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Common Names

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oceanspray

creambush oceanspray

creambush rockspirea

creambush rock spirea

hillside oceanspray
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Conservation Status

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Oceanspray had no special protection status as of 2010. Information on state- and province-level protection status of plants in the United States and Canada is available at NatureServe.
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Description

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More info for the terms: achene, fruit, sclerophyllous, shrub, shrubs

Botanical description: This description covers characteristics that may be relevant to fire ecology and is not meant for identification. Keys for identification are available (for example, [97,99,117,193]). Morris and others [161] provide a key for identifying oceanspray and other shrubs in winter. Oceanspray and rockspirea are distinguished by their forms, leaf characteristics, and distributions [136]; intergradation of the 2 species is most pronounced in Nevada [104] and Utah [236].

  Photo © 2009 Barry Breckling

Morphology:
Form: Oceanspray is a deciduous [1,41,198], spreading shrub with slender arching branches [75,136,223]. It can range from bushy forms about 2.5 feet (0.75 m) tall on poor or frequently disturbed sites to arborescent forms that may be 20 feet (6.1 m) tall in coastal areas. Plants are usually 3 to 10 feet (1-3 m) in height [52,99,198]. They typically have multiple branches [198]. Stem wood is hard and dense [73]; bark of mature plants is shreddy [41,174]. Stand structures of plant communities where oceanspray is important are discussed in the Stand structure section of Fuels.

Leaves and flowers: The leaves are mostly 1.6 to 2.75 inches (4-7 cm) long and 0.8 to 2.75 inches (2-7 cm) wide [136,223]. Oceanspray has a large leaf area relative to most associated shrubs. In the Siskiyou Mountains of southwestern Oregon, its leaves were more densely packed, larger, thinner, and more prone to wilt than leaves of associated shrub species [40].

Oceanspray flowers are small, about 2 mm long [163]. They are borne on large, showy, terminal panicles that may reach 12 inches (30 cm) long [22]. The name "oceanspray" is derived from these masses of loose, creamy plumes [50]. The fruit is a 1-seeded [45] achene [41,97,117], about 2 mm long [198].

Roots: Rooting depth is likely associated with depth to bedrock. In southwestern Oregon, oceanspray extracted water from no deeper than 3 feet (1 m) below ground, indicating a shallow root system [40]. Dyrness and Franklin [57] had similar findings in the west-central portion of the Cascade Range in Oregon, where shallow soils confined roots to <3 feet below the soil surface. However, a planting guide for the Pacific Northwest reports oceanspray roots as "deep and wide" [154], and researchers described oceanspray as "relatively deep-rooted" in the Blue Mountains [249].

Descriptions of oceanspray's root morphology were not found in the literature as of 2010.

Life span: This species rarely lives more than 30 years [10]. On the Jasper Ridge Biological Reserve, California, its mean life span was 4.5 years [1].

Physiology: Oceanspray is highly drought tolerant [51]. It has adapted to dry sites and drought by shutting down or slowing its rate of transpiration. In droughty conditions, it apparently uses water less efficiently than associated sclerophyllous species. Its large leaf area, however, may partially compensate for low water transpiration rates in summer. It is likely that oceanspray depletes water in upper soil layers rapidly in summer [40].

Antieau [13] suggested that oceanspray may differ in water-use efficiency and cold tolerance across its distribution.

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Description

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Distribution

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Oceanspray is native to the western United States and southwestern Canada. It occurs from southern British Columbia south to southern California and Arizona and east to western Montana [86,100,103]. A few collections have been made in Colorado [227]. Plants Database provides a distributional map of oceanspray.
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Fire Regime Table

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Flower and seed production

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More info for the terms: fruit, seed

Thinning, burning, or other canopy-opening events may increase oceanspray's seed output. In the understories of coast Douglas-fir forests in western Oregon, oceanspray showed a "large increase" in flower and/or fruit production after moderate thinnings (leaving 200 trees/ha) or heavy thinnings (leaving 100 trees/ha or 0.4-ha openings); production increases were "minimal" after light thinning (leaving 300 trees/ha) [213].
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Fuels

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More info for the terms: association, cover, density, fire exclusion, fire severity, forest, fuel, herb, herbaceous, ladder fuels, mesic, severity, shrub, shrubs, snag, tree, tussock

Oceanspray is most frequent on south slopes of dry montane forests (see Site Characteristics); these sites typically burn earlier in the season or with higher severities than cooler, drier sites. In northern Idaho, Smith and Fischer [204] placed the Pacific ponderosa pine, Rocky Mountain Douglas-fir, and grand fir forests where oceanspray is most typically dominant in Fire Group 2. These forests tend to have warm temperature regimes, dry to moderate soil moisture, and are generally more productive—with heavier loads of downed woody fuels—compared to cooler or drier forests. Oceanspray also occurs in mesic to moist grand fir forests (Fire Group 7); these forests also have heavy fuel loads. See Smith and Fischer [204] for fuel load measurements representative of coniferous forest habitat types where oceanspray is important in northern Idaho.

In Pacific ponderosa pine-grand fir forests of Washington and Oregon, growing-season moisture content of shrubs, including oceanspray, averaged >125% over 2 years. Shrub moisture content peaked in June at ~175%. Moisture contents of dominant overstory trees are also described in this study [7].

In many forest types with oceanspray, fire exclusion has resulted in higher loads of woody debris compared to woody fuel loads when historic FIRE REGIMES were still functioning. In white fir stands in the Siskiyou Mountains of southwestern Oregon, large woody-debris loads were positively correlated with time-since-fire (P=0.01). Snag density was positively correlated with low (30 snags/ha) and high (23 snags/ha) fire severities (P=0.05). The authors attributed the correlation to nonconsumption of preexisting snags at low fire severity and creation of new snags at high severity. In this study, oceanspray dominated the shrub layer of white fir stands in dry, interior valleys [238].

Stand structure: Stand structure of communities where oceanspray is an important component of the vegetation is variable, as is the amount of fuel oceanspray contributes. On some sites, structure is open, with a sparse shrub component. In the west-central portion of the Cascade Range of Oregon, the coast Douglas-fir/oceanspray association displayed a relatively open stand structure (30-60% crown closure) of old growth, with few shrubs and a "very poorly developed" herb layer. Oceanspray cover averaged 5% [57]. Another study of coast Douglas-fir/oceanspray communities in the Cascade Range found that except for oceanspray, the tall-shrub layer was depauperate; low-shrub and herbaceous cover was also low. Incense-cedar, however, was encroaching in the subcanopy. Tree densities averaged 53 stems/ha for coast Douglas-fir and 5/ha for incense-cedar [153]. Live shrubs, including oceanspray as a dominant, comprised <5% of total stand biomass in mixed-conifer communities in the White Cap Wilderness Study Area of northern Idaho. Total shrub fuel loads ranged from 204 to 2,190 lbs/acre; shrubs were 0.6 inch to 27 inches (1.5-69 cm) tall, with 2% to 50% cover [26].

Some communities with oceanspray have denser overstories and/or understories. A coast Douglas-fir/oceanspray stand on the west-central portion of the Cascade Range, Oregon, had 70% tree cover, 46% shrub cover, and 36% herb cover. Aspect of the forest was southwest; it was the hottest and driest of 18 stand types examined [256]. Bailey [20] found coast Douglas-fir/oceanspray-salal habitat types off the southern coast of Oregon had relatively open canopies and "well-developed" shrub layers. Oceanspray averaged 30% cover [20]. Western redcedar-western hemlock forests often have a dense overstory, but understory cover of oceanspray and other shrubs may be sparse [204].

