Search Results - "fe"

The genome of the heartwater agent Ehrlichia ruminantium contains multiple tandem repeats of actively variable copy number by Collins, N.E., Liebenberg, J., Villiers, Etienne P. de, Brayton, K.A., Louw, E., Pretorius, E., Faber, F.E., Heerden, H. van, Josemans, A., Kleef, M. van, Steyn, H.C., Strijp, M.F. van, Zweygarth, E., Jongejan, F., Maillard, J.C., Berthier, D., Botha, M., Joubert, F., Corton, C.H., Thomson, N.R., Allsopp, M.T., Allsopp, B.A.

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The Tropical managed Forests Observatory: a research network addressing the future of tropical logged forests by Sist, P., Rutishauser, E., Pena-Claros, M., Shenkin, A., Herault, B., Blanc, Lilian, Baraloto, C., Baya, F., Benedet, F., Silva, K.E. da, Descroix, L., Ferreira, J.N., Gourlet-Fleury, S., Guedes, M.C., Bin Harun, I., Jalonen, R., Kanashiro, M., Krisnawati, H., Kshatriya, Mrigesh, Lincoln, P., Mazzei, L., Medjibe, V., Nasi, Robert, D'Oliveira, M.V.N., Oliveira, L.C. de, Picard, N., Pietsch, S., Pinard, M.A., Priyadi, H., Putz, F.E., Rodney, K., Rossi, V., Roopsind, A., Ruschel, A.R., Shari, N.H.Z., Rodrigues de Souza, C., Susanty, F.H., Sotta, E.D., Toledo, M., Vidal, E., West, T.A.P., Wortel, V., Yamada, T.

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Asynchronous carbon sink saturation in African and Amazonian tropical forests by Hubau, W., Lewis, S.L., Phillips, Oliver L., Affum-Baffoe, K., Beeckman, H., Cuní-Sanchez, A., Daniels, A.K., Ewango, C.E.N., Fauset, S., Mukinzi, J.M., Sheil, D., Sonké, B., Sullivan, M.J.P., Sunderland, T.C.H., Taedoumg, H.E., Thomas, S.C., White, Lee J.T., Abernethy, K.A., Adu-Bredu, S., Amani, C.A., Baker, T.R., Banin, Lindsay F., Baya, F., Begne, S.K., Bennett, A.C., Benedet, F., Bitariho, R., Bocko, Y.E., Boeckx, P., Boundja, P., Brienen, R.J.W., Brncic, T., Chezeaux, E., Chuyong, G.B., Clark, C.J., Collins, M., Comiskey, J.A., Coomes, David A., Dargie, G.C., Haulleville, T. de, Kamdem, M.N.D., Doucet, J.-L., Esquivel-Muelbert, A., Feldpausch, T.R., Fofanah, A., Foli, E.G., Gilpin, M., Gloor, E., Gonmadje, C., Gourlet-Fleury, S., Hall, J.S., Hamilton, A.C., Harris, D.J., Hart, T.B., Hockemba, M.B.N., Hladik, A., Ifo, S.A., Jeffery, K.J., Jucker, T., Yakusu, E.K., Kearsley, E., Kenfack, D., Koch, A., Leal, M.E., Levesley, A., Lindsell, J.A., Lisingo, J., López Gonzalez, G., Lovett, J.C., Makana, J.-R., Malhi, Y., Marshall, A.R., Martin, J., Martin, E.H., Mbayu, F.M., Medjibe, V.P., Mihindou, V., Mitchard, E.T.A., Moore, S., Munishi, P.K.T., Bengone, N.N., Ojo, L., Ondo, F.E., Peh, K.S.H., Pickavance, G.C., Poulsen, A.D., Poulsen, J.R., Qie, L., Reitsma, J., Rovero, F., Swaine, M.D., Talbot, J., Taplin, J., Taylor, D.M., Thomas, D.W., Toirambe, B., Mukendi, J.T., Tuagben, D., Umunay, P.M., Heijden, G.M.F. van der, Verbeeck, H., Vleminckx, J., Willcock, S., Wöll, H., Woods, J.T., Zemagho, Lise

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Bicarbonate blocks iron translocation from cotyledons inducing iron stress responses in Citrus roots by Martínez-Cuenca, Mary-Rus, Legaz, Francisco, Forner-Giner, María A., Primo-Millo, Eduardo, Iglesias, Domingo J.

