Papilio glaucus
Papilio glaucus, commonly known as the eastern tiger swallowtail, is a large species of swallowtail butterfly in the family Papilionidae, native to eastern North America and characterized by its vibrant yellow wings marked with bold black stripes, a wingspan of 7.9 to 14.0 cm, and sexual dimorphism where some females exhibit a dark morph mimicking toxic species for protection.[1][2][3] This butterfly is widely distributed from southern Ontario and New England in the north, extending south to the Gulf Coast states of Texas and Florida, and west to the Great Plains, primarily east of the Rocky Mountains, with occasional records in northern Mexico.[1][2] It inhabits a variety of environments, including deciduous woodlands, riverine areas, swamps, suburban gardens, and urban settings, where it is often most abundant near water sources like streams and wooded wetlands.[2][3] The species is polyphagous in its larval stage, with caterpillars feeding on foliage from diverse host plants such as tulip trees (Liriodendron tulipifera), wild black cherry (Prunus serotina), sweet bay magnolia (Magnolia virginiana), birches, willows, and ashes, contributing to its adaptability across ecosystems.[1][3][4] The life cycle of P. glaucus includes four stages: eggs laid singly on host plants, larvae that mimic bird droppings in early instars before developing green coloration with false eyespots for defense, pupae that overwinter in a chrysalis, and adults that emerge in two to three broods annually depending on latitude, with northern populations having two broods and southern ones up to three from late February onward.[1][3] Adults are significant pollinators, feeding on nectar from a broad array of native and introduced flowers while exhibiting behaviors like territorial patrolling by males and high-altitude flight.[3][2] Noted for its cultural and ecological prominence, P. glaucus serves as the state butterfly for Alabama, Delaware, Georgia, North Carolina, and South Carolina, and while it hybridizes with the closely related Canadian tiger swallowtail (Papilio canadensis) in overlapping northern ranges, a February 2025 study described a cryptic new species, Papilio solstitius (midsummer tiger swallowtail), previously misidentified as such hybrids; it faces no major conservation threats from human activities.[3][1][2][5]Taxonomy and Classification
Etymology and History
Papilio glaucus was first described by the Swedish naturalist Carl Linnaeus in the 10th edition of Systema Naturae in 1758, where it was classified under the genus Papilio based on specimens exhibiting yellow wings with black markings. This description marked the formal establishment of the species in binomial nomenclature, drawing from earlier European collections of North American butterflies.[6] The genus name Papilio derives from the Latin word for "butterfly," reflecting Linnaeus's broad grouping of swallowtails and related lepidopterans under this term.[1] The specific epithet glaucus originates from the Greek glaukos, meaning bluish-gray or silvery, alluding to the subtle bluish iridescence observed on the wings, particularly in certain light or on the tails of males. Early taxonomic history involved confusion with the closely related Papilio canadensis, which was initially regarded as a subspecies of P. glaucus due to morphological similarities in northern populations, such as reduced black markings in cooler climates.[1] This classification persisted into the 20th century until genetic and morphological studies elevated P. canadensis to full species status in 1991.[7] A significant development occurred in 1777 when Giovanni Antonio Scopoli introduced the subgenus Pterourus within Papilio to accommodate species like P. glaucus characterized by elongated tails and specific wing venation patterns, as detailed in his Introductio ad historiam naturalem. This subgeneric placement has influenced subsequent revisions, though debates on its rank continue in modern phylogenetics.[8]Phylogenetic Relationships
Papilio glaucus is classified within the subgenus Pterourus (Scopoli, 1777) of the genus Papilio, which encompasses a group of primarily New World swallowtail butterflies characterized by their distinctive tail-like extensions on the hindwings.[5] This subgeneric placement reflects shared morphological and genetic features that distinguish Pterourus from other subgenera in Papilio, such as the Old World Papilio sensu stricto.[9] The species maintains close phylogenetic ties to Papilio canadensis (Canadian tiger swallowtail) and Papilio appalachiensis (Appalachian tiger swallowtail), with which it was historically considered conspecific until taxonomic revisions in the late 20th century separated them based on ecological and morphological distinctions.[10] Molecular phylogenies, including DNA barcoding analyses, reveal minimal genetic divergence among these taxa, with identical COI barcode sequences (BOLD:AAA6909) indicating recent speciation events driven by hybridization and geographic isolation.[11] Genome-wide studies estimate the divergence between P. glaucus and P. canadensis at approximately 0.6 million years ago, while P. appalachiensis emerged as a homoploid hybrid around 0.4 million years ago from ancestral crosses between the two.[5] As part of the broader New World clade within Papilionidae, P. glaucus exemplifies basal traits of the swallowtails, including the elongated hindwing tails that aid in predator evasion and mate signaling, a feature conserved across the subgenus Pterourus.[5] These relationships underscore the role of Pleistocene climate fluctuations in shaping the evolutionary history of North American tiger swallowtails through range shifts and secondary contact.Subspecies and Recent Changes