Mixed-conifer forests of southern Oregon and California are structurally and compositionally complex, with small conifers—often white fir and/or incense-cedar—often forming ladder fuels in a well-developed subcanopy. Snags and large, downed woody debris are common, but fuel loads are highly variable. Many of these mixed-conifer forests support a moderate to dense shrub understory, although some have few shrubs but a dominant herbaceous layer, and others have both depauperate understory and ground layers [34]. Stand structure in California's mixed-conifer forests was mostly open in the presettlement period [79].

Insect attacks increase snag densities in oceanspray habitats, which eventually increase dead and downed woody fuel loads. Youngblood and Wickman [250] provide data on stand structure, live and dead tree abundance, and shrub and herb cover of a grand fir-Douglas-fir forest attacked by Douglas-fir tussock moths 23 years prior. Oceanspray was an important component of the understory (5% cover); the site was in the Wenaha-Tucannon Wilderness in the Blue Mountains of Washington and Oregon [250].

Models: A few models were available for predicting oceanspray's contribution to total fuel loads as of 2010. Smith and Brand [205] review equations for predicting oceanspray biomass. Harris [90] presents models to predict oceanspray aboveground biomass and cover; the models were developed from data collected in coast Douglas-fir, grand fir, and western larch forests on the Umatilla National Forest. Brown [27] provides a model for predicting total aboveground oceanspray biomass and total leaf biomass based on basal stem diameter. Samples on which the model is based were collected in northern Idaho and western Montana [27].

Leaf area indices are used in some fuel models [49]. In the Siskiyou Mountains of southwestern Oregon, oceanspray had a large mean leaf area compared to associated shrubs; about twice as large as the leaf areas of associated greenleaf manzanita (Arctostaphylos patula) and redstem ceanothus (Ceanothus sanguineus) [40]. Agee and Lolley [6] placed oceanspray in fuel type 2: shrubs with thick stems but thin leaves.

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Fuels and Fire Regimes

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Germination, seedling establishment, and plant growth

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More info for the terms: seed, stratification

Fresh oceanspray seed is dormant [74]. In the field, it likely requires overwintering to germinate. As of 2010, little research had been conducted on oceanspray's germination requirements [197]. Stratification at around 41 oF (5 oC) [197] for 15 to 18 weeks breaks dormancy in the laboratory [12,113,197].

Oceanspray seed may have low viability. According to a fact sheet, most seeds lack developed embryos, so only about 7% of a given seed lot may be sound [74].

Seedling establishment is uncommon [140,149,150,208,213] but has been documented a few times. Open stand structure [214], heat, and bare mineral soil may favor oceanspray germination and establishment (review by [196]). In the Oregon Coast Range, oceanspray seedlings emerged well (>70%) in both clearcuts and young, unthinned conifer stands; however, seedlings survived only in the young, unthinned stands [214]. Oceanspray established from seed 3 growing seasons after a debris flow on the Central Coast Ranges of southwestern Oregon [173]. See Seedling establishment in the Plant Response to Fire section for studies on postfire seedling establishment.

A review states that oceanspray seedlings grow slowly in their first 2 years of development [196]. Plants released by overstory removal may grow rapidly, however. Daubenmire and Daubenmire [51] found that in northern Idaho, oceanspray grew up to 15 feet (4.6 m) tall following harvest of the Rocky Mountain Douglas-fir overstory; this was twice its stature in unharvested Rocky Mountain Douglas-fir forests.

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Growth Form (according to Raunkiær Life-form classification)

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More info on this topic.

More info for the term: phanerophyte

Raunkiaer [180] life form:
Phanerophyte
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Habitat characteristics

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More info for the terms: association, cover, forest, frequency, fresh, mesic, presence, woodland

Soils: Oceanspray tolerates soils with a pH range from approximately 5.0 to 7.5, fine to coarse textures, and low nutrient and moisture content [74]. In western redcedar-western hemlock forests of northern Idaho, it had significantly greater cover in soils with pH above 6.1 than in soils with lower pH values (6% vs. ≤1% cover, P=0.05) [165]. Soils supporting oceanspray are often shallow ([87,94,100], review by [196]). In the Blue Mountains of Washington and Oregon, however, oceanspray is dominant in Pacific ponderosa pine-Rocky Mountain Douglas-fir forests on deep, fertile soils similar to those of Palouse prairie [84].

Oceanspray is common in sands and clay loams (review by [196]) but may occur in all soil textures. In the Cascade Range of Oregon, coast Douglas-fir/oceanspray communities occur on coarse soils and loams but not on fine soils [153]. A study in the Blue Mountains, however, found oceanspray presence was positively correlated with fine-textured soils (P<0.05) [249]. In western redcedar-western hemlock forests of northern Idaho, oceanspray cover, frequency, and importance value increased as soil organic matter increased; increases in importance values were significant (P=0.05) [165]. Soils supporting oceanspray are often stony [67,87,94,97,98,100], and oceanspray sometimes grows within rock crevices. It is common on talus slopes (review by [196]). In Nevada and western Utah, oceanspray grew on talus slopes near mountain meadows and in granite boulder piles [65].

Oceanspray occurs on a variety of parent materials. In the Cascade Range of Oregon, coast Douglas-fir/creambush oceanspray communities occur on poorly developed basalts, andesites, and other parent materials of volcanic origin [153]. At Oregon Caves National Monument, mixed-conifer forests with oceanspray occur on soils of diorite origin [240]. Poison-oak (Toxicodendron diversilobum)-creambush oceanspray-Mexican elderberry (Sambucus mexicana) communities of San Luis Obispo County, California, are associated with andesite-derived soils [235].   Photo © Br. Alfred Brousseau, St Mary's College

Moisture regime: Oceanspray is most common on dry sites. McDonald and others [148] list oceanspray as an indicator species of dry montane/shrub forests of the Northern Rocky Mountains. Oceanspray is also associated with dry montane forests in British Columbia [168,179] and elsewhere in the Pacific Northwest. It is an indicator species of very dry to moderately dry, nitrogen-medium soils in coastal British Columbia [110,111]; its occurrence decreases with increasing precipitation [111]. It also grows in dry to fresh soils in coniferous forests of interior British Columbia [168]. The western hemlock-coast Douglas-fir/oceanspray association occurs on some of the hottest and driest sites in the Cascade Range of Washington [222]. In the west-central portion of the Cascade Range in Oregon, Dyrness and Franklin [57] found the coast Douglas-fir/oceanspray association occurs on the dry end of coast Douglas-fir forest types. In an extreme case, oceanspray is "widespread but not abundant" on the Indian Plateau of southwestern Oregon. The plateau is a severe site known for widely fluctuating and extreme temperatures in winter and summer and a record of poor artificial regeneration of conifers [156].

Oceanspray is also reported from sites with moist to mesic soils. It is frequently associated with riparian communities (review by [196]). In southeastern Washington and northern Idaho, Pacific ponderosa pine/mallow ninebark-oceanspray communities dry out later in the growing season than Pacific ponderosa pine/common snowberry communities [152]. Oceanspray occurs on moist woodland edges in California [97] and in moist open woods in British Columbia [193]. In western redcedar-western hemlock forests of northern Idaho, oceanspray frequency was significantly greater on sites with 21% to 25% soil moisture content than on sites with drier or wetter soils [165].

