REVIEW Eur.1. Entomol. 102: 317-324, 2005 ISSN 1210-5759 Seasonal adaptations of green lacewings (Neuroptera: Chrysopidae) MICHEL CANARD 47 chemin Flou de Rious, F-31400 Toulouse, France; e-mail: [email protected] Key words. Chrysopidae, green lacewing, seasonal adaptation, diapause, voltinism, overwintering, eycle synchronization, wintering chambers Abstract. Seasonal adaptations of green lacewings (Neuroptera: Chrysopidae) and their role in the control of aphid populations are discussed. The chrysopids of temperate zones face seasonal changes and must escape cyclic adversity. One way is via the number of broods per year. Most green lacewings are facultatively multivoltine, with the succession of generations most often regulated by photomediated diapause. Others are univoltine and some extend their life-cycle to two years in cold or dry environments. Synchroni­ zation is an important feature of seasonality, often starting in spring. In univoltine species, it is sometimes the result of subtle mecha­ nisms, such as double contradictory signals (short plus long day lengths) for reactivation in spring, or a multi-receptivity of the preimaginal instars to photoperiod throughout a year, combined with photo-controlled and synchronized egg laying in late summer. Only one North American species is known to enter a surnumerary food-mediated diapause in summer. Every postembryonic instar may undergo diapause depending on the species. The timing and impact of the spring resumption in aphid consumption depends on their overwintering strategy. As far is known, chrysopids are intolerant of freezing, but their supercooling points are low enough to enable them to endure hard frost. The numbers of overwintering specimens of green lacewings in the field depend on the structure of the as~emblages in the pre­ vious growing season. Three examples are used to show that the overwintering populations are difIerent in the different biotopes and dependent on the way the dominant species overwinter. Artificial chambers proposed for overwintering adults of common green lacewings afford them protection during diapause and enhance their predatory efficiency in spring. INTRODUCTION any lacewing in the southern hemisphere. The quite well­ studied Westpalaearctic Region harbours about 121 spe­ Organisms living at the higher latitudes are regularly cies of chrysopids (Aspock et aI., 2001), 67 of them occur confronted with seasonal changes in climate (cold/hot or in Europe; in the Nearctic Region, 82 species are dry/wet), which are more or less rigorously adverse and recorded in North America, excluding Mexico (Penny et result in the evolution of strategies for escaping this aI., 1997, 2000). It is mainly by studying these species cyclic adversity. In arthropods, diapause and/or migration that we can understand the mechanisms by which they may offer ways of doing this. As far is known, survive and efficiently colonize the available biotopes Chrysopidae only use diapause. True n1igration (sensu every year. Here their impact on the control of aphid out­ Kennedy, 1975) may occur, but only, as far is known, in breaks will be assessed rather than the physiological Chrysoperla cqrnea (Stephens, 1836), the so-called mechanisms by which this is achieved. "common green lacewing", which obligatorily flies down-wind on the firsttwo nights after emergence, what­ VOLTINISM ever the generation (Duelli, 2001). A con11llonly encountered method of adjusting annua1 WHICH SPECIES OF GREEN LACEWING ARE cycle is the number of broods per year, i.e. univoltinislll INVOLVED? vs multivoltinism, which affects the impact these preda­ tors have on aphids. Responses are variable and not About 1200 species of Chrysopidae are described dependent only on the latitudinal occunence of a species. (Brooks & Barnard, 1990). Most are inhabitants of the For example, Ceraeochrysa placita (Banks, 1908), tropical and equatorial zones and display homodynamic reported from Canada to Mexico, does not enter dor­ development. They do not experience a seasonal alterna­ mancy in order to survive winter in the southern part of tion of favourable and adverse clin1atic and trophic condi­ its range; nevertheless, it is always univoltine (Tauber et tions. This is the case for instance in the Afrotropical aI., 1998). Mallada desjardinsi (Navas, 1911) (Brettell, 1979) and Other species have lllore varied patterns of vo ltinism, the Neotropical Chrysoperla externa (Hagen, 1861) such as the stenotopic Chrysopa phyllochroma Wesmael, (Macedo ct aI., 2003). In Ceraeochrysa cincta 1841 and Chrysopa dasyptera McLachlan, 1872, which (Schneider, 1851), C. cubana (Hagen, 1861) and C. are univoltine in Central Europe according to Zeleny smithi (Navas, 1914), diapause was not observed even at (1965, 1984); but