Efficiency of unlocking or locking existing protected areas for identifying complementary areas for biodiversity conservation

Incorporating Genetic Diversity to Optimize the Plant Conservation Network in the Third Pole

Climate change poses a significant threat to the survival of many species. Although protected areas can slow down biodiversity loss, they often lack systematic planning and do not integrate genetic diversity. Genetic diversity is a key prerequisite for species survival and the ability to tolerate new conditions. Using population genetic and distribution data from 96 plant species in the Third Pole (encompassing the Tibetan Plateau and adjacent mountains), we mapped patterns of genetic diversity, projected climate-driven range dynamics and future genetic erosion, and designed an optimal conservation framework for the region. We identified several patches of high haplotype diversity (HD), with a relatively high number of haplotypes in southeastern Third Pole. Regression models revealed that climate and topography have interacted to shape patterns of genetic diversity, with latitude and precipitation being the best predictors for HD of cpDNA and nrDNA, respectively. Ecological niche modeling predicted an approximate 43 km northwestward and 86 m upward shift in suitable habitats under future climate scenarios, likely leading to a significant loss of up to 13.19% and 15.49% of cpDNA and nrDNA genetic diversity, respectively. Alarmingly, 71.20% of the newly identified conservation priority areas fall outside of the existing protected areas and planned National Park Clusters. Therefore, we recommend expanding the network by 2.02 × 105 km2 (5.91%) in the Third Pole, increasing the total conserved area to 1.36 × 106 km2 (39.93%) to effectively preserve the evolutionary potential of plants. This study represents an innovative attempt to incorporate genetic diversity into biodiversity conservation efforts.

Ecosystem services in conservation planning: Assessing compatible vs. incompatible conservation

The compatible conservation of ecosystem services (ES) refers to the sustainable development of a region and the multiple dimensions of the region population's well-being. Applying the ES relationship to systematic conservation planning (SCP) can help determine the protection priorities associated with ES and support good zoning decisions. This study uses Nanchang, China as a case study to construct a multi-scenario ES protection scheme. This includes evaluating the spatial distribution characteristics of four core ES, and the ES relationships in the subregion in Nanchang. The ES relationship is then used to construct three ES conservation scenarios (synergetic, trade-off and incompatible), and the SCP tool is used for zoning. The results show the following. First, the incompatible scenario prioritizes the conservation of supporting services and provisioning services, which support ecological protection and cultivated land security. Second, given a land management and control threshold, the management zones can be compatible with a large proportion of secondary services in the synergetic scenario (22%). Fewer secondary services are compatible under the trade-off scenario (8%). As the compatible secondary service targets increase, each management zone area experiences a nonlinear change. The spatial change is more stable in the synergetic scenario compared to the trade-off scenario, and the space of management zone becomes discrete under the trade-off scenario. Third, the compatibility process has a feedback effect on the ES relationship. Compared with the trade-off scenario, compatible synergetic services are more stable with respect to changes in the ES relationship. Constructing ecological buffer zones takes up cultivated land, decreasing the synergy between carbon sequestration services and food production services. However, ecological buffer zones should play a role in certain areas. The compatibility of increased food production services and habitat services in priority conservation and controlled development zones enhance ES trade-offs. An increase in cultural services is compatible with carbon sequestration services in the ecological buffer zone. This changes the relationship between ES, from having a weak trade-off to having a weak synergy. Creating a compatible ES is a spatial trade-off process; these synergies and trade-offs should be considered in spatial planning. An appropriate proportion of ES should be allocated to each zone, to increase the coordinated management of the urban-rural ecology.

Dominant Species Abundance, Vertical Structure and Plant Diversity Response to Nature Forest Protection in Northeastern China: Conservation Effects and Implications

The conservation of species diversity and improvement of forest structure are essential roles of the Natural Reserve Policy and the Natural Forest Protection Program (NFPP) in China. However, the long-term effects of NFPP are still not well-defined, and a natural reserve (Liangshui) and surrounding region were surveyed as a proxy of NFPP for approaching the protection effects. Our results showed that long-term conservation significantly altered the dominant species in the herb layer (80% of species), followed by shrub (58%) and tree layers (50%); there was a 1.6-8.0-fold increase in abundance in Corylus shrubs, Acer trees and Carex grass, but a 1.3–10.0-fold abundance decrease in larch trees, Athyrium herbs and Lonicera shrubs. In contrast, tree species diversity and distribution evenness increased by 31% and 23.4% in the reserve, respectively. Forest protection in the reserve also led to the forest structural alteration with the observation of larger-sized trees and shorter herbs, but relatively sparse forests (smaller tree density). Structural equation modeling manifested that the reserve directly altered forest structure, at a coefficient of 0.854, nearly two-fold higher than its impact on diversity (0.459) and dominant species (−0.445). The most affected parameters were plant size (trees and herbs) and tree density related to forest structure, tree diversity, herb richness and evenness for diversity traits, and Oxalidaceae and Rosaceae for dominant species. This study provides basic data that can be used to evaluate the impact of the nature reserve in NE China, and these findings can be used to guide the implementation of NFPP in the long-term in the future.