ABSTRACT

Host-parasite interactions between plants may reduce the vegetative and reproductive performance of the host plant. Although it is well established that parasitic plants may negatively affect the metabolism and the number of vegetative/reproductive structures of their hosts, the effects of this interaction on the reproductive characteristics of the host plant are poorly understood. Here we document the interaction between Cuscuta partita (Convolvulaceae) and its main host, Zornia diphylla (Fabaceae), in the Caatinga of northeastern Brazil. We measured diverse reproductive/vegetative attributes of Z. diphylla in 60 plots randomly distributed in patches that were parasitized and not parasitized by C. partita. Both vegetative and reproductive attributes, such as the number of branches, leaves and flowers, and the individual biomass of Z. diphylla were significantly reduced by the parasitism. The number of pollen grains and ovules per flower were not affected by the parasitism, but since the parasitism reduced flower production, the total number of pollen and ovules per individual and population may also be reduced. Additionally, pollen viability was significantly reduced in the flowers of parasitized individuals. We conclude that C. partita may negatively impact the vegetative and reproductive performance of its main host, Z. diphylla in distinct ways in the Caatinga.

Keywords
Caatinga; Cuscuta partita; floral traits; haustoria; holoparasitic plants; plant-plant interaction; pollen viability; reproductive success; Zornia diphylla

Hemi- and holoparasitic plants may significantly impair the metabolism and the development of vegetative and reproductive structures, such as branches, leaves, flowers, seeds and fruits of many host species (e.g. Hibberd et al. 1996Hibberd JM, Quick WP, Press MC, Scholes JD. 1996. The influence of the parasitic angiosperm Striga gesnerioides on the growth and photosynthesis of its host, Vigna unguiculata. Journal of Experimental Botany 47: 507-512.; Fernandes et al. 1998Fernandes GW, Mattos EA, Franco AC, Lüttge U, Ziegler H. 1998. Influence of the parasite Pilostyles ingae (Rafflesiaceae) on some physiological parameters of the host plant, Mimosa naguirei (Mimosaceae). Botanica Acta 111: 51-54.; Puustinen & Salonen 1999Puustinen S, Salonen V. 1999. Effects of intensity and duration of infection by a hemiparasitic plant, Rhinathus serotinus, on growth and reproduction of a perennial grass, Agrostis capillaris. Ecography 22: 160-168.; Silva & Rio 1996Silva A, Rio CM. 1996. Effects of the mistletoe Tristerix aphyllus (Loranthaceae) on the reproduction of in cactus host Echinopsis chilensis. Oikos 75: 437-442.; Irving & Cameron 2009Irving LJ, Cameron DD. 2009. You are what you eat: interactions between root parasitic plants and their hosts. Advances in Botanical Research 50: 87-138.; Mourão et al. 2009Mourão FA, Jacobi CM, Figueira JEC, Batista EKL. 2009. Effects of parasitism of Struthanthus flexicaulis (Mart.) Mart. (Loranthaceae) on the fitness of Mimosa calodendron Mart. (Fabaceae), an endemic shrub from rupestrian fields over ironstone outcrops, Minas Gerais State, Brazil. Acta Botanica Brasilica 23: 820-825.; Bahia et al. 2015Bahia TO, Zúñiga IG, Souza ML, Coutinho ES, Quesada M, Fernandes GW. 2015. Hemiparasitism effect on Baccharis dracunculifolia DC. and consequences to its major galling herbivore. Acta Botanica Brasilica 29: 339-345.). Additionally, extreme levels of infestation by holoparasitic species may cause host death and changes in plant community composition (e.g. Aukema 2003Aukema JE. 2003. Vectors, viscin and Viscaceae: mistletoes as parasites, mutualists and resources. Frontiers in Ecology and the Environment 1: 212-219.; Grewell 2008Grewell BJ. 2008. Parasite facilitates plant species coexistence in a coastal wetland. Ecology 89: 1481-1488.; Graffis & Kneitel 2015Graffis AM, Kneitel JM. 2015. A parasitic plant increases native and exotic plant species richness in vernal pools. AoB Plants 7: plv100 doi: 10.1093/aobpla/plv100.
https://doi.org/10.1093/aobpla/plv100... ; Těšitel et al. 2016Těšitel J. 2016. Functional biology of parasitic plants: a review. Plant Ecology and Evolution 149: 5-20.). In total, holoparasitic plants comprise more than 400 species distributed in 87 genera (Leake 1994Leake JR. 1994. The biology of myco-heterotrophic (‘saprophytic’) plants. New Phytologist 127: 171-216.; Riches & Parker 1995Riches CR, Parker C. 1995. Parasitic plants as weeds. In: Press MC, Graves JD. (eds.) Parasitic plants. London, Chapman and Hall. p. 226-255.). Currently, Cuscuta (Convolvulaceae) is one of the largest genera of holoparasitic plants including 170-200 species (Costea & Stefanović 2010Costea M, Stefanović S. 2010. Evolutionary history and taxonomy of the Cuscuta umbellate complex (Convolvulaceae): evidence of extensive hybridization from discordant nuclear and plastid phylogenies. Taxon 73: 1-18.).

