Improving Ecological Restoration to Curb Biotic Invasion—A Practical Guide

Abstract Common practices for invasive species control and management include physical, chemical, and biological approaches. The first two approaches have clear limitations and may lead to unintended (negative) consequences, unless carefully planned and implemented. For example, physical removal rarely completely eradicates the targeted invasive species and can cause disturbances that facilitate new invasions by nonnative species from nearby habitats. Chemical treatments can harm native, and especially rare, species through unanticipated side effects. Biological methods may be classified as biocontrol and the ecological approach. Similar to physical and chemical methods, biocontrol also has limitations and sometimes leads to unintended consequences. Therefore, a relatively safer and more practical choice may be the ecological approach, which has two major components: (1) restoration of native species and (2) biomass manipulation of the restored community, such as selective grazing or prescribed burning (to achieve and maintain viable population sizes). Restoration requires well-planned and implemented planting designs that consider alpha-, beta-, and gamma-diversity and the abundance of native and invasive component species at local, landscape, and regional levels. Given the extensive destruction or degradation of natural habitats around the world, restoration could be most effective for enhancing ecosystem resilience and resistance to biotic invasions. At the same time, ecosystems in human-dominated landscapes, especially those newly restored, require close monitoring and careful intervention (e.g., through biomass manipulation), especially when successional trajectories are not moving as intended. Biomass management frequently uses prescribed burning, grazing, harvesting, and thinning to maintain overall ecosystem health and sustainability. Thus, the resulting optimal, balanced, and relatively stable ecological conditions could more effectively limit the spread and establishment of invasive species. Here we review the literature (especially within the last decade) on ecological approaches that involve biodiversity, biomass, and productivity, three key community/ecosystem variables that reciprocally influence one another. We focus on the common and most feasible ecological practices that can aid in resisting new invasions and/or suppressing the dominance of existing invasive species. We contend that, because of the strong influences from neighboring areas (i.e., as exotic species pools), local restoration and management efforts in the future need to consider the regional context and projected climate changes.


Introduction
Several decades ago, restoration merely meant returning vegetation to a predisturbance condition, a characteristic state existing before its degradation or destruction. Guidance for such undertakings was often drawn from "reference conditions" on existing sites or those that were hypothesized to have existed in the past. In more recent decades, restoration usually has been employed to achieve multiple objectives. First, restoration is a way to combat species invasion, especially under the stresses of climate change and the expanding influence of human activities (Esler et al. 2010;Gaertner et al. 2012;Hobbs and Richardson 2011;Kerns and Guo 2012). Second, restoration has been increasingly used to provide much-needed ecosystem services such as sequestering carbon (Carter 2013) and providing wood, biofuels, and other products, partly because the sites needing restoration are often close to human populations and thus undergo greater ongoing disturbances and degradation (Hill 2007;Lugo 2004;Roe 2010). Therefore, today's restoration efforts face much greater challenges than ever before, and the cost for restoration is drastically increasing through time. For these reasons, the importance of incorporating long-term and regional goals in design cannot be overstated (Guo and Norman 2013).
Invasive species, foreign or domestic, threaten native species diversity and ecosystem health and sustainability and cause ecological and economic losses and/or crises in many habitats around the world (Young et al. 2017). In that many habitats have been invaded and suffer from varied degrees of invasion (DI), removal of invasive species is needed before any attempt at restoration. Although there are many approaches to control and manage invasive species, no method has gained broad acceptance as the most effective one (Figure 1). With natural areas and habitats being destroyed and degraded at an accelerating pace because of human population growth and associated activities, restoration offers an important opportunity for preventing invasion and managing invasive species. However, a key requirement of such an approach is that projects be carefully planned, designed, and implemented. This approach requires careful consideration of species selection, abundance, and planting order. Increasing evidence also indicates that local restoration needs to be informed by landscape or regional contexts (Bell et al. 2008) and possible temporal trends in climate conditions (Joyce et al. 2013;McCollum et al. 2017). Additionally, the success of restoration has been constrained by the lack of careful consideration of invasive species and poor design at the beginning of the project. New issues also emerge when considerable ecological, social, and conservation conflicts over invasive species management gradually become evident (Dickie et al. 2014;Estévez et al. 2015).
Despite the apparent technological challenges, many studies have been conducted in recent years to address invasive species control in the context of ecological restoration. Biodiversity experiments have also offered new insights into restoration for maintaining ecosystem function and concurrently controlling species invasion. Increasing numbers of successful restoration and invasive species control efforts have been performed through integrated pest management (Kogan 1998), and many new studies are being conducted to address related emerging issues (SER 2016). Particularly, new experiments using various biomass treatments have substantially added to our understanding of restoration success. For example, a recent study demonstrated how seed limitation and intact plant ground cover can limit the abundance and performance of naturalized species in Pacific Northwest steppe and low-elevation forests (Connolly et al. 2017).
During the past decade, great progress has been made, with newly discovered knowledge and useful technical information becoming available at increased rates. As a result, a comprehensive review of this complex subject is needed to elucidate the most recent progress in both scientific research and field application. An important lesson from past experience is that successful restoration needs careful and integrated management as a necessary follow-up. To address this urgent need, we review and synthesize the new developments in both basic and applied ecology (especially within the last decade) to fill the critical information gap in the application of new scientific findings. Our goal is to provide a useful update of the most recent research, progress, and directions to both ecologists and land managers. The specific objectives of this review are to (1) provide information that will improve the effectiveness of controlling invasive species in invaded ecosystems and (2) aid practitioners in preventing or resisting future invasions when implementing restoration and management programs.

