Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-13T00:39:20.974Z Has data issue: false hasContentIssue false

Transnational research for coastal wetlands conservation in a Cuba–US setting

Published online by Cambridge University Press:  15 July 2020

Victoria C. Ramenzoni*
Affiliation:
Department of Human Ecology, Rutgers University, The State University of New Jersey, 211 Cook Office Building, 55 Dudley Road, New Brunswick, NJ08901-8520, USA
Mark R. Besonen
Affiliation:
Harte Research Institute for Gulf of Mexico Studies, Texas A&M University-Corpus Christi, Corpus Christi, TX78412, USA
David Yoskowitz
Affiliation:
Harte Research Institute for Gulf of Mexico Studies, Texas A&M University-Corpus Christi, Corpus Christi, TX78412, USA
Vanessa Vázquez Sánchez
Affiliation:
Museo Antropológico Montané, Universidad de La Habana, Havana, Cuba
Armando Rangel Rivero
Affiliation:
Museo Antropológico Montané, Universidad de La Habana, Havana, Cuba
Patricia González-Díaz
Affiliation:
Centro de Investigaciones Marinas, Universidad de La Habana, Havana, Cuba
Armando Falcón Méndez
Affiliation:
Parque Nacional Caguanes, Servicio Nacional de Áreas Protegidas, Sancti Spíritus, Cuba
Daily Borroto Escuela
Affiliation:
Parque Nacional Caguanes, Servicio Nacional de Áreas Protegidas, Sancti Spíritus, Cuba
Idania Hernández Ramos
Affiliation:
Parque Nacional Caguanes, Servicio Nacional de Áreas Protegidas, Sancti Spíritus, Cuba
Norgis Valentín Hernández López
Affiliation:
Parque Nacional Caguanes, Servicio Nacional de Áreas Protegidas, Sancti Spíritus, Cuba
Larry McKinney
Affiliation:
Harte Research Institute for Gulf of Mexico Studies, Texas A&M University-Corpus Christi, Corpus Christi, TX78412, USA
*
Author for correspondence: Dr Victoria C. Ramenzoni, E-mail: victoria.ramenzoni@rutgers.edu

Non-technical summary

Sharing information between different countries is key for developing sustainable solutions to environmental change. Coastal wetlands in the Gulf of Mexico are suffering significant environmental and human-related threats. Working across national boundaries, this research project brings together scientists, specialists and local communities from Cuba and the USA. While important advances have been made in strengthening collaborations, important obstacles remain in terms of international policy constraints, different institutional and academic cultures and technology. Overcoming these limitations is essential to formulating a comprehensive understanding of the challenges that coastal socioecological systems are facing now and into the future.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - SA
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike licence (http://creativecommons.org/licenses/by-nc-sa/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the same Creative Commons licence is included and the original work is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use.
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

1. Introduction

In July 2015, after more than 50 years of strained bilateral relations, the USA resumed diplomatic ties with Cuba. The announcements were followed by modifications in travel sanctions and the opening of embassies in both countries. The optimism inspired by these changes was short lived, as many of the new policies would be reversed during the Trump Administration. However, this brief period of interaction, coupled with more relaxed license requirements related to educational and research exchanges, created an unprecedented opportunity for US-based scientists to engage with Cuban counterparts. While tourism activities in Cuba remain prohibited for American citizens and anyone subjected to US federal jurisdiction, the thawing of relationships between both countries has favoured a rapid increase in visits to the island (Guttman, Reference Guttman2016; Lieberman, Reference Lieberman2017). This surge in the demand for recreational services has produced significant pressures on natural habitats (García et al., Reference García, Rodríguez, Peña, Panosso Netto and Trigo2015; Salazar, Reference Salazar2016). In order to anticipate and mitigate impacts, the government has begun a process of reviewing environmental policies and regulations on protected areas. Much remains to be done for wetlands, coastal lagoons and marine habitats that, excluded in the past, have become hotspots for tourism. In this article, we describe an initiative of transnational scientific collaboration between both countries for the protection of coastal wetlands and explore the main lessons drawn from these efforts.

In 2017, a team of researchers from the Harte Research Institute for Gulf of Mexico Studies at Texas A&M University-Corpus Christi, Montané Anthropological Museum and the Center for Marine Research, both at Universidad de La Habana, joined specialists from Caguanes National Park (CNP) and local community members from La Picadora and Yaguajay, Sancti Spíritus, in two 3-day-long workshops. The park sits south of Florida and the Old Bahama Channel, a few hundred kilometres off the south-eastern border of the Gulf of Mexico Large Marine Ecosystem (Yáñez-Arancibia & Day, Reference Yáñez-Arancibia and Day2004). Due to its unique geographical position, it constitutes an important corridor for the migration of biodiversity between the Gulf and the Caribbean seas. It is also a sentinel location for anticipating, comparing and understanding a wide range of impacts associated with environmental and anthropogenic stressors on coastal and marine habitats. Threats such as progressive climatic aridification and exposure to extreme events are already affecting the CNP as well as other wetland ecosystems in the Gulf (Dahl & Stedman, Reference Dahl and Stedman2013; Day et al., Reference Day, Yáñez-Arancibia, Vásquez, Arzapalo, Baltz and Banda2013). In fact, important similarities can be established between the hypersaline conditions predominating in the CNP and the Laguna Madre system in southern USA and northern Mexico. These similarities enable the transfer of study findings and management strategies across sites (Figure 1). With that goal in mind, the main purposes of these collaborative exchanges were to share knowledge and experiences, to identify current and future environmental threats to biological and human communities in these locations and to develop a common programme of research that might directly enhance coastal wetland conservation in the region at large.

Fig. 1. Map of the Gulf of Mexico and the two research sites. Site A is Caguanes National Park. Site B is the Laguna Madre ecosystem.

Connected by the currents of the Gulf of Mexico, Cuba, Mexico and the USA are reciprocally impacted by their coastal management and conservation practices (McKinney, Reference McKinney2017b). Because of these interdependencies, the development of successful responses to pressing socioecological issues in the Gulf needs to build on the complementarity of research efforts in a way that can overcome knowledge fragmentation and chart a unified course of action (Cundill et al., Reference Cundill, Roux and Parker2015; Roman, Reference Roman2018). Many of the challenges that threaten wetlands in Cuba (e.g., diminished freshwater inflow into bays, increasing extreme events such as rapidly intensifying hurricanes, extreme precipitation and drought events) or that the country may face in the future (e.g., fishing pressure, sea-level rise, extreme salinization) are issues that US and Mexican scientists have been working on for a number of years across coastal environments of the Gulf. Conversely, the way in which Cuba has proposed to tackle the long-term impacts of climate change through state-led programmes such as Tarea Vida, how it has effectively and promptly responded to extreme events (e.g., preparedness, mitigation and recovery) and how it has developed participatory grass-root solutions to address sustainability in a holistic approach are some among the many lessons that can be transferred to a wider Gulf scenario.

Transnational studies represent the scientific collaboration of different partners towards the attainment of a common goal. Defined as a complementary effort across multiple countries, transnational research rests on the creation of a network that can facilitate the circulation of knowledge, people and practices (Tripodi & Potocky-Tripodi, Reference Tripodi and Potocky-Tripodi2006; Turchetti et al., Reference Turchetti, Herran and Boudia2012). This type of collaboration can offer unique insights for the sustainable management and restoration of threatened ecosystems that is essential for the creation of new knowledge (Iaria et al., Reference Iaria, Schwarz and Waldinger2018; Stamm & Figueroa, Reference Stamm and Figueroa2012). Through coordinated yet comparative place-based studies, a cooperative transnational approach can foster a synoptic understanding of the cross-scale dynamics that characterize socioecological systems (Balvanera, Calderón-Contreras et al., Reference Balvanera, Calderón-Contreras, Castro, Felipe-Lucia, Geijzendorffer, Jacobs and Gillson2017; Castro et al., Reference Castro, Quintas-Soriano, Brandt, Atkinson, Baxter, Burnham and Norström2018; Massey, Reference Massey2005). Furthermore, as points of intersection of the global and the local, transnational projects that build on processes of knowledge co-construction may lead to the joint development of long-term regional solutions (Cundill et al., Reference Cundill, Roux and Parker2015; Mateos & Suáraz, Reference Mateos and Suáraz2016).

