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Parasitiformes

Parasitiformes is a superorder of arachnids within the subclass Acari (mites and ticks), constituting one of the two major evolutionary lineages of mites alongside . This diverse group includes approximately 12,500 described species distributed across four suborders: Opilioacarida (primitive, ricinuleid-like mites with about 50 species), Holothyrida (heavily sclerotized, tropical predatory mites with around 30 species), Ixodida (ticks, with over 900 species that are obligate parasites of vertebrates), and (the largest suborder, with over 11,000 species, many of which are free-living predators or associates of and vertebrates). Members of Parasitiformes are characterized by their pincer-like adapted for piercing or grasping, a lack of body segmentation into distinct tagmata beyond the gnathosoma (head) and opisthosoma (), and typically four pairs of legs in adults. Biologically, they exhibit a range of feeding strategies, from predatory behaviors targeting nematodes, , and other arthropods to on vertebrates, with some engaging in phoresy (hitching rides on host ) or scavenging. The generally involves a hexapod larval stage followed by octopod nymphal instars and adults, with reproduction often via spermatophores and occasional in certain taxa. The suborder Ixodida, encompassing hard ticks (family ) and soft ticks (family ), stands out for its medical and veterinary significance, as these ectoparasites feed on blood and serve as vectors for pathogens causing diseases such as , , and African tick-bite fever. Mesostigmatid mites, meanwhile, include economically important species like predatory phytoseiids used in biological control of agricultural pests and parasitic forms such as the poultry red mite (Dermanyssus gallinae). Phylogenetically, Parasitiformes form a monophyletic supported by molecular data, including rRNA sequences, though the broader monophyly of Acari remains under debate in recent analyses. Overall, Parasitiformes play critical roles in ecosystems as predators, parasites, and disease transmitters, with ongoing research focusing on their hotspots and evolutionary relationships.

Overview

Definition and Scope

Parasitiformes is a superorder of arachnids within the subclass Acari, representing one of the two primary evolutionary lineages of mites alongside . This grouping encompasses a diverse array of small to medium-sized arthropods, primarily mites and ticks, that play crucial roles in ecosystems as parasites, predators, and decomposers. The superorder was formally established by Reuter in 1909, building on earlier classifications of related mite groups. A key morphological feature distinguishing Parasitiformes from other mites is the presence of , which are respiratory openings typically located on the posterior region of the , with one to four pairs facilitating tracheal . These structures vary in position and number across the superorder's subgroups, such as the four pairs in primitive forms like opilioacarids. The scope of Parasitiformes includes parasitic like ticks that feed on vertebrates, predatory mites that control pest populations, and free-living forms inhabiting and , contributing substantially to and ecological balance. Over 12,000 have been described, primarily within the orders , Ixodida, Holothyrida, and Opilioacarida, with projections estimating 100,000 to 200,000 undescribed in total.

Diversity and Distribution

Parasitiformes encompass approximately 12,000 to 12,500 described species, with estimates suggesting a total diversity of 100,000 to 200,000 species when accounting for undescribed taxa. The suborder dominates this diversity, comprising over 11,600 described species across more than 70 families, far outnumbering the contributions from other suborders such as Ixodida (ticks, around 900 species) and the smaller Opilioacarida and Holothyrida (each with fewer than 50 species). This imbalance highlights Mesostigmata's role as the primary driver of Parasitiformes' overall , with many species functioning as predators, parasites, or soil inhabitants. Members of Parasitiformes exhibit a , inhabiting virtually all terrestrial biomes worldwide, from the arctic tundra to tropical rainforests. While predominantly terrestrial, some species, particularly ticks in the Ixodida, form associations with aquatic or marine hosts such as amphibians, reptiles, and mammals, enabling indirect presence in non-terrestrial environments. Geographic patterns reveal highest in tropical regions, where warm and humid conditions support a proliferation of mite habitats and host interactions. In contrast, Ixodida species are particularly widespread in temperate zones, facilitated by their reliance on hosts that thrive in these areas, leading to seasonal activity peaks influenced by . Endemism within Parasitiformes is notable in certain lineages, such as Opilioacarida, where several species are restricted to arid or semi-arid environments. For instance, members of the genus Neocarus are confined to specific regions in , including the , where they inhabit caves, soil, and litter in xeric habitats. These localized distributions underscore the influence of environmental specificity on the group's , contrasting with the broader dispersal of more adaptable groups like .

