BIOFERTILIZERS AND BIOCONTROLLERS AS AN ALTERNATIVE TO THE USE OF CHEMICAL FERTILIZERS AND FUNGICIDES IN THE PROPAGATION OF YERBA MATE BY MINI-CUTTINGS

Gortari, Fermin; Nowosad, Maximo Ivan Petruk; Laczeski, Margarita Esther; Onetto, Andrea; Cortese, Iliana Julieta; Castrillo, Maria Lorena; Bich, Gustavo Angel; Alvarenga, Adriana Elizabeth; Lopez, Ana Clara; Villalba, Laura; Zapata, Pedro Dario; Rocha, Patricia; Niella, Fernando

doi:10.1590/1806-90882019000400012

ABSTRACT

The production of yerba mate seedlings through seeds has several limitations, which can be overcome by ex vitro vegetative propagation techniques such as the mini-cuttings, in which it is usually necessary to use synthetic chemical fertilizers and fungicides. However, there is a tendency towards sustainable agriculture, using biofertilizers (growth-promoting bacteria) and biocontrollers (Trichoderma sp.). Therefore, the objectives of this work were to evaluate the effect of biofertilizers on the production of mini-cuttings from yerba mate mini-stumps; as well as the effect, of biocontrollers on survival and rooting capacity of mini-cuttings. Strains of Bacillus sp. and Trichoderma asperelloides of yerba mate were used under two radiation conditions. There was a positive relationship between the availability of radiation and the production of mini-cuttings and the rooting capacity. All the mini-stumps sprouted regardless of treatments. The largest production of viable mini-cuttings occurred in a situation of high radiation and fertilization; while the treatments with growth-promoting bacteria and high radiation had intermediate values. The mini-cuttings inoculated with Trichoderma asperelloides had higher rooting percentage, greater number and length of roots than the mini-cuttings treated with fungicide. Therefore, we demonstrated that the use of chemical products can be replaced by biological ones and achieves acceptable yields.

Keywords:
Ilex paraguariensis; PGPR; Trichoderma

RESUMO

A produção de mudas de erva-mate através de sementes tem várias limitações, que podem ser superadas por técnicas de propagação vegetativa ex vitro, como miniestacas, nas quais geralmente é necessário o uso de fertilizantes químicos sintéticos e fungicidas. Portanto, há uma tendência para a agricultura sustentável, usando biofertilizantes (bactérias promotoras de crescimento) e biocontroladores (Trichoderma sp.). Portanto, os objetivos deste trabalho foram avaliar o efeito dos biofertilizantes na produção de miniestacas a partir de minicepas de erva-mate; bem como o efeito dos biocontroladores na sobrevivência e na capacidade de enraizamento de miniestacas. Bacillus sp. e Trichoderma asperelloides de erva-mate foram utilizados sob duas condições de radiação. Houve uma relação positiva entre a disponibilidade de radiação e a produção de miniestacas e a capacidade de enraizamento. Todos os minicepas brotaram independentemente dos tratamentos. A maior produção de miniestacas viáveis ocorreu em uma situação de alta radiação e fertilização; enquanto os tratamentos com bactérias promotoras de crescimento e alta radiação apresentaram valores intermediários. As miniestacas inoculadas com Trichoderma asperelloides apresentaram maior porcentagem de enraizamento, maior número e longitude de raízes que as miniestacas tratadas com fungicida. Portanto, provamos que o uso de produtos químicos pode ser substituído por produtos biológicos e esse fato atingem alcança rendimentos aceitáveis.

Palavras-Chave:
Ilex paraguariensis; PGPR; Trichoderma

1. INTRODUCTION

The Ilex genus (Aquifoliaceae) is distributed around the world, particularly in temperate, tropical and subtropical regions. One of the most important species, within the genus, is Ilex paraguariensis Saint Hilaire, known as yerba mate, typical of northeastern Argentina, southern Brazil and eastern Paraguay. This species constitutes one of the main crops in the province of Misiones, with approximately 165,327 hectares cultivated (INYM, 2016Instituto Nacional de La Yerba Mate - INYM. Superficie cultivada por departamento. 2016. Last access: 01/20/2020 Available: http://www.inym.org.ar/wp-content/uploads/2017/02/sup_cultivada_dpto.pdf.
http://www.inym.org.ar/wp-content/upload... ).

Although yerba mate plantations are abundant in the area, the generation of seedlings through seeds has several limitations, including the reduced germination and long periods of stratification (Wendling, 2004Wendling I. Propagação vegetativa de Erva-Mate (Ilex paraguariensis Saint Hilaire): estedo da arte e tendências futuras. 1.a edn. Colombo: Embrada Florestas; 2004.). Consequently, vegetative propagation, through mini-stumps and mini-cuttings, allows to overcome the limitations of sexual multiplication. Plant propagation using this technology was successfully developed for this species (Nauman et at., 2017Naumann M, Rocha P, Duarte E, Morales V, Niella F. Estudio de factores que afectan la capacidad de enraizmiento de miniestacas de Ilex paraguiariensis St. Hil. Revista Forestal Yvyrareta. 2017;25:15-20.; Stuepp et al., 2017Stuepp CA, Bitencourt J, Wendling I, Koehler HS, Zuffellato-Ribas KC. Age of stock plants, seasons and IBA effect on vegetative propagation of Ilex paraguariensis. Revista Árvore. 2017;41(2):1-7.; Sá et al., 2018Sá FP, Portes DC, Wendling I, Zuffellato-Ribas KC. Minicutting technique of yerba mate in four seasons of the year. Ciência Florestal. 2018;28(4):1431-1442.; Pimentel et al., 2019Pimentel N, Lencina KH, Kielse P, Rodrigues MB, Somavilla TM, Bisognin DA. Produtividade de minicepas e enraizamento de miniestacas de clones de erva-mate (Ilex paraguariensis A. St.-Hil.). Ciência Florestal. 2019;29(2):559-570.) and others, mainly Pinus sp. (Rocha and Niella, 2004Rocha P, Niella F. Efecto de tratamientos inductivos en el enraizamiento de estacas de Pinus elliottii x Caribaea y Pinus taeda. Revista Forestal Yvyrareta. 2004;12:50-54.; Niella et al., 2010Niella F, Rocha P, Pezzutti R, Schenone R. Manejo intesivo para la produccion de estacas en plantas madres de Pinus taeda y Pinus elliotti var. elliottii x Pinus caribaea var. hondurensis. Efecto del tamaño del contenedor e intensidad lumínica. Revista Forestal Yvyrareta. 2010;17:14-19.; Majada et al., 2011Majada J, Martínez-Alonso C, Feito I, Kidelman A, Aranda I, Alía R. Mini-cuttings: an effective technique for the propagation of Pinus pinaster Ait. New Forests. 2011;41(3):399-412.; Martínez-Alonso et al., 2012Martínez-Alonso C, Kidelman A, Feito I, Velasco T, Alía R, Gaspar MJ, et al. Optimization of seasonality and mother plant nutrition for vegetative propagation of Pinus pinaster Ait. New Forests. 2012;43(5-6):651-663.) and Eucalyptus sp. (Wendling et al., 2003Wendling I, Xavier A, Paiva HN. Influência da miniestaquia seriada no vigor de minicepas de clones de Eucalyptus grandis. Revista Árvore. 2003;27(5):611-618.; Assis and Mafia, 2007Assis TF, Mafia RG. Hibridação e clonagem. Viçosa: Suprema Gráfica e Editora; 2007.); in which agrochemicals are applied.

