Colonization sequence influences selection and complementarity effects on biomass production in experimental algal microcosms

Species extinction and immigration are both common in natural communities and the sequence with which species are lost from or added to communities may be crucial to community structure. We experimentally addressed this issue by growing six green algal species in monocultures and all possible two-species mixtures, with two colonization sequences for each mixture. Both convergence and divergence in community structure were observed. The compositions containing particularly productive species were more likely to converge, while those comprising of species with similar monoculture yields were more likely to diverge. The species mixtures with high-yielding initial and low-yielding invading species produced more biomass than monocultures, but mixtures with the opposite assembly order produced only the same level of biomass as monocultures did. To address the diversity–ecosystem functioning issue, we estimate complementarity effect by relative yield total (RYT) and selection effect by the correlation between species' monoculture yields and their relative yields in mixtures, respectively. We found overall negative complementarity and positive selection effect in mixtures with high-yielding species as initial colonizers, but positive complementarity and negative selection effect in mixtures with low-yielding initial species. Nonetheless, because we used only up to two species in each microcosm, our results are limited in addressing the relationship between species diversity and ecosystem functioning. Future research should study the effects of immigration history with many more species involved in community assembly.     

Relative uptake of32P by cassava,banana, elephant foot yam and groundnut in intercropping systems

Absorption of applied³²P by the treated as well as neighbouring plants in two- and three-crop intercropping systems involving cassava (Manihot esculenta Crantz), banana (Musa (AAB) Mysore), elephant foot yam (Amorphophallus campanulatus Blume) and groundnut (Arachis hypogaea L.) was studied in field trials. Radiophosphorus applied to the root zone of one of the component species in the mixed systems was found to be absorbed not only by the treated plant but also by the neighbouring plants. Banana was the most dominant species in the cassava-banana-elephant foot yam intercropping system and accumulated the major portion of the radioactivity recovered in the whole system. Cassava planted on raised mounds absorbed³²P from the root zones of elephant foot yam and banana growing in the interspaces. Absorption of³²P from cassava mounds by elephant foot yam was negligible.In cassava-groundnut intercropping system, cassava was the dominant component accumulating about 96 to 99 per cent of the total³²P recovery in the system when the radiolabel was applied to cassava and about 48 to 88 per cent when applied to the intercrops depending on whether cassava was planted on paired row-ridge, mound or flat bed. The groundnut was able to absorb only negligible quantity of³²P from cassava root zone. The absorption of³²P by treated groundnut was highest in paired-row ridge method of planting and lowest in flat bed method of planting.     

Nitrogen economy in relay intercropping systems of wheat and cotton

Relay intercropping of wheat and cotton is practiced on a large scale in China. Winter wheat is thereby grown as a food crop from November to June and cotton as a cash crop from April to October. The crops overlap in time, growing as an intercrop, from April till June. High levels of nitrogen are applied. In this study, we analyzed the N-economy of the monocultures of cotton and wheat, and of four relay intercropping systems, differing in number of rows per strip of cotton or wheat. Field experiments were carried out from 2001/02 to 2003/04 in the Yellow River region in China. We quantified the nitrogen uptake and nitrogen use efficiency of wheat and cotton in relay intercropping systems to test if intercrops are more resource use efficient in comparison to monocrops. Nitrogen (N) yields of wheat per unit area in the four intercropping systems were lower than in the monocrop, which ranged from 203 to 288 kg ha⁻¹. The total N-uptake per unit biomass was similar between wheat in mono- and intercrops. On average, the N-yield of cotton per unit area was lower in intercrops than in monocrops, which ranged from 110 to 127 kg ha⁻¹, but the total N-uptake per unit biomass was higher in intercropped cotton, as dry matter production was reduced to a greater extent by intercropping than N-uptake. The N-uptake of cotton was diminished during the intercropping phase, but recovered partially during later growth stages. The physiological nitrogen use efficiency (IE) of wheat was not much affected by intercropping, but it was reduced in cotton, due to delayed flowering and less reproductive growth. Total N-efficiency of the system was assessed by comparing the relative nitrogen yield total (RNT), i.e. the sum of the ratio’s of total N-uptake by a component crop in the intercrop relative to the N-uptake in the monocrop, to the relative yield total. RNT ranged from 1.4 to 1.7, while the relative yield total (RYT) ranged from 1.3 to 1.4, indicating that intercrops used more nitrogen per unit production than monocrops. An analysis of the crop nitrogen balance showed that the nitrogen surplus of sole crops amounted to 220 kg ha⁻¹ for wheat and 140 kg ha⁻¹ for cotton, while in the intercropping systems, the annual N surplus exceeded 400 kg ha⁻¹. Conventional N-management in intercrops thus results in high N-surpluses that pose an environmental risk. The N management could be improved by means of a demand-based rate and timing of N applications.     

