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Shedding new light upon circadian emergence rhythmicity in the mountain pine beetle (Coleoptera: Curculionidae: Scolytinae)

Published online by Cambridge University Press:  15 April 2019

Debra L. Wertman  and
Katherine P. Bleiker
Debra L. Wertman*
Affiliation:
Department of Biology, University of Victoria, Cunningham Building, 3800 Finnerty Road, Victoria, British Columbia, V8P 5C2, Canada; and Pacific Forestry Centre, Natural Resources Canada – Canadian Forest Service, 506 W Burnside Road, Victoria, British Columbia, V8Z 1M5, Canada Pacific Forestry Centre, Natural Resources Canada – Canadian Forest Service, 506 W Burnside Road, Victoria, British Columbia, V8Z 1M5, Canada
Katherine P. Bleiker
Affiliation:
Pacific Forestry Centre, Natural Resources Canada – Canadian Forest Service, 506 W Burnside Road, Victoria, British Columbia, V8Z 1M5, Canada
*
2Corresponding author (e-mail: dwertman@uvic.ca)
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Abstract

The phenological behaviours of temperate insects can be highly controlled by photoperiod. Some foundational studies of the mountain pine beetle, Dendroctonus ponderosae (Hopkins) (Coleoptera: Curculionidae), documented a diurnal emergence rhythm that was asynchronous with maximum daily temperatures in the field and persisted under constant temperature and light conditions. In the 1970s, researchers hypothesised that this emergence rhythm was regulated by an endogenous circadian mechanism. Reflecting upon these historical data, we consider that a diurnal pattern of D. ponderosae emergence may result from photoperiodic entrainment of the circadian clock during the immature stages. Mechanistically, we suggest that the long-wavelength-sensitive opsin that we previously found to be expressed across D. ponderosae life stages could mediate, from beneath the bark, the input of light–dark cycle cues that are usually required for entrainment of the insect circadian clock.

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Forum
Information
The Canadian Entomologist , Volume 151 , Issue 3 , June 2019 , pp. 273 - 277
Copyright
© Entomological Society of Canada 2019 

Photoperiod is a ubiquitous regulator of insect phenology, particularly in seasonal environments (Bradshaw and Holzapfel Reference Bradshaw and Holzapfel2007). The insect circadian clock consists of an endogenous light-independent physiological rhythm, which can be entrained to the daily light–dark cycle using light and/or temperature cues, and a molecular mechanism for photoperiodic time measurement (Saunders Reference Saunders1973; Emerson et al. Reference Emerson, Dake, Bradshaw and Holzapfel2009; Bradshaw and Holzapfel Reference Bradshaw and Holzapfel2010). Endogenous circadian regulation in insects can influence patterns of metabolic and behavioural activity (Friedrich Reference Friedrich2013; Tierney et al. Reference Tierney, Friedrich, Humphreys, Jones, Warrant and Wcislo2017). For example, insect behaviours under circadian control may include eclosion, oviposition, egg hatching, and movement (summarised in Felisberti et al. Reference Felisberti, Ventura and Hertel1997 and Lampel et al. Reference Lampel, Briscoe and Wasserthal2005). Direct and circumstantial evidence from a diverse set of entomological studies indicates that a diversity of cryptic (physically concealed, see definition by Wertman et al. Reference Wertman, Bleiker and Perlman2018) insects are capable of photoperiodic time measurement (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996; Doležal and Sehnal Reference Doležal and Sehnal2007; Shintani Reference Shintani2011; Friedrich Reference Friedrich2013). Photoperiod is known to influence development rate, including diapause programming, in certain subcortical tree-tissue developing beetles (Coleoptera) (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996; Doležal and Sehnal Reference Doležal and Sehnal2007; Shintani Reference Shintani2011), and is implicated in the entrainment of circadian behavioural rhythms in cave beetles (Friedrich Reference Friedrich2013).

