Global ETD Search

21	Evaluating small unmanned aerial systems for detecting drought stress in turfgrass HONG, MU January 1900 (has links) Master of Science / Department of Horticulture and Natural Resources / Dale J. Bremer / Recent advances in small unmanned aerial systems (sUAS) may provide rapid and accurate methods for turf research and management. The study was to evaluate early drought detection ability of ultra-high resolution remote sensing with sUAS technology, and compare it with traditional techniques on fairway-height ‘Declaration’ creeping bentgrass (Agrostis stolonifera L.) treated from severe deficit to well-watered irrigation (15, 30, 50, 65, 80, and 100% evapotranspiration replacement). Airborne measurements with a modified digital camera mounted on a hexacopter included reflectance from broad bands (near infrared [NIR, 680-780 nm], and green and blue bands [overlapped, 400-580 nm]), from which eight vegetation indices (VIs) were derived for evaluation. Canopy temperature was measured only in the final year with a thermal infrared camera mounted on a drone. Traditional measurements were volumetric water content (VWC), visual quality (VQ), percentage green cover (PGC), and VIs from handheld devices. Declines in VWC in irrigation-deficit treatments were consistently detected by the NIR band and six VIs from sUAS, and NDVI and red band from a handheld device, before drought stress was evident in VQ. These bands and indices predicted drought stress at least one week before symptoms appeared in VQ. Canopy temperature predicted drought stress as early as the best VIs and NIR, 16 days before symptoms appeared in VQ in 2017. Only the NIR and GreenBlue VI [(green-blue)/(green+blue)] consistently predicted drought stress throughout three years. Results indicate using ultra-high resolution remote sensing with sUAS can detect drought stress before it is visible to the human eye and may prove viable for irrigation management on turfgrass. sUAS remote sensing drought stress creeping bentgrass vegetation index deficit irrigation
22	Modificações morfológicas, fisiológicas e seletividade da soja a diferentes herbicidas em resposta ao estresse hídrico / Morphological, physiological modifications and selectivity of soybean to different herbicides in response to water stress Gonçalves, Clebson Gomes [UNESP] 22 February 2017 (has links) Submitted by CLEBSON GOMES GONÇALVES null (goncalvescg.agro@hotmail.com) on 2017-03-14T21:30:30Z No. of bitstreams: 1 Clebson_Gomes_Gonçalves.pdf: 4338436 bytes, checksum: 5b3165c52c4014dd4f0d507cda926f92 (MD5) / Approved for entry into archive by LUIZA DE MENEZES ROMANETTO (luizamenezes@reitoria.unesp.br) on 2017-03-21T20:24:19Z (GMT) No. of bitstreams: 1 goncalves_cg_dr_jabo.pdf: 4338436 bytes, checksum: 5b3165c52c4014dd4f0d507cda926f92 (MD5) / Made available in DSpace on 2017-03-21T20:24:19Z (GMT). No. of bitstreams: 1 goncalves_cg_dr_jabo.pdf: 4338436 bytes, checksum: 5b3165c52c4014dd4f0d507cda926f92 (MD5) Previous issue date: 2017-02-22 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / O déficit hídrico é o estresse abiótico mais limitante e severo para as culturas agrícolas, pois desencadeia uma série de adaptações fisiológicas e modificações anatômicas nas plantas como um processo adaptativo em resposta ao déficit hídrico e que regula a redução das perdas de água da planta para a atmosfera. A fim de esclarecer o efeito do estresse hídrico sobre as características anatômicas e fisiológicas da soja, bem como a seletividade de herbicidas, o presente trabalho teve como objetivo examinar as alterações morfológicas e enzimáticas das cultivares de soja: MG / BR 46 Conquista (convencional) e a BRS Valiosa (transgênica) por meio de resposta a diferentes manejos de água no solo, em dois estádios vegetativos de desenvolvimento. As plantas foram submetidas a diferentes manejos de água no solo, nos estádio de desenvolvimento vegetativo V2 e V4. Foram realizadas avaliações de condutância estomática, área foliar, medidas de anatomia foliar e caulinar. Também foram avaliados os mecanismos de resposta ao estresse antioxidante pelas medições de, peroxidação lipídica, teor de H2O2, prolina, superóxido dismutase (SOD), catalase (CAT) e ascorbato peroxidase (APX), além de avaliar o comportamento dos herbicidas fomesafen a 250 g i.a. ha-1 e chlorimuron-ethyl 20 g i.a. ha-1 em plantas de soja submetidas a diferentes restrições hídricas. A cultivar BRS Valiosa RR apresentou melhor resposta adaptativa morfológica e anatômica