Perspectives on conservation grazing: The need for monitoring and communication

Vegetation management for the maintenance and conservation of butterfly habitats in temperate human-dominated landscapes

This study investigates the soil functioning and regeneration processes in a semi-arid rangeland subject to an eleven-year conservation grazing (CG) program within the Gonbad paired watershed in Hamadan, Iran. Five distinct sites with varying rangeland vegetation cover were selected based on differences in grazing regimes and soil disturbance histories. These sites include: CG site with Astragalus-Artemisia vegetation (CG(A-A)); CG site with Astragalus-Bromus vegetation (CG(A-B)); CG site, easily accessible to grazing livestock, with Astragalus-Lactuca vegetation (CG(EA)); CG site with a history of past rainfed farming and Centaurea-Grasses vegetation (CG(PRF)); and free grazing (FG) site with Astragalus-Euphorbia vegetation. In addition, a long-term rainfed farming site (RF) was studied as the dominant land use. Rangeland management practices had a discernible impact on nearly all soil quality (SQ) indicators. However, due to their strong interdependence, only soil aggregate stability, carbohydrates, and phosphatase activity proved to be critical indicators representing soil functioning in the area. The general SQ index illustrated a decline in soil functioning at RF (58%), CG(PRF) (55%), FG (42%), and CG(EA) (22%) sites compared to sites classified as "good" (CG(A-A) and CG(A-B)). Total organic carbon and carbon stock were only recovered in well-restored sites, characterized by a predominance of shrubs and perennial grasses. Meanwhile, active carbon and carbohydrates revealed the positive effects of conservation grazing in moderately and poorly restored sites, characterized by a predominance of forbs and annual grasses. Our findings suggest that soil disturbance history and grazing accessibility are critical factors for successfully implementing conservation grazing management in the area.

Grazing and mowing are two major land use types in natural grasslands, which have intensive effects on nutrient cycling of grassland ecosystems by deposition of fecaluria nutrient versus removal of hay nutrient. Plant nutrients sensitively respond to the changes in nutrient cycling, while the information on the effects of diverse grazing versus mowing regimes on plant nutrients at different organs or levels are incomplete. A field experiment was conducted to compare the effects of continuous versus rotational grazing, and low versus high mowing frequencies on grassland ecosystems in a semiarid steppe of Inner Mongolia. Plant community characteristics and C, N and P concentrations of dominant species were determined across different managements. We found (i) plant community height and standing biomass significantly decreased with grazing intensity under both continuous and rotational grazing and under annual mowing. (ii) Plant shoot C concentration decreased, whereas N and P concentrations increased with grazing intensity in the two grazing regimes, while these concentrations showed no significant changes in response to the two mowing regimes. (iii) Plant community aboveground C, N and P pools significantly decreased with grazing intensity of both grazing regimes, but did not decrease with mowing frequency in the two mowing regimes. (iv) Plant root C, N and P concentrations showed little significant response to different grazing or mowing regimes, indicating a relatively bigger stability or slower response in plant root nutrients. Our study provides insights into the nutrient cycling in grazing and mowing grassland ecosystems from multiple perspectives.

Fire is widely accepted as being a valuable tool in the management of natural vegetation. It is a resource modifier (Cutler 1979) and can be used to change the composition of vegetation and its cover or to maintain plant communities in a certain stage of succession. So too in South Africa, where fire has, it would seem, played a role in determining the nature of vegetation for many hundreds of years (chapters 3 and 4). Not unexpectedly, therefore, it has continued to be used by farmers and others in the management of this vegetation. Here its use must be dictated by the desired objectives, the known reaction of the plant communities to burning, the management systems into which it is to be incorporated and by the local legislation pertaining to the use of fire. Previous chapters have dealt with the reaction of plant communities to fire and this chapter will deal with three specific aspects viz the objectives of burning, the incorporation of fire into some management systems and fire legislation.

Grazing is a substantial threat to the sustainability of grassland ecosystems, while it is uncertain about the variety of plant and soil microbial community and the linkages between them limit the comprehensive understanding of grazing ecology. We conducted an experiment on the effects of the grazing regimes rotational grazing (RG), continuous grazing (CG), and grazing exclusion (GE) on an alpine meadow in Qinghai-Tibetan Plateau. The differences of plant community composition, soil microbial community assembly mechanism, and taxonomic and functional composition between grazing regimes were examined, and the relationship between plant species and the soil microbes was assessed by constructing a co-occurrence network. The results showed that the plant community composition varied with the grazing regimes, while the soil microbial community composition did not vary with the grazing regimes. The soil bacterial functional composition was similar under RG and CG, while the soil fungal functional composition was similar under GE and RG. The soil microbial community under all grazing regimes was assembled mainly according to stochastic rather than deterministic mechanisms, and RG and CG reduced the relative importance of the stochastic ratio. At the microbial phylum level, CG and GE increased the relative abundance of Acidobacteria and Armatimonadetes and CG and RG increased the relative abundance of Elusimicrobia. In the network of plant species and soil microbial classes, plants and bacteria themselves were mainly positively linked (symbiosis and promotion), while plants and soil microbes were mainly negatively linked (competition). There were five microbial generalists in the network, which connected with many microbes, and four showed no difference in their abundance among the grazing regimes. Overall, the stable key microbes in the network and the fact that many of the plants are unconnected with microbes weakened the impact of grazing-induced changes in the plant community on soil microbes, probably resulting in the stable soil microbial community composition. Moreover, there was still a dominant and tolerant plant species, Kobresia pygmaea, that connected the plant and microbial communities, implying that the dominant plant species not only played a crucial role in the plant community but also acted as a bridge between the plants and soil microbes; thus, its tolerance and dominance might stabilize the soil microbial community.