Aspect and topography: This species is most common on warm, dry, south-facing slopes [67,98,165]. A grand fir/oceanspray association in southwestern Washington is common on exposed, south-facing slopes and on ridgetops. Sites having this association remain snow-free much of the year and experience extreme summer drought [221]. In Douglas-fir (Pseudotsuga menziesii) forests in the Columbia River Gorge of Washington, oceanspray had greatest cover on south-facing slopes (13%) and least cover in mesic ravines (6%) [243]. The coast Douglas-fir/oceanspray association in Oregon's Coast Ranges occurs most often on relatively steep, south- or west-facing slopes between 2,000 and 3,000 feet (600-900 m) elevation. The environment is hot and dry, and the growing season is long, with drought developing by midsummer. Snowpacks are not generally deep or persistent [94]. The western hemlock-Douglas-fir/oceanspray association is found in some of the hottest and driest forests in the western Cascade Range. Sites are "always" upper slopes and fairly steep, and drainage and solar input are "excessive" [87]. Coast Douglas-fir/oceanspray communities in the Cascade Range of Oregon are also most prevalent on dry, south-facing slopes [153]. In western redcedar-western hemlock forests of northern Idaho, oceanspray cover, frequency, and importance values were significantly greater on south- than north-facing slopes (P=0.05) [165].

Oceanspray grows on more mesic exposures as well. In montane zones on the Umatilla National Forest, it dominated the understory on north, northeast, northwest, and east aspects [90]; in western Oregon clearcuts it occurred only on north-facing slopes [246]. Oceanspray mostly grows on moist slopes in southern California [41], where it reaches the southern end of its distribution.

Elevation: Oceanspray occurs from sea level to about 7,000 feet (2,150 m) across its range. It mostly grows on low-elevation montane sites. In western redcedar-western hemlock forests of northern Idaho, oceanspray cover, frequency, and importance values were significantly greater on 3,000- to 3,400-foot (910-1,000 m) elevations than on higher-elevation sites (P=0.05) [165]. Oceanspray grows mostly on high peaks in the Great Basin (review by [196]).

Location Elevation eastern Washington and Oregon, Blue Mountains 1,700-4,800 feet [84] Deschutes National Forest, Oregon, east slopes >2,800 feet, from ponderosa pine to subalpine mixed-conifer zones [212] California <5,900 feet [97] southern California <4,500 feet [41] Nevada 4,500-9,500 feet [104] Pacific Northwest sea level to 5,500 feet [135]

Climate: Oceanspray occurs mostly in dry zones [135], although it is characterized as a "predominantly humid zone species" in western Washington [53]. Annual precipitation across its United States distribution [37,56,97,137,215,241] ranges from 9.3 inches (236 mm) in central Oregon [56] to 57 inches (1,140 mm) in western Washington [137].

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Importance to Livestock and Wildlife

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More info for the terms: cover, forest, habitat type, prescribed fire, shrub, shrubs

Browse: Oceanspray is a minor browse species [41,50,125,161,178,203,226]. Ungulates generally browse it only when more palatable forage is unavailable [84]. Many low-elevation, dry-site Douglas-fir forests with oceanspray are important cattle rangelands, but the cattle generally seek forage other than oceanspray [35]. Oceanspray is considered poor forage in Idaho [203] and an undesirable "competitor" with redstem ceanothus, a more desirable browse species [139]. Among ungulates in British Columbia, only Sitka black-tailed deer made much use of oceanspray [23].

Importance of oceanspray as browse for wild ungulates in British Columbian [23] Ungulate Importance as Browse Sitka black-tailed deer moderate white-tailed deer low mountain goat low bighorn sheep low Roosevelt elk low Rocky mountain elk low moose low caribou low

However, because this species is common and readily available to wildlife and livestock on low-elevation rangelands, ungulates may make light but frequent use of oceanspray in summer [161,226]. Cattle use it as summer forage in northern Idaho [35,217] and northeastern Oregon [115].

Wildlife [125,161] and livestock [125] sometimes browse oceanspray more heavily [36,62,115], especially in late fall and winter when green forage is less available [125,197]. Snowshoe hares in the Flathead region of western Montana use the leaves and twigs for fall forage [3]. Studies on the Bitterroot National Forest and in the Rattlesnake Creek drainage of western Montana found elk, mule deer, and white-tailed deer preferred oceanspray as winter forage [109,146]. Columbian black-tailed deer in western Oregon browse oceanspray twigs in winter [47]; mule deer on the Los Padres National Forest of southern California also use oceanspray [184]. Oceanspray is heavily utilized by migrating mule deer and elk in central Washington [187].

Green clippings of oceanspray were found in dusky-footed woodrat shelters in Oregon [29], and the shrub is apparently palatable to native slugs in western Washington [31].

Palatability and/or nutritional value: Oceanspray is usually unpalatable to ungulates [157,158] and other browsing animals. A review rated its palatability as poor to fair for cattle and fair for domestic sheep [80]. A study on the Tillamook Burn of northwestern Oregon found mountain beavers browsed oceanspray less than expected based on availability [46]. New postfire sprouts are most palatable ([18,166], review by [196]). On burned sites in northern Idaho, big game species in northern Idaho preferred browsing sprouts of oceanspray and other shrubs to browsing current-year growth of shrubs on adjacent unburned sites, especially the first growing season after fire [18]. On one site, elk utilization of oceanspray increased from 1.3% before fire to 36.3% a year after prescribed fire; elk use dropped to 6.9% in postfire year 2 [127]. Asherin [18] also noted that big game species browsed oceanspray readily in postfire year 1, but use dropped after that. Browsing ungulates may pass over oceanspray sprouts if more palatable shrubs are available. On a wildfire-burned Rocky Mountain Douglas-fir/mallow ninebark habitat type on upper Selway River, northern Idaho, mule deer browsed oceanspray "minimally" in postfire years 2 and 3, while western serviceberry and Scouler willow were used heavily [105]. Following prescribed fires on the Lochsa Watershed in northern Idaho, elk preferred Scouler willow, western serviceberry, and Rocky Mountain maple sprouts to those of oceanspray [126].

Habitat: Conifer/oceanspray communities provide important habitat to a variety of wildlife species. Along the Umatilla River of Oregon, white-tailed deer used Pacific ponderosa pine-coast Douglas-fir/oceanspray and Pacific ponderosa pine/oceanspray communities more than expected based on availability (P<0.0001) [21]. On sky islands across Nevada and in western Utah, yellow-bellied marmot burrows were closely associated with oceanspray, "almost without exception" [64,65]. In the central Oregon Coast Ranges, oceanspray was found on streamside and upslope habitats where 18 of 22 small mammal species and 9 of 13 amphibian species known to the area were captured [145]. This shrub is also common in northern Idaho Pacific treefrog habitats [190].

Cover value: Oceanspray provides cover for a variety of species. Blue grouse hide beneath oceanspray and other shrubs [66]. Dense shrub understories in Rocky Mountain Douglas-fir/mallow ninebark habitat types—where oceanspray is common to codominant—provide visual and thermal cover for deer and elk; in addition, these sites supply nesting habitat, cover, and food for a variety of nongame birds and mammals [36].

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Key Plant Community Associations

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More info for the terms: association, climax, cover, cover type, forest, habitat type, hardwood, mesic, natural, series, shrub, succession

Oceanspray is important or dominant in many plant communities of the Pacific Northwest, California, and the Northern Rocky Mountains. These communities include seral and old-growth conifer, seral and old-growth hardwood, mixed-riparian, and mixed-shrubland types.

Conifer communities:
Oceanspray is called "the most widespread and possibly the most abundant flowering shrub" in coniferous forests of northeastern Washington and northern Idaho [225]. On the Umatilla National Forest, Washington, it is dominant in coast Douglas-fir (Pseudotsuga menziesii var. menziesii), grand fir (Abies grandis), and western larch (Larix occidentalis) forests [90].


