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Acorn worm

Acorn worms, also known as enteropneusts, are benthic marine invertebrates in the class Enteropneusta within the phylum Hemichordata, distinguished by their elongated, worm-like bodies that typically range from a few centimeters to over 2 meters in length and feature a tripartite structure consisting of a muscular proboscis, a collar surrounding the mouth, and an elongated trunk.^[1]^[2]^[3] These animals inhabit intertidal zones to deep-sea sediments worldwide, where they burrow slowly using their proboscis to displace sand or mud, often leaving distinctive spiral fecal casts on the surface as they process organic detritus, bacteria, and microscopic algae through deposit or suspension feeding.^[1]^[2]^[3] Their anatomy includes pharyngeal gill slits—up to 200 in some species—for respiration and filter feeding, a stomochord that serves as a supportive structure analogous to a notochord, and a diffuse nervous system with dorsal and ventral nerve cords, reflecting primitive deuterostome organization.^[1]^[2] Reproduction in acorn worms is sexual and dioecious, with gametes released into the water for external fertilization, and many species exhibit a planktonic tornaria larva that facilitates dispersal before metamorphosis into the adult form.^[2] Ecologically, they play a vital role in marine sediment bioturbation and nutrient cycling, enhancing carbon sequestration by rapidly turning over seafloor deposits and contributing to the biological pump that transports organic matter to deeper ocean layers.^[3] Phylogenetically, acorn worms are significant as non-chordate deuterostomes, sharing traits like gill slits and a dorsal nerve cord with vertebrates, which positions Hemichordata as a key group for understanding the evolutionary transition from invertebrates to chordates, though molecular evidence suggests a closer affinity to echinoderms.^[1]^[2] With around 120 described species, ongoing deep-sea explorations continue to reveal new diversity, underscoring their importance in biodiversity and evolutionary biology.^[2]^[3]

Classification and Phylogeny

Taxonomic Classification

Acorn worms, scientifically known as enteropneusts, are classified within the phylum Hemichordata and the class Enteropneusta.^[4] This class encompasses approximately 111 described species, reflecting ongoing discoveries particularly in deep-sea environments.^[5] Enteropneusta forms part of the deuterostome clade Ambulacraria, sharing a close phylogenetic relationship with echinoderms.^[6] The class Enteropneusta is organized into four main families: Harrimaniidae, Ptychoderidae, Spengelidae, and Torquaratoridae.^[4] The family Harrimaniidae, which predominates in shallow-water habitats, includes around 30 species.^[5] Ptychoderidae, often found in tropical and subtropical regions, comprises approximately 40 species.^[5] The deep-sea family Torquaratoridae, first recognized in the mid-2000s with species discoveries accelerating from 2010 onward, contains about 10 species.^[7] Spengelidae, with fewer species, is less diverse but includes notable genera in coastal settings.^[4] Prominent genera across these families include Saccoglossus (Harrimaniidae), a model organism for developmental studies; Balanoglossus (Ptychoderidae), widely distributed in intertidal zones; and Schizocardium (Spengelidae), known for its distinctive gonadal structure.^[6]^[8] Recent taxonomic expansions have added deep-sea representatives, such as Quatuoralisia malakhovi (Torquaratoridae), described from specimens in the Bering Sea.^[7]

Evolutionary Relationships

Acorn worms, or enteropneusts, belong to the phylum Hemichordata, which forms the sister group to Echinodermata within the clade Ambulacraria.^[9] This clade, in turn, represents the basal group to Chordata within the larger deuterostome lineage Deuterostomia, highlighting the evolutionary proximity of hemichordates to vertebrates.^[10] Early ribosomal RNA (rRNA) analyses established this relationship in the late 1990s, with subsequent phylogenomic studies reinforcing the monophyly of Ambulacraria through analyses of hundreds of genes across diverse taxa.^[11] Molecular evidence from genome sequencing has further elucidated these affinities. The 2015 draft genomes of two acorn worm species, Saccoglossus kowalevskii and Ptychodera flava, revealed extensive conserved synteny with chordates and other bilaterians, including deeply conserved non-coding sequences and developmental genes such as those involved in dorsoventral patterning (e.g., BMP-CHORDIN).^[6] Post-2020 phylogenomic analyses, incorporating chromosome-level assemblies and expanded transcriptomic data, have consistently confirmed Ambulacraria monophyly, with hemichordates and echinoderms sharing derived genomic features like rearranged Hox clusters while resolving prior uncertainties about deep deuterostome branching.^[12]^[13] The fossil record provides direct evidence of hemichordate antiquity, with the earliest known specimens dating to the Cambrian period. A 2024 study described Cambrobranchus pelagobenthos from the early Cambrian Haiyan Lagerstätte in China (~520 million years ago, Ma), preserving larval and juvenile stages that indicate a pelago-benthic lifestyle similar to modern acorn worms.^[14] Middle Cambrian fossils like Spartobranchus tenuis from the Burgess Shale (~505 Ma) further document tubicolous enteropneusts, bridging the gap between early deuterostomes and extant forms. Divergence timelines within Hemichordata align with these ancient origins. The major enteropneust families, represented by the aforementioned Saccoglossus and Ptychodera lineages, separated approximately 370 million years ago, based on molecular clock estimates from genome divergence rates.^[6] Post-2010 discoveries of deep-sea acorn worms, including the family Torquaratoridae, have revealed specialized lineages adapted to abyssal environments, expanding understanding of hemichordate diversification in the Mesozoic and Cenozoic eras.

