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Revista mexicana de micología
versión impresa ISSN 0187-3180
Rev. Mex. Mic vol.37 Xalapa jun. 2013
Contribuciones
Isolation and identification of fungi from leaves infected with false mildew on safflower crops in the Yaqui Valley, Mexico
Aislamiento e identificación de hongos de las hojas infectadas con la falsa cenicilla en cultivos de cártamo en el Valle del Yaqui, México
Eber Addi Quintana-Obregón 1, Maribel Plascencia-Jatomea 1, Armando Burgos-Hérnandez 1, Pedro Figueroa-López 2, Mario Onofre Cortez-Rocha 1
1 Departamento de Investigación y Posgrado en Alimentos, Universidad de Sonora, Blvd. Luis Encinas y Rosales s/n, Colonia Centro. C.P. 83000 Hermosillo, Sonora, México.
2 Campo Experimental Norman E. Borlaug-INIFAP. C. Norman Borlaug Km.12 Cd. Obregón, Sonora C.P. 85000.
* Autor para correspondencia:
M.O. Cortez-Rocha mcortez@guayacan.uson.mx
Received 28 September 2012;
Accepted 27 May 2013.
Resumen
La falsa cenicilla es una enfermedad que afecta seriamente los cultivos de cártamo en el Valle del Yaqui, México, y es causada por la infección de un hongo perteneciente al género Ramularia. En el presente estudio, un hongo aislado de hojas contaminadas fue cultivado bajo diferentes condiciones de crecimiento con la finalidad de estudiar su desarrollo micelial y producción de esporas, determinándose que el medio sólido de Septoria tritici, 18 °C de incubación y fotoperiodos de 12 h luz-oscuridad, fueron las condiciones más adecuadas para el desarrollo del hongo. Este aislamiento fue identificado morfológicamente como Ramularia cercosporelloides, pero genómicamente como Cercosporella acroptili, por lo que no se puede aún concluir que especie causa esta enfermedad. Adicionalmente, en la periferia de las infecciones estudiadas se detectó la presencia de Alternaria tenuissima y Cladosporium cladosporioides.
Palabras clave: Ramularia cercosporelloides, Carthamus tinctorius, Cercosporella acroptili, hongos aislados, Sonora.
Abstract
False mildew is a serious disease of safflower crops in the Yaqui Valley, Mexico, and is caused by infection with a fungus belonging to the genus Ramularia. In the present study, a fungus isolated from leaf lesions was grown under different growth conditions in order to study its mycelial growth and spore production, determining that the solid medium of Septoria tritici at 18 °C of incubation and photoperiod of 12 h light-dark, were the most suitable conditions for the fungal development. The isolated was morphologically identified as Ramularia cercosporelloides, but genomically as Cercosporella acroptili, therefore cannot be concluded which species causes this disease. Also, in the periphery of false mildew were found the presence of Alternaria tenuissima and Cladosporium cladoporioides.
Key words: Ramularia cercosporelloides, Carthamus tinctorius, Cercosporella acroptili, isolated fungi, Sonora.
Slowaffer (Carthamus tinctorius L.) is an alternative agricultural crop suitable for regions with low water availability during the winter season in Mexico or when other crops are damaged by low temperatures. In our country, safflower is a crop mainly used for edible oil (CESAVESON, 2004; Silveira-Gramont et al., 2009). Sonora is one of the States with the largest production of safflower, contributing with about 40% of the national production. During the autumn-winter 2000-2001 crop cycles at the Yaqui and Mayo Valleys, a false mildew appeared in safflower crop, disease unknown in the region until that time. The disease-causing agent was identified as Ramularia spp. Studies conducted by local boards of plant health found a 100% disease incidence in the crop, which generated 36.4% of yield reduction during this cycle (CESAVESON, 2004). For the 2004-2005 crop cycles, the disease was present immediately after the emergence of the plant, six weeks before compared to previous cycles (CESAVESON, 2006). In 2006, the fungus was isolated from safflower leaves infected with false mildew which was morphologically identified as Ramularia cercosporelliodes, and its pathogenicity was determined by in vivo assays and confirmed using the Koch's postulates (Huerta-Espino et al., 2006). In 2007 disease-resistant varieties, lines 04-787 and 04-0765 (Muñoz-Valenzuela et al., 2007) and seeds genetic improvement produced highly tolerant safflower varieties were introduced (Montoya-Coronado et al., 2008); but later, it was found that 78% of the sown acreage presented an infection rate from 51 to 100%. Montoya-Coronado et al. (2008) reported that R. carthami was the causative agent of false mildew, based only morphological identification. Therefore, considering the importance of the problems caused by false mildew in safflower in Mexico, the scarce scientific reports generated to date, the absence of reports with DNA for sequence R. cercosporelloides and the problems associated to isolation by conventional methods, the objectives of this research work were: 1) to isolate the fungus from false mildew affected safflower leaves at the Yaqui Valley, 2) to obtain their DNA sequences and, 3) to establish in vitro conditions for their optimal growth.
