IBT-UNAM : Dra. Alejandra Alicia Covarrubias Robles
Dra. Alejandra Alicia Covarrubias Robles Grupo
Departamento de Biología Molecular de Plantas
Líneas de investigación
email: crobles @ibt.unam.mx
Teléfonos
Oficina +52 (777) 329-1643 red UNAM 27643 +52 (777) 311-4900 ext 293 Laboratorio +52 (777) 329-1668 red UNAM 27668 +52 (777) 311-4900 ext 293
Alejandra A. Covarrubias Robles
es Investigador Titular "C" del Departamento de Biología Molecular del Instituto de Biotecnología
de la Universidad Nacional Autónoma de México. Obtuvo con honores el título de Química Farmacobióloga (1975),
y el Doctorado en Genética Molecular (1983), en la UNAM. Su área de trabajo ha estado encaminada al estudio de
las respuestas de las plantas a la limitación de agua, utilizando enfoques bioquímicos, genéticos, moleculares y celulares.
Ha realizado estancia en el extranjero, entre las que destacan en la Universidad de California en San Francisco,
California (EUA) y en la Universidad de Stanford, California (EUA).
Entre otros reconocimientos, recibió menciones honoríficas
en los tres niveles de los grados obtenidos, reconocimiento como mejor estudiante del Instituto Mexicano de Cultura-CONACyT y
las medallas Gabino Barreda en Maestría y Doctorado. También ha sido distinguida con el nivel III del Sistema Nacional de
nvestigadores desde el 2003 a la fecha, con la Beca de la Fundación Rockefeller y con el Premio Sor Juana Inés de la Cruz
que otorga la UNAM. Fue distinguida con una nominación internacional para ser miembro de la American Association for the
Advancement of Science (AAAS) y ha participado en los Comités Editoriales de revistas científicas de alto impacto en su área.
Es miembro de la Academia Mexicana de Ciencias y de la Academia de Ciencias de Morelos. Ha participado en más de 80 publicaciones,
incluyendo artículos científicos y capítulos en libros, y ha dirigido múltiples tesis a nivel de licenciatura, maestría y doctorado.
Ha sido invitada como conferencista en congresos, simposios y mesas redondas en reuniones científicas internacionales y nacionales.
- Licenciatura: Químico Farmaceutico Biologo, Fac. de Química-UNAM (1975)
Fellow de la American Association for the Advancement of Science (AAAS) (2003)
Estudiantes André Jauma Porcel
Biol. Victor Miguel Palomar "Estudio de la participación de la vía RdDM en respuesta a estrés en plantas."
M.C. Ana Violeta Salazar
Biol. Rosa Brianda De la Sancha
M.C. Inti Arroyo
M.C. Ingrid González
M.C. Paulette Sofía Romero
Laura Verónica Martínez
Q.F.B. Omar Guillermo Rosas
M.C. Coral Martinez
M.C. David Felipe Rendon
Publicaciones recientes
Battaglia,M.E. Martinez-Silva,A.V. Olvera-Carrillo,Y. Dinkova,T.D. Covarrubias,A.A.
2021. Translational enhancement conferred by the 3' untranslated region of a transcript encoding a group 6 late embryogenesis abundant protein Environmental And Experimental Botany, 182, 104310.
Palomar,V.M. Garciarrubio,A. Garay-Arroyo,A. Martinez-Martinez,C. Rosas-Bringas,O. Reyes,J.L. Covarrubias,A.A.
2021. The canonical RdDM pathway mediates the control of seed germination timing under salinity Plant Journal, 105, 691-707.
De La Rosa,C. Lozano,L. Castillo-Ramirez,S. Covarrubias,A.A. Reyes,J.L.
2020. Origin and evolutionary dynamics of the miR2119 and ADH1 regulatory module in Legumes Genome Biology and Evolution, 12, 2355-2369.
Godinez-Vidal,D. Lopez-Leal,G. Covarrubias,A.A. Reyes,J.L.
2020. Early events leading to water deficit responses in the liverwort Marchantia polymorpha Environmental And Experimental Botany, 178, .
Isidra-Arellano,M.C. Pozas-Rodriguez,E.A. Reyero-Saavedra,M.D.R. Arroyo-Canales,J. Ferrer-Orgaz,S. Sanchez-Correa,M.D.S. Cardenas,L. Covarrubias,A.A. Valdes-Lopez,O.