Physical Characteristics

Body Plan

Acorn worms, or enteropneusts, possess a characteristic tripartite body plan divided into three distinct regions along the anteroposterior axis: the proboscis, collar, and trunk. This organization is a defining feature of the class Enteropneusta within the phylum Hemichordata, facilitating their benthic lifestyle in marine environments.^[15] The overall structure is soft and worm-like, with the body wall supported by a coelomic system that includes a protocoel in the proboscis, mesocoels in the collar, and metacoels in the trunk, aiding in hydrostatic movement and burrowing.^[16] The anterior proboscis is typically acorn-shaped and muscular, functioning primarily for burrowing into soft sediments and as a sensory organ for detecting environmental cues. It contains a fluid-filled coelom (protocoel) that provides turgidity for extension and retraction during locomotion and feeding activities. In some species, the proboscis also assists in deposit feeding by collecting particles via its ciliated surface.^[16] The collar, a short neck-like constriction posterior to the proboscis, encircles the mouth, which opens ventrally at its anterior margin into the stomodeal region. This area houses a circumferential nerve ring that coordinates sensory and motor functions, and the collar's coelom (mesocoel) supports its role in stabilizing the head during feeding and movement.^[15]^[16] The trunk forms the bulk of the body, an elongated region subdivided into the anterior branchial portion (containing gill slits for respiration and filter feeding), a middle gonadal region, and a posterior intestinal region for digestion and waste expulsion. The trunk's metacoel provides internal support, and its surface is mucus-covered to protect against abrasion and facilitate gliding through substrates. Some enteropneust species, particularly in the family Ptychoderidae, bear branched tentacles on the collar's posterior margin, which extend into the water column to capture suspended particles via mucociliary mechanisms.^[16]

Size and Variation

Acorn worms exhibit a wide range of body sizes, typically spanning from less than 1 mm to over 1.5 m in length, reflecting their diverse ecological adaptations across marine environments.^[17]^[18] The smallest known species is Meioglossus psammophilus, a miniaturized interstitial form discovered in 2012 from shallow tropical sands in the West Atlantic, measuring up to 0.6 mm in body length and notable for its asexual reproduction by transverse fission.^[17] In contrast, the largest species, Balanoglossus gigas, can reach lengths of 1.5 m, inhabiting elongated burrows in shallow subtropical waters.^[18] Morphological variations are pronounced between shallow-water and deep-sea species, with the former often featuring compact, burrowing forms adapted for sediment-dwelling lifestyles, while deep-sea members of the family Torquaratoridae display semitransparent, gelatinous bodies that enable part-time demersal drifting or floating above the seafloor.^[19] These gelatinous torquaratorids, observed at depths of 2,900–3,500 m, can extend up to 1 m and use ciliary gliding for slow movement over soft sediments.^[19]^[20] Adaptations to specific habitats further highlight this diversity, including extreme miniaturization in interstitial species like M. psammophilus that navigate sand grains, and elongated trunks in burrowing shallow-water forms such as B. gigas that facilitate extensive U-shaped tunnels.^[17]^[18] Recent 2024 studies on the deep-sea torquaratorid Quatuoralisia malakhovi from the Bering Sea reveal additional variation, with separate sexes and a complex male reproductive system featuring lobed testes in genital wings and beak-shaped sperm, underscoring reproductive adaptations in gelatinous, epibenthic deep-sea lineages.^[7] These differences build on the tripartite body plan common to all enteropneusts—proboscis, collar, and trunk—but diverge significantly in proportions and textures to suit habitat demands.^[19]

