Article | Open | Published:

Cassowary casques act as thermal windows

Scientific Reportsvolume 9, Article number: 1966 (2019) | Download Citation

Abstract

Many ideas have been put forward for the adaptive value of the cassowary casque; and yet, its purpose remains speculative. Homeothermic animals elevate body temperature through metabolic heat production. Heat gain must be offset by heat loss to maintain internal temperatures within a range for optimal performance. Living in a tropical climate, cassowaries, being large bodied, dark feathered birds, are under thermal pressure to offload heat. We tested the original hypothesis that the casque acts as a thermal window. With infrared thermographic analyses of living cassowaries over an expansive range of ambient temperatures, we provide evidence that the casque acts as a thermal radiator, offloading heat at high temperatures and restricting heat loss at low temperatures. Interestingly, at intermediate temperatures, the casque appears thermally heterogeneous, with the posterior of the casque heating up before the front half. These findings might have implications for the function of similar structures in avian and non-avian dinosaurs.

Introduction

The cassowary is a large, flightless bird that bears a prominent helmet (or casque). The function of the casque has attracted considerable curiosity and speculation for nearly 200 years1, yet its purpose remains unclear2. Early descriptions of the casque referred to it as a horny structure3,4, a horn-covered bony growth5 or hoof-like material6, giving rise to the most widely recognised idea that the casque is used as a protective structure for moving at high speed in dense vegetation5,7,8 and during fights with other animals5. Others have suggested that the casque is a secondary sexual characteristic9, although this hypothesis might not reflect the reason for its origin since both males and females are casque-bearing. Alternatively, the casque has been proposed to act as a resonance chamber to amplify the cassowary’s low frequency boom10; however, anatomical data argues against this idea11. One report12, of a single cassowary offered a possible thermal function, but the casque was outside the focus of the study, and the animal was studied only at ambient temperatures (Ta) less than 30 °C.

Homeothermic animals maintain a largely stable internal body temperature that is often different from Ta through the metabolic production of heat13,14. Many animals have evolved morphological structures, or adapted existing body regions, known as ‘thermal windows’, for heat exchange13,15,16,17,18,19,20. A pre-requisite that enables a structure to exchange heat with the environment is that it must be highly vascularised and uninsulated13,21,22 to enable some of the warmth in blood to be dissipated. Vessels in these body parts are superficial, facilitating heat exchange before the blood is recirculated towards the core. It is crucial that blood flow is adjustable to these regions13,17. At low Ta, vessel walls constrict, limiting blood flow to the area and enabling the warm blood to flow within the body. At warmer Ta, vessels dilate, which facilitates the cooling of blood before returning to the deep interior of the body.

The cassowary casque meets the characteristics of thermal windows: uninsulated and vascularised. Casques are keratinized, overlying a body crown and network of trabeculae surrounded by dorsoventrally aligned canals containing blood vessels making up an extensive vascular network2,6,9. Moreover, the cassowary faces a thermal challenge owing to its large size (up to 160 cm height; with females (60 kg) heavier than males (30 kg)), dark plumage and tropical distribution in Oceania23,24,25. For these collective reasons, it is possible that the distinctive helmet-like structure upon the cassowary’s head acts as a thermal radiator to remove excess heat. We provide evidence that the casque serves (at least in part) as a thermal window. This finding reinforces the possibility that Mesozoic dinosaurs with similar structures26,27,28 may have also used such appendages to cope with tropical environments.

Results

The cassowary has thermal windows

To better understand whether cassowary’s use their casque for temperature homeostasis, we conducted infrared thermographic analyses of 20 live cassowaries over an expansive range of ambient temperatures (Ta). Consistent with this prediction, we found that the casque displayed evidence of reactive vasomotion across different heat loads. Indeed, the casque, distal end of the bill, and legs all showed a capacity for thermal adjustment (Fig. 1). These regions showed relatively large differentials between appendage surface temperature and Ta at intermediate Ta, and smaller thermal contrasts at either end of Ta extremes. Conversely, the body was minimally affected by changes in Ta, owing to insulation from the feathers. The proximal bill and neck displayed a linear negative relationship with increasing Ta suggesting no active regulation of blood flow to these surfaces. This is not unexpected since at a Ta of 10 °C, the differential is ~20 °C because the surface temperatures of both regions are ~30 °C. Similarly, at a Ta of 30 °C, the differential declines to ~5 °C because the neck and proximal bill are still close to 30 °C. In this way, these regions are not making large thermal adjustments.

