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Pieris rapae

Pieris rapae, commonly known as the small white or cabbage white butterfly, is a small to medium-sized species in the family , characterized by white wings with black-tipped forewings and distinctive spots: males typically have one black spot on each forewing, while females have two. The larvae, often called cabbage worms, are green with yellow dorsal stripes, reaching up to 35 mm in length, and are notorious for feeding on foliage of plants such as and . Native to , , and parts of , it has been introduced to since the 1860s and is now cosmopolitan in temperate regions, often considered an agricultural pest due to its impact on cruciferous crops.

Taxonomy and Classification

Pieris rapae belongs to the order and family , with the species first described by in 1758 as Papilio rapae. It is classified under: Subspecies variations exist, such as P. r. crucivora in , but the nominate form is widespread. The butterfly's name reflects its affinity for brassica plants, though adults primarily nectar-feed.

Distribution and Habitat

Originally from the Palearctic region—including , , and temperate P. rapae was accidentally introduced to , , in the 1860s via imported cabbage plants and rapidly spread across , reaching as far as southern and . It has also established in and , thriving in temperate climates with open habitats such as meadows, fields, gardens, roadsides, and urban areas. Adults prefer sunny, weedy areas near host plants, while larvae are host-specific to , including wild mustards and cultivated crops.

Life Cycle and Ecology

The life cycle of P. rapae is holometabolous, with four stages: , , , and . Females lay 300–400 pale yellow s singly on the undersides of leaves, which hatch in 4–8 days into velvety green larvae that feed voraciously for about 15 days across five instars. Pupation occurs in a chrysalis (19–20 mm long), lasting 11 days to several weeks, with overwintering in colder regions. Adults emerge with a of 45–65 mm, live 3–6 weeks, and fly diurnally from early spring to late fall, producing 2–8 generations annually depending on and . Ecologically, adults pollinate flowers by feeding on , but the species is often invasive, with larvae causing economic damage by defoliating crops; natural enemies include wasps and birds. In some regions, it exhibits migratory behavior, aiding dispersal.

Description

Adults

The adult Pieris rapae, commonly known as the small white or cabbage white butterfly, has a wingspan ranging from 32 to 47 mm. The wings are predominantly creamy white on the upperside, with the forewings featuring distinctive black tips that extend along the outer margins and veins. The hindwings are similarly white, while the undersides of both wings display a pale yellowish tint, particularly on the hindwings, which aids in when at rest. Sexual dimorphism is evident in the wing markings and body coloration. Males typically exhibit a single black spot near the center of each forewing, whereas females have two such spots, along with a slightly more pronounced black shading that can appear as a faint band-like extension from the wing tips inward. The body is robust and covered in dense ; this is white in females but darker, often grayish or yellowish, in males. During flight, adults beat their wings at a of up to 12.8 flaps per second, enabling agile, fluttering movement characteristic of pierid . For identification, P. rapae can be distinguished from the similar Pieris napi (green-veined ) by the absence of greenish-gray scaling along the wing veins on the hindwing underside; in P. rapae, this area remains creamy without such markings, and the forewing tips show fainter shading compared to the more prominent veining in P. napi.

Immature stages

The eggs of Pieris rapae are barrel-shaped, measuring approximately 0.5 mm in width and 1.0 mm in length, with longitudinal and transverse ridges on the surface. They are laid singly, typically upright on the underside of host plant leaves, and initially appear pale before turning yellowish as development progresses. This color change aids in blending with the plant foliage for during the embryonic stage. The larvae, known as imported cabbageworms, undergo five instars, starting as small, pale individuals about 3 mm long and reaching up to 30 mm in mature form. They exhibit a velvety green body covered in fine white and black hairs, accented by a faint stripe and lateral rows of yellow spots, which provide against foliage. Across instars, the larvae grow progressively larger with head capsules widening from 0.4 mm in the first to 2.2 mm in the fifth, while maintaining their green coloration for ; they possess five pairs of prolegs for locomotion. Larvae produce copious greenish-brown pellets, which accumulate beneath feeding sites. The pupae are angular chrysalids, 18–20 mm long, featuring sharp projections for structural support and attachment via a silken and cremaster. Coloration varies for , appearing green when pupating on to match surfaces, or brown, gray, and speckled when on other substrates like stems or fences, enabling background . In overwintering forms, pupae adopt darker, more cryptic hues to endure through colder months. Upon completion, the splits to allow .

