Seed longevity, viability and germination of four weed-ruderal Asteraceae species of ethnobotanic value

Jiménez-Vázquez, Andrea Mariel; Flores-Palacios, Alejandro; Flores-Morales, Alejandro; Perea-Arango, Irene; Gutiérrez, María del Carmen; Arellano-García, José de Jesús; Valencia-Díaz, Susana; Jiménez-Vázquez, Andrea Mariel; Flores-Palacios, Alejandro; Flores-Morales, Alejandro; Perea-Arango, Irene; Gutiérrez, María del Carmen; Arellano-García, José de Jesús; Valencia-Díaz, Susana

doi:10.17129/botsci.2743

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Botanical Sciences

versión On-line ISSN 2007-4476versión impresa ISSN 2007-4298

Bot. sci vol.99 no.2 México abr./jun. 2021 Epub 08-Abr-2021

https://doi.org/10.17129/botsci.2743

Ecology

Seed longevity, viability and germination of four weed-ruderal Asteraceae species of ethnobotanic value

Longevidad, viabilidad y germinación de semillas de cuatro especies de Asteraceae consideradas malezas-ruderales con valor etnobotánico

Andrea Mariel Jiménez-Vázquez¹
http://orcid.org/0000-0002-0959-3581

Alejandro Flores-Palacios²
http://orcid.org/0000-0002-2000-9964

Alejandro Flores-Morales¹
http://orcid.org/0000-0001-5454-4917

Irene Perea-Arango³
http://orcid.org/0000-0003-1944-4739

María del Carmen Gutiérrez³
http://orcid.org/0000-0002-1439-1386

José de Jesús Arellano-García³
http://orcid.org/0000-0003-2367-6217

Susana Valencia-Díaz³^*
http://orcid.org/0000-0002-0089-226X

^¹Facultad de Ciencias Biológicas, Universidad Autónoma del Estado de Morelos (UAEM), Cuernavaca, Morelos, Mexico.

^²Centro de Investigación en Biodiversidad y Conservación (CIβγC), UAEM, Cuernavaca, Morelos, Mexico.

^³Centro de Investigación en Biotecnología (CEIB), UAEM. Cuernavaca, Morelos, Mexico.

Abstract

Background:

A high proportion of Asteraceae species are considered weeds, some of them have recognizable biological properties. To design production protocols and ex situ seed conservation programs is necessary to determine the effect of storage temperature on seed viability and longevity. It is known that cold temperatures maintain seed viability and thus prolong seed longevity.

Hypotheses:

The seeds of Aldama dentata, Verbesina virgata, Stevia origanoides and Roldana barba-johannis stored at low temperature (5 ºC) will have greater longevity than when stored at room temperature (16.45 ± 1.94 ^oC) and will decrease their viability as they age.

Study site and dates:

Seeds of the four Asteraceae were collected (November-December 2015) in The National Park “El Tepozteco”, Morelos, Mexico and in the “Chamilpa” campus of the Universidad Autónoma del Estado de Morelos.

Methods:

The monthly germination experiments (11) were implemented with seeds stored under both temperatures, germination (%) and mean germination time were registered to estimate seed longevity. The seed viability stored at room temperature was evaluated with the tetrazolium test.

Results:

Germination and viability decreased with seed age. Along the experiment, seed germination was similar at both storage temperatures. A. dentata and S. origanoides showed the highest germination but A. dentata alone reached the major seed viability. The oldest seeds germinated faster.

Conclusions:

Seed longevity of all the species exceeded one year. For propagation purposes, it is recommended to use seeds between 8 and 9 months of age, when their germination and viability are the highest.

Keywords: Dormancy; ex situ conservation; mean germination time; seed bank; weeds

Resumen

Antecedentes:

Muchas asteráceas son consideradas ruderales o malezas con propiedades biológicas reconocidas. Para diseñar protocolos de producción y de conservación ex situ de semillas, es necesario determinar el efecto de la temperatura de almacenaje en su viabilidad y longevidad; ya que temperaturas bajas mantienen la viabilidad de las semillas prolongando su longevidad.

Hipótesis:

Las semillas de Aldama dentata, Verbesina virgata, Stevia origanoides y Roldana barba-johannis almacenadas a baja temperatura (5 ºC) tendrán mayor longevidad que cuando son almacenadas a temperatura ambiente (16.45 ± 1.94 ^oC) y disminuirán su viabilidad conforme envejezcan.

Sitio y año de estudio:

Las semillas se colectaron (noviembre-diciembre 2015) en El Parque Nacional “El Tepozteco”, Morelos, México y el campus “Chamilpa” de la Universidad Autónoma del Estado de Morelos.

Métodos:

Los experimentos de germinación (11) se realizaron mensualmente con semillas almacenadas en ambas temperaturas. Se estimó su longevidad con el porcentaje y el promedio del tiempo de germinación. La viabilidad de las semillas almacenadas a temperatura ambiente fue evaluada con la prueba de tetrazolio.

Resultados:

La germinación y viabilidad disminuyeron con la edad de las semillas. Durante el experimento, la germinación fue similar en ambas temperaturas. A. dentata y S. origanoides tuvieron el porcentaje más alto de germinación. La viabilidad fue mayor en A. dentata. Las semillas más longevas germinaron más rápido.

Conclusiones:

La longevidad de las semillas de todas las especies superó el año. Para su propagación; se recomienda usar semillas de entre 8 y 9 meses de edad, cuando su germinación y viabilidad es mayor.