Taxonomy

Classification Hierarchy

The classification hierarchy of Parasitiformes positions it as a superorder within the subclass Acari of the class Arachnida, encompassing a diverse array of mites and ticks. The complete taxonomic hierarchy is as follows: Kingdom Animalia > Phylum Arthropoda > Subphylum > Class Arachnida > Subclass Acari > Superorder Parasitiformes (Reuter, 1909). Historically, the grouping of Parasitiformes was first formalized by Reuter in , who proposed it as an alternative to Gamasiformes based on morphological affinities among certain lineages, including those previously classified under broader categories like Ixodida (established by Leach in 1815). Subsequent classifications evolved through morphological analyses, but modern revisions incorporating molecular data, such as nuclear rRNA sequences, have robustly confirmed the of Parasitiformes, resolving earlier uncertainties about its internal relationships and distinguishing it from the sister superorder . Membership in Parasitiformes is defined by shared morphological synapomorphies, including an emergent tritosternal plate (a , finger-like arising from the third sternal ) and the presence of corniculi (paired, horn-like structures on the subcapitulum in larvae). These traits facilitate fluid feeding and sensory functions, distinguishing Parasitiformes from other acarine groups. Debated aspects of its placement include the status of certain subgroups, such as Ixodida (ticks), which were historically treated as a separate order but have been reclassified as a suborder within Parasitiformes in contemporary phylogenies supported by both morphological and molecular evidence. This adjustment reflects broader shifts toward recognizing Parasitiformes as a cohesive superorder comprising four main suborders: Opilioacarida, Holothyrida, Ixodida, and .

Major Suborders and Families

The suborder represents the most diverse group within Parasitiformes, encompassing over 11,000 described species across numerous families. These mites exhibit a wide range of lifestyles, from free-living predators in and litter to parasitic forms on and vertebrates. Key families include Phytoseiidae, which comprises predatory mites widely used in biological control against phytophagous pests like spider mites on crops. Another notable family is Varroidae, featuring , an ectoparasite that infests colonies, feeding on bee and vectoring viruses that contribute to colony collapse. The suborder Ixodida, commonly known as ticks, includes approximately 1,007 species (as of 2025) divided among three families: Ixodidae (hard ticks, ~786 species), Argasidae (soft ticks, ~220 species), and Nuttalliellidae (1 species). Hard ticks in are characterized by a scutum covering the dorsal surface and typically follow one-, two-, or three-host life cycles, attaching to hosts for extended feeding periods. Soft ticks in lack a scutum and undergo multi-host cycles with rapid feeding bouts, often in nests or burrows. The single species in Nuttalliellidae, Nuttalliella namaqua, is a rare tick with intermediate features between hard and soft ticks. A prominent example is (Ixodidae), the black-legged tick, which serves as the primary vector for , the causative agent of in . Opilioacarida forms a basal lineage within Parasitiformes, with approximately 65 described (as of 2024) confined to the single family Opilioacaridae. These relatively large mites (1.5–2.5 ) are primarily soil-dwelling predators and , inhabiting leaf litter, under stones, and hypogean environments in semi-arid and tropical regions, including arid Mediterranean habitats like phrygana vegetation. The suborder Holothyrida is the smallest and rarest, comprising approximately 30 described species (as of 2025) across families including Holothyridae and Neothyridae, with a distribution centered on former Gondwanan landmasses such as , the Pacific-Indian Ocean islands, and the Neotropics. These large mites (up to 7 mm) are saprophagous, feeding on decaying including fungi, and predaceous on small like nematodes, typically in moist leaf litter and mosses. Among the suborders, Mesostigmata stands out for its unparalleled diversity, vastly outnumbering the others and occupying diverse ecological niches. In contrast, Ixodida holds the greatest economic significance due to the medical and veterinary impacts of tick-borne diseases.

