Next Article in Journal
Microclimate Drives Shelter-Seeking Behaviour in Lambing Ewes
Previous Article in Journal
Root Production and Microbe-Derived Carbon Inputs Jointly Drive Rapid Soil Carbon Accumulation at the Early Stages of Forest Succession
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Forests
Volume 13
Issue 12
10.3390/f13122131
forests-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Effects of Environmental Stress on the Pollen Viability of Ornamental Tree-Species in the City of Granada (South-Eastern Spain)

by
Priscila Ramírez-Aliaga
1,
Inmaculada Foyo-Moreno
2,3 and
Paloma Cariñanos
1,2,*
1
Department of Botany, University of Granada, 18071 Granada, Spain
2
Andalusian Institute for Erath System Research (IISTA-CEAMA), University of Granada, 18071 Granada, Spain
3
Department of Applied Physics, University of Granada, 18071 Granada, Spain
*
Author to whom correspondence should be addressed.
Forests 2022, 13(12), 2131; https://doi.org/10.3390/f13122131
Submission received: 19 October 2022 / Revised: 4 December 2022 / Accepted: 9 December 2022 / Published: 12 December 2022
(This article belongs to the Section Urban Forestry)
Browse Figures
Versions Notes

Abstract

:
Atmospheric conditions, as well as pollutants, can induce changes in the viability and germinability of the pollen grain. This process frequently occurs in cities due to the high rate of air pollution that can alter the quality of pollen, affecting its biological functions. In this work, the effect of different environmental stress factors, mainly UV-B radiation and polluting gases (CO, NO2 and SO2), on the viability and maturity of the pollen of four ornamental tree-species present in the green infrastructure of Granada, namely Acer negundo, Carpinus betulus, Olea europaea and Cupressus spp. is analyzed. Differential staining techniques were used with fresh pollen collected in areas with different exposure to environmental stress to detect intact cell membranes (Trypan blue) and the state of maturity (Pyrogallol red). It was observed that the species from sectors more exposed to environmental stress registered a low viability and were affected by factors such as UV-B radiation and atmospheric pollutants. On the contrary, the pollen from tree species growing in peri-urban forests presented a higher rate of viability and less effect of pollutant factors. Differences were also observed according to the species/genus and according to the sampling area. This modification in the morphological and/or organic composition of the pollen wall may cause a loss of quality in the reproductive processes of plants, and it may be bioindicator of the process of progressive degradation that plant species can experience in urban environments under conditions of environmental stress, and prevent the impacts that can affect other species.

1. Introduction

Variations in environmental conditions can impose important restrictions on the growth and development of plants and, therefore, cause stress situations on them. In this sense, the concept of “stress” implies the presence of a factor external to the plant, caused by the changing environment, which exerts a negative influence on its growth and optimal development [1]. In urban environments, urban trees can suffer a greater degree of stress as some of the environmental factors become more acute and they are also subjected to different maintenance actions carried out by man [2,3]. Most of the time, it is difficult to eliminate the stress factor, so the plants generate a response to it, such as the modification of the photosynthetic function [4], increasing their vulnerability to biotic agents in the form of pests and diseases, or altering the biological quality of some of its essential structures [5], such as the male gametophytes (pollen grains) essential for the reproductive process [6].
There is evidence that under certain stressful environmental conditions, such as those recorded in urban ecosystems, pollen grains can modify the organic composition of their cover, and that consequently, an alteration of pollen fertility and viability occurs, with a direct impact on the reproductive phenology of the species [7]. The impacts are so variable and they will depend both on the environmental conditions, on the concentrations of pollutants and on the morphological characteristics of the different pollen types. Some studies have shown that germination and soluble proteins in the exine of pollen grains of some species of the Betulaceae family (Betula pendula, Ostria carpinifolia and Carpinus betulus) are affected by NO2 exposure in vitro even below the current atmospheric hour-limit value acceptable for human health protection [8]. The high concentrations of NO2 and O3 in polluted areas can also promote the nitration of proteins in the pollen wall, forming long-lived reactive oxygen intermediates (ROIs) and protein dimers, that cause loss of pollen viability [9]. In species such as Ambrosia artemisiifolia, the exposure of pollen to atmospheric pollutants has increased the expression of some proteins, causing a degradation of the pollen structure and significantly reducing its viability [10]. A similar effect occurs when pollen grains from Quercus, Festuca and Ulmus are subjected to low CO, NO2 and SO2 concentrations, where after exposure a change is observed in the water-soluble proteins and molecular weight [11]. Oak pollen exposed to 0.5 ppm NO2 and SO2 for 4 h showed morphological damage and loss of viability, detected using Trypan blue stain [12]. The light, partial or no acetocarmine staining of the morphologically altered pollen grains of several legume species in areas affected by fluoride pollution in Iran, in relation to the clear staining of the scarcely altered pollen grains from non-contaminated areas, has revealed the essential role of the pollen grain as a biomonitor of air pollution [13].
However, there are studies that suggest that some species of plants try to respond adequately to the presence of atmospheric pollutants, increasing the content of enzymes and flavonoids in their pollen grains as a protection mechanism, as has been observed in Thuja orientalis [14]. Some of the main tree species in the Mediterranean region, such as those of the Quercus, Pinus and Olea genera, have been shown to have a high tolerance to atmospheric O3 concentrations due to the opening and closing control mechanism stomata [15], which has not affected either the production or the viability of their pollen grains [16]. In studies in which the pollen viability of four forest species has been evaluated: Acer negundo, Corylus avellana, Quercus robur and Betula pendula, after exposure to the same concentrations of O3 and NO2, they have shown a different response,—pollen being the most resilient in terms of viability. It was also observed that NO2 was the gas with the most negative effect on pollen viability [17].
All of the above reveals two important considerations in relation to the impact that environmental stress has on the pollen grains of different plant species. On the one hand, not all the pollen types respond in a similar way to the presence of one or more environmental stress factors; on the other hand, the pollen grains of some species have a more sensitive response to these factors, so they could be used as bioindicators of adverse environmental conditions [16].
The objective of this work is to analyze the impact produced by different environmental stress factors, mainly air pollutants and UV-B, on the viability of the pollen grains of four species of ornamental trees frequently used in urban forests of Mediterranean cities. The results will reveal the reproductive health status of these species as well as which of them could be used as a specific bioindicator of a polluted environment.

