Tierra de Oro Laboratory

Physiology and Ecology in the Pinyon-Juniper Savanna

Tag: oxygen consumption

  • One Project Becomes Two

    After working very hard this winter to submit a manuscript describing the most recent results of the project, I realized that it has really become two non-overlapping lines of inquiry.

    A few weeks ago, I submitted a manuscript titled “Batesian Mimicry and Thermal Resilience Among Tenebrionid Beetles from a New Mexican Piñon-Juniper Savanna” to the Journal of Experimental Biology. The editor said some kind words about it, but ultimately rejected it because it did not fit comfortably into the aims of the journal. The main complaint was that a significant portion of the paper focused on the ecology of the beetles, rather than their physiology.

    It took a few days for me to realize that the paper had evolved into something different. Looking over the title, two things may stand out.

    Batesian Mimicry

    Thermal Resilience

    Those are really two separate concepts and analyzing either one can be performed relatively independently of the other. In other words, this was two incomplete papers rather than one solid story.

    Now begins the process of completing both of those stories.

    Mimicry

    Several lines of evidence address whether the Asidini Philolithus elatus and Stenomorpha rimata are Batesian mimics of the Amphidorine Eleodes obscura. For an organism to be a bona fide Batesian mimic it must

    • Resemble the model in the eyes (or ears or nose) of potential predators.
    • Be palatable
    • Be undefended (or at least to a potential predator)
    • Overlap the model in space and/or time so that predators can learn the association
    • Be relatively uncommon to prevent predators from discovering their mimicry

    The Asidini fulfill these criteria to varying degrees

    • The major argument for mimicry is that the Asidini look a lot like E. obscura, and are about the same size and mass.
    • A close relative of S. rimata, S. marginata, has been shown to be palatable to mice and skunks. Palatability of P. elatus is unknown.

    On the minus side:

    • P. elatus will regurgitate when handled, suggesting at least mild defense
    • Headstanding behavior, which contributes to the mimicry, is weak (P. elatus) or non-existent (S. rimata)
    • Both Asidini are at least as common as E. obscura during peak season, giving predators plenty of opportunity to learn that they are quite edible.
    • Stenomorpha rimata is present in late September and October, when Eleodes have disappeared from the surface, giving predators plenty of time to learn that they are tasty and undefended.

    I really need to know who the local predators are, so that I can make sense of all this. I hope to use the upcoming field season to find out who is eating beetles around here. Based on scats and scattered body parts, someone is eating them, but who?

    Thermal Resilience

    Maintenance of scent glands is costly, so E. obscura should either use more metabolic energy than the undefended P. elatus and S. rimata, or devote less energy to other aspects of fitness. Based on respirometry across a range of temperatures it would appear that all three species use the same amount of energy per unit time, but the Asidini have much higher survival at elevated temperatures.

    This is a nice partial story, but I need to know more about possible mechanisms. Two sets of experiments would be very helpful in completing this part of the story.

    • Testing survival across a full range of temperatures. I have only tested up to 40C, which is semi-lethal to Eleodes but does not strongly affect P. elatus or S. rimata. Although I am no fond of the idea, I need to test up to a temperature that is 100% lethal in order to have a complete picture of thermal resilience.
    • Because temperature induced lethality is associated with disrupted ionic regulation, it will be important to examine concentrations of ions in the hemolymph (blood) of E. obscura, P. elatus and S. rimata at high temperatures.

    If all goes well, I should have two papers ready by the end of the season. Wish me luck.

  • Desert vs Jungle

    A little bit of physiology to start off the summer.

    We are gearing up to complete the data sets for local beetles this fall. Ultimately, we’ll be comparing metabolism of two Eleodes species, E. obscura and E. longicollis, with those of a few mimics, Philolithus elatus and Stenomorpha marginata. The data from last fall were very interesting, but after drafting the manuscript it was clear that another season of data would help to clarify the results.

    Because of seasonal availability, comparing Eleodes with their mimics will have to wait until late summer and early fall. Eleodes longicollis is common all summer, but E. obscura becomes much more common in July. Philolithus elatus and S. marginatus will not appear until the end of July at the earliest.

