Captan applied before an infection

Captan applied before an infection event consistently reduced crown rot to levels
equal to or below that observed for other fungicide treatments. In previous field
experiments, scheduled applications of captan did not appear to control strawberry
crown rot caused by C. fragariae (6,18). However, consistent with our results, in
unpublished trials (S. J. MacKenzie) captan applied at a 7-day interval throughout
the growing season reduced mortality caused by C. gloeosporioides from 32.1 to
2.1% when infected plants within the plot were the source of inoculum, and from
21.7 to 0.9% when the source of inoculum was from outside the plot.
Captan and thiram were the only fungicide treatments in this study that lacked
systemic activity. Both reduced disease relative to the control when applied after
inoculation as well as before, which suggested that these protectants could have
some effect on disease if applied within 24 h after an infection event. However, efficacy was greatly reduced if captan was applied after rather than before inoculation
in 2 of 3 years. Thiram was as effective if applied before inoculation or after in both
seasons tested, suggesting that its curative Plant Disease / August 2009 819
activity may be of longer duration than captan, although previous reports do not
indicate that thiram has any systemic activity (25). Fungicides with at least some systemic activity reduced crown rot as preventive or as curative treatments. Azoxystrobin was more effective if applied after inoculation. The data suggest that pyraclostrobin and thiophanate-methyl are more effective when applied after infection than before, but for each fungicide this trend was statistically significant for only one season. Although both azoxystrobin and pyraclostrobin target the same site, azoxystrobin is more mobile within plants relative to pyraclostrobin, which may explain the lower efficacy of azoxystrobin when applied preventively (3). Thiophanate-methyl was more effective if applied after inoculation for only one season, and there was no apparent trend the other two seasons. Although it has systemic activity compared to other benzimidazole fungicides, rela-tively high levels of thiophanate-methyl may persist on plant surfaces up to 48 h after application (19). Similar to the results for pyraclostrobin, the persistence of thiophanate-
methyl at the plant surface may explain the absence of a timing effect some
seasons. For diseases caused by a group of ascomycetes, the timing of cyprodinil applications did not appear to affect disease control if applications were made a few days before or after inoculations (14). The relatively wide window that cyprodinil can be applied and provide effective disease control could account for the lack of consistent differences between the 2-DBI and 1- DAI fungicide applications in the combined cyprodinil + fludioxonil treatment. However, given that fludioxonil is a contact fungicide, its inclusion in a mixture should have improved control for preinoculation treatments. This may explain the results observed in 2004–05, where the 2-DBI application was more effective than the 1-DAI application. Except where noted, fungicide effects were in good agreement with trials examining diseases caused by C. gloeosporioides on crops other than strawberry and in vitro studies. Azoxystrobin, pyraclostrobin, thiophanate-methyl, and fludioxonil all reduced the incidence of postharvest anthracnose of tangerine caused by C. gloeosporioides when applied 2 days before harvest (29). Treatment of lupine seed with thiram reduced transmission of anthracnose caused by C. gloeosporioides to plants (25). Abril et al. (1) found that cyprodinil was strongly inhibitory to the germination and growth of C. gloeosporioides in vitro. Zainuri et al. (28) showed that potassium phosphite does not directly interfere with C. gloeosporioides infection of mango fruit. Our results also indicate that potassium phosphite does not directly interfere with the ability of C. gloeosporioides to infect strawberry. Potassium phosphite potentially can reduce disease by activating a plant’s chemical defenses (13). Although we found no effect of potassium phosphite on crown rot, the preinoculation application was made only 2 days before inoculation, which may not have been sufficient time for an activated defense response. Captan is typically included in scheduled fungicide applications for control of a variety of strawberry diseases in Florida (15). In this state, fields with transplants from a source outside of the range of C. gloeosporioides typically have a low incidence of Colletotrichum crown rot, and scheduled captan sprays are normally sufficient to control the disease during the relatively cool growing season. In nurseries located in areas where C. gloeosporioides is present and weather conditions are often conducive to rapid spread of disease, captan or thiram should be included in a scheduled program to control crown rot caused by C. gloeosporioides since the risk for resistance development is low (10). When applied after infection, fungicides with some systemic activity generally were more effective. These fungicides act on a single site, may be more expensive, and are more restricted with respect to the number of applications allowed. However, they may be useful in a management program when applied after weather events that are favorable for disease development and detrimental to the activity of protectant fungicides which may have been applied.