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Seed germination of Cistanche armena (Orobanchaceae), a rare endangered holoparasitic species endemic to Armenia

Published online by Cambridge University Press:  23 March 2023

Yuliya Krasylenko Open the ORCID record for Yuliya Krasylenko [Opens in a new window] ,
Adelá Hýlová Open the ORCID record for Adelá Hýlová [Opens in a new window] ,
Yevhen Sosnovsky Open the ORCID record for Yevhen Sosnovsky [Opens in a new window] ,
Markéta Ulbrichová Open the ORCID record for Markéta Ulbrichová [Opens in a new window] ,
Lukáš Spíchal Open the ORCID record for Lukáš Spíchal [Opens in a new window]  and
Renata Piwowarczyk Open the ORCID record for Renata Piwowarczyk [Opens in a new window]
Yuliya Krasylenko*
Affiliation:
Department of Biotechnology, Faculty of Science, Palacký University Olomouc, Šlechtitelů 241/27, 783-71 Olomouc, Czech Republic
Adelá Hýlová
Affiliation:
Department of Chemical Biology and Genetics, Faculty of Science, Palacký University, Center of the Region Haná for Biotechnological and Agricultural Research, Šlechtitelů 241/27, 783-71 Olomouc, Czech Republic
Yevhen Sosnovsky
Affiliation:
Botanical Garden, Ivan Franko National University of Lviv, Cheremshyny St. 44, 79014 Lviv, Ukraine
Markéta Ulbrichová
Affiliation:
Centre of the Region Haná for Biotechnological and Agricultural Research, Czech Advanced Technology and Research Institute (CATRIN), Palacký University Olomouc, Šlechtitelů 241/27, 783-71 Olomouc, Czech Republic
Lukáš Spíchal
Affiliation:
Centre of the Region Haná for Biotechnological and Agricultural Research, Czech Advanced Technology and Research Institute (CATRIN), Palacký University Olomouc, Šlechtitelů 241/27, 783-71 Olomouc, Czech Republic
Renata Piwowarczyk
Affiliation:
Center for Research and Conservation of Biodiversity, Institute of Biology, Jan Kochanowski University, 7 Uniwersytecka St., 25-406 Kielce, Poland
*
*Author for Correspondence: Yuliya Krasylenko, E-mail: yuliya.krasylenko@upol.cz
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Abstract

The obligate root parasite Cistanche armena is a recently rediscovered, extremely rare endangered species endemic to Armenia, specifically parasitizing camelthorn (Alhagi maurorum, Fabaceae) and saltwort (Salsola dendroides, Chenopodiaceae). Its populations are reputedly declining due to habitat destruction and biotic impacts. Since the only known means of its reproduction is via the seeds, understanding the mechanisms of breaking C. armena seed dormancy and germination along with the related aspects of the species’ biology is highly important both from fundamental (functional ecology and evolution) and applied (conservation and management) perspectives. Here, we present the first in vitro seed germination protocol for C. armena involving fluridone, a systemic herbicide targeting the carotenoid biosynthetic pathway. In addition, the seed micromorphology of C. armena is described using both light microscopy and lignin autofluorescence visualized by confocal laser scanning microscopy. The actin cytoskeleton in radicle cells of germinated C. armena seedlings is described for the first time, being the proof of seed viability. Further elaboration and application of the proposed germination protocol with the cultivation of C. armena on susceptible hosts are altogether seen as a valuable tool for the conservation of this species.

Keywords

actincytoskeletonfluridoneGR24root holoparasiteseed dormancy
Type
Research Paper
Information
Seed Science Research , Volume 33 , Issue 2 , June 2023 , pp. 118 - 125
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

The obligately root-parasitic Orobanchaceae, renowned for their host specificity, reportedly gain much evolutionary success from the production of a plethora of tiny (ca. 1 mm long) ‘dust seeds’ (Eriksson and Kainulainen, Reference Eriksson and Kainulainen2011). Unlike the non-parasitic angiosperms, whose germination requires mostly an optimal combination of abiotic factors (such as temperature, light and moisture), the holoparasitic Orobanchaceae naturally germinate only in close proximity to the host root and (predominantly) in response to the root exudates containing special germination stimuli – the carotenoid-derived phytohormones strigolactones (Yoneyama et al., Reference Yoneyama, Xie, Sekimoto, Takeuchi, Ogasawara, Akiyama, Hayashi and Yoneyama2008; Bouwmeester et al., Reference Bouwmeester, Li, Thiombiano, Rahimi and Dong2021). In turn, in vitro germination of these plants typically requires a conditioning period, usually in darkness and under the temperature mimicking natural growth conditions of a species followed by the treatment of the conditioned seeds with the specific host root exudates, root extracts and/or artificial chemicals to break their physiological dormancy (Pouvreau et al., Reference Pouvreau, Gaudin, Auger, Lechat, Gauthier, Delavault and Simier2013; Matusova et al., Reference Matusova, Kullacova and Toth2014; Bouwmeester et al., Reference Bouwmeester, Li, Thiombiano, Rahimi and Dong2021). Other bioactive compounds such as gibberellic (GA) and abscisic (ABA) acids are also important for breaking Orobanchaceae seed dormancy (Bao et al., Reference Bao, Yao, Cao, Peng, Xu, Chen and Zhao2017). Such a complicacy of initial stages of the life cycle is presumed to secure against the premature ‘suicidal’ germination, when no susceptible hosts are available nearby the parasitic seeds in the soil. Combating this protection by adding strigolactone-containing growth regulators to the soil will pave the way for integrating the suicidal germination approach in sustainable root-parasitic weed management strategies (Jamil et al., Reference Jamil, Wang, Yonli, Patil, Riyazaddin, Gangashetty, Berqdar, Chen, Traore, Margueritte, Zwanenburg, Bhoge and Al-Babili2022).

The Old World holoparasitic genus Cistanche (Orobanchaceae), commonly named ‘ginseng of the desert’, contains about 25 species, favouring arid, semi-arid and halophytic habitats across Eurasia and North Africa. These impressive yet barely understood root-holoparasites often specialize on the species of Chenopodiaceae, Zygophyllaceae and Tamaricaceae as hosts (Piwowarczyk et al., Reference Piwowarczyk, Sanchez Pedraja, Moreno Moral, Fayvush, Zakaryan, Kartashyan and Aleksanyan2019). The herbaceous stems of some Cistanche species (e.g. C. salsa, C. deserticola, C. sinensis, C. tubulosa, etc.) have been used for centuries in the traditional Chinese medicine as a herbal tea and functional food supplement with a plethora of confirmed medicinal functions due to the increased amounts of phenylethanoid glycosides with antioxidant properties, the content of which is host- and organ-dependent (Li et al., Reference Li, Lin, Gu, Gao and Tzeng2016; Piwowarczyk et al., Reference Piwowarczyk, Ochmian, Lachowicz, Kapusta, Sotek and Błaszak2020). Consequently, most Cistanche species are endangered and declining because of their overharvesting, aggravated by the extensive utilization of some of their host plants, such as a saxaul (Haloxylon ammodendron) used as firewood. The high demand for this product has stimulated multiple attempts of Cistanche domestication and further cultivation in some regions of China (Xu et al., Reference Xu, Chen, Chen, Liu, Zhu and Xu2009). Therefore, habitat protection along with the studies of various aspects of Cistanche biology (e.g. germination, haustorium formation and host associations) would contribute to the multi-level strategy of its conservation.