Taxonomy

Nomenclature

The binomial name of this species is Pieris rapae (Linnaeus, 1758), originally described by as Papilio rapae in his . The genus name Pieris derives from the Latin Pieris, which originates from the Πιερίς (Pierís), referring to a worshiped in the region of Pieria, and has been associated with white coloration in butterflies due to mythological connections to the Pierides. The specific epithet rapae comes from the Latin rapa, meaning , alluding to the host plant . Franz von Paula Schrank transferred the species to the genus Pieris in 1801, establishing the current combination. In 1947, Hugh Newman Verity proposed Artogeia as a of Pieris for the napi-group, including P. rapae, which some later elevated to full genus status based on morphological distinctions. However, a 1986 analysis by Robbins and Henson argued for retaining Pieris rapae due to nomenclatural priority, cladistic evidence from wing venation and genitalia, and stability in , a position now widely accepted. Notable synonyms include Artogeia rapae (Linnaeus, 1758), Pontia rapae Fabricius, 1793, Papilio rapae Linnaeus, 1758, Ascia rapae Linnaeus, and Mancipium rapae Linnaeus. Common names for the adult butterfly vary regionally: it is known as the small white in , the cabbage white in and other areas, and simply the white butterfly in places like . The larval stage is commonly called the imported cabbageworm, reflecting its status as an introduced agricultural pest. Subspecies naming follows the species convention, such as P. rapae crucivora Boisduval, 1852, for Asian populations.

Subspecies

Pieris rapae is classified into several subspecies, distinguished primarily by geographic distribution and subtle morphological variations in wing patterns and coloration. Recognized subspecies include the nominate P. r. rapae, P. r. crucivora, P. r. mauretanica, P. r. debilis, and P. r. lusitanica. The nominate subspecies, P. r. rapae, is native to Europe and extends into western parts of Eurasia, featuring white wings with black apical markings on the forewings and typically one or two discal black spots, with females showing two spots and males one. This subspecies serves as the type for the species described by Linnaeus in 1758. In eastern Asia, the subspecies P. r. crucivora occupies regions from through , , , and into the , often in agricultural and open habitats. Morphological differences include variations in wing scale structure, particularly sexual dichroism where females possess UV-reflecting scales that alter wing appearance under light, facilitating mate recognition—a trait less pronounced or absent in P. r. rapae. Additionally, P. r. crucivora tends to exhibit larger black spots on the forewings compared to the nominate form, contributing to regional identification. The subspecies P. r. mauretanica is restricted to , including and surrounding areas, with wing markings similar to P. r. rapae but adapted to arid environments through slight reductions in spot size and paler overall coloration for . Other subspecies include P. r. debilis in and P. r. lusitanica in the , showing minor variations in coloration and spot size. Genetic and morphological variations across these subspecies, such as differences in spot size and UV reflectance, reflect adaptations to local climates and host plants, though intergradation occurs in overlap zones. Recent genomic studies, including post-2020 analyses building on ddRADseq data, have confirmed the distinct lineages of P. r. rapae and P. r. crucivora, with divergence dated to approximately 1,200 , linked to human-mediated dispersal via trade routes. These investigations also validate the invasive origins of non-native populations, tracing them primarily to European (P. r. rapae) introductions.

Distribution and habitat

Native range

Pieris rapae is native to the Palearctic ecozone, specifically , , and temperate . Genetic and historical evidence indicates that the species originated in the or region approximately 20,000 years before present, with subsequent divergence into European and Asian populations around 1,200 years before present, facilitated by the diversification of crops and ancient trade routes like the . Within these native regions, it occupies elevations ranging from to montane habitats up to approximately 2,500 meters, as observed in various European and Asian localities. The preferred habitats of P. rapae in its native range include open, sunny areas such as meadows, fields, gardens, and woodland edges, where larval host plants from the family, like wild mustards and cabbages, are prevalent. These environments provide the necessary resources for oviposition and larval development, with the butterfly showing a strong association with cruciferous vegetation across its distribution. Climatically, P. rapae is adapted to temperate zones with mild winters, typically between 23.5° N and 60° N , where it remains active from through autumn. The species avoids extreme arid deserts and severe cold beyond its overwintering tolerances, with pupae capable of surviving temperatures as low as -20°C but preferring regions without prolonged harsh winters. This climatic preference aligns with its historical spread along temperate corridors in and .

Introduced ranges

Pieris rapae was first introduced to in the 1860s, arriving accidentally via ships from to , , from where it rapidly spread across the continent within two decades. The butterfly reached in 1897, likely through similar inadvertent transport on vessels, establishing populations in the islands' temperate regions. In , it was detected in 1930, having been transported unintentionally through international trade routes, and quickly became widespread. Australia saw its arrival in 1937, again as an accidental introduction via shipping, leading to establishment across southern temperate areas. The success of these invasions stems primarily from the enemy release hypothesis, where the absence of co-evolved natural enemies in the new environments allowed populations to thrive without significant predation or pressures. Additionally, the abundance of suitable host plants, especially cultivated crops like and , provided ample resources for reproduction and larval development, facilitating rapid . Genetic studies indicate that while invasions often involved bottlenecks leading to reduced diversity, the species' adaptability and human-mediated dispersal overcame these limitations. Today, P. rapae is widespread across temperate zones in its introduced ranges, from southern Canada to northern Mexico in North America, and throughout much of Australia and New Zealand. The nominate subspecies P. r. rapae predominates in North American populations, originating from European introductions. In urban and agricultural settings, adult densities can exceed 150,000 individuals per hectare during peak late-summer periods, underscoring its prolific establishment.