Morphology and Anatomy

External Structure

The external morphology of Parasitiformes is characterized by a distinct division of the body into two primary regions: the gnathosoma and the idiosoma. The gnathosoma, also known as the capitulum, is the anterior feeding apparatus that includes the chelicerae for piercing and grasping, paired palps for manipulation, and associated mouthparts adapted for various feeding modes such as blood-sucking or predation. In contrast, the idiosoma forms the main body tagma, which bears the legs and is further segmented in many taxa into the podosoma (anterior portion with the first three pairs of legs) and the opisthosoma (posterior portion housing reproductive and digestive openings). Opilioacarida exhibit more primitive, visible segmentation of the idiosoma with transverse conscuticula and a cluster of multiple eyes, while Holothyrida possess a heavily sclerotized, dome-shaped holodorsal shield. This segmentation enhances flexibility and specialization for locomotion and attachment in diverse microhabitats. The exoskeleton of Parasitiformes varies in degree of sclerotization across suborders, from weakly sclerotized in Opilioacarida to heavily sclerotized in Holothyrida and certain and , consisting of a chitinous that provides protection against and mechanical damage. In hard ticks (suborder , family ), the dorsal surface features a prominent —a hardened, shield-like plate that covers the entire dorsum in males but only the anterior portion in females, allowing expansion during blood engorgement. Soft ticks (family ) lack this , instead possessing a leathery, less sclerotized that permits repeated engorgement without structural rupture. This variation in sclerotization reflects adaptations to parasitic lifestyles, with the serving as a defensive barrier in ixodids. Adults of Parasitiformes typically bear four pairs of ambulatory legs, each equipped with claws and sensory setae for navigation, host attachment, and environmental sensing. These setae include tactile and chemoreceptive structures distributed across the legs and body, facilitating behaviors like questing in ticks. A specialized feature in ixodid ticks is Haller's organ, located on the tarsus of the first pair of legs, which comprises a pit with olfactory sensilla for detecting host kairomones, , and pheromones from afar. Size varies widely across the group, from as small as 0.1 mm in minute species to over 30 mm in engorged female ticks, underscoring their ecological versatility from soil dwellers to large parasites.

Internal Systems

The in Parasitiformes primarily relies on tracheae that branch throughout the body, delivering oxygen directly to tissues, with external openings known as located laterally on the opisthosoma. These typically number 1 to 4 pairs and are positioned dorsolaterally or ventrolaterally, a configuration that contrasts with the more anteriorly placed observed in the related group . This arrangement facilitates efficient in diverse habitats, from environments to parasitic lifestyles. The operates as an open hemocoel, where serves as the circulatory fluid, bathing organs directly rather than being confined to vessels. A dorsal heart, located along the midline of the opisthosoma, pumps anteriorly through ostia (valved openings) and distributes it via lacunae—open channels formed by connective tissues—before it returns posteriorly. This system supports nutrient transport and waste removal, adapted to the low metabolic demands of many sedentary or parasitic species within the group. Sensory systems in Parasitiformes are specialized for host detection and environmental navigation, with notable adaptations across subgroups. In ticks (Ixodida), Haller's organ on the tarsus of the first pair of legs houses chemoreceptors, including sensilla that detect host-derived kairomones, , and pheromones, enabling long-range host location. These structures integrate olfactory and hygrosensory functions, with capsule and rim sensilla contributing to humidity and odor discrimination. In , vibration detection occurs via specialized setae on the legs, allowing predatory and free-living species to sense substrate movements of prey or mates while in ambush postures. The digestive system is adapted for fluid or semi-fluid diets, featuring a muscular pharyngeal pump that generates suction to draw in food through the and hypostome. This pump, equipped with valves, propels ingested material via the to the , the primary site of digestion and absorption. In parasitic forms like ticks, the includes diverticula for storing large blood meals, with epithelial cells secreting proteases and facilitating detoxification to handle high-protein, iron-rich diets without clogging.