2020. Inhibition of Legume Nodulation by Pi Deficiency is Dependent on the Autoregulation Of Nodulation (AON) Pathway Plant Journal, 103, 1125-1139.
Covarrubias,A.A. Romero-Perez,P.S. Cuevas-Velazquez,C.L. Rendon-Luna,D.F.
2020. The functional diversity of structural disorder in plant proteins Archives of Biochemistry and Biophysics, 680, 108229.
Acosta-Maspons,A. Gonzalez-Lemes,I. Covarrubias,A.A.
2019. Improved protocol for isolation of high-quality total RNA from different organs of Phaseolus vulgaris L Biotechniques, 66, 96-98.
De La Rosa,C. Covarrubias,A.A. Reyes,J.L.
2019. A dicistronic precursor encoding miR398 and the legume-specific miR2119 co-regulates CSD1 and ADH1 mRNAs in response to water deficit Plant Cell And Environment, 42, 133-144.
Gente,R. Rehn,A. Probst,T. Stubling,E.M. Camus,E.C. Covarrubias,A.A. Balzer,J.C. Koch,M.
2018. Outdoor Measurements of Leaf Water Content Using THz Quasi Time-Domain Spectroscopy Journal of Infrared, Millimeter, and Terahertz Waves, 39, 943-948.
French-Pacheco,L. Cuevas-Velazquez,C.L. Rivillas-Acevedo,L. Covarrubias,A.A. Amero,C.
2018. Metal-binding polymorphism in late embryogenesis abundant protein AtLEA4-5, an intrinsically disordered protein PeerJ., 6, e4930.
Perez-Morales,M.B. Covarrubias,A.A. Reyes,J.L.
2017. The key role of small RNAs in the making of a leaf Indian Journal of Plant Physiology, 22, 393-400.
Reyero-Saavedra,M.D.R. Qiao,Z. Sanchez-Correa,M.D.S. Diaz-Pineda,M.E. Reyes,J.L. Covarrubias,A.A. Libault,M. Valdes-Lopez,O.
2017. Gene Silencing of Argonaute5 Negatively Affects the Establishment of the Legume-Rhizobia Symbiosis Genes (Basel), 8, .
Cuevas-Velazquez,C.L. Reyes,J.L. Covarrubias,A.A.
2017. Group 4 Late Embryogenesis Abundant Proteins as a Model to Study Intrinsically Disordered Proteins in Plants Plant Signaling and Behavior, 12, e1343777.
Covarrubias,A.A. Cuevas-Velazquez,C.L. Romero-Perez,P.S. Rendon-Luna,D.F. Chater,C.C.C.
2017. Structural disorder in plant proteins: where plasticity meets sessility Cellular and Molecular Life Sciences, 74, 3119-3147.
Sosa-Valencia,G. Romero-Perez,P.S. Palomar,M. Covarrubias,A.A. Reyes,J.L.
2017. Insights into the function of the phasiRNA-triggering miR1514 in response to stress in legumes Plant Signaling and Behavior, 12, 84724.
Sosa-Valencia,G. Palomar,M. Covarrubias,A.A. Reyes,J.L.
2017. The Legume miR1514a modulates a NAC transcription factor transcript to trigger phasiRNA formation in response to drought Journal of Experimental Botany, 68, 2013-2026.
Cuevas-Velazquez,C.L. Saab-Rincon,G. Reyes,J.L. Covarrubias,A.A.
2016. The unstructured N-terminal region of Arabidopsis group 4 Late Embryogenesis Abundant Proteins (LEA) is required for folding and for chaperone-like activity under water deficit Journal of Biological Chemistry, 291, 10893-10903.
Sanchez-Diaz,I. Rosales-Bravo,F. Reyes-Taboada,J.L. Covarrubias,A.A. Narvaez-Padilla,V. Reynaud,E.
2015. The Esg Gene Is Involved in Nicotine Sensitivity in Drosophila melanogaster PLoS ONE, 10, e0133956.
Covarrubias,A.A. Reyes,J.L. Battaglia,M. Rosales,M.A. Cuellar,S. Contreras,C. Rivera,L. De La Rosa,C. Sosa,G. Rabanal,F. Velarde,A. Campos,F. Ocampo,E. Solorzano,R.M.
