Seed integrity, effect of temperature and storage time on germination of Populus luziarum and P. primaveralepensis, endangered subtropical species from Mexico

Jacobo-Pereira, César; Muñiz-Castro, Miguel Ángel; Vázquez-García, J. Antonio; Flores, Joel; Muñoz-Urias, Alejandro; Huerta-Martínez, Francisco Martín; Jacobo-Pereira, César; Muñiz-Castro, Miguel Ángel; Vázquez-García, J. Antonio; Flores, Joel; Muñoz-Urias, Alejandro; Huerta-Martínez, Francisco Martín

doi:10.17129/botsci.2810

Servicios Personalizados

Revista

Articulo

Indicadores

Citado por SciELO
Accesos

Links relacionados

Similares en SciELO

Otros
Otros

Permalink

Botanical Sciences

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

Bot. sci vol.100 no.1 México ene./mar. 2022 Epub 03-Feb-2022

https://doi.org/10.17129/botsci.2810

Physiology

Seed integrity, effect of temperature and storage time on germination of Populus luziarum and P. primaveralepensis, endangered subtropical species from Mexico

Integridad de semillas, efecto de temperatura y tiempo de almacenamiento en la germinación de Populus luziarum y P. primaveralepensis, especies subtropicales en peligro de extinción de México

César Jacobo-Pereira¹
http://orcid.org/0000-0003-1454-575X

Miguel Ángel Muñiz-Castro²
http://orcid.org/0000-0002-9127-057X

J. Antonio Vázquez-García²
http://orcid.org/0000-0002-8393-5906

Joel Flores³
http://orcid.org/0000-0001-8856-6022

Alejandro Muñoz-Urias⁴^*
http://orcid.org/0000-0003-0828-9729

Francisco Martín Huerta-Martínez⁴
http://orcid.org/0000-0001-6923-3425

^¹ Doctorado en Ciencias en Biosistemática, Ecología y Manejo de Recursos Naturales y Agrícolas, Universidad de Guadalajara, Zapopan, Jalisco, México.

^² Instituto de Botánica, Departamento de Botánica y Zoología, Centro Universitario de Ciencias Biológicas y Agropecuarias, Universidad de Guadalajara, Zapopan, Jalisco, México.

^³ Instituto Potosino de Investigación Científica y Tecnológica A.C., División de Ciencias Ambientales, San Luis Potosí, México.

^⁴ Departamento de Ecología, Centro Universitario de Ciencias Biológicas y Agropecuarias, Universidad de Guadalajara, Zapopan, Jalisco, México.

Abstract

Background:

Populus luziarum and P. primaveralepensis are endemic species of western Mexico; growing in riparian forests they are critically endangered. The best way to conserve their seeds is unknown, which could be limiting for their conservation.

Hypothesis:

The germinability of both subtropical species is like that of boreal and template Salicaceae species that disperse seeds in spring and early summer, as they germinate quickly with high percentages, and rapidly lose their viability when stored at ambient temperature.

Studied species:

Populus luziarum and P. primaveralepensis.

Study site and dates:

Western Trans-Mexican Volcanic Belt. Jalisco, Mexico. October 2019.

Methods:

The physical integrity of the seeds was assessed by X-ray imaging and compared with germinability. In addition, the effect of storage time (nine weeks) under two temperatures (4 and 21 °C) on the percentage and mean germination rate was evaluated.

Results:

No significant differences were found between physical integrity and germination in freshly collected seeds for both species. Germination in the first 24 hrs was 91 and 95 % for Populus luziarum and P. primaveralepensis, respectively (week 0). Germination percentages were lower when stored at 21 °C, but P. primaveralepensis was decreased more slowly.

Conclusions:

Seeds of subtropical Populus respond similarly to those of species from temperate and boreal climates with early seed dispersal, a crucial condition for establishing ex situ reforestation and conservation programs.

Keywords: Salicaceae; seed physical integrity; seed storage conditions; subtropical endemic species; white poplars

Resumen:

Antecedentes:

Populus luziarum y P. primaveralepensis son especies endémicas del occidente de México; crecen en bosques ribereños están en peligro crítico. Se desconoce la mejor manera para conservar sus semillas, lo que podría ser limitante para su conservación.

Hipótesis:

La germinabilidad de ambas especies subtropicales, es similar al de las especies de la familia Salicaceae boreales y templadas que dispersan semillas en primavera y principios de verano, ya que germinan rápido con altos porcentajes y pierden rápidamente su viabilidad cuando se almacenan a temperatura ambiente.

Especies estudiadas:

Populus luziarum y P. primaveralepensis.

Sitio de estudio y fecha:

Cinturón Volcánico Trans-Mexicano Occidental. Jalisco, México. Octubre 2019.

Métodos:

se evaluó la integridad física de las semillas mediante imágenes de rayos X y se comparó con germinabilidad. Además, se evaluó el efecto del tiempo de almacenamiento (nueve semanas) bajo dos temperaturas (4 y 21 °C) en el porcentaje y la tasa media de germinación.

Resultados:

No se encontraron diferencias significativas entre la integridad física y la germinación en semillas recién recolectadas, para ambas especies. La germinación en las primeras 24 horas fue 91 y 95 % para Populus luziarum y P. primaveralepensis respectivamente (semana 0). Los porcentajes de germinación fueron menores cuando se almacenaron a 21 °C. pero Populus primaveralepensis disminuyó más lentamente.