    In the meantime, there were a couple of other species available in the lab that will help in understanding the data from Eleodes, Philolithus, and Stenomorpha.

    Zophobas morio. Yellow paint on right elytra is for individual identification.

    Zophobas morio, also known as the “superworm,” is originally from the American tropics. It is widely cultured as a food for pets and is being considered as a source of protein for humans. A colony was established in the lab in early 2024, so they are available for experiments any time. Being from the neotropics, with consistently warm and relatively wet conditions, they are expected to respond more strongly to temperature changes.

    Bluish-black beetle with rough thorax and elytra.
    Asbolus verrucosus, the blue death-feigning beetle.

    Asbolus verrucosus, called the blue death-feigning beetle because of its tendency to play dead when handled, is a long-lived species from the hot, dry deserts of southwestern North America. We received a cohort from Bugs in Cyberspace in January, and they have spent the past few months adjusting to handling and conditions in the lab. Their adaptations to extreme conditions suggest that they will be tolerant of high temperatures.

    Oxygen consumption was measured for the two species from 15°C, at which beetles should be slow and sluggish, to 40°C, just below the lethal temperature for a close relative of A. verrucosus (Cryptoglossa muricata; Ahearn, 1970). Therefore the temperature range may cause cold stress at at the low end and heat stress on the high end, but was not expected to be lethal.

    The two species are just about the same size and mass, with each being somewhat over half a gram. Twelve beetles of each species were tested at each temperature, although technical issues reduced this to eleven in a few cases. The respirometer could handle eight beetles at a time, so four of each species were tested together each day, and each temperature required three days of experiments.

    Oxygen consumption of Z. morio and A. verrucosus between 15°C and 40°C. Each point shows the mean and standard error of 11-12 beetles, with most error bars smaller than the symbols. At each temperature above 15°C, Z. morio consumed more O2 than A. verrucosus. At 40°C, all Z. morio were visibly impaired immediately after experiments, and 8/12 were dead within two days. None of the 12 A. verrucosus showed any signs of stress after 40C experiments, and all survived indefinitely (one week so far) after being returned to their enclosure.

    At 15°C, O2 consumption was identical for the two species. At every other temperature, Z. morio consumed significantly more O2 than A verrucosus. This may reflect a lower standard metabolic rate for the desert species, which is adapted to an environment with limited resources. Neither species showed any sign of stress at either 25°C or 35°C, in that both emerged from experiments active and coordinated, and none died in the three days between experiments.

    The two species diverged further at 40°C, with Z. morio dramatically increasing their O2 consumption (note the log10 scale), while O2 consumption in A. verrucosus increased only slightly. Importantly, all Z. morio were visibly impaired at the end of 40°C experiments, showing slow, uncoordinated movement or no movement at all. Eight of twelve Z. morio were dead within two days. In contrast, none of the A. verrucosus tested at 40°C appeared to be stressed, and all survived indefinitely.

    It is perhaps not surprising that Z. morio, a species originating from a relatively constant, resource rich environment, has a higher metabolic rate and is more sensitive to environmental temperature than the desert beetle, A. verrucosus. The dramatic increase in O2 consumption and lethality between 35°C and 40°C for Z. morio was quite striking, however. The lethality-associated increase in metabolic rate resembles that in the fruit fly, Drosphila melanogaster at 35°C (Sandstrom et al., unpublished), and indicates that a dramatic increase in O2 consumption may be a common indicator of severe heat stress in insects.

    There are a few possible caveats. For example, although the two species have been kept under the same conditions for at least four months, which should be enough to reduce the effects of previous physiological adaptations, their life histories as larvae and pupae were different. Z. morio have been reared for multiple generations at the lab, while A. verrucosus were collected from the wild, which may somehow influence their responses to temperature. Asbolus and their relatives can be reared in captivity (Rider, 2024), so it may be worth repeating the experiment with lab-reared beetles.

    References

    Ahearn, G. A. (1970a). Changes in hemolymph properties accompanying heat death in the desert tenebrionid beetle Centrioptera muricata. Comparative Biochemistry and Physiology 33, 845–857.

    Rider, S (2024) Death Feigning Beetles of the United States and Mexico. Publisher S. Rider Jr. 182 pp.