Nowadays, there is a tendency towards sustainable agriculture, avoiding the indiscriminate use of chemical products. In this sense, the use of biological products that enhance growth of crops in the area is one of the most promising alternatives (Alarcón and Ferrera-Cerrato, 2012Alarcón A, Ferrera-Cerrato R. Biofertilizantes: importancia y utilización en la agricultura. Revista Mexicana de Ciencias Agrícolas. 2012;26(2):191-203.). Biofertilizers and biocontrollers are products obtained from microorganisms found in the soil that can improve the physiological response of plants. In addition, it will contribute to microorganism biodiversity conservation, and a more stable production in the long term (Adesemoye et al., 2009Adesemoye AO, Torbert HA, Kloepper JW. Plant growth-promoting rhizobacteria allow reduced application rates of chemical fertilizers. Microbial Ecology. 2009;58(4):921-929.; Grageda-Cabrera et al., 2012Grageda-Cabrera OA, Díaz-Franco A, Peña-Cabriales JJ, Vera-Nuñez JA. Impacto de los biofertilizantes en la agricultura. Revista Mexicana de Ciencias Agrícolas. 2012;3(6):1261-1274.; Santos et al., 2012Santos VB, Araújo ASF, Leite LFC, Nunes LAPL, Melo WJ. Soil microbial biomass and organic matter fractions during transition from conventional to organic farming systems. Geoderma. 2012;170:227-231.).

Among these microorganisms are plant growth promoting bacteria (PGPR), which can stimulate the growth and development of agricultural crops due to their activity as biofertilizers (Çakmakçi and Tingir, 2001Çakmakçi R, Tingir N. The effect of growing period on growth, yield and quality of sugar beet. Erzurum Seker Fabrikasi. 2010;32:41-49.; Glick, 2012Glick BR. Plant Growth-Promoting Bacteria: mechanisms and applications. Scientifica. 2012:1-15.). In the rhizosphere and roots of yerba mate a wide diversity of bacteria has been found with the capacity to promote plant growth (Bergottini et al., 2015Bergottini VM, Otegui MB, Sosa DA, Zapata PD, Mulot M, Rebord M, et al. Bio-inoculation of yerba mate seedlings (Ilex paraguariensis St. Hill.) with native plant growth-promoting rhizobacteria: a sustainable alternative to improve crop yield. Biology and Fertility of Soils. 2015;51:749-755.; Bergottini et al., 2017Bergottini VM, Hervé V, Sosa DA, Otegui MB, Zapata PD, Junier P. Exploring the diversity of the root-associated microbiome of Ilex paraguariensis St. Hil. (Yerba Mate). Applied Soil Ecology. 2017;109:23-31.). On the other hand, among the most widely studied species, as biocontrollers, are those of the genus Trichoderma due to their efficiency, reproductive capacity, ecological plasticity, stimulating effect on crops and their action as inducer of systemic resistance to different pathogens (Vega, 2001Vega OF-L. Microorganismos antagonistas para el control fitosanitario. Manejo Integrado de Plagas. 2001;62:96-100.; Woo et al., 2014Woo SL, Ruocco M, Vinale F, Nigro M, Marra R, Lombardi N, et al. Trichoderma-based Products and their Widespread Use in Agriculture. The Open Mycology Journal. 2014;8:71-126.). They have antagonistic action against a wide range of phytopathogenic fungi, such as: Fusarium oxysporum, Fusarium roseum, Botrytis cinerea, Rhizoctonia solani, Sclerotium sp., Sclerotinia sp., Pythium sp., Phytophthora sp., Alternaria sp., among others (Montealegre et al., 2014Montealegre JR, Ochoa F, Besoain X, Herrera R, Pérez LM. In vitro and glasshouse biocontrol of Rhizoctonia solani with improved strains of Trichoderma spp. Ciencia e Investigación Agraria. 2014;41(2):197-206.; Woo et al., 2014Woo SL, Ruocco M, Vinale F, Nigro M, Marra R, Lombardi N, et al. Trichoderma-based Products and their Widespread Use in Agriculture. The Open Mycology Journal. 2014;8:71-126.). Although there are some examples of the use of PGPR bacteria (Teixeira et al., 2007Teixeira DA, Alfenas AC, Mafia RG, Ferreira EM, Siqueira L, Maffia LA, et al. Rhizobacterial promotion of eucalypt rooting and growth. Brazilian Journal of Microbiology. 2007;38(1):118-123.; Peralta et al., 2012Peralta KD, Araya T, Valenzuela S, Sossa K, Martínez M, Peña-Cortés H, et al. Production of phytohormones, siderophores and population fluctuation of two root-promoting rhizobacteria in Eucalyptus globulus cuttings. World Journal of Microbiology and Biotechnology. 2012;28(5):2003-2014.) and of Trichoderma sp. (Zaldúa and Sanfuentes, 2010Zaldúa S, Sanfuentes E. Control of Botrytis cinerea in Eucalyptus globulus Mini-Cuttings using Clonostachys and Trichoderma Strains. Chilean Journal Agricultural Research. 2010;70(4):576-582.), in the production of mini-cuttings for different Eucalyptus sp., there is no precedent for the use of these microorganisms in Ilex paraguariensis production.

The combination of modern vegetative propagation techniques associated with the application of biofertilizers and biocontrollers would allow us to obtain homogeneous plant material in a friendly environment. Therefore, the objectives of this work were to evaluate the effect of biofertilizers on the production of mini-cuttings from yerba mate mini-stumps; as well as the effect of biocontrollers on survival and rooting capacity of mini-cuttings.

2. MATERIALS AND METHODS

2.1. BIOFERTILIZER EFFECT ON SPROUT CAPACITY AND MINI-CUTTINGS PRODUCTION FROM YOUNG YERBA MATE MINI-STUMPS (EXPERIMENT 1).

This experiment was carried out with 6-month-old yerba mate seedlings, grown in 1-liter pots with composted pine bark substrate (110 g of substrate per pot). The mini-stumps production and growth was developed according to Rocha et al. (2019)Rocha P, Duarte E, Gortari F, Morales V, Niella F. Protocolo para la propagación por minicepas y miniestacas de yerba mate (Ilex paraguariensis A. St. Hil.) Revista Innovación y Desarrollo Tecnológico y Social. 2019;1(1):61-72.. The nutrient source treatments were applied two weeks after the detopping of the seedlings as follow: PGPR (inoculation with the selected combination of PGPR, 3 applications of 5 ml each, every 15 days of a suspension of 1.5x108 CFU / ml) and Fertilization (F, slow release fertilizer application to the substrate, Plantacote® Plus 6M, 3 kg / m³). A combination of native bacteria strains belonging to Bacillus genus with plant growth promoting capacity isolated from yerba mate roots from the Province of Misiones and available in the internal strain repository of the Misiones Biotechnology Institute (UNaM) were used. At the same time, two radiation conditions were evaluated: low radiation (L, 25% of photosynthetically active radiation (PAR)) and high radiation (H, 50% of PAR). The measurements of PAR were made with a Ceptometer (Cavadevices) during the day and several days during the experiment for a correct characterization inside the greenhouse, over the mini-stumps, and at the same time directly to the sun. Three measurements were made at 70-day intervals (September, December and February) after decapitation, where mini-cuttings were harvested. The variables measured were sprout capacity, shoots number and number of viable mini-cuttings (diameter greater than 2mm, 4 to 6 cm long and at least two internodes) per mini-stumps. Therefore, this experiment consists of three factors: Evaluation date (September, December or February), nutrient source (F or PGPR) and radiation (L or H).