The recently rediscovered endemic species from Armenia (Western Asia), Cistanche armena (K. Koch) M.V. Agab., is an obligate root parasite of a camelthorn (Alhagi maurorum Medik., Fabaceae) and saltwort (Salsola dendroides Pall., Chenopodiaceae), flowering from May to early June and fruiting from June to July (Piwowarczyk et al., Reference Piwowarczyk, Kwolek, Góralski, Denysenko, Joachimiak and Aleksanyan2017, Reference Piwowarczyk, Sanchez Pedraja, Moreno Moral, Fayvush, Zakaryan, Kartashyan and Aleksanyan2019). It is known only from the Ararat and Armavir provinces in Central Armenia, in the Arax River valley and foot of Mount Ararat, on the border between Armenia, Turkey and Nakhchivan (Piwowarczyk et al., Reference Piwowarczyk, Sanchez Pedraja, Moreno Moral, Fayvush, Zakaryan, Kartashyan and Aleksanyan2019; Fig. 1a–f). The species is currently confirmed only at two locations in one of the hottest and extremely arid regions of Armenia (Piwowarczyk et al., Reference Piwowarczyk, Sanchez Pedraja, Moreno Moral, Fayvush, Zakaryan, Kartashyan and Aleksanyan2019). Both the habitat and the range of C. armena have a total area of less than 10 km2, with only several hundreds of individuals remaining because of the habitat degradation, intense amelioration works and arable land expansion (Piwowarczyk et al., Reference Piwowarczyk, Kwolek, Góralski, Denysenko, Joachimiak and Aleksanyan2017, Reference Piwowarczyk, Sanchez Pedraja, Moreno Moral, Fayvush, Zakaryan, Kartashyan and Aleksanyan2019). Besides the abiotic stresses, C. armena suffers from extreme parasitization by the hoverfly larvae (Eumerus mucidus Bezzi, Syrphidae), while its key host, A. maurorum, is highly infested with the stem-parasitic Eastern dodder (Cuscuta monogyna Vahl., Convolvulaceae) (Piwowarczyk et al., Reference Piwowarczyk, Góralski, Denysenko-Bennett, Kwolek, Joachimiak and Fayvush2018; Piwowarczyk and Mielczarek, Reference Piwowarczyk and Mielczarek2018). Consequently, C. armena is considered critically endangered (Piwowarczyk et al., Reference Piwowarczyk, Sanchez Pedraja, Moreno Moral, Fayvush, Zakaryan, Kartashyan and Aleksanyan2019). Largely because of the extremely narrow distribution range and rarity, the biology and ecology of C. armena are barely known. No studies have addressed seed germination in C. armena, with only few published works being known that have challenged this aspect of biology in congeneric species such as C. deserticola (Li et al., Reference Li, Xu, Ge and Xu1989; Niu et al., Reference Niu, Song, Guo, Ma, Li, Zheng and Gao2006; Chen et al., Reference Chen, Wang, Wang, Shan, Zhai and Guo2009, Reference Chen, Li, Chen, Zhang and Song2012; Zhang et al., Reference Zhang, Bai, Lü, Chen and Gao2008, Reference Zhang, Chen, Zhang, Bai and Gao2009; Wang et al., Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017), C. salsa (Qiao et al., Reference Qiao, Wang and Guo2007) and C. tubulosa (Yang et al., Reference Yang, Zhang and Zhuang2007; Chen et al., Reference Chen, Jia, Wang, Shan, Zhu and Guo2011, Reference Chen, Guo, Jiang and Tu2016). Therefore, establishment of the working protocol of C. armena germination, unravelling its early developmental stages, biology and distribution mechanisms, as well as search for the new easy-culturable potential hosts (particularly in the Fabaceae and Chenopodiaceae) are seen as relevant and important steps in developing a complex strategy of the species’ conservation with possible cultivation for medicinal purposes.

Fig. 1. General appearance, habitat and seed micromorphology of C. armena: flowering (a,b) and fruiting (c) individuals on their host plants in semi-desert habitats in Armenia (d–f); seed polymorphism observed with ZOOM stereomicroscopy (g–i); lignin autofluorescence revealed by CLSM (j–l). Scale bars: (g–i) 200 μm; (j,k) 100 μm; (l) 50 μm.

The aim of this work was to design a feasible protocol for breaking C. armena seed dormancy and confirm viability of germinated seedlings by actin cytoskeleton visualization. For germination experiments, fluridone (1-methyl-3-phenyl-5-[3-trifluoromethyl(phenyl)]-4(1H)-pyridinone), a systemic herbicide known to act as an ABA-biosynthesis inhibitor, was used. It has been reported to regulate seed conditioning and germination in parasitic and some non-parasitic plants (Ali-Rachedi et al., Reference Ali-Rachedi, Bouinot, Wagner, Bonnet, Sotta, Grappin and Jullien2004; Chae et al., Reference Chae, Yoneyama, Takeuchi and Joel2004; Song et al., Reference Song, Cao, Jin and Zhou2005; Chen et al., Reference Chen, Guo, Jiang and Tu2016; Wang et al., Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017). Fluridone reduced the conditioning period prior to exposure of S. asiatica seeds to the natural strigolactone strigol (10−10 M) and, when applied alone, induced haustorium formation (Kusumoto et al., Reference Kusumoto, Chae, Mukaida, Yoneyama, Yoneyama, Joel and Takeuchi2006). To the best of our knowledge, we have designed the first protocol for breaking seed dormancy and germination of C. armena.