2. Materials and Methods

Study Area. The study was carried out in Granada (37°11′17″ N; 3°36′24″ W), a standard medium-sized compact Mediterranean city, located in the southeast of the Iberian Peninsula, which extends over an area of 88 km2 at the foot of Sierra Nevada, one of the highest mountain ranges in Europe (Figure 1). The climatic conditions are typical of the Mediterranean area, with a certain degree of continentality and high seasonal and intradaily temperature contrasts. The average annual temperature is 15.6 °C and the total average annual rainfall is 359 mm according to data provided by the Spanish Meteorological Agency, measured at the Granada airport weather station for the reference period 1981–2010 [18]. The study was carried out in 2015, which presented an average annual temperature of 16.6 °C and a total annual rainfall of 260.1 mm, clearly anomalous values in relation to those of the last reference climatic series.
In relation to the Urban Green Infrastructure, there are 363 green elements registered in the city, of which 341 of them have an extension smaller than 10.000 m2 and an average of 4.74 m2 of green area per resident [19]. The proportion of 160 trees per 1000 inhabitants is slightly higher than the European average [20]. The panel of most frequent plant species in the UGI elements exceeds 200 different species [21], a fact that is reflected in the diversity of pollen types found in the aerobiological analysis, which has been routinely carried out in the city since 1992, when the Granada station joined the Spanish Aerobiology Network [22]. Among the main genera contributing to the aeropalinological spectrum of the city are Cupressus, Platanus, Ulmus, Populus, with species widely represented in urban green areas. The concentrations of pollen from peri-urban emission sources are also relevant, forming both natural vegetation such as Quercus and Pinus, as well as large cultivated areas such as Olea [23].
The analysis of the city’s historical pollen data series for the period 1992–2018 has shown that extreme pollen events, that is, those in which the daily concentrations of pollen grains are higher than the 99th percentile of the pollen records during this entire period, are increasing both in frequency and intensity in recent years [24]. It must be also added that the interactions established between pollen and atmospheric pollutants, in particular with NO2, of which the levels recorded in Granada are among the highest in the entire Spanish territory, with average annual values that exceed not only 40 µg/m3 but also the tolerance margin established at 20 µg/m3 more [25,26].
Selection of plant speci0es and sampling areas. For this study, four of the most frequent tree species in the urban forests of the city of Granada and in numerous cities of the Mediterranean region [20,27] were selected: box elder (Acer negundo), European hornbeam (Carpinus betulus), Italian cypress (Cupressus sempervirens) and olive (Olea europaea [28]. The first three species present an anemophilous pollination strategy, for which the production and emission of pollen is very high [29], while in the case of the olive tree, although it presents an ambiphilous pollination strategy, that is, a mixed process between entomophily and anemophily [30], its extensive presence causes very high atmospheric pollen levels to be recorded, reaching more than 30% of the annual pollen content in the city’s atmosphere [22,23].
For the purpose of this study, three urban areas were selected in which several of the following factors converged: (i) intense traffic areas, that is, those with an intensity of traffic of more than 1500 cars/hour according to the information regarding the traffic map of the city of Granada available at: http://www.movilidadgranada.com/tra_estado.php, access date: 15 November 2022; (ii) high exposure to direct solar radiation, from which ultraviolet-B radiation (UV-B) values can be obtained; (iii) area exposed to adverse environmental conditions: high insolation, high/low temperatures, water deficit or wind gusts, based on data from the network of stations of the State Meteorological Agency (AEMET) in the city of Granada (https://x-y.es/aemet/prov-granada, access date: 15 November 2022); (iv) area of high urban density, based on data on the degree of urbanization defined by Eurostat, available at: https://ws089.juntadeandalucia.es/institutodeestadisticaycartografia/blog/2020/03/poblacion-y-espacio-degree-of-urbanization/, access date: 15 November 2022. In addition, an urban area that, due to its characteristics in terms of vegetation, low urban and traffic density, and absence of water stress, could be considered a control area was selected, that is, in which the impact of stress factors on pollen was minimal. These characteristics are brought together by the forests and gardens that surround the Alhambra Monument, the city’s main urban forest in terms of extension and ecosystem services it provides [28,31]. Table 1 presents the characteristics of the different urban areas selected for this study and their location in the urban area.
Data about the levels of three main pollutants: SO2, NO2 and CO were obtained in two stations of the Surveillance and Control Network of Air Quality, Regional Government of Andalusia (REDIAM), located in two areas of the city: one in the City Center (1: Palacio de Congresos) and another in the North area (2: Cartuja), for the period January–June 2015. The values of monthly average direct solar radiation in 10× kJ/m2 for the period January–May 2015, were provided by the State Meteorological Agency (AEMET). Ultraviolet-B (UV-B) radiation data were obtained adapting the model of Foyo-Moreno et al. [32] for the integrated daily values. This model uses only the global irradiation through the broadband hemispherical transmittance (kt) as input data, defined as the ratio between global irradiance and extraterrestrial global irradiance (both on a horizontal surface). This parameter is an indicator of the transparency of the sky, considering the most influencing factors in the determination of the solar radiation as aerosols and clouds. This model has wide applicability to other spectral regions as visible regions (400–700 nm) [33] and was also adapted to estimate erythemal ultraviolet irradiance [34].
Pollen harvesting. The flowers (cones in the case of Cupressus sp.) of the selected species were extracted in the period immediately prior to anthesis, that is, late January 2015 for C. sempervirens, February 2015 for A. negundo and C. betulus and late April 2015 for O. europaea. The optimal state of maturity of the pollen grains was verified by optical microscopy. A variable number of flowers were placed on an oven tray and dried at a moderate temperature (20 °C) to facilitate their extraction. Next, the flowers were placed on a sieve and gentle pressure was exerted to optimize pollen extraction and remove as many plant remains as possible from them. The amount of pollen obtained was approximately 2 g of clean pollen per species. Then, this was stored in plastic microtubes in a refrigerator at 4 °C, adequate temperature to keep them in dormant conditions in the event that the analyzes are carried out in less than a month [35,36]. The analyzes to determine pollen viability were carried out in February for the Cupressus samples, in March for the A. negundo and C. betulus samples and in May for the Olea samples.
Pollen Viability Determination. From the different techniques used to test pollen viability, staining tests are among the most advantageous, as they are faster and easier techniques to use [37,38,39,40]. Several studies also highlight that the determination of viability by staining techniques may correlate with the degree of in vitro-pollen germination, with the percentage of viable pollen generally being higher than that of germinated pollen [39,41,42].
In this study, staining with two different reagents was performed to determine the viability of pollen grains:
  • Trypan blue. It measures cell viability by staining non-viable pollen grains a deep blue color [43]. This type of staining is based on the principle that living cells have an intact cell membrane, which is selective in relation to which compounds can cross it, that is, they exclude certain dyes, while dead cells do not [44].
  • Pyrogallol red (Commercially sold as Redprot-aeromedi©). Evaluates the state of physiological maturity of the pollen grains, differentiating pollen grains with an intact and mature protein coat, which stain purple, from those that do not have the cover in an optimal state of maturity and therefore do not stain. If the pollen grain is mature, it will correspond to a more suitable phase for fertilization [45].
To determine the percentage of viability and maturity of the pollen grains, a small amount of pollen of each species was placed on a slide and 1 or 2 drops of Trypan blue or Pyrogallol red dye were added, and then covered with a coverslip. After 10′, enough time for the pollen to stain, the samples were analyzed by optical microscopy, scanning the sample from left to right and counting 500 grains of pollen in each of the prepared samples. For each type of pollen and zone, three independent repetitions in each of the three different slides were carried out, accounting for a total of 1500 grains of pollen. Trypan blue and Pyrogallol red staining allow easy differentiation of viable and mature pollen grains, respectively, when they appear intensely stained. However, when pollen grains stain weakly, it is necessary to establish selection criteria to distinguish between viable and non-viable and mature and immature. Thus, in the case of viability, viable pollen grains were considered those that did not present coloration and non-viable those that presented some degree of staining (Figure 2). On the other hand, for maturity, mature pollen grains were considered those that showed coloration and immature those that did not show coloration (Figure 2).
Statistical Analysis. To determine differences between treatments and stress conditions, non-parametric Spearman’s correlation analyzes were performed, since the data do not fit a normal distribution. Finally, to determine statistical differences between the control treatments and the samples, an analysis of variance (ANDEVA) and a Tukey HSD test (95%) were performed a posteriori. These methods aim to compare the individual means from an analysis of variance of several samples subjected to different treatments, this test allows discerning whether the results obtained are significantly different or not. To perform the statistical analyzes, the IBM SPSS Statistics software was used.