Anatomy

Digestive System

Acorn worms primarily function as deposit feeders, collecting fine organic detritus and sediment particles using mucus secreted from the proboscis, which traps food as the ciliated surface sweeps over the substrate. In species such as Saccoglossus kowalevskii, the proboscis gathers flocculent material, directing it via ciliary currents toward the mouth, while some deep-sea forms like Quatuoralisia malakhovi utilize expanded collar lips equipped with ciliary grooves to capture particles ranging from 1–200 µm, including planktonic diatoms, enabling a semi-suspension feeding mode.^[21]^[22] The mouth opens ventrally on the anterior wall of the collar, leading into a short buccal cavity that connects directly to the pharynx within the trunk.^[23] The pharynx features numerous U-shaped gill slits that channel food-laden water into a ventral groove, from which particles pass into the esophagus and then the intestine.^[24] Acorn worms possess no distinct stomach; instead, the straight tubular intestine serves as the primary site for digestion and absorption, often featuring hepatic caeca or sacculations in the anterior portion for enhanced processing.^[25] Digestion relies on ciliary action to transport and sort particles throughout the gut, complemented by extracellular enzymatic breakdown in the midgut.^[25] In species with hepatic caeca, such as Balanoglossus, glandular cells secrete enzymes including amylase, maltase, lipase, and proteases to hydrolyze carbohydrates, lipids, and proteins within the detritus.^[25] Conversely, in Saccoglossus lacking such caeca, food particles undergo intracellular digestion after phagocytosis by intestinal epithelial cells.^[22] The heavily ciliated gut wall, with minimal musculature, propels undigested material posteriorly as compact fecal pellets or cords.^[21] The intestine terminates at a dorsal anus positioned at the posterior end of the trunk, through which waste is expelled to the exterior.^[23] In deep-sea species like Quatuoralisia malakhovi, the digestive system exhibits reductions, including a flattened pharynx without a ventral food groove and metameric hepatic sacculations adapted for processing larger particles in low-sediment environments, with fecal cords serving as temporary anchors.^[21]

Circulatory System

Acorn worms possess an open circulatory system, in which colorless, acellular blood circulates through tissue sinuses rather than being confined to a network of closed vessels.^[22] This blood lacks hemoglobin or other respiratory pigments, resulting in its transparent appearance and limiting efficient oxygen transport primarily to diffusion across body tissues.^[22] The system facilitates the distribution of nutrients and other fluids via lacunae, which serve as open spaces within the tissues for blood flow, without the presence of true capillaries.^[26] A key component is a heart-like contractile structure located within the proboscis coelom, specifically a muscular sac in the protocoel surrounding the stomochord that pulsates to propel blood.^[22] Blood flows anteriorly through the dorsal vessel from the trunk toward this heart region and then posteriorly through the ventral vessel beneath the digestive tract, with connecting vessels linking these major channels to the surrounding tissue sinuses.^[27] This unidirectional flow pattern supports basic fluid exchange, though the overall system's reliance on body movements and diffusion constrains long-distance transport efficiency.^[26]

Respiratory System

The respiratory system of acorn worms relies on pharyngeal gill slits located dorsally in the branched pharynx of the trunk, enabling gas exchange through a water-based mechanism. These slits number from 10 to over 100 pairs per side, varying by species and increasing with body size in larger individuals.^[28] Each gill is a U-shaped structure formed by the folding of gill bars (tongue bars), with thin walls that facilitate diffusion of oxygen into the hemichordate's open circulatory system and expulsion of carbon dioxide; the walls are lined with cilia that drive water currents and simultaneously trap food particles for filtration.^[29]^[30] Water enters the mouth and is pumped through the pharyngeal slits via ciliary action along the lateral gill bars, creating a flow that supports both respiration—where gills contribute significantly to oxygen uptake, especially under high demand—and filter feeding, though the skin surface also aids in supplemental gas exchange.^[30]^[31] This dual functionality integrates the pharynx with digestive processes, as filtered particles are directed toward the esophagus while oxygenated water enhances overall metabolic efficiency.^[2]

Nervous System

The nervous system of acorn worms (Enteropneusta) is highly decentralized, lacking a centralized brain and instead consisting of a diffuse basiepidermal nerve plexus that extends throughout the body, integrating sensory and motor functions in a distributed manner.^[32] This plexus features regionalized classes of neurons with intricate morphologies, including long-range projections that span the length of the body, enabling coordinated responses without a dominant central processing center.^[32] Unlike simpler nerve nets in cnidarians, the system shows unexpected complexity, with over three neuropeptides colocalizing in specific regions, such as the proboscis base, which acts as an integrative hub for sensory-motor integration.^[32] The primary neural structures include paired dorsal and ventral nerve cords running along the trunk, connected anteriorly by a prebranchial nerve ring, while the collar region houses a tubular collar cord that serves as a potential analog to more centralized neural structures in other deuterostomes.^[33] The dorsal cord contains glutamatergic neurons, whereas the ventral cord is characterized by histaminergic neurons, facilitating distinct signaling pathways for locomotion and environmental response.^[32] The collar cord exhibits conserved anteroposterior and mediolateral patterning across enteropneust species, with genes like Six3/6, Otx, and Dlx expressed in larval stages that persist into adulthood, underscoring its role in coordinating collar-mediated activities.^[33] Sensory capabilities are modest and primarily chemosensory, with flask-shaped sensory neurons bearing cilia densely tiling the proboscis epithelium to detect chemical, mechanical, and light stimuli, but lacking eyes or other complex sensory organs.^[32] These chemosensory cells contribute to photosensitivity and environmental navigation, with no evidence of specialized visual structures in adults.^[32] Behaviors such as burrowing and ciliary arrest in response to trunk stimulation are reflex-based, mediated by this decentralized network to support substrate interaction and escape responses.^[32]