Life cycle

Developmental stages

Pieris rapae undergoes complete , consisting of , larval, pupal, and stages, with development times varying primarily with . The stage lasts 4–7 days, with hatching accelerated at warmer temperatures and optimal development occurring between 20–25°C. The larval stage spans 10–20 days and comprises five instars, during which the experiences rapid growth, increasing in mass up to approximately 3000-fold. Growth rates are highest at temperatures around 25–30°C, with the entire larval period completing in approximately 10.5 days under conditions at 25°C. The pupal stage in non-diapausing individuals lasts 8–15 days, though pupae entering can overwinter for up to 9 months, with emergence triggered by increasing spring temperatures. Diapause mechanisms, which allow survival through cold periods, are further detailed in the section on voltinism and . Adult have a lifespan of 3 to 6 weeks, during which they mate and lay . The total from to adult emergence ranges from 30–50 days under favorable conditions. Development rates across all stages are temperature-dependent, often modeled using degree-days, with approximately 280–300 degree-days (base temperature ~10°C) required for completion of one .

Voltinism and diapause

Pieris rapae displays a multivoltine life history, producing multiple generations within a single year, with the precise number influenced by environmental conditions such as temperature and photoperiod. In temperate regions, including parts of and the , the species typically completes 2 to 3 generations annually. Further south in warmer temperate areas like , this increases to 3 to 5 generations, while in subtropical and southernmost portions of its range, up to 6 to 8 generations can occur. This variation allows the butterfly to capitalize on favorable growing seasons while adapting to regional climates. To survive unfavorable winter conditions, P. rapae enters facultative primarily at the pupal stage, induced by shortening day lengths in late summer or autumn. Photoperiods of less than approximately 12 hours trigger this response, with a critical day length around 12 hours and 10 minutes associated with 50% diapause incidence in laboratory conditions at 20°C. The mechanism involves physiological arrest through hormonal regulation, including suppression of titers, which halts metamorphic processes and promotes . Diapausing pupae overwinter in sheltered locations, exhibiting reduced metabolic activity to conserve energy reserves. Overwintering survival for diapausing pupae varies with climate severity but typically ranges from 70% to 90% in mild temperate conditions, with lower rates in colder exposures due to freeze risks. Diapause termination occurs in spring, prompted by cumulative chilling followed by rising temperatures that reactivate development, often requiring a period of low temperatures (around 4–10°C) to fulfill the chilling requirement before post-diapause quiescence ends. Recent studies (2023–2025) highlight how climate warming affects this process: acute exposure to higher temperatures elevates metabolic rates in early diapause, depleting reserves, while prolonged warming later in diapause reduces rates but impairs cold tolerance and overall survival. These adjustments underscore potential vulnerabilities to shifting seasonal patterns.

Behavior and ecology

Foraging behavior

Adult Pieris rapae butterflies are nectar feeders that preferentially visit flowers with purple, blue, and yellow colors, including those in the Asteraceae family, to obtain carbohydrates and amino acids essential for flight and reproduction. They locate these resources primarily through visual cues during active flight foraging patterns, often scanning open areas on sunny days for contrasting floral signals against green vegetation. In contrast, P. rapae larvae are specialized herbivores restricted to plants in the family, such as Brassica oleracea, where they consume foliage to support rapid development. Consumption rates increase dramatically in later instars, allowing larvae to process substantial leaf biomass daily while detoxifying plant defenses like glucosinolates through a gut known as the nitrile specifier protein (NSP), which redirects hydrolysis products away from toxic isothiocyanates toward less harmful . Larvae detect suitable host plants using chemosensory receptors on their mouthparts and body, enabling precise foraging on chemically suitable tissues. Foraging efficiency in P. rapae is enhanced by specialized sensory mechanisms and physiological adaptations, with adults relying on for efficient nectar location and larvae employing chemosensory detection for host selection. Larval is particularly notable, exhibiting a high (RGR) exceeding 1.15 day⁻¹ on hosts, which facilitates rapid biomass accumulation and outpaces many other insect-herbivore systems. This high RGR, combined with NSP-mediated detoxification, allows larvae to achieve efficient nutrient extraction despite host plant defenses. Foraging impacts differ between native and introduced ranges, where in native Eurasian habitats P. rapae larvae typically exploit dispersed wild with moderate population densities, whereas in introduced North American and other regions, access to abundant cultivated hosts leads to elevated larval consumption and higher overall foraging pressure on local vegetation.

