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Glabrousness
Glabrousness
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Glabrousness (from Latin glaber 'bald, hairless, shaved, smooth, etc.') is the technical term for a lack of hair, down, setae, trichomes, or other such covering. A glabrous surface may be a natural characteristic of all or part of a plant or animal, or be due to loss because of a physical condition, such as alopecia universalis in humans, which causes hair to fall out or not regrow.

In botany

[edit]
Smooth rupturewort (Herniaria glabra) - a creeping plant with glabrous leaves and stems

Glabrousness or otherwise, of leaves, stems, and fruit is a feature commonly mentioned in plant keys; in botany and mycology, a glabrous morphological feature is one that is smooth and may be glossy. It has no bristles or hair-like structures such as trichomes. In anything like the zoological sense, no plants or fungi have hair or wool, although some structures may resemble such materials[which?].

The term "glabrous" strictly applies only to features that lack trichomes at all times. When an organ bears trichomes at first, but loses them with age, the term used is glabrescent.

In the model plant Arabidopsis thaliana, trichome formation is initiated by the GLABROUS1 protein. Knockouts of the corresponding gene lead to glabrous plants. This phenotype has already been used in gene editing experiments and might be of interest as a visual marker for plant research to improve gene editing methods such as CRISPR/Cas9.[1][2]

Leaves emerging from buds of Oldenburgia grandis are densely tomentose with a dense indumentum, but their upper surface is glabrescent; as seen here they lose their white felt as they mature.

In zoology

[edit]
Naked mole-rat (Heterocephalus glaber) in a zoo.

In varying degrees most mammals have some skin areas without natural hair. In humans, glabrous skin is found on the ventral portion of the fingers, palms, soles of feet and lips, which are all parts of the body most closely associated with interacting with the world around us,[3] as are the labia minora and glans penis.[4] There are four main types of mechanoreceptors in the glabrous skin of humans: Pacinian corpuscles, Meissner's corpuscles, Merkel's discs, and Ruffini corpuscles.

The Naked mole-rat (Heterocephalus glaber) has evolved skin lacking in general, pelagic hair covering, yet has retained long, very sparsely scattered tactile hairs over its body.[3] Glabrousness is a trait that may be associated with neoteny.[citation needed]

Within entomology, the term glabrous is used to refer to those parts of an insect's body with are lacking in setae (bristles) or scales.[5]

See also

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References

[edit]
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Glabrousness

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Glabrousness is the state or condition of being glabrous, characterized by a smooth surface lacking , , pubescence, trichomes, or other similar projections, a term widely used in to describe specific tissues in animals and . In vertebrates, including humans, glabrous is prominently found on the palms of the hands, soles of the feet, ventral surfaces of the digits, , nipples, and umbilicus, where it serves essential sensory and protective functions without the presence of hair follicles. This type of is notably thicker than hairy skin elsewhere on the body, featuring a robust and overall epidermal thickness that can reach up to 1.5 millimeters, with the adding approximately 3 millimeters in depth, enabling it to withstand mechanical stress, , and while forming calluses. Key properties of glabrous skin include its high density of mechanoreceptors—such as Meissner corpuscles for light touch and texture , Merkel cells for sustained , Ruffini endings for skin stretch, and Pacinian corpuscles for —concentrated in the dermal papillae to facilitate fine tactile and grip security through dermatoglyphic ridge patterns and abundant eccrine sweat glands. These adaptations make glabrous areas critical for activities requiring precise manipulation, such as grasping objects, and for via in arteriovenous anastomoses during heat exposure. In , glabrousness refers to structures, such as leaves, stems, or fruits, that are entirely free of hairs, scales, or glandular indumentum, resulting in a glossy or smooth texture that can influence retention, pest resistance, and photosynthetic efficiency. This trait is genetically determined and varies across , often contrasting with pubescent surfaces that provide insulation or defense mechanisms.

