Does soil nitrogen affect early competitive traits of annual weeds in comparison with maize?

Soil nitrogen (N) is considered an important driver of crop‐weed interactions, yet the mechanisms involved have been only partially explored, especially with respect to early‐season growth, when competitive hierarchies are formed. This study characterises the effects of different N levels on biomass accumulation and plant morphology for maize (Zea mays), and four important weed species (Amaranthus retroflexus, Abutilon theophrasti, Setaria faberi, and Chenopodium album). Under glasshouse conditions, plants were grown in separate pots and irrigated with nutrient solution at four N concentrations (0.2, 0.5, 2, 5 μm L⁻¹) until 57 days after emergence. Except for S. faberi, which was unresponsive to N, the relative biomass growth rates (RGR) of maize and the broad‐leaved weeds were positively and similarly affected by increasing nitrogen. At all N levels, maize had a height advantage by virtue of its larger seed size, which conferred early growth benefits independent of RGR. At low N, biomass growth was instrumental to S. faberi’s improved competitive position, whereas height development per unit biomass improved the competitive position of A. theophrasti, C. album and A. retroflexus. The approach presented could be applied to other crop‐weed systems to evaluate environmental impacts on competitive outcomes.     

Variation in growth and aggression of juvenile brown trout (Salmo trutta) from upstream and downstream reaches of the same river

Abstract –  To investigate differences in behaviour and growth between juvenile brown trout from spatially separated reaches, fish were collected from above and below a weir in Silverstream, New Zealand. Population level differences in mass-specific growth rates and aggression level were examined in tank experiments. Monitoring of mass-specific growth rates found that relative growth rates between fish of different sizes varied between fish from the upstream reach but not between fish from the downstream reach. Large individuals grew faster than smaller individuals from the upstream reach but no effect of relative fish size on growth was found among fish from the downstream population, indicating that social organisation in the two populations differed. When tested in pairs, juvenile brown trout from the downstream population were found to be more aggressive than those from the upstream population. Differences in the allometric relationship between growth rate and fish size and in the levels of aggressiveness appear to be related to the failure to form dominance hierarchies among fish from the downstream reach, a fixed behavioural trait most likely related to prior experience of crowding or different genetic backgrounds.     

Contribution of contrasting plant hierarchies to the response to N fertilizer in maize

The typical size structuring process that occurs as a consequence of intra-specific competition in maize promotes the appearance of contrasting plant hierarchies (i.e. dominated and dominant individuals). This process may become more intense under low nitrogen (N) availability. The alleviation of plant competition by N addition may reduce plant yield variability through a differential response to N in individuals of contrasting hierarchies. In this work, the response to N of dominated and dominant plants from stands with contrasting N supply (0 to 140-200 kg N ha⁻¹) was examined on 11 experiments carried out in Paraná, Argentina (31°50′S; 60°31′W) in a broad range of growing conditions that included the variation of the year, genotype, plant population and sowing date. Our objectives were: (i) to evaluate the response to N in contrasting plant hierarchies of maize, (ii) to quantify the contribution of dominated and dominant plants to the response to N of the overall stand, and (iii) to study the effect of N on relationships between plant hierarchies and stand variability. Response to N of yield per plant was associated with biomass per plant in non-fertilized controls, tending to be higher in plants with low biomass. The response to N of yield per unit area (i.e., considering all individuals of the stand) was related to the response to N of dominant and dominated plants (P < 0.0001). However, at a higher level of response to N of grain yield per unit area (>50-60%), dominant plants had a considerable lower response than dominated plants, whereas at a lower level of response (<30%), the contribution of contrasting plant hierarchies was similar. In stands with similar plant biomass between hierarchies, the differences in the response to N between plant types tended to be negligible. The coefficient of variation of yield per plant was reduced (P < 0.05) by effect of N in 4 out of 11 experiments, although it tended to be consistently lower in fertilized treatments. When the differences between the biomass of dominated and dominant plants were ample we found the highest response to N at the stand level, as a result of the higher increase in grain yield per plant in dominated plants than in dominant ones. The response to N in each plant hierarchy was differentially associated with increases in shoot biomass, harvest index, kernel number per plant and kernel weight.     