Reproductive behavior

Males of Pieris rapae initiate by releasing pheromones from specialized scales on their wings, particularly during interactions with potential mates, which helps attract and stimulate females. typically involves aerial pursuits where the male chases the female in flight, performing rapid maneuvers to display vigor and wing patterns; this phase can last several minutes before landing and copulation, with the entire mating event enduring 10–30 minutes. Female in P. rapae is influenced by wing markings, particularly ultraviolet-reflective patterns that signal genetic quality, and the 's demonstrated vigor during pursuits, leading to selective acceptance of copulation attempts. Multiple matings by females are uncommon due to the transfer of a during copulation, which provides nutrients but also reduces female receptivity for several days post-mating. Host selection for oviposition relies on a combination of visual and chemical cues, with females preferring plants that provide high contrast against the background, such as green leaves, and detecting glucosinolates—secondary metabolites unique to this family—as key attractants. Females show a strong preference for young leaves, which offer optimal nutrition and lower defense levels for emerging larvae. During oviposition, females lay individual eggs singly on the undersides of host leaves to protect them from predators and environmental stress, with each female capable of depositing 200–400 eggs over her lifetime. Conspecific eggs release an oviposition-deterring that discourages additional egg-laying on the same , promoting dispersal and reducing larval competition. Searching behavior involves patrolling flights over potential habitat, where females scan for suitable hosts from afar before landing to assess them closely by drumming their tarsi on leaf surfaces to taste chemical cues. This hierarchical process ensures efficient host discrimination and egg placement.

Migration

_Pieris rapae displays migratory behavior primarily in its native European range, characterized by annual southward movements during autumn to evade harsh winter conditions. These migrations involve adults flying in directed paths, often crossing geographical barriers such as the Pyrenees Mountains, with individuals covering distances of up to 40 km in a single day under favorable conditions. While individual flights are relatively short, cumulative multi-generational dispersal can result in broader range shifts spanning hundreds of kilometers, aided by active flight rather than strong reliance on wind currents. The onset of these migrations is influenced by several environmental and biological triggers, including high population densities in summer breeding areas that prompt dispersal, advancing cold fronts signaling winter's approach, and shortening photoperiods that cue seasonal changes in . Migrating adults maintain consistent flight speeds of approximately 8 /h, translating to daily displacements of 20–30 assuming several hours of active flight. Primarily the second and third broods engage in these autumn southward flights, consisting of newly emerged adults of wing size (around 24 mm). The northward return in spring is achieved not by the same individuals but through their , which exhibit varied ages and larger wing sizes (up to 26 mm), continuing the cycle. These migratory patterns contribute to significant ecological implications, particularly enhancing between populations and facilitating the species' invasive spread in introduced ranges such as , , and . By enabling repeated introductions and admixture events tied to trade routes, migrations have supported rapid range expansions over the past 160 years despite genetic bottlenecks, promoting to new environments. Recent studies from 2024–2025 indicate phenological shifts due to climate warming, with flight periods in regions like extending by over 35 days from 1973 to 2023—spring emergence advancing by about 15 days and autumn activity prolonging by up to 23 days—potentially allowing extended migratory opportunities into milder winters and altering seasonal dynamics.

Ecological interactions

Predation and parasitism

Pieris rapae faces significant predation pressure from a variety of generalist predators across its life stages, including such as sparrows and other passerines, which consume eggs, larvae, and pupae, contributing to mortality rates of up to 50% in studies. predators, including spiders, , wasps, and ground beetles, also inflict high mortality, with rates averaging 53% on eggs and early-instar larvae through direct consumption. These predators employ attack mechanisms such as visual for exposed eggs and larvae or web entrapment for mobile stages, often targeting crucifer foliage where P. rapae develops. Larvae of P. rapae exhibit behavioral and physiological defenses against predation, including through their green, velvety coloration that blends with host plant leaves, reducing detection by visually hunting predators. Additionally, larvae sequester glucosinolates—mustard oil precursors—from their host plants, rendering them chemically defended and distasteful to generalist predators like birds and spiders, thereby lowering consumption rates in tritrophic interactions. Parasitoids, particularly , represent a of mortality for P. rapae, with the gregarious braconid wasp targeting young larvae by ovipositing multiple eggs internally, leading to host mummification and parasitism rates of 20-81% in field studies. The pteromalid wasp Pteromalus puparum specializes on pupae, injecting venom to suppress host immunity before laying eggs. These parasitoids locate hosts via herbivore-induced plant volatiles, exemplifying tritrophic interactions where plant signals mediate enemy recruitment. Hyperparasitism further complicates these dynamics, as wasps like Lysibia nana () attack C. glomerata cocoons, with hyperparasitism rates of 20-55% on C. glomerata pupae and influencing overall . Stage-specific vulnerabilities vary markedly: eggs experience low attack but high predation (up to 80%), while larvae face elevated risks from both predation and (50-90% combined mortality), and pupae are more susceptible to specialized parasitoids like P. puparum than to generalist predators.