Reproduction and Development

Reproductive Biology

In Parasitiformes, sexual dimorphism manifests prominently in morphological and physiological traits that support reproductive roles. Within the suborder Ixodida (ticks), adult females are substantially larger than males, particularly after engorgement on blood meals, enabling greater egg production capacity; for instance, unfed adult females of Ixodes ricinus measure 3.0–3.6 mm in length, expanding to 10–12 mm when engorged, compared to 2.4–2.8 mm for males. In some Mesostigmata, arrhenotoky—a form of haplodiploidy—results in haploid males developing from unfertilized eggs, leading to genetic dimorphism where males inherit only maternal chromosomes and exhibit reduced recombination. Mating strategies in Parasitiformes reflect diverse evolutionary adaptations to ensure sperm transfer. In Opilioacarida, males produce stalked spermatophores—sperm packets deposited on the substrate—which females actively retrieve and insert into their genital openings, facilitating indirect transfer without physical penetration. Limited observations in Holothyrida suggest similar indirect sperm transfer via spermatophores, though details remain sparse due to the rarity of these mites. Fertilization across Parasitiformes is internal, with females storing in spermathecae to fertilize eggs sequentially during oviposition, typically resulting in clutches of dozens to thousands of eggs laid in protected sites. occurs commonly in ticks under stressful conditions, such as isolation or host scarcity, allowing unmated females to produce viable offspring; in Amblyomma rotundatum, parthenogenetic lineages are all-female and thelytokous, with diploid eggs developing without fertilization to sustain populations. is less documented in other suborders but reported sporadically in under laboratory conditions. Sex ratios in Parasitiformes are frequently female-biased, particularly in basal groups employing like certain , where arrhenotokous females selectively fertilize eggs to favor diploid daughters over haploid sons, optimizing resource allocation for higher reproductive output in kin-selected contexts. This bias can shift toward equilibrium under high male mortality or density-dependent factors, though empirical studies confirm a consistent skew toward females in many natural populations.

Life Cycle Stages

The life cycle of Parasitiformes generally progresses through four primary developmental stages: , , , and , resembling a form of anamorphic where the number of legs increases from six in the larva to eight in subsequent stages. In Opilioacarida and Holothyrida, the cycle mirrors that of , with eggs laid in or , hatching into hexapod larvae that develop through protonymph and deutonymph stages into adults, though comprehensive data are limited for Holothyrida. In the suborder Ixodida (ticks), the egg stage involves the deposition of large clutches (often thousands) by engorged females, into hexapod larvae after weeks to months depending on and . These larvae then feed, molt into octopod nymphs (typically one , though some species have additional nymphal stages), and finally develop into adults, with reproductive onset occurring shortly after the final molt in females. Variations in the Ixodida life cycle are prominent, with one-host species (e.g., Rhipicephalus spp., formerly Boophilus) completing larval, nymphal, and adult development on a single host, molting off-host between stages, while three-host species (e.g., Ixodes spp.) require separate hosts for each post-egg stage, dropping off after engorgement to quest for new hosts. In contrast, the suborder Mesostigmata exhibits more direct development, often without a prolonged free-living larval stage; the cycle includes an egg, a brief hexapod larva, followed by two or three octopod nymphal instars (protonymph, deutonymph, and sometimes tritonymph), leading to the adult, enabling rapid completion in predatory or soil-dwelling species. The total duration of the life cycle varies widely, from weeks in some under optimal conditions (e.g., 8–10 days at 22–24°C) to several years in Ixodida, where unfed stages can persist for months or years influenced by environmental factors. , a mechanism for overwintering, commonly occurs in tick eggs, larvae, or nymphs, arrested by short photoperiods or low temperatures to synchronize development with host availability. Molting, or , in Parasitiformes is hormonally regulated, primarily by ecdysteroids that initiate apolysis ( separation) and trigger the shedding of the old , followed by sclerotization where the new hardens through protein cross-linking and pigmentation for structural integrity. This process occurs off-host in Ixodida after feeding-induced engorgement, with post-molt hardening completing within hours to days, enhancing protection and mobility in the subsequent stage.