Despite its many contributions, transnational research is not devoid of conflict (Balvanera, Daw et al., Reference Balvanera, Daw, Gardner, Martín-López, Norström, Ifejika Speranza and Perez-Verdin2017; Barahona, Reference Barahona2015; Cundill et al., Reference Cundill, Roux and Parker2015; Pohl, Reference Pohl2008; Walker, Reference Walker2012). Tensions can originate in the sociopolitical contexts in which practice occurs and when different agendas and interests intersect. These conflicts, if left unresolved, can result in significant impediments to the sharing of financial, institutional and educational resources (Moyi Okwaro & Geissler, Reference Moyi Okwaro and Geissler2015; Munung et al., Reference Munung, Mayosi and de Vries2017; Walker, Reference Walker2012; Wang, Reference Wang2010). Most importantly, issues may also emerge in the translation of findings, in the formulation of a common vision and in the maintenance of dialogue (Caniglia et al., Reference Caniglia, Luederitz, Groß, Muhr, John, Withycombe Keeler and Lang2017; Martin & Griffiths, Reference Martin and Griffiths2012; Moyi Okwaro & Geissler, Reference Moyi Okwaro and Geissler2015). In order to understand the origins of these obstacles to collaboration, transnational research needs to be placed within broader debates about transdisciplinary knowledge production, stakeholders’ participation and sustainability in socioecological transformations (Fazey et al., Reference Fazey, Moug, Allen, Beckmann, Blackwood, Bonaventura and Wolstenholme2018a, Reference Fazey, Schäpke, Caniglia, Patterson, Hultman, van Mierlo and Wyborn2018b; Hegger & Dieperink, Reference Hegger and Dieperink2015). Within this context, transdisciplinary practices not only require working at the interfaces of different value systems, institutional cultures and epistemologies of power, but also require the ability to anticipate possible outcomes among a growing number of stressors as societies plan for their future (Iwaniec et al., Reference Iwaniec, Cook, Davidson, Berbés-Blázquez, Georgescu, Krayenhoff and Grimm2020; Kopp et al., Reference Kopp, Gilmore, Little, Lorenzo-Trueba, Ramenzoni and Sweet2019; Sharpe et al., Reference Sharpe, Hodgson, Leicester, Lyon and Fazey2016). Their success may rely on being able to balance different rates of change over a long time horizon, a process that necessarily builds, at the international level, on continuous dialogue and collaboration across different governance structures (Fröcklin et al., Reference Fröcklin, Jiddawi and de la Torre-Castro2018; Stamm & Figueroa, Reference Stamm and Figueroa2012).

Like many other international initiatives, most Cuba–US scientific collaborations exhibit a long history of persistence, but also of fragmentation (Anthes et al., Reference Anthes, Robock, Antuña-Marrero, García, Braun and Arredondo2014; Fink et al., Reference Fink, Leshner and Turekian2014; Pastrana, Reference Pastrana2015; Pastrana & Clegg, Reference Pastrana and Clegg2008; Roman, Reference Roman2018). Few of these projects have translated to concrete actions given the many challenges to sustaining cooperation over changing political and economic scenarios. In the next few sections, we explore some of the advantages and obstacles that result from research collaborations between both countries. Comparing this particular case study to other efforts in the region, we contextualize the initial challenges and benefits. The findings are of unusual value given the limited availability of information regarding the recovery of endangered wetland ecosystems in Cuba as well as the coastal restoration methods that are being used. As a testament to its importance, the project has been included in Cuba's Sixth National Report on the Convention of Biological Biodiversity as part of goal number 1 of the Aichi Biodiversity Targets.

2. Caguanes National Park

The CNP was created in 2001 to protect one of the most uncommon karstic landscapes in the Gulf of Mexico and the Caribbean. Located within the Buenavista Biosphere Reserve in the central provinces of Sancti Spíritus, Villa Clara and Ciego de Ávila, the park extends over the northern floodplains of the Guayaberas swamp, the Llanura Corralillo-Yaguajay and several smaller keys known as Los Cayos de Piedra (Figure 2) (Alcolado et al., Reference Alcolado, García and Arellano Acosta2007; Domínguez González et al., Reference Domínguez González, Torres Martínez and Puerta de Armas2012). Approximately 70% of the 20,490 ha of the CNP are within shallow marine areas between 1 and 4 m deep. Vast meadows of marine seagrasses from the Thalassia, Syringodium and Halodule genera cover the muddy bottoms (Martinez-Daranas et al., Reference Martínez-Daranas, Perdomo López and Guimarais Bermejo2015). The remaining 30% of the park can be described as a marginal marine zone, a transitional area of coastal low plains, littoral marshes, seasonal lagoons, mangrove forests and freshwater swamps (Lahera et al., Reference Lahera, Morgado, González and Silva2007). Home to several endangered species (i.e., Royal palm, Roystonea regia), the park has been designated as a Ramsar site (Alcolado et al., Reference Alcolado, García and Arellano Acosta2007; Martínez-Daranas et al., Reference Martínez-Daranas, Perdomo López and Guimarais Bermejo2015).

Fig. 2. Caguanes National Park, central Cuba.

Several rural communities live in close proximity to the boundaries of the CNP. Historically, these communities were centres of production of the sugarcane industry (Domínguez González et al., Reference Domínguez González, Torres Martínez and Puerta de Armas2012; Funes Monzote & Martin, Reference Funes Monzote and Martin2008). With a population exceeding 55,000 inhabitants, Yaguajay is the head of the district and houses the administrative offices of the CNP (ONEI, 2018). The region experienced low anthropogenic impacts until the second half of the nineteenth century when sugar production intensified and hundreds of hectares of swamps and forests were drained or deforested to facilitate the cultivation of cane (Acosta Rodríguez, Reference Acosta Rodríguez, Domínguez González, Torres Martínez, G and Armas2012; Hernández Ramos & Perdomo González, Reference Hernández Ramos, Perdomo González, Domínguez González, Torres Martínez and Puerta de Armas2012). In the early 2000s, following the collapse of the Soviet Union in the previous decade, the government deactivated local sugar mills in Yaguajay and introduced large-scale livestock operations (Altieri & Funes-Monzote, Reference Altieri and Funes-Monzote2012; Díaz-Briquets & Pérez-López, Reference Díaz-Briquets and Pérez-López2000). The government also committed the area of the Santa Maria cays for the development of international tourism.