Key Issues
A new United Nations report, estimated that 15 billion trees and 24 billion metric tons of fertile soil are lost each year, resulting in a dramatic loss of natural resources during the past 30 yr. This estimate does not include natural habitats (lands) lost to development (e.g., new cities, roads). Because of this drastic loss of native species, many restoration efforts have either been planned or are currently ongoing around the world to create more desirable habitats, mostly with productivity (rate of biomass accumulation) of native species as a main focus (Grime 1998). In that most invasive species prefer a disturbed environment and the most intensive invasions occur following disturbances, a major goal of restoration is to enhance resistance to biotic invasions through niche occupation. Restoration presents practitioners with a more critical set of choices than land management in general, and a well thought out and carefully designed restoration plan will serve as a solid start toward long-term resilience of the restored land. Such new designs need to fully appreciate the progress made, knowledge accumulated, and lessons learned from past restoration. We list in Box 1 common key issues in restoration efforts further discussed in the following sections.

Lessons from Biodiversity Experiments
Experimental restoration research falls into two categories: the first includes many biodiversity experiments conducted to examine the productivity of planted native species at varied diversity levels (Isbell et al. 2015). Such experiments usually start with seeding different numbers of native species on bare or treated soils without preexisting vegetation. The second category includes the relatively much fewer invasion resistance experiments that have been performed to examine the role of existing native species in preventing and/or reducing species invasions through niche occupation (Fargione and Tilman 2005;Kennedy et al. 2002;Knops et al. 1999;Tilman 1997).
In such experiments, new species are planted into preexisting vegetation with different numbers of species to examine how newly seeded species (as invaders) may establish and grow.
Indeed, most small-scale experiments, especially those in grasslands (Isbell et al. 2015;Petersen et al. 2012;Zuo et al. 2012), have shown the ecological benefits of high-diversity planting, which include higher productivity and greater resistance to biotic invasions (Lyons and Schwartz 2001). Priority effects (i.e., a species having a larger impact on ecosystem development or succession because of earlier arrival) also have been demonstrated (e.g., Weidlich et al. 2017) and suggest that planting order is important, but the practical implications of priority effects for restoration design have been little explored. Future restoration research should focus on these important issues in planning and implementation efforts (Temperton et al. 2004).
In practice, the area to be restored is expected to be much larger than an experimental site, thus the question is whether sufficient seeds (measured in both density and total weight) for each species to be planted can be obtained, especially when some species have very low germination rates. In some cases, the seeds/seedlings of native species could be quite expensive, because of the difficulties in collecting them. Yet most previous and ongoing biodiversity experiments may not have considered such economic realities, and the results from small plots may therefore not scale up to operational levels on larger sites. Small-scale experiments are useful for finding the optimal planting density (and species combination or species mix) for both the total amount of seeds/seedlings and density of each component species. However, practitioners must plan for financial costs, as well as a host of additional factors such as elevation, soil fertility, geomorphology, regional context, connectivity, and habitat heterogeneity of the areas to be restored (Doll et al. 2009;Webster et al. 2010).

Site Selection, Assessment, and Preparation
Because restorations are often expensive and time-consuming, managers and practitioners should start with the most easily and effectively repaired lands, because the available resources will then be able to foster recovery across the largest area in need. More highly degraded and/or invaded sites (e.g., where the proportion of nonnative plants is greater than that of native species in terms of richness and/or biomass) can then be serially addressed through a process of site prioritization (Riitters et al. 2018;Wickham et al. 2017).
Previously, there were two common practices in restoration, sowing seeds or planting seedlings either (1) on barren lands (e.g., newly created lands after volcano eruption, landslides, abandoned mining or agricultural sites), often at smaller scales; or (2) into existing vegetation that may have been invaded or disturbed, such as grasslands in the Great Plains in the United States (Guo et al. 2006) or forests in China . The latter may be conducted at larger scales (e.g., sowing seeds via airplane). More recently, restoration that includes integrated pest management and invasive species removal through disturbance, such as herbicide and/or fire followed by seeding or plug planting, has become more widespread (Kogan 1998).
Sites on barren land need different site preparation approaches than those with existing vegetation. On barren lands, irrigation (if feasible) and nutrient supplementation, such as planting "fertilizer species" (e.g., many legumes, including naturalized nonnative species if not invasive) can be very helpful. Such rehabilitating treatments can improve soil fertility and moisture, and the planted species can serve as nurse plants, offering shade needed by certain native species (Figure 2). Soil tillage may also be useful, but may be impractical when the target area is very large (i.e., where aerial seeding is planned). When prairies are reconstructed on former agricultural lands, practitioners often find it useful to grow Roundup Ready® corn (Zea mays L.) and soybean [Glycine max (L.) Merr.] rotations for a few years to reduce weed pressure when the prairie is planted (Heap 2014). In any of these cases, the underlying soils and prevailing climate should be taken into account during site preparation; trying to force arid, low-fertility lands to produce verdant vegetation will likely be costly and ultimately fail.
For sites with existing vegetation, the following procedure can be used as a reference before restoration begins: (1) conduct a comprehensive site assessment, including an inventory both aboveground (existing vegetation) and belowground (seedbanks) for native and exotic species (Chiquoine and Abella 2018;Thilmony and Lym 2017;Wang et al. 2009Wang et al. , 2015, with both domestic and foreign exotic and invasive species identified in local and

