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Tergum
Tergum
Tergum
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Tergites (with lateral paranota) of a polydesmid millipede

A tergum (Latin for "the back"; pl.: terga, associated adjective tergal) is the dorsal ('upper') portion of an arthropod segment other than the head. The anterior edge is called the 'base' and posterior edge is called the 'apex' or 'margin'. A given tergum may be divided into hardened plates or sclerites commonly referred to as tergites.[1]

In a thoracic segment, for example, the tergum may be divided into an anterior notum and a posterior scutellum. Lateral extensions of a tergite are known as paranota (Greek for "alongside the back") or carinae (Latin for "keel"), exemplified by the flat-backed millipedes of the order Polydesmida.

Kinorhynchs have tergal and sternal plates too, though seemingly not homologous with those of arthropods.[2]

Tergo-tergal is a stridulatory mechanism in which fine spines of the abdominal tergites are rubbed together to produce sound.[3] This process is known as abdominal telescoping.[3]

Examples

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  • Abdominal tergum (divided into several tergites) of a bee.
    Abdominal tergum (divided into several tergites) of a bee.
  • Seven sclerites distinctly visible on the back of a pregnant scorpion.
    Seven sclerites distinctly visible on the back of a pregnant scorpion.
  • A tergite of this wasp is labeled 19.
    A tergite of this wasp is labeled 19.
  • Thoracic tergites of various trilobites.
    Thoracic tergites of various trilobites.

See also

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References

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Further reading

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Tergum

View on Grokipedia
from Grokipedia
A tergum (plural: terga; from Latin tergum, meaning "the back") is the dorsal portion of a body segment in , other than the head, forming the upper part of the that covers and protects the segment. In , the tergum typically consists of hardened cuticular plates called tergites, which may be divided into sclerites and often feature spiracles for respiration, particularly in abdominal segments. These structures provide mechanical support, serve as attachment points for dorsal muscles, and contribute to the flexibility and segmentation of the body, enabling movement and protection against predators. The tergum is separated from the ventral by pleural regions and sutural lines, forming a complete encasement for each segment. Terga exhibit variations across classes; in , thoracic terga (such as the pronotum, mesonotum, and metanotum) are adapted for wing attachment and flight, while abdominal terga remain more uniform for protection. In crustaceans like , tergal plates form part of the in thoracic regions and arched structures in the , integrating with pleura for stability. Similar dorsal plates appear in other groups, such as myriapods (e.g., centipedes with overlapping tergal plates) and chelicerates (e.g., scorpions with seven mesosomal terga), highlighting the tergum's conserved role in the phylum's evolutionary diversity.

Definition and Terminology

Definition

In anatomy, a tergum is the dorsal portion of a body segment, excluding the head, forming the upper or back surface of the . The plural form is terga. This structure contrasts with the , which serves as its ventral counterpart covering the lower surface of the same segment. Terga typically consist of hardened sclerites, which are chitinous plates providing rigidity, though they may include membranous areas for flexibility between segments or in less sclerotized regions. Terga are found across the segmented body regions of , such as the and , contributing to the overall exoskeletal framework. In some cases, a tergum may be subdivided into distinct hardened plates known as tergites. The term tergum originates from the Latin word tergum, meaning "back" or "rear," and has been applied in to denote the dorsal surface of an arthropod body segment since the . Key related terms include tergite, which refers to a specific dorsal sclerite or hardened plate that forms part or all of the , particularly in the . In thoracic contexts, notum is often used as a for , emphasizing the dorsal plate of a thoracic segment, derived from Greek nōtos or Latin notum meaning "back." Historically, the terminology emerged in early anatomy studies during the 19th century and gained consistent application in entomological literature by the early , as standardized in glossaries like those by Snodgrass. A notable nomenclature distinction persists between tergum, which describes the entire dorsal region of a segment, and tergite, which specifies its constituent sclerites or subdivisions.

Morphology and Anatomy

In Insects

In insects, the tergum represents the dorsal sclerite of each body segment, forming part of the exoskeleton. Terga are found on both the thorax and abdomen, reflecting the segmented body plan. The thorax comprises three segments: the prothorax with its protergum (pronotum), the mesothorax with mesotergum (mesonotum), and the metathorax with metatergum (metanotum). The abdomen primitively consists of 11 segments, though terga are typically visible on segments 1 through 10 in many adult insects, with the terminal segments often reduced. Thoracic terga exhibit strong sclerotization, providing rigidity, and are frequently fused or modified across segments to accommodate locomotion structures; for instance, the mesonotum features processes that attach to bases. In contrast, abdominal terga are more lightly sclerotized and flexible, separated by intersegmental membranes that allow expansion and movement. Variations in tergal structure occur across subclasses. In , such as (order ), terga remain simple and weakly sclerotized, resembling abdominal patterns with secondary segmentation and lacking modifications for flight. In , the dominant winged subclass, thoracic terga are adapted to support s and associated flight musculature, with enhanced sclerotization for structural integrity. Certain display specialized tergal features. Tergal glands occur in some beetles, notably rove beetles (Staphylinidae) like Aleochara , where they produce secretions including pheromones. Additionally, eversible terga appear in larvae of certain beetles, such as Rhipsideigma raffrayi (Cupedidae), manifesting as protrusible lobes or ampullae on abdominal terga that aid in locomotion.