Over the past 15 years, the administration of the park has begun to recover wetland habitats (Carrera Menéndez, Reference Carrera Menéndez2013; Carrera Menéndez et al., Reference Carrera Menéndez, Guzmán and Priego2006, Reference Menéndez, Guzmán, Gómez Fernández, Capote-Fuentes, T and Rodríguez Farrat2007; Llanes-Regueiro, Reference Llanes-Regueiro2007). Following the adoption of a sustainable development framework at the national level in the early 1990s, the country has spearheaded the decentralization of spatial organization to municipal governments (Boffill Vega, Reyes et al., Reference Boffill Vega, Reyes, Carmona and Díaz2009). This action has had important repercussions for the success of conservation efforts in Yaguajay (Boffill Vega, Calcines Díaz & Sánchez Cid, Reference Boffill Vega, Calcines Díaz and Sánchez Cid2009; Pérez Hernández et al., Reference Pérez Hernández, Rodríguez Otero, Roig Piquero, Abreu Tamayo, Boquet Roque and Favier González2001; Zulueta Acea & Boffill Vega, Reference Zulueta Acea and Boffill Vega2014). Territorial reorganization has led to the implementation of an integrated environmental strategy that focuses on the control of extractive practices, the protection of natural resources and the restoration of degraded habitats by equally weighing social, ecological and economic concerns (Caraballo Yera, Reference Caraballo Yera, Domínguez González, Torres Martínez, G and Armas2012; Méndez Herrera & Sánchez Cid, Reference Méndez Herrera and Sánchez Cid2011). Significant emphasis is placed on fostering local networks through regional economies and technological innovation while continuing environmental reforestation efforts (Driggs-Fuentes, Reference Driggs-Fuentes2015, McCune et al., Reference McCune, González, Alcántara, Martínez, Fundora, Arzola and Hernández2011; Patel & Brogan, Reference Patel and Brogan2017).

While reforestation and careful management have helped reconstitute ecosystems to successful levels (Borrego Díaz, Reference Borrego Díaz2014; Escambray, Reference Escambray2017), these habitats also face pressures from urban development and climate change. Alterations in precipitation and temperature regimes, sea level and coastal morphology and in the intensity and frequency of extreme events have already been observed (Planos Gutiérrez et al., Reference Planos Gutiérrez, Rivero Vega and Guevara Velazco2012). In late 2017 and early 2018, the park suffered critical damage from Hurricane Irma and Tropical Storm Alberto that resulted in the loss of 4000 ha of mangroves. In addition to more frequent flooding and drought episodes, the CNP is preparing for substantial losses in hydrological resources that may approximate 38% for central Cuba by 2100 (Batista Ponvert-Delisles, Reference Batista Ponvert-Delisles2016; Planos Gutiérrez, Reference Planos Gutiérrez2014). The combination of future climatic scenarios with anthropogenic pressures tied to the developing tourism industry, agriculture and the expansion of cattle ranching could further aggravate conditions. This synergy of vulnerabilities represents a cautionary yet recurring tale for other wetland systems in the Gulf of Mexico (Dahl & Stedman, Reference Dahl and Stedman2013).

3. Methodology

Initial exchanges took place in La Picadora and in the offices of the CNP in Yaguajay in February and May of 2017. The main goals of the two workshops were to share knowledge and experiences in the protection of wetlands, to identify current and future environmental threats to biological and human communities in these locations and to develop a common programme of research that might potentially enhance wetland conservation in the larger Gulf region. At the beginning of each workshop, participants ranging from local community leaders to scientific experts conducted a series of presentations on the conditions of the park. Then, researchers facilitated conversations through guided discussions and work sessions regarding specific threats to the CNP habitats. During the first meeting, with the help of a map of the area, participants constructed a timeline of changes and singled out key zones that were affected. In the second workshop, discussions were guided towards establishing research and management priorities and to further exploring changes in wetlands. This approach to data sharing and collection stimulated conversations and resulted in an increased awareness of current climate risks (Bretos et al., Reference Bretos, Ricardo Azanza, Moncada, Peckham, Angulo Valdés, Diego and Thompson2017; Karr et al. Reference Karr, Fujita, Carcamo, Epstein, Foley, Fraire-Cervantes and Kritzer2017). Interactions were captured by two note takers. The programme, while focused on Caguanes’ coastal habitats, can help identify management actions and develop best practices that are transferable to other scenarios. February and May workshops consisted of 34 and 37 participants, respectively, including local farmers, park authorities and research specialists, community leaders, conservationists, scientists and resource managers from the area.

4. Outcomes and results

As direct outcomes of the workshops, participants agreed on a common set of research interests, management priorities and extension activities. In this article, we concentrate on presenting the three major lessons that resulted from these meetings: the identification of threats to wetlands and coastal lagoons; insights from sharing of knowledge and experiences of conservation; and the exploration of the challenges to continued collaboration.

4.1. Getting to know current and future threats

During workshops, participants identified some of the current and future threats that the CNP wetland habitats are experiencing in relation to environmental and anthropogenic change. Comparisons were drawn between conditions in the park and other lagoon environments in the Northern Gulf of Mexico such as the Laguna Madre ecosystem. Extending 445 km along the coasts of Tamaulipas, Mexico, and Texas in the USA, the Laguna Madre is the only hypersaline lagoon system in North America (Figure 3) (Day et al., Reference Day, Yáñez-Arancibia, Vásquez, Arzapalo, Baltz and Banda2013; Yáñez-Arancibia & Day, Reference Yáñez-Arancibia and Day2004). Similarities between the CNP and the Laguna Madre systems are numerous, including the prevalence of shallow coastal lagoons with high levels of salinity (more than 35 parts per thousand), limited freshwater inflow due to reduced water sources, dominance of semiarid conditions (low precipitation, high evaporation and high temperatures) and high exposure to extreme events (droughts and tropical storms). Also characterized by highly productive seagrass meadows and fisheries and constituting essential habitats for bird colonies, both systems have been impacted by intense anthropic modifications, non-point source runoff and agricultural pollution (Smith et al., Reference Smith, Banda, Tunnell, Withers, Day, Yáñez-Arancibia, Vásquez, Arzapalo, Baltz and Banda2013). Through presentations and discussions, the exchange of knowledge about these environments resulted in a more integral picture of stressors, pressures and impacts. Critical threats to wetlands and coastal lagoons include water quality, coastal development and more frequent and intense extreme events.

Fig. 3. Laguna Madre ecosystems, Tamaulipas, Mexico, and Texas, USA.

4.1.1. Water quality issues, pollution and eutrophication processes

Participants indicated that activities related to farming, waste management and industrial practices are affecting water quality in both systems with important consequences for biodiversity. For example, low concentrations of dissolved oxygen are found in all monitoring sites within the CNP as reported by park personnel. Some of these results are attributed to the use of chemical fertilizers and to the discharge of other contaminants suggesting eutrophication processes. The pollution of coastal areas has led to the degradation of near-shore habitats, including soft-bottom environments where large beds of seagrasses grow. This has been also reported in the Laguna Madre system where low ratios of seagrass to unvegetated bottoms and changes in vegetation composition are now seen in several locations (Smith et al., Reference Smith, Banda, Tunnell, Withers, Day, Yáñez-Arancibia, Vásquez, Arzapalo, Baltz and Banda2013). Impacts to seagrass integrity has affected aquatic biodiversity, with fishermen reporting a decrease in abundance and size of captured fish in the CNP, as well as modifications in the diversity of extant species. The channelling of rivers and freshwater streams for irrigation and changes in precipitation patterns have also altered water quality levels by modifying freshwater discharge regimes. This is observed along the estuaries and lagoons of the CNP, which have now become hypersaline for larger portions of the year. A similar process is seen in several locations of the Laguna Madre ecosystem, where poor agricultural practices have limited natural water flow through the systems. Reduced inflows combined with high evaporation rates have increased the residential time of water in lagoons (Smith et al., Reference Smith, Banda, Tunnell, Withers, Day, Yáñez-Arancibia, Vásquez, Arzapalo, Baltz and Banda2013). Finally, water quality issues have also been linked to brown tides in the Laguna Madre and potentially to red tides in the CNP. While the causes of these events are not completely understood, research suggest that climatic conditions play a role in triggering these occurrences. Although control of algae blooms is challenging, preserving the ecological integrity of shallow habitats is essential to maintaining biodiversity. With this purpose, participants agreed that mapping, protection and restoration of seagrass habitats should be priorities in future research and conservation efforts.

