Atriplex canescens

Atriplex canescens, commonly known as fourwing saltbush or chamiso, is a native perennial shrub in the Amaranthaceae family, characterized by its erect, much-branched form, silvery-gray scurfy leaves, and distinctive four-winged fruits.^[1] It typically grows 1 to 3 meters tall with rigid stems and a deep taproot system extending up to 12 meters, enabling exceptional drought and salt tolerance.^[2] The leaves are linear to ovate, 1-5 cm long, and either evergreen or deciduous depending on environmental conditions, while the inconspicuous flowers appear from spring to fall, producing wind-dispersed seeds.^[3] This species is widely distributed across western North America, ranging from southern Alberta and Saskatchewan in Canada through the western United States to northern Mexico.^[1] It thrives in diverse habitats including desert shrublands, salt-desert scrub, grasslands, and pinyon-juniper woodlands, from below sea level to elevations of 2,600 meters, particularly on saline, alkaline, or sandy soils where few other plants can survive.^[2] A. canescens is long-lived, often exceeding 100 years, and plays a key role in soil stabilization and primary succession on disturbed sites like dunes and overgrazed rangelands.^[3] Reproduction occurs primarily through seeds, with the plant being dioecious—having separate male and female individuals—though some populations exhibit monoecious or hermaphroditic traits; seed production yields 17 to 120 seeds per fruit, with germination enhanced by cold stratification.^[2] Vegetative sprouting from root crowns or rhizomes allows persistence after fire or grazing, contributing to its resilience in harsh environments.^[1] Ecologically, it supports biodiversity by providing browse for wildlife such as pronghorn, deer, and birds, as well as habitat in arid landscapes.^[3] A. canescens holds significant value for rangeland management and restoration, serving as a high-protein forage (12-20% in leaves) for livestock like sheep and cattle, and is commonly used in reclamation projects for erosion control and revegetation of saline sites.^[1] Native American communities have historically utilized it for food (seeds ground into flour) and dye, while modern applications include wildlife enhancement and ornamental planting in dryland gardens.^[2] Its adaptability has led to cultivation in arid regions worldwide, though overgrazing can reduce its vigor in native ranges.^[3]

Taxonomy

Classification

Atriplex canescens is classified within the kingdom Plantae, phylum Tracheophyta, class Magnoliopsida, order Caryophyllales, family Amaranthaceae (subfamily Chenopodioideae), genus Atriplex, and species A. canescens.^[4]^[5]^[6] Historically, the genus Atriplex and its relatives were placed in the family Chenopodiaceae, but molecular phylogenetic analyses using chloroplast gene sequences, such as rbcL, demonstrated that Chenopodiaceae is monophyletic and nested within Amaranthaceae, leading to the revised classification subsuming the former into the latter under the APG II and subsequent systems.^[7]^[8] Four varieties are recognized: A. canescens var. canescens (typical form with linear to ovate leaves), var. gigantea (a larger variant reaching up to 1.8 m in height, endemic to Utah dunes), var. laciniata (with laciniate or deeply lobed leaves), and var. macilenta (slender form with narrower leaves).^[9]^[10]^[11]^[12] The species exhibits significant cytogenetic variability, forming a polyploid complex with ploidy levels ranging from diploid (2n=18) to dodecaploid (12x=108) or higher, driven by processes such as autopolyploidy and hybridization, which contribute to its morphological variation across populations.^[13]^[14]

