<i>Agave angustifolia</i> bulbil growth in different substrates, with doses of fertigation and inoculation with <i>Azospirillum brasilense</i>

Jarquín-Rosales, Domitila; Valle, José Raymundo Enríquez-del; Alpuche-Osorno, Juan José; Rodríguez-Ortiz, Gerardo; Campos-Ángeles, Gisela Virginia; Morales, Isidro

doi:10.1590/0103-8478cr20210863

ABSTRACT:

There is little information about the production of agave plants in the nursery, so this research assessed the growth in the nursery of Agave angustifolia plants originating from inflorescence bulbils, subjected to different substrates, fertigation doses, and inoculation with Azospirillum brasilense. The bulbils were established for two months in a 50% peat-50% perlite substrate. One hundred and eighty plants were individually transferred to 3.8 dm³ pots for evaluation in an experiment with three factors: 1) type of irrigation: 1.1) water, or 1.2) fertigation with Steiner’s nutrient solution (NS), NS-50%, or 1.3) NS-100%; 2) inoculation with Azospirillum brasilense, 2.1) inoculated plants, 2.2) non-inoculated plants; 3) substrate, mixtures of bovine manure (BM) + sand (S) in different proportions, Mix1: 75% BM + 25% S; Mix2: 25% BM + 75% S; Mix3: 50% BM + 50% S. Morphological characteristics were quantified for one year. The largest plants were those that were in substrates with 50% BM, and were fertirrigated with NS-100% and inoculated with Azospirillum brasiliense. The smallest plants were those established a in a substrate with the lowest manure content, irrigated with only water and without inoculation, which was respectively 71.6 and 54.10 cm high, 21 and 15.6 leaves, 76.6 and 62.2 mm in stem diameter, 84.4 and 59.8 cm in rosette diameter.

Key words:
agave; Azospirillum brasilense; fertigation; growth; substrate mixtures

RESUMO:

Existem poucas informações sobre a produção de agave em viveiro, portanto o objetivo deste trabalho foi avaliar o crescimento em viveiro de Agave angustifolia provenientes de bulbilhos de inflorescência, submetidos a diferentes substratos, doses de fertirrigação e inoculação com Azospirillum brasilense. Os bulbilhos foram estabelecidos por dois meses em substrato 50% turfa-50% perlita. Cento e oitenta plantas foram transferidas individualmente para vasos de 3,8 dm3 para avaliação em um experimento com três fatores: 1) tipo de irrigação: 1.1) água ou 1.2) fertirrigação com solução nutritiva de Steiner (NS), NS-50% ou 1.3 ) NS-100%; 2) inoculação com Azospirillum brasilense, 2.1) plantas inoculadas, 2.2) plantas não inoculadas; 3) substrato, misturas de esterco bovino (BM) + areia (S) em diferentes proporções, Mix1: 75% BM + 25% S; Mix2: 25% BM + 75% S; Mix3: 50% BM + 50% S. As características morfológicas foram quantificadas por um ano. As maiores plantas foram aquelas que estavam em substrato com 50% de BM, foram fertirrigadas com NS-100% e inoculadas com Azospirillum brasiliense, enquanto as menores foram aquelas estabelecidas em substrato com menor quantidade de esterco, irrigado apenas com água e sem inoculação, que tinham respectivamente, 71,6 e 54,10 cm de altura, 21 e 15,6 folhas, 76,6 e 62,2 mm de diâmetro do caule, 84,4 e 59,8 cm de diâmetro de roseta.

Palavras-chave:
agave; Azospirillum brasilense; crescimento; fertirrigação; misturas de substratos

INTRODUCTION:

