Productos de la asimilación del nitrato se depositan en las plantas como proteínas de almacenamiento
Products of nitrate assimilation are deposited in plants as storage proteins
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Cordero, C., & Jarma Orozco, A. D. jesus. (2011). Productos de la asimilación del nitrato se depositan en las plantas como proteínas de almacenamiento. Temas Agrarios, 16(1), 9-22. https://doi.org/10.21897/rta.v16i1.680
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- Bethke, P., Swanson, S., Hillmer, S. y Jones, R. 1998. From Storage Compartment to Lytic Organelle: The Metamorphosis of the Aleurone Protein Storage Vacuole. Plant Physiology. 82: 399-412.
- Buyukpamukcu, E., Goodall, D., Hansen, C., Keely, B., Kochhar, S. y Wille, H. 2001. Characterization of peptides formed during fermentation of cocoa bean. J. Agric. Food Chem. 49 (12): 5822-5827.
- Chrispeels, M.J. y Herman, E. M. 2000. Endoplasmic Reticulum-Derived Compartments Function in Storage and as Mediators of Vacuolar Remodeling via a New Type of Organelle, Precursor Protease Vesicles. Plant Physiology. 123 (4):1227-1234.
- Chung, T., Kim, C., Nguyen, H. N., Meeley, R. B. y Larkins, B. A. 2007. The Maize Zmsmu2 Gene Encodes a Putative RNA-Splicing Factor That Affects Protein Synthesis and RNA Processing during Endosperm Development. Plant Physiology. 144 (2):821-835.
- Colin, J. 2009. Composición del inóculo (Lb. plantarum, Lb, brevis y Lb. sanfranciscensis) y su efecto en las propiedades viscoelasticas de las masas agrias. Tesis de grado de Maestría. Instituto politécnico nacional CICATAIPN. Mexico D.F. Pag 59.
- Coria, N.A., Perez, A., Sarquís, J.I., Cantú, I., Gonzalez, H. y Gómez, M.V. 2004. Regeneración de la planta de papa (Solanum tuberosum l) in vitro a partir del estolón. Ciencia UANL. VII (003): 361-370.
- Cossegal, M., Chambrier, P., Mbelo, S., Balzergue, S., Martin-Magniette, M.L., Moing, A., Deborde, C., Guyon, V ., Perez, P. y Rogowsky, P. 2008. Transcriptional and Metabolic Adjustments in ADPGlucose Pyrophosphorylase-Deficient bt2 Maize Kernels. Plant Physiology. 146 (4): 1553-1570.
- Dam, S., Laursen, B. S., Ørnfelt, J.H., Jochimsen, B., Stærfeldt, H.H., Friis, C., Nielsen, K., Goffard, N., Besenbacher, S., Krusell, L., Sato, S., Tabata, S., Thøgersen, I.B., Enghild, J. J., y Stougaard, J. 2009. The Proteome of Seed Development in the Model Legume Lotus japonicus. Plant Physiology. 149 (3):1325-1340.
- Díaz, P., Dalla, M., Vázquez, D. y Castro, M. 2006. Elementos de Análisis Cualitativo y Cuantitativo en Proteínas del Gluten de Trigo. Agricultura Técnica. 66 (4):360-369.
- Espitia, E., Martínez, E., Peña, R.J., Villaseñor, H. E., Huerta, J. 2008. Polimosrfismo de gluteninas de alto peso molecular y su relación con trigos harineros para temporal. Agricultura técnica en México. 34(001): 57-67.
- Ferreira, M. y Correa, E. M. 2004. Recognition of n-acetylglucosamine (GlyNac) and poly-n-acetyllactosamine residues in vessels of the rat pineal gland. Int. J. Morphol. 22 (4).
- Gaur, V., Qureshi, I. A., Singh, A., Chanana, V. y Salunke, D. M. 2010. Crystal Structure and Functional Insights of Hemopexin Fold Protein from Grass Pea. Plant Physiology. 152 (4):1842-1850.
- Gavazzi, F., Lazzari, B., Ciceri, P., Gianazza, E. y Viotti, A. 2007. Wild-Type Opaque and Defective opaque Polypeptides Form Complexes in Maize Endosperm Cells and Bind the Opaque2-Zein Target Site. Plant Physiology. 145 (3):933-945.
- Gianibelli, M.C., Larroque, O.R., Macritchie, F. and Wrigley, C.W. 2001. Biochemical, genetic, and molecular characterization of wheat endosperm proteins. AACC, Inc. Disponible en http://www.aaccnet.org/ cerealchemistry/freearticle/gianibelli. pdf. [1 Septiembre 2010].
- Heldt, H. y Heldt F. 2005. Plant Biochemistry. Hans. 2005 Editorial Coordinator Kelly Sonnack. p 353-360. Herman, E. y Larkins, B. 1999. Protein Storage Bodies and Vacuoles Climate Stress Laboratory. The Plant Cell. 11 (4): 601– 614.