Figure 1
Figure 1

Surface temperature differentials of cassowary body regions over a range of air temperatures (5–36 °C). Points reflect raw data; the line is the model fit; grey shading denotes 95% confidence interval. The eye is not presented as it followed a similar pattern to the proximal bill and neck.

The capacity for thermal adjustment translated into propensity for heat exchange, although body surfaces varied significantly in their ability to exchange heat with the environment (Fig. 2, Table S1, χ2 = 741.70, d.f. = 6, P < 0.001). Notably, the surfaces of the cassowary most similar to core body temperature (i.e., the uninsulated eye, neck and proximal bill) were thermal windows at low Ta, losing heat to the cold environment. The ability of a body region to serve as a thermal window depended on Ta2 = 420.30, d.f. = 6, P < 0.001). For instance, the body appendages from which the most heat was lost at low Ta also lost less heat (per m2) at the highest temperatures.

Figure 2
Figure 2

The effects of ambient temperature (Ta) on heat exchange of seven body appendages. Data are presented as mean with 95% confidence interval. Negative values denote heat loss, whereas positive means reflect heat gain. Top, representative thermal images are presented showing thermal profiles of the casque in different Ta. The cassowary in the 5 and 35 °C photographs is the same bird.

The casque is the most important thermal window at high heat loads

Importantly, at the highest Ta, the casque dissipated the greatest amount of heat (per m2) to the environment (Fig. 2). The distal bill and legs likewise increased the amount of heat lost to the environment at increasing Ta, at least when represented as a function of total heat exchange (Fig. 3). Moreover, the casque offloaded more heat to the environment than the eye, bill (distal and proximal) and neck at high Ta. Indeed, heat loss across the casque accounted for 8% of all heat exchange, a disproportionately high value given the relatively small size of the casque. In this way, the casque served as a substantial thermal window when the animal was under high thermal loads. This process is best illustrated by thermal images of the casque over cold, moderate and hot Ta (Fig. 2). At low and high Ta, the surface temperature of the casque approximates Ta, likely owing to vasoconstriction and vasodilation, respectively, of casque vasculature. The thermal images also revealed a mosaic of thermal adjustments at moderate Ta, wherein the posterior (back) part of the casque tended to heat up before the anterior half. We explored this pattern by dividing the casque into quadrants to examine changes in temperature profiles across the casque. The four casque regions (χ2 = 95.42, d.f. = 3, P < 0.001; Fig. 4; Table S2) displayed significantly different heat dissipation patterns. At moderate Ta, the proximal posterior quadrant of the casque was hotter than the proximal anterior region (see also the thermal image in Fig. 2 at 25 °C), a pattern not reflected in the distal portions of the casque (χ2 = 92.69, d.f. = 6, P < 0.001).

Figure 3
Figure 3

Measures of heat exchange across seven body surfaces occurring under four ambient temperatures. A linear mixed model fit provided a predicted mean heat exchange (Qtotal, W). Heat exchange is represented as a percentage of heat exchanged by each appendage (W). Negative values denote heat loss; positive values reflect heat gain. Grey highlight denotes body regions that increased heat loss (as a % of total) with increasing Ta.

Figure 4
Figure 4

Thermal profiles of the four quadrants of the cassowary casque under a range of air temperatures. Inset: Cassowary illustrations show the anterior (grey) and posterior (black) regions of the casque for proximal and distal quadrants. Grey shading around each line reflects 95% confidence interval (CI); the fit points are the model fit with 95% CI. Cassowary head illustration courtesy of Breanna Eastick (used with permission).