Resource acquisition by holoparasitic plants proceeds exclusively via haustoria, which drains water and metabolites from the bundles of the host plant (Pennings & Callaway 2002Pennings CS, Callaway RM. 2002. Parasitic plants: parallels and contrasts with herbivores. Oecologia 131: 479-489.). In addition to photosynthate reallocation, holoparasitic plants may stimulate the secretion of hormones by the host plant, directly inoculating the host structures with their own hormones or mRNA (Knutson 1979Knutson DM. 1979. How parasitic seed plants induce disease in other plants. In: Horsfall JG, Cowling EB. (eds.) Plant disease, an advanced treatise. San Diego, Academic Press. p. 293-312.; Ihl et al. 1984Ihl B, Jabob J, Sembdner F. 1984. Studies on Cuscuta reflexa Roxb. V. The level of endogenous hormones in the parasite, Cuscuta reflexa and its host, Vicia faba L. and a suggested role of in the transfer of nutrients from host to parasite. Journal of Plant Growth and Regulation 2: 77-90.; Westwood et al. 2010Westwood JH, Yoder JI, Timko MP, dePamphilis CW. 2010. The evolution of parasitism in plants. Trends in Plant Science 15: 227-235.). In this sense, holoparasitic plants may negatively impact many metabolic and physiological aspects of their host plants, such as stomata opening, photosynthesis rate, transpiration, hormone secretion or water-use efficiency (Goldstein et al. 1989Goldstein G, Rada F, Sternberg L, et al. 1989. Gas exchange and water balance of mistletoe species and its mangrove hosts. Oecologia 78: 176-183.; Fernandes et al. 1998Fernandes GW, Mattos EA, Franco AC, Lüttge U, Ziegler H. 1998. Influence of the parasite Pilostyles ingae (Rafflesiaceae) on some physiological parameters of the host plant, Mimosa naguirei (Mimosaceae). Botanica Acta 111: 51-54.; Sala et al. 2001Sala A, Carey EV, Callaway RM. 2001. Dwarf mistletoe affects whole-tree water relations of Douglas-fir and western larch primarily through changes in leaf to sapwood ratios. Oecologia 126: 42-52.; Runyon et al. 2008Runyon JB, Mescher MC, Moraes CM. 2008. Parasitism by Cuscuta pentagona attenuates host plant defenses against insect herbivores. Plant Physiology 146: 987-995.; Prider et al. 2009Prider J, Walting J, Facelli JM. 2009. Impacts of a native parasitic plant on an introduced and a native host species: implications for the control of an invasive seed. Annals of Botany 103: 107-115.).