Ecology and Behavior

Habitats and Interactions

Parasitiformes mites occupy a variety of microhabitats, primarily in terrestrial environments where moisture and support their survival. Free-living within the suborder are commonly found in soil litter, humus layers, and decaying organic material such as dung or rotting wood, thriving in ecosystems with high humidity and moderate temperatures. In contrast, ectoparasitic forms, including many ticks of the suborder Ixodida, prefer habitats associated with hosts, such as leaf litter, grassy meadows, and understories where they can quest for attachment. The suborder Opilioacarida inhabits arid or semi-arid soils, often under stones or in litter, adapting to drier conditions compared to other Parasitiformes. Holothyrida mites are found in leaf litter, mosses, and under stones in moist tropical and subtropical s, from near to about 2000 m elevation. Ecological interactions among Parasitiformes span commensal, mutualistic, and antagonistic relationships, influencing community dynamics in their habitats. Many engage in phoresy, a commensal where they attach to or other arthropods for dispersal to new microhabitats, such as from one patch to another, without harming the carrier. Mutualistic interactions occur in some cases, like certain mites (e.g., Poecilochirus and Macrocheles) associated with burying (family Silphidae) that reduce competition for beetle larvae by feeding on fly eggs and maggots in carcasses, in exchange for transport to new resources. Antagonistic interactions are prevalent, with acting as generalist predators on nematodes and small arthropods in agroecosystems and food webs, helping regulate pest populations. Opilioacarida are free-living scavengers with occasional predatory behavior, but no phoresy or mutualistic associations are known. Host specificity varies across Parasitiformes, shaping their ecological roles. Ticks in Ixodida exhibit preferences for mammals and , with some showing high specificity—such as those targeting particular ungulates—while others are generalists across vertebrate classes, influencing disease transmission in shared habitats. ectoparasites often show broader host ranges, infesting nests or dens of and mammals, whereas free-living forms interact nonspecifically with . Microhabitat adaptations in Parasitiformes enhance survival in specialized niches. Burrowing species, particularly some soil-dwelling Mesostigmata, feature reduced sclerites and flexible cuticles that facilitate movement through or , minimizing risks in confined spaces. Dispersal is often humidity-dependent, with phoretic behavior increasing in low-moisture conditions to access distant, suitable habitats via host carriers.

Feeding Strategies

Parasitiformes exhibit a range of feeding strategies adapted to their diverse ecological roles, primarily encompassing , predation, and scavenging or behaviors across suborders such as Ixodida, , Holothyrida, and Opilioacarida. These strategies leverage specialized for penetration and ingestion, with fluid-feeding predominant in parasitic forms and more varied ingestion in free-living ones. Ingestion mechanisms often involve a pharyngeal for drawing in liquids or liquefied contents, while primarily occurs in the via enzymatic breakdown. In the suborder Ixodida (ticks), hematophagy is the dominant parasitic strategy, where adults and immature stages pierce host skin using telescoping chelicerae that cut and anchor into tissue to form a feeding pool of blood. Saliva secreted during feeding contains anticoagulants, such as serine protease inhibitors and FXa blockers, which prevent clotting and enable prolonged attachment, often lasting days. This facilitates rapid engorgement, with females increasing body weight up to 100 times through blood intake, supported by the pharyngeal pump's suction action. In contrast, the parasitic mite Varroa destructor (Mesostigmata) employs histophagy, using chelicerae to incise host bee tissue and feed on fat body cells or hemolymph via a pharyngeal pump operating at approximately 4.5 cycles per second. Blood or tissue fluids are then directed to the midgut, where cysteine and aspartic proteases initiate digestion within acidic endosomes. Predatory feeding is prevalent in free-living Mesostigmata, where are adapted to grasp and pierce prey such as nematodes or other , injecting digestive fluids to liquefy internals before via the pharyngeal . Some uropodoid Mesostigmata graze on fungal mycelia or spores, using robust to scrape and ingest solid fungal material, which is partially digested in the . In the primitive suborder Holothyrida, feeding is primarily predatory or scavenging, targeting small or organic , with suited for tearing solid foods that are enzymatically processed in the . Opilioacarida employ a scavenging strategy, feeding on arthropod carcasses, , and occasionally small prey, using adapted for ingesting solid . These strategies highlight the group's evolutionary flexibility, from fluid to solid-particle ingestion, often referencing the internal pharyngeal for efficient nutrient uptake.