2.2. EFFECT ON ROOTING CAPACITY OF MINI-CUTTINGS FROM YERBA MATE MINI-STUMPS (EXPERIMENTS 2.1 AND 2.2).

The rooting capacity assessment was carried out with mini-cuttings obtained from experiment 1, for the September (experiment 2.1) and February (experiment 2.2) harvests. The same treatments of experiment 1 were maintained (Nutrient source and Radiation). Though, in this case, fungal control factor with 2 levels were added. The first was the application of commercial fungicide (Z, Zineb) and the second was the inoculation with Trichoderma asperelloides IBM193 (T). This strain was isolated from roots of yerba mate plants in the Province of Misiones and is available in the internal strain repository of Misiones Biotechnology Institute (UNaM). This strain was selected given its biological control abilities. Three inoculations of IBM193 of 5 ml each were performed every 15 days, from a suspension of 1.5x106 spores / ml. Rooting was performed under controlled conditions of humidity and temperature in greenhouse with micro-irrigation. After 60 days of installation, the following variables were evaluated: survival and rooting percentage (alive mini-cuttings with roots of at least 5 mm in length); number of roots/mini-cuttings and maximum root length/mini-cuttings (mm). These experiments consisted of three factors: nutrient source (F or PGPR), radiation (L or H) and fungal control (T or Z).

2.3. STATISTICAL ANALYSIS.

The experiments were carried out in a completely randomized design, with a minimum of 10 replications per treatment, the experimental unit was the mini-stump or the mini-cutting. In experiment 1, ANOVA was performed considering evaluation date (September, December or February), nutrient source (F or PGPR) and radiation (L or H) as factors. Complete interactions between the three factors were analyzed. If any interaction was significant (more than two levels), means were compared by Tukey test (p< 0.05). In experiments 2.1 and 2.2, ANOVA was performed considering nutrient source (F or PGPR), radiation (L or H) and fungal control (T or Z) as factors. The same post hoc comparison of means was done, if the interaction was significant. Presumptions of independency, normality and variance homogeneity were proven for the variables (regrowth percentage, shoots number, viable mini-cuttings number, survival percentage, rooting percentage, roots number and roots maximum length).

3. RESULTS

Regardless of the treatments, all the mini-stumps sprouted (data non show). The number of shoots/mini-stumps, showed interaction between evaluation date and source of nutrients; September showed no significant differences between fertilizers or PGPR treatment, with 2.55 and 2.95 shoots/mini-stumps respectively. However, on the following dates, fertilizer treatment showed higher number of shoots, 3.95 shoots/mini-stumps for F and 3.25 shoots/mini-stumps for PGPR treatments in December; and 4.35 shoots/mini-stumps for F and 3.50 shoots/mini-stumps for PGPR treatments in February (Table 1, Figure 1.A). Interaction between evaluation date and radiation was observed; shoots production was always higher at high radiation intensities. However, differences in number of shoots/mini-stumps grown at high radiation and low radiation increased depending on the evaluation dates; the difference between low and high radiation treatments were 0.61, 0.67 and 1.69 in September, December and February respectively (Table 1, Figure 1.A).

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Table 1
ANOVA tests for shoots number and viable mini-cuttings number per mini-stump. Significant factors and interactions p-value are in bold letter (p≤0.05).
Tabela 1
Teste ANOVA para número de brotes e número de mini-estacas viável por mini-cepa. p-value significativos para fatores e interações estão em negrita (p≤0.05).

Figure 1
Shoots number (A) and viable mini-cuttings number (B) per mini-stump. Evaluation date (D): September (Sep), December (Dec) or February (Feb); Nutrient source (N): Fertilization (F) or (PGPR); Radiation (R): high radiation (H, 50% of PAR) or low radiation (L, 25% of PAR). Tukey test is included when interactions are significant, different letters indicate significant differences.
Figura 1
Número de brotes (A) e número de mini-estacas (B) por mini-cepa. data da avaliação (D): Setembro (Sep), Dezembro (Dec) ou Fevereiro (Feb); Fonte de nutrientes (N): Fertilização (F) ou PGPR; Radiação (R): alta radiação (H, 50% PAR) ou baixa radiação (L, 25% PAR). Teste Tukey é incluído quando as interações são significativas. Letras diferentes indicam diferenças significativas.

Viable mini-cuttings production/mini-stumps was modified by triple interaction (D, N and R). The lowest production of viable mini-cuttings/mini-stumps, both with low and high radiation, was observed in February with PGPR treatment, and in December with low radiation; not exceeding 2 viable mini-cuttings/ministumps. While the highest production was achieved, with fertilizer and high radiation treatments, in December and February, with 6 or more viable mini-cuttings/ mini-stumps. The rest of the treatments presented intermediate values between 3 and 4 viable mini-cuttings/mini-stumps (Table 1, Figure 1.B).

Mini-cuttings survival rate for experiment 2.1 varied depending on radiation and the type of fungal control. The higher the intensity of radiation in the mini-stumps, higher the survival rate, 70% and 50% for high and low radiation respectively; and higher survival rate in fungicide-treated mini-cuttings compared to inoculated ones, 72% and 47% respectively (Table 2, Figure 2.A). However, for experiment 2.2, mini-cuttings survival rate was only modified by intensity of radiation. Mini-cuttings obtained from mini-stumps growing with high radiation presented the highest values, more than 96% compared to 70% for low radiation. There were no interactions between factors for this variable in both experiments (Table 2, Figure 2.B).

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Table 2
ANOVA tests for survival percentage and rooting percentage for mini-cuttings in experiments 2.1 and 2.2. Significant factors and interactions p-value are in bold letter (p≤0.05).
Tabela 2
Teste ANOVA para porcentagem de sobrevivência e porcentagem de enraizamento para as mini-estacas nos experimentos 2.1 e 2.2. p-value significativos para fatores e interações estão em negrita (p≤0.05).

Figure 2
Survival percentage (%, A and B), rooting percentage (%, C and D), roots number (E and F) and roots length (mm, G and H) per mini-cutting in experiment 2.1 (September 2017; A, C, E y G) and experiment 2.2 (February 2018; B, D, F y H). Fertilization or inoculation (PGPR); high radiation (H, 50% of PAR) or low radiation (L, 25% of PAR); Zineb application (Z) or Trichoderma sp. inoculation (T).
Figura 2
Porcentagem de sobrevivência (%, A e B), porcentagem de enraizamento (%, C e D), número de raízes (E e F) e longitude de raízes (mm, G e H) por mini-cepa nos experimento 2.1 (Setembro 2017; A, C, E e G) e experimento 2.2 (Fevereiro 2018; B, D, F e H). Fertilização ou inoculação (PGPR); alta radiação (H, 50% PAR) ou baixa radiação (L, 25% PAR); aplicação zineb (Z) ou inoculação com Trichoderma sp. (T).

Rooting percentage for experiment 2.1 was not modified by any of the factors and there were no interactions between them (Table 2, Figure 2.C). However, in experiment 2.2 there was an effect of nutrient source and radiation. Mini-cuttings from mini-stumps inoculated with PGPR presented a value of 67% while for mini-cuttings obtained from fertilized mini-stumps was 41%. Regarding radiation, mini-cuttings from mini-stumps growing with high radiation had a value of 79%, while those from mini-stumps growing in low radiation were 30% (Table 2, Figure 2.D).

Roots number/mini-cutting variations, in experiment 2.1, were observed according to the fungal control method. Mini-cuttings inoculated with Trichoderma asperelloides IBM193 presented higher number of roots than those that received fungicide application, 7.8 and 4.7 respectively (Table 3, Figure 2.E). In experiment 2.2, roots number was modified by the conditions of the mini-stumps, source of nutrient and intensity of radiation. Mini-cuttings from mini-stumps growing with high radiation had greater roots number compared to mini-cuttings obtained from mini-stumps with low radiation, 3.9 and 2.0 respectively. Also, mini-cuttings from mini-stumps inoculated with PGPR had greater number of roots than those from fertilized mini-stumps, 3.9 and 2.0 respectively (Table 3, Figure 2.F). There were no interactions between factors for this variable in both experiments (Table 3).

