication Date: 2008
- Country of Publication:
- United States
- Language:
- English
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