Papilio glaucus has two recognized subspecies as of 2025: the nominate subspecies P. g. glaucus Linnaeus, 1758, which is widespread across the eastern United States, and P. g. maynardi Gauthier, 1984, restricted to the Florida Keys region.[12][13] The species exhibits notable intraspecific variation, particularly in the frequency of female color morphs across its range. Females display a sexual dimorphism with light (yellow) and dark (melanic) forms, the latter mimicking distasteful Battus philenor (pipevine swallowtail) as Batesian mimicry. The proportion of dark-morph females increases southward, reaching up to 80-90% in southern populations such as those in Florida and Texas, compared to less than 10% in northern areas near the Great Lakes.[14][6] A significant taxonomic revision occurred in 2025 with the description of Papilio solstitius as a new cryptic species, elevated from what were previously considered hybrid populations between P. glaucus and P. canadensis. This split, detailed in DeRoller et al., was based on integrated analyses of morphology, genetics, and phenology, revealing P. solstitius as a distinct homoploid hybrid origin entity within the P. glaucus species group.[5] The new species is characterized by delayed post-diapause development, leading to allochronic isolation with midsummer adult emergence (late June to early July), contrasting the earlier flights of P. glaucus and P. canadensis.[5] As a result of this revision, the range of P. glaucus is now more narrowly defined, encompassing primarily southern and eastern United States populations south of the hybrid zone, while northern hybrid-like forms are reassigned to P. solstitius. This excludes former hybrid mosaics from the core definition of P. glaucus, refining its taxonomic boundaries within the broader Pterourus subgenus clade. Morphologically, P. glaucus individuals display more consistent yellow wing patterns with reduced mosaicism, whereas P. solstitius exhibits greater variability, including intermediate and unique traits in both sexes.[5][15]Physical Description
Adult Features
The adult Papilio glaucus, commonly known as the eastern tiger swallowtail, displays a wingspan of 7.9 to 14 cm, making it one of the larger butterflies in its range.[1] The forewings are predominantly yellow with four prominent black bands that mimic tiger stripes, bordered by a marginal row of yellow spots, while the hindwings exhibit black margins and tail-like extensions characteristic of the Papilionidae family.[1][16] The undersides of the wings feature iridescent blue scaling, particularly on the hindwings, along with powdery-blue areas and occasional red spots near the tails in certain individuals.[3][1] The body is robust, with the thorax and abdomen covered in scales displaying black and yellow patterning that aligns with the wing coloration.[2] The antennae are clubbed at the tips, a diagnostic trait of butterflies in the order Lepidoptera.[17] Females typically exhibit a larger body size compared to males, though detailed sexual dimorphism is addressed separately.[2]Sexual Dimorphism and Variation
Papilio glaucus exhibits pronounced sexual dimorphism, particularly in wing coloration and patterning. Males are monomorphic, displaying a uniform yellow ground color with prominent black tiger-like stripes across the forewings and a broad black border along the wing margins, accented by yellow spots.[1] This yellow form lacks any dark melanic variant, making males visually distinct from the polymorphic females.[18] In contrast, females are dimorphic, with one form resembling the males in yellow coloration and black striping, while the other is a dark melanic morph characterized by predominantly black wings with subtle obscured stripes and a striking blue iridescence on the hindwings, particularly near the margins and tails.[19] The dark morph serves as a Batesian mimic, but its occurrence is limited to females.[20] The frequency of this dark female morph has varied historically, reaching over 20% in certain populations in the mid-20th century and up to 90% in some northern areas during the 1950s-1980s, but has declined significantly across the range since the late 1990s (as of 2018), with many populations now below 30%, potentially due to climate warming.[21][14] Geographic variation in the prevalence of the dark morph is notable, with frequencies historically increasing southward across the species' range, from low levels in northern populations to higher proportions in southern areas such as Florida and Georgia, potentially influenced by regional mimicry pressures.[22]Distribution and Habitat
Geographic Range