 
In Oregon, coast Douglas-fir/oceanspray associations on the Willamette National Forest are primarily structurally diverse old-growth stands, containing long-lived canopy trees and a subcanopy of younger trees. Most of the stands are >150 years old [94]. Oceanspray
is common to dominant in dry white fir (A. concolor) forests in the Siskiyou Mountains of southwestern Oregon [238], and it is an important shrub
in Port-Orford-cedar (Chamaecyparis lawsoniana) communities of southwestern Oregon and northwestern California [257]. It is important in many
mixed-conifer forests of southern Oregon and California [33,34]. These communities are codominated by Pacific ponderosa pine (P. ponderosa var.
ponderosa), coast Douglas-fir, Jeffrey pine (P. jeffreyi), California black oak (Quercus kelloggii), tanoak
(Lithocarpus densiflorus), and/or canyon live oak (Q. chrysolepis) [34]. Oceanspray is also important in knobcone pine
(P. attenuata) communities of southern Oregon and California [39].
Oceanspray in mixed-conifer forest of Oregon's Cascade Range. Photo permission of Craig Smith.

In California, oceanspray is a characteristic to dominant species of redwood (Sequoia sempervirens) [202,254], Pacific ponderosa pine [116], shore pine (P. contorta var. contorta) [255], and Sierra Nevada lodgepole pine (P. c. var. murrayana) [77] forests. It is a minor species in pinyon-juniper (Pinus-Juniperus spp.) communities [24].

Oceanspray is associated with Rocky Mountain Douglas-fir (Pseudotsuga menziesii var. glauca) and Rocky Mountain lodgepole pine (Pinus contorta var. latifolia) in northern Idaho [217]; it is commonly dominant in Rocky Mountain Douglas-fir forests of northern Idaho and Montana [178,217,225]. It is infrequent to common in western redcedar-western hemlock (Tsuga heterophylla-Thuja plicata)) forests of the Interior Pacific Northwest and the Northern Rocky Mountains [148,186].

Hardwood communities:
Oceanspray occurs in the understories of Oregon white oak (Q. garryana) communities throughout Oregon white oak's range ([147,185,216], review by [122]). It also occurs or dominates in other montane oak (Quercus spp.) communities in California [142].

Riparian:
Oceanspray occurs in riparian communities throughout its range (review by [196]). Overstory dominants may be conifers, hardwoods or a mix [112,219]. Meriwether Lewis made the first scientific collection of oceanspray on the banks of the Clearwater River in Idaho [48]. Oceanspray is dominant in grand fir floodplain associations of eastern Washington [112]. In western hemlock stands in the central Cascade Range of Washington, it was more common on high floodplains than on low floodplains [229]. On Myrtle Island Research Natural Area, Oregon, oceanspray is occasional in red alder-Oregon ash (Alnus rubra-Fraxinus latifolia) and willow/field horsetail (Salix spp./Equisetum arvense) riparian communities [219].

Shrublands:
Oceanspray is common to dominant in mixed montane shrublands of the Pacific Northwest and the Northern Rocky Mountains [51,204]. These communities are common on harsh slopes and in coniferous forests in early succession [51]. In montane regions of Nevada and western Utah, creambush
oceanspray occurs in mosaics of mountain meadow and mountain big sagebrush (Artemisia tridentata subsp. vaseyana) stands [65]. In Redwood National Park, California, it occurs in Lewis' mockorange/brittle bladderfern (Philadelphus lewisii/Cystopteris fragilis) and Sierra gooseberry/varileaf phacelia (Ribes roezlii/Phacelia heterophylla) bald-hill communities [211]. On the Jasper Ridge Biological Reserve in coastal northern California, oceanspray is an associated species in chamise (Adenostoma fasciculatum) chaparral communities [1].

Publications describing plant communities where oceanspray is a dominant or indicator species are listed below.

Pacific Northwest:

Washington:
  • western hemlock/salal (Gaultheria shallon)-oceanspray forest association of the Olympic National Forest [95]
  • western hemlock-coast Douglas-fir/oceanspray association of the Gifford Pinchot National Forest [222]
  • coast Douglas-fir-Pacific madrone (Arbutus menziesii)/hairy honeysuckle (Lonicera hirsuta)-oceanspray and
    coast Douglas-fir-Pacific madrone/salal-oceanspray associations across the Puget Trough of west-central Washington [32]
  • Rocky Mountain lodgepole pine/Rocky Mountain maple-Saskatoon serviceberry (Acer glabrum-Amelanchier alnifolia)-oceanspray woodlands and forests;
    occur on the east side of the Cascade Range, the Okanogan Highlands, and the Blue Mountains [43]
  • Pacific ponderosa pine-coast Douglas-fir/Saskatoon serviceberry-oceanspray communities of the Blue Mountains [84]
  • oceanspray and oceanspray-mallow ninebark shrublands on north-facing slopes of the Blue Mountains [51]
  • east-canyon mixed shrublands of the Columbia Basin and Blue Mountains [44]
  • grand fir-oceanspray floodplain association of eastern Washington; this type is a variant of the grand-fir-common snowberry (Symphoricarpos albus) floodplain association [112]
  • Rocky Mountain Douglas-fir-Pacific ponderosa pine-Rocky Mountain lodgepole pine/mixed shrub forest zone in the Wallowa Mountains [38]
  • Pacific ponderosa pine/mallow ninebark (Physocarpus malvaceus)-oceanspray association of southeastern Washington [152]
  • Rocky Mountain Douglas-fir-mallow ninebark-oceanspray habitat type of eastern Washington
Oregon:
  • coast Douglas-fir/oceanspray forest communities in the west-central Cascade Range; characterized by open stands of old growth [57]
  • coast Douglas-fir/oceanspray/grass and coast Douglas-fir/oceanspray/vine maple (Acer circinatum) community types of the western
    Cascade Range; the former is the most widely distributed of Oregon's dry-forest types [153]
  • Rocky Mountain lodgepole pine/Rocky Mountain maple-Saskatoon serviceberry-oceanspray woodlands and forests; occur on the east side of the Cascade Range
    and the Blue Mountains [43]
  • oceanspray and oceanspray-mallow ninebark shrublands on north-facing slopes of the Blue Mountains [51]
  • Pacific ponderosa pine-Rocky Mountain Douglas-fir/western snowberry-oceanspray communities of the Blue Mountains [84]
  • east-canyon mixed shrublands of the Columbia Basin and Blue Mountains [44]
  • westside Oregon white oak/oceanspray and dry coast Douglas-fir/oceanspray woodlands and forests; mostly in Willamette Valley and the
    Klamath Mountains [33]
  • coast Douglas-fir/oceanspray-whipplevine (Whipplea modesta) series on the Coast Ranges; occurs on the Medford District of BLM and on the
    Siskiyou and Rogue River National Forests. Indicative of dry sites [19].
  • coast Douglas-fir/oceanspray/salal habitat type off the southern coast [20]
California:
  • coast live oak (Q. agrifolia)/oceanspray-common snowberry subseries of California's hardwood rangeland cover types; on upper-elevation
    (>1,250 feet (380 m)), mesic sites [9]
  • redwood-coast Douglas-fir-hardwood/oceanspray vegetation types of the North Coast Ranges [254]
  • canyon live oak (Q. chrysolepis)-oceanspray forest cover type of central California [142]
Northern Rocky Mountains:

Northern Idaho:
  • Rocky Mountain Douglas-fir/mallow ninebark-oceanspray habitat type [51,152]
  • Pacific ponderosa pine/mallow ninebark-oceanspray association
Montana:
  • Rocky Mountain Douglas-fir/oceanspray and Rocky Mountain Douglas-fir/mallow ninebark-oceanspray forest habitat types [178]
  • climax western redcedar-western hemlock, Rocky Mountain Douglas-fir, grand fir, and subalpine fir (A. lasiocarpa)-Rocky Mountain Douglas-fir-grand
    fir forests [186]
  • indicator species of the Rocky Mountain Douglas-fir/mallow ninebark habitat type [125]
Western United States:
  • indicator species of dry western redcedar-western hemlock/shrub, Pacific ponderosa pine/shrub, and Rocky Mountain Douglas-fir/shrub forests [148]
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Life Form

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Shrub
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Management considerations

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Oceanspray may interfere
with conifer seedlings on plantations [168]. Because its roots are often shallow, oceanspray is likely to compete with conifer seedlings for water [40].