3. Results

In relation to air quality during the study period, the levels of three main pollutants SO2, NO2 and CO obtained in two stations of the Surveillance and Control Network of Air Quality (Table 2) showed that, for the period January–June 2015, NO2 values exceeded the limit values for the protection of health. This limit established by Directive 2008/50/CE of the European Parliament and of the Council, of 21 May 2008, regarding the quality of ambient air and a cleaner atmosphere in Europe, transposed in Spain through the Royal Decree 102/2011, of 28 January 2011, regarding the improvement of air quality, limits the threshold values of an hourly limit value of 125 µg/m3 for SO2, an annual limit value for the protection of human health of 40 µg/m3 for NO2, and maximum eighth-hour average in one day of 10 mg/m3 for CO.
The values of monthly UV-B radiation in 10 kJ/m2 for the period January–May 2015, are presented in Table 3. It can be seen how the average value of direct radiation increases as the year progresses.
The results obtained to assess the viability of pollen from four tree species frequently used in the urban forest of Granada by specific stain are shown in Table 4. In the case of the samples stained with Trypan blue to determine viability, all the species in the control zone showed a higher percentage of viability than the pollen collected in the other sampled zones, that is, Fuentenueva Campus for Acer negundo and Cupressus spp., Bola de Oro for Carpinus betulus, and Cartuja Campus for Olea europaea. Viability percentages ranged from 56% (average of 303 ± 26 pollen grains in the three samples) for Cupressus to 85% (average 427 ± 11 pollen grains) for Olea europaea pollen. In the areas subject to different stress factors, it was observed that the percentage of viable pollen of Acer negundo and Cupressus was 20 (average 100 ± 61 pollen grains) and 39.5% (average 263 ± 30 pollen grains), respectively, while in the case of Carpinus betulus and Olea, the percentage of viability was close to 60% (average 294 ± 80 pollen grains for Carpinus and average 304 ± 80 pollen grains for Olea).
The results that allow determining the maturity degree of the pollen grains by specific stain with Pyrogallol red revealed that Acer negundo and Olea europaea pollen in the control zone presented a percentage greater than 80% in both cases, 83 (average 414 ± 57 pollen grains) and 84% (average 445 ± 85 pollen grains), respectively. The optimal maturity degree was only presented by 17% (average 87 ± 58 pollen grains) of the Carpinus betulus pollen grains in this control area. However, the percentage of maturity for this species rose to 33% (average 163 ± 48 pollen grains) in the other urban locations, although it was also the lowest percentage of the four species sampled. The highest maturity percentage was that presented by Acer negundo, which was 89% (average 445 ± 84.5 pollen grains) of the sample collected in other areas the city.
Spearman’s correlation analysis performed between the percentage of viable and non-viable pollen and the concentrations of atmospheric pollutants during the pre-flowering and flowering periods (Table 5) revealed that, in general, there is no effect of pollutants on the percentage of viable and non-viable pollen in the samples collected in the forests of La Alhambra, although in the case of Carpinus pollen, a significant correlation was found between non-viable pollen and UV-B radiation in February and SO2 concentrations in March, and negative with CO concentrations in March. In the rest of the locations, the correlation of the viable pollen of Acer in the Fuentenueva location with the UV-B radiation of March, and the concentrations of CO in February, and those of the non-viable pollen of this same taxon, with a lower degree of significance, are noteworthy with the UV-B radiation of February and March. In the Fuentenueva location, a significant negative correlation is also obtained between viable Cupressus pollen and SO2 concentration in February and non-viable pollen and UV-B radiation in March. The pollen sample from Olea from Cartuja showed a negative relationship with the UV-B radiation and the concentration of SO2 and NO2 in March.
In the case of the samples stained with Pyrogallol for the detection of maturity (Table 6), the effect of UV-B radiation in February and the concentration of CO in March for the pollen samples of Acer negundo from the Alhambra hardly stands out. Cupressus pollen sample collected in Fuentenueva was also significantly and negatively correlated with several pollutants in February and March.

