The life cycle of
M. debilis is one of the most complicated life cycles among beetles because it involves
viviparity,
hypermetamorphosis,
parthenogenesis, and paedogenesis. The life cycle is also highly unusual because the larvae rarely mature into adults in both sexes. Haplodiploidy is another notable feature of this species, shared with only a few other species of Coleoptera; haploid males are hatched from eggs within the mother's body via haploid parthenogenesis, and diploid females are birthed live via diploid parthenogenesis.
Females Upon being birthed live, the larva emerges as a minute white creature with long, slender legs that resemble the carabid type. This stage is primarily focused on migration, with the young larvae crawling away from the location of their birth to find new areas within their habitat. During this phase, they may consume the remains of their mother before migration. After a period of wandering, the larvae begin to burrow into wood or other suitable substrates again. They feed minimally during this time and undergo their first molt, transforming into a legless form that resembles the larva of
cerambycid beetles. This stage is characterized by the development of an inconspicuous anal armature. Additional molts occur in this form, likely to accommodate head growth and overall body development. The larvae continue to bore through wood, packing their galleries with dust as they progress. The color of their bodies may darken due to the accumulation of food in their
alimentary tract. As the larvae near maturity, the eggs in the ovaries of what will become the paedogenetic form become visible. At this stage, the larvae reverse their position in the gallery, construct a cell, and enter an
aestivation phase. During aestivation, their bodies gradually turn white as they consume all available food in their system. Paedogenesis is the process by which larvae reproduce by giving birth to more larvae without the production of adults and is a process exclusive to females. Once the paedogenetic form emerges, it typically takes around two weeks for the new generation to be born. The young larvae are born tail-first and begin the cycle anew, continuing the species' life cycle.
Males Male larvae are hatched from a single, large egg that adheres to the male-producing larva's body for 8–10 days. The larvae feed on the mother's body and will grow rapidly. The male rarely
pupates and transforms into the
imago, and will often die as a larva. While male adults only develop from
uni-oviparous paedogenetic females, adult females only develop from
cerambycoid paedogenetic females.
Larval sex ratio In naturally occurring paedogenetic larvae, the sex ratio is strongly biased toward females. None of the three canonical explanations for biased sex ratios, local mate competition, local resource competition, and local resource enhancement, are likely explanations for the biased sex ratio in telephone-pole beetle larvae. Local mate competition selects for female-biased sex ratios when male siblings compete to fertilize their female siblings, but this is unlikely in this species which females tend to avoid mating with siblings. Local resource competition selects for biased sex ratios but typically involves competition between females for resources and thus selects for male-biased ratios. Lastly, local resource enhancement can select for biased sex ratios if the offspring of one sex increases the fitness of parents. However, because female offspring feed on the mother, there is more likely competition between female larvae, contradicting this explanation. As such, the cause of sex ratio deviation remains unclear.
Adulthood Adult telephone-pole beetles are unable to copulate, and adult females do not have the physiological mechanisms to reproduce because they are unable to lay eggs or produce live progeny, either sexually or by parthenogenesis. Limited observations and experiments on
M. debilis have resulted in conflicting observational conclusions, particularly regarding the beetle's reproduction, in the existing literature. Pollock & Normack reported the existence of reproductive adult males, but this was based on the incorrect conclusions by Barber. However, all existing experimental literature states that adults are sterile. Since adults do not have a role in reproduction, they are not a physiological part of the life cycle. Thus, the rarity of adult development in the natural world may be an evolutionary response to the lack of their reproductive role. In laboratory settings, development into adults can be induced by high temperatures, but this also results in high mortality because only one out of hundreds of heat-treated larvae will survive and pupate into an adult. The adult females live for about six days and males only live for around 12 hours, with a strongly biased
sex ratio towards females. The adults of both sexes are sterile and are
vestigial remnants of a time when the life cycle involved
sexual reproduction. The loss of sexual reproduction is likely associated with its infection by
Wolbachia bacteria. == Mating behavior ==