The role of maize root size in phosphorus uptake and productivity of maize/faba bean and maize/wheat intercropping systems

Interspecific root/rhizosphere interactions affect phosphorus (P) uptake and the productivity of maize/faba bean and maize/wheat intercropping systems. The aim of these experiments was to determine whether manipulation of maize root growth could improve the productivity of the two intercropping systems. Two near isogenic maize hybrids (the larger-rooted T149 and smaller-rooted T222) were intercropped with faba bean and wheat, under conditions of high- and low-P availability. The larger-rooted T149 showed greater competitive ability than the smaller-rooted T222 in both maize/faba bean and maize/wheat intercropping systems. The higher competitive ability of T149 improved the productivity of the maize/faba bean intercropping system in P-sufficient conditions. In maize/wheat intercropping systems, root growth, shoot biomass, and P uptake of maize were inhibited by wheat, regardless of the P-supply. Compared with T222, the larger-rooted T149 suffered less in the intercropping systems. The total biomass of the maize/wheat intercropping system was higher for wheat/T149 than for wheat/T222 under low-P conditions. These data suggested that genetic improvement of maize root size could enhance maize growth and its ability to compete for P resources in maize/faba bean and maize/wheat intercropping systems. In addition, depending on the P availability, larger maize roots could increase the productivity of intercropping systems.     

Effects of intercropping on field-scale phosphorus acquisition processes in a calcareous soil

Plant and Soil - Calcium uptake by plants and the ratio of calcium to phosphorus (Ca/P) in the uptake have been recently identified as important drivers of P acquisition in neutral to alkaline...     

Acid phosphatase role in chickpea/maize intercropping

• Background and aims Organic P comprises 30–80 %of the total P in most agricultural soils. It has been proventhat chickpea facilitates P uptake from an organic P sourceby intercropped wheat. In this study, acid phosphatase excretedfrom chickpea roots is quantified and the contribution of acidphosphatase to the facilitation of P uptake by intercroppedmaize receiving phytate is examined. • Methods For the first experiment using hydroponics, maize(Zea mays ‘Zhongdan No. 2’) and chickpea (Cicerarietinum ‘Sona’) were grown in either the sameor separate containers, and P was supplied as phytate, KH₂PO₄at 0·25 mmol P L^–1, or not at all. The second experimentinvolved soil culture with three types of root separation betweenthe two species: (1) plastic sheet, (2) nylon mesh, and (3)no barrier. Maize plants were grown in one compartment and chickpeain the other. Phosphorus was supplied as phytate, Ca(H₂PO₄)₂at 50 mg P kg^–1, or no P added. • Key results In the hydroponics study, the total P uptakeby intercropped maize supplied with phytate was 2·1-foldgreater than when it was grown as a monoculture. In the soilexperiment, when supplied with phytate, total P uptake by maizewith mesh barrier and without root barrier was 2·2 and1·5 times, respectively, as much as that with solid barrier.In both experiments, roots of both maize and chickpea suppliedwith phytate and no P secreted more acid phosphatase than thosewith KH₂PO₄ or Ca(H₂PO₄)₂. However, average acid phosphataseactivity of chickpea roots supplied with phytate was 2–3-foldas much as maize. Soil acid phosphatase activity in the rhizosphereof chickpea was also significantly higher than maize regardlessof P sources. • Conclusions Chickpea can mobilize organic P in both hydroponicand soil cultures, leading to an interspecific facilitationin utilization of organic P in maize/chickpea intercropping.     

The role of maternal and paternal effects in the evolution of parental quality by sexual selection

Genetic models of maternal effects and models of mate choice have focused on the evolutionary effects of variation in parental quality. There have been, however, few attempts to combine these into a single model for the evolution of sexually selected traits. We present a quantitative genetic model that considers how male and female parental quality (together or separately) affect the expression of a sexually selected offspring trait. We allow female choice of males based on this parentally affected trait and examine the evolution of mate choice, parental quality and the indicator trait. Our model reveals a number of consequences of maternal and paternal effects. (1) The force of sexual selection owing to adaptive mate choice can displace parental quality from its natural selection optimum. (2) The force of sexual selection can displace female parental quality from its natural selection optimum even when nonadaptive mate choice occurs (e.g. runaway sexual selection), because females of higher parental quality produce more attractive sons and these sons counterbalance the loss in fitness owing to over-investment in each offspring. (3) Maternal and paternal effects can provide a source of genetic variation for offspring traits, allowing evolution by sexual selection even when those traits do not show direct genetic variation (i.e. are not heritable). (4) The correlation between paternal investment and the offspring trait influenced by the parental effects can result in adaptive mate choice and lead to the elaboration of both female preference and the male sexually selected trait. When parental effects exist, sexual selection can drive the evolution of parental quality when investment increases the attractiveness of offspring, leading to the elaboration of indicator traits and higher than expected levels of parental investment.     