Definition and Terminology

Definition

Glabrousness is the biological condition characterized by a smooth surface devoid of hairs, down, setae, trichomes, or other similar projections, resulting in a hairless or bald appearance. This state applies across various organisms, where the absence of such structures imparts a sleek texture to affected surfaces like , leaves, or stems. The term glabrous specifically denotes a complete and persistent lack of hair-like features from the outset, distinguishing it from glabrescent, which refers to surfaces that initially possess such structures but lose them progressively with age, maturity, or environmental influence. This differentiation is crucial in precise biological descriptions to avoid ambiguity in characterizing developmental or ontogenetic changes. Glabrousness occurs in multiple contexts, including as an innate natural trait in certain species, as a consequence of genetic mutations—such as those causing total hair loss akin to in animals—or as an adaptation to environmental pressures like in arid or hot climates. In animals, rare cases of lead to fully glabrous skin through autoimmune mechanisms. Historically, the concept of glabrousness has been integral to biological since the Linnaean era, where it served as a key descriptor for distinguishing lacking pubescence (hairy covering) from their pubescent counterparts, aiding in and identification within genera. This usage emphasized surface texture as a diagnostic morphological trait in early systematic and .

Etymology

The term "glabrousness" derives from the Latin adjective glaber, meaning "bald," "," or "hairless," a word attested in and rooted in the Proto-Indo-European *glhdro- denoting . The adjective "" entered English in the 1630s, primarily through medical and botanical texts to describe surfaces lacking hair or similar projections. By the mid-17th century, it had become established in , with early usages appearing around 1640 in descriptions of anatomical and natural features. The term's adoption in taxonomy accelerated in the 18th century, particularly through the works of , who incorporated glaber and its variants into Latin plant descriptions and starting in the 1750s. For instance, Linnaeus named species such as Herniaria glabra in his (1753), using "glabra" to indicate smooth, hairless characteristics in botanical . This integration helped standardize the term within for denoting absence of trichomes or pubescence in plants. Related terms emerged in the 19th century to refine botanical descriptions; "glabrescent," coined around 1855–1860 from the Latin glabrēscere ("to become smooth"), describes surfaces that progressively lose hairs or become nearly glabrous with maturity. Today, "glabrous" and its derivatives continue to influence scientific , appearing in species epithets like Linnaeus (1753) and in contemporary literature across , , and to precisely characterize hairless traits.

Botanical Aspects

Characteristics in Plants

In plants, glabrousness manifests as the complete absence of trichomes—hair-like epidermal outgrowths—resulting in smooth, glossy, or slick surfaces on leaves, stems, fruits, and other organs. This trait produces a uniform texture without projections, bristles, or glandular structures, often highlighting underlying features like vein patterns or cuticular sheen, in stark contrast to pubescent where dense or sparse hairs create a fuzzy or velvety appearance. Such surfaces are typically described in botanical as lacking any form of indumentum, emphasizing their bare, polished quality. Ecologically, glabrousness influences plant adaptation by enabling higher rates of and , which promote heat dissipation via evaporative cooling in environments where water availability supports such processes. For instance, in the coastal Encelia californica, glabrous leaves promote higher transpiration rates, leading to leaf temperatures often exceeding air temperature under high light intensity, contrasting with the pubescent leaves of its arid-adapted congener E. farinosa that reduce light absorptance and maintain lower leaf temperatures through a reflective , conserving . This trait is particularly advantageous in mesic or coastal habitats rather than extremely dry ones, where it supports enhanced without the insulating barrier of hairs, though it may increase vulnerability to if water becomes limited. In succulent plants like certain cacti, glabrous stems minimize exposed surface area for while spines offer alternative protection, aiding survival in arid zones by balancing water retention with minimal transpiration. Regarding herbivory, the smooth surfaces of glabrous plants lack the mechanical or chemical barriers provided by trichomes, potentially making them more susceptible to feeding damage compared to hairy counterparts. In and identification, glabrousness serves as a critical diagnostic character in dichotomous keys and floras, helping to delineate boundaries based on surface texture. For example, Herniaria glabra (smooth rupturewort), a low-growing annual in the , is distinguished by its entirely glabrous stems, leaves, and flowers, setting it apart from pubescent relatives in dry, sandy habitats across and . Similarly, in the Cactaceae family, genera such as exhibit glabrous, cladodes (flattened stems) as a key identifier, facilitating classification amid diverse spine morphologies in ecosystems. Variations in glabrousness occur across and , with some displaying temporary glabrous phases in seedlings before developing pubescence in mature stages, while others retain permanent smoothness throughout their lifecycle. Many annual grasses in the family, such as fall panicum, have hairy seedlings that become glabrous as the plant matures, reflecting developmental shifts tied to environmental demands. Permanent glabrousness, as in Herniaria glabra or , remains consistent, underscoring its role as a stable taxonomic marker. These variations highlight how glabrous traits, governed by underlying genetic regulation of initiation, adapt to specific ecological niches without delving into molecular details.