“…Finally, the effect of Fe resupply on the above responses was tested in the presence and absence of HCO3- (+Fe+Bic or +Fe, respectively). …”
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Nicotianamine-chelated iron positively affects iron status, intestinal morphology and microbial populations in vivo (Gallus gallus) by Beasley, Jesse T., Johnson, Alexander A. T., Kolba, Nikolai, Bonneau, Julien P., Glahn, Raymond P., Ozeri, Lital, Koren, Omry, Tako, Elad

“…Wheat flour iron (Fe) fortification is mandatory in 75 countries worldwide yet many Fe fortificants, such as Fe-ethylenediaminetetraacetate (EDTA), result in unwanted sensory properties and/or gastrointestinal dysfunction and dysbiosis. …”
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Genome‐wide association study of grain iron and zinc concentration in common bean (Phaseolus vulgaris) by Gelaw, Yonas Moges, Eleblu, John S. Y., Ofori, Kwadwo, Fenta, Berhanu Amsalu, Mukankusi, Clare, Offei, Samuel Kwame

“…The study revealed that 43 quantitative trait loci (QTLs) were associated with grain Fe and Zn concentration. Five quantitative trait nucleotides (QTNs), that is, QTN Fe_1.1, QTN Fe_6.3, QTN Fe_6.5, QTN Fe_10.3 and QTN Fe_11.6 were detected both at Haramaya and Melkassa locations. …”
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Effects of high levels of zinc and manganese ions on Strategy I responses to iron deficiency in citrus by Martínez-Cuenca, Mary-Rus, Quinones, Ana, Iglesias, Domingo J., Forner-Giner, María A., Primo-Millo, Eduardo, Legaz, Francisco

“…Nutrient solutions without iron, zinc or manganese were prepared for assays and then combinations of Fe-EDDHA, ZnSO4 center dot 7H(2)O or MnSO4 center dot H2O were added to obtain the following media: -Fe-Zn, +Fe-Zn, -Fe+Zn, +Fe+Zn, -Fe-Mn, +Fe-Mn, -Fe+Mn and +Fe+Mn. …”
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Elemental composition of the rice plant as affected by iron toxicity under field conditions by Sahrawat, K.L.

“…Iron (Fe) toxicity is a major nutrient disorder affecting the production of wetland rice in the humid zone of West Africa. …”
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Felint morbillivirus – ett nyupptäckt virus med potentiell koppling till kronisk njursjukdom hos katt by Ayata Karbin, Hanna

“…Felint morbillivirus (FeMV) upptäcktes i Hongkong 2012 och är det första morbillivirus som påvisats hos tamkatter. …”
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Iron toxicity tolerance in rice: Roles of Auxins and Gibberellins by Daramola, O.S., Shaibu, A.A., Semwal, V.K.

“…In the present review, we discuss the conditions that enhances Fe toxicity in rice, effects of Fe toxicity in rice and tolerance strategies to Fe toxicity in rice. …”
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Biofortified black beans in a maize and bean diet provide more bioavailable iron to piglets than standard black beans by Tako, E, Laparra, JM, Glahn, Raymond P., Welch, R.M., Lei, XG, Beebe, Stephen E., Miller, DD

“…Our objective was to compare the capacities of biofortified and standard black beans (Phaseolus vulgaris L.) to deliver iron (Fe) for hemoglobin (Hb) synthesis. Two lines of black beans, one standard and the other biofortified (high) in Fe (71 and 106 microg Fe/g, respectively), were used. …”
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Identification of genomic loci regulating grain iron content in aus rice under two irrigation management systems by Talukdar, Partha, Travis, Anthony J., Hossain, Mahmud, Islam, Mohammed Rafiqul, Norton, Gareth J., Price, Adam H.