quando submetida a uma restrição hídrica moderada de até (-0,07 MPa) quando ocorrida nas primeiras semanas de desenvolvimento das plantas. A atividade da SOD, CAT e APX das plantas transgênicas apresentaram um intenso aumento no estádio V4, enquanto que a cultivar convencional não superou a condição de estresse nesse período. Estas respostas determinaram que a BRS Valiosa (transgênica) apresentou uma resposta tardia que aumentou a sobrevivência a longos períodos de escassez de água. A escassez hídrica reduz a fitointoxicação visual quando submetida à pulverização dos herbicidas fomesafen e chlorimuron-ethyl. Constatou-se que o fomesafen e chlorimuron-ethyl proporcionaram um efeito negativo na infecção pelos rizóbios, assim como o déficit hídrico reduziu drasticamente a fixação biológica de nitrogênio e o crescimento das plantas de soja. Quando as plantas de soja foram submetidas a uma condição de escassez hídrica moderada (-0,07 MPa) a cultivar convencional teve o seu desenvolvimento mais afetado em comparação com a cultivar transgênica. Evidenciou-se, ainda, que a cultivar transgênica mostrou ter uma maior capacidade em sustentar a fixação biológica de nitrogênio quando submetida a uma condição de escassez hídrica moderada (-0,07 MPa) em comparação com a cultivar convencional. / The drought is the most limiting and severe abiotic stress for agricultural crops, because it triggers a number of physiological adaptations and anatomical modifications in the plants as an adaptive process in response to the water deficit and which regulates the reduction of water losses from the plant to the atmosphere. In order to know the effect of water stress on the anatomical and physiological characteristics of soybean, as well as the selectivity of herbicides, the present work had as objective to examine the morphological and enzymatic alterations of soybean cultivars: MG / BR 46 Conquista (conventional) and BRS Valiosa (transgenic) by means of response to different water management in the soil, in two stages of vegetative development. The plants were submitted to different soil water management, in the vegetative development stage V2 and V4. Stomatal conductance, foliar area, and leaf and stem anatomy measurements were performed. The antioxidant stress was measured by lipid peroxidation, H2O2 content, proline, superoxide dismutase (SOD), catalase (CAT) and ascorbate peroxidase (APX). The spraying of fomesafen at rate 250 g a.i ha-1 and chlorimuron-ethyl at rate 20 g a.i ha-1 in soybean plants under different water restrictions was also evaluated. BRS Valiosa RR has a better adaptive morphological and anatomical performance in response to a moderate water restriction up to (-0.07 MPa) when it occurs in the first weeks of plant development. SOD, CAT and APX activity of transgenic plants showed an intense increase in the V4 stage, while the conventional cultivar did not overcome the stress condition in this period. These responses appoint that BRS Valiosa (transgenic) has a late response, which increases survival at long periods of water scarcity. Drought reduces visual phytointoxication when sprayed with the herbicides fomesafen and chlorimuron-ethyl. It was found that the spraying of the herbicide fomesafen and chlorimuron-ethyl has a negative effect on rhizobia infection, as well as the water deficit drastically reduced the biological nitrogen fixation and the growth of the soybean plants. When soybean plants were submitted to a moderate drought condition (-0.07 MPa) the conventional cultivar had its development more affected compared to the transgenic cultivar. It was also evidenced that the transgenic cultivar showed to have a greater capacity to support the biological fixation of nitrogen when submitted to a condition of moderate drought (-0.07 MPa) in comparison to the conventional cultivar. Anatomia Estresse oxidativo Déficit hídrico Glycine max PROTOX ALS Anatomy Drought stress Glycine max Oxidative stress