Palabras clave: Banco de semillas; conservación ex situ; latencia; malezas; promedio del tiempo de germinación

The Asteraceae family is one of the most diverse among the vascular plants. It is estimated to comprise about 10 % of angiosperms worldwide (^{Pyšek 1997}, ^{Funk et al. 2005}). Many species of this family are heliophilous (^{Suárez-Mota et al. 2018}) and have a high production of seeds with a specialized structure (pappus) that facilitates their dispersion (^{Yuan & Wen 2016}). The seeds of some Asteraceae species may have a dormancy, which allows the formation of seed banks (^{Fenner & Thompson 2005}). These seed traits facilitate the colonization of disturbed environments by Asteraceae species (^{Diniz et al. 2010}), which have a high invasive capability, to the extent of being considered weeds (^{Villaseñor et al. 2011}, ^{Yuan & Wen 2016}). Despite this, weeds may have important contributions to ecosystems due the fact that harbor beneficial insects such as pollinators and pest controllers, or even due to improvement of soil nutrients (^{Blaix et al. 2018}). This functional group offers also cultural services, such as medicinal, insecticidal, herbicidal, alimentary, or ornamental uses that some species of Asteraceae have (^{Heinrich et al. 1998}, ^{Stepp & Moerman 2001}, ^{Ghani et al. 2011}, ^{Guzmán-Pantoja et al. 2012}, ^{Nenaah et al. 2015}, ^{García-Herrera et al. 2014}, ^{Cicevan et al. 2016}, ^{Benvenuti et al. 2017}, ^{Prebeg et al. 2019}).

There are life traits related to seed biology (viability, longevity, dormancy and storage temperature) that should be considered for weed management and/or implementation of production protocols for potentially useful plant species (^{Rodríguez-Arévalo et al. 2017}). Loss of viability in seeds is related to an increase of reactive oxygen species (i.e., singlet oxygen, hydrogen peroxide and hydroxyl radical) causing DNA damage, protein adducts and lipid peroxidation (^{Sano et al. 2016}, ^{Kurek et al. 2019}). On the other hand, seed longevity is defined as the period that the seeds remain alive (^{Kochanek et al. 2010}, ^{Sano et al. 2016}, ^{Buitink & Leprince 2018}). Under storage conditions of low humidity (< 10 %) and temperature (< 5 ^oC or subzero) the cytoplasm becomes glassy, which impedes the mobility of the molecules avoiding chemical reactions implicated in seed aging (^{Buitink et al. 2000}). As temperature increases, viscosity of cytoplasm is recovered and chemical reactions occur due to the availability of water. Therefore, at high temperatures seed aging accelerates, reducing viability and delaying seed germination (^{Sano et al. 2016}). The optimal storage temperature for the maintenance of seed viability varies among plant species; for example, seeds of the Asteraceae Helianthus annus L. stored for four months under three temperatures (4-5, 21-22 and 35 ^oC) showed the lowest germination at the highest temperature. Furthermore, seed viability diminished with aging (^{Ghasemnezhad & Honermeier 2007}). Similar pattern is observed in the weeds Bacharis dracundifolia DC., Senecio vulgaris L., Solidago altissima L., S. nemoralis Aiton and S. shorti Torr. & A. Gray which seeds reduced germination with aging and at room temperatures of 25-27 ^oC (^{Walck et al. 1997}, ^{Gomes & Fernándes 2002}, ^{Ndihokubwayo et al. 2016}). Knowledge of seed traits allows us to determine appropriate storage conditions, since, if seeds are viable and long-lived but do not germinate, they may have dormancy, which could make them susceptible to prolonged storage.

The Mexican species Aldama dentata La Llave, Stevia origanoides Kunth, Roldana barba-johannis (DC.) H. Rob. & Brettell (Senecio barba-johannis) and Verbesina virgata Cav. (Asteraceae) are ruderal species, distributed in central Mexico with recognized ethnobotanical utility. Aldama dentata has been used for the alleviation of gastritis (^{Chena-Becerra et al. 2014}) and it is an important element of flora for beekeeping (^{Cadena-Rodríguez et al. 2019}), S. origanoides has antioxidant properties (^{Medina-Medrano et al. 2018}), meanwhile R. barba-johannis is used as bioinsecticide (^{Céspedes et al. 2004}), organic fertilizer, firewood and for crafting (^{Aguilar-Santelises & del Castillo 2015}). Also, molecules with antimicrobial activity (eudesmane triols) have been isolated from species of Verbesina (^{Martínez et al. 1983}, ^{Mora et al. 2013}). Given the potential utility of these species, the objective of this study was to determine the viability and longevity (i.e., percentage and timing of germination) in seeds of A. dentata, S. origanoides, R. barba-johannis and V. virgata stored under two different temperature conditions (5 °C and room temperature). We hypothesize that the seeds will have enough longevity to form seed banks, which will make them potential candidates to ex situ storage. Therefore, we expect the following: a) seeds will decrease their viability and germination capacity (percentage and timing of germination) as they age, and b) their longevity will be greater when stored at the lower temperature (5 °C).

Materials and methods

Study area, species and seed collection. Seeds of R. barba-johannis, S. origanoides and V. virgata were collected along the roads that connect the localities of San Juan Tlacotenco and Coajomulco, in the National Park “El Tepozteco”, in Tepoztlán, Morelos, Mexico (18° 53' 20" to 19° 05' 30” N; 99° 02' 00” to 99° 12' 55" W, 2,300 m asl). The mean annual temperature at the study area is 15.9 °C and mean annual precipitation is 1,477.9 mm (^{Cruz-Fernández et al. 2011}). The predominant vegetation types are crassicaule xerophytic scrub and monospecific or mixed Quercus forests dominated by Quercus rugosa Née (^{Cruz-Fernández et al. 2011}). Seeds of Aldama dentata were collected at the “Chamilpa” campus of the Universidad Autónoma del Estado de Morelos in Cuernavaca, Morelos (18º 59´ 00´´ N and 99º 14´ 13´´ W, 1,909 m asl). The campus is located in the north of the urban area of Cuernavaca. Remnants of the original vegetation show that this was pine-oak forest and pine forest; however, due to urbanization, most of the vegetation is secondary and ruderal vegetation (^{Solalinde-Vargas 2014}).

During November and December 2015, capitula (heads) of each species (30 individuals/species) were collected. This collection was conducted when the achenes (uniseminal, dry and indehiscent fruit, hereafter referred to as seeds) separated easily from the capitulum. Once detached, the seeds were quantified, excluding any visibly non-vigorous seeds (soft consistency and grayish color). Visibly healthy seeds (hard, dark and without signs of herbivory) were randomly assigned to the storage conditions described in the following section.