Agave angustifolia is a crassulaceous acid metabolism species adapted to shallow soils, slight or pronounced slopes, and arid and semiarid climates (NAVA-CRUZ et al., 2014NAVA-CRUZ, N. Y. et al. Agave biotechnology: an overview. Critical Review in Biotechnology, v.35, p.1-14, 2014. Available from: <Available from: https://pubmed.ncbi.nlm.nih.gov/25058832/ >. Accessed: Jan. 25, 2020. doi: 10.3109/07388551.2014.923813.
https://pubmed.ncbi.nlm.nih.gov/25058832... ). This species can reproduce asexually through rhizome shoots or bulbils from inflorescences. A plant can produce 6 to 8 rhizome shoots in its lifetime (MACOSSAY & CASTILLO, 1986MACOSSAY, V. M.; CASTILLO, M. E. Telchac pueblo: una comunidad henequenera. Universidad Autónoma Chapingo. Chapingo, México. Colección cuadernos Universitarios n.14, 1986. 178p. ). In the case of bulbils, it has been reported that an Agave angustifolia Haw. the plant produces 500 to 1,735 bulbils, highly heterogeneous in size, ranging from 1 to 15 cm. Although, the rhizome shoots are used more often to establish definitive Agave angustifolia plantations, bulbils selected by size categories have advantages: all the small plants have the same physiological age. Classified by size, plantations from bulbils are more uniform, and bulbils develop roots more rapidly than rhizome shoots (ENRÍQUEZ-DEL VALLE, 2008ENRÍQUEZ-DEL VALLE, J. R. La propagación y crecimiento de agaves. Fundación Produce Oaxaca, A.C. Instituto Tecnológico del Valle de Oaxaca, Oaxaca. México. 2008.46p.). In the state of Oaxaca, México, Agave angustifolia is highly important economically because it is a raw material for the production of mezcal and is widely cultivated in the districts of Sola de Vega, Miahuatlán, Yautepec, Ocotlán, Ejutla, Zimatlán and Tlacolula, which together are called the mezcal region. From 2006 to 2013, an average of 13, 572 ha were planted with agaves, of this area 70% was Agave angustifolia, at a rate of two thousand plants ha^-1. Considering that a crop requires seven to nine years to reach harvest, it is necessary to produce 2.6 million plants to replenish the harvest area every year (RÍOS-RAMÍREZ et al., 2017RÍOS-RAMÍREZ, S. C. et al. Benzylaminopurine and indol-3-acetic acid concentrations in in vitro proliferation of Agave angustifolia adventitious shoots. Ciencia e Investigación Agraria, v.44, n.3, p.285-294, 2017. Available from: <Available from: https://scielo.conicyt.cl/scielo.php?script=sci_abstract&pid=S0718-16202017000300285&lng=e&nrm=iso >. Accessed: Jan. 25, 2020. doi: 10.7764/rcia.v44i3.1810.
https://scielo.conicyt.cl/scielo.php?scr... ). Only eight nurseries are reported in the state. The most of plants established in plantations are propagated by the farmers themself, and specialized production of plants from rhizome shoots is incipient or non-existent. Although, the nursery is part of the agave-mezcal chain, this activity is scarce in the state (PALMA et al., 2016PALMA, F. et al. Diagnóstico de la Cadena de Valor Mezcal en las Regiones de Oaxaca. 83p. 2016. Available from: <Available from: http://www.coplade.oaxaca.gob.mx/wp-content/uploads/2017/04/Perfiles/AnexosPerfiles/6.%20CV%20MEZCAL.pdf >. Accessed: Jul. 31, 2020.
http://www.coplade.oaxaca.gob.mx/wp-cont... ). In the nursery, water and essential nutrients are necessary for optimal plant growth, currently, there are techniques such as fertigation that allow the efficient use of water and fertilizers, because it allows constant application in the necessary quantities in each stage of growing (CADAHIA, 2000CADAHIA, C. Fertirrigación. Ed. Mundi-Prensa Libros, S.A. España. 2000. 475p.; URRESTARAZU, 2004URRESTARAZU, G M. Tratado de cultivo sin suelo. Ed. Mundi-Prensa. Madrid, España . 2004. 914p. ; VALERA et al., 2014VALERA D. et al. Los invernaderos de Almería. Análisis de su tecnología y rentabilidad. Cajamar Caja Rural, Almería. 2014. Available from: <Available from: https://www.publicacionescajamar.es/publicacionescajamar/public/pdf/series-tematicas/economia/los-invernaderos-de-almeria-analisis.pdf >. Accessed: Feb. 03, 2021.
https://www.publicacionescajamar.es/publ... ). It has been reported that in nurseries nutrient supply to A. angustifolia, A. potatorum, and A. americana var. oaxacensis plants is an important factor, affecting growth in terms of both height and accumulation of biomass, leaf area, and number of extended leaves (ENRÍQUEZ-DEL VALLE et al., 2013ENRÍQUEZ-DEL VALLE, J. R. et al. Sustrato y dosis de fertirriego en la aclimatación de vitroplantas de Agave americana var. oaxacencis. Revista de la Facultad de Ciencias Agrarias, v.45, n.2, p.341-348, 2013. Available from: <Available from: https://www.redalyc.org/pdf/3828/382837655002.pdf >. Accessed: May. 10, 2020.
https://www.redalyc.org/pdf/3828/3828376... ; ENRÍQUEZ-DEL VALLE et al., 2016ENRÍQUEZ-DEL VALLE, J. R. et al. Fertigation in nursery plants of Agave potatorum Zucc micropropagated acclimatized. Revista Mexicana de Ciencias Agrícolas, v.7, n.5, 1167-1177, 2016. Available from: <Available from: http://www.scielo.org.mx/scielo.php?pid=S2007-09342016000501167&script=sci_arttext_plus&tlng=en >. Accessed: Jan. 25, 2020. doi: 10.29312/remexca. v7i5.240.
http://www.scielo.org.mx/scielo.php?pid=... ). The substrate is a very important factor in the production of seedlings (ABAD, 1995ABAD, B. M. Sustratos para el cultivo sin suelo. En Nuez F. (Ed.) El Cultivo del Tomate. Mundi-Prensa. Madrid, España. 1995. Cap.4, p.131-265.), they must have physical and chemical characteristics that allow greater water retention, nutrient absorption, root development; and consequently, have an effect on seedlings quality for transplanting (ABAD et al., 2004ABAD, B. et al. Los sustratos en el cultivo sin suelo. En: M. Urrestarazu G. Tratado de cultivo sin suelo. Ed. Mundi-Prensa. Madrid, España, 2004. Cap. 2. p.113-158.; ANSORENA, 1994ANSORENA, M. J. Sustratos. Propiedades y Caracterización. Mundi-Prensa. Madrid, España . 1994. 170p.; CADAHIA, 2000CADAHIA, C. Fertirrigación. Ed. Mundi-Prensa Libros, S.A. España. 2000. 475p.). Some organic materials such as bovine manure are used in substrates that provide some essential nutrients for plants (ÁLVAREZ-SÁNCHEZ et al., 2006ÁLVAREZ-SANCHEZ, J. et al. 2006. Efectividad biológica de abonos orgánicos en el crecimiento de trigo. Terra Latinoamericana, v.24, p.261-268, 2006. Available from: <Available from: https://www.redalyc.org/pdf/573/57311108013.pdf >. Accessed: Feb. 03, 2022.
https://www.redalyc.org/pdf/573/57311108... ; COSTA et al., 2015COSTA, E. et al. Substrate from vermiculite and cattle manure for ornamental pepper seedling production. Horticultura Brasileira, v.33, p.163-167, 2015. doi: 10.1590/S0102-053620150000200005.2015. Available from: <Available from: https://www.scielo.br/j/hb/a/NvcJrcP4Lynvq5mkJxxXmDB/abstract/?lang=en >. Accessed: Feb. 03, 2021. doi: 10.1590/S0102-053620150000200005.
https://www.scielo.br/j/hb/a/NvcJrcP4Lyn... ; SHAJI, et al., 2021SHAJI, H. et al. Organic fertilizers as a route to controlled release of nutrients. In Lewu, F. B. et al. Controlled Release Fertilizers for Sustainable Agriculture. Academic Press, 2021. Cap.13. p.231-245.). However, its use must be in combination with other materials that allow its structure to be improved by increasing permeability, cation exchange capacity, aggregate stability and decreasing bulk density (ABAD, 2004ABAD, B. et al. Los sustratos en el cultivo sin suelo. En: M. Urrestarazu G. Tratado de cultivo sin suelo. Ed. Mundi-Prensa. Madrid, España, 2004. Cap. 2. p.113-158.). Sand is an option to mix with bovine manure, which is a material that can be obtained easily and at low cost, for this reason it is feasible to use it to improve its characteristics. In micropropagated agave plants, it has been demonstrated that the type of substrate in the nursery acclimatization stage is important for good development of the plants (ENRÍQUEZ-DEL VALLE et al., 2009ENRÍQUEZ-DEL VALLE, J. R. et al. Agave angustifolia plants grown with different fertigation doses and organic substrates. Acta Horticulturae. v.843 p.49-55, 2009. Available from: <Available from: https://www.actahort.org/books/843/843_4.htm >. Accessed: May. 10, 2020. doi: 10.17660/ActaHortic.2009.843.4.
https://www.actahort.org/books/843/843_4... ; ENRÍQUEZ-DEL VALLE et al., 2018ENRÍQUEZ-DEL VALLE, J. R. et al. Crecimiento y condición nutrimental de plantas micropropagadas de Agave angustifolia abonadas y fertirrigadas en vivero. Revista Mexicana de Agroecosistemas, v.5, n.2, p.28-38, 2018. Available from: <Available from: https://www.voaxaca.tecnm.mx/revista/docs/RMAE%20vol%205_2_2018/4-RMAE-28-Agave.pdf >. Accessed: Jan. 20, 2020.
https://www.voaxaca.tecnm.mx/revista/doc... ). Like nutrient supply and substrate type, the microorganisms associated with the rhizosphere are an important factor for plant growth (ORTIZ-CASTRO, 2013ORTIZ-CASTRO, R.; LÓPEZ-BUCIO, J. Rapid identification of plant-growth-promoting rhizobacteria using an agar plate cocultivation system with Arabidopsis. In: Molecular Microbial Ecology of the Rhizosphere. Edit: Frans j. de Bruijn. Ed: Wiley Blacwell. p.345-353, 2013. Available from: <Available from: https://doi.org/10.1002/9781118297674.ch32 >. Accessed: Dec. 09, 2019. doi: 10.1002/9781118297674.ch32.
https://doi.org/10.1002/9781118297674.ch... ; ORTIZ-CASTRO & LÓPEZ-BUCIO, 2013ORTIZ-CASTRO, R. The beneficial role of rhizosphere microorganisms in plant health and productivity: Improving root development and nutrient acquisition. Acta Horticulturae, v.1009, p.241-250, 2013. Available from: <Available from: https://doi.org/10.17660/ActaHortic.2013.1009.29 >. Accessed: Mar. 25, 2020. doi: 10.17660 / Acta Hortic.2013.1009.29.
https://doi.org/10.17660/ActaHortic.2013... ). Conversely, there are microorganisms that are reported in the rhizosphere of plants and among them, there are some bacteria that provide beneficial effects for the plant, which are called Plant Growth Promoting Rhizobacteria (AHEMAD et al., 2014AHEMAD, M. Mechanisms and applications of plant growth promoting rhizobacteria: Current perspective. Journal of King Saud University Science, v.26, n.1, p.1-20, 2014. Available from: <Available from: https://www.sciencedirect.com/science/article/pii/S1018364713000293?via%3Dihub >. Accessed: Feb. 03, 2022. doi: 10.1016/j.jksus.2013.05.001.
https://www.sciencedirect.com/science/ar... ; MEHNAZ, 2015MEHNAZ, S.Azospirillum. a biofertilizer for every crop, In: Plant microbes symbiosis: Applied facets, Springer, New Delhi, 2015. Cap.15, p.297-314.; MA et al., 2018MA, M. et al. Isolation and identification of PGPR strain and its effect on soybean growth and soil bacterial community composition. International Journal of Agriculture and Biology, v.20, n.6, p.1289-1297, 2018. Available from: <Available from: https://orbi.uliege.be/handle/2268/225934 >. Accessed: Feb. 05, 2020. doi: 10.17957/IJAB/15.0627.
https://orbi.uliege.be/handle/2268/22593... ). The genera Pseudomonas, Bacillus, Azotobacter, and Azospirillum are some of the most studied rhizobacteria (MEHNAZ, 2015). The main mechanisms by which Azospirillum improves plant growth is by colonizing the roots, and producing phytohormones, mainly indole acetic acid, as well as nitrogen fixation (NGUYEN et al., 2019NGUYEN, M. et al. Biostimulant effects of rhizobacteria on wheat growth and nutrient uptake depend on nitrogen application and plant development. Archives of Agronomy and Soil Science, v.65, n.1 p.58-73, 2019. Available from: <Available from: https://www.tandfonline.com/doi/abs/10.1080/03650340.2018.1485074?journalCode=gags20 >. Accessed: Feb. 03, 2022. doi: 10.1080/03650340.2018.1485074.
https://www.tandfonline.com/doi/abs/10.1... ). There is research that demonstrated the benefits of this bacterium. Young bitter mesquite trees (Prosopis spp) 210 days after inoculation in the nursery with Azospirillum brasilense, developed 0.4 and 1.2 g root and shoots dry weight, and leaves had 400 µg more chlorophyll a, and 120 µg chlorophyll b g^-1 of fresh leaf weight, relative to non-inoculated trees, which had 0.2 and 0.9 g root and shoot dry weight, respectively (GONZALEZ et al., 2018GONZALEZ, E. J. et al. Dry micro-polymeric inoculant of Azospirillum brasilense is useful for producing mesquite transplants for reforestation of degraded arid zones. Applied Soil Ecology, v.129, p.84-93, 2018. Available from: <Available from: https://www.sciencedirect.com/science/article/abs/pii/S0929139318301823 >. Accessed: Feb. 12, 2020. doi: 10.1016/j.apsoil.2018.04.011.
https://www.sciencedirect.com/science/ar... ). Also, maize plants inoculated with this bacterium achieved greater length and total root volume, shoot dry matter, root dry matter, and total biomass, as well as a higher content of total soluble proteins than non-inoculated plants (ZEFFA et al., 2019ZEFFA, D. M. et al. Azospirillum brasilense promueve aumentos en el crecimiento y la eficiencia en el uso de nitrógeno de los genotipos de maíz. PLoS ONE, v.14, n.4, p.1-19, 2019. Available from: <Available from: https://doi.org/10.1371/journal.pone.0215332 >. Accessed: Jul. 15, 2020. doi: 10.1371/journal.pone.0215332.
https://doi.org/10.1371/journal.pone.021... ).