Discussion

The function of the casque has remained enigmatic for nearly 200 years1,29. Our results confirm our hypothesis that the cassowary can regulate heat exchange via the casque. Indeed, cassowaries use their casque much in the same way as some other birds use their beaks for heat exchange13,20,30. Here, cassowaries used the casque as a thermal window when ambient temperature (Ta) was high, but restricting heat loss when Ta was low. It is noteworthy that the cassowaries were observed dunking their heads into water at high Ta (D.L.E. pers. obs.), perhaps to further increase cooling of the blood in the casque. Interestingly, at intermediate Ta (25 °C), the temperature profile of the casque was heterogenous with the posterior of the casque heating up before the front half. Separate vessels may be supplying the anterior and posterior regions, enabling asynchronous dilation and constriction of vessels, as seen in the toco toucan’s (Rhamphastos toco) bill13. Computed tomographic scanning reveals anterior-posterior differences in the amount of trabeculae in the cassowary casque, with dense trabeculae at the front that becomes increasingly diffuse towards the back11. Nonetheless, additional imaging would be useful to reconstruct the arterial and venous pathways of the casque vasculature, as has been used to (virtually) dissect avian vascular anatomy in other species31.

Body surfaces that track Ta are not considered to be actively involved in heat exchange, such as the feathers. The large proportion of total heat exchange by the body is simply a function of its large surface area. The eye, neck, and proximal bill likewise exchange some heat with the environment, but these regions are not specialised for that purpose. Instead, they maintain a consistently high surface temperature independent of environmental variation. Conversely, other body regions vary greatly in temperature over a range of Ta, and can therefore be considered specialised for heat exchange12. Specifically, the casque, distal bill and legs were thermal windows.

Allen’s rule hypothesizes that animals in cooler environments are expected to have smaller appendages, relative to whole-body size32. Appendages tend to lose the most heat, thus enlarged appendages will have increased overall heat dissipation, while conservation of heat is associated with reduced appendage size32,33,34. This holds true for bill size in many birds, which are often larger in birds from warmer environments than those from cooler environments20. Casques and casque-like structures are also present on birds inhabiting warmer habitats, for example hornbills (Bucerotiformes: Bucerotidae)30, helmeted guineafowl (Numida meleagris)35 and the maleo (Macrocephalon maleo)36. Interestingly, pterosaurs and some dinosaurs, including members of the Ornithischia and Saurischia had similar cranial adornments26,27,28. While the function of these structures is still poorly understood, our results suggest these dinosaurian ornaments may have also served a thermoregulatory role. Hence, findings about the function of the casque in extant species could complement current and future findings in fossilised species with similar structures.

Methods

Collection of data

Live, adult southern cassowaries (Casuarius casuarius; n = 20) were photographed with a hand-held thermal imager (Testo 875i, Testo Ag, Lenzkirch, Germany) in zoological parks ranging from Victoria in southern Australia (outside of their natural range) to Queensland in northern Australia, between April 2014 and September 2015 (austral autumn and spring, respectively). These parks were chosen to encompass a wide thermal range without the need to restrain birds within temperature controlled facilities, which would be logistically unlikely owing to their protected status and dangerous disposition. Meteorological conditions were recorded using a wireless weather station (Vantage Pro 2 Plus, Davis Instruments Australia, Pty. Ltd., Kilsyth, Australia) situated within 10 metres of the cassowary’s enclosure.

Thermal images were taken from a distance of 0.5–2 metres. The camera had a double lens which produced a thermal image and a digital image at a resolution of 160 × 120 pixels. Images were collected between 0800–1700 h covering a wide range of ambient temperatures (Ta), 5–36 °C. Temperature data from the images were measured using IRSoft 3.1 (Testo Ag, Lenzkirch, Germany). Average surface temperature of the casque, eye, bill (distal and proximal), neck, body (torso) and ‘legs’ (tarsometatarsus only as the tibiotarsus is covered with feathers) were calculated, assuming an emissivity of 0.96. Mean surface temperatures were measured using either a line (neck, legs, body), point (eye), circle (distal bill; around nostrils, and proximal bill; anterior to eye) or by tracing the area (casque). The casque was further divided into four regions: the distal anterior, proximal anterior, distal posterior and proximal posterior. A total of 2,487 images were used.

The La Trobe University Animal Ethics Committee approved the study (AEC14-11) and all methods were carried out in accordance with the relevant guidelines and regulations.