2014. The response to water deficit in Phaseolus vulgaris Legume Perspectives, 2, 38-41.
Cuevas-Velazquez,C.L. Rendon-Luna,D.F. Covarrubias,A.A.
2014. Dissecting the cryoprotection mechanisms for dehydrins Frontiers in Plant Science, 5, 583.
Rivera-Najera,L.Y. Saab-Rincon,G. Battaglia,M. Amero,C. Pulido,N.O. Garcia-Hernandez,E. Solorzano,R.M. Reyes,J.L. Covarrubias,A.A.
2014. A Group 6 Late Embryogenesis Abundant Protein from Common Bean is a Disordered Protein with Extended Helical Structure and Oligomer-Forming Properties Journal of Biological Chemistry, 289, 31995-32009.
Rodriguez-Valentin,R. Campos,F. Battaglia,M. Solorzano,R.M. Rosales,M.A. Covarrubias,A.A.
2014. Group 6 Late Embryogenesis Abundant (LEA) Proteins in Monocotyledonous Plants: Genomic Organization and Transcript Accumulation Patterns in Response to Stress in Oryza sativa Plant Molecular Biology Reporter, 32, 198-208.
Castro-Camus,E. Palomar,M. Covarrubias,A.A.
2013. Leaf water dynamics of Arabidopsis thaliana monitored in-vivo using terahertz time-domain spectroscopy Scientific Reports, 3, 2910.
Campos,F. Cuevas-Velazquez,C. Fares,M.A. Reyes,J.L. Covarrubias,A.A.
2013. Group 1 LEA proteins, an ancestral plant protein group, are also present in other eukaryotes, and in the archeae and bacteria domains Molecular Genetics and Genomics, 288, 503-517.
Battaglia,M. Covarrubias,A.A.
2013. Late Embryogenesis Abundant (LEA) proteins in legumes Frontiers in Plant Science, 4, 190.
Rosales,M.A. Cuellar-Ortiz,S.M. Arrieta-Montiel,M.D. Acosta-Gallegos,J. Covarrubias,A.A.
2013. Physiological traits related to terminal drought resistance in common bean (Phaseolus vulgaris L.) Journal of the Science of Food and Agriculture, 93, 324-331.
Contreras-Cubas,C. Palomar,M. Arteaga-Vazquez,M. Reyes,J.L. Covarrubias,A.A.
2012. Non-coding RNAs in the plant response to abiotic stress Planta, 236, 943-958.
Rosales,M.A. Ocampo,E. Rodriguez-Valentin,R. Olvera-Carrillo,Y. Acosta-Gallegos,J. Covarrubias,A.A.
2012. Physiological analysis of common bean (Phaseolus vulgaris L.) cultivars uncovers characteristics related to terminal drought resistance Plant Physiology And Biochemistry, 56, 24-34.
Pelaez,P. Trejo,M.S. Iniguez,L.P. Estrada-Navarrete,G. Covarrubias,A.A. Reyes,J.L. Sanchez,F.
2012. Identification and characterization of microRNAs in Phaseolus vulgaris by high-throughput sequencing BMC Genomics, 13, 83.
Contreras-Cubas,C. Rabanal,F.A. Arenas-Huertero,C. Ortiz,M.A. Covarrubias,A.A. Reyes,J.L.
2012. The Phaseolus vulgaris miR159a precursor encodes a second differentially expressed microRNA Plant Molecular Biology, 80, 103-115.
Campos,F. Guillen,G. Reyes,J.L. Covarrubias,A.A.
2011. A general method of protein purification for recombinant unstructured non-acidic proteins Protein Expression and Purification, 80, 47-51.
Olvera-Carrillo,Y. Reyes,J.L. Covarrubias,A.A.
2011. Late Embryogenesis Abundant proteins: Versatile players in the plant adaptation to water limiting environments Plant Signaling and Behavior, 6, 586-589.
Olvera-Carrillo,Y. Campos,F. Reyes,J.L. Garciarrubio,A. Covarrubias,A.A.
2010. Functional Analysis of the Group 4 Late Embryogenesis Abundant proteins reveals their relevance in the adaptive response during water deficit in Arabidopsis thaliana Plant Physiology, 154, 373-390.