In Other Arthropods

In arachnids such as spiders and scorpions, terga are often reduced or fused, with the prosoma typically covered by a dorsal carapace that incorporates tergal elements from multiple segments, while the opisthosoma may feature distinct tergites that are sclerotized but flexible for movement. In scorpions, for example, the mesosoma bears seven tergites that provide dorsal protection, contrasting with the more segmented and rigid tergal structure seen in . In crustaceans, the represents a highly modified tergum that folds over the , originating from the fusion and expansion of dorsal sclerites in the head and thoracic regions to shield vital organs and gills. Abdominal terga, often integrated with lateral pleurae, form flexible plates that aid in swimming; in and , these terga are typically thin and translucent, allowing for abdominal flexion during locomotion, unlike the more robust, flight-adapted terga of . The pleurae project outward in species like lobsters to support pleopods for propulsion. Myriapods, including centipedes and millipedes, possess terga as broad, overlapping dorsal shields that confer flexibility and protection along the elongated trunk. In centipedes, these terga are sclerotized plates that posteriorly overlap adjacent segments, enabling rapid undulating movement through or . This overlapping configuration, distinct from the non-overlapping tergal arrangement in most , allows for greater body curvature during predation or evasion. Horseshoe crabs (xiphosurids) display terga as articulated dorsal plates in the opisthosoma, where up to five movable segmental tergites provide segmented flexibility beneath the fused prosomal . In modern species like Limulus polyphemus, these terga are partially fused posteriorly into a thoracetron, a solid plate homologous to multiple tergites, adapted for benthic locomotion. In , a specialized group, the tergum functions as a distinct opercular plate within the capitulum, pairing with the to seal the and protect feeding cirri. This tergum, often featuring a prominent for articulation, is a highly derived structure from ancestral tergal tissue, modified for sessile life in marine environments. Across groups, terga are homologous as dorsal elements but exhibit profound modifications, particularly in marine forms where fusion or expansion into carapaces enhances hydrodynamic efficiency and protection.

Functions and Evolutionary Role

Structural and Protective Functions

Terga function as the principal dorsal sclerites in body segments, imparting rigidity and structural support to maintain the integrity of the across , crustaceans, and other groups. Composed of sclerotized , these plates form a hardened dorsal framework that encloses and protects internal organs while allowing segmental flexibility through telescoping margins and pleural connections. In , for instance, terga contribute to overall body stability by integrating with ventral and lateral pleura to create a compartmentalized that withstands mechanical stresses during movement. A key structural role of terga involves serving as attachment sites for muscles critical to locomotion and other activities. In , the antecosta—a reinforced anterior on each tergum—anchors dorsal longitudinal muscles that enable segment retraction, abdominal undulation, and coordination with thoracic movements for and . These attachments facilitate efficient force transmission, such as in the tergo-sternal muscles that link dorsal and ventral elements for coordinated body flexion. In broader arthropods like crustaceans, terga similarly support swimmeret and musculature, enhancing in aquatic environments. Terga occupy the dorsal position relative to the ventral , completing the segmental enclosure. Protectively, sclerotized terga act as armored shields against predators, mechanical injury, and environmental hazards, with their hardened composition resisting compression and penetration. High degrees of sclerotization in the endocuticle enhance mechanical stability, deterring attacks from and vertebrates while also barring pathogens and . In , tergal setae—bristled structures on the dorsal surface—further bolster defense by entangling or deterring predators, particularly in larval stages. These setae often retain sensory capabilities, detecting tactile stimuli or vibrations to integrate with mechanoreception. Terga also integrate physiologically by housing respiratory and sensory elements, such as spiracles embedded in their margins for , and facilitating processes essential to growth. During , the flexible pleural regions adjacent to terga allow segmental expansion post-molt, accommodating increased body size without compromising structural integrity. Adaptations in tergal morphology reflect ecological demands: thickened, robust terga in burrowing arthropods provide reinforcement for soil penetration and resistance to abrasion, while in flying , relatively thinner terga minimize weight to optimize without sacrificing essential support.