Materials and methods

Plant material

The mature seeds of C. armena parasitizing A. maurorum and S. dendroides were harvested in south-eastern Armenia, Ararat province, Ararat valley near Khor Virap (39°53″01′N, 44°34″49′E, 818 m a.s.l.) on halophytic vegetation in a semi-desert in May 2016 and July 2017. After the seed harvesting, the material of C. armena (whole individuals with several host-plant branches) was dried under the natural conditions and deposited in the Herbarium KTC (Jan Kochanowski University in Kielce, Poland). In addition, the seeds of two other widespread Orobanchaceae species were used in the experimental design (see below): seeds of the lesser broomrape (Orobanche minor aggr.), growing on an asteraceous host, were collected in 2011 in Porto Cevro (Sardinia) and deposited in the Herbarium KTC, and those of the purple witchweed (Striga hermonthica (Delile) Benth.) from an unknown monocot host were collected in 2007 in Sudan and kindly provided by Prof. Binne Zwanenburg (Radboud University Nijmegen, Netherlands).

Germination assay: seed surface sterilization, conditioning and stimulants

The seeds of C. armena were surface-sterilized for 6 min in 4% v/v sodium hypochlorite and 0.1% v/v Triton X-100 solution under vigorous stirring, then thoroughly washed five times in laminar flow cabinet with MilliQ water using vacuum pump (VACUUBRAND, Germany), a fritted borosilicate glass S3 (Sinter, Czechoslovakia) with a rubber stopper sterilized by UV- and 96% ethanol, and an autoclaved 500 ml Büchner flask. Two layers of filter paper (Whatman, 32 mm in diameter) were placed into each well of a sterile Greiner CELLSTAR 12-well cell culture plate (Greiner Bio-One, Austria) and moistened with 1 ml of ½ Murashige and Skoog medium (½ MS; Duchefa, Netherlands) with 1% w/v sucrose (Murashige and Skoog, Reference Murashige and Skoog1962). Two sterile glass fibre filter paper disks (Whatman, GF/D, 10 mm in diameter) were put into each well and sterile seeds after their sedimentation were dispersed on each disk using a sterile wooden toothpick. The moisture inside the plates was kept by adding the sterile MilliQ water in all spaces between the wells. Plates were thoroughly sealed with parafilm and wrapped in aluminium foil to provide darkness. The seeds of C. armena were exposed to cold stratification at 4°C in darkness for 4 d and then placed into an incubator at 21°C. The same procedure was followed for O. minor and S. hermonthica seeds, with the difference that they were not cold-stratified but were conditioned (Pouvreau et al., Reference Pouvreau, Gaudin, Auger, Lechat, Gauthier, Delavault and Simier2013). Prior to treatments with germination stimulants, the seeds were conditioned (i.e. warm-stratified and imbibed in ½ MS medium) for 7–10 d at 21°C in darkness (except S. hermonthica, which requires conditioning at 30°C). Then, the discs were transferred to a sterile filter paper, aseptically dried for 15 min under flow hood, and placed back to plates. Stock solutions of fluridone (Fluka; Sigma-Aldrich, USA) were preliminary prepared in 0.96% v/v ethanol to 0.3 mM concentration and stored at −20°C for 14 d maximum (Barua et al., Reference Barua, Butler, Tisdale and Donohue2012).

Seed germination was stimulated by imbibition with 100 μl of 0.03 and 0.3 mM fluridone per disk with the final acetone concentration of 0.1% v/v in 100 μl of ½ MS medium. Although sterile MilliQ water can serve an efficient substitute of the ½ MS medium for seeds’ imbibition, we kept the conditions as close as possible to the physiological ones to enable visualization of actin filaments, which are very sensitive to the cultivation medium content and usually degrade when seeds are germinated in water.

A synthetic strigolactone GR24 (Chiralix, Netherlands) was dissolved ex tempore in anhydrous acetone to prepare a 10 mM stock solution and used at 1 μM final concentration. Gibberellin (GA3) stock was prepared in DMSO and diluted 1:1000 in ½ MS to a final solvent percentage of 0.1 (v/v) (Halouzka et al., Reference Halouzka, Zeljkovic, Klejdus and Tarkowski2020).

For double treatments of seeds, the disks imbibed with fluridone (as described above) were kept at 21°C (30°C for S. hermonthica) in darkness overnight. Next day, the fluridone was carefully washed away with ½ MS medium, the disks were dried for 15 min, and 100 μl of 1 μM GA3 (in 0.1% acetone) per disc was added.

All treated seeds were placed back into the incubator and cultivated under 21 or 30°C and darkness for up to 1.5 months, checking their germination status. To examine the germination efficiency and radicle morphology, the seeds were captured with Axio Zoom.V16 Stereo Zoom microscope (Carl Zeiss, Germany) in bright-field illumination (objective lenses PlanApo Z 1.5x, FWD = 30 mm) and processed in ImageJ software using Fiji macros (Schneider et al., Reference Schneider, Rasband and Eliceiri2012). Error bars represent standard deviation in three biological repetitions (n ≥ 150).

F-actin visualization

Actin filaments in the radicle cells were revealed by Alexa Fluor 568-conjugated phalloidin (Thermo Fisher Scientific) following Panteris’ et al. (Reference Panteris, Apostolakos and Galatis2006) protocol with minor modifications. Germinated C. armena seeds (4th–7th day post-germination (dpg)) were incubated in 300 μM m-maleimidobenzoyl-N-hydroxysuccinimide ester (MBS), prepared from a 300 mM DMSO stock, in PEM with 0.1% (v/v) Triton X-100 in darkness for 30 min for actin filament stabilization. Subsequently, they were fixed in 4% (w/v) PFA + 5% (v/v) DMSO and 1:400 phalloidin, rinsed thoroughly and extracted with 5% (v/v) DMSO + 1% (v/v) Triton X-100 and 1:400 phalloidin during 1 h. The staining itself was performed with 1:40 phalloidin in the PBS buffer at 37°C for 2 h. DNA was counterstained with 250 μg ml−1 4,6-diamidino-2-phenylindole (DAPI, Sigma) in PBS for 10 min and after final washing in PBS the specimens were mounted in an antifade solution (0.5% (w/v) p-phenylenediamine in 70% (v/v) glycerol in PBS or 1 M Tris-HCl, pH 8.0) or in the commercial antifade mounting medium VECTASHIELD™ (Vector Laboratories).

Microscopy

General seed morphology was imaged by Axio Zoom.V16 Stereo Zoom system (Carl Zeiss, Germany) in bright-field illumination (objective lenses PlanApo Z 1.5x, FWD = 30 mm). For testa micromorphology imaging based on lignin autofluorescence in non-fixed samples, we employed a LSM710 confocal laser scanning microscope (Carl Zeiss, Jena, Germany) argone laser line with excitation of 568 nm and emission spectra 603 nm for red fluorescence using a 20× Plan-Apochromat (0.8 numerical aperture) objective. Laser excitation intensity did not exceed 2% of the laser intensity range. Images were presented as maximum intensity projections of Z-stacks processed in Zen Blue 2012 software package (Carl Zeiss, Jena, Germany). For the imaging of phalloidin-labelled actin, the fluorescent signal from Alexa Fluor 568 (Thermo Fisher Scientific) was visualized with 20×/0.8NA Plan-Apochromat, 40×/1.40NA and 63×/1.40NA Plan-Apochromat objectives with oil immersion. The DAPI fluorescence signal in nuclei was imaged using excitation laser line 405 nm and emission spectra 410–495 nm.