Papilio glaucus, the eastern tiger swallowtail, is native to eastern North America, with its core distribution—following 2025 taxonomic revisions—spanning from southwestern Ontario, areas south of the Adirondack and Catskill Mountains in New York, and southern New England southward to Florida and westward to Texas and the eastern Dakotas.[23][1][5][24] This range encompasses a broad latitudinal gradient across deciduous forests, woodlands, and riverine habitats east of the Rocky Mountains.[25] The species' presence in these regions has been documented consistently through field observations and citizen science platforms, confirming its widespread occurrence within this delimited area. The 2025 taxonomic revisions refined the geographic range of P. glaucus by excluding northern populations previously included under its broader complex and attributing them to Papilio canadensis (the Canadian tiger swallowtail) and the newly described cryptic species Papilio solstitius—formerly treated as hybrids between P. glaucus and P. canadensis.[5][15][24][26] This adjustment emphasizes P. glaucus' distinction from the boreal and transitional zones, with P. solstitius occupying intermediate areas across the Great Lakes and Appalachian regions such as eastern and south-central Ontario, northern and central New York, Vermont, New Hampshire, and Pennsylvania. The revised boundaries better reflect genetic and phenological differences.[5][24] In recent decades, P. glaucus has shown adaptability by expanding into urban and suburban environments within its range, where nectar sources from ornamental plants support adult populations.[27] Occasional vagrants have been reported west of the Rocky Mountains, including sightings in Colorado and other western states, likely facilitated by wind dispersal or human-assisted transport.[25][28] Historically, the species' range has remained relatively stable since its original description by Linnaeus in 1758, though minor contractions have occurred in localized areas due to deforestation and habitat fragmentation.[29] These changes have been most pronounced in regions with intensive agricultural expansion, yet overall distribution persists without major shifts.[30]Ecological Preferences
Papilio glaucus, the eastern tiger swallowtail, primarily inhabits deciduous woodlands, forest edges, riverine corridors, and suburban gardens across its range. These environments provide the open, sunlit conditions essential for adult activity and the understory vegetation necessary for larval development. The species is less common in dense coniferous forests, favoring instead mixed or purely deciduous settings where light penetration supports its ecological needs.[31][2] This butterfly occurs from sea level up to approximately 1,500 meters in elevation, with populations concentrated in lowland and mid-elevation areas of the eastern United States and adjacent Canada. Proximity to water sources, such as streams, rivers, and swamps, is a key preference, facilitating adult puddling behavior for mineral intake. Microhabitats featuring sunny openings amid woodland edges or clearings are particularly favored, allowing adults to bask and regulate body temperature effectively while maintaining access to understory host plants.[2][32][33] P. glaucus demonstrates notable adaptability to human-altered landscapes, thriving in urban parks, orchards, and residential gardens where deciduous trees and flowering plants persist. This versatility enables the species to persist in fragmented habitats, including suburban developments and agricultural edges, as long as suitable microhabitats with sunlight and moisture are available. Such adaptability contributes to its widespread occurrence beyond pristine forests.[31][3]Life Cycle
Egg Stage
The eggs of Papilio glaucus are spherical and green, typically measuring about 1 mm in diameter.[34] They are laid singly on the upper surface of host plant leaves, with females showing a preference for young, dark green leaves over mature ones to optimize larval survival and growth.[1] A single female deposits up to 250 eggs over her adult lifespan of 2–4 weeks, often selecting sites near nectar sources to support post-oviposition foraging.[35] The incubation period lasts 4–10 days until hatching, varying with environmental temperature; warmer conditions accelerate development, while cooler temperatures prolong it.[36][37] Newly hatched larvae typically consume the eggshell before transitioning to leaf feeding on the host plant.[1]Larval Stage
The larvae of Papilio glaucus, known as caterpillars, undergo five distinct instars during their development, marking progressive stages of growth separated by molts. In the first three instars, the caterpillars are small, typically measuring less than 1 cm, and exhibit a dark brown or black coloration with a white or pale saddle-like marking on the dorsum, effectively mimicking bird droppings to evade predators through camouflage. By the fourth and fifth instars, they transform into larger, bright green forms with a swollen thoracic region, faint blue spots along the abdominal segments, and prominent yellow eyespots outlined in black and blue on the metathorax, which resemble the head of a snake to deter potential threats. Fully mature fifth-instar larvae reach up to 5.5–6.4 cm in length.