Materials and methods
In June 2010, leaves samples of the aerial part of the plant with more than three false mildew lesions, were randomly collected from safflower crops variety S-518 extemporaneously sown. Samples were collected at 50 m from the Dr. Norman E. Borlaug St, km 12, Yaqui Valley, at Cajeme, Sonora. Subsequently, they were placed in hermetically sealed bags and transported to the Laboratory of Microbiology and Mycotoxins of the Food Research and Graduate Department of the University of Sonora, where they were stored at 4 °C until further use.
Observation of leaves infected
False mildew lesions in safflower plants were identified according to the description of Huerta-Espino et al. (2006) throughout observations of leaves under a stereoscope (CARL ZEISS 475002-9902) (16 and 40X magnification) and optical microscope (Leica, Model DME) (100X magnification). False mildew infected leaves were separated and used for fungal isolation.
Fungal isolation
The fungus was sensitive to chemical disinfection of leaves, making difficult the spores removal from the leaf surface, therefore, four isolation techniques were evaluated:
(i) Extraction of spores with a drop of either water or Tween 20 solution: Leaves with false mildew lesions were randomly selected and a drop of either distilled water or sterile Tween 20 was added over the spot lesion. Spores suspension was removed with a sterile Pasteur pipette, deposited on the culture media, and scattered over the surface of the plate with a sterile glass rod. The plates were stored in an incubator (PRECISION, Thermo Scientific, USA) and developed colonies were observed after 96 and 168 h to temperatures evaluated.
(ii) Extraction of spores from lesions found on leaves: Leaves with more than three false mildew lesions, were randomly selected, washed with sterile water, immersed in sodium hypochlorite solution 0.5% (v v-1) for 2 min, and the excess of disinfectant was removed with sterile distilled water. Disinfected leaves were placed on Petri dishes containing 20 mL of base agar and incubated at different temperatures. After 48 h, the mycelium developed on the false mildew lesions was observed with the stereoscope (40x) and the characteristic colonies of Ramularia genera were identified, according to the description of Huerta-Espino et al. (2006). Subsequently, spores were scrapped off the plate using a glass rod, suspended in 2 mL Tween 20 (0.01%, v.v-1) In total, 5 spore suspensions were obtained and, from every suspension, 50 μL aliquots were taken and placed on Petri dishes containing 20 mL of culture medium. They were distributed on the surface of the medium with a sterile glass rod and the plates were incubated at different temperatures evaluated until the appearance of fungal colonies.
(iii) Extraction of spores from lesions found on non-disinfected leaves: Leaves with more than three false mildew lesions were randomly selected and placed on Petri dishes containing 20 mL of agar base. After 48 h, the characteristic colonies of Ramularia genera were identified according to the description of Huerta-Espino et al. (2006). Later, 5 mL of Tween 20 (0.01% v v-1), were poured onto the plate and spores were scrapped off the plate using a glass rod. The 5 mL water volume containing the spore suspension was distributed in Eppendorf vials (1 mL each) until further use. From each suspension, 50 μL aliquots were taken and entirely used to inoculate the culture media. Afterwards, they were distributed over the surface of the culture medium with a sterile glass rod and incubated to observe the development of fungal colonies in center and periphery of spot leaf.
(iv) Inoculation with fragments of diseased leaves: Leaves with more than three false mildew lesions were randomly selected and leaf fragments with disease lesions were cut in 1x1 cm pieces. Leaves pieces were washed with sterile water and immersed in sodium hypochlorite solution 0.5% (v v-1) for 2 min, followed by a sterile distilled water washing. Subsequently, leaves fragments were placed on Petri dishes containing 20 mL of culture medium and incubated at the temperatures previously mentioned, until mycelium developed and subjected to observation. The colonies with the highest incidence of growth were re-cultured in selected media at different temperatures and times of exposure to light evaluated, until obtaining an isolated fungal growth for identification.
