Baseline information on the history of the park and the people living in proximity to park, as well as local stakeholder needs for and uses of various natural resources, provides useful context with which conservation organisations can frame specific resource use projects and programmes. Stakeholder needs and uses are dynamic; hence, ongoing engagement is required to maintain the relevance of resource use programmes in the context of changing needs. Data to be collected would be context-specific depending on the type of resource, but some useful variables may include species (fauna and flora) used, parts harvested, the motivation for harvest, type of use (domestic or commercial), quantity used, product quality requirements, number of people to be involved in the harvesting, level of dependence on the resource and acceptability of alternative resources should demand exceed supply (see Case study 1 in terms of medicinal plant harvesting and surveys with traditional healers).

Broad-scale status of and trends in resource use are useful for assessing the degree to which strategic objectives for resource use are being met, as well as for long-term monitoring of resource use dynamics to inform an adaptive approach to management, specifically in relation to threat identification. The known status of resource use in SANParks is provided by Van Wilgen et al. (2013) and forms the baseline for monitoring long-term trends in resource use (in terms of species and products harvested, volumes harvested, user groups, etc.) as does the annual SANParks resource use report (see, e.g. Symonds 2014 and 2018 for the reports for 2013/2014 and 2017/2018, respectively). Broad-scale trend indicators to monitor the extent of resource use and the benefits accrued include quality and quantity of products harvested, satisfaction of participants, income generated and number of stakeholders directly involved. Setting easy-to-measure species or group-specific indicators of quality is an important step when new projects are set up. For the forest fern Rumohra adiantiformis, for example, it involved recording the number and length of ferns fronds with < 10% blemish, harvested during successive harvest cycles (Vermeulen 2009). The programme also includes indices for illegal, unreported and uncontrolled harvesting (see Case study 1).

Monitoring the simultaneous social and economic impact of resource use enables identification of costs and benefits at multiple stakeholder levels, as well as between stakeholders and the natural environment, in support of a net benefit outcome at most levels (Swemmer & Taljaard 2011; Swemmer et al. 2015a). Examples of social impacts include developing or maintaining social cohesion and continuity as well as changes that occur in people’s way of life (i.e. how they live, work, play and interact with one another on a daily basis), their culture (i.e. shared beliefs, customs and values) and their community (i.e. its cohesion, stability, character, services and facilities) (Lahiri-Dutt, Nair & Dowling 2008). Not only does the SANParks resource use programme aim to promote access to resources but it also aims to build support for conservation through the creation of both positive relationships and vested interest in national parks (Swemmer et al. 2017). Monitoring the economic impact of resource use on the user at various scales (e.g. individual, household and broader scales) is equally important. Identifying indicators for social and economic objectives is not easy because in most cases the outcomes are both quantitative and qualitative. Detailed monitoring of the social and economic aspects is not always needed on an annual basis. Numerous generic well-being indicators exist, but indicators are context-specific in that they must be seen as legitimate by all parties involved. This is best achieved through co-defining programme objectives and indicators through multiple stakeholder lenses together with resource harvesters (Swemmer et al. 2015a). A lack of cohesion and formal representation of user groups, for example, limited inclusion of resource users in developing indicators within the GRNP line fisheries (Case study 2) and will require novel methods to ensure inclusivity in the future. In contrast, the Rastafarian community was directly involved in the monitoring of Bulbine latifolia, a plant used for medicinal purposes (Case study 1) within the park. Monitoring of the indicators is determined at a project level based on local context and should be based on needs, resources and expertise available. The use of community-based monitors has proven successful in natural resource-based programmes (Swemmer et al. 2015b). For example, community monitors employed through South Africa’s Expanded Public Works’ Environmental Monitor Programme patrol certain boundary fences of the KNP, including areas where there have been historical incidents of illegal harvesting of high-value medicinal plants. The community monitors both come from and work in the areas adjacent to the park. Despite advantages of using community monitors (local expertise, connections with community and buy-in to the project) funding for salaries can be a challenge (Swemmer et al. 2015b).

Quantitative, field-based resource inventories or other relevant methods (e.g. life tables for animal populations, biomass estimates for fish and size–class distributions for timber – see Table 1) can provide baseline data on how much of a resource targeted for use is available. Data on the rate of production, which depend on the demography of the target species or the parts harvested, are crucial in determining the sustainable off-take of the available resource. For example, in the case of B. latifolia harvested for medicinal purposes in the GRNP, the size–class distribution of the population and monitoring data on the growth rate of the species were used to formulate harvest prescriptions in terms of harvestable size and harvest rotation, reflecting the sustainable off-take, while rate of bark regrowth was used to assess options for sustainable medicinal bark harvesting (Vermeulen 2009, Case study 1). Population transition and other mathematical models could also be used to determine the potential yield or to assess harvest impact (Ngubeni 2015; Pfab & Scholes 2004) for harvest prescription development and refinement. Where necessary (e.g. large mammals), ecological complexity should be incorporated into the decision-making process and population management should seek heterogeneity favouring biodiversity and ecosystem resilience (Ferreira & Hofmeyr 2011). Indicators of turnover would depend on the species or products harvested, for example, diameter or length growth for whole plants, recruitment and regeneration (including coppice growth), fruit or leaf or bark production for specific plant parts and catch per unit effort for fish.

