Lucas Ricardo Petigrosso scite author profile

Lotus tenuis forage yield has been quantified under defoliation conditions in pastures, grasslands and under dual-purpose production of both livestock forage and seeds. However, little is known about the effects of defoliation management on L. tenuis flower and pod production and subsequent seed yield. Two field experiments were conducted to study the response of L. tenuis to defoliation at different flowering stages and intensities. In Experiment 1, crops were defoliated at the beginning of the flowering (DBF), mid-flowering (DMF) or full flowering (DFF). In Experiment 2, defoliation was in vegetative stage at low (LDI) or high (HDI) intensities. Defoliation in Experiment 1 neither affected plant cover nor the photosynthetically active radiation intercepted by the crop during pod production. There were less umbels with dehiscent (shattered) pods in the DFF treatment than in Control, DBF and DMF treatments. Flower peak occurred first in the Control, DBF and DMF treatments, and eight days later in DFF plots, however, seed yield was not affected (1324 ± 32.8 kg·ha −1 ). Defoliation intensity did not affect seed yield (962 ± 25.9 kg•ha − 1 ) because of self-compensation which increased harvest index in HDI (14.5% ± 0.6%) compared to the Control and LDI (12.0% ± 0.3%) treatments. Plant survival was not affected by defoliation treatments in any of the experiments. Flowering can be synchronized through defoliation. The blooming of large numbers of flowers in a short time was achieved, reducing the number of shattered pods. Compensatory responses through plant plasticity conferred L. tenuis the ability to overcome defoliation without affecting seed yield. Lotus tenuis defoliation as management tool will be considered in future researches because it is possible to harvest forage and to increase seed yield through a reduction of shattered pods. O. R. Vignolio et al.

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EFFECTS OF TEMPERATURE, PHOTOPERIOD AND DEFOLIATION ON FLOWERING TIME OF LOTUS TENUIS (FABACEAE) IN BUENOS AIRES, ARGENTINA

Vignolio

Petigrosso

Rodríguez

et al. 2017

Ex. Agric.

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SUMMARYThe phenological development of crops from emergence to flowering time is largely controlled by temperature and photoperiod. Flowering time is a critical phenological stage for subsequent reproductive phase. Lotus tenuis management in grasslands, pastures and seed production systems is through defoliation and sowing date; however, yet little is known about their effects on flowering time. The data presented in this study were obtained from experiments conducted with L. tenuis during the years 1989 to 2016 under field conditions. Our objectives were to determine if flowering time (a) is affected by sowing date; (b) can be predicted through equations using temperature and photoperiod and (c) is affected by defoliation applied at vegetative stage. Two defoliation intensities were applied, low (LDI) crop height reduced by 54% compared to pre-defoliation crop height and high (HDI), crop height reduced by 75%. The rate of progress from seedling emergence to flowering time (inverse of time from emergence to first flowering, 1/f) was modulated by temperature, photoperiod and photothermal functions. When L. tenuis sowing was delayed from autumn to spring, time from seedling emergence to first flowering decreased from 260 to 100 days. 1/f was linearly related to average temperature (R²=0.75) and photoperiod (R²=0.85) and both variables (R²=0.92). Defoliation retarded flowering time. Flower and pod growth periods were shorter under defoliation than in control one. Defoliation did not cause abortion of flowers and pods. Flower production was fitted to quadratic function of photoperiod. Flowering peak was approximately within 15.2 h. The prediction of flowering time using thermal, photoperiod and photothermal models can provide information about crop management decisions, such as optimal environmental regimes for crop growth through sowing date.

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Eradication of the fungus Epichloë coenophiala from Schedonorus arundinaceus (tall fescue) seeds by interrupting the vertical transmission process

et al. 2019

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Tall fescue is usually infected by a fungal endophyte, responsible of livestock intoxication due to fungal alkaloids. An endophyte fungus grows in the apoplast of aboveground tissues and is vertically transmitted through the seeds. Disinfecting plants or clones not only is useful as a way of eliminating a dangerous microorganism from cultivars, but also for experimental purposes. However, not all fungicides are effective, and if they are, a waiting period must be respected in order to avoid confounding effects of the endophyte and the treatment. We subjected plants (ramets from four genotypes) to different doses of two fungicides, Almagor ® (Triazole + Imidazole) and Amistar ® (Methoxy-acrylate), and evaluated the endophyte persistence. Fungicides were pipette-poured on pseudostems' bases of each plant. Endophytic status was diagnosed in tillers that received the fungicide and in the new tillers produced by the plants and seeds. While Amistar ® had no detectable effect, Almagor ® was 100% effective at all doses. The latter interrupted the verticaltransmission processes (5400 evaluated seeds were endophyte-free). Phytotoxic effects were not observed in seeds. Proportion of normal and abnormal seedlings depended only on plant genotype. Almagor ® was effective in stopping the fungus from growing into reproductive buds when apical meristems were down on the bases. Use of Almagor ® is promising on old pastures dominated by toxic tall fescue, with the purpose of enriching the soil seed-bank with endophyte-free seeds.