The role of fibroblasts in thymocyte-positive selection

Mice with fibroblast-specific expression of TAP-1 were generated by expressing the TAP-1 transgene under the control of the fibroblast-specific protein (FSP) 1 promoter/enhancer on TAP-1-deficient background. MHC class I expression in primary fibroblast cultures isolated from the resulting strain mimicked that of wild-type counterparts. MHC class I was detected in both types of fibroblasts following treatment with IFN-alphabeta. Positive selection of CD4(-)CD8(+) thymocytes was observed in neither adult nor fetal/neonatal thymus of transgenic mice. IFN-alphabeta-induced expression of MHC class I rescued positive selection of CD4(-)CD8(+) T cells in fetal thymic organ cultures, but not in adult mice. Contrary to previous suggestions, our results indicate a limited role of fibroblasts in promoting positive selection. In addition, the results suggest that positive selection may occur by a different mechanism in fetal vs adult thymus.     

The role of habitat selection behavior in population dynamics: source–sink systems and ecological traps

Ecological traps, poor-quality habitat that nonetheless attract individuals, have been observed in both natural and human-altered settings. Until recently, ecological traps were considered a kind of source–sink system, but source–sink theory does not model maladaptive habitat choice, and therefore cannot accurately represent ecological traps or predict their population-level consequences. Although recent models of ecological traps addressed this problem, they used patch-based models containing only two habitats that were very different from one another, but were internally homogeneous. These sorts of patch models may not apply to many real populations, and using them for populations in landscapes with mosaic or gradient habitat structures may be misleading. I developed models that treat source–sink dynamics and ecological traps as special cases of a single process, in which the attractiveness and quality of the habitat are separate variables that can be either positively or negatively related, and in which habitat quality varies continuously throughout the landscape. As expected, sinks are less detrimental to populations than ecological traps, in which preferential use of poor habitat elevates extinction risk. Furthermore, ecological traps may be undetected, and may even appear to be sources, when population sizes are large, but may still prevent recovery in spite of the availability of high-quality habitat when populations drop below threshold levels. Conservation biologists do not routinely consider the possibility that apparent sinks are actually traps, but since traps should be associated with the rapidly changing and novel habitat characteristics primarily produced by human activities, ecological traps should be considered an important and potentially widespread conservation concern.     

The role of natural selection in evolution

To evaluate properly a role of natural selection, its effect should be considered in relation to different phases of the evolutionary cycle postulated earlier by the author. At the first stage of the cycle natural selection is directed towards organism's persistence to detrimental external factors and leads to an increased fitness (that is viability and fecundity) in every generation. At the next stage of the cycle natural selection occurs under conditions of intraspecific competition and is directed towards a more efficient utilization of food resources. At this stage natural selection leads to formation and divergence of intraspecific races and is carried out by "single" selection actions occurring now and then and consisting of the survival of rare mutants with an altered ecological potential. Such a strict selection for certain mutants occurs again during the periods of acute competition for food, the selected mutants being characterized by a decrease of fitness, the latter to have been restored by means of the "ordinary" selection within the intervals between crises. According to the model suggested, homozygotes for "detrimental" recessive alleles could be selected in diploids, as the mutants mentioned with altered ecological potential. At the end of the cycle, there is a kind of selection for hybrids in which ecological potential of specialized intraspecific races is combined. The genetic drift is considered as an inevitable consequence of the postulated mechanism of natural selection.     

保护地间作芹菜对温室粉虱的防治作用

温室白粉虱Trialeurodes vaporariorum(Westwood)和烟粉虱Bemisia tabaci(Gennadius)是严重危害葫芦科、茄科和豆科等多种蔬菜的主要害虫,具有分布范围广、种群数量大、繁殖力强等特性。作者通过田间试验研究了蔬菜保护地内间作温室粉虱非嗜食植物芹菜(Apium graveliens L.)对其的防治效果。结果表明:与空白处理和常规化学防治相比,在番茄和黄瓜保护地内间作芹菜对温室粉虱均具有显著的防治效果,驱避效果分别达到98.0%和84.5%。这些结果是初步的,但其为进一步研究温室粉虱的寄主选择机制和非化学防治方法提供了依据。     

On the relative importance of the effects of selection and complementarity as drivers of diversity–productivity relationships in Mediterranean shrublands