Results

Breaking seed dormancy in the Orobanchaceae seeds

Combined application of fluridone and GA3 was most efficient in stimulating the germination of C. armena seeds (Fig. 2). Contrarily, the seeds of O. minor and S. hermonthica germinated best when treated with GR24 but showed very modest response to the application of fluridone alone and in combination with GA3.

Fig. 2. Germination of the Orobanchaceae seeds: (a) germination rate (%) of C. armena, O. minor and S. hermonthica on the 22nd day after treatment with germination stimulants; (b) control, conditioned seeds incubated without any germination stimulants, 22nd day in ½ MS medium; (c–f) germinated seeds with emerged radicles (indicated by arrows) imaged by a ZOOM microscope at 22nd day after fluridone and GA3 treatment. Scale bars: (b,c) 2000 μm; (d–f) 500 μm.

It is noteworthy that fluridone and GA3 triggered C. armena seed germination only when added sequentially, not simultaneously. Without the conditioning and stimulation, less than 1% of C. armena seeds germinated spontaneously, which was lower than in O. minor (1–2%) and S. hermonthica (4–5%). Some of the spontaneously germinated seeds formed terminal haustoria without the addition of haustorium-inducing factors. However, neither stimulant was sufficient for the germination of C. armena seeds at 21°C without their cold pre-stratification for at least 4 d. Even the cold-stratified seeds of C. armena germinated with significantly longer delay (starting from the 22nd day and till the 40th day after fluridone and GA3 treatment) as compared to O. minor and S. hermonthica, whose germination occurred within the 7th–14th and 4th–7th post-treatment day intervals, respectively.

Seed micromorphology and actin cytoskeleton architecture in radicle cells of C. armena

The seeds of C. armena are highly polymorphous, usually oblongoid to ovoid, rarely subrectangular (Fig. 1g–i), with clearly pitted, reticulate, highly fluorescent testa (Fig. 1j–l). The average length of testa perforations is 19.8 μm, and the width is 14.5 μm. The actin filaments were stained in different types of radicle epidermal cells, being a confirmation for the successful germination of C. armena seeds and the potential of further growth towards the host with intrusion into its tissues (Fig. 3).

Fig. 3. Long F-actin cables, individual microfilaments and nuclei in epidermal cells of the elongating C. armena radicles, 1st day after germination. Labelling: red – Alexa Fluor 568-conjugated phalloidin (actin filaments); blue – DAPI (nuclei). Indications: n – nucleus; arrowheads point at the haustorial hair in the apical part of the radicle. Bars: (a–c) 50 μm; (d,e) 10 μm.

Alexa Fluor 568-conjugated phalloidin staining revealed a dense network of long actin cables traversed by the individual filaments both in the central part of the germinated radicle (Fig. 3a–c) and the pole with apical meristem (Fig. 3e). F-actin filaments in papillate epidermal cells, which will form haustorial hairs, are coiling below their apices (Fig. 3d) as compared to non-papillate cells (Fig. 3a–c). Numerous nuclei stained by DAPI were abundant in C. armena radicle tips (Fig. 3e).

Proposed seed germination protocol for C. armena

Based on our experiments, the following protocol for C. armena seed germination has been designed, still requiring optimization for seed dormancy breaking and in vitro germination:

  1. 1. Seed sterilization (2% v/v NaClO + 0.1% v/v Triton X-100) for 5 min under stirring with further five times washing in the sterile MilliQ water using vacuum pump, sterile glass Buchner flask, and UV-sterilized frit.

  2. 2. Positioning of sterile seeds on two sterile glass fibre filter paper disks (Whatman, GF/D, 10 mm in diameter) on two layers of filter paper (Whatman, 32 mm in diameter) placed into each well of a 12-well plate and moistened with 1 ml of MilliQ water or the sterile ½ MS medium.

  3. 3. Cold stratification at 4°C in darkness (covered with aluminium foil) for 4 d.

  4. 4. Conditioning at 21°C in darkness for 7 d.

  5. 5. Fluridone treatment (0.3 mM fluridone in 96% EtOH, 100 μl per disk) applied on the preliminary dried disks at 21°C in darkness for 24 h.

  6. 6. Fluridone washing five times in sterile MilliQ water with further disk drying for 15 min.

  7. 7. Gibberellic acid (GA3) treatment (100 μl of 1 μM GA3 in 0.1% acetone per disk) applied on the preliminary dried disks at 21°C in darkness for 20 and more days.

  8. 8. Moisture regime support by adding 100 μl of water.

  9. 9. Germination starts after the 22nd day with the steady increase of the percentage of the germinated seeds after GA3 treatment.

Discussion

Although the highest germination rates of Cistanche seeds have been obtained in long-term trials in nature (Wang et al., Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017), efforts to germinate them aseptically in vitro have also shown success (Baskin and Baskin, Reference Baskin and Baskin2022), implying that Cistanche species may not necessarily rely on the external biotic factors (e.g. symbiotic microorganisms or host-emitted stimuli) as germination triggers. On the other hand, ‘dust seeds’ have commonly been associated with such reliance, attributing it to the insufficiency of the seed nutrient reserves and the need for a supplementary host-derived carbon to ensure germination and successful seedling establishment (Eriksson and Kainulainen, Reference Eriksson and Kainulainen2011). As a convergent trait, ‘dust seeds’ also characterize mycoheterotrophic plants, having similar life-history traits as the root parasites but relying upon fungal symbionts as hosts (Merckx et al., Reference Merckx, Mennes, Peay, Geml and Merckx2013). In addition, soil microorganisms may play a role in establishing the orobanchaceous parasite–host interactions, and these relationships are known to be reciprocal (Fitzpatrick and Schneider, Reference Fitzpatrick and Schneider2020). However, most of the studies have emphasized only the suppressive effect of soil microbes on parasitic seeds, either through direct antagonism or indirectly, for example, by affecting hormonal profiles and reducing strigolactone production in the autotrophic hosts (Hristeva et al., Reference Hristeva, Dekalska and Denev2013; Müller-Stöver et al., Reference Müller-Stöver, Nybroe, Baraibar, Loddo, Eizenberg, French and Christensen2016). The knowledge concerning communities and role of bacterial seed endophytes of holoparasitic plant species is still limited (Iasur Kruh et al., Reference Iasur Kruh, Lahav, Abu-Nassar, Achdari, Salami, Freilich and Aly2017; Huet et al., Reference Huet, Pouvreau, Delage, Delgrange, Marais, Bahut, Delavault, Simier and Poulin2020; Durlik et al., Reference Durlik, Żarnowiec, Piwowarczyk and Kaca2021; Petrosyan et al., Reference Petrosyan, Thijs, Piwowarczyk, Ruraż, Vangronsveld and Kaca2022). The recent study on endophytic bacterial communities in seeds of C. armena showed 256 bacterial genera. The plant growth-promoting (PGP) traits of these bacteria, such as production of indole, 1-aminocyclopropane-1-carboxylic acid (ACC)-deaminase and organic acids have the potential to improve plant tolerance against abiotic stresses. However, their benefits for the seed germination and seedling development are still unclear (Petrosyan et al., Reference Petrosyan, Thijs, Piwowarczyk, Ruraż, Vangronsveld and Kaca2022).