Because of the parasitism, host plants may also exhibit reduced individual biomass, which is mainly associated with changes in physiological processes caused by the parasite plant (Irving & Cameron 2009Irving LJ, Cameron DD. 2009. You are what you eat: interactions between root parasitic plants and their hosts. Advances in Botanical Research 50: 87-138.; Westwood et al. 2010Westwood JH, Yoder JI, Timko MP, dePamphilis CW. 2010. The evolution of parasitism in plants. Trends in Plant Science 15: 227-235.). Changes in the biomass of parasitized plants are represented by reductions in the number of branches, leaves, flowers and fruits (Gomes & Fernandes 1994Gomes AL, Fernandes W. 1994. Influence of parasitism by Pilostyles ingae (Rafflesiaceae) on its host plant, Mimosa naguirei (Leguminosae). Annals of Botany 74: 205-208.; Koskela et al. 2002Koskela T, Puustinen S, Salonen V, Mutikainen P. 2002. Resistance and tolerance in a host plant-holoparasitic plant interaction: genetic variation and costs. Evolution 56: 899-908.). Additionally, parasitic interactions may negatively affect the root development of host plants (Irving & Cameron 2009Irving LJ, Cameron DD. 2009. You are what you eat: interactions between root parasitic plants and their hosts. Advances in Botanical Research 50: 87-138.). The intensity of damage caused by the parasitic plant to the host species may change depending on the strategies of acquisition of resources by the parasite or on the genetic diversity and origin of the species involved in the parasitic interaction (Koskela et al. 2002Koskela T, Puustinen S, Salonen V, Mutikainen P. 2002. Resistance and tolerance in a host plant-holoparasitic plant interaction: genetic variation and costs. Evolution 56: 899-908.; Press & Phoenix 2005Press MC, Phoenix GK. 2005. Impacts of parasitic plants on natural communities. New Phytologist 166: 737-751.; Prider et al. 2009Prider J, Walting J, Facelli JM. 2009. Impacts of a native parasitic plant on an introduced and a native host species: implications for the control of an invasive seed. Annals of Botany 103: 107-115.; Li et al. 2012Li J, Jin Z, Song W. 2012. Do native parasitic plants cause more damage to exotic invasive hosts than native non-invasive hosts? An implication for biocontrol. PLoS ONE 7: e34577 doi: 10.1371/journal.pone.0034577.
https://doi.org/10.1371/journal.pone.003... ).

Once parasitic plants have severely reduced host performance, parasitism may lead to changes in competitive interactions between host and non-host plants and impact the community structure, diversity, vegetation cycling and zonation (Pennings & Callaway 2002Pennings CS, Callaway RM. 2002. Parasitic plants: parallels and contrasts with herbivores. Oecologia 131: 479-489.; Aukema 2003Aukema JE. 2003. Vectors, viscin and Viscaceae: mistletoes as parasites, mutualists and resources. Frontiers in Ecology and the Environment 1: 212-219.; Grewell 2008Grewell BJ. 2008. Parasite facilitates plant species coexistence in a coastal wetland. Ecology 89: 1481-1488.; Graffis & Kneitel 2015Graffis AM, Kneitel JM. 2015. A parasitic plant increases native and exotic plant species richness in vernal pools. AoB Plants 7: plv100 doi: 10.1093/aobpla/plv100.
https://doi.org/10.1093/aobpla/plv100... ; Mourão et al. 2016Mourão FA, Pinheiro RBP, Javobi CM, Figueira JEC. 2016. Host preference of the hemiparasite Struthanthus flexicaulis (Loranthaceae) in ironstone outcrop plant communities, southeast Brazil. Acta Botanica Brasilica 30: 41-46.). These effects on community structure are often dynamic and may change depending on the performance of the parasite itself or due to environmental conditions (Pennings & Callaway 2002Pennings CS, Callaway RM. 2002. Parasitic plants: parallels and contrasts with herbivores. Oecologia 131: 479-489.; Press & Phoenix 2005Press MC, Phoenix GK. 2005. Impacts of parasitic plants on natural communities. New Phytologist 166: 737-751.; Grewell 2008Grewell BJ. 2008. Parasite facilitates plant species coexistence in a coastal wetland. Ecology 89: 1481-1488.; Irving & Cameron 2009Irving LJ, Cameron DD. 2009. You are what you eat: interactions between root parasitic plants and their hosts. Advances in Botanical Research 50: 87-138.; Graffis & Kneitel 2015Graffis AM, Kneitel JM. 2015. A parasitic plant increases native and exotic plant species richness in vernal pools. AoB Plants 7: plv100 doi: 10.1093/aobpla/plv100.
https://doi.org/10.1093/aobpla/plv100... ). An aggressive parasite can drive a preferred host to local extinction, which may, in turn, result in the local extinction of the parasite (e.g.Press & Phoenix 2005Press MC, Phoenix GK. 2005. Impacts of parasitic plants on natural communities. New Phytologist 166: 737-751.; Mourão et al. 2009Mourão FA, Jacobi CM, Figueira JEC, Batista EKL. 2009. Effects of parasitism of Struthanthus flexicaulis (Mart.) Mart. (Loranthaceae) on the fitness of Mimosa calodendron Mart. (Fabaceae), an endemic shrub from rupestrian fields over ironstone outcrops, Minas Gerais State, Brazil. Acta Botanica Brasilica 23: 820-825.). Additionally, by inducing changes in the physiological processes of host plants, parasitism could influence the occurrence of plant species in particular habitats, depending on local temperature, light intensity and rainfall (Pennings & Callaway 2002Pennings CS, Callaway RM. 2002. Parasitic plants: parallels and contrasts with herbivores. Oecologia 131: 479-489.; Westwood et al. 2010Westwood JH, Yoder JI, Timko MP, dePamphilis CW. 2010. The evolution of parasitism in plants. Trends in Plant Science 15: 227-235.).