[1] A key defensive adaptation in P. glaucus larvae across instars is the osmeterium, an eversible, orange, forked gland located behind the head that can be extruded when the caterpillar is disturbed, releasing a foul-smelling chemical secretion to repel predators such as birds and ants. Early instars rely more heavily on passive mimicry for protection, while later instars combine this with active osmeterial defense, enhancing survival in exposed feeding positions on host foliage. These strategies contribute to the larvae's ability to avoid predation during vulnerable growth phases.[33][1] The entire larval stage spans 3 to 4 weeks under typical summer conditions, during which the caterpillars molt approximately every 4 to 6 days to accommodate rapid growth fueled by leaf consumption. As solitary feeders, P. glaucus larvae generally avoid conspecific interactions, with cannibalism being rare due to their dispersed distribution on host plants and non-aggressive behavior. This solitary habit minimizes competition and disease transmission within broods.[38][3]Pupal Stage
The pupal stage of Papilio glaucus begins when the mature larva selects a pupation site, typically attaching itself to the underside of a twig, stem, or dead leaf using a silk pad and cremaster, secured by a silk girdle around the thorax. The resulting chrysalis measures approximately 3 cm in length and features cryptic coloration, often tan or brown with a dark-brown or black lateral stripe and a dorsal band, enabling it to blend seamlessly with bark, foliage, or leaf litter. This camouflage is crucial during the immobile pupal phase, significantly reducing visibility to predators such as birds and insects.[39][40] In northern regions of its range, the chrysalis enters diapause, a dormancy state induced by short photoperiods experienced by late-summer larvae, allowing it to overwinter for up to 9 months until spring conditions resume development. Southern populations, benefiting from milder climates, produce non-diapausing pupae that complete metamorphosis in 9–11 days. Emergence from the chrysalis is triggered by environmental cues, primarily lengthening photoperiods and rising temperatures, which signal the end of diapause and initiate adult eclosion.[41][1][42] This stage represents a vulnerable period in the life cycle, where the cryptic morphology and strategic site selection minimize predation risks, ensuring higher survival rates for the developing adult.[39]Adult Emergence and Lifespan
The adult Papilio glaucus emerges from the pupal stage through a process known as eclosion, which typically occurs in the morning hours.[43] This timing allows the newly emerged butterfly to benefit from daylight for the subsequent wing expansion. Upon splitting the pupal case, the adult's wings are initially soft, crumpled, and much smaller than their final size. The butterfly then pumps hemolymph (insect blood) into the veins of its wings, causing them to expand and gradually harden over a period of 1 to 2 hours.[44][45] Once fully expanded and dry, the adult P. glaucus begins its brief lifespan, which generally lasts 1 to 2 weeks under natural conditions.[46] This duration can vary slightly based on environmental factors such as weather and predation, with some individuals surviving up to 14 days.[38] The species exhibits voltinism that varies geographically, being primarily bivoltine (two generations per year) in northern regions and multivoltine (three to four generations) in southern areas like Florida.[1][47] These multiple broods enable the population to exploit seasonal resources effectively across its range. As adults age toward the end of their lifespan, signs of senescence become evident, including fading of wing colors due to the gradual loss of scales and reduced overall activity levels in the final days.[48] This wear not only alters the visual appearance but also reflects physiological decline, contributing to decreased mobility and increased vulnerability to environmental stresses.[49]Behavior and Ecology
Feeding and Foraging
Adult Papilio glaucus butterflies primarily feed on nectar from a wide variety of flowering plants, serving as important pollinators in their habitats. Common nectar sources include species from the Apocynaceae family such as milkweed (Asclepias spp.), the Asteraceae family like goldenrod (Solidago spp.) and ironweed (Vernonia spp.), and the Fabaceae family including clover (Trifolium spp.).[23][1][50] Observations in natural settings document P. glaucus nectaring on at least 17 plant species, highlighting their opportunistic foraging on both native and introduced blooms.[50] In addition to nectar, males frequently engage in puddling behavior, aggregating at moist soil, mud, or dung to extract essential nutrients like sodium ions and amino acids, which are scarce in floral nectar.[51][33] This behavior is stimulated by low concentrations of sodium salts (around 10^{-3} M), and males participate more often than females, potentially to support increased flight activity and reproductive success.[51][52] Foraging in P. glaucus is diurnal, with adults actively visiting flowers during daylight hours, often flying at treetop levels before descending to feed.[1] They use a coiled proboscis that uncoils to access nectar deep within corollas, enabling efficient extraction from diverse flower morphologies.[3] Typical foraging bouts involve sequential visits to multiple flowers within a patch, optimizing energy intake while minimizing travel.[53]Mating and Reproduction