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Table 3
ANOVA tests for roots number and roots length per mother plant. Significant factors and interactions p-value are in bold letter (p≤0.05).
Tabela 3
Teste ANOVA para número e longitude de raízes as mini-estacas nos experimentos 2.1 e 2.2. p-value significativos para fatores e interações estão em negrita (p≤0.05).

Maximum root length in experiment 2.1 was modified by intensity of radiation and by type of fungal control. Mini-cuttings inoculated with Trichoderma sp. presented a value of 1.9 mm while mini-cuttings with fungicide application approximately 1.0 mm (Table 3, Figure 2.G). In experiment 2.2 there was only effect of radiation intensity. Mini-cuttings from mini-stumps growing at greater intensity showed higher values of root length than those from lower radiation, 1.2 mm and 0.5 mm respectively (Table 3, Figure 2.H). There were no interactions between factors for this variable in both experiments (Table 3).

4. DISCUSSION

Yerba mate vegetative propagation is a technique that will help to mitigate problems regarding sexual propagation. Nevertheless, it is still necessary to adjust protocols for its application on a commercial scale, taking into account certain limitations such as environmental management and nutrition (Wendling et al., 2007Wendling I, Dutra LF, Grossi F. Produção e sobrevivência de miniestacas e minicepas de erva-mate cultivadas em sistema semi-hidropônico. Pesquisa Agropecuária Brasileira. 2007;42(2):289-292.). However, its technical viability has been demonstrated, with an average production of 291 mini-cuttings/m2 of garden, 95% survival of mini-stumps and 85% of mini-cuttings rooting capacity (Wendling et al., 2007Wendling I, Dutra LF, Grossi F. Produção e sobrevivência de miniestacas e minicepas de erva-mate cultivadas em sistema semi-hidropônico. Pesquisa Agropecuária Brasileira. 2007;42(2):289-292.). In our experiment, all yerba mate mini-stumps sprouted, in accordance with results observed for this species in similar systems in Brazil (Wendling et al., 2010Wendling I, Brondani GE, Dutra LF, Hansel FA. Mini-cuttings technique: a new ex vitro method for clonal propagation of sweetgum. New For. 2010;39(3):343-353.; Pimentel et al., 2019Pimentel N, Lencina KH, Kielse P, Rodrigues MB, Somavilla TM, Bisognin DA. Produtividade de minicepas e enraizamento de miniestacas de clones de erva-mate (Ilex paraguariensis A. St.-Hil.). Ciência Florestal. 2019;29(2):559-570.).

Production of viable mini-cuttings per I. paraguariensis mini-stumps varies depending on the mini-garden system adopted (Wendling et al., 2010Wendling I, Brondani GE, Dutra LF, Hansel FA. Mini-cuttings technique: a new ex vitro method for clonal propagation of sweetgum. New For. 2010;39(3):343-353.). For our system, viable mini-cuttings production varied depending on date of collection, source of nutrients and radiation level, with interaction between three factors. The highest production was observed in December and February for fertilization and high radiation treatments with more than 6 viable mini-cuttings/mini-stumps; while the lowest production was between 1-2 viable mini-cuttings for treatments inoculated with PGPR and low radiation (Table 1, Figure 1.B). The production values obtained for fertilization and high radiation treatments are similar to those obtained in Colombo (Brazil), although in that case there were 6 collections dates (Wendling et al., 2010Wendling I, Brondani GE, Dutra LF, Hansel FA. Mini-cuttings technique: a new ex vitro method for clonal propagation of sweetgum. New For. 2010;39(3):343-353.).

Fertilization affects production of mini-cuttings, greater nitrogen availability is associated with greater production (Martínez-Alonso et al., 2012Martínez-Alonso C, Kidelman A, Feito I, Velasco T, Alía R, Gaspar MJ, et al. Optimization of seasonality and mother plant nutrition for vegetative propagation of Pinus pinaster Ait. New Forests. 2012;43(5-6):651-663.). Although composted pine bark is widely used as substrate in forest nurseries in Misiones province, due to its abundance and low price, it is characterized by high cation exchange capacity and mainly low nitrogen concentration, making fertilization necessary (Jerez, 2007Jerez ZDPM. Comparación del sustrato de fibra de coco con los sustratos de corteza de pino compostada, perlita y vermiculita en la producción de plantas de Eucalyptus globulus (Labill). [monografia]. Valdivia (CHL): Faculdad de Ciencias Forestales - Universidad Austral de Chile; 2007.). The traditional way is the application of chemical fertilizers; however, use of PGPR bacteria is possible. One of the physiological mechanisms that might explain the positive interaction between PGPR and plants is the fact that microorganisms improve the nutritional status of plants. The nutrients directly involved, could be explained by nitrogen fixation, iron chelation by microorganism releasing substances that made it available to the roots (Pii et al., 2015Pii Y, Penn A, Terzano R, Crecchio C, Mimmo T, Cesco S. Plant-microorganism-soil interactions influence the Fe availability in the rhizosphere of cucumber plants. Plant Physiol Biochem. 2015;87:45-52.), and the release of organic acids that solubilize phosphorus (Know et al., 2011). However, the positive effect of PGPR may also be due to the release of auxins and other hormones (Ramos et al., 2003Ramos B, García JAL, Probanza A, Domenech J, Mañero FJG. Influence of an indigenous European alder (Alnus glutinosa (L.) Gaertn) rhizobacterium (Bacillus pumilus) on the growth of alder and its rhizosphere microbial community structure in two soils. New Forests. 2003;25:149-159.) that stimulate the proliferation of fine roots, and consequently the ability to absorb nutrients present in the soil (Domínguez-Nuñez et al., 2012Domínguez-Nuñez JA, Muñoz D, Planelles R, Grau JM, Artero F, Anriquez A, et al. Inoculation with Azospirillum brasilense enhances the quality of mesquite Prosopis juliflora seedlings. Forest Systems. 2012;21(3):364-372.). In experiment 1, inoculated mini-stumps produced low or intermediate values of viable mini-cuttings compared to chemical fertilization. The mechanisms previously described, in the present work, could only be related to nitrogen fixation and hormone production, due to the substrate (composted pine bark) used for the mini-stumps production.

The other factor analyzed in experiment 1 was the intensity of radiation received by mini-stumps. Yerba mate is a plant that grows under canopy in natural conditions (Eibl et al., 2000Eibl B, Fernandez RA, Kozarik JC, Lupi A, Montagnini F, Nozzi D. Agroforestry systems with Ilex paraguariensis (American holly or yerba mate) and native timber trees on small farms in Misiones, Argentina. Agroforestry Systems. 2000;48(1):1-8.), where intensity of radiation is regulated by the upper canopy. Therefore, under direct sunlight, the excess of radiation, being unable to dissipate it, causes photoinhibition of photosystem II and the consequent loss of growth and yield (Nishiyama and Murata, 2014Nishiyama Y, Murata N. Revised scheme for the mechanism of photoinhibition and its application to enhance the abiotic stress tolerance of the photosynthetic machinery. Applied Microbiology and Biotechnology. 2014;98(21):8777-8796 .). The greatest development of leaves and accumulation of biomass in yerba mate plants occurs when radiation is 50% of direct radiation, being less under full sun or very low radiation intensities (Sansberro et al., 2002Sansberro PA, Mroginski LA, Masciarelli OA, Bottini R. Shoot growth in Ilex paraguariensis plants grown under varying photosynthetically active radiation is affected through gibberellin levels. Plant Growth Regul. 2002;38(3):231-236.; Sansberro et al., 2004Sansberro PA, Mroginski LA, Bottini R. Foliar sprays with ABA promote growth of Ilex paraguariensis by alleviating diurnal water stress. Plant Growth Regulation. 2004;42(2):105-111.). Our results agree with this idea, the highest values of production of viable mini-cuttings were produced in high intensity radiation treatments, which in our case corresponded to 50% of direct solar radiation (Table 1, Figure 1.B).

