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Armadillidiidae
Armadillidiidae
Armadillidiidae
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Not to be confused with Armadillidae.
"Pillbugs" redirects here. For the band, see The Pillbugs.

Armadillidiidae
Temporal range: Chattian–present
An Armadillidium granulatum in various stages of conglobation, i.e., "rolling up"
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Arthropoda
Class: Malacostraca
Order: Isopoda
Suborder: Oniscidea
Section: Crinocheta
Family: Armadillidiidae
Brandt, 1833
Genera

See text

Armadillidiidae is a family of woodlice, a terrestrial crustacean group in the order Isopoda. Unlike members of some other woodlice families, members of this family can roll into a ball, an ability they share with the outwardly similar but unrelated pill millipedes and other animals. This ability gives woodlice in this family their common names of pill bugs[1] or rolly pollies.[2] Other common names include slaters, potato bugs, curly bugs,[3] and doodle bugs.[4] Most species are native to the Mediterranean Basin, while a few species have wider European distributions. The best-known species, Armadillidium vulgare, was introduced to New England in the early 19th century and has become widespread throughout North America.[5]

Common names

[edit]
Name Region
Pill bug Global
Rollie Pollie, Roly Poly US,[6] Canada, Australia
Roll-up bug US[6]
Curly bug Canada
Smooth randy Global
Woodlouse UK, Australia, US[6]
Slater bug Australia
Cheesy bug UK (parts of)
Sowbug, sow bug US[6]
Doodlebug, doodle bug US[6]
Slater Australia, New Zealand, Scotland, Ireland (Ulster)
Cellar bug Germany
Carpenter Canada, US[6] (certain regions)
Bed pisser Pissebed Netherlands / Belgium
Possibly "closed door" Cloporte Francophone regions
Parsons pig UK
Bench biter Denmark
Chiggy pig UK (Devon)
Chuckie pig US (South)
Little pig Chanchito South America (certain countries)
Bicho bolita Argentina
Potato bug UK, Canada, US[6]
Gramersow UK (Cornwall)
Gray sow Sweden
Tatu bolinha Brazil
Basketball bug US[6]
Twiddle bug US[6]
Little soil pig/small creature (porcellino di terra/onisco) Italy
Woodbug Canada
Cement bug Canada
Marranito Colombia
Uri Kadoori (sphere-like "Uri") Israel[7]

Ecology and behavior

[edit]

Pill bugs in the family Armadillidiidae are able to form their bodies into a ball shape, in a process known as conglobation. Conglobation has evolved independently in several families; this behaviour is shared with pill millipedes (which are often confused with pill bugs),[8] armadillos, cuckoo wasps, and some extinct trilobites.[9] It may be triggered by stimuli such as vibrations or pressure, and is a key defense against predation; it may also reduce respiratory water losses.[10] This defense mechanism is possible because of their segmented body structure. Armadillidiidae have overlapping plates called tergites that are connected by flexible joints. The tergites allow the body to roll up inwards. To roll up, they have muscles called pleopods that contract the abdominal tergites inwards.

The diet of pill bugs is largely made up of decaying or decomposed plant matter such as leaves and, to a lesser extent, wood fibers. Pill bugs also eat living plants, especially in wet conditions, sometimes consuming leaves, stems, shoots, roots, tubers, and fruits. Some species of pill bugs are known to eat decaying animal flesh or feces.[11] They will also eat shed snakeskin and dead bugs, if necessary. This diet has a secondary effect of accelerating the breakdown of litter, aiding in the retention of organic material in the soil. This helps in balancing the carbon content in the soil. Pill bugs also contribute to their ecosystem as detritivores.

