Late watergrass is a serious weed of California rice that has evolved resistance to molinate, thiobencarb, fenoxaprop-ethyl, and bispyribac-sodium. To obtain an insight into the origin and spread of resistant (R) late watergrass in California rice fields, we evaluated similarities in morphological traits and amplified fragment length polymorphism (AFLP) fingerprints among 15 R strains compared with susceptible (S) strains. All strains were derived by inbreeding from accessions collected in rice fields of the Sacramento Valley, CA. In the field, R plants were shorter than S plants; they also had narrower and shorter flag leaves and thinner culms. Spikelets also appeared smaller and more slender in R plants. There was greater morphological similarity among the 15 R strains than among the eight S strains. The mean coefficients of variation for morphological traits were much smaller among R strains, which in a cluster analysis (Ward's method) were grouped morphologically apart at early clustering stages from the more variable S strains. AFLP electropherograms also showed greater similarity between R strains. R strains were grouped separately from the S strains in a cluster analysis based on calculated Nei and Li coefficients used in an unweighted pair group method using arithmetic means. However, small genetic differences also existed because the R strains were grouped into six clusters, suggesting that R strains were not samples from an identical strain. It was concluded that R strains originated from a preexisting and preadapted mutant late watergrass population in the Sacramento Valley. This study establishes that resistance moved by spikelet dispersal, not independent mutation events, most likely defined the geographical distribution of R late watergrass in California. Prevention and control of this dispersal combined with elimination of seed-producing survivors after herbicide treatment should be relevant components of the integrated management of herbicide-resistant late watergrass in California rice.
Calystegia japonica Choisy and Calystegia hederacea Wall., common perennial weeds throughout cropped and uncropped land in Japan, are known to regenerate mostly by rhizomes. The rhizome dynamics of the two species were investigated, focusing on their overwintering characteristics. The dry weight of rhizomes continued to increase for 6-7 weeks after the decrease in weight of the aerial parts began, then it decreased in winter because of the partial death and consequent fragmentation of the rhizomes. Overwintering as naturally fragmented rhizomes is a unique characteristic of the two Calystegia spp. as it is not observed in other rhizomatous weeds that maintain systematic connections at least during the following regeneration in spring. In C. japonica, rhizome degradation was more pronounced and more systematic than in C. hederacea, where thicker fragments that included apices remained. Qualitative changes in C. japonica rhizomes, such as increases in dry matter accumulation and starch, and a temporary decrease in sprouting ability, seem to relate to this specialized survival mechanism. Calystegia hederacea did not show either specialization or preparation for overwintering in its rhizome. The adaptability of Calystegia weeds to annual crop fields can be attributed to their capacity to regenerate from naturally fragmented rhizomes.
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