A behavioural approach of dominance establishment in tank‐held sea bream (Sparus aurata L.) under different feeding conditions

Dominance is a strong behaviour exhibited by farmed species that very often impinges on fish growth and welfare. This study presents a behavioural approach of dominance, where colour pattern differentiation was tested as a signal of dominance presence in small sea bream population. The phenotype of dominance was first described in detail, referring to vertical dark stripes and splayed fins. Fish were kept in triplicate tanks for 21 days, during which they were exposed to three feeding conditions (well fed, limited fed and no‐fed) and continuous video recordings. Each tank was stocked with 15 individuals (~30.34 ± 1.70 g), and they were confined to the half volume of the tank via a removable net pen. Percentage of dominants per population was found up to 40%, while duration was calculated to 53.52 ± 7.44 s. Dominance behaviour was further quantified via colour pattern differentiation on sea bream body (CDA, contrast of dominance appearance). The results demonstrated that the body colour of sea bream is directly linked to species social hierarchies and such variations are visual signal of dominance rank inside the population. The fish feeding conditions had an influence on the dominance presence, but not on the dominance rank (as measured by the CDA) between fish groups. The described study provides state‐of‐the‐art knowledge on sea bream dominance. In relevance to aquaculture, dominance quantification would be a reliable tool to evaluate non‐equal food distribution in tank‐held populations, thus, avoid non‐regulate growth performance of fish before transfer to sea‐cage installations.     

Growth, feed utilization and growth heterogeneity in juvenile turbot Scophthalmus maximus (Rafinesque) under different photoperiod regimes

Juvenile turbot (45 g, SE = 1.3) were reared under three photoperiods, 08L:16D, 12L:12D and 20L:04D at slightly elevated ambient temperature for Ireland. Over the 297‐day experimental period, the overall growth rate of the 12L:12D (0.82% d^?1) treatment was higher than for both 08L:16D (0.80% d^?1) and 20L:04D (0.77% d^?1). Overall relative feed intake (FI = % consumption*day^?1) was higher for the 20L:04D (FI = 0.81% d^?1, SE = 0.06) treatment than for the 08L:16D (0.63% d^?1, 0.04) and 12L:12D (0.64% d^?1 0.04) treatments, whereas feed conversion efficiency (FCE = weight gain* consumption^?1) was lower in the 20L:04D (FCE = 0.67, SE = 0.08) group when compared with the 08L:16D (0.88, 0.06) and 12L:12D (0.88, 0.06) treatments. Present results show that the long‐term extended fixed photoperiod may act as an irritant, inducing stress, suppressing growth and reducing feed utilization. It is hypothesized that the progression of size‐dependent hierarchies over time can be divided into two distinct phases herein referred to as ‘hierarchy resolution’ and ‘hierarchy stabilization’ phases (or phases 1 and 2) characterized by increasing and decreasing growth heterogeneity respectively. Growth heterogeneity is measured as coefficient of variation of weight and rank correlation of initial weight of a phase and corresponding growth rate.     

Dynamics of structural traits in two competing C3 grass species: influence of neighbours and nitrogen

This work analysed the regulatory structural mechanisms involved in the competitive interactions between the annual grass Bromus willdenowii Kunth. (BW = prairie grass) and the perennial C₃ grass Dactylis glomerata L. (DG = orchardgrass) during pasture establishment. Four combinations of species (pure BW, pure DG, DG flanked by BW and BW flanked by DG plants), with and without winter nitrogen fertilization, were factorially arranged in a randomized complete block design. Data were recorded at two organization levels: tillers (three tiller age cohorts) and target plants. Annual neighbours caused a decrease in the number of living leaves in tillers of intermediate age of both species. This structural regulatory mechanism led to a decrease in tiller number per plant and, therefore, restricted the development of horizontal space occupation. Annual neighbours did not cause an increase in tiller size, measured as lamina length or pseudostem height, but decreased root biomass. As a consequence, annual neighbours did not lead the hierarchy in light capture, but limited species radical colonization and competitive ability for soil resources. Winter nitrogen fertilization only affected tiller size in older tillers. These findings emphasize the importance of the cultural decisions, as sowing densities and nitrogen fertilization, to optimize pasture floristic composition.     