Storage temperature effect on seed longevity (seed germination and mean germination time). Seed longevity of the four species of Asteraceae was evaluated monthly by measuring both the percentage of germination and the mean germination time. For each species, and prior to carrying out the germination experiments, 176 batches of 50 healthy and vigorous seeds were placed randomly in aluminum foil envelopes; 88 of these envelopes were stored in a cold room (constant temperature 5 ± 0.5 °C) at the Laboratorio de Botánica Estructural in the Centro de Investigación en Biotecnología (CEIB) and the other 88 envelopes of each species were stored at room temperature in CEIB (16.45 ± 1.94 °C, Figure 1) since they were collected. The seeds from eight envelopes stored at room temperature and at 5 °C were germinated (400 seeds for each temperature treatment). Due to the seeds of these species germinate at the end of summer, the first germination trial was carried out in July 2016 using seeds that were 222 days of age, and the subsequent experiments were performed with seeds of 253, 284, 314, 345, 375, 406, 437, 465, 496 and 526 days of age. The final experiment was conducted in May 2017.

Figure. 1 Mean monthly temperature under room conditions for storage of the seeds of four Asteraceae species. Temperature was measured daily from January 2016 until May 2017. Data were obtained from UAEM weather station (Comisión Nacional del Agua). Points and dispersion lines represent mean values and 1SE, respectively

Before each monthly germination experiment, the seeds were disinfected with sodium hypochlorite (1 %, cloralex^®) for 30 seconds under constant agitation, after disinfection the seeds were rinsed three times with sterile distilled water in order to remove traces of chlorine. Finally, the 50 seeds of each envelope were placed in Petri dishes (90 mm in diameter × 15 mm in height) lined with filter paper (Whatman No. 2) and moistened with 4 mL of distilled water. To prevent moisture loss, the Petri dishes were sealed with Parafilm (Pechiney-Plastic packaging, model PM-996, USA) and Clingfilm (Kirkland Signature, model 26761, USA). Thus, 16 Petri dishes per species were considered each month, half of these had seeds that were stored at 5 ^oC and the rest had seeds stored at room temperature. Petri dishes were placed for 18 days in a germination chamber (Scorpion Scientific, Bioclimatic Environmental Chamber A-50624, Mexico) equipped with white warm fluorescent light, with a photoperiod of 12 h light-12h darkness and a constant temperature of 25 °C. A seed was considered to have germinated when the radicle emerged. Each experiment was carried out for 12 days and the number of germinated seeds was recorded daily.

Mean germination time was calculated according to ^{Ranal & García de Santana (2006)} as:

t-=∑i=1kniti/∑i=1kni

Where t_i represents the day of the record of germination data (from 1 to 18), n_i is the number of germinated seeds on day i and k is the number of days of germination recording (k = 18 days). This formula weighs the seed germination according to the time at which they germinated. Thus, if most of the seeds germinate during the initial days, the value of the mean germination time will be low (fast germination) and will increase as a greater number of seeds germinate in the final days of the experiment.

Seed viability. Along with the germination experiments, the viability of the seed lots of each species was evaluated monthly using 1 % tetrazolium (TTZ, 2,3,5-triphenyltetrazolium chloride) (^{Moreno 1984}). TTZ is employed to evaluate seed viability based on the respiratory activity of the tissues, in which the TTZ reaction consists of the reduction of TTZ to the red triphenyl-formazan. If the seed is alive (viable), then there will be activity of the enzyme dehydrogenase, which will reduce the compound (Moreno 1984). To determine the percentage of viability of each species, four samples of 80 seeds were stored in aluminum foil envelopes at room temperature for the same period as that described before (4 envelopes × 4 species × 11 months). Once the TTZ test was carried out, the seeds of each species were observed under a stereoscope microscope (Leica, model EZ4). If the embryo of the seeds became red, the seeds were considered viable. In contrast, seeds of white-pink coloration and those that were partially dyed or with absence of coloration were considered non-viable. Finally, the number of viable seeds was determined, and the viability percentage was calculated for each species.

Statistical Analyses. To determine whether seed germination of each species varied in response to the two storage temperatures and their age, a generalized linear model (GLM) with binomial error and logit link function was performed (^{Crawley 1993}, ²⁰¹³). In this analysis, the factors were storage temperature (5 °C and room temperature) and species (A. dentata, R. barba-johannis, V. virgata and S. origanoides), the covariable was seed age, the dependent variable was the occurrence of germination. To determine whether the mean germination time of the four species varied depending on seed age and storage temperature, a covariance analysis was performed for normal data (^{Crawley 1993}, ²⁰¹³). In this analysis, the covariable was seed age, the factors were identity of the species and temperature and the dependent variable was mean germination time. Finally, the effect of seed longevity on viability was determined using a GLM with binomial error and logit link function, where the factor was identity of the species, the covariable was seed age and the dependent variable was the viability or otherwise of the seed. Contrasts tests between the coefficients of the models were applied where statistical differences were detected (^{Crawley 1993}, ^{Bretz et al. 2011}). All statistical analyses were conducted using R version 3.4.3. (^{R Core Team 2017}), with the multcomp package (^{Hothorn et al. 2008}).

Results

Storage temperature effect on seed longevity (seed germination and mean germination time). The identity of the species and seed age had a statistically significant effect on seed germination (Table 1). The highest germination values corresponded to A. dentata and S. origanoides, while V. virgata and R. barba-johannis had the lowest germination values (Contrast test, P < 0.05, Table 2). At the end of the experiment, the germination of seeds stored at 5 °C was (hereafter, we report X- ±SE) 23.10 ± 0.007 % and was statistically similar to the germination presented by the seeds stored at room temperature (22.40 ± 0.004 %, Table 1). Without considering species identity or storage temperatures, seed germination diminished as the seeds aged (Figure 2).

Table 1 Effect of the Asteraceae species, storage temperature, seed age and their interactions on seed germination of A. dentata, S. origanoides, R. barba-johannis and V. virgata seeds. Degrees of freedom (D.F.), χ² and P-value of Generalized Linear Model with binomial error and logit link function are shown.