The Caatinga is a Brazilian seasonally dry forest characterized by low rainfall that is irregularly distributed throughout the year, with long periods of drought, low levels of air humidity and high temperatures (e.g. Leal et al. 2003Leal IR, Tabarelli M, Silva JMC. 2003. Ecologia da conservação da Caatinga. Recife, Editora Universitária UFPE.). Despite these abiotic restrictions, the Caatinga shows high levels of biodiversity and ecological interactions (sensuLeal et al. 2003Leal IR, Tabarelli M, Silva JMC. 2003. Ecologia da conservação da Caatinga. Recife, Editora Universitária UFPE.). Many of these interactions related to pollination and seed dispersal have been extensively described for the Caatinga (e.g. Machado et al. 1997Machado IC, Barros LM, Sampaio EVSB. 1997. Phenology of Caatinga species at Serra Talhada, PE, northeastern Brazil. Biotropica 29: 57-58.; Leal et al. 2003Leal IR, Tabarelli M, Silva JMC. 2003. Ecologia da conservação da Caatinga. Recife, Editora Universitária UFPE.; 2007Leal IR, Wirth R, Tabarelli M. 2007. Seed dispersal by ants in the semi-arid Caatinga of Northeast Brazil. Annals of Botany 99: 885-894.; Machado & Lopes 2004Machado IC, Lopes AV. 2004. Floral traits and pollination systems in the Caatinga, a Brazilian tropical dry forest. Annals of Botany 94: 365-376. and references therein), while interactions documenting parasitism between plants in this phytogeographical domain are, as far as we know, nonexistent.

Although it is well established that parasitic plants may negatively affect the metabolism, physiology and number of vegetative and reproductive structures of their hosts, the outcomes of this interaction on the host’s reproductive process (e.g. number of pollen and ovules and pollen viability) are poorly understood. By using two common herbaceous plant species in the Caatinga, the aim of this study was to understand and quantify the effects of holoparasitism by Cuscuta partita Choisy (Convolvulaceae) on the growth and development of the vegetative and reproductive structures of its host Zornia diphylla (L.) Pers. (Fabaceae). We hypothesized that the holoparasitic C. partita negatively affect the development of the vegetative and reproductive structures of its host plant, Z. diphylla.