For these reasons, this research was to evaluate the growth of plants obtained from inflorescence bulbils, which under nursery conditions were subjected to various doses of fertigation, substrate and inoculation with Azospirillum brasilense.

MATERIALS AND METHODS:

Plant material

Bulbils from Agave angustifolia inflorescences were collected in November 2018 in the municipality of Zaachila (16° 96’01.196” N, 96° 75’79.45” W, 1,518 m altitude), Oaxaca, México. The bulbils were transported to the laboratory of the Instituto Tecnológico del Valle de Oaxaca (17^o 02’ N, 96^o 44’ W and altitude 1,530 m), in Santa Cruz Xoxocotlán.

Bulbil development

The bulbils were taken to the nursery and established in polystyrene foam trays 26.5 cm wide, 53 cm long and 6 cm high, divided into 50 conical cavities, which had an upper diameter of 4.5 cm, a lower diameter of 3 cm and a volume of 90 cm³. The substrate was a mixture of peat moss and perlite in a 1:1 proportion. The trays with bulbils were placed inside an 8 m wide, 12 m long and 3.3 m high metal structure with white translucid polyethylene cover. Prevailing temperatures were 9 °C at night and 26.6 °C during the day. Water-only irrigation was provided once every two days for two months.

Of the total number of plants, 180 of these exhibiting uniform size and no physical damage were selected. These were transplanted individually to high-density polyethylene pots 17 cm in diameter, 17 cm high, and 1,858.67 cm³, which contained one of three substrate mixtures (Mix) of bovine manure (BM) and sand (S) in different proportions: Mix1: 75% BM + 25% S, Mix2: 25% BM + 75% S, and Mix3: 50% BM + 50% S. Samples of each substrate were taken to analyze their physical and chemical characteristics. All the plants were placed inside a metal structure greenhouse with a white translucid polyethylene cover. A total of 60 plants in each type of substrate were separated into three groups for the application of different types of irrigation. Irrigation type 1) was potable water only, and types 2 and 3 were STEINER (1984STEINER, A. A. The universal nutrient solution, ISOSC (Proceedings). Sixth International Congress on Soilless Culture. Lunteren Wageningen. The Netherlands. 1984. p.633-650.) nutritive solution (NS) at different dilutions: 2) NS-50% and 3) NS-100%). Steiner nutritive solution at 100% contains (mg L^-1) 166.42 N, 30.68 P, 276.44 K, 182.34 Ca, 49.09 Mg, 111.15 S, 1.25 Fe, 0.21 Mn, 0.025 Zn, 0.076 B, 0.005 Cu and 0.021 Mo. Irrigation was applied once a week for one year. Each group of plants that received an irrigation type in each substrate was separated into two subgroups to evaluate the effect of the inoculations with Azospirillum brasilense bacteria: 1) non-inoculated plants and 2) plants inoculated monthly with 1,000,000 colony-forming units (CFU) per plant. The bacteria were obtained in the presentation MaxiFer^® from the company Biofabrica siglo XXI S.A. de C.V.

