Global ETD Search

1	The biology of apple aphids and their predators Skinner, R. N. January 1983 (has links) No description available. 577
2	Preference and performance of the water lily aphid (Rhopalosiphum nymphaeae) among native and invasive duckweeds (Lemnaceae) Storey, Melissa Cameron. January 2007 (has links) (PDF) Thesis (M.S.)--Georgia Southern University, 2007. / "A thesis submitted to the Graduate Faculty of Georgia Southern University in partial fulfillment of the requirements for the degree Master of Science." In Biology, under the direction of Alan Harvey. ETD. Electronic version approved: July 2007. Includes bibliographical references (p. 59-64) and appendices.
3	Plant aphid interactions : effects of diuraphis noxia and rhopalosiphum padi on the structure and function of the transport systems of leaves of wheat and barley / Saheed, Sefiu Adekilekun. January 2007 (has links) Thesis (Ph.D. (Botany)) - Rhodes University, 2008.
4	Candidate genes for resistance and susceptibility to the bird cherry-oat aphid (Rhopalosiphum padi L.) in barley (Hordeum vulgare L.) Mehrabi, Sara January 2016 (has links) Bird cherry-oat aphid (Rhopalosiphum padi L.) is an important pest on spring-sown cereals. The aphid reduces yield and can act as a vector of barley yellow dwarf virus. R. padi does not give visible symptoms, but heavy infestation can reduce the yield substantially. R. padi is one of the most important pests of barley, which has the fourth rank among the cereals in global production. In order to overcome this problem, the plants are treated with pesticides. However, some of the pesticides are no longer permitted to use due to their negative environmental effects. Another problem is that the aphids develop resistance against them. Therefore, a new approach is to identify genetic factors that could be used in breeding host plants for resistance. There are many examples of successful plant breeding for resistance to aphids, but in the case of R. padi and barley, no resistant cultivar is commercially available. The aim of this thesis was to identify and characterise aphid resistance and susceptibility factors in barley. This was done using two major approaches. Firstly, constitutive and aphid-induced gene expression was studied in a large number of barley genotypes with known levels of resistance. Secondly, two cDNAs putatively adding to aphid resistance were transformed to Arabidopsis and barley and the effect of transformation on aphid performance and behaviour was evaluated. The study of constitutive transcript abundance in 23 barley genotypes gave suggestive evidence that two genes might be related to aphid resistance; a thionin and a proteinase inhibitor gene, and that a lipoxygenase gene might be related to aphid susceptibility.The study of both constitutive and aphid-induced transcript abundances of three glucanase genes, gave support to the idea that two of them might be susceptibility factors. The cDNA of the proteinase inhibitor mentioned above was expressed in Arabidopsis, under control of either a constitutive or a phloem-specific promoter and the effects were evaluated using the green peach aphid, Myzus persicae Sulzer. This aphid is a generalist, feeding on many different plant species, both monocot (such as barley) and dicot (such as Arabidopsis). The results showed lower settling and fecundity on some of the transgenic lines as compared to on controls. In conclusion, the thesis suggests a role in resistance against R. padi in barley for two genes encoding a thionin and a proteinase inhibitor. It has also given support for a role in susceptibility against R. padi of genes encoding a lipoxygenase and two glucanases. The work further shows that a cDNA from barley, selected based on the interaction between a monocot plant and an essentially monocot specialist aphid, affected the resistance of the dicot Arabidopsis against a generalist aphid. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p> aphid resistance aphid susceptibility Rhopalosiphum padi Myzus persicae Hordeum vulgare
5	Wheat stress responses during Russian wheat aphid and Bird Cherry Oat aphid infestation : an analysis of differential protein regulation during plant biotic stress responses / Louw, Cassandra Alexandrovna. January 2007 (has links) Thesis (M.Sc. (Biochemistry, Microbiology & Biotechnology)) - Rhodes University, 2007.