At the same time, radiation intensity was also the main factor that influenced the performance of the mini-cuttings; higher survival rates, rooting percentages, roots number and roots length were achieved in high radiation treatments (Table 2 and 3, Figure 2). In Corylus avellanda mini-cuttings, survival and rooting are positively affected by availability of radiation, whereas higher the available radiation, greater the concentration of carbon reserves in stems (Tombesi et al., 2015Tombesi S, Palliotti A, Poni S, Farinelli D. Influence of light and shoot development stage on leaf photosynthesis and carbohydrate status during the adventitious root formation in cuttings of Corylus avellana L. Front Plant Sci. 2015;6:973.).

Optimal conditions for mini-cuttings growth are characterized by high relative humidity and high temperature (Zaldúa and Sanfuentes, 2010Zaldúa S, Sanfuentes E. Control of Botrytis cinerea in Eucalyptus globulus Mini-Cuttings using Clonostachys and Trichoderma Strains. Chilean Journal Agricultural Research. 2010;70(4):576-582.); conditions that also favor diseases development, making necessary to control or prevent such development. When we compared use of chemical fungicide and inoculation with Trichoderma asperelloides IBM193, differences in mini-cuttings survival were slightly higher in fungicide treatment in experiment 2.1. Meanwhile in experiment 2.2, there were no differences between treatments, only higher percentage of rooting was observed (Table 2, Figure 2). We do not strictly measure diseases incidence, but higher mini-cuttings survival could be related to a better phytosanitary status. On the other hand, inoculation of IBM193 strain has a positive effect on mini-cuttings rooting (number and length of roots). Inoculation of mini-cuttings of Eucalyptus globulus with strains of Trichoderma sp. and Clonostachys sp. reduced infection levels of Botritys cinerea and at the same time, increased rooting percentage (Zaldúa and Sanfuentes, 2010Zaldúa S, Sanfuentes E. Control of Botrytis cinerea in Eucalyptus globulus Mini-Cuttings using Clonostachys and Trichoderma Strains. Chilean Journal Agricultural Research. 2010;70(4):576-582.). In mini-cuttings of Passiflora edulis it was demonstrated that the application of Trichoderma sp. increased root production and that this increase was strongly influenced by the inoculation form (Pereira, 2012Pereira GVN. Promoção do crescimento de mudas de maracujazeiro inoculadas com Trichoderma spp. [dissertação]. Vitória da Conquista (BA): Universidade Estadual do Sudoeste da Bahia; 2012.). This radical stimulation is possibly due to the ability of Trichoderma sp. to produce auxins or their precursors (López-Bucio et al., 2015López-Bucio J, Pelagio-Flores R, Herrera-Estrella A. Trichoderma as biostimulant: exploiting the multilevel properties of a plant beneficial fungus. Scientia Horticulturae. 2015;196:109-123.). The application of PGPR could enhance rooting in addition to its proven capacity to stimulate plant growth, also associated with the production of auxins (Teixeira et al., 2007Teixeira DA, Alfenas AC, Mafia RG, Ferreira EM, Siqueira L, Maffia LA, et al. Rhizobacterial promotion of eucalypt rooting and growth. Brazilian Journal of Microbiology. 2007;38(1):118-123.).

5. CONCLUSIONS

We have studied yerba mate vegetative propagation by mini-stumps and mini-cuttings propagation system, under conditions of conventional use of fertilizers and fungicides; and under the paradigm of a more sustainable and environmentally friendly production, using biological products (PGPR and Trichoderma sp.); and two radiation conditions.

There is a positive relationship between availability of radiation and production of viable mini-cuttings as well as rooting capacity.

The highest production of viable mini-cuttings was achieved in fertilization treatments compared to inoculated with PGPR ones. However, treatments inoculated with PGPR give acceptable yields.

In the comparison of fungicide and inoculation with Trichoderma sp. treatments, there were no differences, or they were minimal. Differences on rooting percentage, roots number and roots length/mini-cutting were greater in inoculated plants.

Therefore, it is demonstrated that the use of chemical products can be replaced by biological ones and achieve acceptable yields.