“…Iron (Fe) deficiency is one of the common causes of anaemia in humans. …”
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The effects of foliar fertilization with iron sulfate in chlorotic leaves are limited to the treated area. A study with peach trees (Prunus persica L. Batsch) grown in the field an... by El-Jendoubi, Hamdi, Vazquez, Saul, Calatayud, Ángeles, Vavpetic, Primoz, Vogel-Mikus, Katarina, Pelicon, Primoz, Abadia, Javier, Abadia, Anunciacion, Morales, Fermin

“…Crop Fe deficiency is a worldwide problem. The aim of this study was to assess the effects of foliar Fe applications in two species grown in different environments: peach (Prunus persica L. …”
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Genotype × environment interactions for grain iron and zinc content in rice by Naik, Shilpa M., Raman, Anitha K., Nagamallika, Minnuru, Venkateshwarlu, Challa, Singh, Suresh Prasad, Kumar, Santosh, Singh, Shravan Kumar, Tomizuddin Ahmed, Das, Sankar Prasad, Prasad, Krishna, Izhar, Tajwar, Mandal, Nimmai P., Singh, Nitendra Kumar, Yadav, Shailesh, Reinke, Russell, Swamy, Ballagere Prabhu Mallikarjuna, Virk, Parminder, Kumar, Arvind

“…Promising breeding lines with higher Zn or Fe content, or both, were: IR 82475‐110‐2‐2‐1‐2 (Zn: 20.24–37.33 mg kg−1; Fe: 7.47–14.65 mg kg−1); IR 83294‐66‐2‐2‐3‐2 (Zn: 22–37–41.97 mg kg−1; Fe: 9.43–17.16); IR 83668‐35‐2‐2‐2 (Zn: 27.15–42.73 mg kg−1; Fe: 6.01–14.71); IR 68144‐2B‐2‐2‐3‐1‐166 (Zn: 23.53–40.30 mg kg−1; Fe: 10.53–17.80 mg kg−1) and RP Bio 5478‐185M7 (Zn: 22.60–40.07 mg kg−1; Fe: 7.64–14.73 mg kg−1). …”
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Felint leukemivirus - hur påverkas smittade katter? by Gräsman, Victoria

“…Felint leukemivirus (FeLV) är ett gammaretrovirus som drabbar katter över hela världen. …”

Iron Bioavailability Studies of the First Generation of Iron-Biofortified Beans Released in Rwanda by Glahn, Raymond P., Tako, Elad, Hart, Jonathan J., Haas, Jere D., Lung'aho, Mercy G., Beebe, Stephen E.

“…This paper represents a series of in vitro iron (Fe) bioavailability experiments, Fe content analysis and polyphenolic profile of the first generation of Fe biofortified beans (Phaseolus vulgaris) selected for human trials in Rwanda and released to farmers of that region. …”
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Maize-grain zinc and iron concentrations as influenced by agronomic management and biophysical factors: a meta-analysis by Kihara, Job, Sileshi, Gudeta W., Bolo, Peter, Mutambu, Dominic, Senthilkumar, Kalimuthu, Sila, Andrew, Devkota, Mina, Saito, Kazuki

“…Human Zn and Fe deficiencies can be reduced through agronomic biofortification, but information on factors influencing maize grain-Zn and -Fe levels remain scanty. …”
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Tolerance of iron-deficient and -toxic soil conditions in rice by Mahender, Anumalla, Swamy, B.P. Mallikarjuna, Anandan, Annamalai, Ali, Jauhar

“…Iron (Fe) deficiency and toxicity are the most widely prevalent soil-related micronutrient disorders in rice (Oryza sativa L.). …”
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A model to incorporate the bHLH transcription factor OsIRO3 within the rice iron homeostasis regulatory network by Carey-Fung, Oscar, O'Brien, Martin, Beasley, Jesse T., Johnson, Alexander A. T.

“…Iron (Fe) homeostasis in plants is governed by a complex network of regulatory elements and transcription factors (TFs), as both Fe toxicity and deficiency negatively impact plant growth and physiology. …”
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Iron biofortification in rice: An update on quantitative trait loci and candidate genes by Swamy, B.P. Mallikarjuna, Marathi, Balram, Ribeiro-Barros, Ana I. F., Calayugan, Mark Ian C., Ricachenevsky, Felipe Klein

“…Rice is the most versatile model for cereals and also an economically relevant food crop; as a result, it is the most suitable species for molecular characterization of Fe homeostasis and biofortification. Recently there have been significant efforts to dissect genes and quantitative trait loci (QTL) associated with Fe translocation into rice grains; such information is highly useful for Fe biofortification of cereals but very limited in other species, such as maize (Zea mays) and wheat (Triticum aestivum). …”
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