6	Bacillus subtilis und seine Stoffwechselprodukte als Agenzien zur Resistenzinduktion gegen Blattläuse auf Ackerbohne (Vicia faba) und Sommerweizen (Triticum aestivum) Yao, Vinaman 04 January 2007 (has links) Bacillus subtilis Stämme vom FZB - FZB24, FZB37 und FZB38 des FZB Biotechnik, Berlin - und ihre Stoffwechselprodukte wurden als Agenzien für eine Resistenzinduktion gegen Schädiger in drei Wirtspflanzen-Erreger-Systemen, Vicia faba - Uromyces appendiculatus, Vicia faba - Aphis fabae und Triticum aestivum - Rhopalosiphum padi untersucht. Prä-inokulativ wurden Blätter und Saatgut der Pflanzen mit den Testsubstanzen behandelt. Zur Testung gelangten Bakterien-Kulturfiltrat (KF), KF-Zenrifugationsüberstände, die vegetativen Zellen und Sporen der B. subtilis Stämme. Nach lokaler Applikation der KF-Überstände von B. subtilis auf die Wirtspflanzenblätter konnte eine erhebliche Breite antibiotischer (entwicklungshemmender) Wirkungen auf A. fabae und R. padi beobachtet werden. Eine Untersuchung der freien Aminosäuren im Phloemsaft von Vicia faba zeigte, daß sich nach Befall von Aphis fabae speziell bei den zuvor mit bakteriellem Kulturfiltrat und KF-Überstand behandelten Pflanzen im Vergleich zu der nur mit Wasser behandelten Kontrolle, die Konzentration von neun Aminosäuren änderte. / In topical and systemic plant treatment, in three host–parasite systems, i.e. Vicia faba - Uromyces appendiculatus, Vicia faba - Aphis fabae and Triticum aestivum - Rhopalosiphum padi the culture filtrate and supernatant of Bacillus subtilis (FZB24, FZB37 and FZB38 from FZB Biotechnik Berlin) was shown to inhibit the development of urediospores produced by Uromyces appendiculatus. The performance of Aphis fabae and Rhopalosiphum padi was evaluated using life table tests where the aphids'' development time (tD), pre-reproduction time (td), relative growth rate (RGR) and intrinsic rate of natural increase (rm) were assessed. A wide range of antibiosis effects in Aphis fabae and Rhopalosiphum padi was observed when the supernatant of Bacillus subtilis was used as foliar topical treatment. The tested aphids presented longer development and pre-reproduction time; conversely a lower relative growth rate and intrinsic rate of natural increase was observed. The investigation of the free amino acids of the phloem sap of V. faba plants, showed the concentration of the amino acid serine remained unchanged in the supernatant induced plants in this study, which was interpreted as the major reason for the observed antibiosis effect on the tested aphids. Induzierte Resistenz Ackerbohne Sommerweizen Bacillus subtilis Aphis fabae Rhopalosiphum padi Induced resistance Bacillus subtilis Aphis fabae Rhopalosiphum padi 630 Landwirtschaft, Veterinärmedizin 39 Landwirtschaft, Garten ddc:630
7	Posouzení vlivu ÚSES na stabilizační funkce v krajině / Impact of territorial system of ecological stability on stabilizing functions in landscape DVOŘÁKOVÁ, Radka January 2011 (has links) The fields in farming landscape were united to lerge areas in the last 50 years. The balks were ploughed up and their disappearance contributed to the significant loss of biodiversity. Nowadays attepmts are being made to restore the complex agricultural landscape. The creation of territorial system of ecological stability started. Planting biocorridors is a part of this system. Biocorridor is a linear element, consisting of trees and shrubs, which divides large fields. Such non-crop habitats have large positive impact on surrounding landscape. They can also act as refuges for the insect pest. Exapmle is the bird cherry, Prunus padus, a winter host of a cereal pest aphid, Rhopalosiphum padi. In the work the positive and negative effects of TSES are analysed. The important part of the work was to explore, whether the presence of Prunus padus affects the abundance of aphid in adjacent fields. The relatively newly planted biocorridor in Sedlec u Českých Budějovic was used for the work. Based on the results, the suggestions for planting of biocorridors were made, in order to avoid negative effects of spread of this aphid pest species.