4. Discussion

This study analyzed the effect of different environmental stress parameters on the viability of pollen grains from the tree species Acer negundo, Carpinus betulus, Cupressus spp. and Olea europaea, all of which are producers and emitters of large amounts of pollen, and which are frequently used as ornamentals in the metropolitan area of Mediterranean cities. It was based on the hypothesis that pollen viability decreases significantly when it is subjected to successive environmental stress conditions [46].
UV-B radiation (value obtained from the daily global irradiation data, [32,33,34] is one of the parameters analyzed that has the greatest effect on the viability of pollen grains, since UV-B has the potential to cause considerable damage to external protective structures, resulting in a decrease in the capability of germination [47]. The effects on growth rate and reproduction are also known [48,49]. In our study it has been observed that the pollen of species such as Acer negundo and Cupressus have been the ones that have shown a significant positive correlation between this variable and the percentage of non-viable pollen grains. In both species, the pollen is only protected from the outside by the wall of the pollen sac (cones in Cupressus and staminate catkins in A. negundo), so it is more unprotected than the pollen of plants with protective floral structures. A decrease in the germination rate of exposed Acer negundo pollen to NO2 in contrast to non-exposed pollen has been demonstrated, even when the concentrations of pollutants to which it is exposed are below of the threshold of danger to human health [50]. In the case of Cupressus, an adjuvant factor to this effect could be the higher rupture rate that these pollen types present during their atmospheric transport in the environment case of Cupressus [51]. It should also be noted that both Cupressus and Acer negundo are winter flowering tree species [29], so the pollen maturation period coincided with those of maximum values of NO2 in the atmosphere, whose values of January and February widely exceeded 40 micrograms/day due to the use of heating systems during the colder months, with monthly average values of 65 and 55 micrograms/m3, respectively.
The Olea europaea pollen only showed a negative relationship with March UV-B radiation in the location Campus de Cartuja for non viable pollen. Although some studies have shown the protective role that some floral structures such as petals may have on pollen, March is too early for these structures to be fully developed. To this we must add that the Campus de Cartuja location is the highest of all the locations (780 m a.s.l. compared to 640 m a.s.l of the others), so the exposure to global radiation is also higher. In situations where the flowers are well fully developed, some studies have highlighted how floral structures can exclude up to 70% of radiation in environments where exposure is very intense, such as high-altitude areas [52]. This percentage can even increase up to 98% in the case of those types of pollen that contain flavonoids in their wall. These compounds, in addition to being responsible for the yellow color of pollen, which plays an important role in attracting insects, have been shown to have a relevant protective effect against oxidative stress, and even increase synthesis as a defense measure against changes in UV-radiation [53]. In the case of olive pollen, its flavonoid content can be up to 422 ppm, much higher than the average content of this compound in Angiosperm pollen grains, which would confirm the greater protection of pollen against the effects of UV-B radiation [54].
Motorized traffic and biomass burning are the main sources of emission of atmospheric pollutants such as carbon monoxide (CO) and sulfur dioxide (SO2) in the study area [23,25]. Although all species had their viability affected by almost 50%, again both Acer negundo and Cupressus sp. were the most affected pollen types, with losses of up to 60% of viable pollen grains. Some studies have already highlighted the qualitative and quantitative changes that can occur in the characteristics of the pollen grains of these species when they are subjected to different concentrations of polluting gases [55]. In the case of some Cupressaceae, differences have also been found in the chemical composition of the pollen grains collected in areas with different levels of air pollution [14].
One factor that may play a role in this is the primitive nature of the Cupressaceae pollen grains, and their morphology, which is very fragile to changes in environmental humidity, to which it reacts in the form of rupture, and therefore, with loss of viability [56]. This situation is favored by the high number of existing specimens in the city, due to its consideration as an emblematic tree [31], as well as the very high pollen production per specimen, calculated at more than 275 × 109 [57]. Then, in addition to the pollen fragmentation due to changes in environmental humidity, mechanical fragmentation caused by atmospheric dynamics can occur, especially during the increasingly frequent episodes of extreme pollen events in which daily concentrations exceed 1500 pollen grains/m3 [24].
However, in the case of the olive pollen, no clear relationship has been found between the levels of atmospheric pollution and the structural change of the organic compounds present in the olive tree pollen wall [58]. This could be related to the improvement to which this species has been subjected in order to increase its agricultural yield, which has reinforced its resistance to different types of environmental stress, among them reinforcing the synthesis of protective flavonoids as already mentioned above [59,60]. It should be noted that certain studies confirm that some of the proteins that make up the pollen wall, are not expressed in some of the agricultural varieties subject to genetic improvement [61]. These differences are maintained over the years, and are intrinsic to the genetics of each cultivar [62]. Although with our results we cannot confirm the molecular changes experienced in the protein coat, we have been able to observe how olive pollen grains have been the least affected both in maturity and in viability, confirmed by their high rate of fruiting in the area [63].
In relation to maturity, only in the Cupressus pollen there is evidence that even at ambient NO2 concentrations far below the value at risk for direct effect on the respiratory health, some of the proteins in the pollen wall may stop being expressed, even when these pollen grains are still in the air inside the pollen sacs [64]. Therefore, the pollen emitted after anthesis already has defects in terms of its maturity phase affected by NO2. According to studies by Cuinica et al. [8], the viability, germination and total soluble proteins of pollen exposed to NO2 decrease significantly when compared to species not exposed to this pollutant. This could be due to the fact that, although NO2 levels were sometimes above the critical value for the protection of vegetation, established at 40 µg/m3, the exposure time may not be sufficient to cause damage that would affect pollen maturity, leaving the pollen grains protected by the anthers [55]. Some studies also indicate that the reaction of pollen from different species to the same concentration of NO2 is not the same, presenting different germination rates [8,65]. The maturity results obtained for Carpinus betulus are also striking, since it is the species that has shown a lower percentage of maturity both in the control zone and in the rest of the zones, but also being the percentage of maturity of the zone of lower control than that of the other zones. Although some studies have revealed that viability, germination and total soluble protein decrease significantly when pollen of this species is exposed to low levels of various pollutants (NO2, CO, O3, SO2) [30,64,65], in our results, no significant correlation was obtained with any contaminant. There is evidence of a physiological and biochemical response that these trees may have in the face of a high presence of atmospheric NO2, including changes in soluble protein [66], but in our case we believe that the low maturity and quality of its pollen may be more related to weather conditions. The hornbeam is a mesophilic species of temperate climates in which the high summer temperatures limit its distribution. In Europe it is widely distributed naturally in the central part, but its presence is practically null or marginal in the Iberian Peninsula [67]. However, and although there are several species and varieties that are cultivated in Spain [68], there is also evidence of their vulnerability to heat stress [69], a situation that has worsened in the study area with episodes of waves of more frequent and intense heat in the last 15 years [70].

5. Conclusions

Our results have highlighted that the different environmental and pollution conditions of the areas of the city in which the trees are located will have an influence on the levels of stress that affect them, and consequently, on the viability of the pollen grains of the different tree species. Of the different areas considered in this study, the trees that form the forests of the Alhambra have been the least affected by the parameters and variables evaluated, presenting the highest viability rate, greater than 56%. On the contrary, the pollen of the tree species in the Cartuja and Fuentenueva areas, both with important sources of polluting emissions due to intense traffic, present a viability of less than 40%, with the UV-B and SO2 parameters having the greatest effect on both viability and maturity. Pollen from Olea europaea has had the least impact due to the different stress parameters, while Carpinus betulus and Cupressus have been the two most affected species. In both, clear differences were observed between the samples from the different areas of the city and the one from the forests of La Alhambra, both presenting percentages of non-viability and non-maturity above 50%. These species, in addition to Acer negundo, are winter flowering, so the coincidence of the pollen maturation period in the reproductive structures with the maximum emission of pollutants derived from heating and traffic systems into the atmosphere may also be a factor influencing the viability of pollen grains.
We can conclude that the effect of environmental parameters and pollutants on the viability of pollen grains differs according to the species/genus and according to the conditions of the areas considered. In addition to the importance that the loss of quality of the pollen grain can have in the reproductive processes of plants, the monitoring of the response that the viability and germinability of the pollen of certain species (i.e., Cupressus spp. and Carpinus betulus in our study area) is having before certain stressful environmental conditions, can be used as a bioindicator and prevent the impacts that in the case of not taking action can affect other species.