Etymology and synonyms

The genus name Atriplex derives from the Latin atriplex, an ancient term for orache or a saltbush-like plant, which itself originates from the Greek atraphaxys.^[15]^[16] The specific epithet canescens comes from the Latin canescens, meaning "becoming gray" or "hoary," a reference to the plant's characteristic scurfy, silvery-gray foliage and stems.^[17]^[18] The basionym for Atriplex canescens is Calligonum canescens Pursh, first described in 1814 based on specimens from the 1811 Missouri River expedition.^[18] Thomas Nuttall transferred the species to the genus Atriplex in 1818, establishing the current binomial Atriplex canescens (Pursh) Nutt..^[18]^[5] Historical synonyms include Obione canescens (Pursh) Moq. and the illegitimate nomenclatural synonym Atriplex nuttallii S. Watson, which was proposed in 1871 but superseded by the earlier A. canescens.^[18] Other early names, such as Atriplex canescens James, reflect taxonomic revisions but are no longer accepted.^[19] Common names for Atriplex canescens include fourwing saltbush (or four-wing saltbush), chamiso, and chamiza, with regional variations such as wingscale in parts of the southwestern United States.^[20]^[21]

Description

Morphology

Atriplex canescens is an evergreen to semi-evergreen dioecious shrub that exhibits considerable morphological variability, typically growing 0.5–2.5 m (1.6–8.2 ft) tall, though heights can range from 0.3 m to over 3 m depending on environmental conditions and ecotype.^[9]^[2] The plant is heavily branched with rigid, brittle stems that often have peeling, thin, whitish bark on older branches, and lateral branches may terminate in spiny tips.^[9]^[22] Its deep root system can extend up to 6 m (20 ft), supporting adaptation to arid environments.^[9] The leaves are simple, alternate, and sessile or nearly so, measuring 1–5 cm (0.4–2 in) long and 0.2–1 cm (0.08–0.4 in) wide, with shapes ranging from linear to narrowly oblong or oblanceolate.^[9]^[23] They are covered in a dense, gray-white scurfy pubescence of fine trichomes that reduces water loss and imparts a silvery or mealy appearance, particularly on young growth; in saline conditions, leaves may exude salts.^[2]^[23] Leaves are evergreen in warmer climates but deciduous in colder regions.^[2] Flowers are inconspicuous and greenish, borne from mid-spring to early fall (April–October).^[9] Male (staminate) flowers occur in dense, terminal spikes 2–3 mm wide, while female (pistillate) flowers are axillary or in loose panicles 5–40 cm long, often with bracteate structures.^[2]^[22] Although primarily dioecious, some plants exhibit monoecious or hermaphroditic traits.^[9] The fruits are utricles enclosed in persistent, papery bracts that form a key diagnostic feature: four prominent wings, giving the plant its common name "fourwing saltbush," with overall dimensions of 6–10 mm (0.25–0.4 in) across.^[9]^[23] These winged fruits, dull yellow when mature, are densely clustered on female plants and aid in wind dispersal, containing 17 to 120 brown seeds per fruit, each about 1–2 mm long.^[2]^[22] Morphological variation in A. canescens is pronounced, influenced by polyploidy (diploid to dodecaploid cytotypes), soil conditions, and hybridization, resulting in forms from prostrate and compact to upright and spreading.^[9]^[2] This plasticity affects leaf size, branching density, and fruit wing development across its range.^[2]

