Bruchins: insect-derived plant regulators that stimulate neoplasm formation.

Pea weevil (Bruchus pisorum L.) oviposition on pods of specific genetic lines of pea (Pisum sativum L.) stimulates cell division at the sites of egg attachment. As a result, tumor-like growths of undifferentiated cells (neoplasms) develop beneath the egg. These neoplasms impede larval entry into the pod. This unique form of induced resistance is conditioned by the Np allele and mediated by a recently discovered class of natural products that we have identified from both cowpea weevil (Callosobruchus maculatus F.) and pea weevil. These compounds, which we refer to as "bruchins," are long-chain alpha,omega-diols, esterified at one or both oxygens with 3-hydroxypropanoic acid. Bruchins are potent plant regulators, with application of as little as 1 fmol (0.5 pg) causing neoplastic growth on pods of all of the pea lines tested. The bruchins are, to our knowledge, the first natural products discovered with the ability to induce neoplasm formation when applied to intact plants.

Response ofNp mutant of pea (Pisum sativum L.) to pea weevil (Bruchus pisorum L.) oviposition and extracts.

TheNp mutant of pea (Pisum sativum L.) is characterized by two physiological responses: growth of callus under pea weevil (Bruchus pisorum L., Coleoptera: Bruchidae) oviposition on pods, and formation of neoplastic callus on pods of indoor-grown plants. Although these two responses are conditioned byNp, they are anatomically and physiologically distinguishable, based on sites of origin, distribution pattern, and sensitivity to plant hormones. Further characterization of the response to extracts of pea weevil showed that response of excised pods, measured by callus formation, was log-linear, and treatment with as little as 10(-4) weevil equivalents produced a detectable response. Mated and unmated females contained similar amounts of callus-inducing compound(s), and immature females contained significantly less of the compound(s). Female vetch bruchids (Bruchus brachialis F., Coleoptera: Bruchidae), a related species, contained callus-inducing compound(s), but usually less than pea weevils on a per weevil basis. Males of both species contained less than 10% of the activity of the mature females. Extracts of female black vine weevils, a nonbruchid species, did not stimulate callus formation. Based on partitioning and TLC analysis, the biologically active constitutent(s) was stable and nonpolar. Thus, theNp allele probably conditions sensitivity to a nonpolar component of pea weevil oviposition as a mechanism of resistance to the weevil.

RNA-mediated virus resistance in transgenic plants: exploitation of a cellular pathway possibly involved in RNA degradation.

Transgenic Nicotiana tabacum cv. Burley 49 plants were generated that express the 5' untranslated region of the tobacco etch potyvirus (TEV) genome ligated to a mutated version of the TEV coat protein gene sequence that rendered it untranslatable. Eight different transgenic plant lines were analyzed for transgene expression and for resistance to TEV. Three different responses were noted when the transgenic plant lines were inoculated with TEV: 1) some were highly resistant, and no virus replication occurred; 2) some were susceptible but able to recover from systemic TEV infection; and 3) some were susceptible to TEV infection. Plant tissue displaying the recovery phenotype was analyzed for virus replication and transgene expression. Recovered tissue could not be infected with TEV and had steady-state transgene RNA levels which were five- to eightfold lower than those of unchallenged transgenic plant tissue. Nuclear runoff assays suggested a post-transcriptional reduction in specific RNA levels. The highly resistant and recovery phenotypes associated with TEV challenge inoculation and the reduction of steady-state RNA levels in recovered transgenic leaf tissue may be manifestations of a common mechanism.

Induction of a Highly Specific Antiviral State in Transgenic Plants: Implications for Regulation of Gene Expression and Virus Resistance.

Transgenic tobacco plants expressing either a full-length form of the tobacco etch virus (TEV) coat protein or a form truncated at the N terminus of the TEV coat protein were initially susceptible to TEV infection, and typical systemic symptoms developed. However, 3 to 5 weeks after a TEV infection was established, transgenic plants "recovered" from the TEV infection, and new stem and leaf tissue emerged symptom and virus free. A TEV-resistant state was induced in the recovered tissue. The resistance was virus specific. Recovered plant tissue could not be infected with TEV, but was susceptible to the closely related virus, potato virus Y. The resistance phenotype was functional at the single-cell level because protoplasts from recovered transgenic tissue did not support TEV replication. Surprisingly, steady state transgene mRNA levels in recovered tissue were 12-to 22-fold less than transgene mRNA levels in uninoculated transgenic tissue of the same developmental stage. However, nuclear run-off studies suggested that transgene transcription rates in recovered and uninoculated plants were similar. We propose that the resistant state and reduced steady state levels of transgene transcript accumulation are mediated at the cellular level by a cytoplasmic activity that targets specific RNA sequences for inactivation.