Author Contributions

Conceptualization, P.R.-A. and P.C.; methodology, P.R.-A., I.F.-M. and P.C.; validation, P.R.-A., I.F.-M. and P.C.; formal analysis, P.R.-A.; investigation, P.R.-A. and P.C.; resources, P.C.; data curation, P.R.-A. and P.C.; writing—original draft preparation, P.R.-A. and P.C.; writing—review and editing, P.R.-A., I.F.-M. and P.C.; visualization, P.R.-A. and P.C.; supervision, P.C. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Ahmad, B.; Raina, A.; Khan, S. Retracted Chapter: Impact of biotic and abiotic stresses on plants, and their responses. In Disease Resistance in Crop Plants; Wani, S.H., Ed.; Springer: Cham, Switzerland, 2019. [Google Scholar] [CrossRef]
  2. Beniwal, R.; Hooda, M.; Polle, A. Amelioration of planting stress by soil amendment with hydrogel mycorrhiza mixture for early establishment of beech (Fagus sylvatica L.) seedlings. Ann. For. Sci. 2011, 68, 803–810. [Google Scholar] [CrossRef] [Green Version]
  3. Czaja, M.; Kołton, A.; Muras, P. The complex issue of urban trees-stress factor accumulation and ecological service possibilities. Forests 2020, 11, 932. [Google Scholar] [CrossRef]
  4. Percival, G.; Barrow, I.; Noviss, K.; Keary, I.; Pennington, P. The impact of horse chestnut leaf miner (Cameraria ohridella Deschka and Dimic; HCLM) on vitality, growth and reproduction of Aesculus hippocastanum L. Urban For. Urban Green. 2011, 10, 11–17. [Google Scholar] [CrossRef]
  5. Sæbø, A.; Borzan, Ž.; Ducatillion, C.; Hatzistathis, A.; Lagerström, T.; Supuka, J.; García-Valdecantos, J.; Rego, F.; Van Slycken, J. The selection of plant materials for street trees, park trees and urban woodland. In Urban Forests and Trees; Springer: Cham, Switzerland, 2005; pp. 257–280. [Google Scholar] [CrossRef]
  6. De Storme, N.; Geelen, D. The impact of environmental stress on male reproductive development in plants: Biological processes and molecular mechanisms. Plant Cell Environ. 2013, 37, 1–18. [Google Scholar] [CrossRef]
  7. Neil, K.; Wu, J. Effects of urbanization on plant flowering phenology: A review. Urban Ecosyst. 2006, 9, 243–257. [Google Scholar] [CrossRef]
  8. Cuinica, L.; Abreu, I.; Esteves da Silva, J. Effect of air pollutant NO₂ on Betula pendula, Ostrya carpinifolia and Carpinus betulus pollen fertility and human allergenicity. Environ. Pollut. 2014, 186, 50–55. [Google Scholar] [CrossRef]
  9. Shiraiwa, M.; Selzle, K.; Yang, H.; Sosedava, Y.; Ammann, M.; Pöschl, U. Multiphase chemical kinetics of the nitration of aerosolized proteins by ozone and nitrogen dioxide. Environ. Sci. Technol. 2012, 46, 6672–6680. [Google Scholar] [CrossRef]
  10. Zhao, F.; Elkelish, A.; Durner, J.; Lindermayr, C.; Winkler, J.; Ruëff, F.; Behrendt, H.; Traidl-Hoffmann, C.; Holzinger, A.; Kofler, W.; et al. Common ragweed (Ambrosia artemisiifolia L.): Allergenicity and molecular characterisation of pollen after plant exposure to elevated NO2. Plant Cell Environ. 2015, 39, 147–164. [Google Scholar] [CrossRef]
  11. Ruffin, J.; Liu, M.; Sessoms, R.; Banerjee, S.; Banerjee, U. Effects of certain atmospheric pollutants (SO2, NO2 and CO) on the soluble amino acids, molecular weight and antigenicity of some airborne pollen grains. Cytobios 1986, 46, 119–129. [Google Scholar]
  12. Ouyang, Y.; Xu, Z.; Fan, E.; Li, Y.; Zhang, L. Effect of nitrogen dioxide and sulfur dioxide on viability and morphology of oak pollen. Int. Forum Allergy Rhinol. 2016, 6, 95–100. [Google Scholar] [CrossRef]
  13. Malayeri, B.E.; Noori, M.; Jafari, M. Using the Pollen Viability and Morphology for Fluoride Pollution Biomonitoring. Biol Trace Elem Res 2012, 147, 315–319. [Google Scholar] [CrossRef]
  14. Rezanejad, F. Air pollution effects on structure, proteins and flavonoids in pollen grains on Thuja orientalis L. (Cupressaceae). Grana 2009, 48, 205–213. [Google Scholar] [CrossRef]
  15. Paoletti, E. Impact of ozone on Mediterranean Forests: A review. Environ. Pollut. 2006, 144, 463–474. [Google Scholar] [CrossRef] [PubMed]
  16. Gottardini, E.; Cristofolini, F.; Paoletti, E.; Lazzeri, P.; Pepponi, G. Pollen viability for Air Pollution Bio-Monitoring. J. Atmos. Chem. 2004, 49, 149–154. [Google Scholar] [CrossRef]
  17. Pereira, S.; Fernández-González, M.; Guedes, A.; Abreu, I.; Ribeiro, H. The strong and the stronger: The effects of increasing ozone and nitrogen dioxide concentrations in pollen of different forests species. Forests 2021, 12, 88. [Google Scholar] [CrossRef]
  18. Agencia Estatal de Meteorologia (AEMET). Informe Annual de la Agencia Estatal de Meteorologia; Ministerio de Agricultura, Pesca, Alimentación y Medio Ambiente. Gobierno de España: Madrid, Spain, 2017.
  19. Delgado-Capel, M.; Cariñanos, P. Towards a standard framework to identify green infrastructure key elements in dense Mediterranean cities. Forests 2020, 11, 1246. [Google Scholar] [CrossRef]
  20. Pauleit, S.; Jones, N.; Garcia-Martin, G.; Garcia-Valdecantos, J.; Riviére, L.; Vidal-Beaudet, L.; Bodson, M.; Randrup, T. Tree establishment practice in towns and cities–results from a European survey. Urban For. Urban Green. 2002, 1, 83–96. [Google Scholar] [CrossRef]
  21. Llodrá-Llabrés, J.; Cariñanos, P. Enhancing pollination ecosystem service in urban green areas: An opportunity for the conservation of pollinators. Urban For. Urban Green. 2022, 74, 127621. [Google Scholar] [CrossRef]
  22. Alba, F.; Díaz de la Guardia, C.; Sabariego, S.; Nieto, D. Aerobiología en Andalucía: Estación de Granada (2000–2001). Rea 2002, 7, 65–70. [Google Scholar]
  23. Cariñanos, P.; Foyo-Moreno, I.; Alados, I.; Guerrero-Rascado, J.; Ruiz-Peñuela, S.; Titos, G.; Cazorla, A.; Alados-Arboledas, L.; Díaz de la Guardia, C. Bioaerosols in urban environments: Trends and interactions with pollutants and meteorological variables based on quasi-climatological series. J. Environ. Manag. 2021, 282, 111963. [Google Scholar] [CrossRef]