The mountain pine beetle, Dendroctonus ponderosae (Hopkins) (Coleoptera: Curculionidae: Scolytinae), is an eruptive species of bark beetle and a severe pest of mature pine (Pinus: Linnaeus; Pinaceae) forests in western North America (Safranyik and Carroll Reference Safranyik, Carroll, Safranyik and Wilson2006; Safranyik et al. Reference Safranyik, Carroll, Régnière, Langor, Riel and Shore2010). Aside from a short period of adult dispersal, D. ponderosae completes its development entirely within the subcortical tissues of host trees. Life cycle and emergence synchronicity in D. ponderosae increases the success of mass attacks on host trees and contributes to the establishment of epidemic populations (Bentz et al. Reference Bentz, Logan and Amman1991). Accordingly, D. ponderosae possesses temperature-dependent mechanisms to optimise life cycle synchronisation and overwinter survival (Safranyik Reference Safranyik, Berryman, Amman and Stark1978; Bentz et al. Reference Bentz, Logan and Amman1991, Reference Bentz, Vandygriff, Jensen, Coleman, Maloney and Smith2013). In temperate univoltine populations, adult beetles emerge from their brood trees and disperse to colonise new hosts in late summer, laying eggs within the phloem (Safranyik and Carroll Reference Safranyik, Carroll, Safranyik and Wilson2006). The timing of adult D. ponderosae emergence from beneath the bark is primarily determined by ambient temperature and immature development rate, which is also a function of temperature. The optimal temperature range for D. ponderosae emergence is 25–30 °C (Gray et al. Reference Gray, Billings, Gara and Johnsey1972), and the insects do not emerge below a lower threshold of 16 °C (summarised in Safranyik and Carroll Reference Safranyik, Carroll, Safranyik and Wilson2006).

Within this range of optimal temperatures for D. ponderosae emergence, there exists a rhythmic daily emergence pattern during the flight period that cannot be explained by temperature alone (Reid Reference Reid1962; Gray et al. Reference Gray, Billings, Gara and Johnsey1972; Billings and Gara Reference Billings and Gara1975). For example, Gray et al. (Reference Gray, Billings, Gara and Johnsey1972) documented asynchrony between maximum daily temperatures and peak daily emergence from infested bolts maintained in the field. Over a period of nine days, the authors found that 61% (232 out of 379) of the insects emerged between 11 AM and 2 PM, despite that maximum daily temperatures were reached at 2–4 PM. These findings informed a complement of laboratory experiments that revealed the persistence of the circadian emergence rhythm in D. ponderosae under constant temperature and light conditions (Watson Reference Watson1970; Billings and Gara Reference Billings and Gara1975). Paiva and Vité (Reference Paiva and Vité1982) observed a similar phenomenon for adult Trypodendron lineatum (Olivier) (Coleoptera: Curculionidae: Scolytinae), which displayed rhythmic circadian emergence patterns under constant laboratory conditions after having overwintered in the field beneath the soil.

Here we examine contemporary literature to evaluate the hypothesis presented by Watson (Reference Watson1970), Gray et al. (Reference Gray, Billings, Gara and Johnsey1972), and Billings and Gara (Reference Billings and Gara1975) nearly 50 years ago – that an endogenous circadian mechanism underlies the diurnal D. ponderosae emergence rhythm observed both in the field and in laboratory experiments. We propose that emergence rhythmicity observed in adult D. ponderosae may be a result of photoperiodic entrainment of the circadian clock of the immature stages developing within subcortical tree tissues. This would require that immature D. ponderosae can perceive and respond phenologically to photoperiod from beneath the bark.

Researchers have documented evidence of photoperiodic time measurement and circadian behavioural rhythmicity in cryptic insects. This includes both subcortical tree-tissue developing beetles (immature Ips typographus (Linnaeus) (Coleoptera: Curculionidae: Scolytinae) (Doležal and Sehnal Reference Doležal and Sehnal2007), Psacothea hilaris (Pascoe) (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996), and Phytoecia rufiventris Gautier (Coleoptera: Cerambycidae) (Shintani Reference Shintani2011)) and several species of cave beetle that have reduced ocular organs (Coleoptera: Carabidae) (Friedrich Reference Friedrich2013). However, troglomorphic beetles (Coleoptera: Carabidae, Leiodidae) that lack photoreceptor organs entirely generally display arrhythmic behaviours, indicating that the degradation of circadian rhythmicity in beetle behaviour is related to the degree of subterranean adaptation (Friedrich Reference Friedrich2013).