However, pill bugs can be serious pests in certain agricultural systems, particularly in areas that are prone to heavy rains and flood conditions. Since they are attracted to decaying plant matter, they are often found on farms eating the crop residue. This leads pill bugs to start eating emerging seedlings. This has started to pose agricultural problems in Southern Australia. Farmers in the United States and Argentina have also reported increased rates of pill bugs destroying seed oil and soybean crops. They have also been observed eating wood supports in houses, making them a house pest. Pill bugs will feed on numerous crop plants including corn, beans, squash, peas, melon, chard, beet, cucumber, potato, spinach, lettuce, and strawberry, with potential for significant yield loss in strawberry in particular.

Pill bug on wood mulch

Classification

[edit]

The family Armadillidiidae is differentiated from other woodlouse families by the two-segmented nature of the antennal flagellum, by the form of the uropods, and by the ability to roll into a ball.[12]

Within the family Armadillidiidae, 18 genera are currently recognized:[13]

A 2022 study of myrmecophilous populations indicated that these represented a new species of Cristarmadillidium, and three new species within a new genus, Iberiarmadillidium.[14]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Armadillidiidae

View on Grokipedia
from Grokipedia
Armadillidiidae is a family of terrestrial isopods within the order and suborder Oniscidea, consisting of approximately 18 genera and over 300 species of woodlice renowned for their ability to conglobate by rolling into a protective spherical ball. These crustaceans, often called pill bugs or roly-polies, feature a hard, segmented , seven pairs of legs, and an oblong to body typically measuring 1/3 to 3/4 inch in length, with a smooth, rounded rear end that facilitates their defensive posture. Native primarily to the Mediterranean region and , certain species such as have been introduced worldwide by humans and are now cosmopolitan; they thrive in damp, organic-rich microhabitats such as under leaf litter, mulch, or decaying wood, where they play a key role as detritivores in nutrient cycling. Taxonomically, Armadillidiidae belongs to the superfamily Armadilloidea in the class , distinguishing it from related families like Porcellionidae (sowbugs) by its conglobation capability and more rounded shape. The family includes prominent genera such as , which encompasses over half of its species, with being the most widespread and ecologically significant member, often serving as a in studies of terrestrial . Unlike aquatic crustaceans, these isopods have evolved pseudotracheae—white, invaginated structures on their pleopods—for and water uptake, enabling survival in moderately dry terrestrial environments compared to more hygrophilous families. Biologically, Armadillidiidae species exhibit a lifespan of 2–5 years, with females carrying eggs in a ventral brood pouch (marsupium) where they hatch after 3–4 weeks, producing 1–3 broods annually of up to 200 offspring each. They are nocturnal herbivores and detritivores, consuming decaying vegetation while occasionally damaging tender seedlings in gardens, and undergo periodic molting—shedding the posterior half first followed by the anterior 3 days later—to grow. Conglobation not only deters predators but also conserves by reducing evaporative loss by up to 35% in low-humidity conditions, a critical for their semi-terrestrial lifestyle. Ecologically, they contribute to and , though invasive populations can impact agriculture in humid regions.

Description

Physical characteristics

Members of the Armadillidiidae family are small terrestrial isopods, typically measuring 7 to 15 mm in length, with body widths around half that dimension in mature individuals. Their bodies exhibit an oval, convex dorsal profile and a flatter ventral surface, facilitating movement and protection in leaf litter or environments. The body is divided into a head, (pereon), and (pleon), comprising seven thoracic segments (pereonites) each bearing a pair of pereopods, and six abdominal segments (pleonites). This segmentation allows for coordinated locomotion using their seven pairs of walking legs. The consists of a segmented, calcified with dorsal tergites that provide rigidity while permitting flexibility through overlapping plates and sutures. These tergites are heavily sclerotized, especially in the thoracic region, contributing to the family's characteristic armored appearance in gray to dark brown hues, often with lighter banding. The antennal is distinctly two-segmented, aiding in chemosensory detection of environmental cues. Posteriorly, biramous uropods extend from the sixth pleonite, functioning in sensory perception and body stabilization during movement or posture adjustments. Respiration in Armadillidiidae is adapted for terrestrial through , sponge-like pseudotracheae located on the exopods of the pleopods, particularly the first two pairs, which facilitate in humid microhabitats. These invaginated structures, visible as paired patches on the ventral , branch into fine tracheoles that enhance oxygen uptake while maintaining retention essential for gill-like function. Some possess up to five pairs, increasing respiratory efficiency in drier conditions compared to aquatic ancestors. Sexual dimorphism is evident in the reproductive appendages, where males possess modified endopods on the first two pairs of pleopods, elongated and specialized as gonopods for sperm transfer during copulation. These structures differ from the simpler, biramous pleopods in females, which primarily aid in respiration and brood protection. Overall, body size and coloration show minimal sexual differences, though females possess a marsupium for egg brooding.