Covarrubias,A.A. Reyes,J.L.
2010. Post-transcriptional gene regulation of salinity and drought responses by plant microRNAs Plant Cell And Environment, 33, 481-489.
Flores-Jasso,C.F. Arenas-Huertero,C. Reyes,J.L. Contreras-Cubas,C. Covarrubias,A. Vaca,L.
2009. First step in pre-miRNAs processing by human Dicer Acta Pharmacologica Sinica, 30, 1177-1185.
Arenas-Huertero,C. Perez,B. Rabanal,F. Blanco-Melo,D. De La Rosa,C. Estrada-Navarrete,G. Sanchez,F. Covarrubias,A.A. Reyes,J.L.
2009. Conserved and novel miRNAs in the legume Phaseolus vulgaris in response to stress Plant Molecular Biology, 70, 385-401.
Arora,R. Peng,Y.H. Karlson,D. Reyes,J.L. Covarrubias,A.A.
2008. Physiology of cold-hardening in Rhododendron: role of a dehydrin protein from R. catawbiense (RcDhn5) in cryoprotection and improving freezing tolerance American Rhododendron Society Journal, 62, 153-158.
Peng,Y. Reyes,J.L. Wei,H. Yang,Y. Karlson,D. Covarrubias,A.A. Krebs,S.L. Fessehaie,A. Arora,R.
2008. RcDhn5, a cold acclimation-responsive dehydrin from Rhododendron catawbiense rescues enzyme activity from dehydration effects in vitro and enhances freezing tolerance in RcDhn5-overexpressing Arabidopsis plants Physiologia Plantarum, 134, 583-597.
Battaglia,M. Olvera-Carrillo,Y. Garciarrubio,A. Campos,F. Covarrubias,A.A.
2008. The Enigmatic LEA Proteins and Other Hydrophilins Plant Physiology, 148, 6-24.
Reyes,J.L. Campos,F. Wei,H. Arora,R. Yang,Y. Karlson,D.T. Covarrubias,A.A.
2008. Functional Dissection of Hydrophilins during in vitro Freeze Protection Plant Cell And Environment, 31, 1781-1790.
Cuellar-Ortiz,S.M. Arrieta-Montiel,M. Acosta-Gallegos,J. Covarrubias,A.A.
2008. Relationship between carbohydrate partitioning and drought resistance in common bean Plant Cell And Environment, 31, 1399-1409.
Barrios-Gonzalez,J. Banos,J.G. Covarrubias,A.A. Garay-Arroyo,A.
2008. Lovastatin biosynthetic genes of Aspergillus terreus are expressed differentially in solid-state and in liquid submerged fermentation Applied Microbiology and Biotechnology, 79, 179-186.
Martin,R. Arenas,C. Daros,J.A. Covarrubias,A. Reyes,J.L. Chua,N.H.
2007. Characterization of small RNAs derived from Citrus exocortis viroid (CEVd) in infected tomato plants Virology, 367, 135-146.
Battaglia,M. Solorzano,R.M. Hernandez,M. Cuellar-Ortiz,S. Garcia-Gomez,B. Marquez,J. Covarrubias,A.A.
2007. Proline-rich cell wall proteins accumulate in growing regions and phloem tissue in response to water deficit in common bean seedlings Planta, 225, 1121-1133.
Campos,F. Zamudio,F. Covarrubias,A.A.
2006. Two different late embryogenesis abundant proteins from Arabidopsis thaliana contain specific domains that inhibit Escherichia coli growth Biochemical and Biophysical Research Communications, 342, 406-413.
Reyes,J.L. Rodrigo,M.J. Colmenero-Flores,J.M. Gil,J.V. Garay-Arroyo,A. Campos,F. Salamini,F. Bartels,D. Covarrubias,A.A.
2005. Hydrophilins from distant organisms can protect enzymatic activities from water limitation effects in vitro Plant, Cell and Environment, 28, 709-718.
Folch-Mallol,J.L. Garay-Arroyo,A. Lledias,F. Covarrubias-Robles,A.A.
2004. The stress response in the yeast Saccharomyces cerevisiae Revista Latinoamericana de Microbiologia, 46, 24-46.
Verdoy,D. Lucas,M.M. Manrique,E. Covarrubias,A.A. De Felipe,M.R. Pueyo,J.J.