Evolutionary History

Origins and Fossil Record

The origins of Parasitiformes, a major of mites within the Acari, are estimated through analyses to date back to the late , approximately 320 million years ago during the Permian period, with a 95% of 273–384 million years ago. This timeline predates the major radiations of arachnids and aligns with the diversification of terrestrial lineages following the colonization of land by chelicerates. These estimates are calibrated using constraints from across Acari and related groups, highlighting a deep evolutionary history for Parasitiformes despite a sparse direct record. The fossil record of Parasitiformes is limited, with definitive specimens primarily preserved in amber due to the clade's small size and often soft-bodied nature, which hinders preservation in sedimentary deposits. The oldest confirmed fossils appear in mid-Cretaceous amber, around 100 million years ago, representing a significant gap between molecular estimates and physical evidence. Preservation challenges include the rarity of soft tissues in compression fossils and the need for exceptional conditions like resin entrapment to capture fine morphological details such as and leg setation. inclusions from this period provide the most reliable data, offering insights into early morphologies and potential associations. Key early fossils include an opilioacarid , Opilioacarus groehni, from dated to approximately 99 million years ago ( stage), marking the oldest record for the Opilioacarida superfamily and underscoring the antiquity of basal Parasitiformes lineages. Similarly, deutonymphs of a sejid (Mesostigmata: Sejidae) from the same deposit, dated to about 100 million years ago, represent the earliest valid evidence for the diverse order. For ticks (Ixodida), a larval argasid from , approximately 90–94 million years old ( stage), provides the first record of this parasitic group and effectively doubled the known fossil age of Parasitiformes at the time of its description. Putative earlier traces from the , such as ambiguous impressions, remain debated and unconfirmed due to identification difficulties. These specimens reveal primitive features like reduced sclerotization in some forms, suggesting evolutionary transitions toward modern parasitic lifestyles.

Phylogenetic Relationships

The of Parasitiformes is well-supported by molecular and morphological evidence. Analyses of nuclear ribosomal RNA genes, particularly 18S rRNA, recover the group as a strongly supported across multiple studies. Mitochondrial genes like subunit I (COI) provide additional corroboration, aligning with rRNA-based topologies in confirming the clade's integrity. Morphologically, key synapomorphies include the presence of posterior stigmata, which serve as respiratory openings positioned behind the coxae of legs III and IV, distinguishing Parasitiformes from other arachnids. Within the broader Acari, Parasitiformes forms the to , together comprising the traditional monophyletic Acari. This relationship is upheld in ribosomal and mitochondrial phylogenies, though some phylogenomic datasets suggest potential of Acari relative to other arachnids like spiders. The basal split between Parasitiformes and Acariformes is estimated to have occurred around 400 million years ago in the late , based on relaxed analyses calibrated with chelicerate fossils. Inter-suborder relationships within Parasitiformes position Opilioacarida and Holothyrida as successive basal lineages, with the comprising Mesostigmata and Ixodida emerging as derived. This topology is derived from rRNA sequence data, where Holothyrida + Ixodida receives strong support, and Opilioacarida branches near the base, potentially sister to the remaining suborders.