Reproduction

Atriplex canescens is primarily dioecious, with separate male and female plants, although some populations exhibit trioecy or environmental lability in sex expression.^[2] Male plants bear staminate flowers in dense spikes, while female plants produce pistillate flowers that develop into utricles containing seeds.^[9] Pollination is anemophilous, relying on wind to transfer pollen between plants, which facilitates gene flow across populations.^[2] Female plants generate winged fruits that aid in anemochory, promoting seed dispersal over distances in arid environments.^[24] Seed production on female plants is prolific, with estimates of up to 38,000 winged seeds per pound, though a significant portion may be unfilled or inviable due to environmental stresses like drought or herbivory.^[2] Seeds exhibit both physical dormancy from the impermeable pericarp and physiological dormancy linked to inhibitory compounds such as saponins, necessitating scarification and stratification for germination.^[24] Viability persists for 6 to 10 years in controlled storage, enabling opportunistic recruitment following favorable moisture events.^[9] After-ripening over 10 months post-harvest further alleviates dormancy, enhancing germination rates to 20-50% under laboratory conditions.^[25] Asexual reproduction occurs limitedly through vegetative means, primarily root sprouting from the root crown in response to disturbance such as fire or mechanical damage, with genetic variation influencing sprouting vigor across populations.^[2] Basal branch layering or rare rhizomatous growth can also contribute to clonal expansion in suitable soils, though this is less common than seed-based propagation.^[24] Flowering phenology spans an extended period from mid-spring to early fall, modulated by regional climate and soil moisture availability, with northern populations peaking earlier than southern ones.^[2] Adequate precipitation extends the blooming window, while drought can induce sex shifts or reduce flower output, adapting reproduction to unpredictable arid conditions.^[24] Polyploidy, ranging from diploid (2n) to dodecaploid (12n) levels, bolsters reproductive flexibility by promoting unreduced gamete formation and hybridization, which supports population persistence in heterogeneous habitats without direct apomixis.^[13] Higher ploidy correlates with increased seed output variability but enhanced osmotic tolerance, aiding establishment in saline or dry soils.^[2]

Distribution and habitat

Geographic range

Atriplex canescens is native to the western and midwestern United States, extending from Washington state, southern Alberta, and Saskatchewan in Canada, in the north to Texas in the south, and including key states such as California, Nevada, Utah, Arizona, and New Mexico, with its range continuing into northern Mexico.^[2]^[9] This distribution spans diverse arid and semi-arid landscapes, from the Pacific Coast to the Missouri River.^[9] The species has been introduced and naturalized in various arid regions worldwide, particularly for enhancing forage production and supporting land reclamation efforts, with established populations in Australia (including Western Australia, South Australia, and New South Wales) and Mediterranean regions of Europe.^[2]^[26] Following post-glacial warming, A. canescens underwent migration into the Great Basin and Southwest deserts, where it spread through disturbed sites like roadsides and overgrazed areas, contributing to its broad current occupancy.^[2] Its core distribution centers on sagebrush steppe and salt desert shrublands, occurring at elevations from below sea level to over 8,500 feet (2,600 m).^[9]

Habitat preferences

Atriplex canescens is adapted to arid and semi-arid climates, typically occurring in regions with annual precipitation between 6 and 14 inches (150–350 mm).^[2] This shrub exhibits exceptional drought tolerance, supported by its C4 photosynthesis pathway, which enhances water-use efficiency under low moisture conditions.^[27] As an early successional pioneer species, it readily colonizes disturbed habitats such as sand dunes, roadcuts, overgrazed rangelands, and areas with poor soil stability, where it requires full sun exposure for optimal growth.^[2] The plant thrives in a variety of soil types, including saline, alkaline, sandy, loamy, gravelly, and clayey soils, with a preferred pH range of 6.5 to 8.5.^[2] It demonstrates high salinity tolerance, enduring soil electrical conductivity levels exceeding 10 dS/m, equivalent to approximately 10,000 ppm total dissolved solids, making it suitable for reclamation of salt-affected sites.^[28]^[29] Atriplex canescens is commonly associated with desert shrub communities, including shadscale (Atriplex confertifolia), sagebrush (Artemisia spp.), and creosote bush (Larrea tridentata) ecosystems in the Great Basin, Mojave, and Sonoran deserts.^[2] Its adaptations to these environments include a deep, branched root system that can extend up to 12 meters (40 feet) in deep soils to access subsurface water, and halophytic characteristics such as the accumulation and excretion of salts through specialized leaf bladders and scurfy coatings, which prevent ionic toxicity.^[2]^[30]^[31]

