Atriplex subconferta Rydb.

Scientific Name: Atriplex subconferta Rydb.


Classification: Plantae/ Tracheobionta / Spermatophyta / Magnoliophyta / Magnoliopsida / Caryophyllidae / Caryophyllales / Chenopodiaceae / Atriplex L./ Atriplex subconferta Rydb.

<i>Atriplex subconferta</i> Rydb.
General Information
Usda SymbolATSU3
GroupDicot
Life CyclePerennial
Growth HabitsShrubSubshrub,
Native LocationsATSU3

Plant Guide

Alternate Names

Common Names: shadscale, spiny saltbush Scientific Names: Atriplex jonesii Standl, A. subconferta Rydb., A. collina Woot. & Standl.

Uses

Wildlife: Shadscale saltbush provides forage and cover for wildlife in arid environments. A small number of leaves are shed in the fall, but the majority of leaves remain during the winter providing a valuable source of food when little else is available (Holmgren et al. 2012). The fruit and leaves are browsed by deer, pronghorn, bighorn sheep, rodents, jackrabbits and birds. Small mammals and reptiles use the spiny shrubs for cover from predators and the sun. Livestock: The palatability of the leaves and fruit of shadscale saltbush has been rated as fair to good for cattle and sheep making shadscale an important part of winter diets on desert rangelands. However, the spiny branches limit utilization of shadscale saltbush. Restoration/reclamation: Attempts to establish shadscale saltbush in restoration plantings have been largely unsuccessful. Arid conditions common to shadscale saltbush habitat make seeding efforts highly unpredictable. Establishment from containerized stock has shown the greatest success. Ethnobotanical: The Gosiute and Hopi used the leaves of shadscale saltbush to be eaten as greens or to be cooked with meal to make a pudding (Chamberlin, 1911; Whiting 1939).

Status

Please consult the PLANTS Web site and your State Department of Natural Resources for this plant’s current status (e.g., threatened or endangered species, state noxious status, and wetland indicator values).

Description

Shadscale saltbush is a low growing shrub (1-3 ft) with spine tipped branches. The gray-green leaves are alternate, 1/4 to 1 inch long and orbicular to ovate in outline with entire margins. Shadscale saltbush is dioecious (separate male and female plants). The staminate (male) flowers are yellow and gathered in clusters or spikes. Female flowers are arranged in a 1 to 6 inch long panicle. Each flower is enclosed in 2 fruiting bracteoles fused at the base. There is considerable variation in ploidy races of shadscale saltbush. 2n=18, 36, 54, 72, 90 (Holmgren et al. 2012). Distribution: Shadscale saltbush occurs throughout western North America from California and Oregon east to North Dakota and south to Arizona and Texas. The greatest concentrations of shadscale saltbush are found in the Great Basin and Colorado Plateau (Simonin 2001). Shadscale saltbush can be found in warm and cold desert shrub-steppe environments. Populations occur in low valleys, foothills and mesas from 2,500 to 7,500 ft elevation (Simonin 2001). It often grows in association with other halophytes including mat-atriplex, glasswort and greasewood, but can also be found in sagebrush and pinyon-juniper communities (McArthur and Monsen 2004; Welsh et al. 2003).

Adaptation

Shadscale saltbush is highly drought tolerant and is adapted to sites receiving 6 to 12 inches annual precipitation. This species is tolerant of high saline conditions (pH 7.5-9.0) and is classified as a facultative halophyte (Branson et al. 1973). It prefers well drained soils but may inhabit a wide range of soil textures from fine to gravelly. Differences can be seen between communities of diploid and polyploid shadscale saltbush. Diploid plants are widely spaced and mixed with many other species. Polyploid stands are dense and uniform with few other species intermingled (Tiedemann et al. 1983). Diploids Natural Resources Conservation Service Plant Guide also have more genetic flexibility and tend to occupy a broader variety of sites. Within the Great Basin diploid shadscale saltbush populations are most commonly found above the levels of Pleistocene lakes. As the water receded following the ice age, polyploid populations expanded into the newly available sites (Tiedemann et al. 1983).

Establishment

Shadscale saltbush seed is highly dormant, largely due to the inhibitive role of the pericarp (hard tissue surrounding the seed). Warren and Kay (1983) tested germination following various methods of pericarp removal. Zero seeds germinated with intact pericarps. Germination increased to 21% with the pericarps mechanically removed. Shadscale saltbush seed (utricles). Steve Hurst @ USDA-NRCS PLANTS Database. Baskin and Baskin (2002) placed seeds in cold stratification and saw germination at 12° C and 16/12° C temperature cycles. Germination was equal in light and dark; however they did not report whether or not the pericarp had been removed, the length of the stratification period, or the total percent germination. Pericarp removal is difficult and feasible methods for use in large scale seed processing are lacking. Fall seeding for natural breakdown of the pericarp is recommended, however germination from outdoor stratification is erratic (Tiedemann 1984). Seed should be drill seeded to a depth of 1/4 to 1/2 inch in a firm, weed-free seed bed. Due to the nature of the soils common in shadscale saltbush habitat, soil crusting is common and may prevent seedlings from emerging. Shadscale saltbush is slow to develop and not competitive in the first years of establishment. It should be planted in solid stands or in alternate rows from grasses and other more competitive species (McArthur and Monsen 2004). Transplanting greenhouse grown stock (containerized or bareroot) is the most successful method of establishing shadscale saltbush. Transplants are not competitive, and a 30 inch diameter clearing is recommended to reduce seedling competition (McArthur and Monsen 2004).