Box 1. Pressing and Challenging Issues in Restoration
• Resistance to invasion, from high diversity/evenness native planting and tolerance to high exotic richness but not dominance, should be factored into restoration and management plans (Wilsey and Potvin 2000). • Use functional diversity (evolutionary or phylogenetic), rather than simple overall species richness (the number of species), when designing planting mixes. • Beta-diversity (species turnover over space) has received little attention in large-scale restoration planning. Considering scale-dependency (scaling) and macroecosystem approaches may be an effective way forward for future restoration ). • For invasive species with long-term persistent seedbanks, a major task in restoration is to avoid secondary invasions (Chiquoine and Abella 2018;Pearson et al. 2016). • In highly degraded or totally destroyed habitats, carefully selected exotic species could be used for early restoration or recovery (Guo and Norman 2013;Ren et al. 2014). Such species are often regarded as pioneer species and/or nitrogen fixers, which could facilitate native species colonization as nurse plants during the initial recovery Lugo 2004;Lugo and Erickson 2017;Ren et al. 2008Ren et al. , 2009 (Fig. 2). • Lessons from grassland experiments around the world (e.g., restoration on the Great Plains of the United States) and experimental forests, including plantations (e.g., USDA-Forest Service), have not been extensively and effectively used. • Succession theories related to invasibility and DI (e.g., how DI may change during succession) should be developed (Temperton et al. 2004). • Species selection should take into account mounting evidence that species are shifting their ranges poleward (latitudinal) or upward (elevational). Specifically, planting species or genotypes from lower latitudes or elevations may be more effective for conforming to anticipated long-term environmental change. • Careful extrapolation is required when applying knowledge derived from small-scale experimental restoration studies to larger-scale practice, where beta-and gamma-diversities are among the major objectives. • Continued monitoring of vegetation development and the flux in other ecosystem factors is extremely important but often interrupted because of the lack of resources.
regional species pools (Guo and Ricklefs 2010); (2) measure and rank exotic species, especially invasive species, based on their relative abundance, such as biomass and cover; and (3) establish a reasonable restoration goal based on the present condition and available resources (consider funding, available labor, existing species pools, historic vegetation, etc.). In addition to nearby natural vegetation (if available), records of historical vegetation (before massive human alternation) could be used as a potential target and, in some cases, soil pollen may also inform restoration plans and strategies, as indicated by a few more recent studies describing ecological memory theory (Sun et al. 2014. The boundary conditions outside the site being restored should also be assessed in case additional actions (e.g., fences, buffer zones) are needed ( Figure 3).
Restoration and invasive species management should be synchronized. Site preparation should be well executed before restoration starts to minimize the possible and often rapid invasions by nonnative species either on-site or from nearby areas. This is especially important, as most nonnative but especially invasive plants are favored by disturbance and can invade right after disturbances, such as fires, or on newly abandoned fields, such as mining and agricultural lands (Guo 2017;Martín-Forés et al. 2017;Middleton et al. 2017). Where restoration begins with existing vegetation invaded by invasive plants, herbicide application may be needed (Enloe et al. 2018). Also, the possibility of removing invasive species' seeds or minimizing their germination should be considered. For example, some relatively new techniques such as prior microwave soil treatment on invasive seeds are being developed and evaluated (Wilde et al. 2017).
Nonetheless, whether sites are barren or vegetated, because of existing exotic species pools, their generally greater dispersal capacity (Gaertner et al. 2012;Ricklefs et al. 2008), and the present level of invasion worldwide (Richardson et al. 2000), restoration practitioners will need to manage invasive species at both local and regional levels. This presents a problem when restorations are embedded in a mosaic of lands that are owned or managed by different entities whose goals may not coincide with those of the restoration manager. Broad stakeholder engagement and regional planning are key to successful outcomes in this scenario (Colvin et al. 2016;Stokes et al. 2006).