Ecology

Interactions

Atriplex canescens is primarily anemophilous, with pollination occurring via wind dispersal of pollen from male to female plants, as the species is dioecious and requires spatial proximity between sexes for successful reproduction.^[2] Minimal involvement of insect pollinators has been observed, consistent with the wind-pollinated nature of most Chenopodiaceae species.^[2] The plant serves as a significant forage source and is browsed by various herbivores, including livestock such as sheep and cattle, as well as wild species like deer and rabbits, which preferentially consume it during winter months when other vegetation is scarce.^[2] Its high palatability in winter stems from elevated crude protein content in leaves, reaching up to 18% in some populations, which supports nutritional needs for browsing animals.^[2]^[32] Atriplex canescens exhibits resistance to many desert pests due to associations with non-pathogenic fungal endophytes, but it remains susceptible to certain insects, such as the Atriplex case-bearing moth (Coleophora atriplicivora), which targets seeds and reduces viability.^[2] In wetter conditions, the plant can suffer from root rot caused by soil pathogens, though specific incidences are infrequent in its arid native range.^[2] Occasional fungal infections, including those from genera like Alternaria, have been noted in stressed individuals, but overall pathogen pressure is low compared to mesic-adapted species.^[33] As a pioneer species, Atriplex canescens readily colonizes disturbed or early-successional sites, where it facilitates establishment of later-arriving perennials before being outcompeted in mature communities dominated by longer-lived shrubs.^[2] It exerts competitive effects on associated grasses through resource overlap and potential allelopathy, with leaf extracts inhibiting germination and growth of some native grass species in saline environments.^[34]^[35] Atriplex canescens lacks typical arbuscular mycorrhizal associations, a trait common in the Chenopodiaceae family, though it harbors non-mycorrhizal fungal endophytes in roots that may aid in nutrient uptake under arid stress.^[33] Leaf litter from the plant contributes to nitrogen enrichment in saline soils by decomposing into organic matter that supports microbial activity and gradual nitrogen release, enhancing local soil fertility without direct symbiotic fixation.

Ecosystem role

Atriplex canescens plays a crucial role in stabilizing soils within arid and semi-arid ecosystems through its extensive root system, which can penetrate up to 12 meters deep in suitable soils, effectively preventing erosion on slopes, disturbed sites, and saline-sodic soils.^[9]^[36]^[37]^[2] This deep rooting anchors the plant in harsh environments, reducing wind and water erosion while contributing to soil organic matter accumulation during ecological succession, thereby enhancing long-term soil structure and fertility in degraded landscapes.^[38]^[37] In nutrient cycling, A. canescens facilitates the accumulation of salts and heavy metals such as cadmium, chromium, zinc, lead, and copper in its tissues, supporting phytoremediation efforts in contaminated saline areas.^[37]^[38] Its leaf litter decomposes to add organic matter, improving soil fertility and nutrient availability in otherwise infertile, salt-affected regions, which aids overall ecosystem recovery.^[38]^[36] As a habitat provider, A. canescens offers dense cover and nutrient-rich seeds that support birds such as quail, sage grouse, and songbirds, as well as small mammals like rabbits, while its flowers attract nectar-feeding insects including bees.^[9]^[20] This shrub enhances biodiversity by creating microhabitats in open desert shrublands, benefiting a range of wildlife dependent on sparse vegetation.^[37] In succession dynamics, A. canescens functions as a pioneer species in salt-desert scrub communities, rapidly colonizing disturbed or saline sites and facilitating the establishment of other native plants through soil improvement and reduced competition over time.^[9]^[37] It serves as an indicator of environmental stress, such as salinity or disturbance, signaling conditions that influence community development in arid ecosystems.^[38]^[36] Regarding carbon sequestration, A. canescens contributes moderately to carbon storage in desert shrublands via its evergreen habit and persistent biomass, with potential to capture up to 5 metric tons of CO₂ per hectare annually in low-rainfall, infertile soils.^[37] This role underscores its value in maintaining ecosystem carbon balances amid arid conditions.^[38]