Excretory System

Acorn worms lack a distinct tubular excretory system but possess a glomerulus, also known as the proboscis gland, located in the proboscis coelom adjacent to the heart-like structure and stomochord. This organ consists of a network of blood vessels and podocyte-like cells that filter nitrogenous wastes and other metabolic byproducts from the circulating blood. The filtered fluid is then excreted through a small pore at the tip of the proboscis.^[34]^[26]

Skeletal Support

Acorn worms utilize a hydrostatic skeleton for primary structural support, relying on pressurized coelomic fluid within their tripartite body cavities to maintain shape and facilitate locomotion. The protocoel in the proboscis, paired mesocoels in the collar, and metacoel in the trunk collectively generate internal pressure that works antagonistically with longitudinal and circular muscles to enable extension, contraction, and burrowing through soft substrates.^[35]^[36] A specialized Y-shaped nuchal skeleton, formed by collagenous rods at the proboscis-collar junction, provides additional rigidity and serves as attachment sites for surrounding musculature. This structure features a ventral stem originating from the stomochord and bifurcating into two dorsal horns that extend into the collar, reinforcing the anterior body region during feeding and movement.^[37]^[36] Unlike many marine invertebrates, acorn worms possess no mineralized hard parts, allowing exceptional flexibility that aids in navigating burrows and evading predators in sediment-rich habitats.^[38] In deep-sea species, particularly gelatinous forms within the family Torquaratoridae, the nuchal skeleton is typically reduced to small plates or entirely absent, aligning with their fragile, low-density body adaptations for epibenthic drifting in abyssal environments.^[39]

Chordate Affinities

Shared Anatomical Features

Acorn worms, or enteropneusts, share several key anatomical features with chordates that have traditionally been interpreted as underscoring their close phylogenetic relationship within the deuterostomes, although recent phylogenetic analyses have questioned the monophyly of the clade.^[40] These traits, primarily observed in the pharyngeal and axial regions, provide evidence for a common evolutionary origin. The most striking similarity is the presence of pharyngeal gill slits, which are homologous to the branchial slits of chordates. In acorn worms, these U-shaped slits line the pharynx and number from a few to over 100 pairs, depending on the species; they facilitate both respiration, by allowing oxygen uptake from seawater, and filter-feeding, by directing water flow through the pharyngeal basket.^[41] Another shared feature is the endostyle-like structure within the pharynx, a glandular groove that secretes mucus to ensnare particulate food, much like the endostyle in urochordates and cephalochordates. This organ in acorn worms is a ciliated ventral groove lined with iodine-concentrating cells, paralleling the chordate endostyle's role as a precursor to the vertebrate thyroid gland, which also iodinates proteins.^[42] The nervous system of acorn worms includes a diffuse network with remnants of a dorsal nerve cord, forming a hollow tubular structure in the collar region that extends posteriorly. This configuration resembles the dorsal hollow nerve cord of chordates, where it serves as the central neural axis, though in acorn worms it is less centralized and incorporates radial nerves from the collar.^[43]^[44] The stomochord, an anterior extension of the pharyngeal endoderm into the proboscis, acts as a supportive rod and has been interpreted by some as an analog to the chordate notochord due to its position and mesoderm-derived elements. However, its developmental origin from pharyngeal tissue rather than mesendoderm, and lack of expression of key notochord genes like Brachyury, has led to ongoing debate regarding true homology, with alternatives suggesting it derives from an ancestral pharyngeal structure.^[45]

Developmental and Genetic Similarities

The tornaria larva, characteristic of indirect-developing acorn worms such as Ptychodera flava and Schizocardium californicum, exhibits ciliated bands that facilitate locomotion and particle capture for feeding, along with an anterior apical organ serving sensory functions.^[6]^[46] These features parallel the ciliated bands and apical sensory structures observed in the planktonic larvae of chordates, particularly the amphioxus (Branchiostoma spp.), which also rely on ciliary mechanisms for swimming and sensory integration during early development.^[47]^[48] The presence of these shared larval traits underscores a common deuterostome heritage, where such structures likely represent ancestral adaptations for pelagic dispersal.^[6] Acorn worms displaying indirect development undergo a prolonged free-swimming tornaria phase lasting weeks to months before metamorphosis, akin to the larval stage in amphioxus that transitions from planktonic feeding to benthic settlement.^[6] This developmental trajectory contrasts with direct-developing hemichordates like Saccoglossus kowalevskii but aligns closely with cephalochordate life cycles, highlighting conserved indirect strategies that delay adult morphology until environmental cues trigger transformation.^[47] Such parallels suggest that the tornaria larva retains primitive deuterostome characteristics, providing a model for inferring early chordate evolution.^[49] Genome analyses of acorn worms have revealed shared genetic underpinnings with chordates, including conserved Hox gene clusters that pattern the anterior-posterior axis during embryogenesis.^[6] In Saccoglossus kowalevskii and Ptychodera flava, these clusters exhibit syntenic arrangements similar to those in amphioxus and vertebrates, with expression domains reflecting deuterostome-wide regulatory logic.^[6] Additionally, NK homeobox genes such as nkx2.1 and nkx2.2 are expressed in the pharyngeal endoderm of developing embryos, mirroring their roles in chordate gill slit formation and thyroid development, thus supporting molecular homology in pharyngeal patterning.^[6] Recent analyses of mitochondrial genomes in hemichordates reveal gene arrangements and codon usage biases highly similar to those in vertebrates, supporting shared evolutionary pressures and deep homology within Deuterostomia.^[50] Post-2020 phylogenomic studies, including chromosome-level assemblies of Ptychodera flava and Schizocardium californicum, demonstrate extensive macrosynteny with chordate genomes, deriving from an ancestral deuterostome complement of 24 linkage groups.^[12] These assemblies highlight conserved Hox and pharyngeal gene clusters with low transposable element density, reinforcing hemichordate-chordate affinities through shared developmental regulatory networks.^[12] Cis-regulatory element analyses further reveal ancient conservation in gene expression dynamics for axis formation and mesoderm specification across deuterostomes.^[13]