Pest status and management

Pieris rapae is a significant agricultural , primarily due to larval feeding on cruciferous crops such as (Brassica oleracea) and (B. oleracea var. italica), where it causes extensive defoliation and reduces marketable yield. Larvae skeletonize leaves, leading to up to 85% leaf area damage in unmanaged fields, and can result in significant reductions in marketable heads without intervention. Globally, the species is a major , driving economic impacts through reduced harvests in , , , and . Effective management relies on (IPM) protocols that combine monitoring with multiple tactics to minimize environmental harm and resistance risks. Cultural practices include to disrupt life cycles and row covers to exclude adult from oviposition sites. Physical methods, such as yellow sticky traps, target migrating adults to reduce egg-laying on crops. Chemical controls focus on targeted applications against early-instar larvae, with (Bt) var. kurstaki being highly effective at rates of 0.5–2 lb/acre, preserving beneficial when timed properly. Spinosad formulations like Entrust SC (3–6 fl oz/acre) provide similar efficacy with a pre-harvest interval of 1 day. Unlike the (Plutella xylostella), P. rapae populations have not evolved widespread resistance to Bt toxins, allowing sustained use in rotation with other modes of action to prevent future issues. Biological controls enhance IPM by leveraging natural enemies, including augmentative releases of the Cotesia rubecula, which reduces larval survival by parasitizing early instars and limits pupal densities in field trials across paired sites. Egg parasitoids like Trichogramma spp. wasps, when released alongside , significantly lower larval counts and boost marketable proportions compared to single treatments. Entomopathogens, such as Steinernema carpocapsae nematodes combined with fungi, demonstrate synergistic mortality against 4th-instar larvae and pupae and are compatible with low-dose insecticides. IPM emphasizes weekly scouting (e.g., examining 25 plants per field) and action thresholds, such as treating when >10% of plants are infested at heading stage, to optimize interventions. intensifies outbreaks by elevating nocturnal temperatures, which boost developmental rates and while reducing fitness costs from , potentially increasing generational overlaps and pest pressure in temperate regions.