2004. Differential organ-specific response to salt stress and water deficit in nodulated bean (Phaseolus vulgaris) Plant Cell And Environment, 27, 757-767.
Garay-Arroyo,A. Covarrubias,A.A. Clark,I. Nino,I. Gosset,G. Martinez,A.
2004. Response to different environmental stress conditions of industrial and laboratory Saccharomyces cerevisiae strains Applied Microbiology and Biotechnology, 63, 734-741.
Garay-Arroyo,A. Lledias,F. Hansberg,W. Covarrubias,A.A.
2003. Cu,Zn-superoxide dismutase of Saccharomyces cerevisiae is required for resistance to hyperosmosis FEBS Letters, 539, 68-72.
Olivieri,F. Zanetti,M.E. Oliva,C.R. Covarrubias,A.A. Casalongue,C.A.
2002. Characterization of an extracellular serine protease of Fusarium eumartii and its action on pathogenesis related proteins European Journal Of Plant Pathology, 108, 63-72.
Campos,F. Garcia-Gomez,B.I. Solorzano,R.M. Salazar,E. Estevez,J. Leon,P. Alvarez-Buylla,E.R. Covarrubias,A.A.
2001. A cDNA for nuclear-encoded chloroplast translational initiation factor 2 from a higher plant is able to complement an infB Escherichia coli null mutant Journal of Biological Chemistry, 276, 28388-28394.
Moreno-Fonseca,L.P. Covarrubias,A.A.
2001. Downstream DNA sequences are required to modulate Pvlea-18 gene expression in response to dehydration Plant Molecular Biology, 45, 501-515.
Garay-Arroyo,A. Colmenero-Flores,J.M. Garciarrubio,A. Covarrubias,A.A.
2000. Highly hydrophilic proteins in prokaryotes and eukaryotes are common during conditions of water deficit Journal of Biological Chemistry, 275, 5668-5674.
Garcia-Gomez,B.I. Campos,F. Hernandez,M. Covarrubias,A.A.
2000. Two bean cell wall proteins more abundant during water deficit are high in proline and interact with a plasma membrane protein Plant Journal, 22, 277-288.
Porta,H. Rueda-Benitez,P. Campos,F. Colmenero-Flores,J.M. Colorado,J.M. Carmona,M.J. Covarrubias,A.A. Rocha-Sosa,M.
1999. Analysis of lipoxygenase mRNA accumulation in the common bean (Phaseolus vulgaris L.) during development and under stress conditions Plant and Cell Physiology, 40, 850-858.
Zentella,R. Mascorro-Gallardo,J.O. Van Dijck,P. Folch-Mallol,J. Bonini,B. Van Vaeck,C. Gaxiola,R. Covarrubias,A.A. Nieto-Sotelo,J. Thevelein,J.M. Iturriaga,G.
1999. A Selaginella lepidophylla trehalose-6-phosphate synthase complements growth and stress-tolerance defects in a yeast tps1 mutant Plant Physiology, 119, 1473-1482.
Garay-Arroyo,A. Covarrubias,A.A.
1999. 3.0.CO;2-Q> Three genes whose expression is induced by stress in Saccharomyces cerevisiae Yeast, 15, 879-892.
Villanueva,M.A. Diaz,C. Colmenero-Flores,J.M. Dantan,E. Sanchez,F. Covarrubias,A.A.
1999. Actin expression in germinating seeds of Phaseolus vulgaris L Planta, 207, 582-589.
Colmenero-Flores,J.M. Moreno,L.P. Smith,C.E. Covarrubias,A.A.
1999. Pvlea-18, a member of a new late-embryogenesis-abundant protein family that accumulates during water stress and in the growing regions of well-irrigated bean seedlings Plant Physiology, 120, 93-103.
Colmenero-Flores,J.M. Campos,F. Garciarrubio,A. Covarrubias,A.A.
1997. Characterization of Phaseolus vulgaris cDNA clones responsive to water deficit: identification of a novel late embryogenesis abundant-like protein Plant Molecular Biology, 35, 393-405.
Garciarrubio,A. Legaria,J.P. Covarrubias,A.A.