Calculation of heat exchange

Heat exchange (q; W/m2) estimates were calculated according to previously published studies37, and using the Thermimage package (v. 3.1) in R38,39. The estimates of heat exchange (loss = negative, gain = positive) were calculated as the sum of the convective and radiative heat exchange from a particular body surface, incorporating local measurements of ambient temperature, solar radiation, wind speed, and relative humidity. Operative temperature experienced by the cassowaries was not estimated due to an inability to safely measure the precise local microenvironment near the bird at the time of image capture. To visually inspect differences among surfaces, we plotted estimates of heat exchange at three values of ambient temperature spanning the ranges of measured ambient temperatures. Total heat exchange (Q) was estimated by multiplying heat exchange by area values (m2) obtained from adult specimens found in museums. To assess the proportional role of the casque in heat loss and gain, we fit linear mixed models of Qcasque as a function of Qtotal, and used the slope estimates as an indicator of the proportion of heat exchanged by the appendage.

Statistical analyses

To quantify the influence of ambient temperature on regional differences in casque surface temperature, we fit linear mixed effects models40, incorporating the casque surface of interest (broken into 4 quadrants based on proximal-distal and posterior-anterior designations) as a fixed effect and animal identity as a random effect, with image identity nested within animal identity. Following the estimation of body surface specific heat fluxes, we fitted linear mixed effects models of the area specific heat exchanges (W/m2), using body surface of interest (eye, neck, proximal bill, distal bill, mean casque, leg, and body), ambient temperature, and time of day as fixed effects, animal identity as a random effect, with image identity nested within animal identity. Surface and ambient temperature interactions were also assessed in the above model. In all cases, residuals were verified for normality and homoscedasticity. Finally, to estimate the relative contributions of the casque to heat exchange, we compared the model estimates from total heat exchange for the casque to the total body heat exchange estimates, as well as to published estimates of basal heat production in similarly sized emus41. We used model fits (±95% confidence interval) as measures of support and to summarise results. P-values were obtained using likelihood ratio tests (Type II Wald’s chi-square tests) using the car package in R42.

Data Availability

The datasets generated during and/or analyzed during the current study are availble from the corresponding author on reasonable request.

Additional information

Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

References

  1. 1.

    Gould, J. On a new species of cassowary. Proc. Zool. Soc. Lond. 25, 268–271 (1857).

  2. 2.

    Naish, D. & Perron, R. Structure and function of the cassowary’s casque and its implications for cassowary history, biology and evolution. Hist. Biol. 28, 507–518 (2016).

  3. 3.

    North, A. J. On the early history of the Australian cassowary (Casuarius australis, Wall). Rec. Aust. Mus. 10, 39–48 (1913).

  4. 4.

    Pycraft, W. P. On the morphology and phylogeny of the Palaeognathae (Ratitae and Crypturi) and Neognathae (Carinatae). J. Zool. 15, 149–290 (1900).

  5. 5.

    Cho, P., Brown, R. & Anderson, M. Comparative gross anatomy of ratites. Zoo Biol. 3, 133–144 (1984).

  6. 6.

    Richardson, K. The bony casque of the southern cassowary Casuarius casuarius. Emu 91, 56–58 (1991).

  7. 7.

    Kofron, C. P. Attacks to humans and domestic animals by the southern cassowary (Casuarius casuarius johnsonii) in Queensland, Australia. J. Zool. 249, 375–381 (1999).

  8. 8.

    Fowler, M. E. Comparative clinical anatomy of ratites. J. Zoo Wildl. Med., 204–227 (1991).

  9. 9.

    Chrome, F. & Moore, L. The cassowary’s casque. Emu 88, 123–124 (1988).

  10. 10.

    Mack, A. L. & Jones, J. Low-frequency vocalizations by cassowaries (Casuarius spp.). The Auk 120, 1062–1068 (2003).

  11. 11.

    Brassey, C. A. & O’Mahoney, T. Pneumatisation and internal architecture of the southern cassowary Casuarius casuarius casque: a microCT study. British Ornitologist’s Union (2018).

  12. 12.