Conglobation mechanism

The conglobation mechanism in Armadillidiidae enables individuals to curl their bodies into a compact, spherical as a defensive response, achieved through ventral flexion of the trunk where the free tergites of the pereon and pleon overlap, and the folds over the posterior end to enclose vulnerable appendages. This process involves the sequential rotation of body segments, with the pleon pressing against the anterior pereon, facilitated by flexible arthrodial membranes between tergites and paired rectangular sternites whose anterior edges dip ventrally to imbricate under preceding plates. The resulting minimizes exposure of soft tissues, such as limbs and pleopods, which are tucked inward. Locking of the ball is primarily accomplished by the uropods, whose protopodites bear wedge-shaped endites that interlock with the posterior margin of the head and pereonites, ensuring remains tightly sealed without gaps. Ventral muscles, including longitudinal and oblique fibers attached to tendinous bars on the sternites, provide the contractile force for flexion, while specialized joints at the tergosternal connections allow precise alignment during enrolment. Pleopods are modified with reduced exopodites in many , aiding their retraction into the ball to protect respiratory surfaces. This hydrostatic support from body fluids further stabilizes the compressed form against deformation. As an evolutionary adaptation unique to Armadillidiidae and a few other Oniscidea families, conglobation serves dual roles in mitigating predation by presenting a hard, armored exterior impervious to many attackers and in conserving water by reducing surface area exposed to in terrestrial environments. Studies on demonstrate that enrolment decreases water loss by up to 34.8% at low relative humidities, highlighting its significance for survival in arid conditions. While most genera form near-perfect spheres, variations exist across with different body proportions resulting in slightly looser configurations.

Taxonomy

Phylogenetic position

Armadillidiidae belongs to the kingdom Animalia, phylum Arthropoda, subphylum Crustacea, class , order , suborder Oniscidea, and section Crinocheta. The family was established by Johann Friedrich von Brandt in 1833 in his monograph on oniscidean crustaceans. In the , Armadillidiidae was separated from the closely related family , which Brandt had described two years earlier in 1831, based on differences in body structure and defensive adaptations. This revision distinguished Armadillidiidae primarily by its temperate distribution and specific conglobation traits, such as the plate-like, truncate exopodite of the uropods, contrasting with the more elongated forms in . Within Oniscidea, is positioned among the conglobating families of Crinocheta and is traditionally considered close to , though molecular analyses indicate a nearer relationship to Porcellionidae. The distinction from emphasizes variations in conglobation efficiency and habitat preferences, with favoring moist, terrestrial environments in temperate regions. Molecular evidence supports the of Armadillidiidae, as demonstrated by analyses of complete mitochondrial genomes from multiple species, which place the family as a cohesive within the monophyletic Crinocheta. Earlier studies incorporating 18S rRNA and mitochondrial COI genes have reinforced this, showing consistent basal positioning relative to other Crinocheta families like Porcellionidae.