  24. Cariñanos, P.; Guerrero-Rascado, J.L.; Valle, A.M.; Cazorla, A.; Titos, G.; Foyo-Moreno, I.; Alados-Arboledas, L.; Díaz de la Guardia, C. Assessing pollen extreme events over a Mediterranean site: Role of local surface meteorology. Atmos. Environ. 2022, 272, 118928. [Google Scholar] [CrossRef]
  25. Casquero-Vera, J.A.; Titos, G.; Alados-Arboledas, L. Diagnóstico de la Calidad del Aire del área metropolitana de Granada. Agenda 21. Ayuntamiento de Granada. Available online: https://www.granada.org/inet/agenda21.nsf/cff91acc5fede7f9c125727500305ef9/0aae130c836640acc1257f88002dc457/$FILE/Diagnostico%20Calidad%20Aire.pdf (accessed on 15 November 2022).
  26. Report on the Evaluation of the Quality of the Air in Spain. 2021; Ministerio para la Transición Ecológica y el reto Demográfico. Secretaria General Técnica. Centro de Publicaciones: Madrid, Spain, 2022; 189p.
  27. Heywood, V.H. The nature and composition of urban plant diversity in the Mediterranean. Flora Mediterr. 2017, 20, 195–220. [Google Scholar]
  28. Cariñanos, P.; Adinolfi, C.; Díaz de la Guardia, C.; De Linares, C.; Casares-Porcel, M. Characterization of allergen emission sources in urban areas. J. Environ. Qual. 2016, 45, 244–252. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  29. Piotrowska, K. Pollen production in selected species of anemophilous plants. Acta Agrobot. 2008, 61, 41–52. [Google Scholar] [CrossRef]
  30. Canale, A.; Loni, A. Insects visiting olive flowers (Olea europaea L.) in a Tuscan olive grove. J. Zool. 2010, 92, 95–98. [Google Scholar]
  31. Cariñanos, P.; Casares-Porcel, M.; Valle, A.; De la Cruz-Márquez, R.; Díaz de la Guardia, C. Charting trends in the evolution of the La Alhambra forest (Granada, Spain) through analysis of pollen-emission dynamics over time. Clim. Change 2016, 135, 453–466. [Google Scholar] [CrossRef]
  32. Foyo-Moreno, I.; Vida, J.; Alados-Arboledas, L. A simple all weather model to estimate ultraviolet solar radiation (290–385 nm). J. Appl. Meteorol. 1999, 38, 1020–1026. [Google Scholar] [CrossRef]
  33. Foyo-Moreno, I.; Alados, I.; Alados-Arboledas, L. Adaptation of an empirical model for erythemal ultraviolet irradiance. Ann. Geophys. 2017, 25, 1499–1508. [Google Scholar] [CrossRef]
  34. Foyo-Moreno, I.; Alados, I.; Alados-Arboledas, L. A new conventional regression model to estimate hourly photosynthetic photon flux density under all sky conditions. Int. J. Climatol. 2007, 37, 1067–1075. [Google Scholar] [CrossRef] [Green Version]
  35. Kopp, R.; Maynard, C.; Rocha, P.; Smart, L.; Abrahamson, L. Collection and storage of pollen from Salix (Salicaceae). Am. J. Bot. 2002, 89, 248–252. [Google Scholar] [CrossRef]
  36. Calic, D.; Milojevic, J.; Belic, M.; Miletic, R.; Zdravkovik-Korak, S. Impact of storage temperature on pollen viability and germinavility of four Serbian Autochthon Apple cultivars. Front. Plant Sci. 2021, 12, 709231. [Google Scholar] [CrossRef] [PubMed]
  37. Becker, W.; Ewart, L. Pollination, seed set and pollen tube growth investigation in Viola pedata L. Acta Hortic. 1990, 272, 33–36. [Google Scholar] [CrossRef]
  38. Dafni, A.; Firmage, D. Pollen viability and longevity: Practical, ecological and evolutionary implications. Plant Syst. Evol. 2000, 222, 113–132. [Google Scholar] [CrossRef]
  39. Bolat, I.; Pirlak, L. An investigation on pollen viability, germination and tube growth in some stone fruits. Turk. J. Agric. For. 1999, 23, 383–388. [Google Scholar]
  40. Melloni, M.; Salles, M.; De Mendonça, J.; Perecin, D.; De Andrade, M.; Pinto, L. Comparison of two staining methods for pollen viability studies in sugarcane. Sugar Technol. 2013, 15, 103–107. [Google Scholar] [CrossRef]
  41. Impe, D.; Reitz, J.; Köpnick, C.; Rolletscheck, H.; Börner, A.; Senula, A.; Nagel, M. Assessment of pollen viability for wheat. Front. Plant Sci. 2020, 10, 1588. [Google Scholar] [CrossRef] [PubMed]
  42. Camayo-Mosquera, J.; Cayón-Salinas, D.G.; Ligaretto-Moreno, G.A. Pollen viability and germination in Elaeis oleifera, Elaeis guineensis and their interspecific hybrid. Pesq. Agropec.Trop. Goiania 2021, 51, e68076. [Google Scholar]
  43. Silva, M.; Ribeiro, H.; Abreu, I.; Cruz, A.; Esteves da Silva, J. Effects of CO2 on Acer negundo pollen fertility, protein content, allergenic properties, and carbohydrates. Environ. Sci. Pollut. Res. 2015, 22, 6904–6911. [Google Scholar] [CrossRef]
  44. Strober, W. Trypan blue exclusion test of cell viability. Curr. Protoc. Immunol. 2001. [CrossRef]
  45. Melgar, M.; Trigo, M.; Recio, M.; Docampo, S.; García-Sánchez, J.; Cabezudo, B. Atmospheric pollen dynamics in 3Münster, north-western Germany: A three-year study (2004–2006). Aerobiología 2012, 28, 423–434. [Google Scholar] [CrossRef]
  46. Paupière, M.J.; van Heusden, A.W.; Bovy, A.G. The metabolic basis of pollen thermo-tolerance: Perspectives for breeding. Metabolites 2014, 30, 889–920. [Google Scholar] [CrossRef] [Green Version]
  47. Torabinejad, J.; Caldwell, M.; Flint, S.; Durham, S. Susceptibility of pollen to UV-B Radiation: An Assay of 34 taxa. American J. Bot. 1998, 85, 360. [Google Scholar] [CrossRef]
  48. Mesihovic, A.; Iannacone, R.; Firon, N.; Fragkostefanakis, S. Heat stress regimes for the investigation of pollen thermotolerance in crop plants. Plant Reprod. 2016, 29, 93–105. [Google Scholar] [CrossRef] [PubMed]
  49. Conde-Álvarez, R. Variaciones Espacio-Temporales y Ecofisiología de los Macrófitos Acuáticos de la Laguna Atalosohalina de Fuente de Piedra (Sur de la Península Ibérica); Tesis Doctoral, Universidad de Málaga: Málaga, Spain, 2001. [Google Scholar]
  50. Sousa, R.; Duque, L.; Duarte, A.; Gomes, C.; Ribeiro, H.; Cruz, A.; Esteves da Silva, J.; Abreu, I. In Vitro Exposure of Acer negundo pollen to atmospheric levels of SO2 and NO2: Effects on Allergenicity and Germination. Environ. Sci. Technol. 2012, 46, 2406–2412. [Google Scholar] [CrossRef] [PubMed]