Conclusiones:

Las semillas de Populus subtropicales responden de forma similar a las de las especies de climas templados y boreales con una dispersión temprana de las semillas, una condición crucial para establecer programas de repoblación y conservación ex situ.

Palabras clave: Álamos blancos; condiciones de almacenamiento de semillas; especies endémicas subtropicales; integridad física de semillas; Salicaceae

The genus Populus L. (Salicaceae Mirb.) consists of 32 species worldwide, mostly distributed in the temperate zone of the Northern Hemisphere (^{Kim 2018}). Poplars have an outstanding economic importance for production of wood of industrial purposes, furniture and firewood. Also, they prevent soil erosion, favor restoration of riverbank environments and carbon sequestration reducing the effects of climate change (^{Gordon 2001}). In Mexico, there are 11 species, outnumbering those of the United States (eight spp.) The state of Jalisco, with five species of poplars, represents 45 % of Mexican species richness of the genus and 16 % worldwide (^{Vázquez-García & Cuevas-Guzmán 1989}, ^{Eckenwalder 1996}, ^{Martínez-González & González-Villarreal 2005}, ^{Dickmann & Kuzovkina 2014}, ^{Vázquez-García et al. 2017}, ²⁰¹⁹). The two newly described species of white poplars: Populus luziarum A. Vázquez, Muñiz-Castro & Padilla-Lepe and P. primaveralepensis A. Vázquez, Muñiz-Castro & Zuno, are endemic to central Jalisco, have a very restricted distribution along riparian forests and consist of few and small populations, thus, they are ranked as critically endangered following the criteria of the IUCN Red List, and urgently need a conservation strategy (^{Vázquez-García et al. 2017}, ²⁰¹⁹, ^{IUCN 2019}).

Seed production, dispersal and germination are important factors constraining population dynamics (^{Harper 1977}). Germination, from imbibition to radicle emergence, is often the most critical phase, during the life cycle of any terrestrial plant (^{Vázquez-Yanez & Orozco-Segovia 1993}).

In the family Salicaceae, there are species of temperate (mesothermal) and cold (continental, microthermal) climates with two seed dispersal periods: late spring-early summer (hereafter name as “early”) and late summer-early autumn (hereafter named as “late”) (^{Zasada & Viereck 1975}, ^{Zasada & Densmore 1980}) in addition, some subtropical (megathermal) species are reported, where the relationship between germination and seed dispersal is scarcely known. Populus seeds do not develop a dormant state but have high viability and germination percentage (^{Karrenberg et al. 2002}). Due to their characteristics, Populus luziarum and P. primaveralepensis seeds are small, measuring between 0.2 × 0.1 mm and 0.3 - 0.7 × 0.2 - 0.4 mm, long and width respectively (^{Vázquez-García et al. 2017}, ²⁰¹⁹), so they are considered “late seed-dispersing species” as in other species of the same genus, the seeds can be dispersed by wind or water (^{Karrenberg et al. 2002}). Since Populus seeds lack endosperm, they contain little energy, and their longevity is limited to a few days or weeks and prevent the formation of long-term seed banks under natural conditions (^{Muller et al. 1982}, ^{Venable & Brown 1988}, ^{Karrenberg et al. 2002}, ^{Bonner 2008}). Seed storage of Populus does well at low temperatures, near or below 0 °C, particularly in late seed-dispersing species from boreal to template regions of the Northern Hemisphere with subarctic, circumpolar or cold climates (^{Moss 1938}, ^{Zasada & Viereck 1975}, ^{Tauer 1979}, ^{Zasada & Densmore 1980}, ^{Fechner et al. 1981}, ^{Pence 1996}, ^{González et al. 2010}, ^{Popova et al. 2013}, ^{Kim 2018}). Under ex-situ conservation conditions, seeds tend to increase their longevity by about 12 years or more, but their viability may deteriorate (^{Popova et al. 2013}, ^{Kim 2018}). It is unknown whether cold conditions (4 °C) are favorable in late seed-dispersing subtropical species since no studies are known from subtropical climates (^{Holdridge 1967}) as those of Mexican mountains and highlands. Also, the method of storing Populus seeds could depend on the species (^{Wyckoff & Zasada 2008}). Optimal storage conditions for Populus luziarum and P. primaveralepensis seeds are yet to be determined, so studies are needed to develop short and long-term seed conservation protocols in subtropical species. We hypothesize that germinability behavior of Populus luziarum and P. primaveralepensis, subtropical species are like Salicaceae boreal and template species dispersed in spring or early summer, since they have characteristics such as high germination percentages, germinate faster and loss of viability when stored at ambient temperature. This study can contribute to the knowledge of ex-situ conservation of these two endemic and endangered species in western Mexico, providing new life history data of both species and allowing plant production to contribute to their population and restoration.