Males of Papilio glaucus primarily locate mates through territorial patrolling, flying along forest edges or at treetop levels before descending to pursue females visually.[1] This behavior facilitates interception of receptive females, with courtship involving close-range displays and pheromone release from male hairpencils to elicit female acceptance.[54] Hill-topping, where males aggregate at elevated sites to await females, occurs occasionally but is rare compared to patrolling in this species.[55] Female mate selection in P. glaucus favors larger males, as body size correlates with spermatophore mass and overall virility, providing potential nutritional benefits to females via nuptial gifts.[56] Dark-morph females, which mimic distasteful pipevine swallowtails (Battus philenor), experience similar mating success rates to yellow-morph females, with no strong evidence of male preference influencing morph maintenance.[57] Copulation typically lasts 30–60 minutes, during which the male transfers a spermatophore containing sperm and nutrients to the female's reproductive tract.[58] This transfer ensures fertilization, though incomplete matings under 30 minutes often fail to do so.[58] Females exhibit high fecundity, producing 200–400 eggs over their lifespan, with polyandry occurring occasionally to replenish spermatophore resources and enhance egg viability.[59] Multiple matings do not significantly increase total egg output but can improve fertilization rates in subsequent clutches.[14]Movement and Migration
Papilio glaucus adults possess strong, gliding flight capabilities that enable efficient locomotion over varied terrains, often observed in groups ascending to heights of 50 meters or more. This flight style is characterized by graceful, somewhat leisurely movements, with typical speeds ranging from 8 to 19 km/h, though bursts can reach higher velocities during pursuits.[2][44][60] Males frequently employ this flight for territorial defense, aggressively chasing away intruders from nectar sources or perching sites to secure mating opportunities. Such behaviors contribute to local population dynamics without involving long-distance travel. Unlike migratory species such as the monarch butterfly, P. glaucus does not undertake true seasonal migrations, but individuals exhibit dispersal from emergence sites, with evidence of movements spanning tens to hundreds of kilometers facilitated by weather events like storm fronts.[61] In southern populations, adults show local shifts in response to resource availability and weather. Orientation during these movements likely relies on celestial cues, including sun-compass navigation, as inferred from broader lepidopteran studies and genomic associations in related Papilio species. Habitat connectivity, such as forested corridors, supports these dispersal patterns by facilitating unimpeded flight.[62]Defense Mechanisms
Mimicry Strategies
The eastern tiger swallowtail, Papilio glaucus, employs Batesian mimicry as a primary visual defense mechanism, particularly through a dark morph exhibited exclusively by females. This melanic form features predominantly black wings with an iridescent blue sheen on the dorsal surface, closely resembling the toxic pipevine swallowtail, Battus philenor, which sequesters aristolochic acids from its host plants, rendering it unpalatable to predators.[63][22] In Batesian mimicry, the non-toxic P. glaucus benefits from reduced predation by exploiting the learned avoidance of the model species by avian predators, as the similarity deceives birds into treating the mimic as equally distasteful.[64] This strategy is female-limited, contrasting with the yellow-and-black wing pattern of males and non-mimetic females, which aligns with broader sexual dimorphism in the species.[22] The effectiveness of this mimicry is geographically correlated with the distribution and abundance of the model B. philenor, which is more prevalent in the southern United States. Frequencies of the dark morph in P. glaucus females were historically higher in southern regions, reaching 20-30% or more in central and southern Florida during the 1960s-1980s, compared to less than 10% at northern range edges like Massachusetts or Minnesota; however, frequencies have declined across the range over the past two decades, with southern populations now at 7-24% as of 2017.[21][22][14] This clinal variation supports the hypothesis that selective pressure from co-occurrence with the model drives mimicry rates, as greater model abundance reinforces predator aversion and enhances the survival advantage for mimics. Avian predation experiments provide direct evidence for the protective value of this mimicry. In controlled trials using blue jays as predators, the dark morph P. glaucus females experienced significantly fewer attacks after birds were conditioned to avoid B. philenor models, with attack rates on mimics dropping to near zero in subsequent presentations, demonstrating the survival benefit of phenotypic resemblance.[64] Field observations further corroborate that mimetic forms suffer lower predation in areas with abundant models, underscoring the adaptive role of Batesian mimicry in P. glaucus ecology.Physical and Behavioral Defenses