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Interacción de plantas y concentración de ergovalina en la mezcla de Lotus tenuis y Schedonorus arundinaceus infectada con el hongo Epichloë coenophiala

et al. 2020

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A��. Schedonorus arundinaceus (tall fescue) population can be infected by the endophyte fungus Epichloë coenophiala, responsible of livestock intoxication due to fungal alkaloids (i.e., ergovaline). The effects of ergovaline in pastures can be a�enuated through dilution; this is, to interseed infected tall fescue (E+) with legumes, endophyte-free grass, or with both. Plant interaction and ergovaline concentration in mixture of tall fescue (E+) and Lotus tenuis, a forage legume, were investigated in replacement series experiments under defoliation conditions. The interaction between species was analysed through relative yield total (RYT) of the forage biomass, aggressivity index (AI), plant cover and ergovaline concentration. The work was performed in field conditions. Six cu�ings were applied during the experimental period. Plant monocultures of each species were at a constant density of 80 pl/m 2 , while mixtures ratios were 20:60, 40:40 and 60:20 pl/m² of L. tenuis and tall fescue, respectively. Mortality of L. tenuis and tall fescue plants was not observed. Tall fescues yield and plant cover, in monoculture and in mixture, were higher than in L. tenuis. RYT was higher than 1 for all mixtures. According to AI, in mixture, tall fescue was the dominant species and overcompensated the lower yield of L. tenuis. At the early Autumn, ergovaline concentration in monoculture was 1.637±0.594 ng/g, and in the 40:40 mixture was 0.407±0.109 ng/g. Forage production was higher in mixtures than in monocultures, and L. tenuis contributed to reduce ergovaline concentration. According to the results, 40:40 pl/m 2 of tall fescue and L. tenuis was the best species combination. A positive effect of L. tenuis on growth of tall fescue mediated by nitrogen availability could have allowed the plant coexistence. Future experiments should analyse the variation of alkaloid concentration and forage production in tall fescue pastures, according to L. tenuis proportion, defoliation frequency and intensity under different seasons.

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Respuesta deSchedonorus arundinaceuslibre e infectada con endófito y de otrocultivar libre de endófito en pasturas puras y en mezcla con leguminosas bajodos frecuencias de defoliación

Petigrosso

Irastorza

Vignolio

et al. 2021

ALPA

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Los objetivos del presente trabajo fueron comparar el efecto de dos frecuencias de defoliación sobre laproducción de biomasa aérea de a) pasturas puras deSchedonorus arundinaceus(festuca alta) infectadas con endófitosilvestreEpichloë coenophialaproveniente de semilla de plantas aleatoriamente seleccionadas de un pastizal natural(FNE+) o de un cultivar comercial libre de endófito (FCE) (Experimento 1), b) pasturas mezcla de FCE y FNE+ conleguminosas (Lotus tenuisyTrifoliumrepens) (Experimento 2); y c) evaluar la producción de biomasa subterránea defestucaaltaenpasturas puras ymezclas sometidas ados frecuencias de defoliación. Se llevaronacabodosexperimentos a campo. El diseño experimental utilizado fue completamente aleatorizado con arreglo factorial dedos factores: tipo de festuca alta (FNE+ y FCE) y frecuencia de defoliación (alta: AF; baja: BF), con tres repeticiones.Se realizaron 5 cortes a 70 mmde altura desde el nivel del suelo en los tratamientos de BF y 9 en los de AF. Una vezfinalizada la última cosecha de biomasa aérea, se determinó la biomasa de raíces de festuca en ambos experimentos.La producción de biomasa aérea total acumulada en las pasturas de festuca (tanto pura como en mezcla), durantetodo el periodo experimental, no fue afectada (p > 0.05) por la frecuencia de defoliación ni por el tipo de pastura. Nose detectó un efecto significativo (p > 0.05) de la frecuencia de defoliación ni del tipo de festuca alta sobre la biomasade raíces de festuca alta, ni en las pasturas puras ni en las mezclas.

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