Genera and species diversity

The family Armadillidiidae includes 18 recognized genera, encompassing a rich diversity of terrestrial isopods adapted to various microhabitats, particularly in arid and semi-arid regions. The genus stands out as the most speciose and widespread, comprising about 180 species according to recent catalogs, with subsequent discoveries indicating a total exceeding 180 species globally. In contrast, Alloschizidium contains approximately 17 species, many of which are specialized cavernicolous or endogean forms restricted to subterranean environments in the Mediterranean. The overall species diversity within Armadillidiidae is approximately 270 (as of ), though this figure continues to grow due to ongoing taxonomic research, especially in understudied karstic and insular habitats of the Mediterranean region. Recent multilocus phylogenetic studies have uncovered cryptic diversity, including the of the new Iberiarmadillidium in 2021, which includes three myrmecophilous species endemic to central and southern (I. pinicola, I. psammophilum, and I. sakura). Similarly, Cristarmadillidium has expanded with the addition of C. myrmecophilum from the same study and C. cabanillasi described from central in 2023, highlighting morphological stasis and in these lineages. Endemism patterns are pronounced, with numerous confined to specific islands or localized habitats; for instance, the monotypic Ballodillium (B. pilosum) is restricted to the , while genera like Schizidium exhibit high insular diversity in the Aegean archipelago, with over 20 many of which are single-island endemics. These patterns underscore the family's evolutionary hotspots in fragmented Mediterranean landscapes, where new discoveries continue to refine our understanding of its internal diversity.

Distribution and habitat

Native range

The Armadillidiidae family is primarily native to the Mediterranean Basin, encompassing , , and adjacent regions of the , such as Asia Minor and . This distribution reflects the family's evolutionary cradle in a region characterized by coastal and inland habitats conducive to terrestrial isopods capable of conglobation. While some species exhibit broader European ranges, the core diversity remains concentrated within this basin, with limited natural extension beyond pre-human dispersal. Areas of high species diversity include , , and the , where biogeographic isolation and varied microhabitats have fostered speciation. In alone, 59 valid species of the genus have been documented, highlighting it as a major center of . Similarly, the hosts numerous species, including recently described endemics like Armadillidium boalense from northern . Mediterranean islands such as and further contribute to this pattern, with multiple endemic taxa; for instance, molecular studies have revealed cryptic diversity within Schizidium on , including two distinct epigean clades and the description of two new species in 2023, and species like Armadillidium virgo are known only from Sicilian caves. Biogeographic factors, including adaptation to the of wet winters and dry summers, have significantly influenced within Armadillidiidae. Many species, particularly in the maculatum-group, are thermophilic and suited to arid scrublands, with historical geological events like the formation of mountain chains and the Sea promoting isolation and diversification. This climatic regime has driven evolutionary responses, such as enhanced resistance, contributing to the family's radiation across fragmented habitats. The fossil record provides insights into the family's origins, with the earliest terrestrial isopods appearing in the , but Armadillidiidae-level fossils dating to the . A well-preserved specimen from upper deposits in represents one of the oldest confirmed records for the family, underscoring its emergence in Eurasian contexts.

Introduced ranges

The family Armadillidiidae, particularly the species , has been widely introduced outside its native Mediterranean range through human-mediated dispersal, achieving a in temperate regions worldwide. A. vulgare was first introduced to in the early 19th century, likely arriving in via soil ballast in wooden ships from , and has since become established across the and much of , reaching high population densities in suitable habitats. Introductions have also occurred in other temperate zones, including , where A. vulgare is now common across the continent, often associated with human-disturbed areas; , where it has been present for over a century and is widespread near human settlements; , notably in Argentina's region; and parts of . The family is less prevalent in tropical areas, as species like A. vulgare exhibit intolerance to prolonged high levels, which can promote fungal overgrowth and reduce survival, limiting their establishment in humid equatorial environments. These introductions have been facilitated primarily by maritime trade, with A. vulgare and other armadillidiids transported in soil and attached to imported or nursery stock, enabling rapid spread along trade routes. In invaded ecosystems, they act as competitors for detrital resources, potentially altering rates and nutrient cycling while outcompeting native detritivores in disturbed habitats such as grasslands and urban edges. Genetic analyses of introduced populations reveal evidence of multiple independent introduction events, reflecting repeated transport; for instance, studies in grasslands indicate diverse haplotypes consistent with several European sources, while southern Australian populations show admixture from distinct invasion pathways.