Photoperiod is known to influence the development rate, directly and indirectly, in I. typographus (Doležal and Sehnal Reference Doležal and Sehnal2007), P. hilaris (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996), and P. rufiventris (Shintani Reference Shintani2011). Doležal and Sehnal (Reference Doležal and Sehnal2007) demonstrated that the exposure of immature I. typographus (late instars and older) to specific photoperiod treatments induced reproductive diapause in the adult stage, indicating that the insects were able to perceive light from beneath the bark and store photoperiodic information. The effects of photoperiod on diapause induction and number of instars have been described for P. hilaris (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996) and P. rufiventris (Shintani Reference Shintani2011). For example, the exposure to short day lengths at constant temperature led to the development of one or two supernumerary instars and the subsequent induction of diapause in P. hilaris (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996). Psacothea hilaris larval diapause was maintained under short day lengths and terminated by exposure to longer photoperiods.

Dendroctonus ponderosae larvae, like all scolytid beetle larvae, lack external ocular organs (stemmata) (Jordal Reference Jordal, Leschen and Beutel2014), and photoperiodic information for circadian clock entrainment must therefore be received extraocularly (Wertman et al. Reference Wertman, Bleiker and Perlman2018). The photoperiodic stimuli that reach D. ponderosae larvae developing beneath the bark most likely consist of long-wavelength light (480–600 nm), which is considered important to the ecology of low-light-adapted insects (Jackowska et al. Reference Jackowska, Bao, Liu, McDonald, Cook and Friedrich2007; Friedrich et al. Reference Friedrich, Chen, Daines, Bao, Caravas and Rai2011; Wertman et al. Reference Wertman, Bleiker and Perlman2018). It is therefore probable that long-wavelength-sensitive opsin proteins are the photoreceptors responsible for stimulating physiological responses in cryptic insects (Wertman et al. Reference Wertman, Bleiker and Perlman2018), including those observed in subcortical tree-tissue developing beetles (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996; Doležal and Sehnal Reference Doležal and Sehnal2007; Shintani Reference Shintani2011). We hypothesise that the photoperiodic light input for circadian entrainment could be mediated by the long-wavelength-sensitive opsin that we previously found to be expressed across D. ponderosae life stages and throughout the larval body (Wertman et al. Reference Wertman, Bleiker and Perlman2018). A number of studies have implicated insect opsins, particularly those expressed in the brain, in the reception of photoperiodic information and circadian clock entrainment (Shimizu et al. Reference Shimizu, Yamakawa, Shimazaki and Iwasa2001; Lampel et al. Reference Lampel, Briscoe and Wasserthal2005; Spaethe and Briscoe Reference Spaethe and Briscoe2005; Velarde et al. Reference Velarde, Sauer, Walden, Fahrbach and Robertson2005). Additionally, deep-brain photoreceptor organs that originate from larval stemmata are widespread among endopterygote insects, and are speculated to function in circadian regulation (reviewed in Buschbeck and Friedrich Reference Buschbeck and Friedrich2008).