23	EFFECTS OF ABIOTIC STRESSES ON SORBITOL AND RIBITOL ACCUMULATION AND SORBITOL BIOSYNTHESIS AND METABOLISM IN TOMATO [<em>Solanum lycopersicum</em> L.] Almaghamsi, Afaf 01 January 2019 (has links) Abiotic stresses are responsible for limiting crop production worldwide. Among diverse abiotic stresses, drought and salinity are the most challenging. Plants under these conditions have diverse strategies for tolerating stress. Osmotic adjustment and osmoprotection occur in plants during salinity and drought stress through accumulation of compatible solutes to a high level without interfering with cellular metabolism. Polyols (sugar alcohols) including sorbitol and ribitol are one such class of compatible solutes. Using plants of wild-type (WT) and three genetically-modified lines of tomato (Solanum lycopersicum cv. ‘Ailsa Craig’), an empty vector line ‘TR22’, and 2 sdh anti-sense lines ‘TR45’, and ‘TR49’ designed to severely limit sorbitol metabolism, the objective of this work was to characterize the sorbitol cycle in tomato in response to abiotic stresses. Sorbitol and ribitol content, as well as the enzymatic activities, protein accumulation, and gene expression patterns of the key sorbitol cycle enzymes ALDOSE-6-PHOSPHATE REDUCTASE (A6PR), ALDOSE REDUCTASE (AR), and SORBITOL DEHYDROGENASE (SDH), were measured in mature leaves in response to drought stress by withholding water and by using polyethylene glycol as a root incubation solution to mimic drought stress, to salt stress by incubating roots in NaCl solution, and to incubation of roots in 100 mM sorbitol and ribitol. A6PR, not previously reported for tomato, and AR both exhibited increased activity correlated to sorbitol accumulation during the drought osmotic, and salt stresses, with SDH also increasing in WT and TR22 to metabolize sorbitol. The level of sorbitol accumulation was considerably lower than that of the common sugars glucose and fructose so was not enough to have a significant impact on tissue osmotic potential but could provide other important osmoprotective effects. Use of the sdh antisense lines indicated that SDH has the key role in sorbitol metabolism in tomato as well as a likely role in ribitol metabolism. Like sorbitol, ribitol also accumulated significantly more in the antisense lines during the stresses. Expression and/or activity of A6PR, AR, and SDH were also induced by the polyols, although it is not clear if the induction was due to a polyol signal, the osmotic effect of the incubation solution, or both. In addition, a unique post-abiotic stress phenotype was observed in the sdh anti-sense lines. After both drought and salt stresses and during a recovery phase after re-watering, the antisense lines failed to recover. This may have been due to their accumulation of ribitol. The sdh anti-sense lines were uniquely sensitive to ribitol but not sorbitol, with an apparent foliar and seed germination toxicity to ribitol. The determination that sorbitol, and perhaps ribitol as well, plays a role in abiotic responses in tomato provides a cornerstone for future studies examining how they impact tomato tolerance to abiotic stresses, and if their alteration could improve stress tolerance. drought stress salt stress aldose-6-phosphate reductase aldose reductase sorbitol dehydrogenase Agriculture Physiology Plant Sciences
24	THE ROLE OF ALTERNATIVE POLYADENYLATION MEDIATED BY CPSF30 IN <em>ARABIDOPSIS THALIANA</em> Hao, Guijie 01 January 2017 (has links) Drought stress is considered one of the most devastating abiotic stress factors that limit crop productivity for modern agriculture worldwide. There is a large range of physiological and biochemical responses induced by drought stress. The responses range from physiological and biochemical to regulation at transcription and posttranscriptional levels. Post-transcription, the products encoded by eukaryotic genes must undergo a series of modifications to become a mature mRNA. Polyadenylation is an important one in terms of regulation. Polyadenylation impacts gene expression through determining the coding and regulation potential of the mRNA, especially when different mRNAs from the same gene may be polyadenylated at more than one position. This alternative polyadenylation (APA) has numerous potential effects on gene regulation and function. I have studied the impact of drought stress on APA, testing the hypothesis that drought stress may give rise to changes in the usage of poly(A) sites generating different mRNA isoforms. The results showed that usage of poly(A) sites that lie within 5’-UTRs and coding sequence (CDS) changes more than usage of sites in other regions due to drought stress. Alternative polyadenylation is meditated by the polyadenylation complex of proteins that are conserved in eukaryotic cells. The Arabidopsis CPSF30 protein (AtCPSF30), which is an RNA-binding endonuclease subunit of the polyadenylation complex, plays an important role in controlling APA. Previous study showed that poly(A) site choice changes on a large scale in oxidative stress