4.1.2. Coastal development alterations

In past decades, engineering work, such as the construction of a causeway close to the CNP and in multiple sites of the Laguna Madre, has altered the natural hydrology of these ecosystems. The closing of lagoons to the influx of fresh tidal water has not only resulted in higher salinity in estuaries, but may also have produced changes in currents, in sediment transport and deposition and in shorelines. Other modifications discussed were related to the reconversion and filling of tidal lands such as marshes. For example, in the 1980s, a hotel was built on the waterfront of Playa Vitoria in Yaguajay along with a beach and a pier. The site is now abandoned due to subsidence. Likewise, along the coasts of the Northern Gulf, saltmarshes have been impacted considerably by rising sea levels and by their conversion to upland uses (Dahl & Stedman, Reference Dahl and Stedman2013). Urban and rural development have also produced the encroachment of freshwater marshes, mangroves and swamp forests. Large tracts of land now remain deforested, providing scarce protection from insolation and increasing temperatures. The loss of transitional and riparian areas has exposed upland freshwater marshes to tidal inundations. Elevated levels of salt in soils have caused plant desiccation and exacerbated water stress.

4.1.3. Extended droughts and hurricanes

The prevalence of drought conditions and their effects on local agricultural practices were also mentioned by participants as sources of concern (see Figure 4 for a chronology of most recent changes in Caguanes). For instance, in 2016–2017, prolonged drought prevented farmers from Yaguajay from planting rice and damaged other crops such as maize and beans. In addition to agricultural impacts, reduced freshwater availability provoked the loss of livestock due to heat stress. The period of extensive drought concluded with the arrival of Hurricane Irma in September 2017. The CNP experienced massive damage to vegetation, with up to 80% tree blowdown. The associated increase in precipitation brought by unusually strong cyclonic seasons led to massive flooding in 2017 and 2018. Similar conditions were experienced in the Northern Gulf with the passage of Hurricane Harvey in late August 2017. Reports showed values exceeding 1530 mm of rainfall in areas of south-central Texas (Samenow, Reference Samenow2017).

Fig. 4. Chronological timeline of major events. CNP = Caguanes National Park.

Whereas evidence indicates that coastal and marine environments in the Caribbean and in the Gulf of Mexico have regularly suffered from the action of cyclonic activity in the past few centuries (Wallace et al., Reference Wallace, Donnelly, Hengstum, Wiman, Sullivan, Winkler and Albury2019; Pulwarty et al., Reference Pulwarty, Nurse and Trotz2010), projections indicate a likely increase in their occurrence and strength through the end of the current century (FAO, 2019; Taylor et al., Reference Taylor, Clarke, Centella, Bezanilla, Stephenson, Jones and Charlery2018). In the Laguna Madre, drought conditions have been shown to alternate with hurricanes and tropical storms, resulting in large systemic effects that may ultimately stimulate biological productivity (Smith et al., Reference Smith, Banda, Tunnell, Withers, Day, Yáñez-Arancibia, Vásquez, Arzapalo, Baltz and Banda2013; Yáñez-Arancibia et al., Reference Yáñez-Arancibia, Day and Reyes2013). Dry–wet alternations are represented as decadal cycles of boom and bust where additional precipitation from hurricanes produces a flushing of the system. Yet, climate alterations such as rapidly intensifying storms or the progressive aridification of climatic regimes may create imbalances in the functioning of these dynamics. In order to develop adequate preparedness measures, participants agreed that it was essential to formulate an understanding of each ecosystem's responses to the new pressures and the different trajectories of recovery. Including precautionary and adaptive management approaches into current restoration and conservation efforts at the CNP was also seen as an immediate priority to be addressed in future activities.

4.2. Sharing knowledge and experiences of conservation

Discussions and interactions provided the opportunity for participants to observe the similarities in the threats experienced by the CNP and the Laguna Madre ecosystems. Many were surprised to discover that, despite showing different levels of impact, neither system remained a stranger to the intense landscape modification processes that accelerated the effects of climate change. Already familiar with some of the actions and policy instruments implemented by the USA, much remained to be known about Cuba's marine-environmental policy framework. In this way, US-based researchers learned about the many efforts and mechanisms put in place by Cuban institutions to foster the restoration and sustainable use of resources through educational outreach and hands-on community participation. For example, reforestation programmes involve representatives from local youth organizations who work in coordination with the CNP and other government agencies. Similarly, researchers at the Montané Anthropological Museum and the Center for Marine Research are part of Universidad de La Habana's Local Development Network. The network, which has included the community of La Picadora since 2013, offers a framework to study, analyse and promote academic participation in local development processes connecting society with higher education, knowledge, technology and innovation. Both instances demonstrate the advanced degree of institutionalization that collaborative mechanisms have within Cuba. In all, they make visible differences in each country's model of sustainability.

For instance, Cuba acknowledges the need to subordinate economic development to a more humanistic, equitable and inclusive approach that places people at the centre of all initiatives (Cabello et al., Reference Cabello, Garcia, Sagastume, Priego, Hens and Vandecasteele2012). This belief has led the country to include new legislation in its 2019 constitution that explicitly addresses climate change threats. Yet, even before this explicit commitment, the island has implemented aggressive long-term adaptation programmes, as well as large-scale changes in production systems. These efforts are based on the recognition that, along with different experiences of change, each community of knowledge espouses different views of sustainability along with capacities to anticipate future outcomes (Iwaniec et al., Reference Iwaniec, Cook, Davidson, Berbés-Blázquez, Georgescu, Krayenhoff and Grimm2020). For example, while scientists equate the restoration of degraded wetlands through reforestation with autochthonous species, resource managers and local farmers anticipate the difficulties that such a programme entails (e.g., slower rates of maturation and success than other more resilient but foreign species). Whereas scientists, resource managers and local entrepreneurs see the value of carefully constraining access to CNP habitats by fostering selective practices of ecotourism, some residents wish for the return to more prosperous times when sugarcane cultivation was still prevalent. Noticing this diversity in opinions, after some discussion, participants agreed that, in order to develop strategies that might work over the long term, it is key to attain the active involvement of a wider set of actors not only in the solution, but also in the diagnosis and study of environmental issues (Caniglia et al., Reference Caniglia, Luederitz, Groß, Muhr, John, Withycombe Keeler and Lang2017). As a way to achieve this goal, participants proposed an inclusive framework for sustainability that recognizes the differences in development models between both countries and can learn from them. Strengthening and supporting local networks, fostering the co-production of diverse kinds of knowledge and prioritizing the extension of findings to the larger community are some of the main strategies adopted. In addition, a critical part of this effort lies in the scoping of future scenarios and in the identification of transformative pathways that can lead to sustainable yet equitable outcomes (Fazey et al., Reference Fazey, Schäpke, Caniglia, Patterson, Hultman, van Mierlo and Wyborn2018b). Along with capacity development, this task has become the priority of subsequent meetings and workshops.

4.3. Challenges and obstacles

We observed three sets of challenges in advancing transnational cooperation. Similar to other transnational efforts, obstacles were related to international policy constraints, different institutional and academic cultures and technological obstacles that make communication difficult (Anthes et al., Reference Anthes, Robock, Antuña-Marrero, García, Braun and Arredondo2014; Fink et al., Reference Fink, Leshner and Turekian2014; Pastrana, Reference Pastrana2015; Roman, Reference Roman2018). In terms of the first challenge, the rapid change in the status of relations between Cuba and the USA due to actions of the Trump Administration poses real impediments to transnational cooperation. Despite regulatory provisions that exclude scientific efforts from most US-enforced restrictions, practical issues on how these policies are implemented limit the kinds of collaboration that can be pursued with Cuban scientists. The removal of non-essential personnel from the US embassy in Havana and the closing of consular divisions that are responsible for the processing of visas to visit the USA impede Cuban colleagues from obtaining required travel documents at home. Because they are now required to apply and wait for the issuance of these permits from a third country (e.g., Colombia or México), travel costs increase. Without certainty that visas will be approved and given important financial and legal restrictions that limit US support for Cubans travelling abroad, there are strong disincentives for scholarly visits to the USA. This creates an asymmetry in how relationships are established between research parties, eliminating specific areas of collaboration that include reciprocal academic and educational exchanges.