Species Selection
The key decision in species selection, in places where dominant exotic or invasive species have been identified either before site preparation or in nearby areas, is to choose native species phylogenetically closely related to the invasive species that will be most effective in preventing or resisting exotic invasion (Guo and Norman 2013;Norland et al. 2013). Alternatively, one may choose native species that have similar functional traits to those of potential invasive species, as such communities might have greater resistance to potential invaders (Young et al. 2009). The argument for this practice is that the closely related species usually use similar niches; thus a competitive native species would exclude sister exotic species (but see Larson et al. 2013). An additional recommendation is that when choices are available, we should choose the species that grow easily and quickly after restoration (Grime 1998), although such species could be eventually replaced by more dominant species with slower growth rates. This was the case in an experimental prairie reconstruction study, where Canada wildrye (Elymus canadensis L.) established quickly and excluded invasive species during the early establishment phase, but declined rapidly thereafter (Larson et al. 2013). Such scenarios fit general succession theory (McLane et al. 2012). Finally, a suggested (Larson et al 2013), but as yet untested, possibility is to include in the seed mix native species that are considered invasive outside their range, as a way to produce a reverse "novel weapons" effect on nonnative species that invade the restoration. We summarize here a few key points for consideration before actual restoration takes place.
• Optimal number of species per unit area needs to be evaluated at local and larger scales. Where and when resources are available, native species should be assessed by analysis of Possible pathways for restoring habitats with different levels of degradation and different starting points (e.g., barren sites such as abandoned mining sites vs. highly invaded sites with existing vegetation). In highly degraded or barren habitats, where suitable native species are not available, planting nonnative species (noninvasive) as nurse plants could help to improve conditions for native species to eventually become established. On the other hand, for some habitats where native species can establish themselves, planting natives will be the best choice, even if the recovery rate will be slow (Modified from Guo and Norman 2013).  Figure 3. Site preparation of restoration areas on barren lands and those with existing vegetation. Both types of sites need to take the regional context or at least the landscape context into account. Both may also need some type of buffer zone (or fence) with surrounding habitats to minimize new introductions of invasive species.

Site preparation
alpha (α)-diversity in each plant community; beta (β)diversity, that is, species turnover rate between adjacent communities; and gamma (γ)-diversity across multiple communities at the landscape and regional levels ( Figure 4) (Brockway 1998). Such an approach has been mostly ignored in previous restoration efforts, because comprehensive data and broad-scale coordination were lacking. • The effects of seed/seedling size and sowing/planting density (number or weight of seeds or seedlings per unit area) should be major considerations, as well as the potential influence of species evenness relative to seed density versus seed weight (Guo 2011;Wilsey and Potvin 2000). • Cost of seeds and/or seedlings for the species to be planted must be considered. • Sequence of seeding and/or planting must be determined.
This may reflect known successional trends, such as establishing nurse plants to ameliorate the microclimate for less hardy species, similar to early succession, or to provide soil biota necessary for later successional species to establish. • In prairie restorations, allowing weedy, early-successional native species to fill in between the planted species can enable planted species to gain dominance through time while reducing opportunities for invasive species to establish (Larson et al. 2013).
The first step in selecting suitable species is to acquire a complete list of native and exotic species, both on-site and in nearby areas. When large areas of natural or historical vegetation have been destroyed or severely degraded, it can be challenging to establish a desired target condition for restoration. In such cases, ecological memory could be used through building a historical pollen spectrum (Sun et al. 2014. This approach can help in developing a more complete native species list, but historical climate shifts need to be taken into account. The second step is to identify the dominant traits for these species. For example, which morphological and genetic traits exhibit high flexibility? How might such traits be related to species invasiveness or resistance to species invasion. Conversely, which species may have flexible or unique traits, such as allelopathic chemicals that impact others (Peng et al. 2004)? It is helpful to carefully select nurse plants based on facilitation traits that build soil for use in degraded situations (Gómez-Aparicio et al. 2004;Liu and Guo 2012;Liu et al. 2013) (Figure 2).
Seed source is another important factor to consider before beginning restoration (Wilsey 2010). First, seed source may strongly influence the rate of restoration and performance of restored ecosystems. Some studies, such as that by Carter and Blair (2013), found no major effects of seed source on the performance of restored grassland. However, we believe that this could be a scale-dependence issue. That is, it depends on how far the seed source is from the target site for restoration. If the seed source is very far and different genotypes of the same species are mixed (i.e., could facilitate within-species evolution), the restoration outcome might be different. Second, it has been shown that mixing different genotypes of the same species could help resist pest or disease infestations (Zhu et al. 2000). The bottom line is that species and seed source choices should avoid the unexpected consequence of planting native invasive species.
In heavily degraded systems (e.g., abandoned mines), where native species may not establish sustainable populations, using certain nonnative species may be considered an alternative option. Such nonnative species could subsequently create suitable conditions for native species. However, caution is strongly urged to ensure that there is a high possibility that such nonnative species will be eventually replaced by native species and not be invasive and difficult to eradicate (Guo and Norman 2013;Lugo 2004;Ren et al. 2008).
Recent studies of tallgrass prairie reconstruction in the midwestern United States have highlighted the importance of appropriate locally adapted soil biota, especially nodulating bacteria (Beyhaut et al. 2014) and arbuscular mycorrhizal fungi in both the establishment of planted species (Koziol and Bever 2017) and resilience to their stressors (Middleton et al. 2006). Methods for inoculation at field scales are still in development, but such soil conditioning promises improved resilience with less maintenance in the future and may be especially important when restoring native species in formerly invaded lands (Jordan et al. 2011). Finally, to ensure the success of desirable native species, site conditions such as size, topographic position in the landscape, slope, aspect, soil type (e.g., texture, depth, drainage, fertility), and other factors related to microclimate and microhabitat complexity need to be considered in species selection.