Evolutionary Development

The tergum, as the dorsal sclerite of the , traces its origins to the early diversification of in the period, around 540 million years ago, when the dorsal of ancestral forms began to sclerotize into protective plates. This development marked a key adaptation from the soft, flexible integument seen in stem-group panarthropods, such as onychophorans, which exhibit segmented bodies with a dorsal epidermis but lack hardened sclerites, providing transitional evidence for the evolution of rigid dorsal structures in true arthropods. Fossil records from lagerstätten, including the , preserve these early dorsal cuticles in various euarthropod lineages, illustrating the initial segmentation and sclerotization that defined tergal morphology. A prominent fossil example of tergal evolution appears in trilobites, where the dorsal exoskeleton formed extensive shields composed of fused tergites, offering protection and structural support across the era. These calcified tergal structures, evident in genera like Olenellus from the early , demonstrate the consolidation of dorsal plates into a continuous shield, a feature that persisted until the group's extinction at the end of the Permian. In contrast, transitional forms in onychophorans and lobopodians, such as , show less pronounced dorsal specialization, with soft tissues that foreshadowed the tergum's role in segmentation without full sclerotization. Key evolutionary innovations involving terga include the proposed origin of insect wings, according to the tergal hypothesis, which posits that wings developed as paranotal expansions of the dorsal during the period, approximately 400 million years ago, enabling the pterygote radiation and aerial dispersal. The origin of insect wings remains a topic of debate, with alternative hypotheses including the pleural origin from limb exites (such as gills) and a dual origin combining elements of both. Similarly, in crustaceans, tergal fusion contributed to the formation of the , a protective dorsal resulting from the coalescence of multiple thoracic tergites, as evidenced by genetic regulatory modules conserved across pancrustacean lineages. These innovations highlight terga's versatility in adapting to diverse ecological niches. Evolutionary pressures driving tergal modifications included strong selection for sclerotization during the transition to terrestrial environments, where hardened dorsal plates helped mitigate and mechanical stress in early myriapods and hexapods around 420–400 million years ago. This process involved the incorporation of into the , enhancing rigidity and waterproofing, as seen in the fossil record of Devonian . In parasitic arthropods, such as fleas and lice, terga underwent reductions and flattening to facilitate host attachment and movement within confined spaces, reflecting degenerative evolution under relaxed selective pressures for robust dorsal armor. Overall, these patterns underscore terga's central role in arthropod phylogeny, from origins to adaptive radiations across marine, terrestrial, and parasitic lifestyles.

Notable Examples and Variations

In Specific Insect Orders

In Coleoptera, the beetles, the elytra represent hardened forewings that function as protective tergal covers over the , providing a rigid dorsal shield while allowing the membranous hindwings to fold beneath for storage. The abdominal terga are typically lightly sclerotized in the first five or six segments, enabling flexibility essential for movements such as oviposition in females. In some species, the terminal abdominal tergum forms a pygidium that may protrude beyond the elytra tips, as seen in families like . Lepidoptera, encompassing and moths, feature thoracic terga covered in minute scales that contribute to the order's characteristic coloration and patterning for display or . These scaled terga on the pro-, meso-, and metathorax support the attachment of scaled wings and enhance visual signaling during . Abdominal terga often bear specialized scent organs, such as androconial structures on specific segments, which release pheromones for mate attraction; for instance, in skipper butterflies (Hesperiidae), these organs are associated with tergal modifications. In , including bees, ants, and wasps, the thoracic terga are adapted to accommodate powerful flight musculature, with the mesonotum and metanotum forming expansive sclerites that anchor indirect flight muscles for wing oscillation. A distinctive feature in the suborder is the propodeum, the first abdominal tergum fused to the metathorax, creating a constricted "wasp waist" and forming part of the mesosoma that supports locomotion and stinging apparatus. This fusion enhances structural integrity for agile flight and deployment in parasitic wasps. Orthoptera, such as grasshoppers and crickets, exhibit a prominently expanded pronotal tergum—the dorsal sclerite of the —that often extends as a saddle-like shield over parts of the and anterior , offering protection from predators. Some species possess stridulatory files on the lateral edges of abdominal terga, particularly the third tergum, which are rubbed against the hind femora to produce defensive or calling sounds, as in certain . In the parasitic order Phthiraptera, the lice, terga are notably reduced and often fused into fewer, less segmented dorsal plates compared to free-living , reflecting adaptations to a dorso-ventrally flattened body for navigating host fur or feathers. This simplification of tergal sclerotization minimizes bulk while maintaining adhesion to the host.

In Crustaceans and Other Groups

In decapods such as crabs and lobsters, the functions as a fused dorsal tergal shield over the , providing protection for the gills housed in the underlying branchial chamber. The abdominal pleon features distinct terga on each , with the at the posterior end bearing uropodal extensions that incorporate tergal elements to form a tail fan for propulsion and steering during swimming. In isopods, including terrestrial species like pill bugs, the pereon terga exhibit specialized ridges along their anterior and posterior margins that facilitate ventral flexion, enabling the defensive conglobation or rolling into a protective . The posterior pleotelson represents a fusion of the sixth pleonite tergum with the , forming a rigid, arched dorsal structure that reinforces the body's enclosure during enrollment. Branchiopods, such as fairy shrimp, possess a trunk composed of multiple somites with dorsal terga that serve as attachment sites for the phyllopodous limbs, which beat rhythmically to generate water currents for filter feeding on suspended particles. Among chelicerates, solifuges display prosomal terga consolidated into dorsal shields that cover the anterior body region, offering mechanical protection during predatory activities in arid environments. In contrast, pycnogonids or exhibit highly reduced tergal structures, with the trunk showing minimal segmentation and fused dorsal elements that barely protrude beyond the elongated appendages. A notable variation occurs in sessile (Cirripedia), where the tergum constitutes one of the paired opercular valves, positioned adjacent to the to form a protective lid that seals the aperture and safeguards the thoracic cirri during tidal exposure.

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