References

  1. [1]
    Pieris rapae | INFORMATION - Animal Diversity Web
    Cabbage butterflies (Pieris rapae), known as cabbage worms in their caterpillar stage, are found all around the world in temperate climates.
  2. [2]
    Cabbage White | Missouri Department of Conservation
    Mar 7, 2024 · Pieris rapae. Family. Pieridae (whites, sulphurs, yellows). Description. Male and female cabbage whites are white with dark wingtips. Females ...
  3. [3]
    https://entnemdept.ufl.edu/creatures/veg/leaf/imported_cabbageworm.htm
  4. [4]
    Pieris rapae - an overview | ScienceDirect Topics
    Pieris rapae is defined as the small cabbage white butterfly, a pest native to Europe, Asia, and North Africa, whose larva causes significant damage to cabbage ...Missing: taxonomy | Show results with:taxonomy
  5. [5]
    Pieris rapae (cabbage white butterfly) | CABI Compendium
    Pieris rapae was first described by Linnaeus in 1758 as Papilio rapae, but subsequently placed in the genus Pieris by Schrank. Pieris rapae is the preferred and ...
  6. [6]
    Cabbage White, Small Cabbage White
    The adult butterfly has a wingspan of 1-1/2 inches. The forewings are black-tipped. A female has two black spots on top of each of her forewings; a male has ...Missing: taxonomy | Show results with:taxonomy
  7. [7]
    Species Pieris rapae - Cabbage White - Hodges#4197 - BugGuide.Net
    Other Common Names. Small White ; Size. wingspan 30-50 mm ; Range. Throughout North America ; Season. Adults fly from early spring to September ; Food. Caterpillars ...
  8. [8]
    Cabbage White - Alabama Butterfly Atlas - University of South Florida
    Cabbage White Pieris rapae · Butterfly: Wingspan: 1¼ - 1¾ inches (3.2 - 4.8 cm) UPPER SURFACE (dorsal) Predominantly white with charcoal forewing tips. · Egg: ...
  9. [9]
    EENY-126/IN283: Imported Cabbageworm, Pieris rapae (Linnaeus ...
    Upon emergence from the chrysalis the butterfly has a wingspan of about 4.5 to 6.5 cm (1.8 to 2.6 in). It is white above with black at the tips of the ...
  10. [10]
    (PDF) Relationship between wingbeat frequency and resonant ...
    ... (Pieris rapae, Plusia gamma and Ochlodes), Hymenoptera (Xylocopa pubescens ... flapping at a higher wingbeat frequency (higher than 100 Hz). These ...
  11. [11]
    None
    ### Differences Between Pieris rapae (Small White) and Pieris napi (Green-veined White) for Identification (Adult Morphology)
  12. [12]
    Imported cabbageworm - Agricultural Biology
    Butterflies of imported cabbageworm, commonly called the “cabbage white”, are active during the day and have a wingspan of about 5 cm (2 inch). They have white ...
  13. [13]
    Cabbage White Butterfly | College of Agricultural Sciences
    Adults are white with several black markings on the wings with a wingspan of about 45 mm. They may be seen flying about in the field from early spring to late ...
  14. [14]
    Imported Cabbageworm - Wisconsin Horticulture
    May 28, 2004 · The imported cabbageworm (Pieris rapae) is a lepidopteran insect and the most important cole crop pest in Wisconsin.
  15. [15]
    Pieris - Wiktionary, the free dictionary
    Etymology. From Latin Pieris, from Ancient Greek Πιερίς (Pierís, “a Muse”), first worshiped in Πιερία (Piería, “Pieria”).
  16. [16]
    [PDF] JOURNAL OF THE LEPIDOPTERISTS' SOCIETY - Yale University
    The generic placement of P. rapae has recently been changed from Pieris to Artogeia Verity. Schrank (1801) placed rapae in Pieris when he originally described ...
  17. [17]
    Pieris rapae | NatureServe Explorer
    Robbins, R. K., and P. M. Henson. 1986. Why Pieris rapae is a better name than Artogeia rapae (Pieridae). Journal of the Lepidopterists' Society 40(2):79-92.
  18. [18]
    Pieris rapae (Linnaeus, 1758) - GBIF
    Pieridae. Genus. Pieris Hübner, 1819. Species. Pieris rapae (Linnaeus, 1758). = Artogeia rapae (Linnaeus, 1758). ≡. Papilio rapae Linnaeus, 1758. = Pieris ...Missing: binomial etymology
  19. [19]
    Imported Cabbageworm / Cole Crops / Agriculture - UC IPM
    The adult cabbage butterfly is white to pale yellowish with a wingspan of 1.5 inches and has one to four black spots on each forewing. Adults are often seen ...
  20. [20]
    Pieris rapae subsp. rapae - GBIF
    Pieris rapae subsp. rapae ... This is the interpretation of the species as published in Integrated Taxonomic Information System (ITIS). To view GBIFs view on this ...
  21. [21]
    Pieris rapae crucivora Boisduval, 1836 - GBIF
    SUBSPECIES. Classification. kingdom; Animalia: phylum; Arthropoda: class; Insecta: order; Lepidoptera: family; Pieridae: genus; Pieris: species; Pieris rapae ...
  22. [22]
    Sexual dichroism and pigment localization in the wing scales of ...
    Oct 3, 2006 · Pieris rapae crucivora thus features a distinct sexual dichroism (Obara 1970), which is absent in P. r. rapae (Obara & Majerus 2000). The ...
  23. [23]
    Pieris (Artogeia) rapae - Lepidoptera Mundi
    Pieris (Artogeia) rapae mauretanica, Vérity, 1908. Pieris (Artogeia) rapae meleager, (Hemming, 1934). Pieris (Artogeia) rapae rapae, (Linnaeus, 1758). Pieris ...
  24. [24]
    Global invasion history of the agricultural pest butterfly Pieris rapae ...
    The small cabbage white butterfly, Pieris rapae, is a major agricultural pest of cruciferous crops and has been introduced to every continent except South ...<|control11|><|separator|>
  25. [25]
    Genomic analysis reveals new species and subspecies of butterflies
