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1 September 2008 Comparative Bionomics of Frankliniella occidentalis and Frankliniella tritici
Stuart R. Reitz
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Two of the most abundant thrips in the southeastern USA are Frankliniella occidentalis (Pergande) and Frankliniella tritici (Fitch) (Thysanoptera: Thripidae). Frankliniella occidentalis is a key pest because of damage caused by its feeding and oviposition in many crops and because it is a vector of Tomato spotted wilt virus (Childers 1997; Ullman et al. 1997). Although F. tritici is not a vector of Tomato spotted wilt virus (Assis Filho et al. 2005), its abundance and morphological similarity to F. occidentalis makes it a management concern for growers and crop consultants (Reitz 2002). Despite superficial similarities in their habits and host plants, the seasonal population dynamics of these species differ dramatically (Eckel et al. 1996; Funderburk et al. 2000; Reitz et al. 2002), yet efforts to better understand their population dynamics are hindered by a lack of comparative biological data and because observing individual thrips in the field is almost impossible. Therefore, laboratory studies can provide critical information to better understand their population dynamics. The objectives of this study were to compare development and reproductive success of F. occidentalis and F. tritici.

To determine immature development time, individual adult females were allowed to oviposit for 8 h in 2.5-cm sections of green bean pods contained in 30-ml clear plastic cups. Then females were removed, and the bean sections were held in an environmental chamber (28.0 ± 1.0°C, 65.0 ± 10.0% r.h., 14:10 L: D photoperiod). Bean sections were observed every 12 h under a stereomicroscope to determine when larvae began to emerge. Then a single newly emerged larva from each female was transferred to fresh bean pod section. These individuals were checked every 12 h to determine when molting occurred. There are 2 active larval stages followed by 2 relatively quiescent non-feeding stages, the propupa and pupa (Moritz 1997). Because data were recorded on an interval scale and composed of different events (molts), survival analyses based on the Wei, Lin and Weissfeld model were used to compare development of the life stages (Li & Lagakos 1997; Wei et al. 1989). In this model, molts were stratified according to their order of occurrence with adult eclosion as the terminating event. Because of the stratification, separate hazard ratios can be estimated for each life stage as well as a comparison of the overall development of the species. Subjects that did not complete development were censored.

To determine female adult longevity and fecundity, newly emerged adult females were placed individually in small Petri dishes containing a 2.5-cm piece of green bean, with the ends sealed with Parafilm. Beans were replaced every 24 h, and this process continued for each thrips until death. Beans were subsequently examined over 7 d for larval emergence. The total number of offspring produced per adult female was recorded. Fecundity was analyzed by repeated measures analysis of covariance, with species as a treatment and longevity as a covariate. This analysis allowed a comparison of total fecundity and daily fecundity of thrips. Adult longevity was compared based on survival analysis in which mortality was examined by comparing the Cox proportional hazard for each species (Cox 1972) with ties handled by Breslow’s method (Breslow 1974). Insects that were accidentally lost during the experiment were considered censored observations and not included in fecundity analyses. Experiments were replicated 3 times with colonies that had been established for 4-8 months from specimens collected in Gadsden County, FL. Voucher specimens are deposited in the collections of the author. All statistical analyses were performed in SAS ver. 9.1 (SAS 2004).

Time to egg hatch was approximately 3 d for both F. occidentalis (range 2.5-3.5 d) and F. tritici (range 2.5-3 d). Overall immature development from oviposition to adult eclosion was significantly faster for F. tritici (median = 11.0 d, range = 9.5-14.0 d, n = 26) than for F. occidentalis (median = 12.0 d, range = 9.5-14.5 d, n = 20; χ2 = 14.10, df = 5, P = 0.015). There were no significant differences between the species in development times of the 2 larval stages (median = 2.0 d, range = 1.0-4.0 d, and 3.0 d, 2-4 d, for first and second stadia, respectively), and the propupal stage (median = 1.0 d, range = 0.5-3 d; P > 0.25 for each stage comparison). The difference in total development resulted from the shorter pupal stage of F. tritici (median = 2.0 d, range = 1-3 d) compared with F. occidentalis (median = 3.0 d, range = 2-5 d; χ2 = 5.14, df = 1, P = 0.02).