Uses

Traditional uses

The Zuni people of the Southwestern United States have traditionally utilized Atriplex canescens, known to them as ke'mawe or "salt weed," for both medicinal and ceremonial purposes. An infusion prepared from the dried roots and blossoms, or a poultice made from the blossoms moistened with saliva, was applied externally to treat ant bites and associated swellings.^[39] Similarly, a poultice of fresh or dried flowers was employed for the same dermatological aid.^[40] In rituals, twigs of the plant were incorporated into prayer plumes (pahos) and sacrificed to the cottontail rabbit during the winter solstice ceremony, invoking abundance for hunts and symbolizing successful adaptation to arid environments.^[39] Among the Hopi, the ashes derived from burning Atriplex canescens held particular value in food preparation, serving as an alkaline agent in the nixtamalization of maize to improve nutritional value, texture, and the characteristic blue color of corn products like piki bread. This practice highlighted the plant's role in enhancing staple foods in resource-scarce desert landscapes.^[41] Other Southwestern tribes, including the Navajo, ground the small, salty seeds of Atriplex canescens into flour after parching.^[42] Additionally, various tribes applied the plant medicinally for digestive ailments, such as boiling fresh roots with salt and consuming half-cup doses to alleviate stomach pain or act as a laxative.^[36] Native Americans also produced yellow dyes by boiling the leaves with alum.^[42] Archaeological findings further underscore the plant's longstanding significance, with seeds and plant remains frequently recovered from Pueblo ruins, serving as indicators of ancient habitation, agricultural activity, and reliance on native flora for sustenance in arid regions.^[43] Culturally, Atriplex canescens embodies resilience and survival in harsh desert conditions, often featured in indigenous rituals that celebrate harmony with the arid ecosystem and invoke prosperity amid environmental challenges.^[39]

Modern applications

Atriplex canescens serves as a valuable forage plant in arid and semi-arid regions, providing high-protein browse for livestock such as sheep, goats, and cattle, as well as wildlife including deer and pronghorn.^[36] Its leaves contain 12–18% crude protein during winter months, making it a staple for grazing in rangelands where other vegetation is scarce.^[2] This nutritional profile, comparable to alfalfa in protein and digestibility, supports year-round feeding, particularly in fall and winter when palatability peaks.^[36] The species is widely employed in land reclamation and erosion control projects due to its extensive root system, which can extend up to 6 meters deep and stabilizes soil on disturbed sites.^[36] It is commonly planted on mine spoils, drill pads, roadsides, and highway medians to revegetate saline or sodic soils and prevent erosion.^[2] In restoration efforts, A. canescens enhances biodiversity and facilitates the recovery of degraded rangelands by providing initial cover and improving soil structure.^[36] A. canescens demonstrates significant potential in phytoremediation, accumulating salts, selenium, and heavy metals such as cadmium, nickel, and lead from contaminated soils.^[44] Studies show bioaccumulation factors exceeding 1 for these metals, enabling its use in rehabilitating saline and polluted sites, including mining areas and roadside verges impacted by de-icing salts.^[45] Its halophytic nature allows effective salt extraction, aiding in the cleanup of sodic soils without requiring intensive management.^[46] Beyond primary applications, A. canescens offers potential as a biofuel source owing to its substantial biomass production in harsh environments.^[37] Its seeds serve as a nutritious feed for birds, attracting species like quail and grouse, while the shrub's silvery foliage and drought tolerance make it suitable for limited ornamental use in xeriscaping landscapes.^[36] Economically, A. canescens contributes to arid land restoration through commercial seed mixes, where it comprises 3–7% of rangeland seeding blends to achieve densities of about 400 plants per acre.^[9] Cultivars such as 'Marana' and 'Rincon' are traded globally for desert agriculture and reclamation, supporting sustainable practices in salt-affected regions and generating value in forage and habitat enhancement markets.^[36]