Genetic and Developmental Mechanisms

In , the initiation of trichome formation, which underlies glabrousness when disrupted, is primarily controlled by key regulatory genes such as GLABROUS1 (GL1) in . GL1 encodes an R2R3-MYB transcription factor that acts as a positive regulator by activating downstream targets essential for selecting epidermal cells as trichome precursors. Null mutations in GL1 abolish trichome initiation, resulting in a completely glabrous across leaves, stems, and other aerial organs, as the absence of this factor prevents the early commitment of protodermal cells to the lineage. Complementing GL1, the TRANSPARENT TESTA GLABRA1 (TTG1) gene encodes a WD40-repeat protein that forms part of a core transcriptional complex required for development. TTG1 interacts with GL1 and bHLH factors like GLABROUS3 (GL3) to promote and cell expansion in emerging ; loss-of-function ttg1 mutants exhibit a alongside pleiotropic effects, such as altered seed coat pigmentation and patterning. These genes highlight the modular nature of trichome regulation, where disruptions in either lead to stable glabrous traits. Developmental pathways governing glabrousness involve coordinated epidermal cell differentiation, where the MYB-bHLH-WD40 (MBW) complex drives outgrowth from pavement cells. In the absence of MYB transcription factors like GL1, precursor cells default to a non-hairy fate due to insufficient activation of genes such as GL2, which encodes a homeodomain protein critical for morphogenesis. This process is modulated by hormone signaling, including , which up-regulate GL1 expression to enhance MBW complex formation and promote initiation during primordia expansion. Gibberellin-deficient mutants, such as ga1-3, mimic glabrous phenotypes by reducing GL1 transcript levels, underscoring the integration of hormonal cues in epidermal patterning. Glabrous mutants serve as valuable tools in research applications, particularly for /Cas9-mediated editing to dissect regulatory networks. In , gl1 and ttg1 lines have facilitated targeted knockouts to confirm MBW interactions and downstream effectors. Similarly, in (Solanum lycopersicum), glabrous lines such as the hairless (hl) mutant, which lacks non-glandular s, have been employed in /Cas9 studies; for instance, editing the SlMYC1 bHLH in these backgrounds has generated variants with reduced glandular density, aiding investigations into pest resistance traits. These approaches enable precise functional validation without pleiotropic effects from traditional . From an evolutionary perspective, in regulatory genes like TTG1 and GL1 have produced stable glabrous traits recurrently across angiosperm families, reflecting the deep conservation of the MBW complex in epidermal differentiation. Independent loss-of-function alleles in GL1 homologs, such as those identified in natural populations of lyrata, demonstrate of glabrousness, likely driven by selection for reduced herbivory or altered surface properties. TTG1 orthologs show similar evolutionary stability, with yielding glabrous phenotypes in diverse lineages including and , indicating that regulatory tweaks in this network facilitate adaptive diversification without disrupting core developmental programs.