    Dec 13, 2023 · The character states are given in species diagnoses as abbreviations for one of the four reference genomes: Pieris rapae (Linnaeus, 1758) (pra) (Shen et al.
  26. [26]
    Global invasion history of the agricultural pest butterfly Pieris rapae revealed with genomics and citizen science | PNAS
    ### Summary of Pieris rapae Native Range, Origin, and Distribution History (Pre-Introduction)
  27. [27]
    Pieris rapae - Butterfly Conservation Armenia
    ... elevations from 400 to 2000 m a.s.l. The species uses wide variety of ... Its distribution range is covered by several protected areas, Emerald Sites ...Missing: altitude | Show results with:altitude
  28. [28]
    Cabbage white butterfly - Southern Cross University
    Dec 7, 2023 · Cabbage white butterflies – Pieris rapae – are one of the most common garden visitors across southern and eastern Australia.
  29. [29]
    Global invasion history of the agricultural pest butterfly Pieris rapae ...
    Sep 10, 2019 · The small cabbage white butterfly, Pieris rapae, is a major agricultural pest of cruciferous crops and has been introduced to every continent ...
  30. [30]
    Complete genome of Pieris rapae, a resilient alien,... - F1000Research
    Nov 3, 2016 · Being accidentally introduced into North America, Australia, and New Zealand a century or more ago, it spread throughout the continents and ...<|control11|><|separator|>
  31. [31]
    (PDF) Enemy Release? An experiment with congeneric plant pairs ...
    Aug 9, 2025 · ... Pieris rapae. being abundant and highly damaging in. 2002, but absent ... The Enemy Release Hypothesis suggests that invasions thrive due to a ...
  32. [32]
    cabbage white butterflies (Pieris rapae) as a case study | BMC ...
    May 26, 2017 · Northern North Dakota, southern Manitoba and Saskatchewan have been extensively farmed for canola since the late 1970s and early 1980s. In the ...
  33. [33]
    Imported Cabbageworm | VegEdge
    Females then lay yellow, oblong, and deeply ridged length-wise eggs singly on the leaves of host plants. After 3 to 7 days, depending on temperature, the eggs ...Missing: morphology | Show results with:morphology
  34. [34]
    [PDF] Investigating Life with the Cabbage White Butterfly and Brassicas in ...
    The Cabbage White Butterflies tend to live in captivity from 1 to 3 weeks. In many agricultural areas, Pieris rapae is considered to be a "pest" species. If ...
  35. [35]
    Extremely high relative growth rate makes the cabbage white, Pieris ...
    Jun 15, 2023 · rapae larvae can grow 18.8 times in mass in only 4 days, which means they can more than double their mass each day. The bar indicates 1 cm. Full ...Missing: frass | Show results with:frass
  36. [36]
    Pieris rapae - Knowledge Master
    The adult white butterfly has a wingspan of 1-1/2 inches. The forewings are black-tipped. A female has two black spots on top of each of her forewings; a ...
  37. [37]
    UC IPM Phenology Model Database: Imported Cabbageworm ...
    Imported Cabbageworm, Cabbage Butterfly. Scientific name: Pieris rapae. Phenology models predict timing of events in an organism's development.
  38. [38]
    Photoperiodic Induction of Diapause in Pieris rapae crucivora ...
    The incidence of pupal diapause in the cabbage white butterfly, Pieris rapae crucivora, fed on artificial diet was investigated under various photoperiodic ...Missing: trigger | Show results with:trigger
  39. [39]
    The Role of Juvenile Hormone in Diapause and Phase Variation in ...
    It is well known that various insects respond to environmental stimuli by entering diapause or exhibiting phase variation. In lepidopterous insects ...
  40. [40]
    Seasonal specialization drives divergent population dynamics in two ...
    Jun 20, 2023 · Pieris rapae population sizes are catching up with those of P. napi ... rapae populations are thriving at their northern bivoltine range ...
  41. [41]
    Seasonal Differences in Diapause Induction in a Vermont ...
    We found that diapause induction and termination in P. rapae is dependent on multiple environmental factors, including photoperiod and ...Missing: trigger | Show results with:trigger
  42. [42]
    Thermal effects on metabolic rate in diapausing Pieris rapae butterflies
    Individuals were reared under these conditions until pupation, approximately 14 days post-oviposition. Upon pupation we placed all pupae into individual petri ...
  43. [43]
    Foraging Small White Butterflies, Pieris rapae, Search Flowers ...
    Mar 21, 2021 · Sexual dimorphism in photoreceptor spectral sensitivities appears common among butterflies (Sison-Mangus et al., 2006; McCulloch et al., 2016), ...Missing: morphology wingspan
  44. [44]
    Comparison of color‐learning rates among eight species of three ...
    Jun 21, 2021 · Naïve P. rapae females preferred yellow (19.2%), followed by blue (18.8%), purple (16.3%), magenta (11.4%), and orange (11.2%) ...
  45. [45]
    Cabbage White (Butterflies of Alabama) - iNaturalist
    The small white (Pieris rapae) is a small- to medium-sized butterfly species of the whites-and-yellows familyPieridae. It is also known as the small cabbage ...
  46. [46]
    Successful herbivore attack due to metabolic diversion of a plant ...
    The ability to form nitriles is due to a larval gut protein, designated nitrile-specifier protein, that by itself has no hydrolytic activity on glucosinolates ...
  47. [47]