Materials and methods

Seeds of the two species were collected on two riparian forests of western Mexico. Both species are in the municipality of Zapopan, Jalisco, Mexico (^{Vázquez-García et al. 2017}, ²⁰¹⁹). Populus luziarum is found in Arroyo La Virgen (20° 48' 53.22'' N, 103° 34' 51.30'' W), with an average annual temperature of 21.3 °C, and annual precipitation of 942 - 946 mm (^{Ruiz-Corral et al. 2018}). Populus primaveralepensis in Arroyo La Lobera (26° 18' 0'' N, 103° 35' 59.9'' W) in the Área de Protección de Flora y Fauna La Primavera. Annual precipitation ranges from (899 - 910 mm), with an average annual temperature of 20.6 °C (^{SEMARNAP 2000}, ^{Ruiz-Corral et al. 2018}) (Figure 1).

Source: Esri, HERE, Garmin, Intermap, increment P Corp., GEBCO, USGS, FAO, NPS, NRCAN, GeoBase, IGN, Kardaster NL, Ordnance Survey, Esri Japan, METI, Esri China (Hong Kong), swisstopo, © OpenStreetMap contributors, and the GIS User Community

Figure 1 Seed collection sites for Populus luziarum and P. primaveralepensis in central Jalisco in the western Trans-Mexican Volcanic Belt.

Seed collection and management. During October 2019, catkins with yellowish and brown capsules slightly opened showing cottoned seeds (mature capsules) (^{Bonner et al. 2008}) were collected from five branches of at least 10 trees per species 10 - 400 m apart each other, for a total 250 catkins of Populus luziarum and 310 of P. primaveralepensis. They were taken to the Laboratory of Evolution of Ecological Systems of the Centro Universitario de Ciencias Biológicas y Agropecuarias (CUCBA) of the Universidad de Guadalajara, in airtight plastic bags. The seeds were immediately extracted from the capsules by hand using a strainer; about 1,200 seeds per species were obtained. The seeds were placed for (zero to eight weeks) in sterile plastic bottles with hermetic caps, in two storage conditions: average room temperature inside the laboratory (21 °C), and at 4 °C, placed inside a refrigerator (TOR-REY, Model R-14).

Physical integrity of the seeds. The physical integrity of freshly collected seeds of both species was evaluated according to ^{ISTA (2020)} using X-ray equipment (FAXITRON, Model MX-20, Specimen X-ray System), at the National Center for Genetic Resources (CNRG-INIFAP), in Tepatitlán de Morelos, Jalisco, Mexico. A total of 100 seeds of each species (five replicates with 20 seeds each), were placed on a transparent adhesive tape (double-sided) and fixed in transparent plastic foil. The plastic foil was placed inside the X-ray equipment and subject to radiation for 12 s at 26 kV. Internal morphological changes that could produce damage to seeds during the ripening process and that could influence germination were identified. The number of full and undamaged seeds was quantified and repotted in percentage.

Germination tests. An experiment with 100 seeds randomly selected per specie was carried out to obtain the percentages of germination, five replicates of 20 randomly selected seeds were used. Seeds were placed in sterile glass Petri dishes (60 × 15 mm), containing cotton pads, which were soaked just one time with 5 ml of distilled water, sealed with plastic wrap to prevent evaporation. They were placed in a germination chamber (LUZEREN, Model SPX250) with photoperiods of 12 hrs at 24 °C, based on ^{Karrenberg et al. 2002} who cited that Populus germinate more than 80 % at 15 to 27 °C. The seed was considered germinated when the radicle was observed (^{Baskin & Baskin 2014}) and compare them with the results of the physical integrity. In the second experiment, the storage time factor with nine levels (zero to eight weeks) was evaluated across two levels of storage temperature treatments: 21 and 4 °C, both temperatures were selected because they have been tested in Salicaceae species, in particular Populus (^{Moss 1938}, ^{Siegel & Brock 1990}).

The experimental design was completely randomized, with a 2 × 9 factorial arrangement, with two storage temperatures, and nine storage time trials. For both storage temperatures, freshly collected seeds (week 0) and eight sequential stored seed lots were put to germinate every week, from zero to eight week. For each combination of treatments per species, similar conditions at germination test of first experiment, the number of seeds germinated was recorded daily until seventh day, after no further germination occurred. The number of germinated seeds were counted and expressed as germination percentage, that was calculated, as per the formula by ^{Scott et al. (1984)}:

Germination %=∑i=1kn1N×100

were, n _i the number of seeds germinated in each experimental unit, k the last day of germination evaluation and N, the total number of seeds. Mean germination rate was calculated as the reciprocal of the mean germination time, according to ^{Ranal et al. (2009)}. Mean germination time t- is calculated as:

t-=∑i=1kniti∑i=1kni

where t _i the time from the beginning of the experiment to the i ^th observation (in days); n _i the number of seeds germinated in the i ^th time (not the accumulated number, but the number corresponding to the i ^th observation), and k, the last day of germination evaluation.

Statistical analysis. A Chi-square χ² goodness of fit test was used between the number of seeds with good physical integrity and total germinated seeds from freshly collected seeds. Additionally, germination curves were analyzed through time with a logarithmic regression for both storage treatments, since this was the one that had the best adjustment according to its determination coefficient. Later, germinability and mean germination rate data were analyzed with analysis of variance (two ways ANOVA), where the storage time (weeks) and the storage temperature treatment were used as discrete explanatory factors. The germination percentage was transformed with Arcsinx100 where x is the germination percentage (^{Ranal & Santana 2006}). In both ANOVAs, Shapiro-Wilk test was used to test for normality and a Bartlett test was used to test for equal variances (^{Crawley 2012}). Means were compared using a Tukey test when differences statistical were observed. The germinability result was presented as percentage. All statistical analyses were performed with the R statistical language (^{R Core Team 2018}).