Zoological Aspects

In Mammals

Glabrousness in mammals refers to the absence or significant reduction of across the body surface, a trait observed in various adapted to specific ecological niches. This hairlessness contrasts with the typical mammalian pelage, which includes protective guard hairs, insulating underfur, and sensory vibrissae. In mammals, glabrous often features a thickened and increased glandular activity to compensate for the loss of fur's protective and thermoregulatory functions. Prominent examples of glabrous mammals include the (Heterocephalus glaber), a subterranean with nearly complete hairlessness that facilitates efficient burrowing in arid, low-oxygen soils of . This adaptation minimizes friction during excavation and prevents soil accumulation on the body, enhancing colony survival in underground habitats. Aquatic mammals like dolphins and whales (cetaceans) exhibit pronounced , retaining only sparse fetal hairs, to achieve hydrodynamic efficiency during high-speed swimming. The smooth, streamlined skin reduces drag, allowing for energy-efficient propulsion in marine environments. Structurally, glabrous mammalian lacks the layered hair follicles that produce guard hairs for protection against abrasion and underfur for insulation, as well as the specialized sinus hairs known as vibrissae for tactile sensing. Instead, the is often thicker and more vascularized, with abundant sebaceous and sweat glands that maintain hydration and flexibility. In cetaceans, this glandular secretes oils to form a protective barrier against osmotic stress and pathogens in saltwater. Physiologically, glabrousness supports enhanced in aquatic species through reliance on layers rather than , which would otherwise trap water and impair heat retention or dissipation. provides superior insulation and hydrodynamic benefits compared to in submerged conditions, enabling cetaceans to maintain core temperatures during prolonged dives. However, in terrestrial glabrous mammals like the breed, the absence of increases vulnerability to (UV) radiation, raising risks of sunburn and skin cancers due to unshielded exposure. This sensitivity underscores 's role as a natural UV barrier in haired counterparts. Genetically, hairlessness in certain breeds arises from mutations in key regulatory genes, such as FOXI3, which disrupt ectodermal development and follicle formation. In the Mexican hairless dog (Xoloitzcuintli), a in FOXI3 leads to congenital alopecia, often accompanied by dental anomalies, illustrating the gene's pleiotropic effects on integumentary traits. Similar FOXI3 variants underlie hairlessness in related breeds like the Peruvian Inca Orchid, highlighting selective breeding's role in perpetuating these mutations.

In Other Animals

In non-mammalian animals, glabrousness manifests in diverse integumentary structures adapted to specific ecological niches. Among , particularly , glabrousness refers to the absence of setae (bristles) or scales on body parts such as wings, legs, or exoskeletons, resulting in smooth surfaces. For instance, certain ground beetles in the family Carabidae, such as cavernicolous trechine species, exhibit glabrous elytra and pronota, which lack pubescence and contribute to their streamlined form in subterranean habitats. Similarly, some arthropods, including select scarab and Christmas beetles, display glabrous regions on their exoskeletons, enhancing by mimicking surrounding substrates like soil or bark through a shiny, hairless appearance. In vertebrates outside mammals, glabrous features appear in scaleless or featherless integuments. Certain fish, such as moray eels (family Muraenidae) and electric eels (), possess thick, smooth, scaleless skin covered by a protective layer, which facilitates movement through aquatic environments. Birds like vultures (family Cathartidae) often have featherless patches on their heads and necks, as seen in turkey vultures (Cathartes aura) and black vultures (Coragyps atratus), where the bare skin prevents bacterial buildup and facilitates cleaning after scavenging carrion. Amphibians typically feature smooth, moist skin, but specific species like the eastern spadefoot toad (Scaphiopus holbrookii) exhibit relatively smooth without prominent parotoid glands, relying instead on subtle warts for minimal glandular expression. Functionally, glabrousness in these animals confers advantages such as reduced hydrodynamic drag in aquatic and resistance to ectoparasites. In like eels, the smooth, mucus-coated skin minimizes frictional resistance during swimming, with the slime layer—composed of proteins, polysaccharides, and microbes—significantly reducing drag. For , the provides physical protection alongside chemical defenses from cuticular waxes. In entomological , the term "glabrous" specifically denotes surfaces lacking setae, scales, or hairs, often used to describe in keys and descriptions; for example, it highlights the smooth, setose-absent pronotum in certain genera. This precise usage aids in distinguishing across orders like Coleoptera and .