Source of variation	D.F.	χ²	P
Species	3	107.07	< 0.00001
Temperature	1	0.15	0.69
Seed age	1	996.72	< 0.00001
Species × Temperature	3	26.58	0.0367
Species × Seed age	3	146.43	< 0.00001
Temperature × Seed age	1	0.14	0.70
Species × Temperature× Seed age	3	22.67	< 0.00001

Table 2 Mean ± 1SE of germination, mean germination time (MGT) and viability of seeds of four ruderal Asteraceae species. Different letters show statistically differences among species (Contrast test, P < 0.05), letters should be read within each column.

Species	Germination (%)	MGT (days)	Viability (%)
Aldama dentata	29.81 ± 1.06ª	1.44 ± 0.77^b	59.54 ± 12.92ª
Roldana barba-johannis	27.75 ± 0.73ª	1.07 ± 0.75^c	54.20 ± 11.46a^b
Stevia origanoides	15.88 ± 0.77^b	1.63 ± 0.77^a	47.5 ± 10.59^ab
Verbesina virgata	16.42 ± 0.79^b	0.87 ± 0.58^b	38.29 ± 10.49^b

Figure. 2 Proportion of germinated seeds of four ruderal Asteraceae species in response to seed age (time since collection) and without considering seed storage temperatures. Points and dispersion lines represent mean values and 1SE, respectively

All of the interaction terms in the model were significant, except temperature × seed age (Table 1). Considering the species × storage temperature interaction, the highest germination was presented by A. dentata when its seeds were stored at 5 °C (Table 3), followed by the seeds of this species stored at room temperature and by S. origanoides, the seeds of which had also high seed germination at both temperatures (Table 2). Both R. barba-johannis and V. virgata presented the lowest germination under both storage conditions (Table 3). Regarding the triple interaction between species × temperature × seed age, germination decreased with seed aging (Figure 3a-h). It was observed that, at room temperature, A. dentata and V. virgata have continuous patterns of decreased germination over time (Figure 3a-b), while this decrease in germination is less pronounced in S. origanoides and in R. barba-johannis (Figure 3c-d).

Table 3 Mean ± 1SE values of proportion of germinated seeds in four ruderal Asteraceae species, in which seeds were stored under two temperature conditions (room and 5°C). Different letters denote statistically significant differences (Contrast test P < 0.05)

Species	Room	5 °C
	(16.45 ± 12.92 °C)
Aldama dentata	0.28 ± 0.01^b	0.31 ± 0.01^a
Roldana barba-johannis	0.15 ± 0.01^c	0.16 ± 0.01^c
Stevia origanoides	0.27 ± 0.01^b	0.27 ± 0.01^b
Verbesina virgata	0.15 ± 0.01^c	0.17 ± 0.01^c

Figure. 3 Proportion of germinated seeds throughout seed aging in four Asteraceae species when stored at room (a-d) and 5 °C (e-h) temperatures. Points and dispersion lines represent mean values and 1SE, respectively. Different lowercase letters in parenthesis indicate statistically significant differences (Contrast test P < 0.05)

As with germination percentage, mean germination time was not influenced by storage temperature (χ² = 2.76, df = 1, P = 0.09). However, there were statistically significant differences among species (χ² = 137.60, df = 3, P < 0.0001), seeds of V. virgata had the fastest germination, followed by R. barba-johannis. Stevia origanoides had the slowest seed germination, meanwhile A. dentata was the second species with slow germination (Table 2, Contrasts test, P < 0.05).

Seed age also influenced the mean germination time (χ² = 281.22, df = 1, P < 0.0001); this value was higher when seeds were 222-250 days old (from the time of collection) and mean germination time decreased as the seeds got older (Figure 4a-h). The interaction of species × temperature was statistically significant (χ² = 10.03, df = 1, P < 0.05). At both seed storage temperatures, S. origanoides and A. dentata (5 ^oC) had the highest values of mean germination time (Figure 4a, c, e, g), while the lowest values corresponded to V. virgata (Figure 4b, f). In R. barba-johannis, mean germination time alternated between high and low values when stored at room temperature (Figure 4d), and germination occurred in less time when stored at 5 °C (Figure 4d).

Figure. 4 Mean germination time along seed aging of four Asteraceae species when they were stored at room (a-d) and 5 °C (e-h) temperatures. Points and dispersion lines represent mean values and 1SE, respectively. Different lower-case letters in parentheses indicate statistically significant differences (Contrast test P < 0.05)

Seed viability. The percentage of seed viability diminished as the seeds aged (χ = 44.79, df = 1, P < 0.001). Among species, the statistical differences (χ = 70.21, df = 3, P < 0.0001) are based on the fact that A. dentata seeds had the highest viability, while the lowest seed viability corresponded to V. virgata. Roldana barba-johannis and S. origanoides had similar and intermediate seed viabilities. The interaction between species × seed age did not affect mean germination time (χ = 6.15, df = 3, P = 0.10). This means that, in the evaluated time, the decline in seed viability was equal among the species as they aged.

Discussion

Anthropogenic disturbance of natural ecosystems favors the presence of weeds and ruderals (^{Sakai et al. 2001}), as is the case of many Asteraceae species (^{Van Etten et al. 2017}). This functional group has highly ecological (i.e., maintenance of insect biodiversity, input nutrients into soil) and ethnobotanical values (food, traditional medicine, ornamental). Therefore, is important to determine optimal seed storage conditions that will maximize their viability and longevity. This study shows that seed viability and germination percentage of the studied Asteraceae species decreased with seed natural ageing, and that seed storage temperature had no effect on these parameters.