Management

Overgrazing the plant is largely prevented by the presence of spiny branches. Typically only 15 to 20% of fresh growth is browsed by domestic sheep (Holmgren and Hutchings 1972). Extensive late spring and summer grazing however can cause reduction in stands. Shadscale saltbush is killed by fire; however the lack of continuous fine fuels in shadscale saltbush communities has historically prevented major losses. The introduction of invasive annuals such as cheatgrass has altered the plant communities and increased the risk of wild fire. Slow establishment and development of shrubs like shadscale saltbush following fires allows invasive annuals to thrive and inhibit shrub reestablishment.

Pests and Potential Problems

Surveys of commercial seed lots have shown damage to shadscale saltbush by insects (Haws et al. 1984). Seed should be stored in cold conditions and treated with an insecticide (McArthur and Monsen 2004).

Environmental Concerns

Concerns

Concerns

Shadscale saltbush is native to western North America. It will spread under favorable conditions but does not pose any environmental concern to native plant communities.

Seeds and Plant Production

Plant Production

Plant Production

Seed is harvested by hand or vacuum from wild native stands, Seed is hammermilled to remove the bracteoles and pericarp, but care should be taken to not damage the seed, Inert matter can be removed with an air screen cleaner, Use soil moisture sensors to measure the soil moisture of Atriplex subconferta Rydb.., There are approximately 60,500 seeds per pound (USDA 2014), Seed quality from native stands is variable depending on climatic conditions, Low seed fill in lots of shadscale saltbush is common (McArthur and Monsen 2004), Cultivars, Improved, and Selected Materials (and area of origin) There are no releases of shadscale saltbush, Common seed harvested from native stands is available commercially, Ecotypes should be selected that are adapted to the site and conditions to be planted, Diploid shadscale saltbush typically shows better adaptive flexibility and competitive ability and should be chosen for upland sites, Polyploids are typically more drought tolerant and adapted to lower elevation arid sites, but are less competitive with other species,

References

Baskin, C. C., Baskin, J. M. 2002. Propagation protocol for production of container Atriplex confertifolia plants. University of Kentucky, Lexington, Kentucky. In: Native Plant Network. URL: http://www.nativeplantnetwork.org (accessed 22 January 2014). Moscow (ID): University of Idaho, College of Natural Resources, Forest Research Nursery. Branson, F.A., Miller, R.F and I.S. McQueen. 1976. Moisture relationships in twelve northern desert shrub communities near Grand Junction, Colorado. Ecology. 57(6): 1104-1124. Chamberlin, R. V. 1911. The Ethno-Botany of the Gosiute Indians of Utah. Memoirs of the American Anthropological Association 2(5):331-405. (p. 363). Haws, B.A., Bohart, G.E., Meadows, R.W., Coombs, E.M and A.H. Roe. 1984. Status of information concerning insects associated with selected species of Atriplex. In: Tiedemann, A.R., McArthur, E.D., Stutz, H.C., Stevens, R., and K.L. Johnson, comps. Proceedings-Symposium on the biology of Atriplex and related chenopods. Gen Tech Rep. INT-172. Intermountain forest and Range Experiment Station. Ogden, UT. Holmgren, N.H., Holmgren, P.K., Reveal, J.L. and collaborators. 2012. Intermountain Flora. Vascular Plants of the Intermountain West, U.S.A. Vol. 2, part A, subclasses magnoliidae-caryophyllidae. The New York Botanical Garden Press. New York, NY. 730p. Holmgren, R.C and S.S. Hutchings. 1972. Salt desert shrub response to grazing use. In: McKell, Cyrus, M., Blaisdell, J.P, Goodin, J.R., eds. Wildland shrubs-their biology and utilization. Symposium Proceedings. Gen. Tech. Rep. INT-1. USDA Forest Service, Intemountain Forest and Range Experiment Station. McArthur, E.D. and S.B. Monsen. 2004. Chenopod Shrubs. In: S.B. Monsen, R. Stevens, and N.L. Shaw [compilers]. Restoring western ranges and wildlands. Fort Collins, CO: USDA Forest Service, Rocky Mountain Research Station. General Technical Report RMRS-GTR-136-vol-2. p. 467-491. Simonin, K.A. 2001. Atriplex confertifolia. In: Fire Effects Information System, [Online]. US Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory. Available: http://www.fs.fed.us/database/feis/ Tiedemann, A.R. McArthur, E.D., Stutz, H.C., Stevens, R., and K.L. Johnson. 1983. Proceedings-Symposium on the biology of Atriplex and related chenopods. General Technical Report INT-172. Intermountain forest and Range Experiment Station. Ogden, UT. 309p. [USDA NRCS] USDA Natural Resources