This study was carried out in a private area named Fazenda Olho d’ Água, at Parnamirim, Pernambuco, Brazil (8º5'26"S, 39º34'42"W). The climate in this region is classified as semiarid, with low rainfall, remarkable seasonality and unpredictable precipitation (Nimer 1972Nimer E. 1972. Climatologia da Região Nordeste do Brasil: Introdução à climatologia dinâmica. Revista Brasileira de Geografia 34: 3-51.). The vegetation in the study site is of the hyperxerophitic type, characterized by the presence of a deciduous forest dominated by shrubs and trees, but with a representative presence of annual herbs in the rainy season mainly in the areas with planosols (CPRM 2005CPRM - Serviço Geológico do Brasil. 2005. Projeto cadastro de fontes de abastecimento por água subterrânea. Diagnóstico do município de Parnamirim, estado de Pernambuco. Recife, CPRM/ PRODEEM. ).

Zornia diphylla (Fabaceae) is an annual herb largely distributed in South and Central Americas, and in the southern region of North America (Mohlenbrock 1961Mohlenbrock RH. 1961. A monograph of the leguminous genus Zornia. Webbia 16: 1-141.). It has numerous creeping stems and trifoliate leaves; flowers are yellow and medium-sized (10-20 mm; sensuMachado & Lopes 2004Machado IC, Lopes AV. 2004. Floral traits and pollination systems in the Caatinga, a Brazilian tropical dry forest. Annals of Botany 94: 365-376.) with red macules in the central portion of the flag petal, representing a nectar guide (Fig. 1A) for bees; fruits are legumes with four to six seeds.

The holoparasitic C. partita (Convolvulaceae) lack true roots, leaves and chlorophyll and exhibit numerous haustoria (Prather & Tyrl 1993Prather LA, Tyrl RJ. 1993. The biology of Cuscuta attenuata Waterfall (Cuscutaceae). Proceedings of Oklahoma Academic Science 73: 7-13.). It has small white flowers (<10 mm; sensuMachado & Lopes 2004Machado IC, Lopes AV. 2004. Floral traits and pollination systems in the Caatinga, a Brazilian tropical dry forest. Annals of Botany 94: 365-376.) that secrete nectar as a floral reward (Riches & Parker 1995Riches CR, Parker C. 1995. Parasitic plants as weeds. In: Press MC, Graves JD. (eds.) Parasitic plants. London, Chapman and Hall. p. 226-255.). The species occurs in patches across the study landscape and preferentially parasitizes individuals of Z. diphylla in the study site (O Cruz-Neto unpubl. res.) (Fig. 1B-F).

In total, we sampled 40 patches occupied by C. partita in the study site. Based on this sampling, we randomly chose 30 patches for our study. Control plots were randomly selected near each selected patch occupied by C. partita. In these control plots, individuals of C. partita were absent, i.e. not found parasitizing any other plant. We distributed a single 0.25 m² plot in each parasitized and non-parasitized patch. These two treatments were paired distributed and the distance between plots in a single pair of parasitized and non-parasitized patches ranged from two to six meters. Additionally, the distance between pairs of parasitized and non-parasitized plots ranged from 10 to 15 m. By randomly choosing the patches and the plots, we expected to include distinct levels of intensity of the parasitic interaction in the study site.

In each plot, we counted the number of flowers of Z. diphylla. We sampled only individuals that were totally included, or with at least 90 % of their branches, in the limits of each plot. The number of leaves, branches and flowers was counted for each individual of Z. diphylla. Additionally, the length of the branches (cm) and the size of the flag petal (mm) from different flowers (N= 120) were measured in the field. The size of the flag petal was represented by its width, which together with floral symmetry, has a direct influence on attractiveness to floral visitors (e.g. Hileman 2014Hileman LC. 2014. Bilateral flower symmetry - how, when and why? Current Opinion in Plant Biology 17: 146-152.; Potts 2016Potts JG. 2016. Effects of floral symmetry on pollination in Bidens aristosa. The Southwestern Naturalist 60: 370-373.). All the sampled plants of Z. diphylla were collected, dried at 56-60°C for 36-48 hours and finally weighed to obtain their individual biomass (g).

