1. Introduction
Guayule (
Parthenium argentatum A. Gray) is a woody perennial shrub (50–90 cm high), from the Asteraceae family, indigenous to semi-arid regions of northern Mexico and southern Texas [
1,
2,
3]. Since the beginning of the twentieth century, this plant has received recurrent attention as one of the most important alternative sources to produce high molecular-weight and hypoallergenic natural rubber [
4,
5,
6]. The global production of natural rubber is obtained from Hevea [
Hevea brasiliensis (Willd. ex A. Juss.) Müll. Arg.)] trees, which are grown in tropical regions, primarily Southeast Asia countries [
2,
3]. Particularly in the industrial and medical sectors, natural rubber is of essential and strategic importance in thousand applications, from the production of medical devices to automotive and aircraft tires. Indeed, its unique biopolymer (1,4 cis-polyisoprene) possesses high performance properties, such as resilience, elasticity, abrasion resistance, efficient heat dispersion, impact resistance, and malleability at cold temperatures, which cannot be achieved by synthetic rubber forms [
7]. Hevea rubber could cause allergic reactions, whereas guayule is regarded as an under-used source of hypoallergenic latex. Additionally, potential rubber supply shortages from Southeast Asia might be determined by fungal diseases on Hevea and land use changes in areas of production. For the above reasons, the dependence upon Hevea as a single source of natural rubber is risky for all countries that are not producers. Moreover, natural rubber has been listed as a critical material by European Union [
8], which is completely dependent upon imported natural rubber sources, amounting to about 1.2 million tons annually [
9].
Guayule shrub grows within a temperature range of −15°C to +40 °C, with annual rainfall requirements from 350 to 800 mm. Therefore, it is well suited to semi-arid and Mediterranean regions such as South of France, Italy, Spain, Morocco, and Turkey [
10,
11]. Currently, it is considered as a potential alternative source to produce natural rubber in Europe with the potential to become commercial crop [
12]. According to Snoeck et al. [
13], guayule in Mediterranean countries might be commercially profitable if in addition to rubber, the resin and biomass have economic markets (including bioenergy to drive the guayule processing plant) [
14]. As stated by the same authors, an overall interest in developing new agricultural commodities, such as guayule for Mediterranean or semi-arid climates is justified. In 2018, the US tire manufacturer Bridgestone Americas and Italy-headed polymer and elastomer producer Versalis S.P.A. established a strategic partnership, in order to develop and deploy a “comprehensive technology package” to commercialize guayule in the agricultural, sustainable-rubber and renewable-chemical sectors (info@bioenergyinternational) testifying the strong interest in guayule.
It is noteworthy that first attempts for produce natural rubber from the guayule plant in Italy dated back to 1933. Field experiments were conducted in Apulia region and Sardinia island, but the outbreak of World War II did not support an industrial exploitation, in spite of the collaboration established between the Italian company Saiga and the American Intercontinental Rubber Company [
15]. Sardinia territory was already chosen because its suitability for guayule cultivation. However, Sardinia has microclimates and soil types that can be considered representative for other areas of Mediterranean basin to study the impact of environmental factors on the cultivation of guayule. We hypothesized the environmental diversity might influence guayule performances. A research was conducted in two Sardinian locations to evaluate the adaptation and productive potential of guayule grown under Mediterranean conditions. The specific aims of the research were to; (i) evaluate adaptation and biometric traits of introduced guayule lines; and (ii) determine the growth, biomass production, contents and yields of rubber and resin obtainable from guayule biomass.
4. Discussion
Although it is native to northern Mexico and southwest regions of the USA, guayule is considered suitable to semi-arid and Mediterranean regions [
11]. Currently, there is increasing interest in it, as an alternative source to produce natural rubber in Southern Europe [
12]. Notwithstanding the acknowledged potential suitability of this shrub species, very few papers document the adaptation and performances, over time, of guayule accessions, introduced in Mediterranean areas, which are featured by large environmental and biological diversity.