Results

It was observed that 96 % (Populus luziarum) and 98 % (P. primaveralepensis) of seeds were fully developed, with a well-defined embryonic axis (radius lucida region), and without insect, mechanic damage or malformations. The rest of the seeds showed entire seed cavity opaque, so the embryonic axis is not observed (Figure 2). We found 91 and 95 % of the seeds germinated in 24 h for P. luziarum and P. primaveralepensis, respectively, after this time no germination was observed (Figure 3). Furthermore, no statistically significant differences were found between the proportions of physical integrity test and germination of recently collected seeds (Table 1).

Figure 2 X-ray images of the physical integrity of Populus luziarum (A, B) and P. primaveralepensis seeds (C, D). The arrows indicate embryonic structures. (A, C) and full and undamaged seeds, (B, D) seeds without defined embryonic structures.

Figure 3 Germination after 24 hrs, at the emergence of the radicle. (A) Populus luziarum and (B) P. primaveralepensis.

Table 1 χ² goodness of fit test between germination from freshly collected and physical integrity seeds (full and without damages) of Populus luziarum and P. primaveralepensis (n = 100).

Species	Physical integrity (%)	Germination (%)	χ²	P-value
Populus luziarum	96	91	0.1336	0.7146
Populus primaveralepensis	98	95	0.0466	0.8290

Seeds of Populus luziarum also showed a decrease in germination concerning increased time. Based on logarithmic adjustment, the coefficients of determination were R ² = 0.86 and R ² = 0.86 for seeds stored at 4 and 21 °C, respectively (Figure 4). If the conditions are kept constant, according to equations generated, in seeds stored at room temperature, germination will decrease 44 % before first week of storage, and will decrease 91 % after eight weeks of storage. In contrast, the refrigerated seeds decreased their germination until 50 % in seven weeks. ANOVA revealed significant differences between storage temperature levels (F = 44.06, P < 0.001) and weeks storage (F = 63.46, P < 0.001) for germination percentage. The highest germinability was observed at week 0 for both the 4 and 21 °C storage treatments (93 ± 2.0 and 91 ± 2.4 %), respectively. The lowest germination (14 %) was obtained after the fifth week for the 21 °C treatment and the eight weeks for the seeds stored at 4 °C, (Table 2). The mean germination rate was generally rapid but differed statistically among weeks storage (F = 4.78, P < 0.01). Week seven had the slowest mean germination rate of 0.6 ± 0.09 day ^-1, while the fastest germination was obtained at week 0 (0.9 ± 0.01 day ^-1) (Figure 5).

Figure 4 Decrease in germination rates of Populus luziarum seeds under different temperatures storage conditions over time.

Table 2 Effects of temperature and weeks storage on seed germination percentage of Populus luziarum. Different lower-case letters next to the standard error indicate significant differences between means (P < 0.05) according to Tukey test.

Weeks storage	Temperature (°C)	Germination (%)	Weeks storage	Temperature (°C)	Germination (%)
0	4	93 ± 2.0 a	5	4	26 ± 6.2 cdef
	21	91 ± 2.4 a		21	14 ± 2.9 efgh
1	4	60 ± 3.5 b	6	4	21 ± 1.8 cdefg
	21	42 ± 10.5 bc		21	11 ± 2.4 fgh
2	4	54 ± 4.3 b	7	4	17 ± 2.5 defg
	21	35 ± 6.8 bcde		21	7 ± 1.2 gh
3	4	42 ± 3.3 bc	8	4	14 ± 4.0 efgh
	21	27 ± 3.3 cdef		21	4 ± 1.0 h
4	4	37 ± 5.1 bcd
	21	20 ± 5.2 cdefg

Figure 5 Mean germination rate (day ^-1) for Populus luziarum among different weeks storage. Means and ± SE, different lower-case letters denote significant differences, according to Tukey test (P < 0. 05).

The trends in germination percentages for the different storage times for the seeds of Populus primaveralepensis, with the treatments at 4 and 21 °C, had the best adjustment R ² = 0.87 and R ² = 0.70, respectively, to a logarithmic regression, in which a decrease in germination percentage was observed as storage time increases (Figure 6). Based on the equation obtained, if the seeds are stored at room temperature the germination will be reduce to 54 % in one week, and 94 % in eight weeks, while the refrigerated seeds reduce their germination until 55 % in two weeks. ANOVA of germinability revealed statistically significant differences between storage temperature treatments (F = 328.35, P < 0.001), storage times (F = 105.82, P < 0.001) and the interaction of factors (F = 13.13, P < 0. 001). The highest germination percentages were obtained in week 0 (95 ± 0.31 and 94.8 ± 0.37 %) at 4 and 21 °C respectively, and it decreased as the time of storage increased. From the fourth week on, there were significant differences in germination percentages among the storage treatments carried out per week. In the eighth week, the germination percentages were 4 ± 1.8 % for the storage temperature of 21 °C, while it was 41 ± 2.4 % for that of 4 °C (Table 3). On the other hand, the mean germination rate did not differ significantly among the storage temperature levels (F = 3.043, P > 0.001), but there were significant differences between weeks storage (F = 4.382, P = < 0.001). Mean germination rate was generally fast, values between 0.9 ± 0.01 day ^-1 and 0.6 ± 0.06 day ^-1 were obtained; however, there was no tendency for the mean germination rate to decrease with storage time (Figure 7).