Grazing:
Oceanspray may decline with grazing despite its relative unpalatibility; its growth response in browsing and clipping studies has been mixed. In northern
Idaho sites with elk, moose, mule deer, and white-tailed deer, oceanspray was more common inside than outside exclosures [8]. Another northern Idaho study in
a Douglas-fir habitat type found oceanspray decreased in cattle-grazed stands [253]. Similarly, in the Bitterroot Mountains of northern Idaho, oceanspray showed greater density, cover, and frequency on ungrazed plots than on plots grazed by cattle (989 vs. 522 plants/ha; 2.6% vs. 0.6%; 4.4% vs. 1.3%,
respectively, for desnity, cover, and frequency) [252]. Garrison [71] recommends ≤50% to 60% utilization of oceanspray to prevent the species' decline.


Daubenmire and Daubenmire [51] reported that in eastern Washington and northern Idaho, overgrazing of Pacific ponderosa pine/mallow ninebark stands, in which oceanspray often codominates, may result in a disclimax ponderosa pine/bluegrass (Poa spp.) community.



Exclosure studies in eastern Washington and eastern Oregon found that oceanspray production was significantly greater (P≤0.04) for completely clipped plants (100% of new growth removed, x=200 g/0.25 acre) compared with heavily (75%, x=151 g), moderately (50%, x=162 g), and slightly (25%, x=64 g) clipped plants. Much of the new growth was long twig and branch sprouts. Moderate or heavier clipping suppressed flower production. Results were averaged over 4 to 5 consecutive years of clipping [70].
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Other uses and values

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Oceanspray is planted as an ornamental [197]. Leaf extracts show antifungal, antiviral, and cytotoxic properties ([102], review by [164]).

Traditional uses: Native Americans used oceanspray for making implements, as medicine [255], and sometimes as food. The long, straight, hard branchwood was highly prized for making arrow shafts [50,224], as well as digging sticks, fishing hooks, and needles [73,224]. Native Americans used oceanspray for treating viral and skin diseases ([73], review by [164]) and as a tonic [73]. The bark and leaves were dried and pulverized for application to burns or sores [86]. The Pima made tea from the leaves [118], and Native Americans in the Inland Northwest ate the seeds [55].

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Phenology

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Oceanspray is among the first shrubs to initiate leaves in spring. Although floral buds swell in early [100] to late spring, oceanspray is a late bloomer [12]. Full flowering does not occur until late June or July and may continue into August in some areas [12,100]. Fruits mature in late summer and may persist until fall (reviews by [196,198]). Panicles and panicle branches typically persist through winter after drying in fall [196].

Leaf phenology is closely regulated by weather. In the Siskiyou Mountains of Oregon, leaf water conductance peaked in July [40]. On the Jasper Ridge Biological Preserve, mean leaf age was 4.5 months; leaves were drought-deciduous and mostly absent by August [1]. A study in the western redcedar-western hemlock zone of northern Idaho found summer or fall drought initiated leaf color change and leaf drop [55].

Oceanspray consistently shows a late and long period of flowering throughout its distribution:

Phenology of oceanspray across its range Area Event southern California flowers June-August [41] northern Idaho buds swell and burst late March-early April;
leaf-out late March-mid-April [55];
stem elongation late March-late June [55,170];
flowers early May-late June;
fruits late June-August [55,174];
leaves change color late June-late September [55,170];
leaves fall late July-late November;
seeds disperse late August-late November [55] Montana flowers late June-July [117] Nevada flowers June-August [104] southwestern Oregon flower buds expand in July;
flowers and fruits July-August [183] Oregon and western Washington flowers May-July;
seeds disperse August-September (review by [237]) Pacific Northwest flowers midsummer [113] Puget Sound flowers mid-June [12] Northern Rocky Mountains flowers mid- to late July;
fruit ripens late August;
seeds disperse late August-late November [170]
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Pollination and breeding system

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Insects pollinate oceanspray (review by [196]). The flowers are perfect [100].

Antieau [13] suggested that mountain ranges restrict oceanspray breeding. A study across oceanspray's distribution in Washington and Oregon showed phenotypic differences in oceanspray (for example, in leaf area); these differences were related to geographic regions and climate [13].

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Regeneration Processes

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Oceanspray regenerates by sprouting from the root crown [55,60,61,140,140,167,209,228,245] and establishing from seed [160]. Root crown sprouting is more prevalent than regeneration from seed [140,149,150,208,213]. Ackerly [1] characterizes oceanspray's reproduction as "opportunistic regeneration following disturbance". Fire and other top-killing events favor oceanspray regeneration.
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Seed banking

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Oceanspray has a soil seed bank [60,150]. In western hemlock forests of southwestern British Columbia, viable oceanspray seed was more common in undisturbed soils (x=15.5 germinants/0.04-m² soil sample) compared to clearcut rights-of-way in early-seral succession (x=1-2.5 germinants/0.04-m² soil sample) [150].
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Seed dispersal

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Oceanspray seed is disseminated by wind ([213,237,248], review by [198]) or animals [213].
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Successional Status

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Oceanspray is most common in early succession but occurs in all stages of succession. In mesic coniferous forests of northwestern Montana, it is approximately 5 times as dense in stands ≤150 years old than in old growth [14].

Seral occurrence: Disturbance favors oceanspray [111,113]. Kruckeberg [113] characterized oceanspray as a "colorful reclaimer of open or disturbed lands" of the Pacific Northwest, where it commonly establishes on recently logged sites, in second growth, and on roadbanks. It is especially common in seral Douglas-fir forests [111]. Following the Sundance Fire in northern Idaho, oceanspray was important or codominant in the first decade of postfire succession in Rocky Mountain Douglas-fir-western hemlock forests [206]. On another site in northern Idaho, oceanspray grew rapidly and dominated early-seral sites after a Rocky Mountain Douglas-fir forest was clearcut. The shrub layer regained precutting cover about 60 to 80 years after tree harvest [51]. Oceanspray seedlings established 3 growing seasons after a debris flow on the Central Coast Ranges of southwestern Oregon [173].