The experiment was established according to a completely randomized design with a 2×3×3 factorial arrangement of treatments, where the factor substrate had three levels, the factor irrigation type had three levels, and the factor inoculation with bacteria had two levels, making a total of 18 treatments with ten replicates. The experimental unit was one plant. At the beginning of the experiment and then every two months during the year, the following variables were measured in 10 plants of each treatment: the number of extended leaves, plant height (cm), rosette diameter (cm), length and width of the longest leaf (cm, with a metal Arly^® ruler), and stem diameter (mm, with a Titan^® digital vernier). With the data of each variable, at the beginning and end of the experiment, relative growth rates (RGR) were calculated in height (RGRH), the number of leaves (RGRNL), stem diameter (RGRSD), rosette diameter (RGRRD), length of the largest leaf (RGRLLL), and width of the largest leaf (RGRWLL), using the formula RGR = (Final size ˗ initial size) /365.

Destructive sampling

After 12 months, four plants per treatment were harvested. The leaves, stem without leaves (piña) and the roots of these plants were separated and weighed on an analytical scale (Shimadzu model AY224) with a 500 g capacity and precision of 0.1 mg. Root, piña, and leaf volumes (cm³) were determined by immersion in a test tube with a known volume of water. The leaf area was determined with an HP Scanjet 4890 scanner and the software ImageJ. The roots, piña, and leaves of each plant were placed separately in paper bags and dried at 70 °C for 72 h in a convection oven (Memmert^®, model 100-800). After drying, root, piña and leaves, dry weight was quantified on the analytical scale.

Statistical analyses

Variance homogeneity and normality of the data were verified with the Bartlett and Shapiro-Wilk tests, respectively. The data that did not comply with these assumptions were those of the length of the largest leaf, were transformed with an exponential and later subjected to an analysis of variance. For comparison of means (Tukey, 0.05), the data were used without transformation. In all cases for the statistical analysis, the Statistical Analysis System (SAS, 2004STATISTICAL ANALYSIS SYSTEM, (SAS). User’s guide. SAS/ETS® 9.1. SAS Institute Inc. Cary, NC. USA. 2004.) software was used.

RESULTS AND DISCUSSION:

At the beginning of the experiments, the plants had an average height of 12.31 cm, an average of 6.8 extended leaves, average stem diameter of 22.5 mm, and the largest leaf was on average 10.67 cm long and 2.26 cm wide. During the entire period of evaluation in all the treatments the plants had active growth, but at different relative growth rates by the effect of the conditions of the substrate, nutrient supply through irrigation, and inoculation. The amount of organic fertilizer incorporated into the substrate had a direct relationship with number of nutrients of the substrate (Table 1), this result agrees with SHAJI et al. (2021SHAJI, H. et al. Organic fertilizers as a route to controlled release of nutrients. In Lewu, F. B. et al. Controlled Release Fertilizers for Sustainable Agriculture. Academic Press, 2021. Cap.13. p.231-245.). The substrate with 75% bovine manure + 25% sand (Mix1) had a higher quantity of macro and micronutrients and greater electric conductivity (15 dS m^-1) than the substrate with less bovine manure (Mix2). The quantity of nutrients in the substrate had a direct relationship with the relative growth rates and the final plant size. The application of organic fertilizer increases the bacterial population of the soil that helps to mineralize the soil nutrients and facilitates their absorption by the plant, causing greater growth and yield of the plants (NGUYEN et al., 2019NGUYEN, M. et al. Biostimulant effects of rhizobacteria on wheat growth and nutrient uptake depend on nitrogen application and plant development. Archives of Agronomy and Soil Science, v.65, n.1 p.58-73, 2019. Available from: <Available from: https://www.tandfonline.com/doi/abs/10.1080/03650340.2018.1485074?journalCode=gags20 >. Accessed: Feb. 03, 2022. doi: 10.1080/03650340.2018.1485074.
https://www.tandfonline.com/doi/abs/10.1... ; SHAJI et al. 2021). The analyses of variance (Tables 2 and 3) showed that the levels of the factor irrigation type had significantly different effects (P ≤ 0.001) on height, number of leaves, rosette diameter, the width of the largest leaf, the relative growth rate in height (RGRH), relative growth rate of rosette diameter (RGRRD), leaf area, piña volume, leaf, and piña fresh weight and leaves dry weight. The additional growth of the plants due to the supply of nutrients in the irrigation is an indicator that the substrate did not provide enough nutrients for the plants to express their optimal growth.

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Table 1
Physiochemical characteristics of the substrate mixtures. Oaxaca Mexico, 2018/19.

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Table 2
Summary of 10 analyses of variance in size characteristics of A. angustifolia plants originating from bulbils that during 12 months in the nursery were established in different substrates, nutrient supply through irrigation and inoculation with A. brasilense. Oaxaca Mexico, 2018/19.

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Table 3
Summary of 10 analyses of variance of destructive sampling of A. angustifolia plants originating from bulbils that during 12 months in the nursery were established on different substrates, fertigation doses and inoculation with A. brasilense. Oaxaca Mexico, 2018/19.

The levels of the factor inoculation with A. brasilense had highly significantly different effects (P ≤ 0.001) on the number of leaves, width of the largest leaf, RGRH, RGRRD, and significant different effects (P ≤ 0.05) on the relative growth rate the of number of leaves (RGRNL), leaf area, leaves volume, piña volume, and root dry weight. These increases in the different evaluated variables are due to the benefits of A. brasilense such as the ability to fix nitrogen and the production of indoleacetic acid, which promote greater plant growth (NGYEN, et al., 2019).

The levels of factor substrate (Mix) had significant different effects (P ≤ 0.001) on height, rosette diameter, width of the largest leaf, RGRH, RGRRD, and significant different effects (P ≤ 0.05) on the variables number of leaves, stem diameter, length, and width of the largest leaf, RGRL, leaves volume, piña volume, leaves, and piña fresh weight, leaves and piña dry weight. These increases may be due to the differences in the physicochemical characteristics that the different mixtures of substrates had, due to the content of bovine manure that modified the nutritional content and electric conductivity of the different mixtures evaluated (Table 1). The interaction one (NSxAb) between the type of irrigation and inoculation with Azospirillum brasilense (Ab), had significant effects (P ≤ 0.05) on the variables number of leaves, stem diameter, RGRL, and root dry weight. The interaction two (NSxMix) between irrigation type and substrate type had highly significant effects (P ≤ 0.001) on plant height, rosette diameter, width of the largest leaf, RGRH and RGRRD, leaves, dry weight, leaf area, and leaf volume, and significant effect (P ≤ 0.05) on piña fresh weight, leaf dry weight, piña volume, RGRH, RGRSD, stem diameter and width of the largest leaf. The interaction three (AbxMix) between Ab and Mix only had significant effects (P ≤ 0.05) on leaf volume, piña volume, and piña fresh weight. Interaction four (NSxAbxMix) between irrigation type, Ab and Mix had highly significant effects (P ≤ 0.001) on RGRSD and significant effects (P ≤ 0.05) on RGRH, RGRL, leaf area, and leaf dry weight. The significant effects of the various interactions on some plant growth characteristics showed that, in addition to the significant different effects of the levels of a particular independent variable, it is possible that variations in the magnitude of the response occur due to changes in the levels of another independent variable.