Ecology and Behavior

Habitat and Distribution

Acorn worms (Enteropneusta) are exclusively marine and benthic invertebrates, inhabiting soft-sediment environments across a broad depth gradient from intertidal zones to abyssal and hadal depths exceeding 8,000 meters.^[3] They primarily occupy the ocean floor, where they burrow into substrates such as mud, sand, or silt, often forming U-shaped burrows that facilitate their lifestyle in coastal and deep-sea settings.^[51] This benthic adaptation allows them to thrive in diverse marine ecosystems, from shallow, wave-exposed shores to the extreme pressures of the deep seafloor.^[5] Their global distribution spans all major ocean basins, with approximately 111 described species reported from numerous marine ecoregions worldwide.^[51]^[52] Highest species diversity occurs in temperate coastal regions, particularly the Cold Temperate Northeast Pacific (16 species) and Northern European Seas, though significant richness is also noted in tropical areas like the Northwest Atlantic.^[51] The family Torquaratoridae exemplifies deep-sea specialization, with species distributed from about 350 meters to over 4,000 meters in sedimentary habitats of the Atlantic, Pacific, and Indian Oceans.^[5] In contrast, most shallow-water species are concentrated along continental margins in temperate and tropical latitudes.^[51] A subset of acorn worms, including the miniaturized Meioglossus psammophilus (maximum length 0.6 mm), occupies interstitial spaces within sand grains on shallow tropical subtidal bottoms, such as those at 2–15 meters depth off Belize and Bermuda.^[23] These meiobenthic forms highlight the phylum's versatility in fine-grained, high-energy coastal sediments. A 2024 study revealed additional populations across tropical regions, suggesting cryptic species diversity.^[23]^[53] Recent discoveries underscore their presence in extreme deep-sea environments, including a new locality for the torquaratorid Quatuoralisia malakhovi at 1,957–2,289 meters on the slopes of Piip Volcano in the Bering Sea, reported in 2024.^[54] Enteropneusts have also been documented in hadal zones, such as an unidentified harrimaniid in the genus Stereobalanus at 7,426–7,654 meters in the Japan Trench, expanding known depth records for the group.^[55]

Feeding Mechanisms

Acorn worms, or enteropneusts, primarily employ deposit feeding as their main mechanism for acquiring nutrients, ingesting sediment and extracting organic detritus through a mucociliary system. The proboscis, a muscular and ciliated anterior structure, extends from the burrow or substrate surface to sweep or probe mud and sand, where glandular cells secrete mucus that traps fine particles such as organic matter and microorganisms. These particles, typically ranging from 1–200 μm in size, are then transported posteriorly via ciliary action along the proboscis and into the mouth located between the proboscis and collar, allowing efficient collection in low-nutrient benthic environments.^[56]^[57]^[58] Some species also utilize suspension feeding, particularly those with specialized collar structures, to capture plankton and suspended particulates from the water column. In taxa like Saccoglossus and certain Torquaratoridae, the collar features tentacles or lateral lips lined with ciliary grooves that generate feeding currents and filter particles, directing them through an internal channel to the pharynx for ingestion. Mucus nets formed on these structures enhance particle adhesion, with evidence from particle-tracing experiments showing uptake of suspended materials such as carmine or diatoms. The gills in the pharynx contribute to this filtration by straining larger debris during water passage.^[56]^[57]^[59] Burrowing behavior supports both feeding modes by creating structured habitats that facilitate food access and ventilation. Many enteropneusts construct U- or J-shaped tubes in soft sediments, positioning the proboscis at one opening to probe for deposits while the posterior end at the other generates currents through muscular contractions and ciliary beating, drawing oxygenated water and suspended food inward. This setup, observed in species like Saccoglossus kowalevskii and Balanoglossus clavigerus, minimizes energy expenditure during foraging by confining movements to burrow maintenance and localized probing.^[56]^[58] Enteropneusts maintain a low metabolic rate, with oxygen consumption rates adapted to detritus-poor deep-sea and intertidal sediments containing as little as 5.4% organic matter, enabling survival on sparse resources through efficient intracellular digestion in the hepatic region. This energy budget prioritizes ciliary over muscular activity, supporting sustained feeding in oligotrophic conditions without high caloric demands.^[57]^[59]