Figure 6 Decrease in germination rates of Populus primaveralepensis seeds under different temperature storage conditions over time.

Table 3 Effects of temperature and weeks storage on seed germination percentage of Populus primaveralepensis. Different lower-case letters next to the standard error indicate significant differences between means (P < 0.05) according to Tukey test.

Weeks storage	Temperature (°C)	Germination (%)	Weeks storage	Temperature (°C)	Germination (%)
0	4	94.8 ± 0.4 a	5	4	54 ± 3.3 def
	21	95 ± 0.3 a		21	10 ± 1.6 h
1	4	89 ± 3.7 ab	6	4	52 ± 4.1 def
	21	77 ± 2.9 bc		21	9 ± 1.9 h
2	4	71 ± 4.3 cd	7	4	45 ± 7.6 ef
	21	51 ± 1.9 def		21	6 ± 1.0 h
3	4	61 ± 4.3 cde	8	4	41 ± 2.4 efg
	21	34 ± 4.3 fg		21	4 ± 1.9 h
4	4	59 ± 2.4 cde
	21	26 ± 1.9 g

Figure 7 Mean germination rate (day ^-1) for Populus primaveralepensis among different weeks storage. Means and ± SE, different lower-case letters denote significant differences, according to Tukey test (P < 0. 05).

Discussion

The hypothesis of this work is accepted, since, that seeds dispersal for Populus luziarum and P. primaveralepensis occurs in autumn, however, seed gemination behavior is similar to that of species dispersed in spring or early summer, since they have characteristics such as high germination percentages, germinate faster and loss viability when stored at ambient temperature.

The results of this study showed a high percentage of germination during the first 24 h in freshly collected seeds. Very fast germination may be crucial because ants collect seeds but not seedlings, thus rapid transition from seeds to seedlings allows escape from ant predation (^{Parsons 2012}). Very fast germination also indicates that seeds of both species are non-dormant, which coincides with findings by ^{Karrenberg et al. (2002)} for several Populus species. The lack of dormancy, as well as the fluctuations in temperature and humidity in the seeds, makes them have short longevity and a faster decrease of viability (^{Siegel & Brock 1990}). ^{Zasada & Viereck (1975)} and ^{Karrenberg et al. (2002)} reported that late seed dispersing species of Salicaceae maintain viability at low temperatures (e.g. Salix glauca for eight to nine months), and even require stratification for germination after winter. In contrast, Populus luziarum and P. primaveralepensis reduced germination percentages at 4 °C after four weeks. Both species recorded high germinability (91 and 95 %) respectively without stratification, suggesting a distinct pattern of germination behavior for subtropical Populus species.

In this study, we found that temperature at 4 °C could maintain seed longevity and thus prolong the percentage of germination in both species until to four weeks with percentages greater than 50 %. Similar results have been obtained by ^{Kim (2018)} for Populus davidiana and P. koreana, species with early seed dispersal, registered germination percentages of 97 and 87 %, respectively, for non-stocked seeds, these percentages were significantly reduced in the four weeks of storage at room temperature of 25 °C. However, storage at low temperatures prolonged viability and maintained initial germination percentage for both species. Our results also coincide with ^{Moss (1938)}, with high initial germination of almost 100 % for P. tremuloides, P. balsamifera, and P. petrowskyana, early seed dispersing temperate and boreal species, but in storage conditions at 21 °C, there was a gradual decrease to 45 % at eight weeks and an absence of germinating seeds at 15 weeks for all species. In addition, in storage condition at -5 °C, species showed an increase of longevity, even after two years some seeds obtained 70 % germination. But our results contrast with those obtained by ^{González et al. (2010)} for Populus alba, with 92 % of germination in recently collected seeds that remained viable for two weeks (> 80 %), at average room temperature of 22 °C, with seed longevity relatively long with average viability period of 30 days.

The mean germination rate for both species Populus luziarum and P. primaveralepensis (Figures 5 and 7) registered significant differences among storage times, but the differences are not large, this behavior coincides with the species of Populus without endosperm (^{Karrenberg et al. 2002}, ^{González et al. 2010}). This also coincides with reports by ^{Vandelook et al. (2012)} and ^{Chilpa-Galván et al. (2018)} that endosperm reduction may have evolved as an adaptation to favorable conditions for rapid germination, thus allowing growth and establishment in a short time in favorable environments. A decline in germination percentage observed for Populus luziarum as storage time did increase could partly explain why its population size is smaller than that of P. primaveralepensis, however, this seems to be compensated with the clonal reproduction strategy through rhizomes, while in P. primaveralepensis, being more efficient in its germination, without clones (^{Vázquez-García et al. 2019}).