When data were ordered in function of nutrient supply in the irrigation water, plant size was positively related to the amount of nutrients they received in the irrigation water, in such a way that the plants fertigated with NS-100 were larger than the plants that received only water (Figure 1). In each of these cases, the values were significantly different (Tukey, 0.05) (Tables 4, 5 and 6). ENRÍQUEZ-DEL VALLE et al. (2016ENRÍQUEZ-DEL VALLE, J. R. et al. Fertigation in nursery plants of Agave potatorum Zucc micropropagated acclimatized. Revista Mexicana de Ciencias Agrícolas, v.7, n.5, 1167-1177, 2016. Available from: <Available from: http://www.scielo.org.mx/scielo.php?pid=S2007-09342016000501167&script=sci_arttext_plus&tlng=en >. Accessed: Jan. 25, 2020. doi: 10.29312/remexca. v7i5.240.
http://www.scielo.org.mx/scielo.php?pid=... ) reported similar results with micropropagated-acclimatized Agave potatorum plants that, for five months in a nursery, received different doses of nutrient supply. The plants that received 100% Steiner solution had 1.73 times more dry weight, three times more leaf area, and 1.73 times more leaves than plants fertilized with 1% Steiner solution. In our study, the A. angustifolia plants fertigated with NS-100% Steiner formulation had a growth rate in height of 4.25 cm month^-1. These data coincide with those of ZÚÑIGA-ESTRADA et al. (2018ZÚÑIGA-ESTRADA, L. et al. Características y productividad de una planta MAC, Agave tequilana desarrollada con fertigación en Tamaulipas, México. Revista Mexicana de Ciencias Agrícolas, v.9, n.3, p.553-564, 2018. Available from: <Available from: https://cienciasagricolas.inifap.gob.mx/index.php/agricolas/article/view/1214 >. Accessed: Sep. 22, 2020. doi: 10.29312/remexca.v9i3.1214.
https://cienciasagricolas.inifap.gob.mx/... ), who reported that Agave tequilana plants showed more growth, in the field when they received deep fertilization and fertigation. At the end of 77 months, the plants reached a height of 153.3 cm and had a larger number of leaves, more dry matter, and total soluble solids than the control plants, which grew to 129 cm. YESCAS-ARREOLA et al. (2016YESCAS-ARREOLA, E. et al. Aclimatación de Agave americana var. Oaxacensis obtenidas in vitro. Revista Mexicana de Ciencias Agrícolas, v.7, n.4, p.911-922, 2016. Available from: <Available from: http://www.scielo.org.mx/pdf/remexca/v7n4/2007-0934-remexca-7-04-00911.pdf >. Accessed: Jan. 22, 2020.
http://www.scielo.org.mx/pdf/remexca/v7n... ) reported that Agave americana var oaxacensis nursery-grown plants that were fertigated with NS-100% developed a greater number of leaves and larger than other plants irrigated with only water.

Figure 1
Plant height of A. angustifolia plants that during 12 months in the nursery were established in different substrates, fertigation doses and inoculation with A. brasilense. Oaxaca Mexico, 2018/19. Mix1: 75% BM + 25% S, Mix2: 25% BM + 75% S, Mix3: 50% BM + 50% S.

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Table 4
Characteristics of A. angustifolia plants that during 12 months in the nursery were established in different substrates, fertigation doses and inoculation with A. brasilense. Oaxaca Mexico, 2018/19.

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Table 5
Growth characteristics of A. angustifolia plants that during 12 months in the nursery were established in different substrates, fertigation doses and inoculation with A. brasilense. Oaxaca Mexico, 2018/19.

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Table 6
Characteristics of the destructive sampling of A. angustifolia plants that during 12 months in the nursery were established in different substrates, fertigation doses and inoculation with A. brasilense. Oaxaca Mexico, 2018/19.

When the data were ordered in function of the factor inoculation with Azospirillum brasilense, the inoculated plants grew more than the non-inoculated plants. In most of the characteristics, a promoting effect, but only significant (Tukey, 0.05), of inoculation is observed on the formation of new leaves, the relative growth rate in height, and RGR of new leaves (Tables 4, 5, and 6). BUSTOS-BARRERA et al. (2017BUSTOS-BARRERA, E. et al. 2017 Estudio comparativo del cultivo de jitomate (Solanum lycopersicum L.) bajo diferentes esquemas de fertilización. Revista Mexicana de Ciencias Agrícolas, v.8, n.5, p.1195-1201, 2017. Available from: <Available from: http://www.scielo.org.mx/pdf/remexca/v8n5/2007-0934-remexca-8-05-1195.pdf >. Accessed: Apr. 12, 2020.
http://www.scielo.org.mx/pdf/remexca/v8n... ) reported that Solanum lycopersicum L. plants inoculated with bacteria of the genus Azospirillum produced 12 kg m^-2 of fruits, which was 67.3% higher than the yield of non-inoculated plants. Moreover, ZEFFA et al. (2019ZEFFA, D. M. et al. Azospirillum brasilense promueve aumentos en el crecimiento y la eficiencia en el uso de nitrógeno de los genotipos de maíz. PLoS ONE, v.14, n.4, p.1-19, 2019. Available from: <Available from: https://doi.org/10.1371/journal.pone.0215332 >. Accessed: Jul. 15, 2020. doi: 10.1371/journal.pone.0215332.
https://doi.org/10.1371/journal.pone.021... ) reported that maize plants inoculated with Azospirillum brasilense showed better root growth, higher concentration of total soluble proteins, more efficient nitrogen use, and higher yield than non-inoculated plants.

When the data were ordered in the function of levels of substrate mix, we observed that the amount of manure was an important condition that affected the magnitude of plant growth. The plants established in substrate with 50% sand and 50% bovine manure (Mix3) reached a larger size than plants established in the substrate with 25% BM and 75% sand (Mix2) (Figure 1B). The plants in the substrate with 50% manure tended to have significantly larger values in most of the characteristics (Tukey, 0.05): in leaf and piña volume, leaf fresh weight, piña fresh weight, leaf dry weight, piña dry weight (Tables 4, 5, and 6). Agave angustifolia plants grown from inflorescence bulbils, established for 12 months in a nursery with the mixture that contained 50% sand + 50% bovine manure, fertigated with NS-100%, and inoculated, were outstanding compared with plants that were established in substrate with 25% bovine manure and 75% sand, irrigated with water and non-inoculated (Table 7).

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Table 7
Characteristics of A. angustifolia plants that during 12 months in the nursery were established in different substrates, fertigation doses and inoculation with A. brasilense. Oaxaca Mexico, 2018/19.

Diverse studies have shown the importance of substrate characteristics. For example, Dutch-type cucumbers (Cucumis sativus L.) established in a mixture of coconut fiber + 20% commercial organic fertilizer were larger and yielded more fruits (15.57 kg m^-2) than plants grown in a substrate with 70% palm fiber + 30% sawdust, which produced 10.37 kg m^-2 (MENESES-FERNANDEZ et al., 2018MENESES-FERNÁNDEZ, C.; QUESADA-ROLDÁN, G. Crecimiento y rendimiento del pepino holandés en ambiente protegido y con sustratos orgánicos alternativos. Agronomia Mesoamericana, v.29, n.2, p.235-250, 2018. Available from: <Available from: https://doi.org/10.15517/ma.v29i2.28738 >. Accessed: Jan. 20, 2020. doi: 10.15517/ma.v29i2.28738.
https://doi.org/10.15517/ma.v29i2.28738... ). Also, Agave americana var. Oaxaquensis plants growing in the nursery and established in a substrate of 66% peat moss and 33.3% sand and fertigated with NS-100% grew to a larger size than plants in substrates with a higher proportion of sand (33.3% peat moss + 66.6% sand) and were not fertigated (CRUZ- GARCÍA et al., 2019CRUZ-GARCÍA, H. et al. Desarrollo de plantas micropropagadas de Agave americana var. Oaxacensis durante su aclimatización en invernadero. Revista Mexicana de Ciencias Agrícolas, v.10, n.7. p.1491-1503, 2019. Available from: <Available from: https://cienciasagricolas.inifap.gob.mx/editorial/index.php/agricolas/article/view/1625/2710 >. Accessed: Apr. 8, 2020.
https://cienciasagricolas.inifap.gob.mx/... ).