Human and Ecological Significance

Medical and Veterinary Impact

Members of the Parasitiformes, particularly ticks in the order Ixodida, serve as primary vectors for numerous zoonotic pathogens that pose significant threats to human health. For instance, the blacklegged tick () transmits , the spirochete bacterium responsible for , which manifests as a multisystem inflammatory disorder often beginning with rash, fever, and , potentially progressing to neurological, cardiac, or complications if untreated. Similarly, the American dog tick () and Rocky Mountain wood tick (Dermacentor andersoni) transmit , causing , a potentially fatal rickettsial illness characterized by fever, headache, , and vascular damage that can lead to organ failure without prompt antibiotic intervention. In the United States, alone affects an estimated 476,000 individuals annually through diagnosis and treatment, underscoring the substantial burden of these tick-borne infections. In , Parasitiformes inflict considerable morbidity and mortality on and companion animals, exacerbating agricultural challenges. in , caused by intraerythrocytic protozoans such as Babesia bovis and Babesia bigemina, is transmitted primarily by the tropical bont (Rhipicephalus microplus) and results in , fever, , and high mortality rates in naïve herds, particularly in endemic regions of , , and . In dogs, arises from infection with Anaplasma phagocytophilum, vectored by Ixodes scapularis, leading to symptoms including lethargy, fever, joint pain, and , which can mimic other tick-borne illnesses and require serological confirmation for diagnosis. Globally, tick-borne diseases in animals contribute to economic losses estimated at approximately $19 billion annually, encompassing costs from reduced productivity, treatment, and mortality in sectors, including control measures. Mites within Parasitiformes, such as in the family Varroidae, indirectly impact human health by threatening populations essential for agriculture. This ectoparasitic mite feeds on hemolymph, weakening adult bees and transmitting viruses like , which collectively contribute to —a phenomenon involving the sudden disappearance of worker bees, leaving hives unsustainable. The resulting decline in managed colonies has led to deficits affecting crop yields, with global agricultural losses tied to pollinator health estimated in the billions, amplifying food security concerns. Emerging threats from Parasitiformes are amplified by , which facilitates the geographic expansion of vector species into new regions. The Asian longhorned tick (Haemaphysalis longicornis), first detected in in 2017, has spread to more than 20 states across the eastern and midwestern U.S., with recent detections in , , and as of 2025; it is capable of parthenogenetic reproduction and transmitting pathogens like Theileria orientalis that cause bovine theileriosis, posing risks to health and potentially human-associated diseases. Warmer temperatures and altered precipitation patterns are projected to broaden suitable habitats for such invasive ticks, increasing exposure risks in previously unaffected areas of .

Economic and Conservation Roles

Parasitiformes, particularly ticks and mites, impose substantial economic burdens on , , and sectors worldwide. These burdens form part of the global economic impact of tick-borne diseases estimated at $14-30 billion annually. Mite pests within Parasitiformes contribute to losses in sectors such as apiculture and production. These impacts highlight the need for targeted management to safeguard and economic stability. In biocontrol applications, predatory mites from the family Phytoseiidae play a vital role in (IPM) programs, effectively suppressing populations of herbivorous s on crops such as tomatoes, strawberries, and ornamentals. Species like Phytoseiulus persimilis are commercially reared and released to prey on spider mite eggs and immatures, reducing the need for chemical interventions and thereby saving millions in agricultural production costs through prevented yield losses. These biological agents enhance by maintaining ecological balance in agroecosystems, with successful IPM implementations demonstrating reduced reliance and improved long-term profitability. From a perspective, soil-dwelling Parasitiformes, including mesostigmatid mites, serve as key bioindicators of , reflecting , nutrient cycling, and disturbance levels in forests, grasslands, and agricultural lands. Declines in their diversity and abundance signal , such as from or , underscoring their importance in monitoring efforts. Overharvesting or indiscriminate removal of predatory mites as natural enemies can disrupt food webs, leading to and reduced resilience in ecosystems where these arthropods regulate pest populations. Management of Parasitiformes increasingly incorporates sustainable practices to combat emerging resistance to traditional acaricides like , a synthetic widely used against ticks and mites but now facing widespread resistance in species such as . Resistant strains have been documented globally, prompting shifts toward integrated approaches including habitat rotation—such as crop diversification and —to disrupt mite life cycles and promote natural enemy populations. These strategies, combined with selective use, foster long-term ecological and economic viability in affected sectors.