According to ^{Maroder et al. (2000)} and ^{Kim (2018)}, the correlation observed between low-temperature storage and germination in this study could be explained because low temperature maintains the moisture content in the seeds, which is the main factor controlling all cellular activities. ^{Bonner (2008)} and ^{Pritchard & Nadarajan (2008)} mentions that seeds can be kept viable for several years, when stored at sub-zero temperatures and in a dry atmosphere. For future research, we suggest to include treatments at temperatures below 0 °C and cryopreservation for more promising ex situ seed conservation of these species (^{Suszka et al. 2014}), as it has been shown that these techniques could obtain favorable results in longevity and maintain viability for longer periods (^{Pawłowski et al. 2019}).

The high percentages of physical integrity of seeds through the analysis of X-ray images, and seed germination for both Populus species, are consistent with those reported by ^{Javorski & Moure (2017)} and ^{Javorski et al. (2018)} who indicate a significant relationship between physical integrity and germination percentages. ^{Gomes-Junior et al. (2013)} and ^{De Medeiros et al. (2018)} obtained similar results for a wide variety of species in different genera. According to the results of the present research, X-ray image analysis for Populus luziarum and P. primaveralepensis seeds can be a competent, non-destructive alternative that allows a realistic assessment of physical integrity (^{Gomes-Junior et al. 2012}). This coincides with the reported by ^{Abud et al. (2018)} and ^{De Medeiros et al. (2020)}, about the positive and significant correlations, among morphology, internal physiological quality of the seeds, viability and germination percentage.

The results of this study provide valuable information, revealing that decrease of germination capacity is related to the storage conditions of the seeds. In general, our data contribute to the understanding of the processes associated with ex situ seed conservation and the strategies to increase the possibility of maintaining viable seeds for subtropical Populus species.

Acknowledgements

We thank anonymous reviewers for suggesting improvements to the manuscript. To the Agricultural Forestry Laboratory, Orthodox Seeds Section of the National Center for Genetic Resources (CNRG-INIFAP, Jalisco, Mexico), especially to Dr. J. M. Pichardo Gonzalez for his support and advice in carrying out this work. To the Consejo Nacional de Ciencia y Tecnología (CONACYT), for the funding granted for this research to the first author (CVU): 923519. To Doctorado en Ciencias en Biosistemática, Ecología y Manejo de Recursos Naturales y Agrícolas (BEMARENA) and the Centro Universitario de Ciencias Biológicas y Agropecuarias of the Universidad de Guadalajara.

Literature cited

Abud HF, Cicero SM, Gomes-Junior FG. 2018. Radiographic images and relationship of the internal morphology and physiological potential of broccoli seeds. Acta Scientiarum Agronomy 40: 1-9. DOI: https://doi.org/10.4025/actasciagron.v40i1.34950 [ Links ]

Baskin CC, Baskin JM. 2014. Seeds: Ecology, biogeography, and evolution of dormancy and germination. San Diego: Elsevier Sciences. ISBN 13: 978-0-12-416677-6 [ Links ]

Bonner FT. 2008. Storage of seed. In: Bonner FT, Karrfalt RP, eds. The woody plant seed manual agriculture Handbook 727, Washington DC. U.S. Department of Agriculture, Forest Service pp. 85-96. https://www.fs.usda.gov/treesearch/pubs/32626 (accessed May 20, 2019) [ Links ]

Chilpa-Galván N, Márquez-Guzmán J, Zotz G, Echevarría-Machado I, Andrade JL, Espadas Manrique C, Reyes-García C. 2018. Seed traits favouring dispersal and establishment of six epiphytic Tillandsia (Bromeliaceae) species. Seed Science Research 4: 349-359. DOI: https://doi.org/10.1017/S0960258518000247 [ Links ]

Crawley MJ. 2012. The R Book. UK: John Wiley & Sons. ISBN 978-0-470-97392-9 [ Links ]

De Medeiros AD, Araújo JO, León MJZ, Da Silva LJ, Dias DCFS. 2018. Parameters based on X-ray images to assess the physical and physiological quality of Leucaena leucocephala seeds. Ciência e Agrotecnologia 42: 643-652. DOI: https://doi.org/10.1590/1413-70542018426023318 [ Links ]

De Medeiros AD, Zavala-León MJ, Da Silva LJ, Oliveira AMS, Dias DCFS. 2020. Relationship between internal morphology and physiological quality of pepper seeds during fruit maturation and storage. Agronomy Journal 112: 25-35. DOI: https://doi.org/10.1002/agj2.20071 [ Links ]

Dickmann DI, Kuzovkina J. 2014. Poplars and willows of the world, with emphasis on silviculturally important species. In: Isebrands JG, Richardson J, eds. Poplars and Willows: Trees for Society and the Environment. Rome: CAB International and FAO, pp. 88-91. DOI: https://doi.org/10.1079/9781780641089.0008 [ Links ]

Eckenwalder JE. 1996. Systematics and evolution of Populus. In: Stettler RF, Bradshaw Jr. HD, Heilman PE, Hinckley TM, eds. Biology of Populus and its implications for management and conservation, Part I, Ottawa: NRC Research Press, pp.7-32. ISBN: 0-660-16506-6 [ Links ]

Fechner GH, Burr KE, Myers JF. 1981. Effects of storage, temperature, and moisture stress on seed germination and early seedling development of trembling aspen. Canadian Journal of Forest Research 11: 718-722. DOI: https://doi.org/10.1139/x81-100 [ Links ]