We also randomly collected one pre-anthesis floral bud of Z. diphylla per plot in order to check the number of ovules per ovary, number of pollen grains per flower and pollen viability. Based on the 30 collected flower buds per treatment, we randomly choose 20 for the measurements and counting. All buds were fixed in 70 % alcohol. A Neubauer chamber was used to estimate the total number of pollen grains per flower (Maêda 1985Maêda JM. 1985. Manual para uso da Câmara de Neubauer para contagem de grãos de pólen em espécies florestais. Rio de Janeiro, UFRJ, Departamento de Silvicultura, Seropédica.). Pollen viability was inferred by the presence of cytoplasmatic content in each grain using a staining technique with 1.2 % acetic-carmine solution (Radford et al. 1974Radford AE, Dickinson WC, Massey R, Bell CR. 1974. Vascular plant systematics. New York, Harper and Row Publishers.), where stained grains are considered viable and non-stained, i.e. without cytoplasmatic content, are inviable. Because the absence of cytoplasmatic content in a pollen grain is impeditive for its germination, a significantly higher number of grains without such content may predict lower pollen viability. To obtain the number of ovules per bud/flower, we longitudinally sectioned the ovaries to access and count the ovules.

We used the Kolmogorov-Smirnov test to check the normality of the data. The data were log transformed except for the number of ovules per ovary and number of flowers per plot and per individual. To investigate the changes of vegetative and reproductive attributes of Z. diphylla between parasitized and non-parasitized plots, we used a paired T test or Wilcoxon signed-rank test, depending on the normality of the data. The statistical significance was assessed by the one tailed p-value (P < 0.05). All the tests were performed using the software Infostat/F v.2013 (Rienzo et al. 2013Rienzo JAD, Casanoves F, Balzarini MG, Gonzalez L, Tablada M, Robledo CW. 2013. InfoStat versión 2016. Córdoba, InfoStat Group, Facultad de Ciencias Agropecuarias, Universidad Nacional de Córdoba. URL URL http://www.infostat.com.ar . 30 Mar. 2016.
http://www.infostat.com.ar... ).

All of the analyzed vegetative attributes of Z. diphylla were negatively impacted by interaction with C. partita (Tab. 1). The individual biomass of Z. diphylla was significantly reduced by 33.1 % by the parasitism. In this case, individuals of Z. diphylla exhibited an average biomass of 12.7 g in non-parasitized patches and 8.5 g in parasitized ones. These changes in biomass were represented by significant reductions of 53.9 % in the number of leaves, 29.8 % in the production of branches and 18.7 % in the length of branches in parasitized individuals of Z. diphylla.

Regarding reproductive traits, the average number of Z. diphylla flowers per plot was significantly reduced by 77.3 % in plots with the presence of the parasite (Tab. 1). The non-parasitized plants had an average of 20.2 flowers/day per individual during the field observations, while parasitized plants exhibited an average of 5.6 flowers/day, indicating a significant reduction of 72.1 % in flower production per individual.

In the case of the flower morphology, the average size of the flag petal, the number of ovules per ovary and the number of pollen grains per flower were not significantly affected by the parasitism of C. partita (Tab. 1). However, when we consider that the parasitism reduced the number of flowers per individual, it consequently reduced these traits per individual/population. Additionally, pollen viability was significantly reduced on average from 94.4 % in non-parasitized plants to 59.3 % in parasitized plants of Z. diphylla.