Human Glabrousness

Glabrous Skin in Humans

Glabrous skin in refers to the hairless regions of the , primarily located on the palms of the hands, soles of the feet, ventral surfaces of the digits, margins of the , nipples, eyelids, umbilicus, and certain genital areas such as the inner , , and prepuce. These sites are specialized for enhanced tactile sensitivity and mechanical protection, forming distinct patterns like fingerprints and footprints due to epidermal ridges. Together, these glabrous areas constitute approximately 10% of the total . Structurally, glabrous features a notably thick , the outermost layer of the , which provides robust against and abrasion; on the soles, this layer can measure up to 1.5 mm in thickness, significantly thicker than the 0.01-0.15 mm found in hairy elsewhere on the body. Unlike haired , glabrous regions lack pilosebaceous units, which are complexes of hair follicles and associated sebaceous glands responsible for growth and sebum production, resulting in a smooth, non-pilose surface optimized for direct contact. The in thick glabrous areas, such as the palms and soles, also includes a prominent , an additional translucent layer absent in most other types, further enhancing durability. Embryologically, glabrous originates from the surface during the fourth week of , when the separates and the differentiates into epidermal precursors; in these specific regions, developmental signaling pathways suppress initiation, leading to hairless ectodermal derivatives that contrast sharply with adjacent areas programmed for vellus or development. This regional specification ensures the formation of specialized, non-follicular adapted for sensory and protective roles. Pathologically, conditions like atrichia congenita, an autosomal recessive disorder caused by mutations in the HR gene on chromosome 8p22, result in congenital total across the body, thereby expanding glabrous-like areas beyond the typical sites and often accompanied by papular lesions due to follicular cysts. This highlights the genetic regulation of hairlessness, where disrupted hairless protein function leads to irreversible atrichia while preserving inherent glabrous zones like palms and soles.

Physiological Functions

Glabrous in humans, particularly on the palms and soles, serves critical sensory functions through its dense innervation by mechanoreceptors. These include Meissner corpuscles, which detect low-frequency vibrations and light touch for fine tactile discrimination; Pacinian corpuscles, specialized for high-frequency vibrations and rapid pressure changes; Merkel cells, which respond to sustained pressure and contribute to spatial acuity; and Ruffini endings, which sense skin stretch and sustained deformation. This specialized array enables precise manipulation and texture perception, essential for dexterous activities. Protective roles of glabrous skin are enhanced by friction ridges, known as , which increase grip efficacy on varied surfaces by channeling sweat and modulating , thereby preventing slippage during object handling. Additionally, the absence of allows eccrine sweat glands to function unimpeded in , secreting fluid directly onto the surface for evaporative cooling without follicular obstruction, which is vital during physical exertion or heat exposure. Vascular features, such as rich arteriovenous anastomoses (AVAs) in the palms and soles, facilitate rapid heat dissipation by shunting blood flow to the skin surface, supporting overall when core temperature rises. These AVAs also contribute to modulation through or dilation, influencing peripheral resistance in response to thermal and circulatory demands. Clinically, disruptions in glabrous skin's sensory functions, such as reduced responsiveness, are common in peripheral neuropathies like diabetic sensorimotor , leading to impaired touch sensitivity and increased risk of injury. This physiological specialization underscores the evolutionary retention of glabrous skin for advanced tool use and manipulation in humans.

