Caterpillars Larvae feed on the host plant, first consuming the
terminal bud. After they have exhausted the resources of the plant they have hatched on, later
instars may move to another plant.
Adults H. erato is a
pollen-feeding species, collecting from the
Lantana camara flower. They do not spend much time or energy collecting
nectar (only remaining for a few seconds). Instead, they collect pollen in a mass on the ventral side of their
proboscis. They then agitate the pollen by coiling and uncoiling their proboscis in order to release its nutrients.
H. erato is then able to extract
nitrogenous compounds in a clear liquid, including
amino acids like
arginine,
leucine,
lysine,
valine,
proline,
histidine,
isoleucine,
methionine,
phenylalanine,
threonine, and
tryptophan. Females typically carry larger loads of pollen than males as females require more amino acids for egg production.
Co-evolution between Heliconius erato and host plants Previous studies have shown that host plants, such as
Passiflora, have coevolved with
Heliconius butterflies.
Passiflora plants are usually found in low densities with even less plants in fruiting or flower conditions due to caterpillar feeding. To increase chances of survival and cross-pollination,
Passiflora plants synthesize toxins in leaves to deter
Heliconius.
Passiflora species produce different toxins, leading to different preferences for oviposition among
Heliconius species. This leads to a lower chance of herbivore damage for individual
Passiflora species and thus helps protect
Passiflora plants. Chemical composition of toxins in such plants have not been studied widely. Studies have identified cyanogenic glycosides and
alkaloids as potential chemicals that drive distasteful reactions among
Heliconius. Toxin variation among
Passiflora is one of the reasons for host specificity among
Heliconius butterflies. Studies have shown that
H. erato species that feed on specific
Passiflora species tend to spend more time on the host plant and are thus exposed to the toxins for a longer period. Accumulation of toxins such as cyanogenic glycosides leads to a low survival rate among
H. erato larvae. Increasing exposure to parasitoids due to longer time spent on the host plant also contributes to the high mortality rate. One recent study showed that mortality increased among
H. erato larvae which fed on cyanide-releasing
Passiflora. Survived butterflies were capable of excreting higher levels of cyanides, suggesting a defense mechanism in
H. erato.
H. erato species with more mechanisms to detoxify and secrete ingested toxins are the result of genetic differences among
H. erato subspecies. Nectar excretion from
Passiflora has also been studied as one factor which contributes to
coevolution.
Passiflora nectar is known to produce aggressive behaviors among ants, wasps, and egg parasitoids. Ehrlich and Gilbert have estimated that parasitoids are capable of destroying most
Heliconius eggs under nectar influence. Therefore, host plants such as
Passiflora are believed to have self-defense mechanisms that utilize predators against
Heliconius butterflies. == Parental care ==