The larvae of Papilio glaucus employ the osmeterium, an eversible Y-shaped gland located behind the head, as a primary chemical defense mechanism against predators such as ants and birds.[65] When disturbed, the gland is everted by hemolymph pressure, releasing volatile organic compounds that produce a foul odor to deter attackers. In early instars, the secretion is dominated by approximately 50 terpene compounds, such as δ-elemene, which effectively repel ants in laboratory assays by reducing their approach and contact time.[65] By the fifth instar, the chemistry shifts to aliphatic acids like 2-methylbutyric and isobutyric acids, enhancing unpalatability to vertebrate predators such as lizards, though field experiments indicate only marginal survival benefits against birds.[65] Genetic variation influences terpene profiles more than diet, with parental lineage accounting for significant differences in compound quantities across instars.[65] Early-instar larvae also utilize physical camouflage by mimicking bird droppings through a brown-and-white coloration and compact body shape, which reduces predation risk from visually oriented predators during their vulnerable small size.[66] This masquerade is particularly effective on host plant foliage, where the larvae remain motionless to avoid detection.[66] As larvae mature into later instars, they transition to green crypsis, blending with leaf backgrounds, and develop large false eyespots on the thorax resembling a snake's eyes to intimidate or deflect predators.[66][1] Pupae exhibit similar adaptive camouflage, with green or brown forms matching surrounding foliage or bark to evade detection during the immobile stage; the choice of color is influenced by pupation site and environmental cues.[66] Adult P. glaucus rely on behavioral defenses, including rapid and erratic flight patterns that make pursuit difficult for predators like birds. When disturbed, adults abruptly ascend and dart through vegetation in unpredictable zigzags, leveraging their strong thoracic musculature for quick evasion. Throughout the larval stage, P. glaucus acquires mild chemical deterrence by sequestering and processing plant secondary metabolites from host species, such as cyanogenic glycosides from Prunus trees and sesquiterpene lactones like parthenolide from Liriodendron tulipifera. These compounds impart low-level toxicity or unpalatability, deterring generalist predators without rendering the larvae strongly aposematic. Larvae metabolize parthenolide into less reactive forms, such as 2-α-hydroxydihydroparthenolide, via reduction and hydroxylation, while excreting unmetabolized portions to minimize internal accumulation. This sequestration provides subtle protection, complementing other defenses across life stages.[67][68]Host Plants and Interactions
Primary Host Species
The Eastern Tiger Swallowtail (Papilio glaucus) is a polyphagous species whose larvae feed on multiple plant families, but females exhibit preferences for certain primary host species during oviposition, influenced by regional availability and chemical cues from the plants. Across much of its range in eastern North America, the tulip tree (Liriodendron tulipifera, Magnoliaceae) is frequently cited as a preferred primary host, particularly in deciduous forests where it is abundant, providing tender leaves suitable for larval feeding.[3][33] Similarly, wild black cherry (Prunus serotina, Rosaceae) serves as a key primary host in upland and woodland habitats, valued for its nutritional content that supports rapid larval growth through multiple instars.[3][69] In southern regions, such as peninsular Florida, sweet bay magnolia (Magnolia virginiana, Magnoliaceae) emerges as the dominant primary host, especially in wetland and coastal areas, where it is often the sole species used due to its prevalence and palatability; larvae consume the leaves, avoiding tougher parts, and pupate nearby in leaf litter.[1] Other notable primary hosts include species of ash (Fraxinus spp., Oleaceae), such as white ash (F. americana) and pop ash (F. caroliniana), which are favored in northern and central parts of the range for their widespread distribution and acceptance by ovipositing females.[1][69] These preferences reflect adaptations to local ecology, with females selecting hosts based on volatile compounds that signal suitability for offspring survival.[70]| Primary Host Species | Plant Family | Regional Preference | Notes on Larval Use |
|---|---|---|---|
| Tulip tree (Liriodendron tulipifera) | Magnoliaceae | Widespread, especially northern and central range | Leaves eaten from early instars; high nutritional value for growth.[3][33] |
| Wild black cherry (Prunus serotina) | Rosaceae | Upland forests across range | Preferred for egg-laying; larvae feed on foliage, avoiding fruits.[3][69] |
| Sweet bay magnolia (Magnolia virginiana) | Magnoliaceae | Southern wetlands, e.g., Florida | Dominant in south; sole host in some areas, supports full larval development.[1] |
| White ash (Fraxinus americana) | Oleaceae | Northern and central areas | Commonly used; larvae consume leaves, contributing to population stability.[1][69] |