The deleterious effects of the parasite on the vegetative and reproductive performance of Z. diphylla may be caused by the establishment of haustoria on many of the host plant’s structures. Haustoria may act as drains that redirect photosynthates into the parasite and thus change the physiological patterns of its host (Ihl et al. 1984Ihl B, Jabob J, Sembdner F. 1984. Studies on Cuscuta reflexa Roxb. V. The level of endogenous hormones in the parasite, Cuscuta reflexa and its host, Vicia faba L. and a suggested role of in the transfer of nutrients from host to parasite. Journal of Plant Growth and Regulation 2: 77-90.; Bock & Fer 1992Bock FD, Fer A. 1992. Effects of abscisic acid on the transfer of sucrose from host, Pelargonium zonale (L.) Aiton, to a phanerogamic parasite Cuscuta reflexa Roxb. Australian Journal of Plant Physiology 19: 679-691.; Parker & Riches 1993Parker C, Riches CR. 1993. Parasitic weeds of the world: biology and control. Wallingford, CAB International.). Specifically, parasitic interactions associated with the establishment of haustoria may lead to changes in the photosynthetic parameters of host species, such as the average of CO₂ partial intracellular pressure and photosynthetic electron transport rates (e.g. Gomes & Fernandes 1994Gomes AL, Fernandes W. 1994. Influence of parasitism by Pilostyles ingae (Rafflesiaceae) on its host plant, Mimosa naguirei (Leguminosae). Annals of Botany 74: 205-208.; Fernandes et al. 1998Fernandes GW, Mattos EA, Franco AC, Lüttge U, Ziegler H. 1998. Influence of the parasite Pilostyles ingae (Rafflesiaceae) on some physiological parameters of the host plant, Mimosa naguirei (Mimosaceae). Botanica Acta 111: 51-54.; Runyon et al. 2008Runyon JB, Mescher MC, Moraes CM. 2008. Parasitism by Cuscuta pentagona attenuates host plant defenses against insect herbivores. Plant Physiology 146: 987-995.; Prider et al. 2009Prider J, Walting J, Facelli JM. 2009. Impacts of a native parasitic plant on an introduced and a native host species: implications for the control of an invasive seed. Annals of Botany 103: 107-115.; Li et al. 2012Li J, Jin Z, Song W. 2012. Do native parasitic plants cause more damage to exotic invasive hosts than native non-invasive hosts? An implication for biocontrol. PLoS ONE 7: e34577 doi: 10.1371/journal.pone.0034577.
https://doi.org/10.1371/journal.pone.003... ). Because of these changes, parasitized plants may exhibit a reduced number of leaves, branches, flowers and individual biomass, relative to non-parasitized plants, as may be the case for Z. diphylla in the Caatinga.

Regarding reproductive structures, parasitic interactions often affect the reproductive performance of the host by reducing the production of flowers and fruits and the seed quality (e.g. Silva & Rio 1996Silva A, Rio CM. 1996. Effects of the mistletoe Tristerix aphyllus (Loranthaceae) on the reproduction of in cactus host Echinopsis chilensis. Oikos 75: 437-442.; Puustinen & Salonen 1999Puustinen S, Salonen V. 1999. Effects of intensity and duration of infection by a hemiparasitic plant, Rhinathus serotinus, on growth and reproduction of a perennial grass, Agrostis capillaris. Ecography 22: 160-168.; Mourão et al. 2009Mourão FA, Jacobi CM, Figueira JEC, Batista EKL. 2009. Effects of parasitism of Struthanthus flexicaulis (Mart.) Mart. (Loranthaceae) on the fitness of Mimosa calodendron Mart. (Fabaceae), an endemic shrub from rupestrian fields over ironstone outcrops, Minas Gerais State, Brazil. Acta Botanica Brasilica 23: 820-825.). Indeed, in the case of parasitism in Z. diphylla, we documented a reduction of 72 % in flower production. Despite the fact that parasitism reduced the production of flowers of Z. diphylla, changes in petal dimensions between parasitized and non-parasitized plants were not significant. We emphasize that floral traits such as dimensions of petals are mostly related to genetic and natural selection factors in many plant species (sensuWeiss et al. 2005Weiss J, Delgado-Benarroch L, Egea-Cortines M. 2005. Genetic control of floral size and proportions. The International Journal of the Developmental Biology 49: 513-525.; Krizek & Anderson 2013Krizek BA, Anderson JT. 2013. Control of flower size. Journal of Experimental Botany 64: 1427-1437.), as may be the case for Z. diphylla.