When analyzing the total combinations of factors and levels, the treatments with the highest amount of nutrients applied by fertigation (50 and 100%) had the highest values in the plant growth variables, compared to those that did not have application. of nutrient solution, water only (Tables 7 and 8). These data coincide with those of ZÚÑIGA-ESTRADA et al. (2018ZÚÑIGA-ESTRADA, L. et al. Características y productividad de una planta MAC, Agave tequilana desarrollada con fertigación en Tamaulipas, México. Revista Mexicana de Ciencias Agrícolas, v.9, n.3, p.553-564, 2018. Available from: <Available from: https://cienciasagricolas.inifap.gob.mx/index.php/agricolas/article/view/1214 >. Accessed: Sep. 22, 2020. doi: 10.29312/remexca.v9i3.1214.
https://cienciasagricolas.inifap.gob.mx/... ) carried in the cultivation of Agave tequilana Weber when applied different concentrations of nutrient solution. Results of the relative growth rates of the variables evaluated, had the same behavior, the values increased when the nutrient content applied by fertigation was higher, that is, plants that received fertigation at 100% nutrient concentration reached larger sizes compared to plants that were only irrigated with water (Table 7). In the case of the destructive variables, only the leaf area was the variable that did not have the same behavior of presenting a higher value according to the nutrient content in the applied nutrient solution (Table 8).

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Table 8
Characteristics of the destructive sampling of A. angustifolia plants that during 12 months in the nursery were established in different substrates, fertigation doses and inoculation with A. brasilense. Oaxaca Mexico, 2018/19.

CONCLUSION:

Agave angustifolia obtained from inflorescence bulbils and established in a substrate mixture of 50% bovine manure + 50% sand, where they were fertigated for 12 months with 100% Steiner solution and inoculated with Azospirillum brasilense monthly, had a higher relative growth rate, as well as twice the leaf area, root volume, leaf fresh weight, and root, leaf and piña dry weight than plants established in a substrate mixture of 25% bovine manure and 75% sand, irrigated with water and without inoculation.

ACKNOWLEDGEMENTS

To the Consejo Nacional de Ciencia y Tecnología (CONACYT-México) for the support provided, through a research grant. The research was funded by the Tecnológico Nacional de México (TecNM), with project 6617.18-P, entitled “Asexual propagation of two endemic species of Oaxaca”.

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CR-2021-0863.R1

Edited by

Editors: Leandro Souza da Silva(0000-0002-1636-6643) Alessandro Dal’Col Lúcio(0000-0003-0761-4200)

Publication Dates

Publication in this collection
24 June 2022
Date of issue
2023

History

Received
07 Dec 2021
Accepted
21 Mar 2022
Reviewed
05 June 2022

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

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Substrate	N	P	K	Ca	Mg	Fe	Zn
Substrate	------------------------------------------------------mg kg^-1---------------------------------------------------
Mix1: 75% BM + 25% S	1738.00	41.64	4119.60	6329.50	1983.20	1.81	3.24
Mix2: 25% BM + 75% S	960.50	11.85	559.90	1906.10	429.30	1.75	1.47
Mix3: 50% BM + 50% S	1360.50	34.60	1816.60	3756.90	1108.80	1.20	2.85
	Cu mg kg^-1	Mn mg kg^-1	R C/N	EC dS m^-1	pH	OM %	OC %
Mix1: 75% BM + 25% S	0.39	4.10	11.59	15.00	8.12	3.48	2.02
Mix2: 25% BM + 75% S	0.22	2.54	11.59	8.20	8.08	1.92	1.11
Mix3: 50% BM + 50% S	0.22	2.75	11.59	10.10	7.40	2.72	1.58

Sources of variation	DF	-------------------------------------------------------------------Mean squares-----------------------------------------------------------------------
Sources of variation	DF	Height	Number of leaves	Stem diameter	Rosette diameter	Length of the largest leaf
Type of irrigation	2	690.822^**	86.422^**	55.858^ns	395.297^**	8.162e55^ns
A. brasilense	1	86.632^ns	92.011^**	106.711^*	26.569^ns	2.184e55^ns
Mix	2	439.447^**	13.678^*	129.633^*	448.172^**	1.933e55^*
NSxAb	2	10.134^ns	11.344^*	153.286^*	36.342^ns	2.092e+55^ns
NSxMix	4	804.515^**	3.144^ns	114.667^*	667.629^**	8.087e+55^*
AbxMix	2	47.864^ns	4.678^ns	48.211^ns	26.101^ns	2.263e+55^ns
NSxAbxMix	4	154.420^ns	4.111^ns	254.161^**	56.687^ns	2.140e+55^ns
Error	162	14.209	2.078	19.061	22.340	2.896e+55
Total	179
Source of variation	DF	--------------------------------------------------------Mean squares (Relative growth rate)------------------------------------------------------
Source of variation	DF	Width of the largest leaf	Height	Number of leaves	Stem diameter	Rosette diameter
Type of irrigation	2	2.374^**	0.001522^**	0.00017^*	0.000055^ns	0.002177^**
A. brasilense	1	0.004^ns	0.001115^*	0.00082^**	0.000753^ns	0.000031^ns
Mix	2	0.570^*	0.001278^**	0.00013^*	0.001533^*	0.003291^**
NSxAb	2	0.052^ns	0.000120^ns	0.00009^*	0.002519^**	0.000059^ns
NSxMix	4	0.669^**	0.001318^**	0.00004^ns	0.000065^*	0.005149^**
AbxMix	2	0.097^ns	0.000176^ns	0.00002^ns	0.000038^ns	0.000354^ns
NSxAbxMix	4	0.087^ns	0.000509^*	0.00009^*	0.002409^**	0.000355^ns
Error	162	0.058	0.000113	0.00002	0.000201	0.0001947
Total	179

Source of variation	DF	--------------------------------------------------------Mean squares---------------------------------------------------------
Source of variation	DF	Leaf area	Root volume	Leaf volume	Piña volume	Root fresh weight
Type of irrigation	2	852078.24^**	566.17^ns	515923.64^*	1950.72^**	0.29^ns
A. brasilense	1	988541.26^*	1020.01^ns	377580.50^*	342.35^ns	2532.35^*
Mix	2	97331.02^ns	669.19^ns	224179.04^*	633.09^*	306.79^ns
NSxAb	2	99951.14^ns	2970.06^ns	40907.79^ns	137.06^ns	869.01^ns
NSxMix	4	936716.80^**	3024.58^ns	258698.10^**	468.70^*	470.15^ns
AbxMix	2	64576.75^ns	62.35^ns	1264497.38^*	1020.18^*	50.04^ns
NSxAbxMix	4	320254.98^*	3608.89^ns	73045.60^ns	274.33^ns	1702.12^ns
Error	123	76925.39	1339.21	37108.05	154.92	548.71
Total	143
Source of variation	DF	---------------------------------------------------------Mean squares--------------------------------------------------------
Source of variation	DF	Leaf fresh weight	Piña fresh weight	Root dry weight	Leaf dry weight	Piña dry weight
Type of irrigation	2	430946.06^**	1842.26^**	553.55^*	9303.30^**	77.06^ns
A.brasilense	1	368797.35^*	242.00^ns	815.07^*	1326.55^ns	87.21^ns
Mix	2	169705.43^*	1233.60^*	46.75^ns	2594.093^*	154.73^*
NSxAb	2	38080.39^ns	37.04^ns	489.85^*	569.14^ns	38.547^ns
NSxMix	4	210976.24^**	491.81^*	125.71^ns	2364.65^*	29.21^ns
AbxMix	2	70035.60^ns	534.13^*	115.14^ns	408.9^ns	43.93^ns
NSxAbxMix	4	70956.08^ns	143.92^ns	140.82^ns	1388.52^*	58.01^ns
Error	123	28045.87	159.88	108.35	400.29	28.31
Total	143

