Nurse plants

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This is a paloverde tree acting as a nurse plant to a saguaro in the Sonoran Desert not far from the Superstition mountains. Nurse plant.jpg
This is a paloverde tree acting as a nurse plant to a saguaro in the Sonoran Desert not far from the Superstition mountains.

Nurse plants are plants that serve the ecological role of helping seedlings establish themselves and protecting young plants from harsh conditions. This effect is particularly well studied among plant communities in xeric environments.

Contents

Effects

Overstory trees and shrubs have a facilitative effect on the establishment of understory plants. This effect is also seen in some interactions between herbaceous plant species. [1] Nurse plants are important in xeric environments because they provide shaded microhabitats for the survival of several other plant species, buffering temperature extremes and reducing moisture loss. For example, in the Sonoran Desert, nurse plants canopies provide reduced summer daytime temperatures, soil surface temperatures, and direct sunlight, higher soil fertility, protection from the wind and browsing animals, reduced evapotranspiration rates in the nursed species, elevated nighttime temperatures, and post-fire resprouting in some species... [2] [3] This means that nurse plants provide a positive interaction between themselves and the organisms they protect, and are often crucial in maintaining biodiversity in water-scarce environments. [4] [5]

It has been suggested that the assistance provided by nurse plants can enhance the performance of stress intolerant species on green roofs. [6] There is also evidence suggesting that phenotypic traits affect how protégé plants that grow on large green roofs react to nurse plants. [7]

Nurse plants also aid with recovery after herbivore grazing, because they provide higher levels of resources to the plant. [8] The effect of nurse plants on any particular species is dependent upon species richness and the dispersal strategy of the organism. [8] Nurse plants can help with seedling recruitment and protect plants from granivory. [9] [10] A saguaro's root system is restricted to 15 cm of soil surface and the Palo Verde's ( Cercidium microphyllum ) roots go deeper under the surface. Studies suggest that a saguaro's network of roots intercept moisture before it can reach a Palo Verde's roots.[ citation needed ]

When analyzing the contributions of Nurse trees, the prevention of herbivory is reduced in arid environments because the herbivores are at a much lower density, so the contribution of herbivore defense is excluded from arid environments. [11]

Nurse plants also have better soil under their canopies than what is out in the open. "Soil properties under nurse plants were always better than outside them, which are in concordance with the generalized existence of fertility islands in high mountains" [12]

Palo Verde (Cercidium spp.), mesquite (Prosopis spp.), and ironwood ( Olneya tesota ) trees all provide positive interactions among other plants species like facilitating seedling survival and germination. [13] The richness and abundance of many plant species is greater under the canopies of these trees than in surrounding areas [13]

The density of plant species that depend on nurse plants depends on the number of nurse plants in a community. For example, the density of the senita cactus ( Pachycereus schottii ) was higher when there was a higher density of nurse plants. [9] But the study by Holland et al., [9] found that "there was not a significant main factor effect of nurse plants on the germination and seedling recruitment of senita cacti." The positive effects of nurse plants with this plant species depended on rainfall [9]

Examples

Olneya tesota

Study of ironwood trees (O. tesota) has shown that a nurse plant's importance is not only as a temperature buffer, but also as a water buffer. In terms of water stress, there was a difference in the facilitative effects between mesic and xeric sites. In xeric sites, the richness and abundance of perennial plants was higher, whereas, ephemerals saw no difference. In mesic sites, the abundance of perennial and ephemeral plants was no different, but the ephemeral richness was lower.[ citation needed ]

The size of the canopies of ironwood trees was no different between xeric and mesic sites. But the canopy size did affect perennial plants more than ephemeral plants. With the perennial plants, there was a positive effect. The richness, abundance, and size of the plants was greater under the canopies. With ephemeral plants the richness was unaffected, and the abundance increased in xeric sites. [13]

Ironwood tree canopies have provided facilitative effects on plant species richness and abundance in xeric sites in the Sonoran Desert. [13] Two factors, water stress and benefactor size, had effects on facilitation and are factors to consider when looking at the richness, abundance, and size of the plants under nurse plant canopies in xeric and mesic habitats.[ citation needed ]

The ironwood was often the only tree growing in xeric areas and their canopies had the largest effect on plant community structure and richness even when water stress was high. [13] Thus, ironwood trees creative diversity that is absent in other desert microhabitats.[ citation needed ]

Palo verde (Cercidium microphyllum) and saguaro (Carnegiea gigantea)

An example of a nurse plant would be the Palo Verde tree (C. microphyllum), found in the Sonoran Desert, that may have saguaro cacti underneath its canopy. Other examples of nurses are grasses and cacti. [2] Trees and shrubs are the more common nurse plants.[ citation needed ]