8	Wheat stress responses during Russian wheat aphid and Bird Cherry Oat aphid infestation: an analysis of differential protein regulation during plant biotic stress responses Louw, Cassandra Alexandrovna January 2007 (has links) Plants possess a complex and poorly understood network of defence mechanisms that enable them to counteract the effects of abiotic and biotic stress. Aphid phloem feeding is source of biotic stress in plants. Russian wheat aphid and Bird Cherry-Oat aphid feeding cause significant losses in the annual wheat crop, and control by conventional methods such as pesticide application, has proved to be ineffective. Infestation by the Russian wheat aphid has a particularly devastating effect in South Africa. Aphid-resistant wheat cultivars have been identified but an incomplete understanding of the mechanism of the plant’s resistance thwarts the development of improved cultivars. A two-dimensional gel electrophoresis method was developed, partially optimised and validated in order to determine the effect of Russian wheat aphid and Bird Cherry-Oat aphid phloem feeding on the Betta and Betta DN wheat proteome. Differentially expressed proteins that were up or down regulated more than two fold were identified using PDQuest™ Basic software and matched to known wheat proteins stored in the SwissProt protein database on the basis of their molecular mass and isolectric point. Initial analysis of the differential protein expression of Betta and Betta DN wheat in response to Russian wheat aphid and Bird Cherry-Oat aphid phloem feeding at different growth stages revealed that younger plants display higher levels of resistance than older plants. Feeding by the Bird-Cherry Oat aphid does not result in the upregulation of proteins implicated in a defence response, which indicates that the damage incurred by the plant due to feeding by this aphid is not enough to trigger a classic defence response. Feeding by the more damaging Russian wheat aphid resulted in a stress response in susceptible wheat cultivar Betta, and a defence response in resistant wheat cultivar Betta DN. The infestation of Betta DN resulted in the upregulation of putative thaumatins and amylase trypsin inhibitors, indicating that the Betta DN resistance response could be due to the combined effect of protease inhibitors that discourage aphid phloem feeding and the activation of the salicylic acid and jasmonic acid plant defence pathways. Russian wheat aphid Plants, Effect of stress on Wheat -- Diseases and pests Rhopalosiphum Plant proteins
9	Plant aphid interactions : effects of diuraphis noxia and rhopalosiphum padi on the structure and function of the transport systems of leaves of wheat and barley Saheed, Sefiu Adekilekun January 2008 (has links) The infestation of the cultivated grain crops by phloem feeding aphids has generated a great deal of interest over the years, due to the serious damage they cause to the crops and yield losses that result. The mechanism of the interaction between aphids and host plants remains largely unknown in spite of efforts to understand the basis of aphid feeding on grain crops. Greater efforts are required to explain the mechanism(s) of this interaction in order to achieve sustainable agriculture. This thesis focused on an investigation of the mechanism of feeding by the Russian wheat aphid, Diuraphis noxia Mordvilko (RWA) and the bird cherry-oat aphid, Rhopalosiphum padi L. (BCA) on barley and wheat cultivars. These two aphids co-occur naturally, but they inflict very different feeding effects on host plants. Structural and functional approaches were employed to investigate their feeding habits and these were then related to the observed differences in their host plants. Transmission electron microscopy (TEM) techniques were used to study the ultrastructural damage, while fluorescence microscopy techniques – using aniline blue fluorochrome (a specific stain for callose) and 5, 6-CFDA (a phloem-mobile fluorophore) – were employed to investigate the functional response to damage via wound callose formation and phloem transport capacity respectively. RT-PCR and quantitative real-time RT-PCR techniques were used to investigate the regulation of the genes involved in callose synthesis and degradation at the transcriptional level. Morphological observation of the damage caused by the aphids show that infestation by RWA results in extensive leaf chlorosis, necrosis and rolling, while infestation by BCA does not lead to any observable symptoms within the same period. Interestingly, the population study shows that BCA breeds faster than RWA within the two-week experimental period. The ultrastructural study of feeding damage caused by the two aphids on the vascular bundles of susceptible barley cv Clipper, shows a different patterns of damage. Probing the vascular bundles results in the puncturing of vascular parenchyma by both aphids, but severe damage occurs in sieve tubes-companion cell complex during sustained feeding by RWA. In contrast, less damage occurs when BCA feeds on the phloem. Drinking from the xylem by RWA results in deposition of a large quantity of electron-dense watery saliva, which apparently seals the xylem vessels completely, by blocking all the pit membrane fields between the xylem vessels and associated parenchyma