During Restoration
The worst species invasions usually occur right after disturbances or planting and before the establishment of native species. When a site is chosen and preparation is done, a major goal of restoration is to enhance the germination rate and ensure high productivity. This could enforce the resistance to biotic invasions through fast niche occupation and higher community resilience under environmental fluctuation (Isbell et al. 2015). When a carefully planned procedure is in place, restoration practitioners need to closely follow and implement it, step-by-step (Figure 4). We list here a few items to be considered in practice.  Figure 4. Actual restoration process needs to assign the optimal number of species to be planted in a local plot or area (α-diversity) and the entire region (γ-diversity), species composition (identity of species and their relative abundance), and the order or sequence of species (groups) to be planted through time. Species composition should be determined following a comparative analysis of invasive plants (or all nonnative plants) either onsite or in nearby/surrounding areas (as potential invaders). The order of planting may also consider nonnative plants that are not invasive as nurse species if needed (see Figure 2).

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choose one or two dominant native species for seeding. This is typical in forest plantations, done mostly to obtain economic gains through high production of the planted species (e.g., timber, medicine) or to lower the cost of seeds and/or seedlings (Chen et al. 2017). • Continue to monitor and identify species in restored ecosystems that could facilitate or resist nearby invasive species based on phylogenetic relatedness or functional traits (Young et al. 2009). • Continue to add/seed suitable species when necessary to fill in the gaps where originally seeded species did not germinate or survive. • Knowing which species have been successfully planted and/or what restoration strategies have been adopted in nearby areas/ regions is useful. • Determine which species contribute to resistance (high diversity/evenness planting) and tolerance (high exotic richness but not dominance) (Nunez-Mir et al. 2017). Relate phylogenetic resistance to the nearby nonnative species pool (Iannone et al. 2016). • With abundant evidence that species are shifting their ranges poleward (latitudinal) or upward (elevational), species selection for restoration needs to take this factor into account. Specifically, including genotypes that are from lower latitudes or elevations may be more effective.

Multitrophic Considerations
Webster et al. (2010) and Wilson et al. (2016) extensively discussed the role of animals and soil microbes. In particular, they examined how the structure, composition, and fragmentation of landscapes, especially edges, may influence the functional traits and diversity of a host of organisms, including microbes, pathogens, plants, mammals, birds, amphibians, and insect pollinators (bees and butterflies). Restoration needs to increasingly consider the species to be planted or introduced when they may serve as potential hosts for serious diseases or agents of secondary invasions. Maintaining biodiversity and associated functional traits in restoration is critical for the long-term sustainability of ecosystem function and ecological services at multiple trophic levels.
A timely example of the importance of maintaining multitrophic interactions during restoration is the plight of native pollinators, some of which have come to rely on floral resources provided by invasive species. It has been shown that flowering invasive species can fundamentally change pollination networks (Stouffer et al. 2014), but upon removal of the invasive flowers, these pollinators will take advantage of co-occurring floral resources (Larson et al. 2016). It behooves the manager to ensure that alternative floral resources are available before removal of the invasive, which can be difficult and require careful planning in a restoration context.

Management of Restored Vegetation
There is no question that species invasions are likely to be a major challenge; thus, determining how to better manage the restored ecosystem to reduce and resist invasive species will be a major task for us. An important consideration in managing the restored ecosystem is the role of succession and how the entire restored community and planted component species may vary with time. In a long-term (more than 20 yr) study, Ren et al. (2007) found idiosyncratic responses of different ecosystem variables to time and microclimate change, with soil fertility being a critical factor that influences early recovery following degradation in subtropical China. In other words, different variables in the same community exhibited different rates of change through time. McLauchlan (2006) found similar variability in recovery times from agricultural disturbance in the Great Plains, suggesting that ecosystem processes that influence vegetation during restoration are not synchronous.
The principal goal of ecological restoration and sustainable management (Guo 2003), including biomass manipulation of planted species (Doll et al. 2009;Guo 2007;Webster et al. 2010), is to create an ecosystem that is self-perpetuating and resistant to biological invasion. This requires knowledge of the maximum and optimal diversity, biomass, and productivity, based on historic records and future projections. Ideally, both aboveground and belowground communities and conditions should be evaluated and closely monitored and manipulated to achieve optimal ecosystem performance (i.e., for productivity and stability). Specific management actions may include biomass reduction through fire, harvesting, mowing, and grazing (Bi et al. 2018;Tälle et al. 2018) and biomass enhancement through fire suppression (although a risky option if applied long term in a fire-dependent plant community), fertilization, and irrigation (Dalmayne et al. 2013;Lindgren and Sullivan 2013). Because of the varying sensitivities of different community variables to environmental fluctuation, which could further influence the degree of invasion during restoration or succession, managers employing biomass manipulation must consider treatment effects on other community measures, especially diversity-biomass-productivity relationships (Guo 2007;Li et al. 2017). We discuss these manipulation options in detail in the following sections, and the techniques listed could be used separately or in combination to manage plant dominance in restoration projects.