Oceanspray prefers open sites [111,218]. It is described as a "light demanding, early successional" species [218]. Logging and fire promote oceanspray by opening the canopy. A study at the Eastern Oregon Experiment Station showed shrub cover, including that of oceanspray, decreased with increasing cover of the mixed-conifer overstory. At about 90% canopy closure, shrub cover dropped to about 5%. However, even under a nearly closed canopy, a few shrubs remained alive in the understory, and seedlings of these shrubs established in canopy breaks [247]. In coast Douglas-fir/salal stands on foothills of the Cascade Range, Washington, maximum oceanspray cover occurred approximately 20 years after disturbance (clearcutting or wildfire); oceanspray generally declined after that [137]:

Oceanspray cover in different-aged Douglas-fir stands in Washington [137] Disturbance and stand age Postclearcut year 5 Postfire year 22 Postfire year 30 Postfire year 42 Postfire year 73 Cover (%) 1.72 4.46 3.34 2.13 2.84

Defoliation and/or death of overstory trees due to insects may favor oceanspray. In the Blue Mountains, oceanspray showed 5% cover and 15% frequency 23 years after a record-breaking, 2-year attack by Douglas-fir tussock moths. About 1,250 miles² (3,240 km²) of a grand fir-Douglas-fir forest was affected by the outbreak [250].

Where it is a minor species, oceanspray may not decline with canopy closure. In western redcedar-western hemlock forests of northern Idaho, its cover, frequency, and importance values were not significantly different in 5 canopy-cover classes ranging from 1% to 100% closure. Oceanspray had ≤1% cover in all canopy-cover classes. Similarly, its cover, frequency, and importance values in these forests were not significantly different between logged, logged-and-burned, single-broadcast-burned, or multiple-broadcast-burned sites and sites with no history of logging or prescribed fire [165].

Logging: Lightly-shaded areas, such as those occurring a few decades after thinning, can promote oceanspray growth [194]. In Douglas fir-western hemlock forests of coastal Oregon, oceanspray was associated with intermediate tree densities (P<=0.01) [199]. In Douglas- fir stands in northern Idaho, its cover peaked about 20 years after logging [176].

Oceanspray cover in unlogged and logged Douglas-fir stands in northern Idaho [176] Treatment Unlogged Logged 13 years previous Logged 20 years previous Logged 40+ years previous Cover (%) 0.6 21.4 26.8 8.0

On the Fort Lewis Military Reservation of Washington, a late 1990s study found oceanspray cover was greater in a coast Douglas-fir/oceanspray forest that had been clearcut in the 1920s and thinned twice afterwards (2.5% oceanspray cover) than in a coast Douglas-fir/oceanspray forest that had been partially cut only once, in the 1930s (1.5% oceanspray cover) [220]. In Pacific ponderosa pine and Rocky Mountain Douglas-fir habitat types of the Swan Valley, Montana, oceanspray cover was greater on clearcut (15%) and plantation (10%) plots than on untreated plots (8%) [69].

In the Klamath Mountains of Oregon and California, shrubfields of oceanspray and other sprouting shrubs develop after logging or fire when conifers fail to regenerate in the early postfire community; conifers eventually replace the shrubs on most sites [149].

Logging does not favor oceanspray on all sites. In northern Idaho logging reduced oceanspray frequency slightly compared to its frequency in the understory of an adjacent unlogged site. The study site was in a western hemlock/pachistima forest. A tall-shrub (>3 feet (1 m)) community developed after logging; oceanspray was a component of this early-seral, tall-shrub community. On cut sites, oceanspray had 1.4% frequency 7 years after logging and 0.7% frequency 25 years after logging. It had 2.1% cover on the unlogged site 25 years after treatments [242].

See Plant response to fire for more information on oceanspray occurrence in seral postfire communities.

Late-successional occurrence: Oceanspray sometimes occurs in late succession. In Glacier Park's western redcedar-western hemlock forests, it is mostly restricted to late-seral or climax communities [81]. Oceanspray also occurs in late succession in western redcedar-western hemlock and grand fir forests of Montana [186], and it is a late-successional or climax species in some western hemlock habitat types of Washington [95] and northern Idaho [251]. However, Henderson and others [95] point out that on the Olympic National Forest, climax western hemlock/salal-oceanspray forests rarely develop due to recurrent fires. Coast Douglas-fir dominates the seral stands; oceanspray often codominates the understory of these seral stands [95]. Oceanspray also dominates the understories of late-successional Douglas-fir forests in Oregon [256] and Montana [186]. In mixed-conifer forests of western Oregon and California, oceanspray and other deciduous shrubs are more likely to dominate in late succession on north-facing and other mesic slopes than on south-facing, dry slopes [240].
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Synonyms

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Holodiscus discolor (Pursh) Maxim. var. dumosus (Nutt. ex Hook.) Maxim. ex J.M. Coult.

Holodiscus dumosus (Pursh) Maxim. var. glabrescens (Greenm.) Jeps. [104]
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Taxonomy

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The scientific name of oceanspray is Holodiscus discolor (Pursh) Maxim (Rosaceae) [97,99,103,117,193].

The Holodiscus taxonomy is confused because oceanspray, rockspirea (H. dumosus),
and small-leaved rockspirea (H. microphyllus) are taxonomically and morphologically very similar [45,163]. Authorities separating these 3 closely related taxa do so based on different leaf morphologies [45,136] and distributions [136]. This review follows the taxonomy of Lis (in [97]), who authored the Flora of North America's [63] Holodiscus chapter. In Lis's treatment, oceanspray, rockspirea, and small-leaved rockspirea are treated as separate and distinct species [97]. Some systematists lump either oceanspray and rockspirea [104,236], oceanspray and small-leaved rockspirea [103], or all 3 taxa [233] into single species.

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Value for rehabilitation of disturbed sites

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Oceanspray could potentially be used on Burned Area Recovery sites, although to date (2010), there was no documentation of its suvivorship after transplanting onto burns. It is used successfully for erosion control ([154], review by [196]), highway plantings, windbreaks, riparian plantings, and wildlife plantings (reviews by [196,197]). It establishes readily through natural regeneration on burned sites [35,246] (see Successional Status and Plant response to fire). In northern Idaho, for example, oceanspray dominated (48% of total understory cover) a Pacific ponderosa pine-Rocky Mountain Douglas-fir stand in early postfire succession; its size (10-15 feet (3-4.6 m)) and relative unpalatability allowed it to compete successfully with other shrubs for light, moisture, and space. Because it is a "poor forage species", researchers predicted it would dominate the burn until crowded out by conifers [203].

Oceanspray is propagated from cuttings or seed [12,113], with cuttings the usual method. A 2004 review found oceanspray seeds were "rare and costly" [196], and as of 2008, there were no published guidelines for growing this species from seed [197]. See these sources: ([74], reviews by [196,197]) for information on propagating oceanspray. Plants are available commercially [74].