Ch. phyllochroma may have two gen­ 30 0 N in Florida and Texas, nor induced experimentally in erations a year in western Europe (Trouve et aI., 2002) the laboratory (Lopez-Anoyo et aI., 1999). and Ch. dasyptera has two generations a year in the Green lacewings in the Holarctic Region show adapta­ Middle Volga Region in Russia (52-54°N) (Kovrigina, tions to the seasonal changes; diapause is not recorded for 317 1990). In the case of facultative uni/multivoltinism, some Little is known about the physiological mechanism of individuals of a species mostly only show a slight their cold hardiness, but cryoprotection in Neuropterida response depending on their place of origin, as in probably does not differ from that in other insects. In Chrysopa abbreviata Curtis, 1834, in Italy (Pantaleoni, overwintering cocoons of Chlysopa "walkeri McLachlan, 1982). Nevertheless, most green lacewings exhibit facul­ 1893, carbohydrate analysis shows glycogen and treha­ tative multivoltine cycles with the number of broods per lose as the major stored elements. The glycogen level was year a direct function of the climatic and trophic condi­ consistantly higher than that of trehalose, whilst polyol tions. levels were low or undetectable (Sagne et ai., 1986). Some species manifest a tendency to prolong and n1ain­ Overwintering adults of Chrysoperla affinis (Stephens, tain diapause for more than one year and so have a two­ 1836) [Chrysoperla kolthoffi (Navas, 1927)] showed a year cycle. This precaution against unfavourable strong decrease in total lipid content at the beginning and environmental conditions is adopted in northern, cold at the end of winter reproductive diapause; the percentage countries, e.g. by Chrysopa dorsalis Burmeister, 1839, in of phospholipids increased significantly during post­ Russia (Volkovich, 1998), and in xerothermic conditions, diapause, while that of glycerids decreased, especially in e.g. by the Iberian C~hrysopa regalis Navas, 1915 females (Lemesle et aL, 1998). (Canard, 1986a). This particular adaptation involves spe­ WHICH INSTARS OVERWINTER? cies diapausing as prepupa within a cocoon, since this is the only stage able to provide protection against dehydra­ In all species of green lacewings there is one, SOIne­ tion and weight loss (Canard et aI., 1996). times two, developmental stages which are able to survive adverse winter conditions, namely frost and scarcity, if CUES REGULATING VOL TINISM not total lack, of prey. In the family Chrysopidae, When "obligatory" (i.e. always Inanifested in natural depending on the species, all stages except the embryo, conditions) univoltinism is a totally innate function, can overwinter. Thirty nine of th~ 67 species in Europe genetically mediated (Tauber & Tauber, 1981; Tauber et and 17 North American species o'verwinter as a prepupa aI., 1986). On the other hand, as in most arthropods within a cocoon (Table 1). exhibiting facultative multivoltinisIn, photoperiod is the OVERWINTERING OF FIELD POPULATIONS IN main factor regulating the cycle, more or less tnodulated DIFFERENT BIOTOPES by temperature and/or thermoperiod, as in Dichochrysa flav~rrons (Brauer, 1850) (Principi et aI., 1990), Chrysopa Aphid control is often determined early in a growing pallens (Rambur, 1838) (Orlova, 1998) and Dichochrysa season, because if the aphid fundatrices encounter an prasina (Burmeister, 1839) (Volkovich, 1998) in northern abundance of natural enemies when they colonize plants, Russia. the resulting colonies are less numerous and when estab­ lished, less crowded. Early occurrence of predators is a ARE GREEN LACEWINGS FROST TOLERANT? key factor in efficient aphid management. Whether uni- or multivoltine, chrysopids in ten1perate The tiine of resumption of predatory activity by green climates experience low temperature in winter. There is lacewings depends on thei r overwintering strategy, which little information on the ability of green lacewings to determines their impact on aphid abundance (Fig. I). resist cold. The available data indicate a good hardiness - If they overwinter as partly grown larvae as in to frost even if the green lacewings are unbiased frost Dichochrysa spp., they start feeding on prey immediately; intolerant. - if they overwinter as prepupae within a cocoon, the Prepupae of Chrysopa perla (Linnaeus, 1758) on the first contact between the predator and the prey is delayed sixth month of diapause are unable to survive 3 days at until the adults emerge if they are predacious, as in -17°C, but can survive -6°C (Sagne & Canard, 1984). Chlysopa spp.; Overwintering adults of the common green lacewings in - if they overwinter as adults, the impact on prey is NOlih America survived well (97%) 31 weeks at 5°C delayed until reproduction ( ovogenesis, mating) + when in