Other less practical but equally significant issues further restrict transnational scientific cooperation. The tenor of political rhetoric has once again assumed a negative tone that undermines the many efforts directed at building trust among both nations (McKinney, Reference McKinney2017a). US university bureaucrats become suspicious and afraid of engaging with a partner who is listed as being in a sanctioned country (Roman, Reference Roman2018). Likewise, Cuban counterparts see their paperwork increase at the prospect of receiving American visitors. In this context, navigating the many cultural differences and regulation challenges that exist between academic policies and legal frameworks becomes increasingly difficult. Collaboration only works through the commitment of involved people, the strength of personal relationships and dedication to sustaining a mutual understanding that can prevent missteps (Pastrana, Reference Pastrana2015). For example, an important difference exists in university regulations concerning the timing and manner of funding applications. In the USA, given the delay that mediates the submission of a research proposal and the awarding of financial support, it has become increasingly common to prioritize the solicitation of funding over the request of research permits. This is the opposite of what occurs in Cuba, where funding can only be pursued once all authorizations from relevant government offices (e.g., the Ministry of Higher Education) have been secured. Whereas this institutional regulation ensures that much-needed provisions are in place before starting research, it can affect the capacity to collaborate over distance, as monetary and human resources for exploratory activities are subject to a limited budget.

The final challenges that this case study shows are related to technological barriers to cooperation. Differences in technical infrastructure and availability of broadband connectivity affect communications between partners and limit the types of research that can be conducted (Anthes et al., Reference Anthes, Robock, Antuña-Marrero, García, Braun and Arredondo2014; Marrero et al., Reference Marrero Antuña, Miller, Mattioli, Feaux, Anthes, Braun, Wang and Robock2014). The US embargo against Cuba, which began in 1960, only permits the export of agricultural and medical goods to the island nation. While Cuba has established trade relations with other countries such as China and Russia, US scientists are forbidden from engaging in the transfer of technological assets such as computers and of proprietary software and datasets. Prohibitions not only complicate the exchange, sharing and storage of study-related data, but also the pursuit of project activities that support local capacity development such as mapping and geospatial analysis and the sampling, processing and documentation of biodiversity.

5. General discussion and conclusion: building a sustainable approach for coastal wetlands protection

This article presents initial results from an ongoing transnational research project between the USA and Cuba for the conservation of coastal wetlands in the CNP, Sancti Spíritus, Cuba. Focusing on the first two exchanges among scientists, resource managers and local communities, it discusses key outcomes from this collaboration. Efforts have resulted in the socialization of knowledge and the identification of gaps in information and capacity. Initial workshops were followed by several training and educational exchanges, numerous participations in conferences and regional meetings, the signing of official agreements of cooperation and several peer-reviewed articles. The collaboration continues and has expanded to incorporate Mexican-based institutions. Beyond language and participation barriers, a common understanding has begun to emerge in terms of shared challenges to the conservation of coastal wetlands.

In all, lessons from these two initial exchanges converge with findings from different studies of transdisciplinary collaboration. They show that working together towards future sustainability can help broaden participants’ knowledge bases, foster dialogue and increase reflexivity among researchers, practitioners and stakeholders (Boon et al., Reference Boon, Chappin and Perenboom2014; Hegger & Dieperink, Reference Hegger and Dieperink2015; Iwaniec et al., Reference Iwaniec, Cook, Davidson, Berbés-Blázquez, Georgescu, Krayenhoff and Grimm2020). For example, the comparison between the Caguanes and Laguna Madre ecosystems has allowed participants to identify a synergy of anthropogenic and climate-related vulnerabilities impacting coastal habitats. The interconnected nature of many of the transformations suffered by wetlands has led to the realization that an integrated transboundary vision that can advance regional strategies for adaptation is urgently needed (Yáñez-Arancibia et al., Reference Yáñez-Arancibia, Day and Reyes2013). However, despite a long history of collaborations between Cuba, Mexico and the USA, proposing an integrative conservation approach that would link place-based research in these countries has proved challenging. Significant differences exist in the policy and legal frameworks, which continue to hinder joint efforts. Institutional and technological restrictions prevent establishing an equal partnership by affecting academic and scientific exchanges and knowledge co-production.

Comparative studies of transnational efforts have underscored that, along with important benefits, any kind of collaboration involves trade-offs, obstacles and risks. Where political systems and legal and institutional frameworks differ, the success of cooperation is affected by the distinct modes of governance exhibited by each country (Berkman, Reference Berkman2011; National Research Council, 2012; Stamm & Figueroa, Reference Stamm and Figueroa2012). Trade-offs must be made between including and excluding partners, and complexity increases as the number of participant institutions grows. In this context, any scientific undertaking must reconcile not only divergences in how natural resources are managed and protected within each nation, but also be able to navigate across different priorities, agendas and research approaches. Obstacles are, as a consequence, a normal outcome of working across diverse institutional settings.

Yet, as this case study shows, while agreements can be made at higher levels that indicate commitment to a unified goal, researchers must still struggle with rules for things such as technology sharing, public–private partnerships and data publication. This exposes participants to a complex set of challenges with considerable personal risks in terms of rigorous sanctions that go beyond professional careers. The potential for failure is high when parties are constrained from finding a common ground by bureaucratic structures (Stamm & Figueroa, Reference Stamm and Figueroa2012). In these scenarios, if no mechanisms are in place to maintain connections and despite the many incentives to collaborate, participants may discontinue their involvement (National Research Council, 2012). The situation is congruent with what we have observed in our collaboration where continued work has been achieved only at the expense of many sacrifices and through strong personal ties. It also helps explain the fate of other bilateral initiatives. In short, these obstacles, which are mostly political in nature, deprive countries from interactions that could benefit the scalability of research findings to other biodiversity conservation activities in the region (Roman, Reference Roman2018).

As societies recognize that their futures rely on working together, it is critical that we strengthen transnational efforts to enhance knowledge sharing and collaboration in problem-solving (Dinar, Reference Dinar2011). To that end, we must foster research cooperation mechanisms that are truly inclusive and can overcome the constant reintroduction of an outdated isolationist rhetoric. A truly collaborative agenda requires not only enabling opportunities to build scientific exchanges, but also identifying and working with formal political and normative structures to support rather than restrict the co-production of new knowledge. While most countries still have significant difficulties to overcome in this respect, establishing a complementary approach that can foster a transnational culture of sustainability is dependent upon several steps (Fazey et al., Reference Fazey, Schäpke, Caniglia, Patterson, Hultman, van Mierlo and Wyborn2018b). First and foremost are the fostering of reflexivity and the deconstruction of social, political and economic values, interests and assumptions that can enable informed yet balanced participation. Second is the provision of intermediary spaces that can support the communication, development and implementation of joint solutions focused on sustainable socioecological transformations. Third is the recognition of the contrasts in different development models along with the processes of accepting and learning from these differences. In a world that is rapidly changing beyond our best predictions, a transnational understanding of the complexity of the threats faced by coastal ecosystems in the Gulf is essential for developing precautionary and early warning systems. The devastating impacts from events such as Hurricanes Harvey and Irma have shown us what is at stake. Now we must act.

Acknowledgements

We would like to thank the personnel from Caguanes National Park and residents from La Picadora for participating in these workshops. We would also like to thank the Harte Charitable Foundation for its support.