tolerant 6 (oxt6), a mutant lacking AtCPSF30. Within the mutant/WT genotypes, there are three classes of poly(A) site, wild type specific, oxt6 specific, and common (both in wild type and mutant). The wild type specific and oxt6 specific mRNAs make up around 70% of the total of all mRNA species. I hypothesize that the stability of these various mRNA isoforms should be different, and that this is a possible way that AtCPSF30 regulates gene expression. I tested this by assessing the influence poly(A) sites can have on the mRNA isoform’s stability in the wild type and oxt6 mutant. My results show that most mRNA isoforms show similar stability profiles in the wild-type and mutant plants. However, the mRNA isoforms derived from polyadenylation within CDS are much more stable in the mutant than the wild-type. These results implicate AtCPSF30 in the process of non-stop mRNA decay. Messenger RNA polyadenylation occurs in the nucleus, and the subunits of the polyadenylation complex that meditate this process are expected to reside within the nucleus. However, AtCPSF30 by itself localizes not only to the nucleus, but also to the cytoplasm. AtCPSF30 protein contains three predicted CCCH-type zinc finger motifs. The first CCCH motif is the primary motif that is responsible for the bulk of its RNA-binding activity. It can bind with calmodulin, but the RNA-binding activity of AtCPSF30 is inhibited by calmodulin in a calcium-dependent manner. The third CCCH motif is associated with endonuclease activity. Previous studies demonstrated that the endonuclease activity of AtCPSF30 can be inhibited by disulfide reducing agents. These published results suggest that there are proteins that interact with AtCPSF30 and act through calmodulin binding or disulfide remodeling. To test this hypothesis, I screened for proteins that interact with AtCPSF30. For this, different approaches were performed. These screens led me to two proteins-one protein that is tyrosine-phosphorylated and whose phosphorylation state is modulated in response to ABA, which well-known ABA regulates guard cell turgor via a calcium-dependent pathway, and the other is ribosome protein L35(RPL35), which plays an important role in nuclear entry, translation activity, and endoplasmic reticulum(ER) docking. These results suggest that multiple calcium-dependent signaling mechanisms may converge on AtCPSF30, and AtCPSF30 might be directly interact with ribosome protein. AtCPSF30 Alternative polyadenylation Drought stress Protein-protein interaction Arabidopsis thaliana Bioinformatics Biotechnology Molecular Biology
25	The evaluation and promotion of best practices for the restoration of arid- and semi-arid rangelands in southern Africa / Loraine van den Berg Van den Berg, Loraine January 2007 (has links) Thesis (Ph.D. (Botany))--North-West University, Potchefstroom Campus, 2008. Land degradation Desertification Conservation Restoration Alternative livelihoods Environmental legislation Cenchrus ciliaris Drought stress
26	Physiological And Biochemical Screening Of Different Turkish Lentil (lens Culinaris M.) Cultivars Under Drought Stress Condition Gokcay, Derya 01 September 2012 (has links) (PDF) Legumes being the most important crops worldwide are limited in terms of adaptability and productivity mainly by the abiotic stresses. In this study, the aim was to understand tolerance mechanisms of lentil cultivars under drought stress by physiological and biochemical analyses. This study was carried out with six Turkish Lentil cultivars (Seyran, Kafkas, Malazgirt, &Ccedil / agil, &Ccedil / ift&ccedil / i, &Ouml / zbek) subjected to drought stresses (10% and 15% PEG) and their physiological and biochemical properties were examined to select drought-tolerant and drought-sensitive cultivars. Drought stress was applied for 5 days to 7 days-grown lentil plants. 12-days old, stressed and control plant shoots and roots were analyzed in terms of physiological and biochemical parameters (length, fresh weight, ion leakage, proline, MDA and H SB Food Crops 175-177