6. REFERENCES

Adesemoye AO, Torbert HA, Kloepper JW. Plant growth-promoting rhizobacteria allow reduced application rates of chemical fertilizers. Microbial Ecology. 2009;58(4):921-929.
Alarcón A, Ferrera-Cerrato R. Biofertilizantes: importancia y utilización en la agricultura. Revista Mexicana de Ciencias Agrícolas. 2012;26(2):191-203.
Assis TF, Mafia RG. Hibridação e clonagem. Viçosa: Suprema Gráfica e Editora; 2007.
Bergottini VM, Hervé V, Sosa DA, Otegui MB, Zapata PD, Junier P. Exploring the diversity of the root-associated microbiome of Ilex paraguariensis St. Hil. (Yerba Mate). Applied Soil Ecology. 2017;109:23-31.
Bergottini VM, Otegui MB, Sosa DA, Zapata PD, Mulot M, Rebord M, et al. Bio-inoculation of yerba mate seedlings (Ilex paraguariensis St. Hill.) with native plant growth-promoting rhizobacteria: a sustainable alternative to improve crop yield. Biology and Fertility of Soils. 2015;51:749-755.
Çakmakçi R, Tingir N. The effect of growing period on growth, yield and quality of sugar beet. Erzurum Seker Fabrikasi. 2010;32:41-49.
Domínguez-Nuñez JA, Muñoz D, Planelles R, Grau JM, Artero F, Anriquez A, et al. Inoculation with Azospirillum brasilense enhances the quality of mesquite Prosopis juliflora seedlings. Forest Systems. 2012;21(3):364-372.
Eibl B, Fernandez RA, Kozarik JC, Lupi A, Montagnini F, Nozzi D. Agroforestry systems with Ilex paraguariensis (American holly or yerba mate) and native timber trees on small farms in Misiones, Argentina. Agroforestry Systems. 2000;48(1):1-8.
Glick BR. Plant Growth-Promoting Bacteria: mechanisms and applications. Scientifica. 2012:1-15.
Grageda-Cabrera OA, Díaz-Franco A, Peña-Cabriales JJ, Vera-Nuñez JA. Impacto de los biofertilizantes en la agricultura. Revista Mexicana de Ciencias Agrícolas. 2012;3(6):1261-1274.
Instituto Nacional de La Yerba Mate - INYM. Superficie cultivada por departamento. 2016. Last access: 01/20/2020 Available: http://www.inym.org.ar/wp-content/uploads/2017/02/sup_cultivada_dpto.pdf
» http://www.inym.org.ar/wp-content/uploads/2017/02/sup_cultivada_dpto.pdf
López-Bucio J, Pelagio-Flores R, Herrera-Estrella A. Trichoderma as biostimulant: exploiting the multilevel properties of a plant beneficial fungus. Scientia Horticulturae. 2015;196:109-123.
Majada J, Martínez-Alonso C, Feito I, Kidelman A, Aranda I, Alía R. Mini-cuttings: an effective technique for the propagation of Pinus pinaster Ait. New Forests. 2011;41(3):399-412.
Martínez-Alonso C, Kidelman A, Feito I, Velasco T, Alía R, Gaspar MJ, et al. Optimization of seasonality and mother plant nutrition for vegetative propagation of Pinus pinaster Ait. New Forests. 2012;43(5-6):651-663.
Montealegre JR, Ochoa F, Besoain X, Herrera R, Pérez LM. In vitro and glasshouse biocontrol of Rhizoctonia solani with improved strains of Trichoderma spp. Ciencia e Investigación Agraria. 2014;41(2):197-206.
Jerez ZDPM. Comparación del sustrato de fibra de coco con los sustratos de corteza de pino compostada, perlita y vermiculita en la producción de plantas de Eucalyptus globulus (Labill). [monografia]. Valdivia (CHL): Faculdad de Ciencias Forestales - Universidad Austral de Chile; 2007.
Naumann M, Rocha P, Duarte E, Morales V, Niella F. Estudio de factores que afectan la capacidad de enraizmiento de miniestacas de Ilex paraguiariensis St. Hil. Revista Forestal Yvyrareta. 2017;25:15-20.
Niella F, Rocha P, Pezzutti R, Schenone R. Manejo intesivo para la produccion de estacas en plantas madres de Pinus taeda y Pinus elliotti var. elliottii x Pinus caribaea var. hondurensis. Efecto del tamaño del contenedor e intensidad lumínica. Revista Forestal Yvyrareta. 2010;17:14-19.
Nishiyama Y, Murata N. Revised scheme for the mechanism of photoinhibition and its application to enhance the abiotic stress tolerance of the photosynthetic machinery. Applied Microbiology and Biotechnology. 2014;98(21):8777-8796 .
Pereira GVN. Promoção do crescimento de mudas de maracujazeiro inoculadas com Trichoderma spp. [dissertação]. Vitória da Conquista (BA): Universidade Estadual do Sudoeste da Bahia; 2012.
Peralta KD, Araya T, Valenzuela S, Sossa K, Martínez M, Peña-Cortés H, et al. Production of phytohormones, siderophores and population fluctuation of two root-promoting rhizobacteria in Eucalyptus globulus cuttings. World Journal of Microbiology and Biotechnology. 2012;28(5):2003-2014.
Pii Y, Penn A, Terzano R, Crecchio C, Mimmo T, Cesco S. Plant-microorganism-soil interactions influence the Fe availability in the rhizosphere of cucumber plants. Plant Physiol Biochem. 2015;87:45-52.
Pimentel N, Lencina KH, Kielse P, Rodrigues MB, Somavilla TM, Bisognin DA. Produtividade de minicepas e enraizamento de miniestacas de clones de erva-mate (Ilex paraguariensis A. St.-Hil.). Ciência Florestal. 2019;29(2):559-570.
Ramos B, García JAL, Probanza A, Domenech J, Mañero FJG. Influence of an indigenous European alder (Alnus glutinosa (L.) Gaertn) rhizobacterium (Bacillus pumilus) on the growth of alder and its rhizosphere microbial community structure in two soils. New Forests. 2003;25:149-159.
Rocha P, Niella F. Efecto de tratamientos inductivos en el enraizamiento de estacas de Pinus elliottii x Caribaea y Pinus taeda. Revista Forestal Yvyrareta. 2004;12:50-54.
Rocha P, Duarte E, Gortari F, Morales V, Niella F. Protocolo para la propagación por minicepas y miniestacas de yerba mate (Ilex paraguariensis A. St. Hil.) Revista Innovación y Desarrollo Tecnológico y Social. 2019;1(1):61-72.
Sá FP, Portes DC, Wendling I, Zuffellato-Ribas KC. Minicutting technique of yerba mate in four seasons of the year. Ciência Florestal. 2018;28(4):1431-1442.
Sansberro PA, Mroginski LA, Bottini R. Foliar sprays with ABA promote growth of Ilex paraguariensis by alleviating diurnal water stress. Plant Growth Regulation. 2004;42(2):105-111.
Sansberro PA, Mroginski LA, Masciarelli OA, Bottini R. Shoot growth in Ilex paraguariensis plants grown under varying photosynthetically active radiation is affected through gibberellin levels. Plant Growth Regul. 2002;38(3):231-236.
Santos VB, Araújo ASF, Leite LFC, Nunes LAPL, Melo WJ. Soil microbial biomass and organic matter fractions during transition from conventional to organic farming systems. Geoderma. 2012;170:227-231.
Stuepp CA, Bitencourt J, Wendling I, Koehler HS, Zuffellato-Ribas KC. Age of stock plants, seasons and IBA effect on vegetative propagation of Ilex paraguariensis. Revista Árvore. 2017;41(2):1-7.
Teixeira DA, Alfenas AC, Mafia RG, Ferreira EM, Siqueira L, Maffia LA, et al. Rhizobacterial promotion of eucalypt rooting and growth. Brazilian Journal of Microbiology. 2007;38(1):118-123.
Tombesi S, Palliotti A, Poni S, Farinelli D. Influence of light and shoot development stage on leaf photosynthesis and carbohydrate status during the adventitious root formation in cuttings of Corylus avellana L. Front Plant Sci. 2015;6:973.
Vega OF-L. Microorganismos antagonistas para el control fitosanitario. Manejo Integrado de Plagas. 2001;62:96-100.
Wendling I. Propagação vegetativa de Erva-Mate (Ilex paraguariensis Saint Hilaire): estedo da arte e tendências futuras. 1.a edn. Colombo: Embrada Florestas; 2004.
Wendling I, Dutra LF, Grossi F. Produção e sobrevivência de miniestacas e minicepas de erva-mate cultivadas em sistema semi-hidropônico. Pesquisa Agropecuária Brasileira. 2007;42(2):289-292.
Wendling I, Brondani GE, Dutra LF, Hansel FA. Mini-cuttings technique: a new ex vitro method for clonal propagation of sweetgum. New For. 2010;39(3):343-353.
Wendling I, Xavier A, Paiva HN. Influência da miniestaquia seriada no vigor de minicepas de clones de Eucalyptus grandis. Revista Árvore. 2003;27(5):611-618.
Woo SL, Ruocco M, Vinale F, Nigro M, Marra R, Lombardi N, et al. Trichoderma-based Products and their Widespread Use in Agriculture. The Open Mycology Journal. 2014;8:71-126.
Zaldúa S, Sanfuentes E. Control of Botrytis cinerea in Eucalyptus globulus Mini-Cuttings using Clonostachys and Trichoderma Strains. Chilean Journal Agricultural Research. 2010;70(4):576-582.

Publication Dates

Publication in this collection
21 Feb 2020
Date of issue
2019

History

Received
02 Apr 2019
Accepted
30 Aug 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Adesemoye AO, Torbert HA, Kloepper JW. Plant growth-promoting rhizobacteria allow reduced application rates of chemical fertilizers. Microbial Ecology. 2009;58(4):921-929.

[2] Alarcón A, Ferrera-Cerrato R. Biofertilizantes: importancia y utilización en la agricultura. Revista Mexicana de Ciencias Agrícolas. 2012;26(2):191-203.

[3] Assis TF, Mafia RG. Hibridação e clonagem. Viçosa: Suprema Gráfica e Editora; 2007.

[4] Bergottini VM, Hervé V, Sosa DA, Otegui MB, Zapata PD, Junier P. Exploring the diversity of the root-associated microbiome of Ilex paraguariensis St. Hil. (Yerba Mate). Applied Soil Ecology. 2017;109:23-31.

[5] Bergottini VM, Otegui MB, Sosa DA, Zapata PD, Mulot M, Rebord M, et al. Bio-inoculation of yerba mate seedlings (Ilex paraguariensis St. Hill.) with native plant growth-promoting rhizobacteria: a sustainable alternative to improve crop yield. Biology and Fertility of Soils. 2015;51:749-755.

[6] Çakmakçi R, Tingir N. The effect of growing period on growth, yield and quality of sugar beet. Erzurum Seker Fabrikasi. 2010;32:41-49.

[7] Domínguez-Nuñez JA, Muñoz D, Planelles R, Grau JM, Artero F, Anriquez A, et al. Inoculation with Azospirillum brasilense enhances the quality of mesquite Prosopis juliflora seedlings. Forest Systems. 2012;21(3):364-372.

[8] Eibl B, Fernandez RA, Kozarik JC, Lupi A, Montagnini F, Nozzi D. Agroforestry systems with Ilex paraguariensis (American holly or yerba mate) and native timber trees on small farms in Misiones, Argentina. Agroforestry Systems. 2000;48(1):1-8.