The culture media used for propagation of mycelia and spores were V-8 medium (15 g agar, 3 g CaCO3, 200 mL juice of 8 vegetables, and graduated to 1000 mL with H2O), Septoria tritici medium (ST) (1000 mL H2O, 18 g agar, 4 g sucrose, 4 g yeast extract, 4 g malt extract) (Huerta-Espino et al., 2006), potato and dextrose agar media (PDA Bioxon), and Czapeck Bioxon medium (BD Bioxon). Cultures and re-cultures of the inocula were incubated at different temperatures (18, 20, 25, and 30 °C) and times of exposure to light (exposure cycles of 12h light-dark and 24 h dark). From these experiments, the best fungal growing conditions were selected for further propagation and cultivation trials. The spores developed in each culture media were suspended or re-cultivated, according to the isolation technique used.
After determining the most suitable growth conditions in vitro, the isolation was inoculated in 20 mL of culture medium contained in a 125 mL Erlenmeyer flask and incubated for 7 days at 18 °C. Then, 10 mL of sterile water was added and stirred for 5 min using a disinfected magnetic bar. An aliquot of 25 μL of the spore suspension was taken and deposited on a slide for observation. The observations were made using an optical microscope and 10 to 20 images of the spores were randomly taken with the software Image-Pro Plus v. 6.3 X (Media Cybernetics, Inc., USA, 1993-2008) at magnifications of 100, 400, and 1000x. The length and width of 25 randomly selected spores were measured. The experiments were performed in triplicate and measurements obtained from the three trials were averaged, with a total of 75 data.
Fungal identification
The descriptions for morphological identification of the database Nomenclature and Species Banks were employed to identify Ramularia isolated species (Robert et al., 2005).
DNA sequence analyses
Samples of isolated fungi were sent to the Center for Genomic Biotechnology of the National Polytechnic Institute (Reynosa, Tamaulipas, Mexico) for genomic identification. Genomic DNA was extracted from 240 h-old mycelia cultures grown in Potato Dextrose Broth (PDB). DNA extracted (1 mL) was placed into a 2 mL microcentrifuge tube and spun for 2 min at 12,000 rpm. The supernatant was aspirated and discarded. Then, 100 μL of PrepMan ®Ultra Sample Preparation Reagent were added. The sample was shaked for 30 s using a Vortex, heated for 10 min at 100 °C, and cooled down to room temperature for 2 min. Then, the sample was centrifuged at 12,000 rpm for 2 min and 50 μL of the supernatant were transferred into a new microcentrifuge tube. The supernatant was ready for Polymerase Chain Reaction (PCR) (Protocol PrepMan®Ultra, Applied Biosystems, USA). Purified DNA was used to obtain the sequence. The primers ITS1/ITS4 and NL1/NL4 were used to amplify both, the fungal DNA region segment D2, which belongs to a large rDNA sub-unit LSU, and the DNA 26S segment. The sequencing conditions included a denaturation process carried out at 94°C during 5 min, followed by a cycle at 94°C during 30 s, and an annealing step at 58°C (for ITS) and at 63°C (for 26S), both during 30 s. An extension was carried out at 72°C for 1 min for a total of 36 cycles and a final extension at 72°C and 4°C for 7 and 5 min, respectively. The genomic DNA sequence was finally obtained using a fluorescent Big Dye 3.1 (Applied Biosystems). The PCR products were sequenced using a Sequencing Applied Biosystems Mod. 3130 and generated sequences were aligned with BLAST algorithm (GenBank) of the National Center for Biotechnology Information (NCBI) (http://blast.ncbi.nlm.nih.gov/Blast)
Microcultures
The microculture technique reported by Tuite (1969) was employed with the following modifications: 1 cm2 agar plugs were obtained from sterile solid medium and placed onto a slide was placed into a humidified chamber, consisting of a 9 mm-diameter Petri dish which bottom had been previously covered with gray paper and moistened with 5 mL of sterile distilled water, to prevent dehydration of the culture medium. Each agar plug was inoculated with a straight handle loop in both the center and the ends, and covered with a coverslip. The chamber was incubated under previously selected conditions and observed until the appearance of the fungal colony.