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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Vegetative regeneration

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More info for the terms: layering, root crown, top-kill

Oceanspray sprouts from the root crown after top-kill [55,60,61,140,140,150,167,209,228,245]. It may also reproduce by layering ([74], review by [196]).
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Fryer, Janet L. 2010. Holodiscus discolor. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: https://www.fs.fed.us/database/feis/plants/shrub/holdis/all.html

Comprehensive Description

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Sericotheca saxicola (Heller) R,ydberg
Holodiscus saxicola Heller, Muhlenbergia 1 : 41. 1904.
A shrub, about 1 m. high, much branched; bark of the young twigs light-brown, villous; that of the older branches brown or gray, exfoliating; leaf-blades broadly oval, ovate or orbicular, 8-15 mm. long, rounded at the apex, abruptly narrowed into a very short winged petiole, crenate except at the base, bright-green and sparingly pubescent above, grayish-tomentose and slightly villous beneath ; inflorescence 3-10 cm. long, simple or with a few short branches below, villous ; sepals lance-ovate, acute, 1.5 mm. long ; petals almost white, broadly ovate, obtuse, 2 mm. long; stamens about 20, 2 mm. long; pistils 5 ; carpels about 2 mm. long, their beaks 1 mm. long.
Type locality : Among granite rocks at Donner Pass, Nevada County, California. Distribution : Nevada County, Californiii.
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Frederick Vernon Coville, Nathaniel Lord Britton, Henry Allan Gleason, John Kunkel Small, Charles Louis Pollard, Per Axel Rydberg. 1908. GROSSULARIACEAE, PLATANACEAE, CROSSOSOMATACEAE, CONNARACEAE, CALYCANTHACEAE, and ROSACEAE (pars). North American flora. vol 22(3). New York Botanical Garden, New York, NY
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Comprehensive Description

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Sericotheca discolor (Pursh) Rydberg
spiraea discolor Vvlx^^ F1. Am. Sept. 342. 1814.
Spiraea ariaefolia Smith, in Rees, Cycl. 33 : no. 16. 1819.
Schizonoius discolor Raf. New Fl. 3 : 75. 1838.
Spiraea discolor ariaefolia S. "Wats. Bot. Calif. 1 : 170. 1876.
Holodiscus discolor Maxim. Acta Hort. Petrop. d : 254. 1879.
Schizonoius argenteus ariaefolius Kuntze, Rev. Gen. 225. 1891.
Schizonoius argenteus discolor Kuntze, Rev. Gen. 225. 1891.
Schizonoius ariaefolius Greene, Fl. Fran. 58, in part. 1891.
Schizonoius discolor ariaefolius Koehne. Deuts. Dendr. 265. 1893.
Holodiscus ariaefolius Greene, Man. Bay Reg. 113. 1894.
Holodiscus discolor ariaefolius Jepson, Fl. W. Middle Calif. 277, in part. 1901.
Schizonoius discolor Purshianus Rehder, Cycl. Am. Hort. 1627. 1902.
A shrub, 1-4.5 m. high ; bark of the young twigs light-brown, more or less villous and tomentose; that of the older branches darker, chestnut or purplish, exfoliating; petioles 1-2 cm. long, villous ; leaf-blades rounded-ovate or oval, usually double-toothed with broadly ovate, mucronate teeth, acute at the apex, truncate, rounded or cuneate at the base, but slightly if at all decurrent, 4-10 cm». long, thin, green and sparingly pubescent or in age glabrate above, more or less densely villous and tomentose beneath, in the t5rpical form white, but in the more common form {Spiraea ariaefolia^ merely gTa3dsh ; inflorescence conic or ovate, 10-20 cm. long, 5-15 cm. wide, twice or thrice compound ; branches villous, usually divergent; hypanthium small, saucer-shaped; sepals oblong or lance-oblong, obtuse or acutish, 1.25-1.5 mm. long; petals white, elliptic, 1.5 mm, long or more; stamens 15-20, filaments 2-2.5 mm. long; pistils usually 5; carpels semi-ovate, straight on the inner, strongly curved on the outer margin, 1-5 mm. long with a beak of the same length.
Type locality : Banks of the Kooskoosky.
Distribution : Hills and river-banks, from British Columbia to northern California, Idaho, and western Montana.
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Frederick Vernon Coville, Nathaniel Lord Britton, Henry Allan Gleason, John Kunkel Small, Charles Louis Pollard, Per Axel Rydberg. 1908. GROSSULARIACEAE, PLATANACEAE, CROSSOSOMATACEAE, CONNARACEAE, CALYCANTHACEAE, and ROSACEAE (pars). North American flora. vol 22(3). New York Botanical Garden, New York, NY
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Comprehensive Description

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Sericotheca boursieri (Carr.) Rydberg
spiraea Boursieri Carr. Rev. Hort. 1859 : 520. 1859.
A shrub, 1 m. high or less, branched from the base; bark of the young twigs lightbrown, densely villous ; that of the older branches dark-gray or brown or nearly black, exfoliating ; leaves 1-3 cm. long ; blades suborbicular or flabelliform, rounded at the apex, abruptly contracted into the short winged petioles, more or less doubly toothed with ovate, mucronate teeth, densely villous on both sides, green above, grayish beneath ; inflorescence 5-7 cm. long, simple or with a few short branches below ; sepals broadly ovate, acute, fully
2 mm. long ; petals oval, a little longer than the sepals ; stamens 20, 2 mm. long ; pistils 5 ; carpels about 2 mm. long, their beaks 1 mm.
Type locality : California.
Distribution : Mountains of California and adjacent Nevada.
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Frederick Vernon Coville, Nathaniel Lord Britton, Henry Allan Gleason, John Kunkel Small, Charles Louis Pollard, Per Axel Rydberg. 1908. GROSSULARIACEAE, PLATANACEAE, CROSSOSOMATACEAE, CONNARACEAE, CALYCANTHACEAE, and ROSACEAE (pars). North American flora. vol 22(3). New York Botanical Garden, New York, NY
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Sericotheca glabrescens (Greenman) Rydberg
spiraea dumosa Torr. in Stansb. Kxpl. Utah 387. 1852. Not 5. dumosa Nutt. 1847. Spiraea discolor glabrescens Greenman Erythea 7 : 116. 1899. Holodiscus glabrescens Heller, Muhlenbergia 1 : 40. 1904.
A diffuse shrub, 6-12 dm. high ; bark of young twigs light-brown, sparingly hairy or glabrous, but conspicuously glandular-atomiferous, that of the older branches dull-brown or almost black ; leaf-blades cuneate-obovate, 1-1.5 cm. long, obtuse at the apex, decurrent on the short petioles, evenly toothed above the middle, glabrous or hairy on the veins, glandular-atomiferous and green on both sides ; inflorescence more or less compound, 3-6 cm. long; the branches short and more or less spreading; sepals ovate, acute or shortacuminate, 1.5 mm. long; petals white, oval, 2 mm. long; stamens 20, about 2 mm. long; carpels 1.5 mm. long, their beaks 1 mm. long.
Type locality : Stein's Mountain, Oregon.
Distribution : Mountains from Oregon and northern California to Utah.
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Frederick Vernon Coville, Nathaniel Lord Britton, Henry Allan Gleason, John Kunkel Small, Charles Louis Pollard, Per Axel Rydberg. 1908. GROSSULARIACEAE, PLATANACEAE, CROSSOSOMATACEAE, CONNARACEAE, CALYCANTHACEAE, and ROSACEAE (pars). North American flora. vol 22(3). New York Botanical Garden, New York, NY
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Sericotheca microphylla Rydberg
Holodiscus microphyllus Rydb. Bull. Torrey Club 31 : 559. 1904. Holodiscus dumosus C. K. Schneid. Handb. lyaudb. 1 : 497, in part. 1905.
A low diffuse shrub, 3-10 dm. high ; bark of the young twigs light-brown or yellowish, soft-villous, that of the stems dark-brown or gray and exfoliating ; leaf-blades spatulatecuneate, 1-1.5 cm., rarely 2 cm. long, evenly serrate above the middle, obtuse at the apex, cuneate at the base and decurrent on the short petioles, finely pubescent and green above, white silky-villous and tomentose beneath ; inflorescence small, 3-5 cpi. long, its branches few, short and few-flowered, spreading; sepals about 1 mm. long, ovate, villous; petals broadly obovate or oval, a little exceeding the sepals, stamens 20, about 1.5 mm. long.
Type locality : Alta, Wahsatch Mountains, Utah.
Distribution : Mountains of Colorado, Wyoming, and Utah ; apparently also in California.
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Frederick Vernon Coville, Nathaniel Lord Britton, Henry Allan Gleason, John Kunkel Small, Charles Louis Pollard, Per Axel Rydberg. 1908. GROSSULARIACEAE, PLATANACEAE, CROSSOSOMATACEAE, CONNARACEAE, CALYCANTHACEAE, and ROSACEAE (pars). North American flora. vol 22(3). New York Botanical Garden, New York, NY
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Sericotheca franciscana Rydberg, sp. nov
spiraea discolor Brew. & Wats. Bot. Calif. 1 : 170, in part. 1876. Not Spiraea discolor Pursh.
Schizonoius ariaefolius Greene, Fl. Fran. 58 ; in part. 1891.
Holodiscus ariaefolius Greene, Man. Bay Reg. 113 ; in part. 1894.
Holodiscus discolor ariaefolius Jepson, Fl. W. Middle Calif. 277, in part. 1901.
A tall shrub, 2-7 m. high; bark of the young twigs rather dark-brown, villous and tomentose, that of the older branches more or less exfoliating ; petioles 5-10 mm. long, villous ; leaf-blades thick, 3-6 cm. long, rounded-ovate, acute at the apex, rounded or truncate at the base, rarely somewhat cuneate, not decurrent, dark-green and densely pubescent (when young almost velvety) above, white villous and tomentose beneath, usually double-toothed with ovate, mucronate teeth ; inflorescence conic or ovate, 5-15 cm. long, 5-10 cm. wide, twice or thrice compound, with divergent villous branches ; bracts linear ; hypanthium small, saucer-shaped; sepals ovate, acute, nearly 1.5 mm. long, thick; petals oval, white. over 1,5 mm. long ; stamens about 20 ; filaments about 2 mm. long; pistils and fruit as in the preceding.
Type collected at San Iveandro, California, in 1888, L. M. Underwood (herb. N. Y. Bot. Gard.). DiSTtiiBUTiON : Hills and mountains of Oregon and California, near the coast, from Columbia River to San Luis Obispo.
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Frederick Vernon Coville, Nathaniel Lord Britton, Henry Allan Gleason, John Kunkel Small, Charles Louis Pollard, Per Axel Rydberg. 1908. GROSSULARIACEAE, PLATANACEAE, CROSSOSOMATACEAE, CONNARACEAE, CALYCANTHACEAE, and ROSACEAE (pars). North American flora. vol 22(3). New York Botanical Garden, New York, NY
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Holodiscus discolor