Reproduction and Life Cycle

Sexual Reproduction

Acorn worms, or enteropneusts, are gonochoristic, possessing separate male and female individuals, with gonads developing as paired structures within the coelomic cavities of the trunk region.^[7] The gonads consist of numerous simple or lobed sacs aligned along the dorsal and ventral sides of the pharyngeal region in the trunk, opening externally through pores in the epidermis to facilitate gamete release.^[60] Sexual reproduction occurs via external fertilization, with adults functioning as broadcast spawners that release gametes directly into the surrounding seawater. Females typically initiate spawning by ejecting large numbers of oocytes embedded in gelatinous mucus strings or masses, which attract males to release sperm in response, allowing fertilization in the water column.^[60] In some species, such as Balanoglossus misakiensis, spawning events are synchronized with tidal cycles, occurring during the transition from high to low tide to optimize gamete dispersal and fertilization success.^[61] Spawning behaviors differ between shallow-water and deep-sea species. In shallow, benthic forms like Saccoglossus and Ptychodera, mass synchronous releases of gametes are common during seasonal breeding periods, often triggered by environmental cues such as temperature or lunar phases in tropical populations.^[62] Deep-sea torquaratorids, however, exhibit reduced or modified spawning, with some species displaying externalized ovaries or brooding structures that may limit mass release and suggest adaptations to sparse populations and low encounter rates for mates.^[19] Recent histological studies have provided detailed insights into the male reproductive system, particularly in the deep-sea species Quatuoralisia malakhovi. The testes are lobed organs housed within genital wings along the trunk, featuring a germinative epithelium lined with spermatogenic cells progressing from spermatogonia to spermatozoa, which possess an acorn-shaped head, beak-like acrosome, and elongated flagellum. Monociliary muscle cells encase the gonad pores, enabling coordinated contractions to expel sperm during spawning.^[7]

Asexual Reproduction

Asexual reproduction in acorn worms (Enteropneusta) is rare and not the primary mode of propagation, which is typically sexual in most species.^[16] It has been documented primarily through mechanisms like paratomy and fragmentation, allowing for the regeneration of complete individuals from body parts. These processes are observed mainly in miniaturized, interstitial species adapted to sandy or sediment-rich environments, as well as some deep-sea forms, rather than being widespread across the group.^[53] Paratomy, a form of transverse fission where the body divides into segments that each regenerate into a full organism, was first reported in 2012 in the miniaturized species Meioglossus psammophilus, an interstitial enteropneust discovered in the Philippines.^[17] This species, measuring only about 1 mm in length, exhibits paratomy as its dominant reproductive strategy, with no evidence of sexual reproduction such as females or eggs in examined populations. Subsequent observations over the following decade, including a 2024 study across 14 tropical and subtropical populations (spanning the Caribbean, Red Sea, Indian Ocean, and East China Sea), confirmed paratomy in M. psammophilus and extended the finding to eight newly described cryptic species within the Meioglossus genus, all showing morphological stasis despite genetic divergence.^[53] In these lineages, sperm cells are present but their role remains unclear, possibly serving as an energy reserve rather than for fertilization.^[53] Fragmentation, or architomy, involves the spontaneous breaking of the body into pieces, each of which regenerates missing structures to form a new individual, and has been observed in several other species. For instance, the ptychoderid Balanoglossus simodensis from Japan undergoes asexual reproduction via fragmentation, where the anterior and posterior body regions separate and regenerate independently, a process detailed through morphological studies in 2010.^[63] Similarly, the deep-sea swimming species Glandiceps hacksi exhibits fragmentation leading to asexual propagation, with post-fragmentation regeneration completing the formation of new worms.^[64] These modes highlight the regenerative capabilities of enteropneusts, though they appear confined to specific ecological niches and have not been broadly reported in larger, more typical acorn worm species.^[16]