Worth noting is that not all holoparasitic Orobanchaceae species require external chemical cues (e.g. strigolactones, host root exudates, GA3, etc.) for the stimulation of germination. For instance, the seeds of the Indian broomrape (Aeginetia indica) can germinate just under the right combination of dormancy-breaking signals, such as light and temperature, after conditioning (Kato and Hisano, Reference Kato and Hisano1983; Kato et al., Reference Kato, Inoue and Onishi1984; Chen and Hsiao, Reference Chen and Hsiao2011), probably by producing endogenous gibberellins (Suwa et al., Reference Suwa, Suzuki, Zhang, Murofushi and Takeuchi1995).

Reported effects of the germination stimulants, tested in this study, on the seeds of Cistanche species have proved highly inconsistent under different experimental conditions being set. Qiao et al. (Reference Qiao, Wang and Guo2007) reported that 0.1 mg l−1 fluridone treatment for 24–29 h in the temperature range 20–30°C was efficient for germinating the seeds of C. tubulosa, C. deserticola and C. salsa, whereas Wang et al. (Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017) failed to germinate fresh C. deserticola seeds either in water or in a 10−5 M fluridone solution at any incubation temperature within 60 d. Furthermore, C. deserticola seeds stratified at 5°C for 6 months displayed no germination in the GA3 and GR24 solutions and only 11% germination in the mixed fluridone/GA3 solution (Wang et al., Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017). This contrasted with Chen's et al. (Reference Chen, Wang, Wang, Shan, Zhai and Guo2009) results, showing >70% germination of GA3-treated seeds that had been cold-stratified for 4–5 months. Conversely, Zhang et al. (Reference Zhang, Chen, Zhang, Bai and Gao2009) achieved up to 4.7% of germination of C. deserticola seeds with the GA3 treatment only. In addition, Niu et al. (Reference Niu, Song, Guo, Ma, Li, Zheng and Gao2006) stated that soaking seeds in water at 24–25°C for 30 d, rather than cold stratification at 4°C for 60 d, increased their sensitivity to exogenous GA3. It has been suggested that the responsiveness of C. deserticola seeds to exogenous GA3 may be determined by the physiological status of the seeds (Wang et al., Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017).

However, this fluridone/GA3 triggered germination of Cistanche seeds might be mediated by endogenous strigolactones synthetized by the seeds. Fluridone, as a potent inhibitor of de novo carotenoid biosynthesis, inhibits phytoene desaturase, which catalyzes the desaturation step of phytoene to phytofluene in the carotenoid-biosynthesis pathway (Chae et al., Reference Chae, Yoneyama, Takeuchi and Joel2004; Matusova et al., Reference Matusova, Mourik and Bouwmeester2004). Nevertheless, already formed carotenoids are not targeted by fluridone, which might be used as a substrate for endogenous strigolactone production by biosynthetic machinery present in Orobanchaceae species (Das et al., Reference Das, Fernández-Aparicio, Yang, Huang, Wickett, Alford, Wafula, dePamphilis, Bouwmeester, Timko, Yoder and Westwood2015). Furthermore, carotenoid biosynthesis might also recover soon after the double treatment, since fluridone was washed out (see Materials and Methods) and might have been metabolized or degraded during further incubation. In addition, it has been shown for other Orobanchaceae species, whose germination is dependent on host-produced or artificial strigolactones, that the expression of strigolactone-biosynthesis genes significantly decreases during the conditioning period, making the seeds become highly sensitive to these regulatory molecules (Matusova et al., Reference Matusova, Mourik and Bouwmeester2004; Das et al., Reference Das, Fernández-Aparicio, Yang, Huang, Wickett, Alford, Wafula, dePamphilis, Bouwmeester, Timko, Yoder and Westwood2015; Brun et al., Reference Brun, Braem, Thoiron, Gevaert, Goormachtig and Delavault2018). It was found that fluridone also shifts ABA/GAs ratio in seeds due to the steady inhibition of ABA-biosynthesis with the increased concentration of GAs (Chen et al., Reference Chen, Guo, Jiang and Tu2016). In turn, GA signalling negatively regulates the endogenous levels of strigolactones (Ito et al., Reference Ito, Yamagami, Umehara, Hanada, Yoshida, Sasaki, Yajima, Kyozukam, Ueguchi-Tanaka, Matsuoka, Shirasu, Yamaguchi and Asami2017).

Our results for C. armena partly conform with those of Wang et al. (Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017) for C. deserticola, showing increased seed germination after the mixed fluridone/GA3 treatment as compared to the treatments with each of the stimulants alone (Fig. 2). Taken together, results of the above studies imply that (1) the Orobanchaceae root parasites seem to display a species-specific response to different germination stimulants, modulated by the physiological condition of seeds and/or general ecophysiology of species; and (2) a number of abiotic factors, such as temperature, darkness and the season, play key role in the orobanchaceous seed germination. For instance, the seeds of alpine root-hemiparasitic Euphrasia minima and E. salisburgensis reportedly germinate both at constant (5°C) and varying temperatures (3–10°C), and never before spring after seed ripening (Liebst and Schneller, Reference Liebst and Schneller2008). Cold stratification appears to be an important environmental factor also for C. armena (Fig. 2). Since this species naturally grows under the harsh semi-desert climate with contrasting day and night temperatures, its seeds are adapted to survive extreme temperatures but germinate only under optimal ones (21°C). Similarly, Qiao et al. (Reference Qiao, Wang and Guo2007) reported the optimal germination temperature of 20–30°C and the absence of germination at sub- or supraoptimal temperatures (5 and 35°C) in C. tubulosa, C. deserticola and C. salsa. The promoting effect of darkness on seed germination may be attributed to the underground conditions under which the seeds are naturally stored in the soil. According to Pouvreau et al. (Reference Pouvreau, Gaudin, Auger, Lechat, Gauthier, Delavault and Simier2013) and Matusova et al. (Reference Matusova, Kullacova and Toth2014), seed conditioning under light exposure may cause photoinhibition of germination even after adding fluridone and GA3. This is in line with our study, showing the successful germination of C. armena without illumination. In turn, the importance of season is likely related to a specialized kind of morphophysiological dormancy and/or critical size of embryo crucial for its further development. For C. deserticola seeds, the working protocol with over 50% germination rate included the incubation of the fresh seeds in 10−5 M fluridone solution in darkness in spring after they had overwintered on the soil surface in the natural habitat (Wang et al., Reference Wang, Baskin, Baskin, Liu, Yang and Huang2017).