Extensive research has been devoted to understanding the role of biodiversity as a driver of ecosystem functioning. However, no previous study has evaluated the relative contribution of complementarity and selection to productivity in shrublands. We have attempted to do this for a Mediterranean shrubland dominated by Quercus coccifera , Cistus albidus , Ulex parviflorus and Rosmarinus officinalis . We found a highly significant and linear positive relationship between productivity and species richness. No selection effect was apparent, but both the complementarity and net effects were highly significant. The magnitude of these effects increased from two to three species, but became non-significant in the four-species mixtures. Analysis of pairwise interactions revealed that legumes did not promote overyielding. Complementarity was mostly driven by Cistus , which always performed better when growing with other species than when growing with conspecifics. Our results are an addition to the still scarce literature dealing with diversity–productivity relationships in communities dominated by woody species, and show that methodologies commonly used to assess complementarity may not provide a precise estimation when a given species has negative effects on its conspecifics.     

The role of intercropping different cereal species in controlling lepidopteran stemborers on maize in Kenya

Abstract:  The effects of mixed cropping systems containing maize, sorghum, millet and beans on infestations of cereals by lepidopteran stemborers and on associated parasitoids, as well as on yields and land equivalent ratios (LER) were assessed during four consecutive rainy seasons at two sites in the semi-arid eastern region of Kenya. Systems containing the non-host bean were more efficient in reducing pest densities than those with millet or sorghum only. Higher parasitism in diversified systems compared to monocrops was due to density-dependent effects rather than superior suitability of such systems to parasitoids. The maize–bean system, which had the highest proportion of bean plants, had LERs >1.65 while most other systems had LERs <1. It is concluded that mixed cropping with several cereal species has little advantages in terms of yield loss abatement due to stemborers and land use efficiency. However, including the drought-tolerant crops such as sorghum and millet in the system stabilizes food security in drought-prone areas such as eastern Kenya.     

淮北平原杨-麦间作系统的小气候效应与土壤水分变化研究

对淮北平原的杨－麦间作系统的小气候效应与土壤水分的研究表明,在冬小麦发育的拔节期和灌浆期,林粮带状间作与对照地相比可以降低农田地面温度1－7℃,提高相对湿度2％－8％,农田日照时数减低量随间作为间距和时间而变化,在范围在4．1％－15．3％之间,农田林网可以提高相对湿度6．4％－11．6％,日照时数减少8．5％－11．75,农林 间作可以提高土壤含水率,幅度随间作密度而定,一般可提高含水率0．67％－3．875,农田林网的土壤含率与林带的方位和离林带的距离有关,在各个方位上均与离林带的距离呈显著负相关。     

High affinity iron-uptake systems in Vibrio damsela: role in the acquisition of iron from transferrin

In this work, the high affinity iron-acquisition systems displayed by virulent and avirulent strains of Vibrio damsela have been investigated. This species is an autochthonous member of marine ecosystems that can behave as an opportunistic pathogen for fish and mammals. All strains tested (i) were able to grow under the restricted conditions imposed by the iron chelators transferrin (Tf) and EDDHA, (ii) secreted siderophores of hydroxamic type, other than aerobactin and desferal, that were able to stimulate the growth of the auxotroph mutant Arthrobacter flavescens JG9, and (iii) expressed common iron-regulated outer membrane proteins (IROMPs). No change in LPS patterns was observed in response to iron restriction. Results from the assays with transferrin suggest that these siderophores could be utilized to sequester iron from Tf, a protein for which no surface receptor was detected in any strain. In summary, the overall data demonstrate that V. damsela expresses siderophore-mediated iron-uptake systems. These systems are probably involved in the survival of the species in the different environments that it can colonize, i.e. water and several vertebrate hosts.     

Inorganic carbon acquisition systems in cyanobacteria

This minireview focuses on the mechanism of inorganic carbon uptake in cyanobacteria and in particular the two CO₂-uptake systems and two bicarbonate transporters recently identified in Synechocycstis PCC 6803, and their presence in other cyanobacterial strains. This revised version was published online in August 2006 with corrections to the Cover Date.     

Sensory acquisition in active sensing systems

A defining feature of active sensing is the use of self-generated energy to probe the environment. Familiar biological examples include echolocation in bats and dolphins and active electrolocation in weakly electric fish. Organisms that utilize active sensing systems can potentially exert control over the characteristics of the probe energy, such as its intensity, direction, timing, and spectral characteristics. This is in contrast to passive sensing systems, which rely on extrinsic energy sources that are not directly controllable by the organism. The ability to control the probe energy adds a new dimension to the task of acquiring relevant information about the environment. Physical and ecological constraints confronted by active sensing systems include issues of signal propagation, attenuation, speed, energetics, and conspicuousness. These constraints influence the type of energy that organisms use to probe the environment, the amount of energy devoted to the process, and the way in which the nervous system integrates sensory and motor functions for optimizing sensory acquisition performance.