    Phillips, P. K. & Sanborn, A. F. An infrared, thermographic study of surface temperature in three ratites: ostrich, emu and double-wattled cassowary. J. Therm. Biol. 19, 423–430 (1994).

  13. 13.

    Tattersall, G. J., Andrade, D. V. & Abe, A. S. Heat exchange from the toucan bill reveals a controllable vascular thermal radiator. Science 325, 468–470 (2009).

  14. 14.

    Lancaster, W. C., Thomson, S. C. & Speakman, J. R. Wing temperature in flying bats measured by infrared thermography. J. Therm. Biol. 22, 109–116 (1997).

  15. 15.

    Phillips, P. K. & Heath, J. E. Heat exchange by the pinna of the African elephant (Loxodonta africana). Comp. Biochem. Physiol. A 101, 693–699 (1992).

  16. 16.

    Reichard, J. D., Prajapati, S. I., Austad, S. N., Keller, C. & Kunz, T. H. Thermal windows on Brazilian free-tailed bats facilitate thermoregulation during prolonged flight. Integr. Comp. Biol. 50, 358–370 (2010).

  17. 17.

    Hagan, A. A. & Heath, J. E. Regulation of heat loss in the duck by vasomotion in the bill. J. Therm. Biol. 5, 95–101 (1980).

  18. 18.

    Noren, D. P., Williams, T. M., Berry, P. & Butler, E. Thermoregulation during swimming and diving in bottlenose dolphins. Tursiops truncatus. J. Comp. Physiol. B 169, 93–99 (1999).

  19. 19.

    Moritz, G. L. & Dominy, N. J. Thermal imaging of aye-ayes (Daubentonia madagascariensis) reveals a dynamic vascular supply during haptic sensation. Int. J. Primatol. 33, 588–597 (2012).

  20. 20.

    Tattersall, G. J., Arnaout, B. & Symonds, M. R. The evolution of the avian bill as a thermoregulatory organ. Biol. Rev. 92, 1630–1656 (2017).

  21. 21.

    Tattersall, G. J. & Milsom, W. K. Transient peripheral warming accompanies the hypoxic metabolic response in the golden-mantled ground squirrel. J. Exp. Biol. 206, 33–42 (2003).

  22. 22.

    Klir, J. J., Heath, J. E. & Bennani, N. An infrared thermographic study of surface temperature in relation to external thermal stress in the Mongolian gerbil. Meriones unguiculatus. Comp. Biochem. Physiol. A 96, 141–146 (1990).

  23. 23.

    Moore, L. Population ecology of the southern cassowary Casuarius casuarius johnsonii, Mission Beach north Queensland. J. Ornith. 148, 357–366 (2007).

  24. 24.

    Westcott, D. A., Bentrupperbäumer, J., Bradford, M. G. & McKeown, A. Incorporating patterns of disperser behaviour into models of seed dispersal and its effects on estimated dispersal curves. Oecologia 146, 57–67 (2005).

  25. 25.

    Chrome, F. J. H. Some observations on the biology of the cassowary in northern Queensland. Emu 76, 8–14 (1976).

  26. 26.

    Lü, J. et al. High diversity of the Ganzhou oviraptorid fauna increased by a new “cassowary-like” crested species. Sci. Rep. 7, 6393 (2017).

  27. 27.

    Hone, D. W., Naish, D. & Cuthill, I. C. Does mutual sexual selection explain the evolution of head crests in pterosaurs and dinosaurs? Lethaia 45, 139–156 (2012).

  28. 28.

    Lamanna, M. C., Sues, H.-D., Schachner, E. R. & Lyson, T. R. A new large-bodied oviraptorosaurian theropod dinosaur from the latest Cretaceous of western North America. Plos One 9, e92022 (2014).

  29. 29.

    Rothschild, W. & Pycraft, W. P. V. I. A Monograph of the Genus. Casuarius. J. Zool. 15, 109–148 (1900).

  30. 30.

    van de Ven, T., Martin, R., Vink, T., McKechnie, A. & Cunningham, S. Regulation of heat exchange across the hornbill beak: functional similarities with toucans? Plos One 11, e0154768 (2016).