Gomes-Junior FG, Chiquito AA, Marcos-Filho J. 2013. Semi-automated assessment of the embryonic area of cucumber seeds and its relationship to germination and seedling length. Journal of Seed Science 35: 183-189. DOI: https://doi.org/10.1590/S2317-15372013000200007 [ Links ]

Gomes-Junior FG, Yagushi JT, Belini UL, Cicero SM, Tomazello-Filho M. 2012. X-ray densitometry to assess internal seed morphology and quality. Seed Science and Technology 40: 102-107. DOI: https://doi.org/10.15258/sst.2012.40.1.11 [ Links ]

González E, Comín FA, Muller E. 2010. Seed dispersal, germination and early seedling establishment of Populus alba L. under simulated water table declines in different substrates. Trees 24: 151-163. DOI: https://doi.org/10.1007/s00468-009-0388-y [ Links ]

Gordon JC. 2001. Poplars: trees of the people, trees of the future. The Forestry Chronicle 77: 217-219. DOI: https://doi.org/10.5558/tfc77217-2 [ Links ]

Harper JL. 1977. Population Biology of Plants. London: Academic Press, ISBN: 9780123258502 [ Links ]

Holdridge LR. 1967. Life zone ecology. San José: Tropical Science Center, ISBN 13: 9780719518867 [ Links ]

ISTA [International Seed Testing Association]. 2020. Rules for Seed Testing. International Seed Testing Association. [ Links ]

IUCN. 2019. IUCN Red List Categories and Criteria: Version 3.1. Second edition. Gland, Switzerland and Cambridge, UK: IUCN, iv +32 pp. https://www.iucnredlist.org/resources/categories-and-criteria (accessed March 14, 2019). [ Links ]

Javorski M, Castan DOC, Silva SS, Gomes-Junior FG, Cicero SM. 2018. Image analysis to evaluate the physiological potential and morphology of pearl millet seeds. Journal of Seed Science 40: 127-134. DOI: https://doi.org/10.1590/2317-1545v40n2176904 [ Links ]

Javorski M, Moure S. 2017. Utilização de raios x na avaliaçãoda morfologia interna de sementes de sorgo. Revista Brasileira de Milho e Sorgo 16: 310-318. DOI: https://doi.org/10.18512/1980-6477/rbms.v16n2p310-318 [ Links ]

Karrenberg S, Edwards PJ, Kollmann J. 2002. The life history of Salicaceae living in the active zone of floodplains. Freshwater Biology 47: 733-748. DOI: https://doi.org/10.1046/j.1365-2427.2002.00894.x [ Links ]

Kim DH. 2018. Extending Populus seed longevity by controlling seed moisture content and temperature. Plos One 13: p.e0203080. DOI: https://doi.org/10.1371/journal.pone.0203080 [ Links ]

Maroder HL, Prego IA, Facciuto GR, Malldonado SB, Maldonado SB. 2000. Storage behaviour of Salix alba and Salix matsudana seeds. Annals of Botany 86: 1017-1021. DOI: https://doi.org/10.1006/anbo.2000.1265 [ Links ]

Martínez-González RE, González-Villarreal LM. 2005. Taxonomía y biogeografía del género Populus, (Salicaceae) en México. BSc Thesis. Universidad de Guadalajara. [ Links ]

Moss EH. 1938. Longevity of Seed and establishment of seedlings in species of Populus. Botanical Gazette 99: 529-542. [ Links ]

Muller C, Teissier du Cros E, Laroppe E, Duval H. 1982. Conservation pendant 5 ans de graines de peupliers noirs (Populus nigra L.). Annales des Sciences Forestieres 39: 179-185. DOI: https://doi.org/10.1051/forest:19820205 [ Links ]

Parsons RF. 2012. Incidence and ecology of very fast germination. Seed Science Research 22: 161-167. DOI: https://doi.org/10.1017/S0960258512000037 [ Links ]

Pawłowski TA, Klupczyńska EA, Staszak AM, Suszka J. 2019. Proteomic analysis of black poplar (Populus nigra L.) seed storability. Annals of Forest Science 76: 104. DOI: https://doi.org/10.1007/s13595-019-0887-y [ Links ]

Pence VC. 1996. Germination, desiccation and cryopreservation of seed of Populus deltoides Barr. Seed Science and Technology 24: 151-157. [ Links ]

Popova EV, Kim DH, Han SH, Moltchanova E, Pritchard HW, Hong YP. 2013. Systematic overestimation of Salicaceae seed survival using radicle emergence in response to drying and storage: implications for ex situ seed banking. Acta Physiol Plant 35: 3015-3025. DOI: https://doi.org/10.1007/s11738-013-1334-6 [ Links ]

Pritchard HW, Nadarajan J. 2008. Cryopreservation of Orthodox (Desiccation Tolerant) Seeds. In: Reed BM. eds. Plant Cryopreservation: A Practical Guide. New York: Springer, pp. 485-501. DOI: https://doi.org/10.1007/978-0-387-72276-4_19 [ Links ]

R Core Team. 2018. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. https://www.R-project.org/ [ Links ]

Ranal MA, Santana DG. 2006. How and why to measure the germination process? Brazilian Journal of Botany 29: 1-11. DOI: https://doi.org/10.1590/S0100-84042006000100002 [ Links ]