Cytoskeletal proteins, especially actin, are the driving force for cell processes such as tip growth, intracellular trafficking, exo- and endocytosis, cytoplasm streaming, organelle movement and cytokinesis (Šamaj et al., Reference Šamaj, Müller, Beck, Böhm and Menzel2006; Szymanski and Staiger, Reference Szymanski and Staiger2018). Dynamic reorganization of actin cytoskeleton (F-actin cables, patches, individual filaments, rings and acquosomes) is a key prerequisite for growth and morphogenesis in higher plants (Smertenko et al., Reference Smertenko, Deeks and Hussey2010), and seems to be important also for the germination and interaction of parasitic plants with their susceptible hosts (Kaštier et al., Reference Kaštier, Krasylenko, Martinčová, Panteris, Šamaj and Blehová2018). Therefore, we addressed for the first time the organization of the actin cytoskeleton in the radicle cells of C. armena.

In conclusion, this long-term in vitro approach of C. armena germination may contribute to its successful propagation and become a part of the conservation strategy of this rare species. The germination of C. armena seeds, using susceptible host's root exudates, up to the formation of the functional haustoria requires further investigations both in vitro and in vivo. The hormonal mechanism of the stimulatory effect of fluridone on the Orobanchaceae seed germination was not addressed here, since ABA concentration in the seeds was not measured, and hence, it is yet to be discovered.

Financial support

The field research was partially supported by the National Geographic grant GEFNE 192-16 (2017). The microscopy part was supported by the European Regional Developmental Fund (ERDF) project ‘Plants as a tool for sustainable global development’ (No. CZ.02.1.01/0.0/0.0/16_019/0000827).

Author contributions

Conceptualization: R.P. and Y.K.; methodology: R.P., A.H., M.U. and Y.K.; software: Y.K.; validation: A.H. and Y.K.; formal analysis: Y.K. and Y.S.; investigation: A.H., Y.K. and M.U.; resources: R.P., L.S. and Y.K.; data curation: R.P.; writing original draft: Y.K., R.P. and Y.S.; writing reviewing and editing: R.P., Y.K. and Y.S.; visualization: Y.K.; supervision: Y.K. and R.P.

Data availability

All data generated or analysed during this study are included in this published article.

Conflict of interest

The authors declare that they have no competing interests.

Footnotes

These authors contributed equally.