[9] Glick BR. Plant Growth-Promoting Bacteria: mechanisms and applications. Scientifica. 2012:1-15.

[10] Grageda-Cabrera OA, Díaz-Franco A, Peña-Cabriales JJ, Vera-Nuñez JA. Impacto de los biofertilizantes en la agricultura. Revista Mexicana de Ciencias Agrícolas. 2012;3(6):1261-1274.

[11] Instituto Nacional de La Yerba Mate - INYM. Superficie cultivada por departamento. 2016. Last access: 01/20/2020 Available: http://www.inym.org.ar/wp-content/uploads/2017/02/sup_cultivada_dpto.pdf
» http://www.inym.org.ar/wp-content/uploads/2017/02/sup_cultivada_dpto.pdf

[12] López-Bucio J, Pelagio-Flores R, Herrera-Estrella A. Trichoderma as biostimulant: exploiting the multilevel properties of a plant beneficial fungus. Scientia Horticulturae. 2015;196:109-123.

[13] Majada J, Martínez-Alonso C, Feito I, Kidelman A, Aranda I, Alía R. Mini-cuttings: an effective technique for the propagation of Pinus pinaster Ait. New Forests. 2011;41(3):399-412.

[14] Martínez-Alonso C, Kidelman A, Feito I, Velasco T, Alía R, Gaspar MJ, et al. Optimization of seasonality and mother plant nutrition for vegetative propagation of Pinus pinaster Ait. New Forests. 2012;43(5-6):651-663.

[15] Montealegre JR, Ochoa F, Besoain X, Herrera R, Pérez LM. In vitro and glasshouse biocontrol of Rhizoctonia solani with improved strains of Trichoderma spp. Ciencia e Investigación Agraria. 2014;41(2):197-206.

[16] Jerez ZDPM. Comparación del sustrato de fibra de coco con los sustratos de corteza de pino compostada, perlita y vermiculita en la producción de plantas de Eucalyptus globulus (Labill). [monografia]. Valdivia (CHL): Faculdad de Ciencias Forestales - Universidad Austral de Chile; 2007.

[17] Naumann M, Rocha P, Duarte E, Morales V, Niella F. Estudio de factores que afectan la capacidad de enraizmiento de miniestacas de Ilex paraguiariensis St. Hil. Revista Forestal Yvyrareta. 2017;25:15-20.

[18] Niella F, Rocha P, Pezzutti R, Schenone R. Manejo intesivo para la produccion de estacas en plantas madres de Pinus taeda y Pinus elliotti var. elliottii x Pinus caribaea var. hondurensis. Efecto del tamaño del contenedor e intensidad lumínica. Revista Forestal Yvyrareta. 2010;17:14-19.

[19] Nishiyama Y, Murata N. Revised scheme for the mechanism of photoinhibition and its application to enhance the abiotic stress tolerance of the photosynthetic machinery. Applied Microbiology and Biotechnology. 2014;98(21):8777-8796 .

[20] Pereira GVN. Promoção do crescimento de mudas de maracujazeiro inoculadas com Trichoderma spp. [dissertação]. Vitória da Conquista (BA): Universidade Estadual do Sudoeste da Bahia; 2012.

[21] Peralta KD, Araya T, Valenzuela S, Sossa K, Martínez M, Peña-Cortés H, et al. Production of phytohormones, siderophores and population fluctuation of two root-promoting rhizobacteria in Eucalyptus globulus cuttings. World Journal of Microbiology and Biotechnology. 2012;28(5):2003-2014.

[22] Pii Y, Penn A, Terzano R, Crecchio C, Mimmo T, Cesco S. Plant-microorganism-soil interactions influence the Fe availability in the rhizosphere of cucumber plants. Plant Physiol Biochem. 2015;87:45-52.

[23] Pimentel N, Lencina KH, Kielse P, Rodrigues MB, Somavilla TM, Bisognin DA. Produtividade de minicepas e enraizamento de miniestacas de clones de erva-mate (Ilex paraguariensis A. St.-Hil.). Ciência Florestal. 2019;29(2):559-570.

[24] Ramos B, García JAL, Probanza A, Domenech J, Mañero FJG. Influence of an indigenous European alder (Alnus glutinosa (L.) Gaertn) rhizobacterium (Bacillus pumilus) on the growth of alder and its rhizosphere microbial community structure in two soils. New Forests. 2003;25:149-159.

[25] Rocha P, Niella F. Efecto de tratamientos inductivos en el enraizamiento de estacas de Pinus elliottii x Caribaea y Pinus taeda. Revista Forestal Yvyrareta. 2004;12:50-54.

[26] Rocha P, Duarte E, Gortari F, Morales V, Niella F. Protocolo para la propagación por minicepas y miniestacas de yerba mate (Ilex paraguariensis A. St. Hil.) Revista Innovación y Desarrollo Tecnológico y Social. 2019;1(1):61-72.

[27] Sá FP, Portes DC, Wendling I, Zuffellato-Ribas KC. Minicutting technique of yerba mate in four seasons of the year. Ciência Florestal. 2018;28(4):1431-1442.

[28] Sansberro PA, Mroginski LA, Bottini R. Foliar sprays with ABA promote growth of Ilex paraguariensis by alleviating diurnal water stress. Plant Growth Regulation. 2004;42(2):105-111.

[29] Sansberro PA, Mroginski LA, Masciarelli OA, Bottini R. Shoot growth in Ilex paraguariensis plants grown under varying photosynthetically active radiation is affected through gibberellin levels. Plant Growth Regul. 2002;38(3):231-236.

[30] Santos VB, Araújo ASF, Leite LFC, Nunes LAPL, Melo WJ. Soil microbial biomass and organic matter fractions during transition from conventional to organic farming systems. Geoderma. 2012;170:227-231.

[31] Stuepp CA, Bitencourt J, Wendling I, Koehler HS, Zuffellato-Ribas KC. Age of stock plants, seasons and IBA effect on vegetative propagation of Ilex paraguariensis. Revista Árvore. 2017;41(2):1-7.

[32] Teixeira DA, Alfenas AC, Mafia RG, Ferreira EM, Siqueira L, Maffia LA, et al. Rhizobacterial promotion of eucalypt rooting and growth. Brazilian Journal of Microbiology. 2007;38(1):118-123.

[33] Tombesi S, Palliotti A, Poni S, Farinelli D. Influence of light and shoot development stage on leaf photosynthesis and carbohydrate status during the adventitious root formation in cuttings of Corylus avellana L. Front Plant Sci. 2015;6:973.

[34] Vega OF-L. Microorganismos antagonistas para el control fitosanitario. Manejo Integrado de Plagas. 2001;62:96-100.

[35] Wendling I. Propagação vegetativa de Erva-Mate (Ilex paraguariensis Saint Hilaire): estedo da arte e tendências futuras. 1.a edn. Colombo: Embrada Florestas; 2004.

[36] Wendling I, Dutra LF, Grossi F. Produção e sobrevivência de miniestacas e minicepas de erva-mate cultivadas em sistema semi-hidropônico. Pesquisa Agropecuária Brasileira. 2007;42(2):289-292.

[37] Wendling I, Brondani GE, Dutra LF, Hansel FA. Mini-cuttings technique: a new ex vitro method for clonal propagation of sweetgum. New For. 2010;39(3):343-353.

[38] Wendling I, Xavier A, Paiva HN. Influência da miniestaquia seriada no vigor de minicepas de clones de Eucalyptus grandis. Revista Árvore. 2003;27(5):611-618.

[39] Woo SL, Ruocco M, Vinale F, Nigro M, Marra R, Lombardi N, et al. Trichoderma-based Products and their Widespread Use in Agriculture. The Open Mycology Journal. 2014;8:71-126.