Yams (Dioscorea spp.) plant size hierarchy and yield variability: Emergence time is critical

Yam crops (Dioscorea spp.) present a very high and unexplained interplant variability which hinders attempts at intensification. This paper aims to characterize the plant-to-plant variability in yield and to identify its underlying causes for the two major yam species (Dioscorea alata and Dioscorea rotundata). Four field experiments were carried out between 2006 and 2009 in Benin. Yams were grown using a traditional cropping method (i.e. in mounds at 0.7 plants m⁻²) without biotic or abiotic stresses. In order to test interplant competition, a low density treatment (0.08 plants m⁻²) was included for D. alata in the 2006 experiment. Throughout four years of experimentation, yields varied from 12 Mg ha⁻¹ to 21 Mg ha⁻¹. Both yam species presented a high interplant coefficient of variation (CV) for tuber yield (42–71%). The unbiased Gini coefficient (G′) was used to measure how steep a hierarchy is in an absolute sense. CV and G′ of individual plant biomass both confirm clear plant size hierarchies from early growth. However, no difference in the CV of plant size and plant tuber yield was observed between high and low plant density. This implies that, despite early interaction between neighbouring plants, competition was not the driving factor controlling plant variability. In fact uneven emergence proved to be the primary cause. Yam emergence takes place over a long period (e.g. it took 51 and 47 days for the 90% central range to emerge for D. alata and D. rotundata, respectively), creating an early inter-plant size hierarchy which later affected tuber production. For both species, plants which emerged early initiated their tuberization earlier in the growing season and reached higher maximum yield regardless of weather conditions (e.g. 1200 and 764 g plant⁻¹ for early-emerging D. alata and D. rotundata plants respectively, and 539 and 281 g plant⁻¹ for late-emerging plants). Plant size hierarchization together with its observed left-skewed distribution, led to reduce total and marketable yield by increasing the proportion of small tubers. These results highlight the need to better understand the underlying mechanisms controlling the yams’ uneven emergence before attempting to improve traditional cropping systems.     

Intra-specific competition in maize: Ear development,flowering dynamics and kernel set of early-established plant hierarchies

Maize canopies with a synchronous seedling emergence and a uniform plant spatial distribution exhibit early-established plant hierarchies (at the 4-leaf stage; V₄). The dominant and dominated individuals of the stand differ in plant growth rate during both the pre-silking period (i.e. from V₇ to V₁₃; PGR_PS) and the period around silking (i.e. a 30 d period centered in silking; PGR_S), and in the ear growth rate around silking (EGR_S). Based on the depleted availability of assimilates of the dominated plants, we tested the hypotheses that (i) the low PGR_PS of dominated individuals affects the morphogenesis of the apical ear leading to a low number of completely developed flowers per ear, and (ii) the low EGR_S of dominated individuals results in a pronounced asynchrony of flowering dynamics and uneven silk exsertion from the husks. Two hybrids with contrasting tolerance to crowding stress (DK752 and DK765 as the tolerant and the intolerant hybrid, respectively) were cropped under different intensities of interplant competition (6, 12, 12 plants m⁻² thinned to 6 plants m⁻² at V₉ and 6 plants m⁻² shaded from V₉ onwards) during 2004/2005 and at 12 plants m⁻² during 2005/2006 at Pergamino (34°56′S 60°34′W), Argentina. Dominant plants were the individuals of the stands with the highest PGR_PS (ca. 1.72 and 2.56 g d⁻¹ for dominated and dominant plants, respectively), PGR_S (ca. 3.05 and 3.94 g d⁻¹ for dominated and dominant plants, respectively) and EGR_S (ca. 1.06 and 1.55 g d⁻¹ for dominated and dominant plants, respectively). This plant type also exhibited the most synchronous flowering dynamics (anthesis–silking interval ca. 1.49 and 1.15 days for dominated and dominant plants, respectively) and the highest kernel set (ca. 401 and 572 kernels plant⁻¹ for dominated and dominant plants, respectively). Apical ears of dominated plants exhibited a delayed in the rate of progress to successive floral stages, but the final number of completely developed flowers per ear did not differ between extreme plant types (ca. 967 and 803 completely developed flowers per ear for DK752 and DK765, respectively). Hence, kernel number per plant was not limited by the number of completely developed flowers per ear, but flowering dynamics were a decisive factor in kernel set of both plant types. Asynchronous silking within the ear of dominated plants determined a greater proportion of flowers per ear with non-exposed silks on silking + 5 d and a larger asynchrony in silk extrusion within the ear. These responses increased kernel abortion rate respect to figures obtained for dominant individuals.