In the Solanaceae, self-incompatibility is controlled by a single, multi-allelic ('S') locus. One product of this locus is a ribonuclease, the S-RNase, which is expressed predominantly in mature pistils and has recently been shown to cause allele-specific pollen rejection in transgenic plants. Hybrid Nicotiana plumbaginifolia x N. alata plants were used to test the effects of antisense suppression of the SA2-RNase from N. alata using three different gene constructs: two driven by RNA polymerase II-transcribed promoters, and the third, containing a truncated soybean tRNA (met-i) gene, transcribed by RNA polymerase III. All three constructs caused suppression of S-RNase activity in the transgenic plants. Unexpectedly, the CaMV 35S promoter was more effective for antisense suppression than the tissue specific tomato ChiP promoter. Antisense suppression of S-RNase correlated with low sense SA2 transcript levels and high antisense SA2 transcript levels. Untransformed hybrids that contained the N. alata SA2 allele were incompatible with N. alata SA2 pollen, while transgenic plants with suppressed SA2 gene expression accepted the pollen. The utility of this hybrid plant system for studying some aspects of antisense gene suppression is discussed.
Cauliflower mosaic virus (CaMV) strains D4 and W260 can be distinguished by the type of symptoms they induce in Nicotiana clevelandii and N. edwardsonii. W260 induces systemic cell death in addition to a mosaic symptom in N. clevelandii and a hypersensitive response (HR) in N. edwardsonii, whereas D4 induces a systemic mosaic in both hosts. To determine which W260 genes are responsible for systemic cell death, chimeric viruses were constructed between the D4 and W260 strains. It was found that W260 gene VI was responsible for the elicitation of systemic cell death; previous studies had shown that this same gene elicited HR in N. edwardsonii. An immunological analysis of plants infected with W260 or D4 indicated that the systemic cell death symptom was not associated with enhanced levels of either W260 virions or the W260 gene VI product. To investigate the inheritance of systemic cell death, crosses were made between N. clevelandii and N. bigelovii, a host that reacts with a systemic mosaic symptom upon infection with W260. All F1 plants developed a systemic mosaic after inoculation with W260, whereas the F2 generation segregated 3:1 for systemic mosaic versus cell death. The plant gene responsible for cell death was designated ccd1, for CaMV cell death gene. These results demonstrate that the systemic cell death symptom in N. clevelandii is induced by the interaction between a single host gene and gene VI of CaMV.
Nodal cuttings from micropropagated potato plantlets give rise to microtubers when placed on Murashige and Skoog medium containing 6% sucrose and 2.5 mg/liter kinetin and incubated in the dark at 19 degrees C. Microtubers produced from the cultivar Superior were shown to contain the same characteristic group of proteins as field-grown tubers. As with field-grown tubers, the 40,000-dalton major tuber glycoprotein, patatin, accumulated to high levels in microtubers, reaching 3.7 +/- 0.2 mg/g fresh weight after 90 d. Also in agreement with field-grown plants, stems and leaves of micropropagated plantlets did not contain detectable levels of patatin, but small amounts of an electrophoretically distinct form accumulated transiently in roots. Patatin mRNA is readily detectable in developing microtubers 15 d after transfer of the cuttings to inductive medium. Patatin mRNA was also present in roots, but as with field-grown plants, was 50- to 100-fold less abundant and could be distinguished from that in tubers by primer extension. Microtuber development and patatin accumulation were inhibited by gibberellic acid.
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