[40] Zaldúa S, Sanfuentes E. Control of Botrytis cinerea in Eucalyptus globulus Mini-Cuttings using Clonostachys and Trichoderma Strains. Chilean Journal Agricultural Research. 2010;70(4):576-582.

	ANOVA test for shoots number per mini-stump
	SS	D. of Freedom	MS	F	p
Intercept	2473,01	1	2473,01	1902,16	≤0,01
Nutrient source (N)	7,10	1	7,10	5,46	0,02
Radiation (R)	50,02	1	50,02	38,47	≤0,01
Evaluation Date (D)	51,52	2	25,76	19,81	≤0,01
N x R	0,14	1	0,14	0,10	0,74
N x D	14,67	2	7,33	5,64	≤0,01
R x D	13,16	2	6,58	5,06	≤0,01
N x R x D	7,78	2	3,89	2,99	0,06
Error	266,52	205	1,30
	ANOVA test for viable mini-cuttings number per mini-stump
	SS	D. of Freedom	MS	F	p
Intercept	2590.01	1	2590.01	828.62	≤0.01
Nutrient source (N)	185.41	1	185.41	59.31	≤0.01
Radiation (R)	84.21	1	84.21	26.94	≤0.01
Evaluation Date (D)	107.01	2	53.50	17.11	≤0.01
N x R	86.45	1	86.45	27.66	≤0.01
N x D	47.45	2	23.72	7.59	≤0.01
R x D	1.52	2	0.75	0.24	0.78
N x R x D	56.93	2	28.46	9.10	≤0.01
Error	637.63	204	3.12

ANOVA test for survival percentage in experiment 2.1
	SS	D. of Freedom	MS	F	p
Intercept	36.86	1	36.86	170.91	≤0.01
Nutrient source (N)	0.15	1	0.15	0.73	0.39
Radiation (R)	1.06	1	1.06	4.94	0.02
Fungal control (C)	1.65	1	1.65	7.67	≤0.01
N x R	0.13	1	0.13	0.60	0.43
N x C	0.75	1	0.75	3.50	0.06
R x C	0.60	1	0.60	2.81	0.09
N x R x C	0.82	1	0.82	3.80	0.06
Error	22.85	106	0.21
ANOVA test for survival percentage in experiment 2.2
	SS	D. of Freedom	MS	F	p
Intercept	72.34	1	72.34	537.67	≤0.01
Nutrient source (N)	0.52	1	0.52	3.89	0.06
Radiation (R)	3.96	1	3.96	29.45	≤0.01
Fungal control (C)	0.29	1	0.29	2.19	0.14
N x R	0.13	1	0.13	0.97	0.32
N x C	0.13	1	0.13	0.97	0.32
R x C	0.29	1	0.29	2.20	0.14
N x R x C	0.14	1	0.14	0.97	0.33
Error	14.80	110	0.13
ANOVA test for rooting percentage in experiment 2.1
	SS	D. of Freedom	MS	F	p
Intercept	10.40	1	10.40	49.20	≤0.01
Nutrient source (N)	0.20	1	0.20	0.97	0.32
Radiation (R)	0.69	1	0.69	3.28	0.07
Fungal control (C)	0.70	1	0.69	3.29	0.07
N x R	0.65	1	0.65	3.14	0.08
N x C	0.01	1	0.01	0.01	0.90
R x C	0.10	1	0.10	0.50	0.47
N x R x C	0.03	1	0.03	0.18	0.66
Error	22.41	106	0.21
ANOVA test for rooting percentage in experiment 2.2
	SS	D. of Freedom	MS	F	p
Intercept	35.43	1	35.43	203.24	≤0.01
Nutrient source (N)	2.04	1	2.04	11.70	≤0.01
Radiation (R)	7.26	1	7.26	41.66	≤0.01
Fungal control (C)	0.12	1	0.12	0.72	0.39
N x R	0.14	1	0.14	0.84	0.36
N x C	0.03	1	0.03	0.17	0.67
R x C	0.53	1	0.53	3.05	0.80
N x R x C	0.03	1	0.03	0.20	0.65
Error	19.17	110	0.17

ANOVA test for roots number in experiment 2.1
	SS	D. of Freedom	MS	F	p
Intercept	1562.76	1	1562.76	93.76	≤0.01
Nutrient source (N)	38.08	1	38.08	2.28	0.13
Radiation (R)	26.28	1	26.28	1.57	0.21
Fungal control (C)	83.60	1	83.60	5.01	0.03
N x R	0.15	1	0.15	0.01	0.92
N x C	13.16	1	13.16	0.78	0.37
R x C	3.17	1	3.17	0.19	0.66
N x R x C	48.64	1	48.64	2.91	0.10
Error	683.36	73	9.36
ANOVA test for roots number in experiment 2.2
	SS	D. of Freedom	MS	F	p
Intercept	739.58	1	739.58	80.77	≤0.01
Nutrient source (N)	78.77	1	78.77	8.54	≤0.01
Radiation (R)	77.29	1	77.29	8.44	≤0.01
Fungal control (C)	27.52	1	27.52	3.01	0.08
N x R	13.37	1	13.37	1.46	0.23
N x C	4.28	1	4.28	0.46	0.49
R x C	13.14	1	13.14	1.43	0.23
N x R x C	7.38	1	7.38	0.80	0.37
Error	769.08	84	9.15
ANOVA test for roots length in experiment 2.1
	SS	D. of Freedom	MS	F	p
Intercept	67.30	1	67.30	73.39	≤0.01
Nutrient source (N)	1.09	1	1.09	1.18	0.27
Radiation (R)	5.63	1	5.63	6.14	≤0.01
Fungal control (C)	7.36	1	7.36	8.02	≤0.01
N x R	1.04	1	1.04	1.13	0.29
N x C	0.01	1	0.01	0.01	0.90
R x C	0.60	1	0.60	0.66	0.41
N x R x C	1.02	1	1.02	1.12	0.29
Error	66.95	73	0.91
ANOVA test for roots length in experiment 2.2
	SS	D. of Freedom	MS	F	p
Intercept	52.63	1	52.63	80.33	≤0.01
Nutrient source (N)	2.53	1	2.53	3.86	0.52
Radiation (R)	11.52	1	11.52	17.56	≤0.01
Fungal control (C)	0.70	1	0.70	1.07	0.30
N x R	0.02	1	0.02	0.01	0.95
N x C	0.20	1	0.20	0.31	0.57
R x C	0.06	1	0.06	0.09	0.76
N x R x C	0.53	1	0.53	0.81	0.37
Error	55.04	84	0.65

Brasil

Brasil

BIOFERTILIZERS AND BIOCONTROLLERS AS AN ALTERNATIVE TO THE USE OF CHEMICAL FERTILIZERS AND FUNGICIDES IN THE PROPAGATION OF YERBA MATE BY MINI-CUTTINGS

BIOFERTILIZANTES E BIOCONTROLADORES COMO ALTERNATIVA AO USO DE FERTILIZANTES E FUNGICIDAS QUÍMICOS NA PROPAGAÇÃO DO ERVA-MATE POR MINIESTACAS

ABSTRACT

RESUMO

1. INTRODUCTION

2. MATERIALS AND METHODS

2.1. BIOFERTILIZER EFFECT ON SPROUT CAPACITY AND MINI-CUTTINGS PRODUCTION FROM YOUNG YERBA MATE MINI-STUMPS (EXPERIMENT 1).

2.2. EFFECT ON ROOTING CAPACITY OF MINI-CUTTINGS FROM YERBA MATE MINI-STUMPS (EXPERIMENTS 2.1 AND 2.2).

2.3. STATISTICAL ANALYSIS.

3. RESULTS

4. DISCUSSION

5. CONCLUSIONS

6. REFERENCES

Publication Dates

History