Options for Biomass Reduction
• Fire: Ecological restoration should also include restoring historical disturbance regimes, such as periodic fire by prescribed burning, which emulates as much as possible the fire frequency and intensity that fostered development and maintenance of the desired historical plant community (Brockway et al. 2005). Prescribed fires have several benefits when kept at appropriate levels: see the "intermediate disturbance hypothesis" in Huston (2014). Fire, which periodically reduces the long-term accumulation of dry biomass (e.g., forest fuels), can reduce the possibility of catastrophic events that result in massive destruction. It can improve habitat quality for wildlife, promote fire-tolerant species, reduce pathogens and pests, release nutrients bound in vegetation to the mineral soil, and decrease soil acidity. However, prescribed burning requires very careful planning and application with regard to area, frequency, intensity, season, and which native and exotic species are present (Fuentes et al. 2018;Keeley 2006). Invertebrates, some of which have limited mobility during certain life stages, require special attention (Panzer 2003). Positive feedbacks between fire (as a disturbance agent) and species invasion have been reported in the past (Pauchard et al. 2008), especially in more productive habitats (Huston 2004). In this regard, consultation with local residents, landowners, and managers could be very helpful. Observations from a recently burned site could be useful as a reference.
• Grazing: The relative intensity and timing are critical factors in choosing and using this method. For example, a relatively new study on grasslands in northeastern China shows, after 5-8 yr, that areas fenced from grazing have better restoration results, in terms of vegetation and soil characteristics and recovery rates, although the long-term consequences remain to be seen ). However, some other studies suggest a reduction of biomass could facilitate restoration. Nevertheless, even if the same amount of biomass is removed, another new study shows that rotational grazing (especially at a moderate level) is better than mowing in terms of reaching diversity goals (Na et al. 2018;Wrage et al. 2011). This is partly a result of natural grazing often being selective on species and creating spatial heterogeneity, whereas mowing usually targets all species (Middleton et al. 2006). • Thinning: Yuan et al. (2013) reported that thinning can enhance the establishment and growth of planted and naturally regenerated seedlings of native woody (tree) species. Thinning reduces organic matter, total nitrogen, bulk density, and water content of the soil, but increases phosphorus and potassium levels. Moderate thinning should be periodically used as part of the long-term management of plantations. Different thinning intensities (i.e., variable retention among forest trees) can be used to increase the spatial heterogeneity in overstory vegetation (Franklin et al. 2007). Uneven-aged silvicultural systems, such as single-tree selection and group selection (Brockway et al. 2014), can also improve overstory structure while increasing the species diversity, richness, and evenness of native understory plants (Brockway andOutcalt 2015, 2017). • Herbicides: Use of chemicals to control undesirable plant competitors or invaders is viewed as a less favorable option, because of the potential adverse effects posed to desirable species present in local and regional habitats. Although some of these chemicals are more selective in their action and can be safely used in forestry and some restoration programs, application of broad-spectrum chemicals can cause harm to understory species and may lead to soil pollution or a decline in biodiversity. When carefully applied in a limited spot-grid pattern, herbicides have been used to effectively reduce competition from understory and overstory oaks, thereby producing progressive increases in the foliar cover of desirable species of graminoids and forbs during restoration (Brockway and Outcalt 2000). The cost of herbicide application serves as a practical constraint on its use in the field, where it is often limited to smaller-scale and/or higher-value projects. • Physical methods: In addition to thinning, forest restoration may be fostered through other mechanical management practices, such as clearcutting with reserves, to more rapidly change overstory composition from one dominant species to another, and partial-cutting through mastication (i.e., woody plant biomass reduction by a rotating drum with cutting heads, which leaves a shredded mulch on the forest floor). By retaining the preferred trees on-site, such practices create an opportunity for encouraging desirable plant species and more safely reestablishing natural processes, such as periodic prescribed burning following the removal of midstory fuel ladders (Brockway et al. 2009). Mowing is a fairly common management practice that may be used in grasslands. However, its application should strive to be minimally disruptive to the life cycles of native species, while attempting to impair invasive species. Hand pulling of invasive plants may also be a helpful biomass reduction technique in communities invaded by exotic species that have not formed pure stands. However, physical methods may also create disturbances that have adverse impacts on other species or surrounding habitats. Therefore, they should be selectively used and carefully implemented, as either individual treatments or in combination with other biomass reduction techniques (chemical, fire, etc.) to produce desirable results.