Nurse plants provide the ideal microclimatic environment for species like the saguaros. They allow them to extend their ranges "in otherwise inhospitably cold areas". [2] Some of the benefits described above can limit saguaros during establishment, but subfreezing temperatures is one variable the cactus is susceptible to. [2] These temperatures in the northern part of Arizona are why saguaros haven't established there. Nurse plants also have better soil under their canopies than what is out in the open. "Soil properties under nurse plants were always better than outside them, which are in concordance with the generalized existence of fertility islands in high mountains" [12]

Saguaros are established on the south side of a nurse plant's canopy more than the north side. According to Drezner and Garrity, [14] the south side of canopies have higher minimum temperatures and the north sides have colder temperatures. Saguaros establish under denser canopies than plants with a more open canopy because of better microclimatic conditions. [14] It might have been unexpected that the saguaro established on the south side because of higher minimal temperature. Saguaros can handle higher temperatures but are susceptible to subfreezing temperatures. With the temperatures on the south side of the nurse, the risk of experiencing subfreezing temperatures is reduced in the winter.[ citation needed ]

Ambrosia deltoidea and Cercidium microphyllum were the two main nurse plants observed. The study found that maximum temperatures under C.microphyllum were lower and the minimum temperatures were higher, showing that nurse plants provide a microclimate under their canopy and protects the saguaros from extreme cold or hot temperatures.[ citation needed ]

The death of a nurse plant generally precedes the plant species it protects. [15] There is evidence of competitive interactions between saguaro cacti and paloverde trees. The saguaros under a paloverde's canopy negatively impacted the vigor of the tree. [15] Trees in the absence of saguaros ( Carnegiea gigantea ) did not die as quickly. One factor of this competitive interaction is root competition. [15] The saguaro's roots exist in shallow soil, whereas, a paloverde's roots go deeper. The saguaro's roots are like an umbrella and capture most of the moisture before it can reach the paloverde's roots.[ citation needed ]

Creosote bush (Larrea tridentata)

Larrea tridentata , commonly known as creosotebush, exhibits characteristics of a nurse plant by facilitating the establishment and growth of other species in harsh desert environments. Its dense canopy provides shade and shelter, creating a microclimate that reduces temperature extremes and moisture loss, thus promoting the survival of seedlings and young plants. Creosotebushes also trap seeds beneath their canopies, increasing seedling recruitment and contributing to vegetation recovery. Studies have shown that many plant species in desert ecosystems are positively associated with Larrea tridentata, indicating its role in providing a hospitable environment for diverse plant communities. [16] Overall, the presence of creosotebushes enhances biodiversity and ecosystem resilience in arid regions, underscoring their significance as nurse plants.[ citation needed ]

Spanish sage (Salvia officinalis subsp. lavandulifolia)

Salvia officinalis subsp. lavandulifolia (syn. S. lavandulifolia) serves as a crucial nurse plant in the challenging terrain of Mediterranean mountains, facilitating the growth and survival of newly planted pine seedlings. As a member of the Lamiaceae family, this shrubby species, typically ranging from 20 to 35 cm in height, creates an optimal microenvironment for young pines to thrive. Its shallow root system minimizes competition with developing seedlings, ensuring their access to vital nutrients and water. Additionally, its modest stature enables the pine trees to outgrow it over time, making it an advantageous companion during the initial stages of reforestation efforts. [17]

Mesquite (Prosopis spp.)

Prosopis species, particularly Prosopis flexuosa , demonstrate a notable capacity to function as nurse plants in arid and semiarid ecosystems. Some research underscores Prosopis' role in improving challenging environmental conditions, particularly in areas characterized by low forage quality and water scarcity. A study demonstrated that Opuntia ellisiana, when planted beneath the canopy of Prosopis flexuosa, exhibited enhanced productivity and nutrient content compared to those outside the canopy. [18] Noteworthy increases in cladode production and higher levels of key nutrients, such as moisture, organic matter, and potassium, underscore the facilitative effects of Prosopis on the growth and nutritional quality of associated plant species. Furthermore, the observed mitigation of frost damage beneath the Prosopis canopy highlights its additional protective function, further solidifying its status as a beneficial nurse plant in arid landscapes.[ citation needed ]

Invasibility and nurse plants

Badano et al. used two hypotheses to look at the invasibility by alien species with nurse plants in the area. They used the biotic resistance hypothesis where a new species that arrives is more likely to find strong competitors that impede their success as the number of native species increases and local diversity acts as a barrier for biological invasions, and the biotic acceptance hypothesis, which is described as the main force that regulates native and alien species' performance and diversity and increased availability of resources and habitat heterogeneity associated with increased surface area. [19]

Neither of these hypotheses considered the variations of harsh environments. [19] This harshness could reduce competition in plant communities and the overall performance of plants.[ citation needed ]