References

Ali-Rachedi, S, Bouinot, D, Wagner, MH, Bonnet, M, Sotta, B, Grappin, P and Jullien, M (2004) Changes in endogenous abscisic acid levels during dormancy release and maintenance of mature seeds: studies with the Cape Verde Islands ecotype, the dormant model of Arabidopsis thaliana. Planta 219, 479488.CrossRefGoogle ScholarPubMed
Bao, YZ, Yao, ZQ, Cao, XL, Peng, JF, Xu, Y, Chen, MX and Zhao, SF (2017) Transcriptome analysis of Phelipanche aegyptiaca seed germination mechanisms stimulated by fluridone, TIS108, and GR24. PLoS ONE 12, e0187539.CrossRefGoogle ScholarPubMed
Barua, D, Butler, C, Tisdale, TE and Donohue, K (2012) Natural variation in germination responses of Arabidopsis to seasonal cues and their associated physiological mechanisms. Annals of Botany 109, 209226.CrossRefGoogle ScholarPubMed
Baskin, JM and Baskin, CC (2022) Germination and seed/embryo size in holoparasitic flowering plants with ‘dust seeds’ and an undifferentiated embryo. The Botanical Review 88, 149.CrossRefGoogle Scholar
Bouwmeester, H, Li, C, Thiombiano, B, Rahimi, M and Dong, L (2021) Adaptation of the parasitic plant lifecycle: germination is controlled by essential host signaling molecules. Plant Physiology 185,12921308.CrossRefGoogle ScholarPubMed
Brun, G, Braem, L, Thoiron, S, Gevaert, K, Goormachtig, S and Delavault, P (2018). Seed germination in parasitic plants: what insights can we expect from strigolactone research? Journal of Experimental Botany 69, 22652280.CrossRefGoogle ScholarPubMed
Chae, SH, Yoneyama, K, Takeuchi, Y and Joel, DM (2004) Fluridone and norflurazon, carotenoid-biosynthesis inhibitors, promote seed conditioning and germination of the holoparasite Orobanche minor. Physiologia Plantarum 120, 328337.CrossRefGoogle ScholarPubMed
Chen, JS and Hsiao, SC (2011) Study on seed morphogenesis of Orobanchaceae in Taiwan. Taiwania 56, 267278.Google Scholar
Chen, QL, Wang, HL, Wang, ZF, Shan, CG, Zhai, ZX and Guo, YH (2009) Effects of cold stratification and exogenous gibberellic acid (GA3) on seed germination and contents of endogenous gibberellins (GAs) and abscisic acid (ABA) in Cistanche deserticola. Plant Physiology Communications 45, 270272.Google Scholar
Chen, QL, Jia, YM, Wang, ZF, Shan, CG, Zhu, JB and Guo, YH (2011) Postembryonic development of Cistanche tubulosa (Schrenk) Whigt. Pakistan Journal of Botany 43, 18231830.Google Scholar
Chen, YC, Li, M, Chen, XJ, Zhang, L and Song, YX (2012) Effects of exogenous signal substances on seed germination and haustorium formation of Cistanche deserticola. Plant Physiology Communications 48, 260264.Google Scholar
Chen, QL, Guo, Y, Jiang, Y and Tu, P (2016) Mechanism of fluridone-induced seed germination of Cistanche tubulosa. Pakistan Journal of Botany 48, 971976.Google Scholar
Das, M, Fernández-Aparicio, M, Yang, Z, Huang, K, Wickett, NJ, Alford, SR, Wafula, EC, dePamphilis, CW, Bouwmeester, H, Timko, M, Yoder, J and Westwood, JH (2015) Parasitic plants Striga and Phelipanche dependent upon exogenous strigolactones for germination have retained genes for strigolactone biosynthesis. American Journal of Plant Sciences 6, 11511166.CrossRefGoogle Scholar
Durlik, K, Żarnowiec, P, Piwowarczyk, R and Kaca, W (2021) Culturable endophytic bacteria from Phelipanche ramosa (Orobanchaceae) seeds. Seed Science Research 31, 6975. doi:10.1017/S0960258520000343CrossRefGoogle Scholar
Eriksson, O and Kainulainen, K (2011) The evolutionary ecology of dust seeds. Perspectives in Plant Ecology, Evolution and Systematics 13, 7387.CrossRefGoogle Scholar
Fitzpatrick, CR and Schneider, AC (2020) Unique bacterial assembly, composition, and interactions in a parasitic plant and its host. Journal of Experimental Botany 71, 21982209.CrossRefGoogle Scholar
Halouzka, R, Zeljkovic, SC, Klejdus, B and Tarkowski, P (2020) Analytical methods in strigolactone research. Plant Methods 16, 76.CrossRefGoogle ScholarPubMed
Hristeva, T, Dekalska, T and Denev, I (2013) Structural and functional biodiversity of microbial communities in the rhizosphere of plants infected with broomrapes (Orobanchaceae). Biotechnology & Biotechnological Equipment 27, 40824086.CrossRefGoogle Scholar
Huet, S, Pouvreau, J-B, Delage, E, Delgrange, S, Marais, C, Bahut, M, Delavault, P, Simier, P and Poulin, L (2020) Populations of the parasitic plant Phelipanche ramosa influence their seed microbiota. Frontiers in Plant Science 11, 1075.CrossRefGoogle ScholarPubMed
Iasur Kruh, L, Lahav, T, Abu-Nassar, J, Achdari, G, Salami, R, Freilich, S and Aly, R (2017) Host-parasite-bacteria triangle: the microbiome of the parasitic weed Phelipanche aegyptiaca and tomato-Solanum lycopersicum (Mill.) as a host. Frontiers in Plant Science 8, 269.CrossRefGoogle ScholarPubMed
Ito, S, Yamagami, D, Umehara, M, Hanada, A, Yoshida, S, Sasaki, Y, Yajima, S, Kyozukam, J, Ueguchi-Tanaka, M, Matsuoka, M, Shirasu, K, Yamaguchi, S and Asami, T (2017) Regulation of strigolactone biosynthesis by gibberellin signaling. Plant Physiology 174, 12501259.CrossRefGoogle ScholarPubMed
Jamil, M, Wang, JY, Yonli, D, Patil, RH, Riyazaddin, M, Gangashetty, P, Berqdar, L, Chen, G-TE, Traore, H, Margueritte, O, Zwanenburg, B, Bhoge, SE and Al-Babili, S (2022) A new formulation for strigolactone suicidal germination agents, towards successful Striga management. Plants 11, 808.CrossRefGoogle ScholarPubMed
Kaštier, P, Krasylenko, YA, Martinčová, M, Panteris, E, Šamaj, J and Blehová, A (2018) Cytoskeleton in the parasitic plant Cuscuta during germination and prehaustorium formation. Frontiers in Plant Science 9, 794.CrossRefGoogle ScholarPubMed
Kato, Y and Hisano, K (1983) In vitro culture of a root parasite, Aeginetia indica L. The Botanical Magazine – Shokubutsu-gaku-zasshi 96, 203209.CrossRefGoogle Scholar
Kato, Y, Inoue, T and Onishi, Y (1984) In vitro culture of a root parasite, Aeginetia indica L. II. The plane of cell division in the tendril. Plant and Cell Physiology 25, 981987.Google Scholar
Kusumoto, D, Chae, SH, Mukaida, K, Yoneyama, K, Yoneyama, K, Joel, DM and Takeuchi, Y (2006) Effects of fluridone and norflurazon on conditioning and germination of Striga asiatica seeds. Plant Growth Regulation 48, 7378.CrossRefGoogle Scholar
Li, TR, Xu, YY, Ge, JX and Xu, MY (1989) The seed germination of Cistanche deserticola Ma and it's relationship with host plant Haloxylon ammodendron Bunge. Acta Scientiarum Naturalium Universitatis Intramongolicae 20, 395400.Google Scholar
Li, Z, Lin, H, Gu, L, Gao, J and Tzeng, CM (2016) Herba Cistanche (Rou Cong-Rong): one of the best pharmaceutical gifts of traditional Chinese medicine. Frontiers in Pharmacology 7, 41.CrossRefGoogle ScholarPubMed
Liebst, B and Schneller, J (2008) Seed dormancy and germination behaviour in two Euphrasia species (Orobanchaceae) occurring in the Swiss Alps. Botanical Journal of the Linnean Society 156, 649656.CrossRefGoogle Scholar
Matusova, R, Mourik, T, and Bouwmeester, H (2004) Changes in the sensitivity of parasitic weed seeds to germination stimulants. Seed Science Research 14, 335344.CrossRefGoogle Scholar
Matusova, R, Kullacova, D and Toth, P (2014) Response of wild and weedy broomrapes to synthetic strigolactone analogue GR24. Journal of Central European Agriculture 14, 7282.CrossRefGoogle Scholar
Merckx, VSFT, Mennes, CB, Peay, KG and Geml, J (2013) Evolution and diversification, pp. 215244 in Merckx, VSFT (Ed.), Mycoheterotrophy: the biology of plants living on fungi. New York, Springer.CrossRefGoogle Scholar
Müller-Stöver, D, Nybroe, O, Baraibar, B, Loddo, D, Eizenberg, H, French, K and Christensen, S (2016) Contribution of the seed microbiome to weed management. Weed Research 56, 335339.CrossRefGoogle Scholar
Murashige, T and Skoog, F (1962) A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia Plantarum 15, 473497.CrossRefGoogle Scholar
Niu, DL, Song, YX, Guo, SH, Ma, HA, Li, M, Zheng, GQ, Gao, XY (2006) Original studies on dormancy and germination properties of Cistanche deserticola seeds. Seed 25, 1721.Google Scholar
Panteris, E, Apostolakos, P and Galatis, B (2006) Cytoskeletal asymmetry in Zea mays subsidiary cell mother cells: a monopolar prophase microtubule half-spindle anchors the nucleus to its polar position. Cell Motility and the Cytoskeleton 63, 696709.CrossRefGoogle Scholar
Petrosyan, K, Thijs, S, Piwowarczyk, R, Ruraż, K, Vangronsveld, J and Kaca, W (2022) Characterization and diversity of seed endophytic bacteria of the endemic holoparasitic plant Cistanche armena (Orobanchaceae) from a semi-desert area in Armenia. Seed Science Research 32, 264273.CrossRefGoogle Scholar
Piwowarczyk, R and Mielczarek, Ł (2018) First report of Eumerus mucidus (Diptera: Syrphidae) on Cistanche armena (Orobanchaceae) and from Armenia. Florida Entomologist 101, 519521.CrossRefGoogle Scholar
Piwowarczyk, R, Kwolek, D, Góralski, G, Denysenko, M, Joachimiak, AJ and Aleksanyan, A (2017) First report of the holoparasitic flowering plant Cistanche armena on Caspian manna (Alhagi maurorum) in Armenia. Plant Disease 101, 512.CrossRefGoogle Scholar
Piwowarczyk, R, Góralski, G, Denysenko-Bennett, M, Kwolek, D, Joachimiak, AJ and Fayvush, G (2018) The first report of eastern dodder (Cuscuta monogyna) parasitizing licorice (Glycyrrhiza glabra) in Armenia. Plant Disease 102, 2664.CrossRefGoogle Scholar
Piwowarczyk, R, Sanchez Pedraja, Ó, Moreno Moral, G, Fayvush, G, Zakaryan, N, Kartashyan, N, and Aleksanyan, A (2019) Holoparasitic Orobanchaceae (Cistanche, Diphelypaea, Orobanche, Phelipanche) in Armenia: distribution, habitats, host range and taxonomic problems. Phytotaxa 386, 101106.CrossRefGoogle Scholar
Piwowarczyk, R, Ochmian, I, Lachowicz, S, Kapusta, I, Sotek, Z and Błaszak, M (2020) Phytochemical parasite-host relations and interactions: a Cistanche armena case study. Science of the Total Environment 716, 137071.CrossRefGoogle ScholarPubMed
Pouvreau, JB, Gaudin, Z, Auger, B, Lechat, MM, Gauthier, M, Delavault, P and Simier, P (2013) A high-throughput seed germination assay for root parasitic plants. Plant Methods 9, 112.CrossRefGoogle ScholarPubMed
Qiao, XY, Wang, HL and Guo, YH (2007) Study on conditions of seed germination of Cistanche. Zhongguo Zhong Yao Za Zhi 32, 18481850.Google Scholar
Šamaj, J, Müller, J, Beck, M, Böhm, N and Menzel, D (2006) Vesicular trafficking, cytoskeleton and signaling in root hairs and pollen tubes. Trends in Plant Science 11, 594600.CrossRefGoogle ScholarPubMed
Schneider, CA, Rasband, WS and Eliceiri, KW (2012) NIH Image to ImageJ: 25 years of image analysis. Nature Methods 9, 671675.CrossRefGoogle ScholarPubMed
Smertenko, AP, Deeks, MJ and Hussey, PJ (2010) Strategies of actin reorganisation in plant cells. Journal of Cell Science 123(17), 30193028.CrossRefGoogle ScholarPubMed
Song, WJ, Cao, DD, Jin, ZL and Zhou, WJ (2005) Studies on factors influencing the seed germination of root parasitic plant Orobanche. Seed 24, 4447.Google Scholar
Suwa, H, Suzuki, Y, Zhang, YH, Murofushi, N and Takeuchi, Y (1995) Endogenous gibberellins in Aeginetia indica, a parasitic plant, and its host. Bioscience, Biotechnology, and Biochemistry 59, 17121715.CrossRefGoogle Scholar
Szymanski, D and Staiger, CJ (2018) The actin cytoskeleton: functional arrays for cytoplasmic organization and cell shape control. Plant Physiology 176, 106118.CrossRefGoogle ScholarPubMed
Wang, J, Baskin, JM, Baskin, CC, Liu, G, Yang, X and Huang, Z (2017) Seed dormancy and germination of the medicinal holoparasitic plant Cistanche deserticola from the cold desert of northwest China. Plant Physiology and Biochemistry 115, 279285.CrossRefGoogle ScholarPubMed
Xu, R, Chen, J, Chen, SL, Liu, TN, Zhu, WC and Xu, J (2009) Cistanche deserticola Ma cultivated as a new crop in China. Genetic Resources and Crop Evolution 56, 137142.CrossRefGoogle Scholar
Yang, CH, Zhang, XS and Zhuang, ZK (2007) Effect of acetylcholine on seed germination and endogenous IAA and ABA contents of Cistanche tubulosa. Journal of Plant Physiology 43, 295297.Google Scholar
Yoneyama, K, Xie, X, Sekimoto, H, Takeuchi, Y, Ogasawara, S, Akiyama, K, Hayashi, H and Yoneyama, K (2008) Strigolactones, host recognition signals for root parasitic plants and arbuscular mycorrhizal fungi, from Fabaceae plants. New Phytologist 179, 484494.CrossRefGoogle ScholarPubMed
Zhang, RM, Bai, J, , CL, Chen, HW and Gao, Y (2008) Fluctuating temperature stratification induced seed germination of Cistanche deserticola. Scientia Silvae Sinica 44, 170173.Google Scholar
Zhang, RM, Chen, HW, Zhang, D, Bai, J and Gao, Y (2009) Chemical induction on the seed germination and haustorium formation of Cistanche deserticola. Scientia Silvae Sinica 9, 170173.Google Scholar
Figure 0