  31. 31.

    Porter, W. R. & Witmer, L. M. Avian cephalic vascular anatomy, sites of thermal exchange, and the rete ophthalmicum. Anat. Rec. 299, 1461–1486 (2016).

  32. 32.

    Allen, J. A. The influence of physical conditions in the genesis of species. Rad. Rev. 1, 108–140 (1877).

  33. 33.

    Rensch, B. Some problems of geographical variation and species-formation. Proc. Linn. Soc. Lond. 150, 275–285 (1938).

  34. 34.

    Greenberg, R., Cadena, V., Danner, R. M. & Tattersall, G. Heat loss may explain bill size differences between birds occupying different habitats. Plos One 7, e40933 (2012).

  35. 35.

    Ratcliffe, C. & Crowe, T. Habitat utilisation and home range size of helmeted guineafowl (Numida meleagris) in the midlands of KwaZulu-Natal province, South Africa. Biol. Cons. 98, 333–345 (2001).

  36. 36.

    Butchart, S. H. & Baker, G. C. Priority sites for conservation of maleos (Macrocephalon maleo) in central Sulawesi. Biol. Cons. 94, 79–91 (2000).

  37. 37.

    Tattersall, G. J., Chaves, J. A. & Danner, R. M. Thermoregulatory windows in Darwin’s finches. Funct. Ecol. 32, 358–368 (2018).

  38. 38.

    Tattersall, G. J. Thermimage: Thermal Image Analysis, https://doi.org/10.5281/zenodo.1069705 (2017).

  39. 39.

    Tattersall, G. J. Infrared thermography: A non-invasive window into thermal physiology. Comp. Biochem. Physiol. A 202, 78–98 (2016).

  40. 40.

    Bates, D., Maechler, M., Bolker, B. & Walker, S. Fitting linear mixed-effects models usinglme4. J Stat. Soft. 67, 1–48 (2015).

  41. 41.

    Maloney, S. J. & Dawson, T. J. Sexual dimorphism in basal metabolism and body temperature of a large bird, the emu. Condor 95, 1034–1037 (1993).

  42. 42.

    Fox, J. & Weisberg, S. An {R} Companion to Applied Regression. Second edn, (Sage, 2011).

Download references

Acknowledgements

This research was supported by several Zoological Parks that gave us access to their cassowaries: Australia Zoo, Birdworld Kuranda, Cairns Tropical Zoo, Currumbin Wildlife Sanctuary, David Fleay Wildlife Park, Halls Gap Zoo, Hartley’s Crocodile Adventures, Healesville Sanctuary, Melbourne Zoo, Rainforestation Wildlife Park and Wildlife Habitat. M. Symonds kindly provided advice, B. Eastick sketched the cassowary heads accompanying Fig. 4. The Peter Rawlinson award and the Richard Zann Bursary to D.E. and internal funding from La Trobe University Department of Ecology, Environment and Evolution to D.E., and K.R. and J.L. funded the project.

Author information

Affiliations

  1. Department of Ecology, Environment and Evolution, La Trobe University, Melbourne, Victoria, 3086, Australia

    • Danielle L. Eastick
    • , Simon J. Watson
    • , John A. Lesku
    •  & Kylie A. Robert
  2. Department of Biological Sciences, Brock University, St. Catharines, Ontario, L2S 3A1, Canada

    • Glenn J. Tattersall

Authors

  1. Search for Danielle L. Eastick in:

  2. Search for Glenn J. Tattersall in:

  3. Search for Simon J. Watson in:

  4. Search for John A. Lesku in:

  5. Search for Kylie A. Robert in:

Contributions

Conceived and designed experiment: D.E., J.L. and K.R. Investigation: D.E. Analysis: G.T., D.E. and S.W. Writing-Original draft: D.E. Writing- Review & Editing: D.E., J.L., K.R., G.T. and S.W.

Competing Interests

The authors declare no competing interests.

Corresponding author

Correspondence to Danielle L. Eastick.

Supplementary information

About this article

Publication history

Received

Accepted

Published

Issue Date

DOI

https://doi.org/10.1038/s41598-019-38780-8

Comments

By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.