Larval Development

Acorn worms, or enteropneusts, typically exhibit indirect development through a planktonic tornaria larva following external fertilization. The tornaria is a free-swimming, telotrochous larva characterized by a prominent posterior telotroch—a ring of long, compound cilia that propels the larva through the water column—and a complex circumoral ciliary band that loops around the mouth for feeding on planktonic particles. Hatching occurs early, often within 1-2 days post-fertilization, as a ciliated gastrula that develops into the definitive tornaria over several days, reaching sizes of 1-9 mm. This larval stage can persist for weeks to months in the plankton, with laboratory observations documenting durations up to 85 days in species like Schizocardium karankawa, during which the larva grows, develops an apical sensory organ, and forms initial gill slits.^[8]^[15]^[60] Metamorphosis marks the transition from the tornaria to the juvenile worm and is a gradual process initiated in the plankton, typically after 50 days in feeding species. During this phase, larval structures such as portions of the ciliary bands regress, while the anterior region evaginates to form the proboscis (the "acorn" structure) and collar, and the trunk elongates with the development of definitive gill pores—up to six in early juveniles. The telotroch may be retained temporarily for locomotion during early settlement. Settlement occurs when the metamorphosing larva descends to the benthos, burrowing into soft sediments to establish as a juvenile worm, often 1.5-2 mm long, with the process completing by around 85 days post-fertilization in observed cases.^[8]^[15]^[65] Developmental modes vary across enteropneust families, with direct development—lacking a prolonged planktonic tornaria—reported in some shallow-water species like Saccoglossus kowalevskii (Harrimaniidae), where large eggs hatch as lecithotrophic larvae that settle after brief swimming.^[60] In deep-sea lineages such as Torquaratoridae, large oocyte sizes (up to nearly 2 mm) were previously thought to indicate direct development without a free larval stage, potentially as an adaptation to nutrient-poor abyssal environments; however, a 2025 study suggests diverse modes, including lecithotrophic and planktotrophic larvae, with the enigmatic giant Planctosphaera pelagica potentially representing planktotrophic tornaria larvae of torquaratorids.^[60]^[66] The tornaria's banded ciliation and tripartite body plan echo early chordate larval features, underscoring hemichordate contributions to deuterostome evolution.^[60]