Storage temperature effect on seed germination and mean germination time. Storage temperature affects seed physiological processes (^{Visscher et al. 2016}). For example, low seed storage temperature could prolong seed longevity if seeds have low moisture content (^{Probert et al. 2009}). There is evidence that cool temperatures act to increase seed lifespan in orthodox (desiccation-tolerant) seeds (^{Ellis 1991}); according to the data base of the Kew Royal Botanical Gardens (https://data.kew.org/sid/) seeds of A. dentata, S. origanoides and V. virgata, and also seeds of the genus Roldana have orthodox seeds, thus is probable that low temperatures prolong their seed longevity. Seed germination is regulated by the levels of abscisic (ABA) and gibberellic (GA) acids, through the expression of genes involved in ABA and GA biosynthesis. NCDE genes are related to ABA and are up-regulated when seeds are exposed at high temperatures (i.e., 34 °C); unlike, over expression of GA 20-oxydase genes occurs at lower temperatures (22 °C), as found in Arabidopsis thaliana (^{Toh et al. 2008}). This is complemented with the mobility or kinetic model which establish that high temperatures accelerate biochemical reactions in seeds provoking seed aging (^{Buitink et al. 2000}, ^{Ballesteros & Pence 2017}) and this is manifested in a loss of viability and delayed germination (^{Sano et al.
2016}). It was expected that seed longevity in the plant species studied would be prolonged at 5 °C, but neither seed longevity nor seed germination were affected by these seed storage temperature conditions. This lack of effect of temperature on seed longevity has been reported previously (^{Dickie et al. 1990}), where variation in seed storage temperature, particularly at sub-zero temperatures, did not affect seed longevity in Lactuca sativa L. (Asteraceae). It is possible that a prevalent room temperature (of around 18 °C) during storage may not be high enough to increase seed germination and, consequently, seed longevity. Previous studies have shown that temperature did not affect germination in orthodox seeds of the Asteraceae Helianthus annuus L., when seeds were stored at 5 °C and 20 °C (^{Brunick 2007}); however, germination increased when these seeds were stored at 25 °C (^{Rodríguez et al. 2018}). It is possible that the storage temperatures used in this study did not include the limits that would have caused an effect on seed germination. For future research, we recommend assessing the effect of colder temperatures on seed germination, such as that used to preserve Bidens seeds (-20 °C, ^{Xuan et al. 2016}). There are other factors not considered here that can affect seed germination, such as light requirements which may vary in plant species. Some Taraxacum species respond differently when their seeds germinate under different light conditions; moreover, depending on the species; the interaction of light and temperature affect germination (^{Luo & Cardina
2012}). For future research, the inclusion of light preferences for germination could evidence different percentages of germination for the studied species.

According to ^{Sano et al. (2016)}, one of the main symptoms of seed aging is delayed germination. However, in this study, the opposite was observed in the four species of Asteraceae: germination of seeds sowed in the first experiment was slower than in older seeds. In ecological terms, it has been hypothesized that delayed germination may act to avoid competition between seeds (^{Tielbörger & Prasse 2009}). The results of this study indicate that, although young seeds delay their mean germination time (non-deep physiological dormancy, ^{Baskin & Baskin 2004}), they also present a higher percentage of germination compared to old seeds, which could be a strategy to avoid intra-specific competition. It is also possible that, given to the typically stressful environmental inhabited by ruderal species (i.e., high temperatures and water scarcity), species of these environments could delay their germination until favorable conditions occur (^{Tielbörger & Prasse 2009}). Timing of seed germination is related with the permanence of species in variable environments, those genotypes with a high variation on this trait could adapt better to seasonal uncertainty, especially if the germination is retarded until the occurrence of favorable conditions. However, if early germination occurs, then natural selection would eliminate the unfavorable genotypes in the early stages of their life (^{Donohue et al. 2005}). In the present study, towards the end of the experiment, the seeds displayed faster germination than those that germinated at the beginning of the experiment. This rapid germination coincides with the lack of rainfall that would cause decreased survival of the seedlings of the four species of Asteraceae. It is important to conduct long-term evaluations of the mean germination time on stored seeds since it is known that retarded germination in Arabidopsis thaliana (L.) Heynh. increases its fitness (^{Donohoue et al. 2005}).

Seed longevity and seed viability. It is estimated that seed longevity of the four species of Asteraceae exceeded one year (19 months), considering the age of the seeds from the time of their collection. According to Thompson's classification (^{Thompson et al. 1997}), the studied species could therefore present a short-term persistent soil seed bank (ranging from 1 to 5 years). Although the viability and germination of the seeds decreased with increased longevity, the fact that they can potentially form a short-term seed bank makes development of an ex-situ seed conservation protocol feasible. Within a general pattern of decrease in germination, it is observed a lack of germination uniformity during the period of 375-465 days, when there were alternations between higher and lower germination. This germination asynchrony contributes to the maintenance of populations in seasonal environments (^{Bhatt et al. 2019}). In this study, germination asynchrony was observed in winter months when rain is scarce.

At the other hand, maintenance of viable seeds was similar among the study species. However, it is important to highlight that both A. dentata and S. origanoides were the species with the highest germination percentages, although these values did not exceed 30 %, which is low compared to the average maximum germination percentage (64.4 %) of 40 species of Asteraceae of arid and semiarid environments (^{Valencia-Díaz & Montaña
2003}). For other species of Stevia and Aldama, the maximum germination percentages are 71 and 97 %, respectively (^{Bertolosi et al. 2015}, ^{Uçar et al. 2016}). It is possible that the germination percentage observed in this study could increase in substrates that provide higher water availability to the seeds, so that there is a better imbibition to start and complete their germination. The large differences between the germination and viability percentages indicate that germination could be increased: this difference was 30.54 % for A. dentata, 26.21 % for S. origanoides, 27.77 % for V. virgata and 32.5 % for R. barba-johannis. On the other hand, according to ^{Fenner & Thompson (2005)}, dormancy is the mechanism used by seeds to persist for longer than one year in seed banks. In this case and considering the difference between seed viability and seed germination, the seeds of the studied Asteraceae could present dormancy that allows them to spread the occurrence of their germination over time.

Although the germination percentages of the species were not similar, the behavior in terms of viability, longevity and germination rate did follow a similar pattern. It is important to study the seed biology of useful weed species since this can facilitate the establishment of effective germplasm conservation and/or weed management programs. According to the information generated here, it is suggested to investigate lower seed storage temperatures that may prolong their longevity and avoid loss of viability.