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Holodiscus discolor, commonly known as ocean spray or oceanspray, creambush, or ironwood, is a shrub of western North America.[3][4][5]

Description

Holodiscus discolor is a fast-growing deciduous shrub usually from to 1.2–1.5 metres (4–5 feet) in width, and up to 2.1 m (7 ft) tall. Its alternate leaves are small, 5–9 centimetres (2–3+12 inches) long and 4–7 cm (1+12–3 in) broad, lobed, juicy green when new.[6] The young branches have longitudinal ridges.

Cascading clusters of white flowers drooping from the branches give the plant its two common names. The flowers have a faint sweet, sugary scent. The bloom period is May to July.

It bears a small, hairy fruit containing one seed which is light enough to be dispersed by wind.

Distribution and habitat

The plant is common in the Pacific Northwest, and throughout California in diverse habitats including California mixed evergreen forest, California oak woodlands, chaparral, Coast redwood forest, Douglas-fir forest, Yellow pine forest, Red fir forest, and Lodgepole pine forest. It is native to regions of California including the High Sierra Nevada, Northern and Southern California Coast Ranges, Klamath Mountains, Santa Cruz Mountains, Western Transverse Ranges, and the San Gabriel Mountains.

It is found in both openings and the common understory shrub in a variety of forest overstories from 300–1,300 m (980–4,270 ft) in elevation. In open mountain habitat in the Sierra Nevadas it can be found as high as 3,500 m (11,500 ft). It is found in a variety of habitats, from moist coastal forests to drier, cooler mountains of inland California. The plant is found in areas prone to wildfire, and it is often the first green shoot to spring up in an area recovering from a burn. It is commonly found in chaparral communities, a fire ecology ecosystem which evolved with burning periodically. It also may grow in areas cleared by logging.

In the California black oak woodland plant community, common understory associate species include Toxicodendron diversilobum (Western poison-oak), Heteromeles arbutifolia (toyon), and Dryopteris arguta (coastal wood fern).[7]

Ecology

It is of special value as a pollinator plant for native bees and butterflies.[8] It is also a larval host to Lorquin's admiral, pale tiger swallowtail, and spring azure caterpillars.[9]

Uses

Historically, the plant has been used by Indigenous peoples for many purposes.[10] Raw and cooked seeds were eaten,[11] and leaves were mixed with those of other plants and boiled with small game animals.[12] Many tribes used the wood and bark for making tools and furniture. Noted for the strength of its wood, it was often used for making digging sticks, spears, arrows, bows, harpoons and nails. The wood, like with many other plants, was often hardened with fire and was then polished using horsetail.[13]

Comox natives use oceanspray when flowering as an indicator of the best time to dig for butter clams.[14]

Medicinal

The Lummi used the flowers as an antidiarrheal and the leaves as a poultice. Several Native American tribes, such as the Stl'atl'imx, would steep the berries in boiling water to use as a treatment for diarrhea, smallpox, chickenpox and as a blood tonic.[5]

References

  1. ^ "Holdiscus discolor". NatureServe Explorer. NatureServe. Retrieved 2021-05-08.
  2. ^ "The Plant List: A Working List of All Plant Species".
  3. ^ "Holodiscus discolor (Pursh) Maxim". Plants Profile. USDA. 2008.
  4. ^ BSBI List 2007 (xls). Botanical Society of Britain and Ireland. Archived from the original (xls) on 2015-06-26. Retrieved 2014-10-17.
  5. ^ a b Pojar, Jim; Andy MacKinnon (1994). Plants of the Pacific Northwest. Lone Pine Publishing. p. 71. ISBN 1-55105-042-0.
  6. ^ Jepson Manual, 1993
  7. ^ C. Michael Hogan (2008) Globaltwitcher.com: California Black Oak Quercus kelloggii Archived 2012-02-18 at the Wayback Machine, ed. Nicklas Stromberg.
  8. ^ Lady Bird Johnson Wildflower Center−NPIN: Holodiscus discolor (Ocean spray)
  9. ^ The Xerces Society (2016), Gardening for Butterflies: How You Can Attract and Protect Beautiful, Beneficial Insects, Timber Press.
  10. ^ University of Michigan at Dearborn: Ethnobotany of Holodiscus discolor
  11. ^ Patterson, Patricia A. (1985). Field Guide to the Forest Plants of Northern Idaho (PDF). United States Department of Agriculture Forest Service. p. 46.
  12. ^ Reiner, Ralph E. (1969). Introducing the Flowering Beauty of Glacier National Park and the Majestic High Rockies. Glacier Park, Inc. p. 12.
  13. ^ Pojar; J, MacKinnon, A.; Alaback, P., et al. 1956/1994. Plants of the Pacific Northwest Coast: Washington, Oregon, British Columbia & Alaska, ISBN 978-1-55105-530-5
  14. ^ "The effects of climate change on wild plant life cycles" Archived 2017-01-17 at the Wayback Machine; Susan Mazer, PhD, Liz Matthews, PhD, National Park Service.

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Holodiscus discolor: Brief Summary

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Holodiscus discolor, commonly known as ocean spray or oceanspray, creambush, or ironwood, is a shrub of western North America.

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