Fig. 1. General appearance, habitat and seed micromorphology of C. armena: flowering (a,b) and fruiting (c) individuals on their host plants in semi-desert habitats in Armenia (d–f); seed polymorphism observed with ZOOM stereomicroscopy (g–i); lignin autofluorescence revealed by CLSM (j–l). Scale bars: (g–i) 200 μm; (j,k) 100 μm; (l) 50 μm.

Figure 1

Fig. 2. Germination of the Orobanchaceae seeds: (a) germination rate (%) of C. armena, O. minor and S. hermonthica on the 22nd day after treatment with germination stimulants; (b) control, conditioned seeds incubated without any germination stimulants, 22nd day in ½ MS medium; (c–f) germinated seeds with emerged radicles (indicated by arrows) imaged by a ZOOM microscope at 22nd day after fluridone and GA3 treatment. Scale bars: (b,c) 2000 μm; (d–f) 500 μm.

Figure 2

Fig. 3. Long F-actin cables, individual microfilaments and nuclei in epidermal cells of the elongating C. armena radicles, 1st day after germination. Labelling: red – Alexa Fluor 568-conjugated phalloidin (actin filaments); blue – DAPI (nuclei). Indications: n – nucleus; arrowheads point at the haustorial hair in the apical part of the radicle. Bars: (a–c) 50 μm; (d,e) 10 μm.