- Hernández, P., Perez, E., Martínez, L., Ortiz, B. y Martínez, G. 2005. Las lectinas vegetales como modelo de estudio de las interacciones proteina carbohidrato. Revista de educación bioquimica. 24 (001):21-27.
- Jerkovic, A., Kriegel, A. M., Bradner, J.R., Atwell, B. J., Roberts, T.H. y Willows, R.D. 2010. Strategic Distribution of Protective Proteins within Bran Layers of Wheat Protects the Nutrient-Rich Endosperm. Plant Physiology. 152 (3):1459-1470.
- Jiang, L., Phillips, T., Hamm, C., Drozdowicz, Y., Rea, P., Maeshima, M., Rogers, S. y Rogers, J. 2001. The protein storage vacuole: a unique compound organelle. The Journal of Cell Biology. 155 (6):991- 1002.
- Jobet, C. y Hewstone, C. 2003. Kumpa-inia: nueva variedad de trigo invernal para el sur de Chile. Agricultura Técnica. 63(1): 81-86.
- Kawakatsu, T., Hirose, S., Yasuda, H. y Takaiwa, F. 2010. Reducing Rice Seed Storage Protein Accumulation Leads to Changes in Nutrient Quality and Storage Organelle Formation. Plant Physiology. 154 (4):1842-1854.
- Kawaura, K., Mochida, K. y Ogihara, Y. 2005. Expression Profile of Two StorageProtein Gene Families in Hexaploid Wheat Revealed by Large-Scale Analysis of Expressed Sequence Tags. Plant Physiology. 139 (4):1870-1880.
- Lancien, M., Gadal, P. y Hodges, M. 2000. Enzyme Redundancy and the Importance of 2-Oxoglutarate in Higher Plant Ammonium Assimilation. Plant Physiology. 123 (3):817-824.
- Liu, Y., Ahn, J., Datta, S., Salzman, R.A., Moon, J., Huyghues-Despointes, B., Pittendrigh, B., Murdock, L.L., Koiwa, H. y Zhu-Salzman, K. 2005. Arabidopsis Vegetative Storage Protein Is an Anti-Insect Acid Phosphatase. Plant Physiology. 139: 1545-1556.
- López, B.L., Marcelo, L., Vidueiros, S.M., Pallaro, A., Valencia, M.E. 2010. Determinación del contenido de gliadinas en alimentos elaborados con amaranto, quínoa y/o chía. Revista Chilena de Nutrición. 37(1):80-86.
- Loponen, J., Sontag-Strohm, T., Venalainen, J. y Salovaara, H. 2007. Prolamin hydrolysis in wheat sourdoughs with differing proteolytic activities. Journal of Agricultural and Food Chemistry. 55 (3):978-984.
- Martínez, E., Espitia, E., Benítez, I., Peña, R. J., Santacruz, A. y Villaseñor, H. E. 2007. El complejo Gli-1/Glu-3 y las propiedades reológicas y volumen de pan de trigos harineros. Revista Fitotecnia Mexicana. 30(002):167-172.
- Mechin, V., Thevenot, C., Guilloux, M.L., Prioul, J.L. y Damerval, C. 2007. Developmental Analysis of Maize Endosperm Proteome Suggests a Pivotal Role for Pyruvate Orthophosphate Dikinase. Plant Physiology. 143 (3):1203–1219.
- Molina, M.I., Otegui, M. y Petruccelli, S. 2006. Sunflower storage proteins are transported in dense vesicles that contain proteins homologous to the pumpkin vacuolar sorting receptor 72. Electronic Journal of Biotechnology. 9 (3):326-330.
- Müntz, K., Belozersky, M., Dunaevsky, Y., Schlereth, A. y Tiedemann, J. 2001. Stored proteinases and the initiation of storage protein mobilization in seeds during germination and seedling growth. Journal of Experimental Botany. 52 (362): 1741-1752.
- Müntz, K. 2007. Protein dynamics and proteolysis in plant vacuoles. Journal of Experimental Botany. 58 (10):2391-2407.
- Olán, M., Espitia, E., Molina, J. D., Peña, R. J., SantaCruz, A. y Villaseñor, H. E. 2006. Efecto de diferentes subunidades de gluteninas APM sobre la calidad panadera en trigos harineros mexicanos. Revista fitotecnia mexicana. 29 (004): 291-297.
- Olbrich, A., Hillmer, S., Hinz, G., Oliviusson, P. y Robinson, D. G. 2007. Newly Formed Vacuoles in Root Meristems of Barley and Pea Seedlings Have Characteristics of Both Protein Storage and Lytic Vacuoles. Plant Physiology. 145 (4):1383-1394.