The nurse plant in this study was the field chickweed, Cerastium arvense L. For natural assemblages, there was a positive relationship between C. arvense and the abundance and diversity of plant assemblages growing within cushion plants, or cushions. [19] Cushion plants are plants that grow a few inches in height, three meters in diameter, and form a compact mat of closely spaced stems. It was found from this study that invasive species grew under nurse plant canopies and that they were providing protection for those species.[ citation needed ]

According to Badano et al., "This study indicated that the performance of the invasive plant C. arvense was positively affected by increasing diversity of native species within the habitat patches created by the cushion plant A. madreporica, while these relationships were negative or absent in the surrounding open areas."[ citation needed ]

Nurse plants and ants

These nurse plants also help the composition of ant communities. They provide protection and food to the different ant communities in the Sonoran Desert. Four ant species ( Camponotus atriceps , Pheidole sciophila, and Pheidole titanis) "were associated with tree habitats, whereas Pheidole sp. A was associated with open areas". [20]

In the Sonoran Desert, ant species are greater than in the Mojave Desert, Chihuahuan Desert, or Chihuahuan desert grassland, and that is due to greater precipitation. [20] When rainfall increases, so does the ant diversity. [20]

See also

Related Research Articles

<span class="mw-page-title-main">Deserts and xeric shrublands</span> Habitat type defined by the World Wide Fund for Nature

Deserts and xeric shrublands are a biome defined by the World Wide Fund for Nature. Deserts and xeric shrublands form the largest terrestrial biome, covering 19% of Earth's land surface area. Ecoregions in this habitat type vary greatly in the amount of annual rainfall they receive, usually less than 250 millimetres (10 in) annually except in the margins. Generally evaporation exceeds rainfall in these ecoregions. Temperature variability is also diverse in these lands. Many deserts, such as the Sahara, are hot year-round, but others, such as East Asia's Gobi, become quite cold during the winter.

<span class="mw-page-title-main">Sonoran Desert</span> Desert in Mexico and the United States

The Sonoran Desert is a hot desert in North America and ecoregion that covers the northwestern Mexican states of Sonora, Baja California, and Baja California Sur, as well as part of the southwestern United States. It is the hottest desert in both Mexico and the United States. It has an area of 260,000 square kilometers (100,000 sq mi).

<span class="mw-page-title-main">Yuma Desert</span> Part of the Sonoran Desert

The Yuma Desert is a lower-elevation section of the Sonoran Desert in the southwestern United States and the northwest of Mexico. It lies in the Salton basin. The desert contains areas of sparse vegetation and has notable areas of sand dunes. With an average rainfall less than 8 inches (200 mm) each year, it is among the harshest deserts in North America. Human presence is sparse throughout, the largest city being Yuma, Arizona, on the Colorado River and the border of California.

<i>Pachycereus pringlei</i> Species of cactus

Pachycereus pringlei is a species of large cactus native to northwestern Mexico, in the states of Baja California, Baja California Sur, and Sonora. It is commonly known as cardón, a name derived from the Spanish word cardo, meaning "thistle"; additionally, it is often referred to as sabueso, which is possibly an early Spanish interpretation of the native Seri term for the plant, xaasj.

<span class="mw-page-title-main">Forest ecology</span> Study of interactions between the biota and environment in forests.

Forest ecology is the scientific study of the interrelated patterns, processes, flora, fauna, funga, and ecosystems in forests. The management of forests is known as forestry, silviculture, and forest management. A forest ecosystem is a natural woodland unit consisting of all plants, animals, and micro-organisms in that area functioning together with all of the non-living physical (abiotic) factors of the environment.

Ecological facilitation or probiosis describes species interactions that benefit at least one of the participants and cause harm to neither. Facilitations can be categorized as mutualisms, in which both species benefit, or commensalisms, in which one species benefits and the other is unaffected. This article addresses both the mechanisms of facilitation and the increasing information available concerning the impacts of facilitation on community ecology.

<span class="mw-page-title-main">Ironwood Forest National Monument</span> Protected area in the Sonoran Desert of Arizona

Ironwood Forest National Monument is located in the Sonoran Desert of Arizona. Created by Bill Clinton by Presidential Proclamation 7320 on June 9, 2000, the monument is managed by the Bureau of Land Management, an agency within the United States Department of the Interior. The monument covers 129,055 acres (52,227 ha), of which 59,573 acres (24,108 ha) are non-federal and include private land holdings and Arizona State School Trust lands.

<i>Parkinsonia microphylla</i> Species of tree

Parkinsonia microphylla, the yellow paloverde, foothill paloverde or little-leaved palo verde; syn. Cercidium microphyllum), is a species of palo verde.

<i>Prosopis velutina</i> Species of tree

Prosopis velutina, commonly known as velvet mesquite, is a small to medium-sized tree. It is a legume adapted to a dry, desert climate. Though considered to be a noxious weed in states outside its natural range, it plays a vital role in the ecology of the Sonoran Desert.