  51. Galveias, A.; Costa, A.; Bortoli, D.; Alpizar-Jar, R.; Salgado, R.; Costa, M.; Antunez, C. Cupressaceae pollen in the city of Evora, South of Portugal: Disruption of the pollen during air transport facilitates allergen exposure. Forest 2021, 12, 64. [Google Scholar] [CrossRef]
  52. Peñuelas, J.; Filella, I.; Llusiá, J.; Siscart, D.; Piñol, J. Comparative field study of spring and summer leaf gas exchange and photobiology of the Mediterranean trees Quercus ilex and Phillyrea latifolia. J. Exp. Bot. 1998, 49, 229–238. [Google Scholar] [CrossRef] [Green Version]
  53. Del Valle, J.; Buide, M.; Whittall, J.; Valladares, F.; Narbona, E. UV radiation increases phenolic compound protection but decreases reproduction in Silene littorea. PLoS ONE 2020, 15, 231611. [Google Scholar] [CrossRef]
  54. Basuny, A.; Arafat, S.; Soliman, H. Chemical analysis of olive and palm pollen: Antioxidant and antimicrobial activation properties. Her. J. Agric. Food Sci. Res. 2013, 2, 91–97. [Google Scholar]
  55. Sénéchal, H.; Visez, N.; Charpin, D.; Shahali, Y.; Peltre, G.; Biolley, J.; Lhuissier, F.; Couderc, R.; Yamada, O.; Malrat-Domenge, A.; et al. A Review of the effects of major atmospheric pollutants on pollen grains, pollen content and allergenicity. Sci. World J. 2015, 53, 1–29. [Google Scholar] [CrossRef] [Green Version]
  56. Danti, R.; Della Rocca, G.; Calamassi, R.; Mori, B.; Mariotti, M. Insights into a hydration regulating system in Cupressus pollen grains. Ann. Bot. 2011, 108, 299–306. [Google Scholar] [CrossRef] [Green Version]
  57. Aboulaïch, N.; Bouziane, H.; Kadiri, M.; Riadi, H. Male phenology and pollen production of Cupressus sempervirens in Tetouan (Morocco). Grana 2008, 47, 130–138. [Google Scholar] [CrossRef] [Green Version]
  58. Plaza, M.; Alcázar, P.; Oteros, J.; Galán, C. Atmospheric pollutants and their association with olive and grass aeroallergen concentrations in Córdoba (Spain). Environ. Sci. Pollut. Res. 2020, 27, 45447–45459. [Google Scholar] [CrossRef] [PubMed]
  59. Rugini, E.; Gutiérrez, P. Genetic improvement of olive. Pomol. Croat. 2006, 12, 43–72. [Google Scholar]
  60. Bracci, T.; Busconi, M.; Fogher, C.; Sebastiani, L. Molecular studies in olive (Olea europaea L.): Overview on DNA markers applications and recent advances in genome analysis. Plant Cell Rep. 2011, 30, 449–462. [Google Scholar] [CrossRef] [PubMed]
  61. Rugini, E.; Biasi, R.; Muleo, R. Olive (Olea europaea var. sativa) transformation. In Molecular Biology of Woody Plants; Springer: Cham, Switzerland, 2000; pp. 245–279. [Google Scholar] [CrossRef]
  62. Alché, J.; Castro, A.; Jiménez-López, J.; Morales, S.; Zafra, A.; Hamman-Khalifa, A.; Rodríguez-García, M. Differential characteristics of olive pollen from different cultivars: Biological and clinical implications. J. Investig. Allergol. Clin. Immunol. 2007, 17, 17–23. [Google Scholar] [PubMed]
  63. Oteros, J.; Orlandi, F.; García-Mozo, H.; Aguilera, F.; Dhiab, A.; Bonofiglio, T.; Abichou, M.; Ruiz-Valenzuela, L.; Mar del Trigo, M.; Díaz de la Guardia, C.; et al. Better prediction of Mediterranean olive production using pollen-based models. Agron. Sustain. Dev. 2014, 34, 685–694. [Google Scholar] [CrossRef] [Green Version]
  64. Mattei, F.; Della, G.; Schiavoni, G.; Paoletti, E.; Afferni, C. Traffic-related NO2 affects expression of Cupressus sempervirens L. pollen allergens. Ann. Agric. Environ. Med. 2022, 29, 232–237. [Google Scholar] [CrossRef]
  65. Chichiriccó, G.; Picozzi, P. Reversible inhibition of the pollen germination and the stigma penetration in Crocus vernus spp. Vernus (Iridaceae) following fumigation with NO2, CO and O3 gases. Plant Biol. 2007, 9, 730–735. [Google Scholar] [CrossRef]
  66. Sheng, Q.; Song, M.; Zhu, Z.; Cao, F. Physiological and biochemical responses of two precious Carpinus species to high-concentration NO2 stress and their natural recovery. Sci. Rep. 2021, 11, 9500. [Google Scholar] [CrossRef]
  67. Sikkema, R.; Caudullo, G.; de Rigo, D. Carpinus betulus in Europe: Distribution, habitats, usage an threats. In European Atlas of Forest Tree Species; San Miguel-Ayanz, J., de Rigo, D., Caudullo, G., Houston Durrant, T., Muri, A., Eds.; Publications Office of the EU: Luxembourg, 2016. [Google Scholar]
  68. López-Lillo, A.; Sánchez de Lorenzo Cáceres, J.M. Árboles de España. Manual de Identificación; Mundi-Prensa: Madrid, Spain, 2001. [Google Scholar]
  69. Strashock, O. Comparative Analysis of Heat Resistance of Ornamental Urban Plants in Kyiv. J. Ecol. Eng. 2022, 23, 145–153. [Google Scholar] [CrossRef]
  70. Hidalgo-García, D.; Arco-Díaz, J. Modeling the Surface Urban Heat Island (SUHI) to study of its relationship with variations in the thermal field and with the indices of land use in the metropolitan area of Granada (Spain). Sustain. Cities Soc. 2022, 87, 104166. [Google Scholar] [CrossRef]
Forests 13 02131 g001 550
Figure 1. Location of the city of Granada and of the sampling points. 1: Fuentenueva Campus; 2: Cartuja Campus; 3: La Alhambra Forests; 4: Bola de Oro Sport Center; C1: Congress Palace station; C2: Cartuja Station; M1: IFAPA Station; M2: Air Base Station; M3: Cartuja Station.
Figure 1. Location of the city of Granada and of the sampling points. 1: Fuentenueva Campus; 2: Cartuja Campus; 3: La Alhambra Forests; 4: Bola de Oro Sport Center; C1: Congress Palace station; C2: Cartuja Station; M1: IFAPA Station; M2: Air Base Station; M3: Cartuja Station.
Forests 13 02131 g001
Forests 13 02131 g002 550
Figure 2. Cupressus pollen stained with Trypan blue (left) and Pyrogallol red (right).
Figure 2. Cupressus pollen stained with Trypan blue (left) and Pyrogallol red (right).
Forests 13 02131 g002
Table
Table 1. Sampling areas in the city of Granada. The reference station of the Surveillance and Control Network of Air Quality and of the State Meteorological Agency are indicated with numbers.
Table 1. Sampling areas in the city of Granada. The reference station of the Surveillance and Control Network of Air Quality and of the State Meteorological Agency are indicated with numbers.