Ecology and behavior

Diet and feeding habits

Armadillidiidae, commonly known as pill bugs or roly-polies, are primarily detritivores that consume decaying plant matter, including leaf litter, wood fibers, and fungi, which forms the bulk of their diet. They also ingest , bark, and , contributing to the breakdown of organic debris in terrestrial environments. While their feeding is predominantly on dead or decomposing materials, occasional herbivory occurs, particularly on tender seedlings or roots of live when detrital resources are scarce. These isopods possess digestive adaptations that enable efficient processing of lignocellulosic materials, such as from . Their plays a crucial role, producing enzymes that facilitate the degradation of , , and , allowing the hosts to extract nutrients from otherwise indigestible substrates. Foraging activity is largely nocturnal, helping to minimize water loss through in their moisture-dependent , as they emerge at night to feed under cover of darkness or high . In ecosystems, Armadillidiidae serve as key decomposers, accelerating the of nutrients from back into the , akin to the role of earthworms in . High population densities, however, can lead to economic impacts, such as damage to crops like strawberries, where they feed on fruits or seedlings, potentially causing significant losses in agricultural settings. Dietary variations exist among species, with some exhibiting opportunistic omnivory by consuming small dead , animal , or even their own coprophagous waste to recover essential minerals like .

Defensive behaviors and predators

Members of the Armadillidiidae family, commonly known as pill bugs, employ conglobation as their primary defensive mechanism against predators. This involves curling the body into a tight spherical , protecting the vulnerable ventral side and appendages with the hardened dorsal . Conglobation effectively deters a range of predators, including birds, amphibians, and , by making the isopod difficult to grasp or consume. In addition to physical protection, some species within the family possess repugnatorial glands on the pereon that secrete unpleasant chemicals, further repelling attackers; recent research as of 2025 has linked these glands to aposematic coloration in certain species, enhancing visual deterrence. Beyond conglobation, Armadillidiidae exhibit several behavioral adaptations to evade predation. These isopods are predominantly nocturnal, and moving primarily at night to minimize encounters with diurnal predators while resting in concealed locations during the day. They often burrow into soil or seek refuge under leaf litter, rocks, and logs, enhancing hiding opportunities. Group aggregation is another strategy, where individuals cluster together, providing collective and reducing individual visibility to predators. Rapid escape movements may also occur under threat, though conglobation remains the dominant response. Common predators of Armadillidiidae include invertebrates such as spiders (e.g., Dysdera crocata), centipedes, ground beetles, and ants (e.g., Tetramorium caespitum), as well as vertebrates like birds (e.g., common starlings), amphibians (e.g., frogs and toads), and small mammals. In introduced ranges, such as North America, additional pressures from local fauna like robins and parasitoid insects can occur, though specific fly parasitoids are less documented. These interactions highlight the family's broad vulnerability across ecosystems. Predation impacts on Armadillidiidae are exacerbated in dry conditions, where reduced moisture limits mobility and increases exposure, making individuals more susceptible to capture. During molting, when the is soft, vulnerability peaks, further emphasizing the role of conglobation. Evolutionarily, conglobation has been shaped by predation pressures as a key facilitating terrestrial life, balancing defense against predators with needs.