Author contributions

VCR analysed the data and wrote the manuscript. MRB provided maps. VCR, MRB, DY, VVS, ARR and PG-D conceived and executed the workshops and provided significant comments to the manuscript. AFM, DBE, IHR and NVHL participated in exchanges and provided key corrections to the manuscript at all stages. LM supervised the project.

Financial support

The Harte Charitable Foundation provided financial support for this study.

Conflict of interest

The authors do not have any conflicts of interest to declare.

Publishing ethics

This research and article comply with Global Sustainability's publishing ethics guidelines.

References

Acosta Rodríguez, E. (2012). La asimilación antrópica del territorio: modelos culturales y cambios en el paisaje. In Domínguez González, A. Z., Torres Martínez, M. & G, Y.. Armas, Puerta de (eds), Experiencias en la protección de la biodiversidad y el desarrollo sostenible en la provincia de Sancti Spíritus, pp. 4550. Ministerio de Ciencia, Tecnología y Medio Ambiente.Google Scholar
Alcolado, P. M., García, E. E. & Arellano Acosta, M. (2007). Ecosistema Sabana-Camagüey: Estado actual, avances y desafíos en la protección y uso sostenible de la biodiversidad. Editorial Academia.Google Scholar
Altieri, M. A. & Funes-Monzote, R. (2012). The Paradox of Cuban Agriculture. Monthly Review. Retrieved from https://monthlyreview.org/2012/01/01/the-paradox-of-cuban-agricultureCrossRefGoogle Scholar
Anthes, R., Robock, A., Antuña-Marrero, J. C., García, O., Braun, J. J. & Arredondo, R. E. (2014). Cooperation on GPS Meteorology between the United States and Cuba. Bulletin of the American Meteorological Society, 96(7), 10791088.CrossRefGoogle Scholar
Balvanera, P., Calderón-Contreras, R., Castro, A. J., Felipe-Lucia, M. R., Geijzendorffer, I. R., Jacobs, S., … Gillson, L. (2017). Interconnected place-based social–ecological research can inform global sustainability. Current Opinion in Environmental Sustainability, 29, 17.CrossRefGoogle Scholar
Balvanera, P., Daw, T., Gardner, T., Martín-López, B., Norström, A., Ifejika Speranza, C., … Perez-Verdin, G. (2017). Key features for more successful place-based sustainability research on social-ecological systems: a Programme on Ecosystem Change and Society (PECS) perspective. Ecology and Society, 22(1), 14.CrossRefGoogle Scholar
Barahona, A. (2015). Transnational science and collaborative networks. The case of Genetics and Radiobiology in Mexico, 1950–1970. Dynamis (Granada, Spain), 35(2), 333358.Google Scholar
Batista Ponvert-Delisles, D. (2016). Algunas consideraciones sobre el comportamiento de la sequía agrícola en la agricultura de Cuba y el uso de imágenes por satélites en su evaluación. Cultivos Tropicales, 37(3). Retrieved from https://www.redalyc.org/articulo.oa?id=193246976003Google Scholar
Berkman, P. A. (ed.) (2011). Science Diplomacy: Antarctica, and the Governance of International Spaces. Smithsonian Institution Scholarly Press.Google Scholar
Boffill Vega, S., Calcines Díaz, C. M. & Sánchez Cid, A. (2009). Modelo De Gestión Para Contribuir Al Desarrollo Local, Basado En El Conocimiento Y La Innovación En Cuba. Ingeniería Industrial, XXX(2). Retrieved from https://www.redalyc.org/pdf/3604/360433569007.pdfGoogle Scholar
Boffill Vega, S., Reyes, R., Carmona, F. T., & Díaz, E. S. (2009). Desarrollo local sostenible a partir del manejo integrado en el parque nacional caguanes de Yaguajay. DELOS: Desarrollo Local Sostenible, 2(4), 5.Google Scholar
Boon, W. P. C., Chappin, M. M. H. & Perenboom, J. (2014). Balancing Divergence and Convergence in Transdisciplinary Research Teams. Environmental Science & Policy, 40, 5768.CrossRefGoogle Scholar
Borrego Díaz, J. A. (2014). Andar Caguanes. Retrieved from http://www.granma.cu/cuba/2014-03-28/andar-caguanesGoogle Scholar
Bretos, F., Ricardo Azanza, J., Moncada, F., Peckham, S. H., Angulo Valdés, J. A., Diego, A. & Thompson, K. R. (2017). Fisheries learning exchanges and sea turtle conservation: an effort between Mexico, Cuba and the U.S. to engage Cuban coastal communities in non-consumptive alternative behaviors. Marine Policy, 77, 227230.CrossRefGoogle Scholar
Cabello, J. J., Garcia, D., Sagastume, A., Priego, R., Hens, L. & Vandecasteele, C. (2012). An approach to sustainable development: the case of Cuba. Environment, Development and Sustainability, 14(4), 573591.CrossRefGoogle Scholar
Caniglia, G., Luederitz, C., Groß, M., Muhr, M., John, B., Withycombe Keeler, L., … Lang, D. (2017). Transnational collaboration for sustainability in higher education: lessons from a systematic review. Journal of Cleaner Production, 168, 764779.CrossRefGoogle Scholar
Caraballo Yera, J. A. (2012). El ecoturismo como opción en el Parque Nacional Caguanes. In Domínguez González, A. Z., Torres Martínez, M. & G, Y.. Armas, Puerta de (eds), Experiencias en la protección de la biodiversidad y el desarrollo sostenible en la provincia de Sancti Spíritus, pp. 8083. Ministerio de Ciencia, Tecnología y Medio Ambiente.Google Scholar
Carrera Menéndez, L. M. (2013). El ecosistema de manglar en el archipiélago cubano: bases para su gestión. Doctoral dissertation, Departamento de Ecología, Universidad de Alicante. Retrieved from http://rua.ua.es/dspace/handle/10045/35983Google Scholar
Menéndez, Carrera, Guzmán, L. M., Gómez Fernández, J. M., Capote-Fuentes, R., T, R.. & Rodríguez Farrat, L. (2007). Estado de los ecosistemas terrestres de los cayos. In Ecosistema Sabana-Camaguey. Estado actual, avances y desafios en la proteccion y uso sostenible de la biodiversidad, p. 187. Retrieved from https://www.researchgate.net/profile/Pedro_Alcolado/publication/265379940_Ecosistema_Sabana-Camaguey_Estado_Actual_avances_y_desafios_en_la_proteccion_y_uso_sostenible_de_la_biodiversidad/links/544006b10cf21227a11ba151/Ecosistema-Sabana-Camagueey-Estado-Actual-avances-y-desafios-en-la-proteccion-y-uso-sostenible-de-la-biodiversidad.pdfGoogle Scholar
Carrera Menéndez, L. M., Guzmán, J. M. & Priego, A. (2006). Ecosistema de manglar en el Archipiélago Cubano (UY/2002/SC/ECO/PI/2). Retrieved from http://repositorio.geotech.cu/jspui/bitstream/1234/1315/1/Ecosistema%20de%20manglar%20en%20el%20Archipiélago%20Cubano_Parte1.pdfGoogle Scholar
Castro, A. J., Quintas-Soriano, C., Brandt, J., Atkinson, C. L., Baxter, C. V., Burnham, M., … Norström, A. V. (2018). Applying place-based social-ecological research to address water scarcity: insights for future research. Sustainability, 10(5), 1516.CrossRefGoogle Scholar
Cundill, G., Roux, D. & Parker, J. (2015). Nurturing communities of practice for transdisciplinary research. Ecology and Society, 20(2), 22.CrossRefGoogle Scholar