1997. Abscisic acid inhibits germination of mature Arabidopsis seeds by limiting the availability of energy and nutrients Planta, 203, 182-187.
Mascorro-Gallardo,J.O. Covarrubias,A.A. Gaxiola,R.
1996. Construction of a CUP1 promoter-based vector to modulate gene expression in Saccharomyces cerevisiae Gene, 172, 169-170.
Covarrubias,A.A. Ayala,J.W. Reyes,J.L. Hernandez,M. Garciarrubio,A.
1995. Cell-Wall Proteins Induced by Water Deficit in Bean (Phaseolus vulgaris L.) Seedlings Plant Physiology, 107, 1119-1128.
Castano,I. Flores,N. Valle,F. Covarrubias,A.A. Bolivar,F.
1992. gltF, a member of the gltBDF operon of Escherichia coli, is involved in nitrogen-regulated gene expression Molecular Microbiology, 6, 2733-2741.
Castano,I. Bastarrachea,F. Covarrubias,A.A.
1988. gltBDF operon of Escherichia coli Journal of Bacteriology, 170, 821-827 * .
Miranda-Rios,J. Sanchez-Pescador,R. Urdea,M. Covarrubias,A.A.
1987. The complete nucleotide sequence of the glnALG operon of Escherichia coli K12 Nucleic Acids Research, 15, 2757-2770 * .
Garciarrubio,A.A. Covarrubias,A.A.
1987. Promoter selection by a bacterial enhancer-like activator element (BELE) in Escherichia coli Gene, 54, 275-280 * .
Rocha,M. Vazquez,M. Garciarrubio,A. Covarrubias,A.A.
1985. Nucleotide sequence of the glnA-glnL intercistronic region of Escherichia coli Gene, 37, 91-99 * .
Leon,P. Romero,D. Garciarrubio,A. Bastarrachea,F. Covarrubias,A.A.
1985. Glutamine synthetase-constitutive mutation affecting the glnALG upstream promoter of Escherichia coli Journal of Bacteriology, 164, 1032-1038.
Osorio,A.V. Servin-Gonzalez,L. Rocha,M. Covarrubias,A.A. Bastarrachea,F.
1984. cis-Dominant, glutamine synthetase constitutive mutations of Escherichia coli independent of activation by the glnG and glnF products Molecular and General Genetics, 194, 114-123.
Covarrubias,A.A. Bastarrachea,F.
1983. Nucleotide sequence of the glnA control region of Escherichia coli MGG Molecular & General Genetics, 190, 171-175 * .
Valle,F. Sanvicente,E. Seeburg,P. Covarrubias,A. Rodriguez,R.L. Bolivar,F.
1983. Nucleotide sequence of the promoter and amino-terminal coding region of the glutamate dehydrogenase structural gene of Escherichia coli Gene, 23, 199-209.
Garciarrubio,A. Lozoya,E. Covarrubias,A. Bolivar,F.
1983. Structural organization of the genes that encode two glutamate synthase subunits of Escherichia coli Gene, 26, 165-170.
Covarrubias,L. Cervantes,L. Covarrubias,A. Soberon,X. Vichido,I. Blanco,A. Kupersztoch-Portnoy,Y.M. Bolivar,F.
1981. Construction and characterization of new cloning vehicles. V. Mobilization and coding properties of pBR322 and several deletion derivatives including pBR327 and pBR328 Gene, 13, 25-35 * .
Covarrubias,A.A. Rocha,M. Bolivar,F. Bastarrachea,F.
1980. Cloning and physical mapping of the glnA gene of Escherichia coli K-12 Gene, 11, 239-251 * .
Covarrubias,A.A. Sanchez-Pescador,R. Osorio,A. Bolivar,F. Bastarrachea,F.
1980. ColE1 hybrid plasmids containing Escherichia coli genes involved in the biosynthesis of glutamate and glutamine Plasmid, 3, 150-164 * .
Lozoya,E. Sanchez-Pescador,R. Covarrubias,A. Vichido,I. Bolivar,F.
1980. Tight linkage of genes that encode the two glutamate synthase subunits of Escherichia coli K-12 Journal of Bacteriology, 144, 616-621 * .
Greene,P.J. Heyneker,H.L. Bolivar,F. Rodriguez,R.L. Betlach,M.C. Covarrubias,A.A. Backman,K. Russel,D.J. Tait,R. Boyer,H.W.