Floral dimensions such as the symmetry of floral parts, scent and color and size of petals may exert a strong influence on pollinator attraction and thus on the fruit and seed set of many plant species (e.g., Giurfa et al. 1996Giurfa M, Eichmann B, Menzel R. 1996. Symmetry perception in an insect. Nature 382: 458-461.; Galen 1999Galen C. 1999. Why do flowers vary? The functional ecology of variation in flower size and form within natural plant populations. Bioscience 49: 631-640.; Karron & Mitchell 2012Karron JD, Mitchell RJ. 2012. Effects of floral display size on male and female reproductive success in Mimulus ringens. Annals of Botany 109: 563-570.; Hileman 2014Hileman LC. 2014. Bilateral flower symmetry - how, when and why? Current Opinion in Plant Biology 17: 146-152.; Potts 2016Potts JG. 2016. Effects of floral symmetry on pollination in Bidens aristosa. The Southwestern Naturalist 60: 370-373.). Because the size and symmetry of the flag petals of Z. diphylla were not affected by interaction with C. partita, it is possible that this parasitic interaction does not affect the individual attractiveness of the host plant flowers. On the other hand, C. partita may possibly impact the nectar secretion and anthesis of Z. diphylla, since the parasite plant may drain water and essential metabolites and promote changes in the flower physiology of the host species.

Surprisingly, although the numbers of ovules and pollen grains per flower were similar in parasitized and nonparasitized individuals of Z. diphylla (these numbers were clearly reduced when considering the reduction caused by parasites to the number of flowers per individual), pollen viability was significantly reduced by the parasitism. We emphasize that the parasitism of C. partita on Z. diphylla may act beyond the redirection of resources and the hormonal control of the host plant, as has been described for many interactions involving other species of parasitic plants (e.g.,Knutson 1979Knutson DM. 1979. How parasitic seed plants induce disease in other plants. In: Horsfall JG, Cowling EB. (eds.) Plant disease, an advanced treatise. San Diego, Academic Press. p. 293-312.; Puustinen & Salonen 1999Puustinen S, Salonen V. 1999. Effects of intensity and duration of infection by a hemiparasitic plant, Rhinathus serotinus, on growth and reproduction of a perennial grass, Agrostis capillaris. Ecography 22: 160-168.; Pennings & Callaway 2002Pennings CS, Callaway RM. 2002. Parasitic plants: parallels and contrasts with herbivores. Oecologia 131: 479-489.; Runyon et al. 2008Runyon JB, Mescher MC, Moraes CM. 2008. Parasitism by Cuscuta pentagona attenuates host plant defenses against insect herbivores. Plant Physiology 146: 987-995.). In this sense, cell division processes during the development of vegetative and generative cells of pollen grains of Z. diphylla may also be affected by parasites.

In conclusion, parasitism by C. partita is severely impairing the development of the vegetative and reproductive structures of Z. diphylla in the Caatinga. The direct effect of parasitism by C. partita on the reproductive success of Z. diphylla is related mainly to the reduction of the number of flowers and, consequently, of the fruit and seed sets of the host plant. The indirect effect is associated with the reduction in the number of pollen grains and in the quality of the pollen released by the flowers of Z. diphylla in parasitized patches, which would result in even more reduced fruit and seed sets. Future studies aiming to investigate the reproductive success of host and parasitic plants in different generations should be useful to identify the relative roles of the direct and indirect effects of parasitism in herbaceous communities in the Caatinga.

Acknowledgements

We thank J. A. Siqueira Filho for kindly identifying the studied species and P. Blažek and P. Svetlikova for their constructive reviews. Financial support and logistical and field infrastructures were provided by PROCAD-CAPES (n. 0166057), UFPE, UFRPE and UFMG. Additional financial support was provided by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (post-doctoral fellowship to OCN) and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) (Research Grants to AVL, IRL and JCS) .

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