<span class="mw-page-title-main">Nurse tree</span>

A nurse tree is a larger, faster-growing tree that shelters a smaller, slower-growing tree or plant. The nurse tree can provide shade, shelter from wind, and protection from animals that would feed on the smaller plant and significant changes in temperature. Fallen leaves from the nurse tree fertilize the ground underneath creating nutrient-rich soil for the saplings and vegetation beneath. Some nurse trees act as Nitrogen-fixing agents in the soil. The nurse tree relationship occurs both naturally and via human intervention.

<span class="mw-page-title-main">White-throated woodrat</span> Species of rodent

The white-throated woodrat is a species of rodent in the family Cricetidae. It is found from central Mexico north to Utah and Colorado in the United States. It is primarily a western species in the United States, extending from central Texas west to southeastern California. Populations east of the Rio Grande in New Mexico and Trans-Pecos Texas, previously considered to be variants of the white-throated woodrat, have since 1988 been assigned to the white-toothed woodrat.

<i>Prosopis tamarugo</i> Species of plant

Prosopis tamarugo, commonly known as the tamarugo, is a species of flowering tree in the pea family, Fabaceae, subfamilia Mimosoideae. It is only found in northern Chile, particularly in the Pampa del Tamarugal, some 70 km (43 mi) east of the city of Iquique. This bushy tree apparently grows without the benefit of rainfall, and it is thought to obtain some water from dew. Studies indicate it is a Phreatophyte; having deep roots that tap into ground water supplies. It also participates in hydraulic redistribution moving water from deeper levels to the upper and also reversing the process in times of severe drought.

<span class="mw-page-title-main">Lower Colorado River Valley</span> Landform in Arizona and California

The Lower Colorado River Valley (LCRV) is the river region of the lower Colorado River of the southwestern United States in North America that rises in the Rocky Mountains and has its outlet at the Colorado River Delta in the northern Gulf of California in northwestern Mexico, between the states of Baja California and Sonora. This north–south stretch of the Colorado River forms the border between the U.S. states of California/Arizona and Nevada/Arizona, and between the Mexican states of Baja California/Sonora.

<span class="mw-page-title-main">Saguaro</span> Species of cactus in the Sonoran Desert

The saguaro is a tree-like cactus species in the monotypic genus Carnegiea that can grow to be over 12 meters tall. It is native to the Sonoran Desert in Arizona, the Mexican state of Sonora, and the Whipple Mountains and Imperial County areas of California. The saguaro blossom is the state wildflower of Arizona. Its scientific name is given in honor of Andrew Carnegie. In 1933, Saguaro National Park, near Tucson, Arizona, was designated to help protect this species and its habitat.

<i>Ambrosia deltoidea</i> Species of flowering plant

Ambrosia deltoidea is a North American species of flowering plant in the family Asteraceae known by the common names triangle bur ragweed, triangle bursage, and triangleleaf bursage.

The Goldfield Mountains of Arizona are located adjacent to the Superstition Mountains, between Usery Pass and Canyon Lake (Arizona). In 1893, the southern part of the Goldfield Mountains was a large mining district.

Flora of the Sonoran Desert includes six subdivisions based on vegetation types. Two are north of the boundary between the United States and Mexico, and four are south of the boundary. The flora of the Colorado Desert are influenced by the environment of the very dry and hot lower areas of the Colorado River valley, which may be barren, treeless, and generally have no large cacti. Flora of the Arizona Upland are comparatively lush, with trees and large columnar cacti that can withstand winter frosts. Those subdivisions of the Sonoran Desert which lie south of the international border are characterized by plants that cannot withstand frost.

Flora of the Arizona Upland includes higher elevation Sonora Desert plants that require more moisture and cooler climates than those of the adjacent Sonoran Desert areas in the Colorado Desert of the lower Colorado River valley area, and which can withstand frost, unlike plants of the Sonoran Desert south of the border between the United States and Mexico.

Drosophila nigrospiracula is a fly species indigenous to the Sonoran Desert, spanning Arizona, Baja California, and part of Sonora, Mexico. D. nigrospiracula share the Sonoran Desert with three other species of Drosophila: D. pachea, D. mettleri, and D. mojavensis. This fly breeds on the decomposing tissues of two species of cacti that are also endemic to the region: cardón (Pachycereus pringlei) and saguaro (Carnegiea gigantea).

Drosophila metlerri, commonly known as the Sonoran Desert fly, is a fly in the genus Drosophila. The species is found in North America and is most concentrated along the southern coast of California and in Mexico. D. mettleri are dependent on plant hosts, namely, the saguaro and cardon cacti. Thus, they are most prevalent in arid, desert conditions. It is able to detoxify chemicals found in the rotting liquid of cacti hosts, which allows it to use otherwise lethal soil as a nesting site.

References

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