1978. A general method for the purification of restriction enzymes Nucleic Acids Research, 5, 2373-2380 * .
Bolivar,F. Covarrubias,A. Rodriguez,R.
1976. Clonación de ADN de N. crassa y E. coli utilizando tres enzimas de restricción y un vehículo molecular con sitios específicos para cada una de ellas. Revista de la Sociedad Química de México, 20, 260-264 * .
Libros y capítulos recientes Rendon-Luna,D.F. Romero-Perez,P.S. Cuevas-Velazquez,C.L. Reyes,J.L. Covarrubias,A.A. 2020. Determining the Protective Activity of IDPs Under Partial Dehydration and Freeze-Thaw Conditions en: Intrinsically Disordered Proteins. pags. 519-528
Chater,C.C.C. Covarrubias,A.A. Acosta-Maspons,A. 2019. Crop Biotechnology for Improving Drought Tolerance: Targets, Approaches, and Outcomes en: Roberts,J.A. Annual Plant Reviews. pags. 1-39
Contreras-Cubas,C. Covarrubias,A.A. Reyes,J.L. 2013. Determining Abundance of MicroRNAs and Other Small RNAs in Legumes en: Rose,R.J. Legume Genomics. pags. 81-92
Sosa-Valencia,G. Covarrubias,A.A. Reyes,J.L. 2013. Signaling by MicroRNAs in Response to Abiotic Stress en: Abdin,M. Stress Signalling in Plants: Genomics and Proteomics Perspectives vol 1. Springer. pags. 51-67
Covarrubias-Robles,A.A. 2008. Sobrevivir al estrés: cómo responden las plantas a la falta de agua en: *agustin Una ventana al quehacer científico. Instituto de Biotecnología de la UNAM 25 aniversario, cap 22. Mexico, D.F.. UNAM. pags. 253-262
Covarrubias,A. Cassab,G.I. Sanchez,F. 2006. Hormones in Plants en: *joseph Molecular Endocrinology. Kerala, India,. Research Signpost. pags. 193-244
Covarrubias,A. 2004. Ventajas y limitaciones de la biotecnologia en la obtencion de variedades resistentes a estres ambiental en: Munoz Rubio,J. Alimentos transgenicos: ciencia, ambiente y mercado, un debate abierto. Mexico. Siglo XXI. pags. 51-66
Covarrubias,A. Cassab,G.I. 2003. Matriz extracelular de plantas en: Jimenez,L.F. Biología Celular y Molecular. Mexico,D.F.. Prentice Hall. pags. 547-591
Covarrubias,A. Sanchez,F. 2003. Importancia de un proyecto genómico de frijol (Phaseolus vulgaris L.). en: Herrera-Estrella,L. Fronteras de la Biología en los Inicios del Siglo XXI, Módulo III.. Mexico,D.F.. El Colegio Nacional. pags. 53-72
Covarrubias,A. 2003. Revelaciones de un genoma vegetal: Arabidopsis thaliana, un modeloexperimental en: *bolivar Fronteras de la Biología en los Inicios del Siglo XXI, Módulo I.. Mexico,D.F.. El Colegio Nacional. pags. 125-141
Bolivar,F. Lopez,S. Arias,C.F. Puente,J.L. Palacios,R. Davila,G. Flores,M. Gonzalez,A. de Luna,A. Anaya,V. Covarrubias,A. Cantu,J.M. Garcia,J.E. Collado,J. Medrano,A. 2003. Fronteras de la Biología en los Inicios del Siglo XXI: Genómica, Proteómica y Bioinformática. Mexico, D.F.: El Colegio Nacional.