27	Cotton Production under Traditional and Regulated Deficit Irrigation Schemes in Southwest Texas Wen, Yujin 2011 August 1900 (has links) The urban water demand in Southwest Texas has grown rapidly in recent years due to the population increases in urban areas, which caused conflict between municipal and agricultural water use. Deficit irrigation is one important measure for solving this problem. A field experiment with seven different irrigation treatments and four cotton varieties was conducted at the Texas AgriLife Research and Extension Center at Uvalde in the summers of 2008 and 2009 to examine the water saving potential and related phenological/physiological responses in Southwest Texas. The results showed that: 1) The threshold deficit ratio for a traditional deficit irrigation scheme falls between 0.7 and 0.8 for cotton production in Southwest Texas under a low energy precision application (LEPA) sprinkler irrigation system. The 70 percent evapotranspiration (ET)-initialled regulated deficit irrigation scheme (70R) performed well in maintaining lint yield in most cotton varieties tested. The significant changes detected in lint quality failed to introduce premiums or discounts in cotton price. 2) The phenological parameters (plant height, node number and flower/fruit number) showed clear trends that illustrate the relationship between increased stress level and decreased plant growth and development. The observed inconsistency of the physiological responses in the two growing seasons may imply that physiological parameters are not good direct predictors of lint yield if measurements are conducted only on a point basis. The partitioning coefficients of boll dry weight in both years failed to show a significant difference between deficit irrigation treatments and the control, indicating that reallocation of carbohydrates may not be the major factor of maintaining lint yield for the deficit irrigation treatments. 3) Economic analysis showed that due to the low water price, it is not currently profitable to adopt deficit irrigation. In case that water price is increased, it may become more profitable to adopt deficit irrigation. This work provides reference information to water authorities and policy makers to set quotas for municipal and agricultural water use and to value water properly through setting different water prices. cotton production deficit irrigation drought stress production function carbon assimilation rate water use efficiency
28	Stadtbäume im Klimawandel - Dendrochronologische und physiologische Untersuchungen zur Identifikation der Trockenstressempfindlichkeit häufig verwendeter Stadtbaumarten in Dresden. Gillner, Sten 14 August 2012 (has links) (PDF) Der bereits stattfindende Klimawandel mit ansteigenden Temperaturen, einer Zunahme von Trockenperioden und Hitzewellen während der Vegetationsperiode wird das Risiko von Trockenstress für Bäume und Sträucher erheblich erhöhen. Eine der Herausforderungen ist daher die erfolgreiche Etablierung von gesunden, langlebigen und an die spezifischen urbanen Standorte adaptierten Bäume, um die ökologischen und ökonomischen Wohlfahrtswirkungen städtischen Grüns auch in Zukunft zu gewährleisten. Das Ziel dieser Arbeit war es deshalb, sowohl die Eignung einiger häufig verwendeter Straßenbaumarten für stark versiegelte Straßenbaumstandorte als auch deren Toleranz gegenüber Trockenstress am Beispiel von Dresden zu identifizieren. Die Arbeit verfolgt einen dendrochronologischen und einen physiologischen Ansatz. Im dendrochronologischen Teil der Arbeit wurden die Jahrringzeitreihen von 16 Straßenbaum-Chronologien, 3 Einzelbaum-Chronologien im Stadtgebiet von Dresden und 4 Chronologien eines trockenen Waldstandortes in einem Naturschutzgebiet sowie 2 Chronologien frischer Waldstandorte analysiert. Auf Basis der trendbereinigten Zuwachszeitreihen wurden Klima-Zuwachs-Relationen, moving correlations, Weiserjahranalysen und superposed epoch analyses (SEA) durchgeführt. Im physiologischen Teil der Arbeit wurde in den Sommermonaten der Jahre 2009 und 2010 auf vier urbanen Straßenbaumstandorten der lichtgesättigte Gasaustausch von sechs Baumarten und das Blattwasserpotential von vier Baumarten ermittelt. Für die Messperioden und in ausgewählten Trockenperioden wurde die Wassernutzungseffizienz der Baumarten verglichen. Auf urbanen Straßenbaumstandorten reagieren die Arten Acer platanoides, Acer pseudoplatanus und Fagus sylvatica stark sensitiv auf Trockenheit. Im Gegensatz dazu können die Arten Platanus x hispanica, Quercus robur subsp. sessiliflora und Quercus rubra als weniger trockenheitsempfindlich betrachtet werden. Die dendrochronologischen und physiologischen Ergebnisse erlauben für Tilia cordata Mill., Tilia platyphyllos und Pyrus communis eine Einordnung in eine mittlere Eignung für versiegelte Flächen. Aus den dendrochronologischen und physiologischen Ergebnissen dieser Untersuchung lässt sich schließen, dass sich die höheren Temperaturen und die zunehmenden Trockenperioden für alle untersuchten Arten negativ auswirken können. Dennoch zeigen die Baumarten Platanus x hispanica, Quercus robur subsp. sessiliflora und Quercus rubra, dass sie den sich verändernden Klimabedingungen auf stark versiegelten urbanen Standorten gut widerstehen können und auch in Zukunft eine hohe Vitalität beibehalten werden. Stadtbäume Klimawandel Trockenstress urban trees climate change drought stress ddc:630 rvk:ZH 9660 rvk:AR 23100