Dahl, T. & Stedman, S. M. (2013). Status and Trends of Wetlands from 2004 to 2009, p. 46. Retrieved from https://www.scribd.com/document/186127508/Status-and-Trends-of-Wetlands-from-2004-to-2009Google Scholar
Day, J. W., Yáñez-Arancibia, A., Vásquez, H. A., Arzapalo, W. W., Baltz, D. M. & Banda, A. (2013). Gulf of Mexico Origin, Waters, and Biota: Volume 4, Ecosystem-Based Management. Retrieved from https://muse.jhu.edu/book/24556Google Scholar
Díaz-Briquets, S. & Pérez-López, J. F. (2000). Conquering Nature: The Environmental Legacy of Socialism in Cuba. University of Pittsburgh Press.CrossRefGoogle Scholar
Dinar, S. (2011). Beyond Resource Wars: Scarcity, Environmental Degradation, and International Cooperation. MIT Press.CrossRefGoogle Scholar
Domínguez González, A. Z., Torres Martínez, M. & Puerta de Armas, Y. G. (2012). Experiencias en la protección de la biodiversidad y el desarrollo sostenible en la provincia de Sancti Spíritus. Ministerio de Ciencia, Tecnología y Medio Ambiente.Google Scholar
Driggs-Fuentes, R. (2015). Perspectiva integradora del ordenamiento territorial y urbano en los procesos de desarrollo económico local. Retrieved from http://www.ipf.gob.cu/sites/default/files/revista/Perspectiva…%20Rafael.pdfGoogle Scholar
Escambray, (2017). Flora y fauna | Escambray. Periódico de Sancti Spíritus. Cuba. Retrieved from http://www.escambray.cu/especiales/caguanes-entre-la-magia-y-la-aventura/flora-y-faunaGoogle Scholar
Fazey, I., Moug, P., Allen, S., Beckmann, K., Blackwood, D., Bonaventura, M., … Wolstenholme, R. (2018a). Transformation in a changing climate: a research agenda. Climate and Development, 10(3), 197217.CrossRefGoogle Scholar
Fazey, I., Schäpke, N., Caniglia, G., Patterson, J., Hultman, J., van Mierlo, B., … Wyborn, C. (2018b). Ten Essentials for action-oriented and second order energy transitions, transformations and climate change research. Energy Research & Social Science 40: 5470.CrossRefGoogle Scholar
FAO (2019). Impacts of climate change on fisheries and aquaculture: Synthesis of current knowledge, adaptation and mitigation options. FAO Fisheries and Aquaculture Technical Report. Paper 627. Food and Agriculture Organization, United Nations.Google Scholar
Fink, G. R., Leshner, A. I. & Turekian, V. C. (2014). Science diplomacy with Cuba. Science, 344(6188), 10651065.CrossRefGoogle ScholarPubMed
Fröcklin, S., Jiddawi, N. & de la Torre-Castro, M. (2018). Small-scale innovations in coastal communities: shell-handicraft as a way to empower women and decrease poverty. Ecology and Society, 23(2), 34.CrossRefGoogle Scholar
Funes Monzote, R. & Martin, A. (2008). From Rainforest to Cane Field in Cuba: An Environmental History since 1492. Retrieved from https://muse.jhu.edu/book/24019CrossRefGoogle Scholar
García, M. E. B., Rodríguez, M. C. F. & Peña, L. B. (2015). ‘Jardines del Rey’: an integrated a sustainable management of a Cuban touristic destiny. In Panosso Netto, A. & Trigo, L. G. G. (eds), Tourism in Latin America, pp. 143157. Springer.Google Scholar
Guttman, A. (2016). In Cuba, American tourists increase demand for hotels. Retrieved from http://www.pbs.org/newshour/bb/cuba-american-tourists-increase-demand-hotelsGoogle Scholar
Hegger, D. & Dieperink, C. (2015). Joint knowledge production for climate change adaptation: what is in it for science? Ecology and Society, 20(4), 1.CrossRefGoogle Scholar
Hernández Ramos, I. & Perdomo González, F. P. (2012). Calidad del agua en áreas costeras vulnerables del Parque Nacional Caguanes. In Domínguez González, A. Z., Torres Martínez, M. & Puerta de Armas, Y. G. (eds), Experiencias en la protección de la biodiversidad y el desarrollo sostenible en la provincia de Sancti Spíritus, pp. 5056. Ministerio de Ciencia, Tecnología y Medio Ambiente.Google Scholar
Iaria, A., Schwarz, C. & Waldinger, F. (2018). Frontier knowledge and scientific production: evidence from the collapse of international science. Quarterly Journal of Economics, 133(2), 927991.CrossRefGoogle Scholar
Iwaniec, D. M., Cook, E. M., Davidson, M. J., Berbés-Blázquez, M., Georgescu, M., Krayenhoff, E. S., … Grimm, N. B. (2020). The co-production of sustainable future scenarios. Landscape and Urban Planning, 197, 103744.CrossRefGoogle Scholar
Karr, K. A., Fujita, R., Carcamo, R., Epstein, L., Foley, J. R., Fraire-Cervantes, J. A., … Kritzer, J. P. (2017). Integrating science-based co-management, partnerships, participatory processes and stewardship incentives to improve the performance of small-scale fisheries. Frontiers in Marine Science, 4, 345.CrossRefGoogle Scholar
Kopp, R. E., Gilmore, E. A., Little, C. M., Lorenzo-Trueba, J., Ramenzoni, V. C. & Sweet, W. V. (2019). Usable science for managing the risks of sea-level rise. Earth's Future, 7(12), 12351269.CrossRefGoogle ScholarPubMed
Lahera, J. P. G., Morgado, A. O., González, A. D. & Silva, B. P. (2007). Flora y vegetación del Parque Nacional Caguanes, Sancti Spíritus, Cuba. Brenesia, 67, 924.Google Scholar
Lieberman, M. (2017). Cuba Welcomed a Record Number of Tourists in 2016. Retrieved from http://www.travelandleisure.com/travel-tips/travel-trends/cuba-record-tourism-2016Google Scholar
Marrero Antuña, J. C., Miller, M., Mattioli, G., Feaux, K., Anthes, R., Braun, J., Wang, G. & Robock, A. (2014). Partnering with Cuba: weather extremes. Science, 345(6194): 278.CrossRefGoogle Scholar
Martin, F. & Griffiths, H. (2012). Power and representation: a postcolonial reading of global partnerships and teacher development through north–south study visits. British Educational Research Journal, 38(6), 907927.CrossRefGoogle Scholar
Martínez-Daranas, B., Perdomo López, M. E. & Guimarais Bermejo, M. (2015). Protección y Aprovechamiento Sostenible de Los Pastos Marinos. In ¿Tendremos Desarrollo Socioeconómico Sin Conservación de La Biodiversidad? Experiencias Del Proyecto Sabana Camagüey En Paisajes Productivos, pp. 146–153. PNUD-GEF. La Habana: Editorial AMA. Retrieved from http://repositorio.geotech.cu/jspui/bitstream/1234/659/14/Experiencias%20Proyecto%20Sabana%20Camag%C3%BCey%20paisajes%20productivos%20cap%2011.pdfGoogle Scholar
Massey, D. (2005). For Space. Sage Publications Ltd.Google Scholar
Mateos, G. & Suáraz, E. (2016). Mexican science during the Cold War: an agenda for physics and the life sciences. Ludus Vitalis, 20(37), 4769.Google Scholar
McCune, N. M., González, Y. R., Alcántara, E. A., Martínez, O. F., Fundora, C. O., Arzola, N. C., … Hernández, F. G. (2011). Global questions, local answers: soil management and sustainable intensification in diverse socioeconomic contexts of Cuba. Journal of Sustainable Agriculture, 35(6), 650670.CrossRefGoogle Scholar
McKinney, L. (2017a). Continue U.S.–Cuban science diplomacy. Science (New York, N.Y.), 358(6370), 15491549.Google Scholar