The current study is one of the first reports regarding bioagronomic traits and quantification of rubber and resin contents and yields from both twigs and branches of guayule plants grown in Mediterranean environment. Despite the first attempts carried out in Italy to grow guayule before the outbreak of World War II [
15], no information is available in literature on guayule adaptation to Italian environmental conditions, to the best of our knowledge. The only available information for southern European areas comes from the long-term activity on guayule carried out by the French Cirad (Centre de coopération internationale en recherche agronomique pour le développement) at Montpellier (France). Within the EU-Pearls project [
24], a specific workpage dealt with guayule germplasm, breeding, and agronomy. Field experiments have been carried out at Montpellier (France) and Cartagena (Spain), which are two sites differing for climatic traits (a mean annual rainfall of 776 and 350 mm, respectively). Therefore, Sardinian sites having 450 to about 750 mm of precipitation can be considered quite comparable with the abovementioned Spanish and French sites. First, our results testify the importance of environmental conditions on the survival of guayule plants, indicating a lower adaptation capacity in the improved lines AZ-1 and AZ-2 compared to 11591 at the site of northern Sardinia. Higher rainfall coupled with a poor soil drainage and/or occasional frost events might presumably favoured root diseases, causing a high plant mortality at that site, reducing possible comparison with other results. Snoeck et al. [
25] reported an overall higher adaptation of guayule germplasm (both Mexican and US accessions) in the drier site of Cartagena, whereas frost damage on plants was recorded in Montpellier where irrigation was conversely unnecessary because rainfall was already high. Plant survival, rubber content, dry matter and rubber yields were affected by genotype, site and adopted management in terms of irrigation and fertilization. However, rubber content of stems at Cartagena reached 6.8% as in our results, very different from values of Montpellier site (about 4%).
Outside southern Europe, Dissanayake et al. [
26] evaluated improved lines of guayule in a black earth soil at a sub-tropical climate site of Australia. They reported a rubber and resin yield increase in the range of 53–123% for lines AZ-1 and AZ-2 over 11591. In contrast to Dissanayake et al. [
26], we recorded quite similar or even higher values for 11591 compared to AZ-1 and AZ-2. The different duration of growth period from transplanting to harvesting and adopted management interventions in the different experiments, make it difficult to compare the same guayule accession grown worldwide. On the other hand, improved lines were developed for specific and targeted USA areas and not for a global spreading of the guayule cultivation [
17]. Additionally, proper comparisons for the same accessions carried out at the same or similar plant age (i.e., 24 or 30 months after transplanting) are quite limited.
Dissanayake et al. [
27] also evaluated the same accessions in two distinct Australian sites and found higher rubber and resin contents for AZ-1 and AZ-2 in the drier site, but similar yields in both sites. They found very lower rubber and resin yields for 11591 in the drier site, even though rubber and resin contents were higher. Compared to the Australian results, our values were lower for AZ-1 or very lower for AZ-2, but similar or higher for 11591. Potential rubber yields were overall lower than our values for the same 11591 accession when grown in Argentina [
28] where the different season at harvest had little effect on yield performances. Not surprisingly, rubber and resin yields were also affected by plant dry matter yields, which also varied in the different experiments. More recently, the performances of several guayule lines were investigated in the Western Cape regions of South Africa [
29] indicating a successful establishment of guayule lines AZ-1 and 11591 as in our research. Additionally, field measurements carried out on 2-year old plants allowed direct comparisons with our results for some biometric traits. At the Western Cape experimental farm, AZ-1 and AZ-2 reached a plant height of 90 cm and were taller than in Sardinia, whereas plant height values for 11591 were quite similar. On the contrary, main stem diameters for AZ-1, AZ-2 and 11591 lines in Sardinia were twice as larger as in South Africa. The comparisons for biometric traits with Australian results [
27] showed quite similar plant height values for AZ-1 and 11591, whereas higher values for AZ-2 leading to taller plants than those recorded in southern Sardinia. However, in that Sardinian site AZ-2 and 11591 did not significantly differ for plant height.