Ranal MA, Santana DGD, Ferreira WR, Mendes-Rodrigues C. 2009. Calculating germination measurements and organizing spreadsheets. Brazilian Journal of Botany 32: 849-855. DOI: https://doi.org/10.1590/S0100-84042009000400022 [ Links ]

Ruiz-Corral JA, Medina-García G, García-Romero GE. 2018. Agroclimatic information system for Mexico-Central America. Revista Mexicana de Ciencias Agrícolas 9: 1-10. DOI: https://doi.org/10.29312/remexca.v9i1.843 [ Links ]

Scott S, Jones R, Williams W. 1984. Review of data analysis methods for seed germination. Crop Science 24: 1192-1199. DOI: https://doi.org/10.2135/cropsci1984.0011183X002400060043x [ Links ]

SEMARNAP. 2000. Programa de Manejo Área de Protección de Flora y Fauna La Primavera, México. México, DF: Secretaría del Medio Ambiente, Recursos Naturales y Pesca. [ Links ]

Siegel RS, Brock JH. 1990. Germination requirements of key southwestern woody riparian species. Desert Plants 10: 3-8. [ Links ]

Suszka J, Plitta BP, Michalak M, Bujarska-Borkowska B, Tylkowski T, Chmielarz P. 2014. Optimal seed water content and storage temperature for preservation of Populus nigra L. germplasm. Annals of Forest Science 71: 543-549. DOI: https://doi.org/10.1007/s13595-014-0368-2 [ Links ]

Tauer CG. 1979. Seed tree, vacuum, and temperature effects on eastern cottonwood seed viability during extended storage. Forest Science 25: 112-114. DOI: https://doi.org/10.1093/forestscience/25.1.112 [ Links ]

Vandelook F, Janssens SB, Probert RJ. 2012. Relative embryo length as an adaptation to habitat and life cycle in Apiaceae. New Phytologist 195: 479-487. DOI: https://doi.org/10.1111/j.1469-8137.2012.04172.x [ Links ]

Vázquez-García JA, Cuevas-Guzmán R. 1989. Una nueva especie tropical de Populus (Salicaceae) de la Sierra de Manantlán, Jalisco, México. Acta Botánica Mexicana 8: 39-45. DOI: https://doi.org/10.21829/abm8.1989.586 [ Links ]

Vázquez-García JA, Muñiz-Castro MA, Martínez-González RE, Nieves-Hernández G, Pulido-Ávila MG, Hernández-Vera G, Zuno-Delgadillo O. 2019. Populus primaveralepensis sp. nov. (Salicaceae, Malpighiales), a new species of white poplar from the Bosque La Primavera Biosphere Reserve in western Mexico. European Journal of Taxonomy 498: 1-16. DOI: https://doi.org/10.5852/ejt.2019.498 [ Links ]

Vázquez-García JA, Muñiz-Castro MA, Padilla-Lepe J, Pulido MG, Nieves G, Martínez RE. 2017. Populus luzae (Salicaceae), a new species of white poplar endemic to the western Transmexican Volcanic Belt, in Zapopan, Jalisco, Mexico. Phytotaxa 328: 243-256. DOI: https://doi.org/10.11646/phytotaxa.328.3.3 [ Links ]

Vázquez-Yanes C, Orozco-Segovia A. 1993. Patterns of seed longevity and germination in the tropical rainforest. Annual Review of Ecology and Systematics 24: 69-87. DOI: https://doi.org/10.1146/annurev.es.24.110193.000441 [ Links ]

Venable DL, Brown JS. 1988. The selective interaction of dispersal, dormancy, and seed size as adaptation for reducing risk in variable environments. The American Naturalist 131: 360-384. DOI: https://doi.org/10.1086/284795 [ Links ]

Wyckoff G, Zasada JC. Populus L. 2008. In: Bonner FT, Karrfalt RP, eds. The Woody Plant Seed Manual Agriculture Handbook 727, Washington DC. U.S; Department of Agriculture, Forest Service pp. 856-871. https://www.fs.usda.gov/treesearch/pubs/32626 (accessed May 18, 2019). [ Links ]

Zasada JC, Densmore RC. 1980. Alaskan willow and balsam poplar seed viability after 3 years storage. Tree Planters' Notes 31: 9-10. https://rngr.net/publications/tpn/31-2/31_2_9_10.pdf [ Links ]

Zasada JC, Viereck LA. 1975. The effect of temperature and stratification on germination in selected members of the Salicaceae in interior Alaska. Canadian Journal of Forest Research 5: 333-337. DOI: https://doi.org/10.1139/x75-045 [ Links ]

Received: December 14, 2020; Accepted: May 18, 2021; Published: November 09, 2021

^*Corresponding author: alejandro.munozu@academicos.udg.mx

Associate editor: Edilia de la Rosa

Author contributions: CJP: idea conception, field work, laboratory, analysis, and writing. MAMC: idea conception, project management, and field work. AVG: taxonomy, description of species and revision. JF: analysis in ecophysiological responses in germination. AMU: database compilation, statistical analysis, and writing. FMHM: statistical analysis, discussion, and revision.

This is an open-access article distributed under the terms of the Creative Commons Attribution License