McKinney, L. (2017b). The diplomacy of science must continue in any policy about Cuba. Retrieved from https://www.tribtalk.org/2017/06/23/the-diplomacy-of-science-must-continue-in-any-policy-about-cubaGoogle Scholar
Méndez Herrera, L. & Sánchez Cid, A. (2011). Los actores locales en los procesos de ordenamiento ambiental y el manejo integrado costero. Experiencias del municipio Yaguajay. Retrieved from http://repositorio.geotech.cu/jspui/handle/1234/1009Google Scholar
Moyi Okwaro, F. & Geissler, P. W. (2015). In/dependent collaborations: perceptions and experiences of African scientists in transnational HIV research. Medical Anthropology Quarterly, 29(4), 492511.CrossRefGoogle ScholarPubMed
Munung, N. S., Mayosi, B. M. & de Vries, J. (2017). Equity in international health research collaborations in Africa: perceptions and expectations of African researchers. PLoS One, 12(10), e0186237.CrossRefGoogle ScholarPubMed
National Research Council (2012). U.S. and International Perspectives on Global Science Policy and Science Diplomacy: Report of a Workshop. The National Academies Press.Google Scholar
ONEI (2018). Anuario Demográfico de Cuba 2017, p. 122. Retrieved from http://www.onei.gob.cu/node/13810Google Scholar
Patel, R. & Brogan, J. (2017). What Cuba Can Teach Us About Food and Climate Change. Slate. Retrieved from http://www.slate.com/articles/health_and_science/future_tense/2012/04/agro_ecology_lessons_from_cuba_on_agriculture_food_and_climate_change_.htmlGoogle Scholar
Pastrana, S. J. (2015). Science in U.S.–Cuba Relations. Science, 348(6236): 735.CrossRefGoogle ScholarPubMed
Pastrana, S. J. & Clegg, M. T. (2008). U.S.–Cuban Scientific Relations. Science, 322(5900): 345.CrossRefGoogle ScholarPubMed
Pérez Hernández, A. L., Rodríguez Otero, C. M., Roig Piquero, M., Abreu Tamayo, M., Boquet Roque, A. & Favier González, L. (eds) (2001). Los Asentamientos Humanos, el Uso de la Tierra y los Cambios Globales en Cuba (Vol. 1). Programa Nacional de Cambios Globales y Evolución del Medio Ambiente Cubano, Subprograma Dimensionamiento Humano del Cambio Global, Ministerio de Ciencia, Tecnología y Medio Ambiente. Retrieved from http://www.ipf.cu/es/content/los-asentamientos-humanos-el-uso-de-la-tierra-y-los-cambios-globales-en-cuba-0Google Scholar
Planos Gutiérrez, E. O. (2014). Síntesis Informativa sobre Impactos de Cambio Climático y Medidas de Adaptación en Cuba. Retrieved from http://repositorio.geotech.cu/xmlui/handle/1234/1545Google Scholar
Planos Gutiérrez, E. O., Rivero Vega, R. & Guevara Velazco, V. (2012). Impacto del Cambio Climático y Medidas de Adaptación en Cuba (GEF/UNDP). Retrieved from http://www.redciencia.cu/geobiblio/paper/2012_Planos_Impacto%20y%20Adaptacion,%20Libro.pdfGoogle Scholar
Pohl, C. (2008). From science to policy through transdisciplinary research. Environmental Science & Policy, 11(1), 4653.CrossRefGoogle Scholar
Pulwarty, R. S., Nurse, L. A. & Trotz, U. O. (2010). Caribbean islands in a changing climate. Environment: Science and Policy for Sustainable Development, 52(6), 1627.Google Scholar
Roman, J. (2018). The ecology and conservation of Cuba's coastal and marine ecosystems. Bulletin of Marine Science, 94(2), 149169.Google Scholar
Salazar, J. A. F. (2016). Sostenibilidad: una respuesta para el desarrollo del turismo. Retrieved from http://www.cubahora.cu/economia/sostenibilidad-una-respuesta-para-el-desarrollo-del-turismoGoogle Scholar
Samenow, J. (2017). 60 inches of rain fell from Hurricane Harvey in Texas, shattering U.S. storm record. Retrieved from https://www.washingtonpost.com/news/capital-weather-gang/wp/2017/08/29/harvey-marks-the-most-extreme-rain-event-in-u-s-historyGoogle Scholar
Sharpe, B., Hodgson, A., Leicester, G., Lyon, A. & Fazey, I. (2016). Three horizons: a pathways practice for transformation. Ecology and Society, 21(2), 47.CrossRefGoogle Scholar
Smith, E., Banda, M. M., Tunnell, J. W. & Withers, K. (2013). Ecosystem-based management in the Laguna Madre, Western Gulf of Mexico. In Day, J. W., Yáñez-Arancibia, A., Vásquez, H. A., Arzapalo, W., Baltz, D. M. & Banda, A. (eds), Gulf of Mexico Origin, Waters, and Biota: Volume 4, Ecosystem-Based Management, pp. 131152. Texas A&M University Press.Google Scholar
Stamm, A. & Figueroa, A. (2012). Effective international science, technology and innovation collaboration: from lessons learned to policy change. In Meeting Global Challenges through Better Governance: International Co-Operation in Science, Technology and Innovation, pp. 207231. OECD Publishing.Google Scholar
Taylor, M. A., Clarke, L. A., Centella, A., Bezanilla, A., Stephenson, T. S., Jones, J. J., … Charlery, J. (2018). Future Caribbean climates in a world of rising temperatures: the 1.5 vs 2.0 dilemma. Journal of Climate, 31(7), 29072926.CrossRefGoogle Scholar
Turchetti, S., Herran, N. & Boudia, S. (2012). Introduction: have we ever been ‘transnational’? Towards a history of science across and beyond borders. British Journal for the History of Science, 45(3), 319336.CrossRefGoogle Scholar
Walker, M. (2012). The ‘national’ in international and transnational science. British Journal for the History of Science, 45(3), 359376.CrossRefGoogle Scholar
Wallace, E. J., Donnelly, J. P., Hengstum, P. J., Wiman, C., Sullivan, R. M., Winkler, T. S., … Albury, N. (2019). Intense hurricane activity over the past 1500 years at South Andros Island, The Bahamas. Paleoceanography and Paleoclimatology, 34(11), 17611783.CrossRefGoogle Scholar
Wang, Z. (2010). Transnational science during the Cold War: the case of Chinese/American scientists. Isis, 101(2), 367377.CrossRefGoogle ScholarPubMed
Yáñez-Arancibia, A. & Day, J. W. (2004). Environmental sub-regions in the Gulf of Mexico coastal zone: the ecosystem approach as an integrated management tool. Ocean & Coastal Management, 47(11–12), 727757.CrossRefGoogle Scholar
Yáñez-Arancibia, A., Day, J. W. & Reyes, E. (2013). Understanding the coastal ecosystem-based management approach in the Gulf of Mexico. Journal of Coastal Research, 63(63), 244262.CrossRefGoogle Scholar
Zulueta Acea, M. A. & Boffill Vega, S. (2014). Planificación y manejo para potenciar el turismo de naturaleza en el Parque Nacional Caguanes de Yaguajay. Revista Caribeña de Ciencias Sociales, (2014_10). Retrieved from http://caribeña.eumed.net/wp-content/uploads/caguanes.pdfGoogle Scholar
Figure 0

Fig. 1. Map of the Gulf of Mexico and the two research sites. Site A is Caguanes National Park. Site B is the Laguna Madre ecosystem.

Figure 1

Fig. 2. Caguanes National Park, central Cuba.

Figure 2

Fig. 3. Laguna Madre ecosystems, Tamaulipas, Mexico, and Texas, USA.

Figure 3

Fig. 4. Chronological timeline of major events. CNP = Caguanes National Park.