Acknowledgements

We thank R. Jiménez-Salmeron for laboratory assistance. We also appreciate the invaluable help of G. Flores for species identification. Special thanks to K. MacMillan and three anonymous reviewers for their valuable comments. An early version of this manuscript was produced as the Bachelor thesis of AMJV at Facultad de Ciencias Biológicas-UAEM.

Literature cited

Aguilar-Santelises R, del Castillo RF. 2015. Demographic and socio-economic attributes as determinant of traditional knowledge among the mixtecs of Oaxaca, Southern Mexico. Human Ecology an Interdisciplinary Journal 47: 655-667. DOI: https://doi.org/10.1007/s10745-015-9772-y [ Links ]

Ballesteros D, Pence VC. 2017. Survival and death of seeds during liquid nitrogen storage: a case study on seeds with short lifespans. Cryoletters 38: 278-289. [ Links ]

Baskin CC, Baskin JM. 2004. A classification system for seed dormancy. Seed Science Research 14: 1-16. DOI: https://doi.org/10.1079/SSR2003150 [ Links ]

Benvenuti S, Cioni PL, Flamini G, Pardossi A. 2017. Weeds for weed control: Asteraceae essential oils as natural herbicides. Weed Research 57: 342-353. DOI: https://doi.org/10.1111/wre.12266 [ Links ]

Bertolosi BA, Santos de Oliveira T, Apezzato-da-Glória B, Coehho NADL. 2015. Seed germination of Brazilian Aldama species (Asteraceae). Journal of Seed Science 37: 185-191. DOI: https://doi.org/10.1590/2317-1545v37n3146138 [ Links ]

Bhatt A, Bath NR, Lozano-Isla F, Gallacher D, Santo A, Batista-Silvia W, Fernandes D, Pompelli MF. 2019. Germination asynchrony is increased by dual seed bank presence in two desert perennial halophytes. Botany 97: 639-649. DOI: https://doi.org/10.1139/cjb-2019-0071 [ Links ]

Blaix C, Moonen AC, Dostatny DF, Izquierdo J, Corff JLE, Morrison J, von Redwitz C, Schumacher M, Westerman PR. 2018. Quantification of regulating ecosystem services provided by weeds in annual cropping systems using a systematic map approach. Weed Research 58: 151-164. DOI: https://doi.org/10.1111/wre.12303 [ Links ]

Bretz F, Hothorn T, Westfall P. 2011. Multiple comparisons using R. New York: CRC Press. ISBN: 978-158-4885-74-0 [ Links ]

Brunick R. 2007. Seed dormancy in domesticated and wild sunflowers (Helianthus annuus L.): types, longevity and QTL discovery. PhD Thesis. Oregon State University. [ Links ]

Buitink J, Leprince O. 2018. Letters to the twenty first century botanist second series: What is a seed?-2. Regulation of desiccation tolerance and longevity in developing seeds: two faces of the same coin. Botany Letters 165: 181-185. DOI: https://doi.org/10.1080/23818107.2018.1476177 [ Links ]

Buitink J, Leprince O, Hemminga MA, Hoekstra FA. 2000. Molecular mobility in the cytoplasm: An approach to describe and predict lifespam of dry germoplasm. Proceedings of the National Academy of Sciences 97: 2385-2396. DOI: https://doi.org/10.1073/pnas.040554797 [ Links ]

Cadena-Rodríguez Y, Vázquez-Sánchez M, Cruz-Cárdenas G, Villaseñor JL. 2019. Use of ecological niche models of plant species to optimize placements of apiaries. Journal of Apicultural Science 63: 244-265. DOI: https://doi.org/10.2478/JAS-2019-0017 [ Links ]

Céspedes CL, Torres P, Marın JC, Arciniegas A, de Vivar AR, Pérez-Castorena AL, Aranda E. 2004. Insect growth inhibition by tocotrienols and hydroquinones from Roldana barba-johannis. Phytochemistry 65: 1963-1975. DOI: https://doi.org/10.1016/j.phytochem.2004.03.037 [ Links ]

Chena-Becerra F, Palmeros-Sánchez B, Fernández MS, Lozada-García JA. 2014. Antimicrobial activity of nine medicinal plants from Veracruz, México. International Journal of Applied Biology and Pharmaceutical Technology 5: 113-119. [ Links ]

Cicevan R, Al Hassan M, Sestras AF, Prohens J, Vicente O, Sestras RE, Boscaiu MM. 2016. Screening for drought tolerance in cultivars of the ornamental genus Tagetes (Asteraceae). Peer J 4: e2133. DOI: https://doi.org/10.7717/peerj.2133 [ Links ]

Crawley MJ. 1993. GLIM for ecologist. Oxford, UK: Blackwell Scientific Pub. ISBN: 063-203-1565 [ Links ]

Crawley MJ. 2013. The R book. Chichester, UK: John Wiley & Sons. ISBN: 978-0-470-97392-9 [ Links ]

Cruz-Fernández T, Alquicira-Arteaga ML, Flores-Palacios A. 2011. Is orchid species richness and abundance related to the conservation status of oak forest? Plant Ecology. 212: 1091-1099. DOI: https://doi.org/10.1007/s11258-010-9889-4 [ Links ]

Dickie JB, Ellis RH, Kraak HL, Ryders K, Tompsett PB. 1990. Temperature and seed storage longevity. Annals of Botany 65: 197-204. DOI: https://doi.org/10.1093/oxfordjournals.aob.a087924 [ Links ]

Diniz S, Prado PI, Lewinsohn TM. 2010. Species richness in natural and disturbed habitats: Asteraceae and flower-head insects. Neotropical Entomology 39: 163-171. DOI: https://doi.org/10.1590/S1519-566X2010000200004 [ Links ]

Donohue K, Dorn L, Griffith C, Kim G, Aguilera A, Polissety CR, Schmitt J. 2005. The evolutionary ecology of seed germination of Arabidopsis thaliana: variable natural selection on germination timing. Evolution 59: 758-770. DOI: https://doi.org/10.1111/j.0014-3820.2005.tb01751.x [ Links ]