Options for Biomass Enhancement
• Fertilization: Lindgren and Sullivan (2013) found that fertilizing 15-yr-old lodgepole pine [Pinus contorta Douglas var. latifolia (Engelm.) Critchfield] stands significantly enhanced mean structural diversity of the total plant community. A rich literature exists concerning forest fertilization to augment the biomass production of crop trees, with lesser focus on understory plant species. Fertilization mostly benefits the overstory following a thinning operation that allows the residual trees to grow more freely, with nitrogen an aid in rebuilding leaf biomass in the canopy, thus enhancing photosynthetic capacity and subsequent growth (Miller 1981). However, the cost of fertilizer application limits its usefulness in the field to smaller-scale and higher-value restoration projects. • Irrigation: In agronomic disciplines, irrigation and fertilization are common techniques for promoting plant growth. However, in a recent study, Müller et al. (2016) found contrasting effects for irrigation and fertilization on the plant diversity in hay meadows, where plant species richness was unaffected by irrigation but negatively influenced by application of nitrogen fertilizer. This is a common outcome in grasslands, as well, primarily mediated via increased productivity (Hautier et al. 2009;Socher et al. 2012). Use of irrigation is largely limited by costs and logistical considerations (i.e., proximity to a water source and ability to deliver water to the site). Thus, it is reserved for small-scale and high-value restoration projects where natural precipitation is inadequate and irrigation is crucial for success.

Management of Invasive Species
Unlike habitats that have long been invaded by exotic species, in newly restored habitats, exotic species can be fairly easy to physically remove, especially during early stages, because invasive species are few and their abundance is low. Therefore, early detection, rapid response (including eradication), and continuous monitoring are strongly recommended for newly restored habitats. New regulations to limit or minimize the possibility of bringing exotic species into such habitats may also be needed and/ or enforced. Disturbance and physical modification of habitats from human activities facilitate invasions by nonnative species (Fei et al. 2014). At the same time, initial restoration work could also cause some level of "disturbance" that may facilitate species invasions (Hobbs and Richardson 2011). Therefore, during site preparation, managers should take precautions and consider removing invasive species before actual seeding and/or planting starts. Some undesirable species can be extremely abundant during the early (≤3 yr) stages of tallgrass prairie reconstruction from farmland, despite extensive site preparation, but naturally Invasive Plant Science and Management 169 decline through time as more competitive planted species become established (Larson et al. 2017). In this case, patience is the best response, as control methods, by further disturbing the site, may produce more harm than good. More effort should be placed on reducing the dominance of invasive species (Hejda et al. 2016), not just decreasing the richness of all nonnative species. In habitats where complete eradication of invasive species is not possible, techniques that can effectively remove their biomass should be developed. However, it is prudent to bear in mind that management tools such as burning, grazing, physical or chemical treatment, and biocontrol agents (Figure 1) also cause new disturbances, and their effects on native species need to be evaluated. Based on available evidence, it is reasonable to argue that the effectiveness of such control methods or treatments would depend on the degree of invasion. For example, Ereth et al. (2017) recently reported that both herbicide and burning can help in controlling Kentucky bluegrass (Poa pratensis L.) invasion, but the outcome depends on its level of invasion. Poa pratensis and smooth bromegrass (Bromus inermis Leyss.), though initially absent in experimental tallgrass prairie reconstructions in Minnesota and Iowa, increased through the 10 yr that sites were monitored and constitute the greatest threat to the plant communities going forward. The frequency of invasive forbs, including noxious weeds such as Canada thistle [Cirsium arvense (L.) Scop.], stabilized or declined at the same sites shortly after planting without active control (Larson et al. 2017). We list here some key points to be considered in managing invasive species during restoration.
• Belowground species richness and biomass should also be evaluated in restoration and management plans (Leisher et al. 2012). • Different strategies are needed for managing individual (target) species (Deák et al. 2011) versus all nonnative species (Ruijven et al. 2003) • Biocontrol may be a suitable alternative, if harm is not done to non-target desirable species (Miao et al. 2012). • Rapid evolution of invasive species is a concern, because adaptation is no doubt a key to their previous success and continuing persistence (LaRue et al. 2017) • There is an ongoing debate as to whether management efforts should be focused on the abundance centers or the invasion front/border (Dickie et al. 2014;Simberloff 2003). For example, the presence of kudzu [Pueraria lobota (Willd. ) Ohwi] appears to be fine at its northern border (e.g., Nebraska), where it could be regarded as a "useful" plant. In North Carolina, however, where the species abundance center is located, there is too much of it, causing great damage to native species and costs in trying to control it. In management with limited resources, should we start from the abundance center or at the border or do everything we can across the species' entire invaded range? Perhaps climate change models may suggest more focus is needed on higher latitudinal limits or higher elevations (Hellmann et al. 2008 (2) increasing human use of invasive plants for a variety of purposes (e.g., food, medicine, chemicals, fiber for clothing, phytochemistry) (Stafford et al. 2018). • The trajectory and ultimate success of any local restoration effort, to a large extent, depends on the landscape or regional context where the exotic species pool exists (Riitters et al. 2018).
It is worth noting that, in addition to grazing generally reducing overall community biomass (as discussed in the previous section), grazing by introduced large herbivores can greatly alter plant community species composition by encouraging certain plants while depressing others. Taking grassland restoration as an example, grazing by different large herbivores and at different stocking rates could be a useful practice in managing degraded or invaded grasslands to control invasive species, although some exotic herbivores could sometimes directly facilitate certain exotic species (Best and Arcese 2009;Skaer et al. 2013). On one hand, it is well known that foraging by different large herbivores exerts various effects through dietary selection by the animal (Liu et al. 2015;Zhong et al. 2014). That is, cattle prefer foraging on grasses, while sheep like to eat forbs growing in steppe communities (Kimball and Schiffman 2003). Therefore, cattle grazing is often considered useful for controlling invasive annual grasses. Johnson and Cushman (2007) reported that reintroduction of elk can significantly reduce the abundance and biomass of highly invasive exotic grasses in a California grassland. On the other hand, because of the different responses of plant species to grazing intensity, large herbivores can enhance plant community tolerance through compensatory growth and thereby depress the invasive species (Gao et al. 2008).