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Recent molecular phylogenomic studies have provided evidence to support the sister group relationship between Ambulacraria and Xenacoelomorpha, and some even ...
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Enteropneusts (acorn worms) are hemichordates, the sister group to echinoderms. Together they form the clade Ambulacraria, which is closely related to chordates ...An Early Cambrian... · Systematic Paleontology · Discussion
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The development and metamorphosis of the indirect developing ...
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An Anatomical Description of a Miniaturized Acorn Worm ...
Nov 7, 2012 · With a maximum body length of 0.6 mm, it is the first microscopic adult enteropneust known, a group otherwise ranging from 2 cm to 250 cm in ...
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An Anatomical Description of a Miniaturized Acorn Worm ...
Here we describe a new enteropneust species inhabiting the interstices among sand grains in shallow tropical waters of the West Atlantic.
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https://palaeo-electronica.org/content/2024/5163-origin-of-the-hemichordate-larva
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ABSTRACT Ten individuals of an enteropneust in the family Torquaratoridae were videotaped between 2,900 and 3,500 m in the Eastern Pacific—one drifting a ...
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Torquaratoridae - Wikipedia
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Jul 19, 2012 · Enteropneusts in the family Torquaratoridae were imaged using ... floating ~1 m above the sea floor. Living specimens of Y. purpurata ...
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Male reproductive system of the deep-sea acorn worm Quatuoralisia ...
Oct 8, 2024 · Eleven species of torquaratorids have already been described [1, 5,6,7,8,9,10,11], and according to the photo and video data, many ...<|separator|>
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https://repository.si.edu/bitstreams/3e23ad87-ae23-4cc6-ba27-832a793a9ff8/download
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Saccoglossus kowalevskii - Lander University
The gut wall almost entirely lacks musculature but its epithelium is heavily ciliated and food is transported by ciliary currents.<|control11|><|separator|>
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https://doi.org/10.1134/S0012496623600100
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https://lanwebs.lander.edu/faculty/rsfox/invertebrates/saccoglossus.html
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Balanoglossus: Habitat, Development and Affinities
It is also claimed that hepatic caeca secrete amylase, maltase, lipase and weak protease. The enzymes digest the organic particles in the mud or sand.
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[PDF] CILIATED ORGANS FUNCTION IN DETRITIVORE ACORN WORMS
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Head regeneration in hemichordates is not a strict recapitulation of ...
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Hemichordate models - ScienceDirect.com
Hemichordates are marine animals with two different lifestyles. The solitary, free-living enteropneusts or acorn worms resemble polychaetes or earthworms.
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The development and metamorphosis of the indirect developing ...
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(PDF) The gill slits and pre‐oral ciliary organ of Protoglossus ...
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Hemichordates' diffuse “skin brain” shows unexpected complexity
Sep 20, 2023 · The paper demonstrates that the acorn worm nervous system is anything but an “unstructured nerve plexus” and that there is a hidden ...
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Neuronal patterning of the tubular collar cord is highly conserved ...
Aug 1, 2017 · However, the worm-shaped enteropneusts possess a less complex nervous system featuring only a short hollow neural tube, whereby homology to its ...<|control11|><|separator|>
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The rôle of the body fluid in relation to movement in soft ... - Journals
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A detailed description of the development of the hemichordate ...
Sep 6, 2013 · In the present study, we investigated the development of all tissues in an enteropneust, Saccoglossus kowalevskii by using modern morphological techniques.
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Using experimental decay of modern forms to reconstruct the early ...
Jun 4, 2015 · The collagenous nuchal skeleton and gill bars are by far the most decay-resistant structures in enteropneust anatomy (Fig. 3). These structures ...
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Biological Diversity 9
Fluids within the coelomic cavity carry out the function of diffusing substances and gases. Gas exchange occurs across the skin gills and tube feet. Nitrogenous ...
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Deep-sea acorn worms (Enteropneusta) from the Bering Sea with the description of a new genus and a new species of Torquaratoridae dominating soft-bottom communities
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A stem-deuterostome origin of the vertebrate pharyngeal ...
Jun 15, 2011 · 1. Introduction. Pharyngeal gill slits are one of the four classic chordate anatomical synapomorphies (along with a dorsal hollow nerve cord, a ...
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Evolution and Development of the Chordates - Oxford Academic
We review the development of chordate characters in hemichordates and present new data characterizing the pharyngeal gill slits and their cartilaginous gill ...
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The origin and evolution of chordate nervous systems - PMC
Thus, the dorsal nerve cord of hemichordates is homologous to the chordate nerve cord. (c) The ancestor of the Ambulacraria plus Chordata had a ventral ...<|separator|>
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https://www.sciencedirect.com/science/article/pii/S096098222500805X
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On a Possible Evolutionary Link of the Stomochord of ...
As a group closely related to chordates, hemichordate acorn worms are in a key phylogenic position for addressing hypotheses of chordate origins.
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Development and Neural Organization of the Tornaria Larva of the ...
The tornaria nervous system with ciliary bands and an apical organ is rather similar to the echinoderm bipinnaria larvae.
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Evolution of the chordate body plan: New insights from phylogenetic ...
1 A and B), reproduce sexually, and either have a tornaria larva or are direct developers (17, 21). ... It has long been recognized that ascidian tadpole larvae ...
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Report The Adult Body Plan of Indirect Developing Hemichordates ...
Jan 9, 2017 · The ectoderm comprises an anterior sensory organ (the apical organ), a looped circum-oral ciliary band used in feeding and swimming, and a ...
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https://pmc.ncbi.nlm.nih.gov/articles/PMC5673098/
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https://bioone.org/journals/zoological-science/volume-21/issue-1/0289-0003_2004_21_69_DANOOT_2.0.CO_2/Development-and-Neural-Organization-of-the-Tornaria-Larva-of-the/10.2108/0289-0003%282004%2921%5B69:DANOOT%5D2.0.CO%3B2.full
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Biogeography and adaptations of torquaratorid acorn worms ...
The enteropneust family Torquaratoridae, discovered in 2005, has the fewest species of the four living families. It is composed of seven species that live ...Missing: count | Show results with:count
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Response of Saccoglossus kowalevskii (Phylum
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Digestive System Anatomy and Feeding Mechanism of ... - PubMed
The digestive system was anatomically studied in the deep-sea enteropneust Quatuoralisia mala-khovi. It was shown that lateral collar lips are twisted in such ...
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[PDF] Hemichordata, Class Enteropneusta: The Acorn Worms
The class Enteropneusta includes about 70 species distributed into four ... Species with large eggs in the genera Harrimania and Protobalanus may also ...
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A Histological Investigation of the Maturation of the Acorn Worm, an ...
In the present study, four experiments were conducted to learn about the synchronization for spawning/spermiation in this acorn worm. As a result, however ...
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Reproductive Periodicity, Spawning Induction, and... : Journal of ...
The phylum Hemichordata encompasses two classes of animals, the solitary Enteropneusta (acorn worms) and the colonial Pterobranchia ( Benito and Pardos, 1997 ).Materials And Methods · Gene Cloning And Sequence... · Results And Discussion
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Circumtropical distribution and cryptic species of the meiofaunal ...
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Morphological characterization of the asexual reproduction in the ...
Aug 27, 2010 · The acorn worm Balanoglossus simodensis reproduces asexually by fragmentation and subsequent regeneration from the body fragments.
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Biology of the Swimming Acorn Worm Glandiceps hacksi ... - BioOne
May 1, 2012 · Enteropneusta is a class of the phylum Hemichordata, accommodating ca. 80 species assigned to four families, Harrimaniidae, Spengelidae ...
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The embryology, metamorphosis, and muscle development of ...
Apr 19, 2023 · Remarks Of the four known genera included in this family—Schizocardium, Willeyia, Glandiceps and Spengelia, only one species, a result of the ...
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[PDF] Collin et al. Page 1 of 31 Unexpected Molecular and Morphological ...
The development and metamorphosis of the indirect developing acorn worm Schizocardium californicum (Enteropneusta: Spengelidae). Frontiers in Zoology, 15(1) ...