Cultivation

Propagation methods

Atriplex canescens is commonly propagated by seed, with winged fruits collected from female plants in late fall, typically from mid-September to December, by hand stripping or mechanical vacuuming.^[36] Seed dormancy is naturally broken through after-ripening over about 10 months post-harvest, and while cold moist stratification (up to 24 weeks at 2°C) can enhance germination for some ecotypes, it is not always required.^[36]^[47] Direct sowing is recommended at rates of 0.25–0.50 pounds of pure live seed (PLS) per acre, planted ½ inch deep in moist fine soils or up to ¾ inch in sandy conditions, ideally in late fall or early winter to align with natural cycles.^[48] Germination rates vary by ecotype, with viability assessments showing around 52% filled seeds across populations.^[47] Dewinged seeds are preferred for commercial seeding to improve drill flow, and no mycorrhizal inoculation is necessary as the species does not strictly require such associations.^[48]^[49] Vegetative propagation is feasible through semi-hardwood stem cuttings (7.6 cm long, 1–3 mm diameter) taken from new growth, soaked in nutrient solution, treated with 0.3% indolebutyric acid, and rooted in a sand-peat mix under mist for 5 weeks, achieving success rates of 80–93%.^[50] Rooted cuttings are then transplanted to 75% sand and 25% peat flats, watered every 4–5 days, and pruned after 3–4 weeks to promote branching.^[50] The species can also root sprout from buried stems in moist soil or after disturbances like wildfire, providing another clonal method.^[36] As a mostly dioecious species, with separate male and female plants, propagation for seed production requires a mix of sexes (e.g., 1 male per 5 females); vegetative methods like cuttings preserve the sex of the parent clone.^[36]^[50] Challenges include variable seed dormancy by ecotype, which can lower germination in non-saline media without adequate after-ripening or stratification, and sensitivity to overwatering in cuttings, which reduces root development.^[47] Fall planting timing is critical to match natural dispersal of winged seeds and avoid mold from damp conditions.^[51]

Growing requirements

Atriplex canescens, commonly known as fourwing saltbush, thrives in full sun exposure, requiring at least six hours of direct sunlight daily to promote vigorous growth and seed production.^[52] It prefers well-drained soils, particularly saline, sandy, or gravelly types, and performs best in deep loamy substrates that prevent waterlogging.^[9] It tolerates a range of soils including dense clay, provided drainage is adequate, though high-rainfall areas exceeding 360 mm (14 inches) annually are unsuitable due to susceptibility to prolonged moisture.^[36] Once established, A. canescens exhibits high drought tolerance, requiring no supplemental irrigation in arid environments with 200–360 mm (8–14 inches) of annual precipitation.^[9] During the first year of cultivation, provide irrigation as needed to support root development, such as to field capacity before fall freeze-up, reducing frequency thereafter.^[36] The plant briefly tolerates flooding or high water tables but is sensitive to extended inundation, particularly in late winter, which can lead to crown rot.^[9] Fertilization requirements are minimal, as A. canescens adapts well to nutrient-poor soils; routine application is not recommended unless soil tests reveal severe deficiencies, in which case targeted nitrogen supplementation may enhance growth in suboptimal sites.^[36] Maintenance involves light pruning to maintain shape, especially for ornamental plantings, by removing dead or rubbing branches in late winter or early spring, cutting back up to one-third of older growth without affecting second-year or mature wood to preserve productivity.^[52] In forage applications, monitor for overgrazing and implement deferred rotation, utilizing no more than 40–50% of annual growth to ensure plant health and regeneration.^[36] It demonstrates strong winter hardiness, surviving temperatures down to -29°C (-20°F) depending on ecotype, with protection recommended for young plants in exposed sites.^[2] Overall, A. canescens shows resistance to most pests and diseases, though young stands may suffer damage from rabbits, rodents, or the Atriplex case-bearing moth (Coleophora atriplicivora), necessitating fencing or targeted controls during establishment.^[36]