The Scale Issue
Despite many ongoing efforts in controlling species invasions, at the regional level the degree of invasions is likely to increase through time because of ongoing human activities (Guo 2015(Guo , 2017. Local invasive species removal needs to take this time factor and the regional exotic species pools into account. In addition to careful application of small-scale, experimental experience, there are several major differences between small-and large-scale restoration and management (Walters and Holling 1990). The success and trajectory of a local restoration project to a large extent depends on pool of exotic species in the region (Larson et al. 2018). While large-scale removal of invasive species is often not feasible, successful removal and even total eradication of at least some species at local scales could be achieved. Largescale restoration and invasive species management require longterm and collective efforts in collaboration and coordination by many local governments and managers (including the invasive species removal efforts) and involving public and private landowners (Colvin et al. 2016;Stokes et al. 2006). More importantly, removal of invasive species at any scale is useful, as it would help open up niche spaces for native species and thus promote restoration.

Additional Thoughts
When both processes and consequences are monitored at a welldesigned restoration site, ecologists can take advantage of the restoration project as a semi-controlled experiment, as an in-depth examination of the inhibitory and facilitating mechanisms of species invasion (Sargent et al. 2017). It is crucial to remember that any management action (e.g., burning, grazing, harvesting) that occurs after restoration can serve as a disturbance agent that may encourage a subsequent invasion of exotic species. Thus, considerable caution is always appropriate when planning management actions and careful execution is required during field implementation.
Research and management efforts at multiple levels will be strengthened through the global sharing of lessons learned and exchange of technical information related to successes and failures for restoration and curbing invasive species. Dissemination of helpful knowledge could be facilitated through citizen science and volunteer (learning-by-doing) programs, in addition to more formal education and onsite demonstrations for interested groups (e.g., landowners, policy makers) and the general public.
Most restoration efforts to date have focused on species at the same trophic level and the possible consequences for species at different trophic levels have been largely ignored, although pollinators are increasingly a target of restoration. In other words, when reintroducing particular species of animals and planting plants, practitioners should carefully consider what invasive plants or pests might be accompanying the restored species, using information from lessons learned about the plant-animal interactions from nearby species pools (Davidson et al. 2018).
Very much different from restoration efforts in earlier times, today's restoration programs should increasingly aim to serve multiple purposes. These may include (1) restoring to desirable conditions, which protect high numbers of native species; (2) preventing and reducing biotic invasions; (3) maximizing economic goals (e.g., bioenergy crops can simultaneously restore degraded lands and serve food, energy, and water needs); and (4) ensuring long-term ecosystem sustainability as the basis for developmental stability (Chen et al. 2017). To accomplish this, restoration needs to use both ecological and evolutionary theories and past experiences as progressive guides for future practice.
Related to our earlier discussions regarding the possible adverse effects of projected climate warming, many weather-and climate-related extreme events may serve as disturbance agents that could disrupt normal ecosystem processes and facilitate species invasions (Joyce et al. 2013). At the same time, they could also provide opportunities for restoration and invasive species management (Guo 2003;Katz et al. 2005). This becomes increasingly important if climate change is leading to more severe and destructive conditions (Isbell et al. 2015). For example, in some heavily invaded habitats, extreme climate and weather could also cause negative effects on invasive species, thus affording opportunities for replacement with native species.
Finally, historical records and data sets of vegetative composition (e.g., fire and pre-restoration conditions), successional status (e.g., vegetation, soil), and management actions should be well maintained as much as possible for future evaluation purposes (Larson et al. 2018).

Conclusion
Today's restoration programs need to target both natural conservation and economic aims. To achieve both goals, restoration needs to curb biotic invasions (even under ongoing climate change) and mitigate continuing human disturbance. Invasive plant management includes two traditional parallel lines leading to success. First, in basic research, (1) more experimental work at both population (individual species) and community (multispecies) levels and (2) greater focus on the idiosyncrasies of species and habitats in response to disturbance (e.g., resistance, acceptance) are needed (Moon et al. 2015). Second, with regard to management, (1) setting more realistic goals and (2) establishing more inclusive communication with a broader and more diverse audience (e.g., different types of landowners) will enhance success (Estévez et al. 2015;Gaertner et al. 2012).