Cyana Moths: The Case of the Curious Cocoon

Photo Story Published : Mar 04, 2022 Updated : Aug 29, 2022
The uncommon survival strategies of these lichen-feeding moths include developing a fascinating cage-like cocoon for metamorphosis
Cyana Moths: The Case of the Curious Cocoon Cyana Moths: The Case of the Curious Cocoon
The uncommon survival strategies of these lichen-feeding moths include developing a fascinating cage-like cocoon for metamorphosis

Globally there are about 3,000 species of lichen-feeding moths. They are from the tribe Lithosiini, which belongs to a larger group of moths called “tiger moths”. Their larvae are lichenivores, i.e. they feed on lichens found on tree trunks.

The bright colouration in adults is “aposematic”— a warning sign to predators that the moth is toxic. It is unpalatable to many potential predators due to toxins ingested and metabolised at the larval stage and retained through metamorphosis into adulthood. These moths have some interesting sensory abilities, both as caterpillars and adults. Like typical adult tiger moths, they have “ears” located on their thorax. They also make a variety of ultrasonic sounds with the tymbal organs on their thorax, which insectivorous bats, the most formidable of moth predators, can pick up. These click sounds warn bats that the moth is unpleasant to eat while also jamming the bats’ sonar system. These moths have it all!

Cyana is a lichen-feeding moth genus with a geographic range that spans Africa, East and Southeast Asia, and Australasia. There are about 176 species in Asia, with about 36 in India. These moths have distinct red-bordered white wings with black spots, though the forewing pattern varies with species. They have three discrete life-history stages. The egg hatches into a larva, which feeds, moults, and grows larger, and then pupates (pupal stage) and emerges as an adult that looks quite different from the larva. These insects are “holometabolous”, meaning they undergo a complete metamorphosis or change. Insects that undergo complete metamorphosis not only have a physical transformation, but their diet, survival instincts, and dependency on different senses also change. The peculiar process of metamorphosis by which animals undergo physical transformation after birth has bewildered us for ages, feeding myths and mysticism. Cyana moths exhibit a fascinating metamorphosis process that is unlike any other insect.

Cyana moths have evolved a particularly interesting type of cocoon for their metamorphosis. It’s a cage-like structure, constructed with recycled setal hairs, within which they suspend themselves — it’s a hammock of spiny hairs spun together with silk. The oval-shaped structure is a crisscross of strands of hair that converge at two points, one of which serves as the exit for the adult that emerges. Although the pupal stage appears to be a resting phase, it is the most active phase of the lifecycle where many changes occur under cover.
This particular cocoon design ensures that the pupa undergoes developmental changes in direct contact with the ambient conditions; there is no cover layer, unlike most other lepidopteran cocoons. As a result, the cocoons are oriented in a particular direction to maximise their thermoregulation (managing of body temperature). In a paper published in the journal Oriental Insects in 2016, Timothy C. Hawes states that in tropical regions Cyana cocoons are north-facing, which reduces the impact of solar radiation during the hottest part of the day.
It seems unreal that a cryptic caterpillar chewing on leaves turns into a winged adult with beautiful patterns. Ultimately, the impetus for undergoing radical transformations is survival. Each stage of the lifecycle has defence strategies to fend off predators. The pupal cage is surprisingly tough and strong enough to deter most birds and parasitoid wasps. Unfortunately, some predators do break through these defences. Crematogaster ants, for instance, are known to invade developing pupae (top), while weaver ants, one of the most prolific predators (above), can gobble up entire adult bodies. 

In the world of insect metamorphosis, countless strategies exist to enable insects to colonise every corner and diversify to vast numbers. Evolutionarily, the process of metamorphosis prospered because young and adults of the same insect species occupied different ecological spaces and did not compete for the same resources. The niches they occupy are small. Undergoing metamorphosis, they can further divide their environment into smaller parts. At each stage, they occupy a different habitat and become specialised in it. They rule the world by their sheer numbers and strategies of adaptation. As rightly portrayed by the renowned biologist EO Wilson, invertebrates (mostly insects) are the “little things that run the world”. 


About the contributors

Pritha Dey

Pritha Dey

is a moth-biologist, a post-doctoral fellow at the Centre for Ecological Sciences, IISc, Bangalore. When not looking for moths, she indulges in coffee, writing, graphic novels, baking, and painting.
Ripan Biswas

Ripan Biswas

is an award-winning nature photographer from Coochbehar, West Bengal, with a keen interest in macro fauna.

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