Conservation

Service. 2014. The PLANTS Database, version 3.5. URL: http://plants.usda.gov (accessed 21 Jan 2014). Baton Rouge (LA): National Plant Data Center. Warren, D.C. and B.L. Kay. 1984. Pericarp inhibition of germination of Atriplex confertifolia. In: Tiedemann, A.R. McArthur, E.D., Stutz, H.C., Stevens, R., and K.L. Johnson. 1983. Proceedings-Symposium on the biology of Atriplex and related chenopods.

General

Technical Report INT-172. Intermountain forest and Range Experiment Station. Ogden, UT. 309p. Welsh, S.L., Atwood, N.D., Goodrich, S. and L.C. Higgins. 2003. A Utah Flora. Brigham Young University. Provo, UT. 912p. Whiting, A. F. 1939 Ethnobotany of the Hopi. Museum of Northern Arizona Bulletin #15 (p. 73). Citation D. Tilley and L. St. John, L. 2013. Plant guide for shadscale saltbush (Atriplex confertifolia). USDA-Natural Resources Conservation Service, Plant Materials Center, Aberdeen, Idaho 83210. Published February 2014 Edited: 22Jan2014ls;27Jan2014jab For more information about this and other plants, please contact your local NRCS field office or Conservation District at http://www.nrcs.usda.gov/ and visit the PLANTS Web site at http://plants.usda.gov/ or the Plant Materials Program Web site http://plant-materials.nrcs.usda.gov. PLANTS is not responsible for the content or availability of other Web sites.

Plant Traits

Growth Requirements

Temperature, Minimum (°F)-38
Adapted to Coarse Textured SoilsYes
Adapted to Fine Textured SoilsYes
Adapted to Medium Textured SoilsYes
Anaerobic ToleranceNone
CaCO3 ToleranceHigh
Cold Stratification RequiredNo
Drought ToleranceHigh
Fertility RequirementMedium
Fire ToleranceLow
Frost Free Days, Minimum165
Hedge ToleranceMedium
Moisture UseMedium
pH, Maximum9.0
pH, Minimum7.5
Planting Density per Acre, Maxim2800
Planting Density per Acre, Minim1200
Precipitation, Maximum12
Precipitation, Minimum4
Root Depth, Minimum (inches)10
Salinity ToleranceHigh
Shade ToleranceIntolerant


Morphology/Physiology

BloatLow
ToxicityNone
Resprout AbilityNo
Shape and OrientationSemi-Erect
Active Growth PeriodSpring and Summer
C:N RatioHigh
Coppice PotentialNo
Fall ConspicuousNo
Fire ResistantYes
Flower ColorYellow
Flower ConspicuousNo
Foliage ColorGreen
Foliage Porosity SummerModerate
Foliage Porosity WinterPorous
Foliage TextureCoarse
Fruit/Seed ConspicuousNo
Nitrogen FixationNone
Low Growing GrassNo
LifespanModerate
Leaf RetentionNo
Known AllelopathYes
Height, Mature (feet)3.0
Height at 20 Years, Maximum (fee3
Growth RateSlow
Growth FormMultiple Stem
Fruit/Seed ColorBrown


Reproduction

Vegetative Spread RateSlow
Small GrainNo
Seedling VigorLow
Seed Spread RateSlow
Fruit/Seed Period EndFall
Seed per Pound60585
Propagated by TubersNo
Propagated by SprigsNo
Propagated by SodNo
Propagated by SeedYes
Propagated by CormNo
Propagated by ContainerYes
Propagated by BulbNo
Propagated by Bare RootYes
Fruit/Seed PersistenceNo
Fruit/Seed Period BeginSummer
Fruit/Seed AbundanceMedium
Commercial AvailabilityRoutinely Available
Bloom PeriodEarly Summer
Propagated by CuttingsNo


Suitability/Use

Veneer ProductNo
Pulpwood ProductNo
Protein PotentialMedium
Post ProductNo
Palatable HumanNo
Palatable Graze AnimalHigh
Palatable Browse AnimalHigh
Nursery Stock ProductNo
Naval Store ProductNo
Lumber ProductNo
Fodder ProductNo
Christmas Tree ProductNo
Berry/Nut/Seed ProductNo

<i>Atriplex subconferta</i> Rydb.

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