cells. In contrast, drinking from xylem by BCA results in deposition of a dense, granular saliva into the xylem vessels only, which does not appear to totally occlude the pit membrane fields. This is the first known report in which ultrastructural evidence of aphids’ drinking in xylem is provided. The comparative effects of RWA feeding on a susceptible Betta and resistant Betta-Dn1 wheat cultivars showed that after two weeks, the Betta cultivar expressed damage symptoms such as chlorosis, necrosis and leaf roll, while few chlorotic patches and necrotic spots occur in resistant Betta-Dn1 cultivars. An ultrastructural investigation of the feeding damage caused to all leaf tissues revealed, for the first time, that RWA is capable of both intra- and inter-cellular probing within mesophyll cells. Probing in the mesophyll cells induces a more severe damage in susceptible Betta than in the resistant Betta-Dn1 counterpart. Similar differences in damage occurred during feeding in the thin-walled sieve tubes of the phloem, with the sieve tubes of the Betta showing more damage than that of the resistant Betta-Dn1. However, drinking from xylem resulted in the characteristic occlusion of metaxylem vessels by copious deposition of saliva by RWA in both Betta and Betta-Dn1 cultivars. In all cases of probing, feeding, and drinking by RWA in both cultivars, all probed cells with evidence of salivary material deposit and those cells adjacent to salivary material deposit, exhibit significant damage in susceptible Betta cultivar, whereas similar cells in Betta-Dn1 cultivars do not show as damage as severe. Investigation of the functional response of the plants to feeding by aphids through the deposition of wound-induced callose shows that formation and deposition of wound callose occurs in both longitudinal and cross veins within 24h of feeding by RWA. This deposition increases through short-term feeding (72h) and prolonged feeding (14d). This is in sharp contrast to the observations with BCA feeding,where little or no callose formation occurs within the same time frame. Callose formation and deposition occurs only when a higher population of BCA feeds on barley leaves. This is the first report of aphid-induced wound callose by BCA. In all cases of callose deposition, aphid stylet tracks were associated with callose and the deposition of callose appears to be a permanent feature, because wound callose remained in the leaf tissues even after 120h of the aphids’ removal. Wound callose signals (defence and anti-defence) are discovered to be transported in the phloem tissues and are dependent on the direction of assimilate flow. Examination of the possible regulation of wound callose genes at the transcriptional level shows that the two expressed glucan synthase gene sequences (GSL – genes involved in callose formation) analysed did not show any significant increase or regulation upon aphid infestation. Contrary to expectation, all three aphid-induced β-1, 3-glucanases (genes which are thought to be involved in callose degradation) showed higher expression in RWA-infested tissue than in BCA-infested tissue. The results of the feeding damage on the transport capacity of the phloem shows that BCA infestation does not lead to a significant reduction in the phloem transport capacity during short-term feeding (72h), while RWA-infested leaves showed considerable reduction in the transport capacity of the phloem within the same period. However, prolonged feeding (14d) by BCA induces a considerable reduction on the transport capacity of the phloem on the infested tissues. In contrast, a marked reduction in the transport capacity of the phloem occurs in RWA-infested leaves and in most cases, complete cessation of transport ensues. In conclusion, these data collectively suggest that RWA is a serious and most destructive phloem feeder in comparison to the BCA. RWA causes severe damage to all cellular tissues of the host plants, which result in apoplasmic and symplasmic isolation of xylem and phloem tissues, while BCA infestation does not result in such isolation within the same time and population levels. Resistance genes appear to function by conferring resistance to cell damage on the resistant cultivars during aphid feeding. Responses by plants to aphid infestation via wound callose deposition are again shown to be species-specific. A quick response results when RWA feeds, even at a very low population level, while a response occurs only at a higher infestation level by BCA, and this response was shown as not regulated at the transcriptional level. Differences in the damage to leaf tissues and wound callose deposition eventually lead to varying degrees of damage to the transport capacity of the phloem. These differences in the damage signatures are hereby suggested to be the cause of the diversity in the observed damage symptoms and the yield losses upon infestation by the two aphid species. Russian wheat aphid Rhopalosiphum padi Aphids -- Host plants Wheat -- Diseases and pests
10	Induced responses of wheat to aphid feeding : consequences for both sides of the insect-plant interaction / Gianoli, Ernesto. January 1900 (has links) (PDF) Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniv., 1999. / Härtill 5 uppsatser.

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