Reproduction and life cycle

Mating and brood care

In the family Armadillidiidae, typically occurs during the female's parturial molt cycle, when she becomes receptive to males. Males detect receptive females using chemical cues and climb onto their backs to perform copulation, which lasts from seconds to minutes and involves direct transfer via the first pair of pleopods into the female's gonopores. Females can store viable in their spermathecae for up to 12 months, allowing fertilization of multiple broods from a single event, with precedence often given to from the first male. Brood care in Armadillidiidae is provided exclusively by females through a specialized ventral marsupium, or brood pouch, formed during the parturial molt. Fertilized eggs, numbering 100–200 per brood, are incubated within the marsupium for 3–4 weeks until hatching into mancas (juvenile stage), during which time the female secretes nutrient-rich fluid to support development. Females typically produce 1–3 broods per year, depending on environmental conditions and individual health. Post-hatching, mancas remain in the marsupium for an additional 3–4 days or up to 1–2 weeks, receiving protection and nourishment before emerging independently. Sex determination in Armadillidiidae follows a ZW chromosomal system, but is significantly influenced by the endosymbiotic bacterium in many populations. In species like , feminizing strains of (e.g., wVulC) convert genetic males (ZZ) into phenotypic and functional females by inhibiting the differentiation of the androgenic gland, which is responsible for male development. This results in female-biased sex ratios, with infected populations producing 70–80% female offspring and natural sites showing as low as 20% males. Such manipulation enhances transmission, as the bacterium is maternally inherited, but it can reduce overall fertility in infected females despite increased reproductive investment per clutch. Males provide no after , contributing only gametes, while females invest substantially in offspring survival through brooding and post-emergence protection, such as sheltering mancas in burrows or moist habitats. This unilateral investment aligns with the species' polygynandrous , where females may mate with multiple males to ensure and sperm availability for successive broods.

Development stages

The post-embryonic development of Armadillidiidae species, such as , proceeds through direct development without a free-living larval stage, beginning immediately after eggs hatch within the female's marsupium. Upon , juveniles emerge as mancas, which are small, mobile individuals possessing 6-7 thoracic segments and lacking the seventh pair of pereopods; these mancas typically measure 1.5-2 mm in length and remain in the marsupium for a short period before release. From the manca stage, individuals undergo anamorphic growth via periodic , molting up to 15 times to reach adulthood, with each molt allowing for segment completion, development, and overall increase—typically doubling in over successive instars. The molting in these isopods is biphasic, where the posterior body sheds first, followed by the anterior portion a few days later, enabling continued respiration and locomotion during the vulnerable period; intermolt durations vary from 1-2 weeks in early juveniles to longer intervals in later stages. Sexual maturity is generally attained after 4-6 months, depending on species and conditions, at which point adults measure 10-18 mm in length; full adult morphology, including reproductive structures, is achieved by the final 1-2 molts. In the wild, lifespan averages 2-3 years, though individuals may live only 1.5 years under suboptimal conditions; in captivity, with stable humidity and nutrition, lifespans can extend to 3-5 years. Environmental factors significantly influence growth rates, with faster development occurring in moist habitats (50-80% ) and abundant organic detritus, where juveniles can complete molts more rapidly at optimal temperatures of 20-25°C. In contrast, dry or food-scarce conditions slow and reduce size at maturity; many temperate species overwinter as juveniles, resuming growth in spring after a dormancy period that may last 4-6 months.

Common names and cultural significance

Species in the Armadillidiidae family are known by a variety of common names worldwide, reflecting their distinctive ability to roll into a ball. In , they are most frequently called pill bugs, roly-polies, or rollie pollies. Other regional names include potato bugs, woodlice, slaters, doodle bugs, and chiggy-wigs. In the and parts of , woodlice is the predominant term. Culturally, Armadillidiidae have limited significance in or traditional narratives, with most references stemming from their commonality in everyday environments. They are often encountered in children's outdoor play and educational activities, where their conglobation behavior is a point of fascination. In some regional dialects, such as Appalachian and , "roly-poly" also serves as a colloquial term for a chubby person, derived from the bug's rounded form.

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  62. https://study.com/learn/lesson/armadillidiidae-facts-classification.html
  63. https://extension.msstate.edu/newsletters/bugs-eye-view/2020/pillbugs-vol-6-no-24
  64. https://www.nhm.ac.uk/discover/pill-bugs-terrestrial-isopods.html
  65. https://www.hillbillyslang.com/definitions/roly-poly/
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