Evolutionary Perspectives

Adaptations in Plants

Glabrousness in plants has evolved primarily as a response to selective pressures favoring reduced loss in arid environments. In species such as Lavoisiera campos-portoana, glabrous leaves exhibit lower , which minimizes rates during drought stress—compared to higher values in pubescent leaves—thereby maintaining higher and enabling osmotic adjustment earlier in water shortage events. This adaptation enhances by preventing excessive dehydration without relying on reactive physiological responses seen in -bearing counterparts. Additionally, in lineages with reduced density, such as certain , glabrousness correlates with chemical defenses like glucosinolates, providing resistance where physical barriers are absent. These chemical strategies compensate for the loss of -based deterrence, allowing low-trichome plants to persist under herbivory pressure. The expansion of angiosperms into open habitats during the period is associated with traits suited to higher light exposure and variable moisture, often linked to glabrous surfaces in modern analogs. Early angiosperms (ca. 136–112 Ma) began diversifying in disturbed, riparian, and environments. By the mid- (ca. 108–94 Ma), increased vein density in leaves—reaching means of 5.55 mm/mm²—supported efficient in sun-exposed settings, where glabrousness likely facilitated rapid and heat dissipation. This correlation with open, non-forested habitats underscores how glabrous aided angiosperm dominance amid shifting paleoenvironments. While advantageous in high-light conditions, glabrousness involves trade-offs, including heightened susceptibility to ultraviolet (UV) damage balanced against improved . Low density increases leaf absorbance of and UV, potentially elevating photochemical stress and accumulation, as high coverage reflects more UV in pubescent species. However, this enhanced capture boosts net in intense , particularly when paired with high stomatal density for CO₂ uptake, enabling glabrous to thrive in exposed areas where pubescent forms might overheat or limit carbon gain. Such compromises highlight the context-dependent nature of glabrous adaptations. In modern agriculture, glabrous traits have been selectively bred into crops for enhanced resilience. Certain rice (Oryza sativa) varieties, such as the cultivar 'Gowoo', feature glabrous leaves and hulls, contributing to multiple insect resistances (e.g., against stem borers and leafhoppers) alongside high yield and disease tolerance, making them valuable in pest-prone regions. These selections leverage glabrousness to reduce physical cues for oviposition and feeding by herbivores, while integrating with genetic pathways for overall vigor, as explored in broader developmental mechanisms.

Adaptations in Animals

In aquatic environments, cetaceans such as whales and dolphins have evolved nearly complete hairlessness to minimize hydrodynamic drag and facilitate streamlined , a key during their transition from terrestrial ancestors to fully approximately 50 million years ago. This loss of , accompanied by the development of a thicker, more elastic , reduced frictional resistance in water and supported efficient locomotion over long distances. Genetic analyses reveal accelerated pseudogenization of hair genes in cetacean lineages, underscoring the selective pressure for this trait in marine habitats. Thermoregulatory advantages of glabrousness are evident in tropical and subterranean mammals, where reduced enhances heat dissipation in hot or humid conditions. For instance, exhibit sparse hair coverage that promotes convective cooling in environments by increasing airflow over the skin and aiding evaporation from large surface areas like the ears. Similarly, the naked mole-rat's profound hairlessness is an to its underground, low-oxygen system, where minimal reduces metabolic costs and facilitates eusocial behaviors in confined, thermally stable spaces. This trait aligns with the species' eusocial structure, minimizing individual thermoregulatory needs in a colony-based . In , the retention and expansion of glabrous skin areas supported bipedal locomotion and endurance activities by enabling efficient sweating for , likely emerging around 2.2–2.4 million years ago during the early genus. This hair reduction may also reflect , as smoother skin could have signaled health and attractiveness, driving further loss of beyond functional needs for dexterity in tool use and heat management. Despite these benefits, glabrousness incurs costs such as heightened vulnerability to ultraviolet radiation, increasing risk in exposed animals like humans and potentially elephants without compensatory mechanisms. Such traits have evolved convergently across mammalian lineages, including cetaceans, proboscideans, and , as well as in analogous bare-skin patches in birds (e.g., heads for and cooling), reflecting parallel responses to environmental pressures like aquatic drag, heat stress, or subsurface constraints.

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