Loss of functional reduces robustness of 24-hour behavioral rhythms in monarch butterflies.

Light is one of the strongest cues for entrainment of circadian clocks. While some insect species rely only on visual input, others like use both the visual system and the deep-brain blue-light photoreceptor cryptochrome for entraining circadian rhythms. Here, we used the monarch butterfly (), which possesses a light-sensitive (), to test the conservation of mechanisms of clock entrainment.

TRITHORAX-dependent arginine methylation of HSP68 mediates circadian repression by PERIOD in the monarch butterfly.

Transcriptional repression drives feedback loops that are central to the generation of circadian (∼24-h) rhythms. In mammals, circadian repression of circadian locomotor output cycles kaput, and brain and muscle ARNT-like 1 (CLOCK:BMAL1)-mediated transcription is provided by a complex formed by PERIOD (PER) and CRYPTOCHROME (CRY) proteins. PER initiates transcriptional repression by binding CLK:BMAL1, which ultimately results in their removal from DNA.

Cryptochrome 1 mediates light-dependent inclination magnetosensing in monarch butterflies.

Many animals use the Earth's geomagnetic field for orientation and navigation. Yet, the molecular and cellular underpinnings of the magnetic sense remain largely unknown. A biophysical model proposed that magnetoreception can be achieved through quantum effects of magnetically-sensitive radical pairs formed by the photoexcitation of cryptochrome (CRY) proteins.

Monarch Butterfly Migration Moving into the Genetic Era.

The genetic architecture and neurogenetics of animal migration remain poorly understood. With a sequenced genome and the establishment of reverse genetic tools, the monarch butterfly has emerged as a promising model to uncover the genetic basis of migratory behavior and associated traits. Here, we synthesize major advances made in the genetics of monarch migration, which includes the discovery of genomic regions associated with migration and molecular mechanisms underpinning its seasonality.

Photoperiodic and clock regulation of the vitamin A pathway in the brain mediates seasonal responsiveness in the monarch butterfly.

Seasonal adaptation to changes in light:dark regimes (i.e., photoperiod) allows organisms living at temperate latitudes to anticipate environmental changes.