Covarrubias,A. Reyes-Taboada,J. Rodrigo,M.J. Campos,F. Colmenero,J. Garay,A. Garciarrubio,A. Bartels,D. 2001. Hydrophylins and their possible role in drought tolerance en: Nitrogen Fixation Research Center XX Anniversary. pags. 113-117
Covarrubias,A.A. Colmenero-Flores,J.M. Campos,F. Garciarrubio,A. Garay-Arroyo,A. 1997. Molecular mechanisms of the drought response in higher plants en: Biotechnology for Water Use and Conservation. OECD Workshop Mexico 96 on Biotechnology for Water Use and Conservation. pags. 619-635
Covarrubias,A. Sanchez-Pescador,R. Lozoya,E. Bastarrachea,F. Bolivar,F. 1980. Isolation of E. coli Chromosomal DNA Regions Carrying glnA, gdh and gltB Structural Genes en: Palacios,R. Glutamine: Metabolism, Enzymology, and Regulation. Academic Press. pags. 123-137 *
Bastarrachea,F. Brom,S. Covarrubias,A.A. Osorio,A. Bolivar,F. 1980. Genetic Characterization of Mutations Affecting Glutamine Biosynthesis and its Regulation in Escherichia coli K12 en: Palacios,R. Glutamine: Metabolism, Enzymology, and Regulation. Academic Press. pags. 107-121 *
Tait,R.C. Heyneker,H.L. Bolivar,F. Rodriguez,A. Covarrubias,A.A. Betlach,M. Boyer,H.W. 1978. Tetracycline resistance conferred by pSC101, pMB9 and their derivatives en: Microbiology-1978, American Society for Microbiology. pags. 174-176 *
Otras Publicaciones Cuevas-Velazquez,C.L. Vellosillo,T. Guadalupe,K. Schmidt,H.B. Yu,F. Moses,D. Brophy,J.A.N. Cosio-Acosta,D. Das,A. Wang,L.X. Jones,A.M. Covarrubias,A.A. Sukenik,S. Dinneny,J.R.
2021. Intrinsically disordered protein biosensor tracks the physical-chemical effects of osmotic stress on cells bioRxiv, Preprint posted February 18, .
Covarrubias,A.A.
2016. Bases moleculares de la respuesta de las plantas a la sequía.Universidad: Ciencia y Tecnología (Universidad Autónoma del Estado de Morelos)., 2, 21-25.
Cuevas-Velazquez,C.L. Covarrubias-Robles,A.A.
2011. Las proteínas desordenadas y su función: una nueva forma de ver la estructura de las proteínas y la respuesta de las plantas al estrés TIP revista especializada en Ciencias Quimico-Biologicas, 14, 97-105.
Cuellar-Ortiz,S. Covarrubias-Robles,A.A.
2009. El uso de métodos tradicionales en combinación con nuevas tecnologías y conocimiento de vanguardia para afrontar el problema de la sequía en el cultivo de frijol Claridades Agropecuarias, 193, 38-47.
Flores,F. Martinez,M.A. Arenas,C. Covarrubias,A. Reyes,J.L.
2007. ¡Silencio mensajeros! Qué son y cómo actúan los micrornas REB Revista de Educación Bioquímica, 26, 135-141.
Cuellar-Ortiz,S. Covarrubias-Robles,A.A.
2005. Alternativas para enfrentar la sequía en el cultivo de frijol Claridades Agropecuarias, 142, 32-41.
Covarrubias,A. Sanchez,F.
2002. La genesis de una verdadera revolucion verde Revista Universidad de Mexico, 627, 56-63.
Campos-Alvarez,F. Cruz-Garcia,F. Torres-Espinosa,A. Sanchez-Jimenez,M.P. Colmenero-Flores,J.M. Smith-Espinoza,C. Covarrubias-Robles,A.A. Vazquez-Ramos,J.M.
2002. Expresión De Genes Codificantes Para Proteína, Abundantes En Embriogénesis Tardía (Lea), Durante El Osmoacondicionamiento De Semillas De Maíz Y Frijol Agrociencia, 36, 461-470.
Covarrubias,A. Porta,H. Cevallos,M.A.
2001. El codigo verde de la vida: la secuencia completa de un genoma vegetal.Como ves, 29, 22-25.
Mendieta,R. Garciarrubio,A. Covarrubias,A.
1992. Algunos aspectos fisiologicos del frigol (Phaseolus vulgaris L.) bajo deficit de agua.Universidad: Ciencia y Tecnología (Universidad Autónoma del Estado de Morelos)., 2, 27-33.
Rocha,M. Bastarrachea,F. Covarrubias,A.A.
1983. [Characterization of the glnA-glnG region of Escherichia coli K12].Boletin de estudios medicos y biologicos, 32, 299-307.
* Indica publicación con otra institución de adscripción
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