Adult longevity of females differed between the species, with F. occidentalis having a significantly greater longevity than F. tritici (log rank test χ2 = 8.2, df = 1, P = 0.004). The quartile estimates of times at which 25%, 50%, and 75% of the individuals had died were all significantly greater for F. occidentalis (Fig. 1A) indicating that the greater survivorship of F. occidentalis was consistent throughout the adulthood. Initial survivorship was high for both species, with less than 10% mortality in the first week after eclosion. The maximum longevity was similar for both species, with females living up to 38 and 39 d for F. tritici and F. occidentalis, respectively. However, the hazard ratio of F. tritici to F. occidentalis, which compares how rapidly subjects are dying, was 1.894 (95% confidence interval: 1.223-2.934), indicating that the rate of death was almost twice as fast for F. tritici compared with F. occidentalis.

There was a 2-day preoviposition period for both species (Fig. 1B). The majority of eggs were laid in the first 2 weeks of adulthood for both species (Fig. 1B and Fig. 2). Reproduction varied significantly over time (F = 1.87, df = 31, 1017, P = 0.003), with both species showing cyclical peaks and declines in daily oviposition (Fig. 2). Despite the difference in lifespans, total numbers of progeny averages were similar for F. tritici (52.4 ± 4.4) and for F. occidentalis (49.4 ± 4.3; F = 0.30, df = 1, 47, P = 0.60).

The mean daily fecundity was over 9% higher for F. tritici (2.26 ± 0.13) than for F. occidentalis (2.07 ± 0.11; F = 4.19, df =1, 47, P = 0.046). This difference resulted from the low number of eggs laid by the oldest F. occidentalis females towards the end of their lifetime. The maximum number of eggs laid in 1 d was 18 for F. occidentalis and 17 for F. tritici. Lifetime reproduction was significantly related to adult longevity for F. tritici (slope estimate ± 95% CI: 2.88 ± 1.12 eggs per additional day of adulthood, t = 8.01, df = 47, P < 0.0001) but not for F. occidentalis (slope estimate ± 95% CI: 1.02 ± 1.83, t = 1.62, df = 47, P = 0.12).

While F. occidentalis has been intensively studied, little information on the bionomics of less pestiferous Frankliniella species is available. The results of the present study demonstrate that there are broad similarities in the development and reproduction of F. occidentalis and F. tritici, although these similarities may change at higher or lower temperatures than tested in the present study. Still, both species are capable of increasing rapidly with overlapping generations. The faster development and higher daily oviposition of F. tritici may enable its populations to build at faster rates than populations of F. occidentalis and contribute to its greater abundance in the southeastern USA (Reitz 2002).

Mention of trade names or commercial products in this article is solely for the purpose of providing specific information and does not imply recommendation or endorsement by the U.S. Department of Agriculture. I appreciate the technical assistance of Eric Hansen and Xinhua Yan, and the comments of Joe Funderburk on an earlier draft.


The development and reproduction of Frankliniella occidentalis and F. tritici were evaluated. Both species showed similar patterns in development and reproduction at 28.0°C. However, median development time for immatures of F. tritici was 1 d faster than for F. occidentalis, and although F. occidentalis females survived longer than F. tritici, there was no difference in total progeny production.

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Fig. 1.

Adult longevity (A) and mean cumulative lifetime fecundity (B) of Frankliniella occidentalis (n = 35) and F. tritici (n = 35) females.


Fig. 2.

Mean daily fecundities of Frankliniella occidentalis (n = 26) and F. tritici (n = 25) over the completed female lifetime. Bars represent standard errors of the means.

Stuart R. Reitz "Comparative Bionomics of Frankliniella occidentalis and Frankliniella tritici," Florida Entomologist 91(3), 474-476, (1 September 2008).[474:CBOFOA]2.0.CO;2
Published: 1 September 2008
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