Regarding leaf chlorophyll contents (measured as SPAD units) at northern Sardinia site, P803 showed the highest values that were significant different from AZ-1 and AZ-2 but not from 11591. Unfortunately, direct comparisons for leaf chlorophyll contents and leaf chlorophyll fluorescence (Fv/Fm) are not possible for the same accessions grown in field. However, P803 accession differed significantly from remaining ones under comparison for Fv/Fm and the AZ-2 value, not different from P803, was lower than AZ-1 at 30-month sampling. Overall, our values recorded at 12, 18 and 30-month sampling were slightly higher than values obtained in hydroponically grown guayule plants or its shoot-regenerated cultures [
30,
31]. It is worth noting that the leaves of P803 were very small and with a different shape compared to AZ-1, AZ-2 and 11591. In healthy non-stressed plants, Fv/Fm is around 0.83, while any type of stress that results in inactivation or damage to photosystem II (photoinhibition) causes a decreasing of Fv/Fm value [
20]. Therefore, our measurements of chlorophyll fluorescence in vivo, and on intact and attached leaves, indicated differences among accessions under comparison, as well as possible associated stress conditions. According to Veatch and Ray [
32] difference in photosynthetic rates could account for the increase of rubber production in the winter months.
A recent comparison across six sites in Arizona and Texas evaluated the phenotypic variations in dry biomass, rubber and resin content and production in nine improved guayule germplasm [
33]. The reported mean rubber and resin yields for 2-year old plants of 11591 were almost coincident with our values, even if rubber and resin contents differed. On the contrary, mean rubber and resin yields were twice as high as our values for AZ-1 and almost 4-fold than our values for AZ-2. It is worth noting that large variation was found for the same trait. For example, AZ-2 rubber content ranged from 2.05 to 4.80% in individual locations as well as resin yield varied from 791 to 2207 kg ha
−1, and so on. Authors pointed out that the investigated guayule germplasm has a good genetic variability in biomass rubber and resin production also suggesting the possibility of selection for more than one trait at a time. Finally, the potential rubber and resin yields from Abdel-Haleem et al. [
33] were quite conservative compared to those indicated by Luo et al. [
34]. Derived from an experiment carried out in Arizona for estimating the potential breeding values for different guayule accessions (as Best Linear Unbiased Prediction), the potential rubber yield of 1200 kg ha
−1 for 11591 and about 900 kg ha
−1 for both AZ-1 and AZ-2, respectively, were reported [
34].
Based on the above reported comparisons within global trials, it might be stated that the accession 11591 performed better in regions of Texas, France, South Africa and now Italy. However, it did not occur in Argentina and Australia. The worldwide performances of AZ-2 have always overtaken our results. Such differential yields between countries may be accounted for by genotype x environmental interaction, where the specific combination of different factors, namely soil type, temperature, rainfall, irrigation, is important. In summary, our findings indicate a low suitability of AZ-1 and AZ-2 to be grown at the environmental conditions of the northern Sardinia site, where 11591 had the highest survival rate, and the limited performances of the AZ-2 accession at the conditions of the southern Sardinia site, not in agreement with reports from other countries. Unfortunately, no comparative values are available in literature for the accession P803, to the best of our knowledge. However, based on the divergent information from worldwide reports and taking into account the environmental variability of Mediterranean climatic areas, caution must be used when extrapolating our information for other environments of Mediterranean basin, which are not necessarily similar for soil type and annual rainfall amounts. For the same reasons, additional fields experiments are required country by country in order to ascertain the possibility of guayule cultivation across its potential cultivation area in Mediterranean Europe and/or Mediterranean basin, which is characterized by a diversified gradient of land suitability for guayule cultivation, as already indicated [
12].
Finally, traditional farming systems are important at the same Mediterranean areas and therefore, it is preferable, at least as a valuable option, for the integration of guayule crop into existing farming systems. As evergreen drought resistant shrubs might alleviate critical fodder shortage, the forage potential of guayule leaves is also being investigated [
35]. This approach will contribute to exploitation of the whole plant biomass and non-rubber co-products not only for biobased by-products [
14,
36,
37,
38], but also for complementing traditional activities. Additionally, it might contribute to support the interest in developing new agricultural commodities such as guayule for Mediterranean regions over the next years.