Sampling AreaStress FactorReference
Air Quality
Station		Reference Meteorological Station
1. Fuentenueva Campusi, ii, iii, iv12
2. Cartuja Campusi, ii, iii21
3. La Alhambra ForestsCONTROL21
4. Bola de Oro Sport Centerii, iii13
Reference air quality station: 1: Congress Palace station; 2: Cartuja Station. Reference meteorological stations: 1: Cartuja Station; 2: IFAPA Station; 3: Air Base Station. i: intense traffic area; ii: high exposure to direct solar radiation; iii: area exposed to adverse environmental conditions; iv: area of high urban density.
Table
Table 2. Monthly average values for pollutants SO2, NO2 and CO measured in two locations of the city of Granada during the study period.
Table 2. Monthly average values for pollutants SO2, NO2 and CO measured in two locations of the city of Granada during the study period.
Granada NortePalacio de Congresos
Monthly Average Value
Monthly Average Value(µg/m3)
SO2(µg/m3)8.516.0
NO2(µg/m3)47.336.3
CO(mg/ m3)0.60.4
Table
Table 3. Monthly average UV-B radiation for the period January–May 2015.
Table 3. Monthly average UV-B radiation for the period January–May 2015.
UV-B (10 kJ/m2)
MonthAverage
January2.467
February2.956
March4.325
April5.428
May6.293
Table
Table 4. Percentage of viability (Trypan blue) and maturity (Pyrogallol red) of the 4 pollen types considered in this study.
Table 4. Percentage of viability (Trypan blue) and maturity (Pyrogallol red) of the 4 pollen types considered in this study.
Trypan BluePyrogallol Red
ControlSample *ControlSample *
Viable (%)Viable (%)Mature (%)Mature (%)
Acer negundo60.520.082.888.9
Carpinus betulus81.858.917.432.5
Cupressus spp.56.039.531.749.3
Olea europaea84.960.984.567.7
* Sample is Fuentenueva Campus for Acer negundo and Cupressus spp., Bola de Oro for Carpinus betulus, and Cartuja Campus for Olea europea.
Table
Table 5. Spearman’s correlation analysis between the percentage of viable and non-viable pollen (Trypan blue) and the concentrations of atmospheric pollutants during the pre-flowering and flowering periods.
Table 5. Spearman’s correlation analysis between the percentage of viable and non-viable pollen (Trypan blue) and the concentrations of atmospheric pollutants during the pre-flowering and flowering periods.
Pollen TypeLocationViabilityUV-B FebruaryUV-B MarchSO2 FebruarySO2 MarchNO2 FebruaryNO2 MarchCO FebruaryCO March
Acer negundoAlhambraViable0.018−0.102−0.1270.1190.0700.0460.121−0.013
Non-viable−0.1260.257−0.008−0.1260.2040.0860.1410.118
FuentenuevaViable0.192−0.064−0.331−0.078−0.302−0.3310.508 **0.112
Non-viable−0.412 *0.367 *0.067−0.0530.052−0.1090.2690.312
Carpinus betulusAlhambraViable0.089−0.0300.0740.1280.030−0.0710.074−0.034
Non-viable0.320 *−01940.0770.543 **−0.219−0.0410.028−0.483 **
Bola de oroViable−0.200−0.3110.003−0.423 *−0.053−0.083−0.2770.326
Non-viable0.101−0.1020.178−0.2620.1060.078−0.0370.444 *
Cupressus spp.AlhambraViable0.196−0.199−0.0130.173−0.245−0.020−0.099−0.157
Non-viable0.1068−0.445 *−0.0780.1990.0270.199−0.022−0.151
FuentenuevaViable−0.105−0.084−0.466 **−0.075−0.349−0.100−0.2270.070
Non-viable−0.0270.388 *−0.324−0.177−0.274−0.186−0.067−0.003
Olea europaeaAlhambraViable−0.409−0.0970.1570.0770.1280.3230.0300.380 *
Non-viable−0.190−0.086−0.0350.2170.070−0.0500.142−0.148
CartujaViable0.2950.240−0.180−0.099−0.051−0.080−0.0620.119
Non-viable0.025−0360 *0.086−0.442 *0.043−0.424 *−0.103−0.296
* The correlation is significant at 0.05. ** The correlation is significant at 0.01.
Table
Table 6. Spearman’s correlation analysis between the percentage of mature pollen (Pyrogallol red) and the concentrations of atmospheric pollutants during the pre-flowering and flowering periods.
Table 6. Spearman’s correlation analysis between the percentage of mature pollen (Pyrogallol red) and the concentrations of atmospheric pollutants during the pre-flowering and flowering periods.
Pollen TypeLocationMaturityUV-B FebruaryUV-B MarchSO2 FebruarySO2 MarchNO2 FebruaryNO2 MarchCO FebruaryCO March
Acer negundoAlhambraMature−0.173 **−0.162−0.214−0.032−0.084−0.314−0.013−0.356 *
Immature0.054 *−0.096−0.241−0.039−0.1900.424−0.3340.227
FuentenuevaMature−0.182−0.372−0.205−0.081−0.207−0.2890.101−0.036
Immature0.100−0.157−0.229−0.205−0.120−0.4580.0−0.422
Carpinus betulusAlhambraMature−0.020.0581−0.2700.161−0.221−0.228−0.143−0.176
Immature−0.016−0.2440.0350.2490.0070.071−0.093−0.229
Bola de oroMature−0.438 *0.175−0.1600.027−0.168−0.007−0.085−0.265
Immature0.1630.147−0.0860.0510.0170.038−0.0740.036
Cupressus spp.AlhambraMature−0.036−0.0760.182−0.0420.0220.3220.0860.025
Immature−0.109−0.1100.330−0.185−0.0940.119−0.0860.063
FuentenuevaMature−0.238 *0.179−0.166−0.327−0.079−0.279−0.093−0.103
Immature−0.042−0.1100.308−0.398 *0.387 *−0.391 *0.348−0.501 **
Olea europaeaAlhambraMature−0.0640.1770.086−0.123−0.051−0.180−0.1930.068
Immature−0.129−0.1110.008−0.123−0.028−0.2040.0880.132
CartujaMature0.3710.047−0.006−0.1510.088−0.104−0.1490.106
Immature0.377 *−0.180−0.0880.332−0.0980.203−0.2990.148
* The correlation is significant at 0.05. ** The correlation is significant at 0.01.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Ramírez-Aliaga, P.; Foyo-Moreno, I.; Cariñanos, P. Effects of Environmental Stress on the Pollen Viability of Ornamental Tree-Species in the City of Granada (South-Eastern Spain). Forests 2022, 13, 2131. https://doi.org/10.3390/f13122131

AMA Style

Ramírez-Aliaga P, Foyo-Moreno I, Cariñanos P. Effects of Environmental Stress on the Pollen Viability of Ornamental Tree-Species in the City of Granada (South-Eastern Spain). Forests. 2022; 13(12):2131. https://doi.org/10.3390/f13122131

Chicago/Turabian Style

Ramírez-Aliaga, Priscila, Inmaculada Foyo-Moreno, and Paloma Cariñanos. 2022. "Effects of Environmental Stress on the Pollen Viability of Ornamental Tree-Species in the City of Granada (South-Eastern Spain)" Forests 13, no. 12: 2131. https://doi.org/10.3390/f13122131

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop