Heterospecific Pollen Receipt Research Articles

Heterospecific pollen avoidance strategy prevails in the generalized plant-pollinator network on Yongxing Island.

Heterospecific pollen (HP) deposition varies widely among species in communities, which has been explicated by two adaptation strategies: HP avoidance and HP tolerance. Studies of the plant-pollinator network have uncovered that oceanic island communities are highly generalized and strongly connected. It remains unclear, however, which strategy prevails in such communities. We examined stigma pollen deposition on 29 plant species, and assessed patterns of HP load size and diversity in the Yongxing Island community. We assessed the effects of phenotypic specialization and species-level network structural properties of plant species on pollen deposition among species. The hypothesis of three accrual patterns of HP within species was tested by illustrating the relationship between conspecific pollen (CP) and HP receipt. Extensive variation occurred among species in HP receipt, while 75.9% of species received less than 10% HP and one species received more than 40% HP throughout the community. Flower size strongly drives the variation of HP receipt, while network structural properties had no effect on the pollen receipt. Nineteen species showed no relationship between the number of HP and CP loads, and they received smaller HP load sizes and lower HP proportions. Most plant species evolved HP avoidance strategy, and HP receipt was an occasional event for most plant species in the generalized community. HP and CP receipts are independent of each other in plant species with the HP avoidance mechanism. Our results highlight that plants in the generalized pollination system may preferentially select to minimize the HP load on stigmas.

Evaluating the influences of floral traits and pollinator generalism on α and β diversity of heterospecific pollen on stigmas

Abstract Pollinator sharing often leads to receipt of heterospecific pollen (HP) along with conspecific pollen. As a result, flowering plants can accumulate diverse communities of HP on stigmas. While variation in HP diversity is an important selective force contributing to flowering plant fitness, evolution and community assembly, our understanding of the extent and drivers of heterogeneity of HP diversity is limited. In this study, we examined the species compositions and abundances of ~1000 HP communities across 59 co‐flowering plant species in three serpentine seep communities in California, USA. We evaluated the variation in HP diversity (γ diversity) across plant species in each seep and asked whether the variation in HP γ diversity was caused by variation in HP diversity within stigmas (α diversity) or HP compositional variation among stigmas (β diversity) due to the replacement of HP species (turnover) or their loss (nestedness) from one stigma to another. We further evaluated the potential drivers of variation in HP α and β diversity using phylogenetic structural equation models. We found that variation in HP γ diversity across plant species was driven strongly by differences among species in HP α diversity and to a lesser extent by HP β diversity. HP community turnover contributed more to HP β diversity than nestedness consistently across plant species and seeps, suggesting a general pattern of HP compositional heterogeneity from stigma to stigma. The phylogenetic structural equation models further revealed that floral traits (e.g., stigma area, stigma‐anther distance, stigma exposure) and floral abundance were key in determining HP α diversity by influencing HP abundance (load size), while floral traits and abundance showed variable impact on HP β diversity (turnover and nestedness). Pollination generalism contributed relatively less to HP‐α and β diversity. These findings disentangle the heterogeneity in HP diversity at different levels, which is essential for understanding the process underlying patterns of HP receipt in plant communities. That floral traits drive the heterogeneity in HP diversity points to additional avenues by which HP receipt may contribute to plant evolution. Read the free Plain Language Summary for this article on the Journal blog.

Spatial variation of pollen receipt and effects of heterospecific pollen on seed set in Salvia przewalskii.

Generalized pollinators visit multiple co-flowering plant species and may transfer heterospecific pollen grains. Recent studies have indicated that the effect of heterospecific pollen (HP) on reproduction success is variable and depends on the identity of donor and recipient species. However, few studies have documented variation in HP receipt and evaluated the reproductive effects of HP receipt across geographic locations under natural conditions. We investigated the spatial variation of pollen deposition across eight sites and how the pollen receipt related to the seed set of Salvia przewalskii, a subalpine perennial herb in Hengduan Mountain in southwest China. We found that stigmatic pollen loads substantially varied among sites for several metrics, including quantities of conspecific and heterospecific pollen, the proportion of HP, and species composition of HP donors. Five different plant families were the most common HP source at one or two sites, and the proportion of HP ranged from 3.4% to 51.3% across sites. The association of conspecific pollen with seed set was positive and variable among sites, whereas the association of HP receipt and seed set was negative and not significantly different among sites. Our results demonstrate variation in the quantity and fitness effect of pollen receipt across sites, which is a precondition for evolution of local adaptation. Further study of variation in patterns and effects of HP receipt for the same recipient species across natural communities would allow better understanding of the ecological and evolutionary consequences of HP receipt.

Colour similarity to flowering neighbours promotes pollinator visits, pollen receipt and maternal fitness

While co-flowering plants often compete for pollination through pollinator visits and pollen transfer, recent studies reveal potential for the facilitation of pollination. Pollination may be promoted when similarities in the floral traits of co-flowering species enhance pollinator visitation and seed set. Floral similarity, however, could also lead to heterospecific pollen transfer, creating a fitness trade-off that is seldom explored empirically.Here we construct experimental communities of Oxalis to investigate the trade-off between enhanced visitation and heterospecific pollen receipt, which can impact seed set at varying relative plant abundance. Our experimental communities comprise O. purpurea that is matched or mismatched to congeners in flower colour at low and high relative plant abundance. We investigate the consequences of colour overlap for pollinator visitation and the receipt of conspecific, heterospecific, and mixed pollen loads, and assess seed set in natural plots.Flower colour similarity increases visitation by shared pollinators at both low and high relative abundance when O. purpurea occurs in matched flower colour communities. The receipt of pollen analogues from conspecifics is also greater at both abundances when neighbours are matched in floral colour. Although conspecific pollen in matched communities is mostly delivered in mixed pollen loads, hand pollinations confirm the receipt of mixed pollen carries no fitness costs for seed production. Consequently, plants in natural populations plots of O. purpurea experiences increase maternal fitness when growing in matching flower colour communities.We demonstrate a positive net effect of flower colour similarity, relative to flower colour dissimilarity, that can facilitate plant reproduction. Through field experiments we systematically test previously observed patterns of clustered flower colour assembly in Oxalis communities to provide a comprehensive assessment of facilitative co-flowering interactions.

A quick glance at noteworthy articles for September 2021

A quick glance at noteworthy articles for September 2021

Causes and consequences of variation in heterospecific pollen receipt in Oenothera fruticosa.

PremiseHeterospecific pollen transfer, the transfer of pollen between species, is common among co‐flowering plants, yet the amount of pollen received is extremely variable among species. Intraspecific variation in heterospecific pollen receipt can be even greater, but we lack an understanding of its causes and fitness consequences in wild populations.MethodsWe examined potential drivers of variation in heterospecific pollen receipt in Oenothera fruticosa. We evaluated the relationship between heterospecific and conspecific pollen receipt and considered how visitation by different pollinator groups, local floral neighborhood composition, and flowering phenology affect the total amount and proportion of heterospecific pollen received. Finally, we tested whether variation in heterospecific pollen receipt translated into lower seed production.ResultsHeterospecific pollen was ubiquitous on O. fruticosa stigmas, but the amount received was highly variable and unrelated to conspecific pollen receipt. Heterospecific pollen receipt depended on pollinator type, the proportion of nearby conspecific flowers, and flowering date. Significant interactions revealed that the effects of pollinator type and neighborhood were not independent, further contributing to variation in heterospecific pollen. Naturally occurring levels of heterospecific pollen were sufficient to negatively impact seed set, but large amounts of conspecific pollen counteracted this detrimental effect.ConclusionsAlthough selection could act on floral traits that attract quality pollinators and promote synchronous flowering in O. fruticosa, the risk of heterospecific pollen is equally dependent on local floral context. This work highlights how extrinsic and intrinsic factors contribute to intraspecific variation in heterospecific pollen receipt in wild plants, with significant fitness consequences.

Spatial variation in the intensity of interactions via heterospecific pollen transfer may contribute to local and global patterns of plant diversity

Studies that aim to understand the processes that generate and organize plant diversity in nature have a long history in ecology. Among these, the study of plant-plant interactions that take place indirectly via pollinator choice and floral visitation has been paramount. Current evidence, however, indicates that plants can interact more directly via heterospecific pollen (HP) transfer and that these interactions are ubiquitous and can have strong fitness effects. The intensity of HP interactions can also vary spatially, with important implications for floral evolution and community assembly. Interest in understanding the role of heterospecific pollen transfer in the diversification and organization of plant communities is rapidly rising. The existence of spatial variation in the intensity of species interactions and their role in shaping patterns of diversity is also well recognized. However, after 40 years of research, the importance of spatial variation in HP transfer intensity and effects remains poorly known, and thus we have ignored its potential in shaping patterns of diversity at local and global scales. Here, I develop a conceptual framework and summarize existing evidence for the ecological and evolutionary consequences of spatial variation in HP transfer interactions and outline future directions in this field. The drivers of variation in HP transfer discussed here illustrate the high potential for geographic variation in HP intensity and its effects, as well as in the evolutionary responses to HP receipt. So far, the study of pollinator-mediated plant-plant interactions has been almost entirely dominated by studies of pre-pollination interactions even though their outcomes can be influenced by plant-plant interactions that take place on the stigma. It is hence critical that we fully evaluate the consequences and context-dependency of HP transfer interactions in order to gain a more complete understanding of the role that plant-pollinator interactions play in generating and organizing plant biodiversity.

Recipient and donor characteristics govern the hierarchical structure of heterospecific pollen competition networks

Abstract Pollinator sharing can have negative consequences for plant fitness via competition for visits as well as with the arrival of heterospecific pollen. Plant traits and relatedness of donor and recipient species have been suggested to drive the observed variation in plant fitness effects of both processes, but how they shape the structure of interspecific pollen competition networks has been overlooked at the community level. To understand the importance of reproductive traits and relatedness to the impact of heterospecific pollen, we conducted a controlled glasshouse experiment with an artificial co‐flowering community. We performed 2,200 hand pollination crosses by experimentally transferring conspecific pollen alone or with 50% and 100% foreign pollen among 10 species belonging to three different plant families. Relative to conspecific pollen alone, there was a significant reduction in seed set with 50% heterospecific pollen for 67% of the crosses. This effect is driven largely by recipient traits and the interaction between recipient and donor traits under specific circumstances of trait matching. In general, species with shorter styles, smaller stigmas and lower pollen:ovule ratios were more impacted by heterospecific pollen. These traits and their differences among species led to a hierarchical (or transitive) structure of pollen competition with clear winners and losers. However, phylogenetic distance among recipient and donor species did not explain the effects. Synthesis. Our study shows that specific traits and trait combinations between donor and recipient species are important in determining seed production outcomes with heterospecific pollen receipt. Moreover, the differences in traits between species lead to a competitive structure with clear ‘winners’ or ‘losers’ species. The results of this study highlight the importance of specific traits in understanding the position of the competitive hierarchy of the species and the mechanisms underlying heterospecific pollen impacts upon plant reproductive success.

Pollen transfer networks reveal alien species as main heterospecific pollen donors with fitness consequences for natives

Abstract The ecological dynamics of co‐flowering communities are largely mediated by pollinators. However, current understanding of pollinator‐mediated interactions primarily relies on how co‐flowering plants influence attraction of shared pollinators, and much less is known about plant–plant interactions that occur via heterospecific pollen (HP) transfer. Invaded communities in particular can be highly affected by the transfer of alien pollen, but the strength, drivers and fitness consequences of these interactions at a community scale are not well understood. Here we analyse HP transfer networks in nine coastal communities in the Yucatan Mexico that vary in the relative abundance of invasive flowers to evaluate how HP donation and receipt varies between native and alien plants. We further evaluate whether HP donation and receipt are mediated by floral traits (e.g. display, flower size) or pollinator visitation rate. Finally, we evaluated whether post‐pollination success (proportion of pollen tubes produced) was affected by alien HP receipt and whether the effect varied between native and alien recipients. HP transfer networks exhibit relatively high connectance (c. 15%), suggesting high HP transfer within the studied communities. Significant network nestedness further suggests the existence of species that predominantly act as HP donors or recipients in the community. Species‐level analyses showed that natives receive 80% more HP compared to alien species, and that alien plants donate 40% more HP than natives. HP receipt and donation were mediated by different floral traits and such effects were independent of plant origin (native or alien). The proportion of alien HP received significantly affected conspecific pollen tube success in natives, but not that of alien species. Synthesis. Our results suggest that HP transfer in invaded communities is widespread, and that native and alien species play different roles within HP transfer networks, which are mediated by a different suite of floral traits. Alien species, in particular, play a central role as HP donors and are more tolerant to HP receipt than natives—a finding that points to two overlooked mechanisms facilitating alien plant invasion and success within native co‐flowering communities.

Patterns and effects of heterospecific pollen transfer between an invasive and two native plant species: the importance of pollen arrival time to the stigma.

Invasive plant species can integrate into native plant-pollinator communities, but the underlying mechanisms are poorly understood. Competitive interactions between invasive and native plants via heterospecific pollen (HP) and differential invasive HP effects depending on HP arrival time to the stigma may mediate invasion success, but these have been little studied. We evaluated patterns and effects of HP receipt on pollen tube growth in two native and one invasive species in the field. We also used hand-pollination experiments to evaluate the effect of invasive HP pollen and its arrival time on native reproductive success. Native species receive smaller and less-diverse HP loads (5-7 species) compared to invasive species (10 species). The load size of HP had a negative effect on the proportion of pollen tubes in both native species but not in the invasive, suggesting higher HP tolerance in the latter. Invasive HP arrival time differentially affected pollen tube success in native species. Our results highlight the need to study reciprocal HP effects between invasive and native species and the factors that determine differential responses to HP receipt to fully understand the mechanisms facilitating invasive species integration into native plant-pollinator communities.

Global geographic patterns of heterospecific pollen receipt help uncover potential ecological and evolutionary impacts across plant communities worldwide

Species interactions are known to be key in driving patterns of biodiversity across the globe. Plant-plant interactions through heterospecific pollen (HP) transfer by their shared pollinators is common and has consequences for plant reproductive success and floral evolution, and thus has the potential to influence global patterns of biodiversity and plant community assembly. The literature on HP transfer is growing and it is therefore timely to review patterns and causes of among-species variation in HP receipt at a global scale, thus uncovering its potential contribution to global patterns of biodiversity. Here we analyzed published data on 245 species distributed across five continents to evaluate latitudinal and altitudinal patterns of HP receipt. We further analyzed the role of floral symmetry and evolutionary history in mediating patterns of HP receipt. Latitude and elevation affected the likelihood and intensity of HP receipt indicating that HP transfer increases in species-rich communities and in areas with high abundance of vertebrate pollinators. Floral symmetry and evolutionary history determined HP load size across plant communities worldwide. Overall, our results suggest that HP receipt may have the potential to contribute to global geographic patterns of plant diversity by imposing strong selective pressures in species-rich areas across the globe.

Interactive effects between donor and recipient species mediate fitness costs of heterospecific pollen receipt in a co-flowering community.

Evaluation of pollen transfer in wild plant communities revealing heterospecific pollen receipt is common, yet experimental hand pollinations have revealed high among-species variation in the magnitude of its effect on recipient fitness. The causes of this among-species variation are unknown, however, prompting the investigation of underlying factors. Here, we conducted a hand-pollination experiment with ten co-flowering species to determine whether the effects of heterospecific pollen receipt are mediated by the pollen donor or recipient species alone, or whether the effects are determined by the interaction between them. We further assessed species traits potentially mediating interactive effects in heterospecific pollen receipt by evaluating the relationship between heterospecific pollen effect size and three different predictors reflecting a unique combination of pollen donor and recipient characteristics. Our results show, for the first time, that the magnitude of the heterospecific pollen receipt effect is determined by the specific combination of donor and recipient species (i.e., interactive effects). However, we were unable to uncover the specific combination of traits mediating these effects. Overall, our study provides strong evidence that an understanding of heterospecific pollen receipt effects based on recipient or donor characteristics alone may be insufficient. This study is an important step toward an understanding of consequences of heterospecific pollen receipt in co-flowering communities.

Adaptive Strategy of Co‐Flowering Species Reducing Deleterious Effects of Heterospecific Pollen Transfer

Pollinator visiting multiple co-flowering species is not uncommon in natural communities. Pollinator interspecific moves may bring or deliver heterospecific pollen among different plant species. Heterospecific pollen transfer (HPT) is deleterious to both pollen donor and receipt species, suggesting that co-flowering species may have evolved adaptive strategies to reduce the effects of HPT. One would predict that more pollinator interspecific moves result in higher HPT among interacting species given that HPT is mediated by interspecific moves. If there are no interspecific moves, HPT will not occur. However, heterospecific pollen carried by pollinators may not be picked up by stigmas of the next visiting plant species. A quantification of interspecific moves and consequent HPT involving 14 co-flowering species in an alpine meadow in the eastern Himalaya, southwest China, showed that plant species with more outgoing pollinator moves tended to disperse more of their own pollen to others, as expected. Interestingly, plant species which received more pollinator moves from other species received less HP, suggesting that only species with low acceptance of HP were likely to permit frequent pollinator moves. The paradoxical relation between pollinator interspecific moves and HP receipt unveils an adaptive strategy of co-flowering species limiting deleterious effects of HPT. Bumble bee carrying pollen from multiple plant species. Photograph by Shuang-Quan Huang. A colorful meadow in Shangri-La Alpine Botanical Garden, southwest China. Photograph by Shuang-Quan Huang. These photographs illustrate the article “A paradoxical mismatch between interspecific pollinator moves and heterospecific pollen receipt in a natural community” by Qiang Fang and Shuang-Quan Huang, published in Ecology 97:1970–1978, August 2016. http://dx.doi.org/10.1002/ecy.1433

A paradoxical mismatch between interspecific pollinator moves and heterospecific pollen receipt in a natural community.

Pollinators visiting multiple plant species may cause heterospecific pollen transfer (HPT). To test a null model that more pollinator interspecific moves result in higher HPT among interacting species, we quantified the comparative magnitudes of the two networks involving 14 co-flowering species in an alpine meadow in the eastern Himalaya, southwest China. Interspecific moves accounted for 4% of the total visits,whereas heterospecific pollen constituted 22% of the total stigmatic pollen loads. On average, plant species received interspecific moves and HPT from 6.9 and 9.7 other species, respectively. Although the two networks were largely concordant, 21.6% of interspecific move links were not correspondingly linked by HPT, and 44.1% of heterospecific pollen transfer links were not linked by moves. Plant species with more outgoing pollinator moves tended to disperse more of their own pollen to others, as expected. Surprisingly, our data reveal that plant species which received more pollinator moves from other species tended to receive less HP, implying that only species with low acceptance of HP were likely to permit frequent pollinator moves. These new findings unveil a paradoxical relation between pollinator interspecific moves and HP receipt, suggesting an adaptive strategy of co-flowering species that reduces deleterious effects of HPT.

Invasion status and phylogenetic relatedness predict cost of heterospecific pollen receipt: implications for native biodiversity decline

SummaryUnderstanding the mechanisms by which invasive species affect native plants is a central challenge. Invasive plants have been shown to reduce pollinator visitation to natives and increase pollen quantity limitation. However, visitation and conspecific pollen delivery are the only two components of the pollination process; post‐pollination interactions on the stigma (heterospecific pollen [HP] receipt) could intensify pre‐pollination responses to invasion.Here, we used meta‐analysis to test the hypotheses that invasive plants are more detrimental asHPdonors than natives ones and thatHPdonors that are closely related to the recipients have stronger effects on fruit and seed production compared to distantly related ones.InvasiveHPdonors reduced fruit and seed production of recipients to a greater degree than native ones, and this was more intense forHPdonors closely related to natives. Related donors were more detrimental overall.Synthesis. These results suggest that the total effect of invasive plants on native plant reproductive success could be greater than what is inferred from visitation and conspecific pollen transfer alone. Furthermore, these results indicate that invasive species can reduce reproductive success of native species even if pollinator visitation rates remain unaltered. Thus, we highlight the need to evaluate pre‐ and post‐pollination processes in order to fully understand the potential effects of invasive species on the reproductive success and maintenance of native plant populations.

Patterns of among- and within-species variation in heterospecific pollen receipt: The importance of ecological generalization.

Coflowering plants are at risk for receiving pollen from heterospecifics as well as conspecifics, yet evidence shows wide variation in the degree that heterospecific pollen transfer occurs. Evaluation of patterns and correlates of among- and within-species variation in heterospecific pollen (HP) receipt is key to understanding its importance for floral evolution and species coexistence; however, the rarity of deeply sampled multispecies comparisons has precluded such an evaluation. We evaluated patterns of among- and within-species variation in HP load size and diversity in 19 species across three distinct plant communities. We assessed the importance of phenotypic specialization (floral phenotype), ecological specialization (contemporary visitor assemblage), and conspecific flower density as determinants of among-species variation. We present hypotheses for different accrual patterns of HP within species based on the evenness and quality of floral visitors and evaluated these by characterizing the relationship between conspecific pollen (CP) and HP receipt. We found that within-species variation in HP receipt was greater than among-species and among-communities variation. Among species, ecological generalization emerged as the strongest driver of variation in HP receipt irrespective of phenotypic specialization. Within-species variation in HP load size and diversity was predicted most often from two CP-HP relationships (linear or exponentially decreasing), suggesting that two distinct types of plant-pollinator interactions prevail. Our results give important insights into the potential drivers of among- and within-species variation in HP receipt. They also highlight the value of explorations of patterns at the intraspecific level, which can ultimately shed light on plant-pollinator-mediated selection in diverse plant communities.

Can plants evolve tolerance mechanisms to heterospecific pollen effects? An experimental test of the adaptive potential inClarkiaspecies

Flowering plants do not occur alone and often grow in mixed‐species communities where pollinator sharing is high and interactions via pollinators can occur at pre‐ and post‐pollination stages. While the causes and consequences of pre‐pollination interactions have been well studied little is known about post‐pollination interactions via heterospecific pollen (HP) receipt, and even less about the evolutionary implications of these interactions. In particular, the degree to which plants can evolve tolerance mechanisms to the negative effects of HP receipt has received little attention. Here, we aim to fill this gap in our understanding of post‐pollination interactions by experimentally testing whether two co‐floweringClarkiaspecies can evolve HP tolerance, and whether tolerance to specific HP ‘genotypes’ (fine‐scale local adaptation to HP) occurs. We find thatClarkiaspecies vary in their tolerance to HP effects. Furthermore, conspecific pollen performance and the magnitude of HP effects were related to the recipient's history of exposure to HP inC. xantianabut not inC. speciosa. Specifically, better conspecific pollen performance and smaller HP effects were observed in populations ofC. xantianaplants with previous exposure to HP compared to populations without such exposure. These results suggest that plants may have the potential to evolve tolerance mechanisms to HP effects but that these may occur not from the female (stigma, style) but from the male (pollen) perspective, a possibility that is often overlooked. We find no evidence for fine‐scale local adaptation to HP receipt. Studies that evaluate the adaptive potential of plants to the negative effects of HP receipt are an important first step in understanding the evolutionary consequences of plant–plant post‐pollination interactions. Such knowledge is in turn crucial for deciphering the role of plant–pollinator interactions in driving floral evolution and the composition of co‐flowering communities.

A first test of elemental allelopathy via heterospecific pollen receipt.

Coflowering plants often share pollinators and may receive mixed species pollen loads. Although detrimental effects of heterospecific pollen receipt have been documented, trait-based modifiers of interactions on the stigma remain largely unknown. Chemicals that mediate interactions between sporophytes could also influence pollen-pollen or pollen-style interactions. We test for the first time whether nickel (Ni) accumulation in pollen can lead to "elemental allelopathy" and intensify the fitness consequences of heterospecific pollen receipt. We grew Ni-hyperaccumulator Streptanthus polygaloides in soils augmented with three concentrations of Ni, measured pollen Ni concentration, and hand-pollinated non-Ni hyperaccumulator Mimulus guttatus. We assayed pollen germination, tube growth and seeds of M. guttatus after pure and mixed species pollinations. Streptanthus polygaloides pollen accumulated Ni in proportion to soil availability and at levels significantly greater than M. guttatus pollen. Although receipt of S. polygaloides pollen increased M. guttatus pollen germination, it decreased the proportion of pollen tubes reaching the ovary and seed number. Increased Ni in pollen, however, did not significantly intensify the effect of S. polygaloides pollen receipt on M. guttatus seed production. Different levels of Ni in the pollen of S. polygaloides achieved in the greenhouse did not significantly reduce the fitness of M. guttatus. Stigma tolerance to Ni may also have contributed to the lack of response to increased Ni in heterospecific pollen. This study paves the way for additional tests in other metal hyperaccumulators and recipients, and to identify mechanisms of interactions on the stigma.

Negative effects of heterospecific pollen receipt vary with abiotic conditions: ecological and evolutionary implications

Studies that have evaluated the effects of heterospecific pollen (HP) receipt on plant reproductive success have generally overlooked the variability of the natural abiotic environment in which plants grow. Variability in abiotic conditions, such as light and water availability, has the potential to affect pollen-stigma interactions (i.e. conspecific pollen germination and performance), which will probably influence the effects of HP receipt. Thus, a more complete understanding of the extent, strength and consequences of plant-plant interactions via HP transfer requires better consideration of the range of abiotic conditions in which these interactions occur. This study addresses this issue by evaluating the effects of two HP donors (Tamonea curassavica and Angelonia angustifolia) on the reproductive success of Cuphea gaumeri, an endemic species of the Yucatan Peninsula. Mixed (conspecific pollen and HP) and pure (conspecific pollen only) hand-pollinations were conducted under varying conditions of water and light availability in a full factorial design. Reproductive success was measured as the number of pollen tubes that reached the bottom of the style. Only one of the two HP donors had a significant effect on C. gaumeri reproductive success, but this effect was dependent on water and light availability. Specifically, HP receipt caused a decrease in pollen tube growth, but only when the availability of water, light or both was low, and not when the availability of both resources was high. The results show that the outcome of interspecific post-pollination interactions via HP transfer can be context-dependent and vary with abiotic conditions, thus suggesting that abiotic effects in natural populations may be under-estimated. Such context-dependency could lead to spatial and temporal mosaics in the ecological and evolutionary consequences of post-pollination interactions.

Breeding system of <i>Linum rigidum</i> and effect of heterospecific pollen from introduced <i>Euphorbia esula</i>

This study investigates the reproductive biology of, and effect of heterospecific pollen from introduced Euphorbia esula on, Linum rigidum, an annual plant native to western and central North America. Breeding-system studies revealed that L. rigidum is self-compatible, with similar pollination success, fruit set and seed set for flowers pollinated with self or outcrossed pollen. Untreated flowers not exposed to pollinators set seed, albeit at a lower rate than hand-pollinated flowers, indicating that L. rigidum can autonomously self pollinate. Experiments investigating whether heterospecific pollen transfer from E. esula interferes with pollination of L. rigidum indicated that large amounts of heterospecific pollen receipt 2 - 4 hours prior to conspecifc pollen receipt reduced fruit and seed production, but that small amounts of heterospecific pollen or larger amounts received immediately prior to conspecific pollen did not affect reproduction. Pollen of E. esula was observed to germinate on and penetrate into L. rigidum stigmas and styles. Nevertheless, Euphorbia esula is unlikely to interfere with L. rigidum’s reproduction because L. rigidum is self-compatible, capable of autonomous self-pollination, and unaffected by receipt of small amounts of Euphorbia pollen.