- Ortiz, L., Maldonado, H., Parra, P. y Graziani, L. 2006. Caracterización electroforética de las globulinas del grano fermentado de tres tipos de cacao. Interciencia. 31(006):441-445.
- Osborne, T. 1924. The Vegetable Proteins. Longmans, Green and Co, London, p125.
- Park, M., Kim, S., Vitale, A. y Hwang, I. 2004. Identification of the Protein Storage Vacuole and Protein Targeting to the Vacuole in Leaf Cells of Three Plant Species. Plant Physiology. 134 (2):625- 639.
- Peralta, M. E. 2004. Caracterización bioquimica de las proteinas de la semillas de Jatropha Curcas L. Tesis Maestro en ciencias, Instituto Politécnico Nacional, Yautepec Morelos.
- Pereira, M., Rodrigues, I., Grossi-de-Sa, M. F. y Xavier-Filho, J. 2000. Do Legume Storage Proteins Play a Role in Defending Seeds against Bruchids?. Plant Physiology. 124 (2):515-522.
- Peumans, W. J., Proost, P., Swennen, R.L. y Van Damme, J.M. 2002. The Abundant Class III Chitinase Homolog in Young Developing Banana Fruits Behaves as a Transient Vegetative Storage Protein and Most Probably Serves as an Important Supply of Amino Acids for the Synthesis of Ripening-Associated Proteins. Plant Physiology. 130 (2):1063-1072.
- Ramos, O.J. 2009. Detección de péptidos de lupino similares a lunasina de soya. Tesis Maestro en Ciencias. Instituto Politécnico Nacional, Yautepec Morelos.
- Rocha, G. F., Fernández, G. y Parisi, M.G. 2010. Estudios de Caracterización Cinética y Fisicoquímica de una Proteinasa Aspártica Aislada de Frutos Maduros de Salpichroa origanifolia. Información Tecnológica. 21 (2):21-28.
- Rolletschek, H., Hosein, F., Miranda, M., Heim, U., Gotz, K. P., Schlereth, A., Borisjuk, L., Saalbach, I., Wobus, U. y Weber, H. 2005. Ectopic Expression of an Amino Acid Transporter (VfAAP1) in Seeds of Vicia narbonensis and Pea Increases Storage Proteins. Plant Physiology. 137:1236-1249.
- Sabelli, P. A. y Larkins, B.A. 2009. The Development of Endosperm in Grasses. Plant Physiology. 149 (1):14-26.
- Sales MP, Macedo MLR, Xavier-Filho J. 1992. Digestibility of cowpea (Vigna Unguiculata) vicilins by pepsin, papain and bruchid midgut proteinases. Comparative Biochemistry and Physiology - Part B. 103 (4):945-950.
- Scott, N. 2008. Domain duplication, Darwinian selection and the origins of the seed storage globulins. Thesis Master of Science, Brigham Young University. Provo Utah. Thompson, R., Burstin, J. y Gallardo, K. 2009. Post-Genomics Studies of Developmental Processes in Legume Seeds. Plant Physiology. 151 (3):1023-1029.
- Torres, E., Gonzalez-Melendi, P., Stoger, E., Shaw, P., Twyman, R.M., Nicholson, L., Vaquero, C., Fischer, R., Christou, P. y Perrin, Y. 2001. Native and Artificial Reticuloplasmins Co-Accumulate in Distinct Domains of the Endoplasmic Reticulum and in Post-Endoplasmic Reticulum Compartments. Plant Physiology. 127 (3):1212-1223.
- Wieser, H. 2007. Chemistry of Gluten proteins. Food Microbiology. 24 (2): 115-119.
- Wu, Y. y Messing, J. 2010. RNA InterferenceMediated Change in Protein Body Morphology and Seed Opacity through Loss of Different Zein Proteins. Plant Physiology. 153 (1):337-347.
- Yamakawa, H., Hirose, T., Kuroda, M. y Yamaguchi, T. 2007. Comprehensive Expression Profiling of Rice Grain Filling-Related Genes under High Temperature Using DNA Microarray. Plant Physiology. 144 (1):258-277.
- Zerené, M., Granger, D., Prehn, D., y Hinrichsen, P. 2000. Secuencias de microsatélites asociadas a genes de proteínas de reserva en variedades chilenas de trigo harinero: descripción y posible uso como marcadores de calidad panadera. Agricultura Técnica. 60 (1):14-31.
- Zhu, B. y Coleman, G. 2001. PhytochromeMediated Photoperiod Perception, Shoot Growth, Glutamine, Calcium, and Protein Phosphorylation Influence the Activity of the Poplar Bark Storage Protein Gene Promoter (bspA).Plant Physiology. 126 (1):342-351.
- Zhu-Salzman, K., Luthe, D.S. y Felton, G. W. 2008. Arthropod-Inducible Proteins: Broad Spectrum Defenses against Multiple Herbivores. Plant Physiology. 146 (3):852-858.