    Herbivory and Relative Growth Rates of Pieris rapae are Correlated ...
    The average larva feeding on a spring-flowering mustard disk gained 0.19 mg/mg of initial mass, whereas the average larva feeding on a summer-flowering ...
  48. [48]
    Differential regulation of host plant adaptive genes in Pieris ... - Nature
    May 10, 2019 · Pierid butterflies use Brassicales plants by disarming GLS defense with a protein expressed in the larval gut called nitrile-specifier protein ( ...
  49. [49]
    Aphrodisiac pheromones from the wings of the small cabbage white ...
    The two macrolides 1 and 2 are aphrodisiac pheromone components of male small and large cabbage white butterflies, respectively.Missing: courtship | Show results with:courtship
  50. [50]
    Rapid Divergence of Wing Volatile Profiles Between Subspecies of ...
    Mar 23, 2018 · Courtship in P. rapae occurs in two stages. During early courtship, males pursue flying females and perform aerial courtship behaviors that ...
  51. [51]
    Mating in the Afternoon: Time-Saving in Courtship and ... - jstor
    Obara Y (1964) Mating behaviour of the cabbage white, Pieris rapae crucivora. II. The "mate refusal posture" of the fe- male. Zool Mag 73:175-178. Pliske TE ...Missing: aerial | Show results with:aerial
  52. [52]
    Mate Preference in Males of the Cabbage Butterfly, Pieris Rapae ...
    We initially investigated whether females of the cabbage butterfly, Pieris rapae crucivora, exhibit a seasonal change in ultraviolet wing color, which is a key ...
  53. [53]
    Effect of Male Mating History and Body Size on Ejaculate Size ... - jstor
    male mating history and body size on ejaculate size and quality in two polyandrous butterflies, Pieris napi and Pieris rapae. 2. The interval between first ...<|control11|><|separator|>
  54. [54]
    How do Pieris rapae search for Brassicaceae host plants?
    ▻ Post-mating females of Pieris rapae began active searching behavior for host plants immediately after mating and had a markedly higher preference for cabbage ...How Do Pieris Rapae Search... · Abstract · Introduction
  55. [55]
    Plant Glucosinolate Content and Host-Plant Preference and ... - NIH
    May 29, 2023 · Glucosinolates are used in host-plant recognition by insects specialized on Brassicaceae, such as Pieris rapae L. (Lepidoptera: Pieridae).Missing: contrast | Show results with:contrast
  56. [56]
    Impacts of belowground herbivory on oviposition decisions in two ...
    Jul 5, 2010 · Pieris rapae, the small cabbage white butterfly, is a solitary species that lays single eggs on the leaves of the food plant. Delia radicum ...
  57. [57]
    Control of Size and Fecundity in Pieris rapae - jstor
    and 480 eggs per female for the B and C strains respectively (20% fecundity differential). Survival values are taken direct from Gilbert's Table 3. The ...
  58. [58]
    Does the imported cabbageworm,Pieris rapae, use an oviposition ...
    Eggs ofPieris rapae (L.) contain a water- and methanol-soluble oviposition-deterring pheromone (ODP) that is avoided by ovipositing females offered treated.
  59. [59]
    The Search for Resources by Cabbage Butterflies (Pieris Rapae)
    In this study we describe how the flight behavior of ovipositing P. rapae results in the placement of more eggs on isolated hosts. The flight paths of females ...
  60. [60]
    [PDF] Drumming Pierisbutterflies: A gustatory journey among ...
    This behaviour, known as drumming, stimulates the gustatory receptor neurons inside the contact- chemo sensilla. Pieris butterflies are holometabolous ...Missing: searching patrolling
  61. [61]
    https://images.peabody.yale.edu/lepsoc/jls/2000s/2005/2005(1)10-Gilbert.pdf
  62. [62]
    Long-Term Phenological Shifts in Butterfly Species from ...
    Oct 20, 2025 · The five butterfly species with multiple generations per year and a long flight period which extends towards autumn were: Pieris rapae (Linnaeus ...Missing: migration | Show results with:migration
  63. [63]
    Bird predation as a selective pressure on the immature stages of the ...
    The importance of bird predation as a selective pressure on the eggs, larvae and pupae of the cabbage butterflies, Pieris rapae L. and P. brassicae L. has ...
  64. [64]
    Experimental Evaluation of Arthropod Predation on Pieris rapae ...
    Estimated mortality of eggs and larvae from arthropod predators ranged from 23 to 80%, averaged 53% for all 8 cohorts, and affected mainly the eggs and 1st ...Missing: rates | Show results with:rates
  65. [65]
    Tritrophic metabolism of plant chemical defenses and its effects on ...
    Dec 16, 2019 · Genetic manipulation demonstrates the costs and benefits of detoxifying glucosinolate plant defenses in a pest insect and its predator.
  66. [66]
    [PDF] Introduced braconid parasitoids and range reduction of a native ...
    Pieris napi oleracea Harris is a native pierid butterfly that has suffered a range reduction in New England that began after the.
  67. [67]
    Hyperparasitoids exploit plant volatiles to locate their parasitoid host ...
    Herbivore-induced plant volatiles (HIPVs) induced by parasitized caterpillars have been found to be exploited by hyperparasitoids in the cabbage system.
  68. [68]
    Hyperparasitoids Use Herbivore-Induced Plant Volatiles to Locate ...
    Nov 27, 2012 · glomerata (CG) are primary parasitoids that both attack caterpillars of the Small Cabbage White butterfly, Pieris rapae (PR), that feed on ...