Oil palm plantations have expanded rapidly in recent decades, and are causing substantial impacts on tropical habitats and biodiversity. However, owing to its long lifespan (25-30 years), oil palm forms a much more varied and structurally-complex habitat than many other crops. This can include abundant understory vegetation and also epiphytes on palm trunks. However, the diversity of this plantation vegetation has been poorly studied, and there has been little consideration of the impacts of common plantation vegetation management practices on plant communities. We conducted a long-term vegetation management experiment that forms part of the Biodiversity and Ecosystem Function in Tropical Agriculture (BEFTA) Programme in Riau, Indonesia. We manipulated herbicide and manual cutting regimes within mature oil palm plantations to create three different understory complexity treatments (Reduced, Normal, and Enhanced vegetation) across replicated sets of plots. Plant communities were surveyed before and after experimental understory vegetation treatments began in three different microhabitats: within the middle of the plantation block (core), on the road edge (edge) and on oil palm trunks (trunk). Part of the sampling was also conducted during a drought event. We recorded 120 plant species, which comprised a mixture of native, non-native, ‘beneficial’, and ‘problem’ species. We found substantial variation in plant communities between edge, core, and trunk microhabitats, indicating high levels of heterogeneity within the plantation. There were significant effects of varying understory treatment within both core and edge microhabitats, but no spillover of impacts into the trunk microhabitat. We also observed substantial impacts of drought on plant communities, with declines in either biomass, percentage cover, or richness seen across core, edge, and trunk microhabitats during low-rainfall periods. Our findings highlight the diversity of plant communities that can be supported within oil palm plantations, and the substantial impacts that management decisions, and also drought, can have on them. Given the role that diverse plant communities can have in supporting species in other groups, this is likely to have a significant impact on the wider plantation biodiversity. We suggest that plantation management strategies give greater consideration to within-plantation understory plant communities and choose more wildlife-friendly options where possible.

Effect of plant community composition on plant response to fire and herbicide treatments

An analysis of the vegetation of Goedverwacht farm in the mixed bushveld of the Northern Province is presented. Releves were compiled in 33 stratified random sample plots. Eight distinct plant communities were identified by means ofBraun-Blanquet pro-cedures. Detrended correspondence analysis (DCA) was applied to the floristic data set using the computer programme DECORANA (Detrended Correspondence Analysis) to determine a probable environmental gradient and to facilitate in the identification of management units. The computer programme CANOCO (Canonical Correspondence Analysis) was used to apply canonical correspondence analysis (CCA) to the floristic data set. Two management units were determined by means of vegetation ordinations and soil data. A classification, description and ecological interpretation of the plant communities as well as a description of the management units are presented.

Lower forest–grassland ecotones and 20th Century livestock herbivory effects in northern Mongolia

Grassland Community Composition Response to Grazing Intensity Under Different Grazing Regimes

基于盐分梯度的荒漠植物多样性与群落、种间联接响应

Plant communities form the structural and functional basis for nearly all terrestrial ecosystems. Good knowledge about plant communities is therefore necessary to understand and protect life on our planet. Journal of Vegetation Science publishes papers on all aspects of plant community ecology with an emphasis on articles that develop new concepts and methods, test theory, or identify general patterns. This article is protected by copyright. All rights reserved.

Mechanisms That Result in Large Herbivore Grazing Distribution Patterns

QuestionHow are semi‐natural ecosystems affected by goat grazing regime (heavy, light and long‐term abandonment)?LocationAnaga Rural Park, Tenerife Island, Canary Islands (Spain).MethodsWe evaluated plant species composition, diversity and structure (frequencies of functional groups based on growth form and bare ground) for three goat grazing regimes using 63 permanent point‐quadrat transects. The effect of orientation (N vs S slope) was also analysed. Data were collected in the spring during each year from 2001 to 2005.ResultsGrazing regime affected the studied functional groups differently. The frequency of annual grasses was higher in the heavily grazed areas, shrubs decreased sharply from abandoned to heavily grazed areas, and shrub legumes appeared less abundant in the lightly grazed transects. An interaction between grazing regime and orientation affected some functional groups. Grazing led to higher plant diversity, and did not affect the frequency of bare ground or native and endemic species. There were no strong differences in species composition among the three grazing regimes. However, species composition in abandoned areas was characterized by a higher abundance of late‐successional and endemic shrub species, while herbaceous species typical of pastures were more common in the grazed areas.ConclusionsGrazing regimes noticeably affect the composition and structure of the vegetation of semi‐natural ecosystems but do not result in a complete turnover in species composition. Goat grazing is beneficial for maintaining traditional open agroecosystems; however, controlling the grazing intensity can avoid negative effects on the vegetation, particularly the sharp reduction in shrub and palatable species. Some abandoned areas should be maintained to preserve grazing‐sensitive endemic shrub species in these Canarian semi‐natural ecosystems.

Cattle Distribution on Mountain Rangeland in Northeastern Oregon