In Drosophila melanogaster Meigen (Diptera: Drosophilidae), the molecular circadian clock can be entrained by two different classes of photoreceptor proteins, opsins and cryptochromes (Helfrich-Förster et al. Reference Helfrich-Förster, Winter, Hofbauer, Hall and Stanewsky2001), the latter of which are considered to function in circadian regulation in all metazoans (Yuan et al. Reference Yuan, Metterville, Briscoe and Reppert2007). The D. melanogaster circadian clock is governed by a transcriptional feedback loop involving a number of clock genes and their encoding proteins, including cryptochrome 1 (reviewed in Saunders Reference Saunders2012). While cryptochrome 1 is known to be photosensitive, cryptochrome 2 is thought to be photo-insensitive and to function in light-independent circadian regulation (Yuan et al. Reference Yuan, Metterville, Briscoe and Reppert2007). Cryptochrome 1 is absent from the genomes of beetles, including Tribolium castaneum (Herbst) (Coleoptera: Tenebrionidae) (Yuan et al. Reference Yuan, Metterville, Briscoe and Reppert2007), Ptomaphagus hirtus (Tellkampf) (Coleoptera: Leiodidae, Cholevinae) (Friedrich et al. Reference Friedrich, Chen, Daines, Bao, Caravas and Rai2011), and D. ponderosae (Keeling et al. Reference Keeling, Yuen, Liao, Roderick Docking, Chan and Taylor2013, National Centre for Biotechnology Information Resource Coordinators 2017), which appear to encode only cryptochrome 2. Based on the absence of cryptochrome 1 and lack of additional opsin orthologs in the D. ponderosae genome (Wertman et al. Reference Wertman, Bleiker and Perlman2018), we contend that the long-wavelength-sensitive opsin is the most probable candidate receptor of photoperiodic information for entrainment of the molecular clock in this species.

Daytime temperatures are generally higher than nighttime temperatures, resulting in daily thermoperiodic cycles that roughly track the photoperiod (see definition by Beck Reference Beck1982). Although the photoperiod is a far more reliable environmental cue for daylength than thermoperiod and is considered a primary environmental stimulus for insect circadian regulation (Bradshaw and Holzapfel Reference Bradshaw and Holzapfel2007), some insects can also use the thermoperiod for entrainment of the molecular clock (reviewed in Saunders Reference Saunders2014). For example, female Nasonia vitripennis (Walker) (Hymenoptera: Pteromalidae) parasitic wasps, when reared from the egg stage in darkness, are able to differentiate short- from long-day thermoperiods and produce either diapausing or developing broods in response (Saunders Reference Saunders1973). Photoperiodic and thermoperiodic cues may be involved in the entrainment of the D. ponderosae circadian clock. This could be tested by rearing D. ponderosae from the egg stage under photoperiodic and sustained darkness conditions at constant temperature, and by comparing these results to those obtained under thermoperiodic conditions. For example, if photoperiodic entrainment of the D. ponderosae circadian clock occurs, beetles reared in constant darkness should exhibit no defined emergence rhythm, while those reared under photoperiodic laboratory conditions of stable temperature should display circadian emergence rhythmicity.

Over the last several decades, technological progress has greatly enhanced our understanding of the molecular mechanisms supporting the insect circadian clock, leading to the exploration of the physiological effects of circadian regulation (reviewed in Bradshaw and Holzapfel Reference Bradshaw and Holzapfel2010). In the context of circadian regulation, an evaluation of existing experimental observations from across insect taxa reveals common phenological responses to the photoperiod, even among cryptic species (Shintani et al. Reference Shintani, Ishikawa and Tatsuki1996; Doležal and Sehnal Reference Doležal and Sehnal2007; Shintani Reference Shintani2011), which can inform our interpretations of historical data. With respect to D. ponderosae, diurnal emergence must optimise dispersal success, as visual cues are known to be important in adult beetle navigation and host-tree location (Reid Reference Reid1962; Shepherd Reference Shepherd1966). Photoperiodic entrainment of the D. ponderosae circadian clock, via the long-wavelength-sensitive opsin, would ensure that adult emergence is restricted to a period of the day that is marked by both optimal temperatures and light conditions for coordinated flight.

Acknowledgements

We are indebted to the authors of the original D. ponderosae articles reviewed herein, as well as the work of L. Safranyik. We thank S. Perlman and G. Smith, and acknowledge support provided by Natural Resources Canada.

Footnotes

1

Present address: Department of Forest and Conservation Sciences, Forest Sciences Centre, University of British Columbia, 3041 – 2424 Main Mall, Vancouver, British Columbia, V6T 1Z4, Canada.

Subject editor: Therese Poland

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