Factor	Height (cm)	Number of Leaves	Stem Diameter (mm)	Rosette Diameter (cm)	Length of largest leaf (cm)
------------------------------------------------------------------------Type of irrigation-------------------------------------------------------------------------
H₂O	57.72^c	16.33^c	63.35^b	65.45^b	50.50^b
NS-50	60.36^b	17.50^b	64.48a^b	67.95^b	52.31a
NS-100	64.46a	18.73^a	66.06^a	72.60^a	56.48^a
----------------------------------------------------------------------------Inoculation-----------------------------------------------------------------------------
Non-inoculated	59.86^b	16.51^b	63.54^b	69.21^a	52.55^b
Inoculated	61.83^a	18.53^a	65.72^a	68.12^a	54.98^a
-----------------------------------------------------------------------------Substrate------------------------------------------------------------------------------
Mix1: 75% BM + 25% S	59.33^b	18.07^a	65.80^a	67.11^b	51.38^b
Mix2: 25% BM + 75% S	59.23^b	16.77^b	62.23^b	65.82^b	52.91^b
Mix3: 50% BM + 50% S	63.97^a	17.73^a	65.87^a	73.06^a	56.98^a

Factor	Width of the largest leaf (cm)	-------------------------------------------Relative growth rate------------------------------------------
Factor	Width of the largest leaf (cm)	Height (cm day^-1)	Number of leaves (NL day^-1)	Stem diameter (mm day^-1)	Rosette diameter (cm day^-1)
---------------------------------------------------------------------------------------Type of irrigation-------------------------------------------------------------------------------------
H₂O	4.71^c	0.12^b	0.028^b	0.12^a	0.15^b
NS-50	4.95^b	0.13^a	0.031^a	0.12^a	0.16^b
NS-100	5.27^a	0.14^a	0.033^a	0.12^a	0.17^a
-------------------------------------------------------------------------------------------Inoculation-----------------------------------------------------------------------------------------
Non-inoculated	4.98^a	0.13^b	0.027^b	0.11^a	0.16^a
Inoculated	4.97^a	0.14^a	0.033^a	0.12^a	0.16^a
--------------------------------------------------------------------------------------------Substrate------------------------------------------------------------------------------------------
Mix1: 75% BM + 25% S	4.91^b	0.13^b	0.033^a	0.12^a	0.16^b
Mix2: 25% BM + 75% S	4.89^b	0.13^b	0.028^b	0.11^b	0.15^b
Mix3: 50% BM + 50% S	5.14^a	0.14^a	0.031^a	0.12^a	0.17^a

Brasil

Brasil

Agave angustifolia bulbil growth in different substrates, with doses of fertigation and inoculation with Azospirillum brasilense

Crescimento de bulbos de Agave angustifolia em diferentes substratos, com doses de fertirrigação e inoculação com Azospirillum brasilense

ABSTRACT:

RESUMO:

INTRODUCTION:

MATERIALS AND METHODS:

RESULTS AND DISCUSSION:

CONCLUSION:

ACKNOWLEDGEMENTS

REFERENCES

Edited by

Publication Dates

History

Factor	Leaf area (cm²)	-------------------------Volume (cm³)----------------------			Fresh Weight Root (g)
Factor	Leaf area (cm²)	Root	leaf	Piña
-----------------------------------------------------------------------Type of irrigation------------------------------------------------------------------------
H₂O	1750.6^b	85.3^a	891.7^b	46.0^b	68.3^a
NS-50	1965.8^a	81.9^a	1062^a	56.0^a	68.5^a
NS-100	2126.1^a	75.7^a	1183.5^a	64.0^a	68.5^b
----------------------------------------------------------------------------Inoculation---------------------------------------------------------------------------
Non-inoculated	1830.3^b	77.2^a	973.3^b	53.2^a	62.6^b
Inoculated	2064.7^a	84.7^a	1118.2^a	57.5^a	74.4^a
-----------------------------------------------------------------------------Substrate----------------------------------------------------------------------------
Mix1: 75% BM + 25% S	1967.3^a	81.3^a	1046.5^ab	55.0^ab	69.0^a
Mix2: 25% BM + 75% S	1876.3^a	86.0^a	948.8^b	50.4^b	71.7^a
Mix3: 50% BM + 50% S	1998.90^a	75.5^a	1142.0^a	60.7^a	64.7^a
Factor	--------------Fresh weight (g)------------			-------------------------Dry Weight (g)------------------------
Factor	Leaf	Piña	Root	Leaf	Piña
-----------------------------------------------------------------------Type of irrigation------------------------------------------------------------------------
H₂O	804.2^c	47.0^b	26.0^b	93.5^c	14.2^a
NS-50	949.6^b	57.3^a	26.8^b	108.9^b	14.7^a
NS-100	1071.9^a	64.4^a	34.7^a	132.6^a	17.5^a
----------------------------------------------------------------------------Inoculation---------------------------------------------------------------------------
Non-inoculated	870.3^b	54.4^a	25.8^b	107.4^a	14.3^a
Inoculated	1013.5^a	58.1^a	32.5^a	116.0^a	16.4^a
------------------------------------------------------------------------------Substrate---------------------------------------------------------------------------
Mix1: 75% BM + 25% S	938.6^ab	54.7^b	28.4^a	110.9^ab	14.7^ab
Mix2: 25% BM + 75% S	859.5^b	50.0^c	28.3^a	101.7^b	13.4^b
Mix3: 50% BM + 50% S	1027.6^a	64.0^a	30.8^a	122.5^a	18.3^a