The impact of harvesting according to specific harvest intensities on the target species, as well as on other components of the ecosystem, is an important component of monitoring. Two approaches are followed here: monitoring trends in quality and quantity of the product harvested from the same harvest area and the health of the population after harvesting. Data collection depends on the specific species and product harvested and could include the number or volumes harvested (quantity) and size (or any other measures that define the quality, e.g., condition factor) of the individuals or products harvested. Monitoring population health entails assessing the quantity and quality of the remaining product in the harvest area, as well as the population status as a whole. For example, in the GRNP, monitoring included assessing tree response to bark stripping and susceptibility to insect and fungal damage following bark stripping (Case study 1). In some instances, population parameter monitoring should be implemented within areas where resource use occurs, and also in ‘no-take’ areas to provide an indication of population trends independent of anthropogenic influence. For example, target populations of various fish species are known to show natural fluctuations in population abundance (Götz et al. 2008), while a natural decline in R. adiantiformis fern populations has also been recorded (Vermeulen 2009), which may need to be taken into consideration.

The overharvesting of resources has been identified as an international threat to biodiversity and ecosystem services and as such a driver of global change (Van Wilgen & Herbst 2017). This is no different in SANParks where the demand for medicinal plants is increasing (Van Wilgen et al. 2013), particularly so in the GRNP where demand for forest and fynbos medicinal plants species is exacerbated by the nature of the open access park, changes in stakeholder dynamics and commercialisation (Vermeulen 2009).

Table 2 summarises Garden Route projects in terms of monitoring objectives, methods, frequency of monitoring and important indicators. A baseline inventory of medicinal plant harvesting was provided by Van Wilgen et al. (2013), while local traditional healers were surveyed to determine their requirements for plant species in the region (Ngubeni 2015). Medicinal tree bark was identified as a high priority, considering the demand for bark for private and commercial use, and the destructive nature of strip harvesting. Tree response to bark stripping and the rate of bark regrowth were assessed (Vermeulen 2009). Monitoring of B. latifolia, also a species in high demand and subjected to overharvesting, was aimed at assessing the rate of growth and population turnover to inform harvest prescriptions for sustainable use (Vermeulen 2009). This monitoring was conducted in consultation with the Rastafarian community as an important user group. A project was initiated to monitor the increasing unauthorised use of medicinal and other plants (Vermeulen et al. 2015).

A wide range of medicinal plant species and products are in demand (Ngubeni 2015; Vermeulen 2018). Users seem to be receptive to exploring alternatives to assist sustainability (Ngubeni 2015). Harvest prescriptions have been formulated for high-demand species such as B. latifolia, which is slow growing with a low rate of turnover of populations in the wild (Vermeulen 2009). However, a sustainable supply of B. latifolia can be provided by growing this in gardens and engagements are underway with stakeholders to facilitate this. For medicinal tree bark, harvest prescriptions have been developed for Ocotea bullata, but for most other species, little scope exists for sustainable strip harvesting because of poor bark regrowth, and susceptibility to fungal and insect damage (Vermeulen 2009; Vermeulen, Geldenhuys & Esler 2012). Harvesting bark as by-product from timber harvesting or full-tree harvesting under sustainable timber harvesting systems (see Seydack et al. 1995) would be more viable options than strip harvesting.

Managing unauthorised resource use in a fragmented and open access park, such as the GRNP, requires pro-active engagement with stakeholders together with law enforcement and vigilant monitoring of population health. Improved understanding of stakeholder dynamics and needs enable research and monitoring to focus on priority species and products, and assess to what extent needs could realistically be addressed. Achieving inclusive engagement with all plant harvesters is key but difficult because many are not members of a user group. Park management needs to drive a more structured effort to identify stakeholders because the demand for medicinal plant products is expected to increase.

Recreational fishing managed nationally under the Marine Living Resources Act (1998) has been primarily top-down and subsistence (or small-scale) fisheries, in particular, were historically marginalised and neglected within policies and management systems (Sowman 2006). Recreational and subsistence fishing occurs within the GRNP, but little information about participants or trends in fishing effort and catches was available to management.

To evaluate the sustainability of marine and estuarine fishing, a monitoring programme was implemented in 2008. Two estuaries and two coastal sections were selected as monitoring sites through a prioritisation exercise. Objectives, key questions and hypotheses were co-developed by scientists and park management. Sustainability indicators along with trends, performance criteria and TPCs were set within the ecological and social domains. Indicators were standard between estuarine systems and coastal areas but reference points were area specific. For example, in estuarine systems, targeted catch per unit effort (cpue) for Cape stumpnose is an indicator but the TPC differs between systems.

The programme provides spatially explicit information including catch rates, proportion of different user groups, cpue, retention rates, proportion of undersized fish, number of patrols and annual estimates (e.g. total fishing effort and total catch). Results are fed into the adaptive management loop and used to guide management interventions and identify further research questions (Figure 2). For example, monitoring highlighted a large proportion of undersized fish being retained, and as a result, research is being conducted regarding the drivers of angler behaviour and non-compliance, while management increased its emphasis on law enforcement. Similarly, poor angler awareness and knowledge of fishery regulations resulted in management interventions, including the development of illustrative and locally relevant fishery signboards, pocket field guides and brochures. The influence of these interventions is currently being re-assessed on a 5-year basis.

Currently, the monitoring programme is in partial compliance with the desired resource use monitoring system. The impact on the targeted populations and biodiversity is less well covered and, in particular, social and economic indicators need to be developed in collaboration with the local anglers. Future research and monitoring should strengthen the interdisciplinary nature of the work, with the aim of gaining greater understanding on how recreational and subsistence fisheries respond to socio-ecological change. Of particular importance is further engagement with local fishermen and enabling their input into the monitoring framework and future refinements. This is a challenge as most anglers do not belong to a club and, in particular, subsistence fishermen are not well organised or represented.