Ellis RH. 1991. The longevity of seeds. HortScience 26: 1119-1125. [ Links ]

Fenner M, Thompson K. 2005. The Ecology of Seeds. Cambridge, USA. University Press. ISBN: 0-521-65368-1 [ Links ]

Funk VA, Randall JB, Keeley S, Chan R, Watson L, Gemeinholzer B, Schilling E, Panero JL, Baldwin BG, García-Jacas N, Alfonso S, Jansen RK. 2005. Everywhere but Antarctica: Using a supertree to understand the diversity and distribution of the Compositae. Biologiske Skrifter 55: 343-373. [ Links ]

García-Herrera P, Sánchez-Mata MC, Cámara M, Fernández-Ruíz V, Díez-Márques C, Molina M, Tardio J. 2014. Nutrient composition of six wild edible Mediterranean Asteraceae plants of dietary interest. Journal of Food Composition and Analysis 34: 163-170. DOI: https://doi.org/10.1016/j.jfca.2014.02.009 [ Links ]

Ghani A, Tehranifar A, Shooshtarian S, Boghrati M. 2011. Comparative study of ornamental potential of six Achillea species from Iran. South-Western Journal of Horticulture Biology and Environment 2: 139-155. [ Links ]

Ghasemnezhad A, Honermeier B. 2007. Influence of storage conditions on quality and viability of high and low oleic sunflower weeds. International Journal of Plant Production 3: 39-48. [ Links ]

Gomes V, Fernandes GW. 2002. Germination of Baccharis dracunculifolia DC (Asteraceae). Acta Botanica Brasilica 16: 421-427. DOI: https://doi.org/10.1590/S0102-33062002000400005 [ Links ]

Guzmán-Pantoja LE, Lina-García LP, Bustos-Zagal G, Hernández-Velázquez VM. 2012. Current Status: Mexican Medicinal Plants with insecticidal potential. In: Rasooli I, ed. Bioactive Compounds in Phytomedicine. Croatia: InTechOpen. ISBN: 978-953-307-805-2 [ Links ]

Heinrich M, Robles M, West JE, Ortiz de Montellano BR, Rodríguez E. 1998. Ethnopharmacology of Mexican Asteraceae (Compositae). Annual Review of Pharmacology and Toxicology 38: 539-565. DOI: https://doi.org/10.1146/annurev.pharmtox.38.1.539 [ Links ]

Hothorn T, Bretz F, Westfall P. 2008. Simultaneous inference in general parametric models. Biometrical Journal 50: 346-363. DOI: https://doi.org/10.1002/bimj.200810425 [ Links ]

Kochanek J, Bucley YM, Probert RJ, Adkins SW, Steadman J. 2010. Pre-zygotic parental environment modulates seed longevity. Austral Ecology 35: 837-848. DOI: https://doi.org/10.1111/j.1442-9993.2010.02118.x [ Links ]

Kurek K, Plitta-Michalak B, Ratajczak R. 2019. Reactive oxygen species as potential drivers of the seed aging process. Plants 8: 174-187. DOI: https://doi.org/10.3390/plants8060174 [ Links ]

Luo J, Cardina J. 2012. Germination patterns and implications for invasiveness in three Taraxacum (Asteraceae) species. Weed Research 52: 112-121. DOI: https://doi.org/10.1111/j.1365-3180.2011.00898.x [ Links ]

Martínez M, Roma VA, Ortega A, Quintero MDL, García C, Fronezec FR. 1983. Eudesmane triols from Verbesina virgata. Phytochemistry 22: 979-982. [ Links ]

Medina-Medrano JR, Torres-Contreras JE, Valiente-Banuet JI, Mares-Quiñones MD, Vásquez-Sánchez M, Álvarez-Bernal D. 2018. Effect of solid liquid extraction solvent on the phenolic content and antioxidant activity on three species of Stevia leaves. Separation Science and Technology 54: 2283-2293. DOI: https://doi.org/10.1080/01496395.2018.1546741 [ Links ]

Mora F, Alpan L, McCracken J, Nieto M. 2013. Chemical and biological aspects of the genus Verbesina. The Natural Products Journal 3: 140-150. DOI: https://doi.org/10.2174/2210315511303020009 [ Links ]

Moreno ME. 1984. Análisis físico y biológico de semillas agrícolas. Instituto de Biología. D.F. México: Universidad Nacional Autónoma de México. ISBN: 968-837-3044 [ Links ]

Ndihokubwayo N, Nguyen VT, Cheng D. 2016. Effects of origin, seasons and storage under different temperatures on germination of Senecio vulgaris. PeerJ 4: e2346. DOI: https://doi.org/10.7717/peerj.2346 [ Links ]

Nenaah GE, Ibrahim SIA, Al-Assiuty BA. 2015. Chemical composition, insecticidal activity and persistence of three Asteraceae essential oils and their nanoemulsions against Callosobruchus maculatus (F.). Journal of Stored Products Research 61: 9-16. DOI: https://doi.org/10.1016/j.jspr.2014.12.007 [ Links ]

Prebeg T, Bedran S, Žutić I. 2019. The effect of mechanical stress on transplants of three ornamental Asteraceae species. Journal of Central European Agriculture 20: 365-375. DOI: https://doi.org/10.5513/JCEA01/20.1.2063 [ Links ]

Probert RJ, Daws MI, Hay FR. 2009. Ecological correlates of ex situ seed longevity: a comparative study on 195 species. Annals of Botany 104: 57-69. DOI: https://doi.org/10.1093/aob/mcp082 [ Links ]

Pyšek P. 1997. Compositae as invaders: Better than the others? Preslia 69: 9-22. [ Links ]

R Core Team. 2017. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL https://www.R-project.org/. [ Links ]

Ranal MA, García de Santana D. 2006. How and why to measure the germination process. Revista Brasileira de Botanica 1: 1-11. DOI: https://doi.org/10.1590/S0100-84042006000100002 [ Links ]