T	Leaf área (cm²)	------------------------------------------Volume (cm³)---------------------------------			Fresh Weight Root (g)
T	Leaf área (cm²)	Root	leaf	Piña
1	2143.7^abcd	122.5^a	1005.0^bcd	42.5^cd	81.0^a
2	1717.9^bcde	117.5^a	825.0^d	45.0^bcd	85.3^a
3	1793.2^bcde	58.0^a	870.0^cd	41.0^d	61.8^a
4	2073.6^abcde	81.3^a	1100^abcd	52.5^abcd	66.0^a
5	1699.2^cde	72.5^a	772.5^d	45.0^bcd	68.8^a
6	1665.7^cde	75.0^a	885.0^cd	46.3^bcd	69.3^a
7	1533.9^de	55.0^a	810.0^d	52.3^abcd	46.0^a
8	1828.5^abcde	72.5^a	862.5^d	50.0^bcd	49.8^a
9	2219.1^abcd	85.0^a	1187.5^abcd	65.8^abcd	74.8^a
10	2510.4^ab	101.3^a	1362.5^abc	67.8^abcd	89.0^a
11	2106.1^abcd	112.5^a	1095.0^abcd	51.3^abcd	90.0^a
12	1895.4^abcde	65.00^a	1054.8^abcd	48.8^bcd	61.5^a
13	1278.6^e	43.00^a	762.5^d	45.0^bcd	39.8^a
14	1827.5^abcde	51.3^a	987.5^bcd	61.3^abcd	58.3^a
15	2454.3^abc	90.0^a	1450.0^ab	75.8^ab	66.3^a
16	1748.9^bcde	70.0^a	1131.3^abcd	73.8^abc	70.3^a
17	2128.3^abcd	90.0^a	1150.0^abcd	50.0^abcd	78.3^a
18	2604.4^a	95.0^a	1512.5^a	82.5^a	76.5^a
	-------------------Fresh weight (g)-----------------		--------------------------------------Dry Weight (g)-------------------------------------
	Leaf	Piña	Root	Leaf	Piña
1	919.5^bcd	42.8^c	27.7^ab	116.7^bcd	11.5^a
2	736.0^d	43.8^c	31.3^ab	87.6^cd	13.7^a
3	788.3^d	46.5^c	23.2^ab	103.8^bcd	12.4^a
4	967.5^bc	52.0^abc	27.7^ab	99.7^cd	13.0^a
5	705.3^d	43.3^c	22.4^ab	80.9^cd	13.6^a
6	817.0^cd	51.8^abc	24.0^ab	96.3^cd	21.4^a
7	711.8^d	53.0^abc	16.5^b	85.0^cd	13.2^a
8	799.5^cd	49.3^bc	21.6^ab	96.1^cd	12.6^a
9	1045.0^abcd	68.3^abc	31.2^ab	127.6^abcd	19.3^a
10	1225.0^abc	69.8^abc	38.2^ab	132.8^abc	18.2^a
11	980.3^bcd	51.5^abc	24.4^ab	107.3^bcd	11.9^a
12	936.3^bcd	52.3^abc	28.7^ab	104.8^bcd	12.8^a
13	680.0^d	48.3^bc	23.0^ab	80.0^d	11.9^a
14	880.3^bcd	58.0^abc	25.9^ab	115.0^bcd	14.8^a
15	1272.8^ab	79.8^ab	31.7^ab	154.8^ab	19.7^a
16	1019.8^abcd	64.0^abc	36.8^ab	127.4^abcd	19.9^a
17	1055.8^abcd	54.0^abc	44.3^a	123.4^abcd	13.6^a
18	1414.5^a	84.0^a	46.0^a	171.3^a	24.6^a

T	Height (cm)	Number of Leaves	Stem Diameter (mm)	Rosette Diameter (cm)	Length of largest leaf (cm)	width of the largest leaf (cm)
1	60.2^cde	17.0^cde	66.3^bcde	76.1^abc	51.3^bcde	4.9^bc
2	56.2^cde	15.4^e	59.6^ef	65.8^cdefg	49.3^cde	4.9^bc
3	55.6^de	15.2^e	61.0^def	64.9^cdefg	49.0^cde	4.8^bc
4	60.0^cde	18.0^abcd	68.8^abcd	67.4^cdrfg	52.9^bcde	4.7^bc
5	57.4^cde	15.8^e	60.6^def	61.9^g	51.4^bcde	4.7^bc
6	58.4^cde	16.2^de	62.0^cdef	61.6^g	52.0^bcde	4.6^bc
7	54.1^e	15.6^e	62.8^bcdef	59.8^g	46.1^e	4.6^c
8	58.8^cde	16.0d^e	63.2^bcdef	63.2^efg	52.0^bcde	5.0^bc
9	64.8^bc	17.8^abcd	71.6^abc	75.6^abce	59.0^ab	5.0^bc
10	63.3^bcd	20.0^abc	72.7^ab	67.8^cdefg	55.6^abcd	5.1^bc
11	57.9^cde	17.6^bcde	60.4^def	62.4^fg	52.3^bcde	4.7^bc
12	61.7^cde	18.4^abcd	57.0^f	73.8^abcde	58.0^ab	5.1^bc
13	56.2^cde	17.6^bcde	63.8^bcdef	61.0^g	46.9^de	5.0^bc
14	61.7^cde	16.6^de	59.4^ef	73.2^bcdef	55.6^abc	5.1^bc
15	71.2^ab	17.4^bcde	64.2^bcdef	83.2^ab	63.8^a	5.8^a
16	60.7^cde	20.6^ab	62.2^cdef	65.4^cdefg	52.7^bcde	5.1^bc
17	63.4^bcd	19.2^abcd	70.2^abcd	68.4^cdefg	56.9^abc	5.1^bc
18	73.61^a	21.0^a	76.6^a	84.4^a	63.0^a	5.7^a
----------------------------------------------------------------------------Relative growth rate-----------------------------------------------------------------------------
T	Height (cm day^-1)	Number of leaves (NL day^-1)	Stem Diameter (mm day^-1)	Rosette Diameter (cm day^-1)	Length of largest leaf (cm day^-1)	width of the largest leaf (cm day^-1)
1	0.13^bcde	0.03^bcde	0.13^abcd	0.18^abc	0.11^cdef	0.007^abc
2	0.12^de	0.02^de	0.10^de	0.15^bcdef	0.11^def	0.007^abc
3	0.12^de	0.02^e	0.11^bcde	0.15^bcdef	0.11^def	0.006^bc
4	0.13^cde	0.03^abcd	0.13^abcde	0.16^bcdef	0.11^bcdef	0.006^bc
5	0.13^cde	0.03^cde	0.11^cde	0.14^ef	0.11^bcdef	0.007^abc
6	0.13^cde	0.03^bcde	0.11^bcde	0.15^def	0.12^bcdef	0.007^abc
7	0.11^e	0.03^cde	0.12^bcde	0.13^f	0.10^f	0.006^c
8	0.13^bcde	0.03^cde	0.12^bcde	0.15^bcdef	0.12^abcde	0.008^abc
9	0.14^bcd	0.03^abcde	0.14^abcd	0.18^ab	0.13^abc	0.008^abc
10	0.14^abc	0.04^ab	0.14^ab	0.16^bcdef	0.13^abcd	0.008^abc
11	0.12^cde	0.03^abcd	0.10^de	0.15^def	0.12^bcdef	0.006^bc
12	0.14^bcde	0.03^abcd	0.10^de	0.18^abcd	0.13^abc	0.008^abc
13	0.12^e	0.03^abcde	0.11^bcde	0.14^ef	0.10^fe	0.007^abc
14	0.13^bcde	0.03^cde	0.10^e	0.17^abcd	0.12^abcde	0.008^abc
15	0.15^ab	0.03^bcde	0.10^de	0.20^a	0.14^ab	0.009^ab
16	0.13^bcde	0.04^abc	0.11^bcde	0.15^cdef	0.11^bcdef	0.007^abc
17	0.14^bcde	0.03^abcde	0.13^abcde	0.16^bcdef	0.13^abcd	0.008^abc
18	0.17^a	0.04^a	0.15^a	0.20^a	0.14^a	0.010^a