29	Glutathione S-transferase Activity And Glutathione Levels In Drought Stressed Pinus Brutia Ten. Trees Growing In Ankara Yilmaz, Can 01 October 2006 (has links) (PDF) Turkish red pine is coastal tree and is a drought resistant pine that withstands more aridity and poor soils than most other timber species growing in the same climatic conditions. In Turkey, this species grows in southern and western Anatolia and is also found in the Marmara region. Drought results in a water deficit in plant tissues, which, in turn, can lead to an imbalance in the redox poise of plant cells, and thus inducing oxidative stress in plants. Resistance to conditions associated with oxidative-stress must, in part, rely on endogenous antioxidative defense mechanisms required to maintain cellular homeostasis. Glutathione is one of the major endogenous antioxidants in plants known to play an important role in plant defense mechanisms. Glutathione S-transferase (GST, EC 2.5.1.18) is a GSH dependent detoxifying enzyme in plants, which catalyzes the conjugation of GSH. In this study, we investigated the changes in cytosolic glutathione S-transferase enzyme activity using CDNB as substrate and total thiol amount in Pinus brutia Ten., related to the drought stress during four months, June to September. The osmotic pressure in the needles was also determined as an indirect measure of drought condition. Together with the increase in the temperature values from June to July, GST enzyme activity increased from 15,78 &plusmn / 1,36 &micro / moles min-1 mg protein-1 to 22,91 &plusmn / 1,99 &micro / moles min-1 mg protein-1 which was statistically significant. However in August, GST activity had fallen to 16,54 &plusmn / 1,61 &micro / moles/min/mg protein, which may be because of a local rainfall at the beginning of the August in the sampling area. In September, GST activity significantly increased with respect to June, in accordance with high temperatures. The total thiol amount was not changed significantly during the sampling period. Although there were statistically significant changes in osmotic pressure in the needdles collected during the same sampling period, it did not exactly correlated to the changes in GST activity. QD Biochemistry 415-436
30	Effect Of Drought And Salt Stresses On Antioxidant Defense System And Physiology Of Lentil (lens Culinaris M.) Seedlings Ercan, Oya 01 February 2008 (has links) (PDF) In this study, 14 days old lentil seedlings (Lens culinaris Medik cv. Sultan), which were subjected to 7 days of drought (20% PEG 6000), and salt (150 mM NaCl ) stress , were examined in a comparative manner for the effects of drought and salt stress treatments. In shoot and root tissues physiological parameters such as wet-dry weight, relative water content, root-shoot lengths, membrane electrolyte leakage, and lipid peroxidation in terms of malondialdehyde (MDA) were determined. H2O2 content, proline accumulation and chlorophyll fluorescence analysis were also performed. Changes in the activity of antioxidant enzymes such as superoxide dismutase (SOD: EC 1.15.1.1), catalase (CAT: EC 1.11.1.6) ascorbate peroxidase (APX: EC 1.11.1.11) and glutathione reductase (GR: EC 1.6.4.2) were observed upon stress treatments. In salt treated lentil seedlings, significant decreases in wet-dry weight, RWC, shoot-root length and chlorophyll fluorescence measurements indicated a sensitivity, when compared to drought treated plants. Higher MDA concentration and higher electrolyte leakage amounts are supported these results. APX, GR and proline seem to play important roles in antioxidant defense against salt stress for both tissues by removing reactive oxygen species and protecting macromolecules and membranes. GR and proline are also maintains the main protective mechanism against drought stress effects. SOD is active in drought stressed roots and salt stressed shoots, where the H2O2 contents are also observed to be increased. QK Plant Physiology 710-899

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