Rodríguez-Arévalo I, Mattana E, García L, Liu U, Pritchard HW, Ulian T. 2017. Conserving seeds of useful wild plants in Mexico: main issues and recommendations. Genetic Resources and Crop Evolution 64: 1141-1190. DOI: https://doi.org/10.1007/s10722-016-0427-7 [ Links ]

Rodríguez MV, Bodrone MP, Castellari MP, Batlla D. 2018. Effect of storage temperature on dormancy release of sunflower (Helianthus annuus) achenes. Seed Science Research 21: 101-111. DOI: https://doi.org/10.1017/S0960258518000065 [ Links ]

Sakai AK, Allendorf FW, Holt JS, Lodge DM, Molofsky J, With KA, Baughman S, Cabin RJ, Cohen JE, Ellstrand NC, McCauley DE, O´Neil P, Parker IM, Thompson JN, Weller SG. 2001. The population biology of invasive species. Annual Review of Ecology and Systematics 32: 305-332. DOI: https://doi.org/10.1146/annurev.ecolsys.32.081501.114037 [ Links ]

Sano N, Rajjou L, North HM, Debeaujon I, Marion-Poll A, Seo M. 2016. Staying alive: Molecular aspects of seed longevity. Plant Cell and Physiology 57: 660-674. DOI: https://doi.org/10.1093/pcp/pcv186 [ Links ]

Solalinde-Vargas D. 2014. Área de actividad, uso de hábitat y conducta territorial de Bassariscus astutus en una zona periurbana. MSc Thesis. Universidad Autónoma del Estado de Morelos. [ Links ]

Stepp JR, Moerman DE. 2001. The importance of weeds in ethnopharmacology. Journal of Ethnopharmacology 75: 19-23. DOI: https://doi.org/10.1016/S0378-8741(00)00385-8 [ Links ]

Suárez-Mota ME, Villaseñor JL, Ramírez-Aguirre MB. 2018. Sitios prioritarios para la conservación de la riqueza florística y el endemismo de la Sierra Norte de Oaxaca, México. Acta Botánica Mexicana. 124: 1-28. DOI: https://doi.org/10.21829/abm124.2018.1296 [ Links ]

Tielbörger K. Prasse R. 2009. Do seeds sense each other? Testing for density-dependent germination in desert perennial plants. Oikos 118: 792-800. DOI: https://doi.org/10.1111/j.1600-0706.2008.17175.x [ Links ]

Thompson K, Baker JP, Bekker RM. 1997. The soil seed banks of North West Europe: Methodology, density and longevity. Cambridge, Cambridge University Press. ISBN: 05-214-9519-9 [ Links ]

Toh S, Imamura A, Watanabe A, Nakabayashi K, Okamoto M, Jikumaru Y, Hanada A, Aso Y, Ishiyama K, Tamura N, Iuchi S, Kobayashi M, Yamaguchi S, Kamiya Y, Nambara R, Kawakami N. 2008. High temperature-induced abscisic acid biosynthesis and its role in the inhibition of gibberellin action in Arabidopsis seeds. Plant Physiology 146: 1368-1385. DOI: https://doi.org/10.1104/pp.107.113738 [ Links ]

Uçar E, Özyiğit Y, Turgut K. 2016. The effects of light and temperature on germination of Stevia (Stevia rebaudiana Bert.) seeds. Turkish Journal of Agriculture Research 3: 37-40. DOI: https://doi.org/10.19159/tutad.76528 [ Links ]

Valencia-Díaz S, Montaña C. 2003. Effects of seed age, germination substrate, gibberelic acid, light and temperature on seed germination in Flourensia cernua (Asteraceae), a Chihuahuan Desert shurb. The Southwestern Naturalist 48: 1-13. DOI: https://doi.org/10.1894/0038-4909(2003)048<0001:EOSAGS>2.0.CO;2 [ Links ]

Van Etten ML, Conner JK, Chang SM, Baucom RS. 2017. Not all weeds are created equal: A data base approach uncovers differences in the sexual system of nature and introduced weeds. Ecology and Evolution 7: 2636-2642. DOI: https://doi.org/10.1002/ece3.2820 [ Links ]

Villaseñor JL, Ortiz E, Hinojosa-Espinosa O, Segura-Hernández G. 2011. Especies de la familia Asteraceae exóticas a la flora de México. México: SAGARPA, SENASICA, CONACOFI, IBUNAM, ASOMECIMA. ISBN: 978-607-96105-1-7. [ Links ]

Visscher AM, Seal CE, Newton RJ, Latorre FA, Pritchard HW. 2016. Dry seeds and environmental extremes: consequences for seed life span and germination. Functional Plant Biology 43: 656-668. DOI: https://doi.org/10.1071/FP15275 [ Links ]

Walck J. Baskin JM, Baskin CC. 1997. A comparative study of the seed germination biology of a narrow endemic and two geographically widespread species of Solidago (Asteraceae). 5. Effect of dry storage on after-ripening and survivorship. Seed Science Research 7: 311-318. DOI: https://doi.org/10.1017/S0960258500003664 [ Links ]

Xuan T, Minh TD, Trubg KH, Khanhi TD. 2016. Allelopathic of sweet potato varieties to control weeds: Imperata cylindrica, Bidens pilosa and Ageratum conyzoides. Allelopathy Journal 38: 41-54. [ Links ]

Yuan X, Wen B. 2016. Seed germination response to light, temperature and water stress in three invasive Asteraceae weeds from Xishuangbanna, SW China. PLoS ONE 13: e0191710. https://doi.org/10.1371/journal.pone.0191710 [ Links ]

Received: September 07, 2020; Accepted: December 18, 2020; Published: February 15, 2021

^*Author for correspondence: susana.valencia@uaem.mx

Associate editor: Pablo Cuevas Reyes

Author contributions: All authors contributed to the study conception and design. Material preparation, experiments and data collection were performed by AMJV. Experimental design, financial support and revision were performed by AFP. Revision and seed collection were made by AFM. Revision and theoretical input were made by IPA, JJAG, MCG. Conceptualization, data analyses, financial support and supervision were performed by SVD. All authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.

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