Tomato is the most important vegetable crop in Spain. The mirid bug Nesidiocoris tenuis (Reuter) commonly appears in large numbers in protected and open-air tomato crops where little or no broad-spectrum insecticides are used. Nesidiocoris tenuis is known to be a predator of whiteflies, thrips and several other pest species. However, it is also considered a pest because it can feed on tomato plants, causing necrotic rings on stems and flowers and punctures in fruits. Our objectives were to evaluate predation by N. tenuis on sweetpotato whitefly Bemisia tabaci Gennadius under greenhouse conditions and establish its relationship to N. tenuis feeding on tomato. Two different release rates of N. tenuis were compared with an untreated control (0, 1 and 4 N. tenuis plant -1 ) in cages of 8 m 2 . Significant reductions of greater than 90% of the whitefly population and correspondingly high numbers of N. tenuis were observed with both release rates. Regression analysis showed that necrotic rings on foliage caused by N. tenuis were best explained by the ratio of B. tabaci nymphs:N. tenuis as predicted by the equation y = 15.086x -0.6359.
Entomopathogenic nematodes (EPN) are excellent biocontrol agents against various insect pests. Novel biotechnological approaches can enhance their utility against insects above-ground, opening a new venue for selecting superior EPN against certain insects. We hypothesize that different populations of the same species but from different origins (habitat, ecoregion) will differ in their virulence. This study aimed to evaluate the virulence of various EPN populations against two pests of worldwide incidence and damage to high value crops:
Frankliniella occidentalis
(Thysanoptera: Thripidae) and
Tuta absoluta
(Lepidoptera: Gelechiidae). We tested 10 EPN populations belonging to three EPN species:
Heterorhabditis bacteriophora
(Koppert, MG-618b, AM-203, RM-102),
Steinernema feltiae
(Koppert, RS-5, AM-25, RM-107), and
Steinernema carpocapsae
(Koppert, MG-596a). Each EPN population was tested at two concentrations.
Frankliniella occidentalis
was tested at 160 and 80 IJs/cm
2
and
T. absoluta
at 21 and 4 IJs/cm
2
. Control treatments followed the same experimental procedure but only adding distilled water. Overall, whenever different, higher IJs concentration resulted in lower adult emergence, higher larval mortality, and shorter time to kill the insects. Considering the low concentration,
S. feltiae
provided the best results for both insects and instars investigated, while
H. bacteriophora
and
S. carpocapsae
required a high concentration to reach similar or slightly better results. Differences among populations of each of the species were detected, but only the native populations of
H. bacteriophora
populations showed consistently higher control values against both insects/instar compared with the commercial one. Differences among
S. feltiae
and
S. carpocapsae
populations depended on the IJs concentration, insect, and instar. We consider
S. feltiae
a very promising species for their application against
F. occidentalis
and
T. absoluta
, with the Koppert population as the most consistent among the populations tested. Specific EPN-populations of
S. carpocapsae
and
H. bacteriophora
were good candidates against certain instar/insects at high concentrations. This study emphasized the importance of intraspecific variability for EPN virulence.
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