Results
Observation of infected leaves
Fungal colonies and spores characteristic of the Ramularia genera were observed on the surface of false mildew infected safflower leaves (Figure 1). Disease lesions on safflower leaves were similar to those reported by Huerta-Espino et al. (2006). In summary, they were observed as brown circular or angular-irregular shaped necrotic lesions on the leaves, (2-20 mm in diameter), and sometimes, it a diffuse yellowish halo and fungus growth (resembling the whitish mold) was observed. Next, ovoid, cylindrical (20-45 x 3.5-10 mm) septated (0 to3 septum), solitary conidia or formed in short chains at scar sites on conidiophores, were observed.
Furthermore, in the periphery of lesions, spores and mycelium of Alternaria and Cladosporium were observed; consequently, the isolation of pure conidia from the leaf spot was difficult. Independently from host and leaf surface, Heuser and Zimmer (2002) found that the removal of spores only from Ramularia sp., Cladosporium sp., and others spores was difficult.
Fungal isolation
"Extraction of spores from lesions found on leaves" and "extraction of spores from lesions found on non-disinfected leaves" were the most appropriate isolation techniques for the development of Ramularia, Cladosporium and Alternaria after 48 h of incubation.
ST culture medium at 18 °C, with a photo period of 12 h light-dark, was the most suitable culture conditions for the propagation of isolate genomic identified as C. acroptili. Areas with white to salmon pink-colored mycelium were found, as well as diffuse pigmentation of colonies obtained with spores cultivated in medium ST and extracted with technique extraction of spores from lesions found on leaves. These colonies were re-cultivated in new ST culture media and incubated under the same conditions, until full adaptation of the fungus to the environment from which a pure culture might be possible to obtain. The isolation and adaptation of colonies from ST culture medium was obtained until the fifth re-cultivation (Figure 3).
With respect to culture conditions, V-8 and ST media were suitable for the production of spores. It was observed that, the ST media had the highest density of mycelium on the surface and production of spores after 7 days of incubation (25 °C or 18 °C, and photoperiod of 12 h light-dark) when spores inoculated on culture media ST and V-8 came from a suspension in sterile water (Table 1). Therefore, the culture conditions selected for the propagation of isolation were: ST medium, 18 °C and a photoperiod of 12 h. Under these conditions, the spores generated had the following dimensions in size, 17.21 ± 5.63 in length and 7.54 ± 1.40 μm wide.
Fungal identification and DNA sequence
The fungal genus isolated from the central part of the false mildew was morphologically identified as Ramularia and the fungi from the periphery of lesions were identified as Cladosporium and Alternaria. According to the database reported by Robert et al. (2005), the presumptive species were Ramularia cercosporelloides, Cladosporium cladosporioides, and Alternaria tenuissima.
The presumptive fungal species (after morphological identification) were genomically aligned with the nucleotide sequence obtained (Figure 2). R. cercosporelloides was 100% identical to Cercosporella acroptili (gb|GU214689.1|) by genomic alignment; C. cladosporioides (gb|AY213695.1|) and A. tenuissima (gb|FJ755240.1|) were confirmed (verified with BLAST algorithm in NCBI, February 2013).
Discussion
The present research work reports the genomic identification of Cercosporella acroptili (Ramularia acroptili in MycoBank Database, International Mycological Association, accessed on February 2013) in safflower. Other studies have reported the presence ofRamularia carthami Z. as the species isolated from false mildew (Montoya-Coronado et al., 2008; Borbon-Garcia et al., 2011). However, Huerta-Espino et al. (2006), reported that R. cercosporelloides was the fungi that caused false mildew in safflower. Nowadays, R. carthami is recognized as Ramularia cynerae (MycoBank Database, International Mycological Association, accessed on February 2013) but it is not R. cercosporelloides (a nom. nov. for Cercosporella carthami, see notes in Koike et al., 2011).
Ramularia acroptili and C. acroptili have been reported in Acroptilon repens (Berner et al., 2005), whereas R. cercosporelloides and C. carthami have only been reported in Carthamus tinctorius (Kirschner, 2009; Huerta-Espino et al. , 2006). At this time, the question was still in the air, what causes false mildew on safflower, R. carthami, C. acroptili or C. carthami?
The fungal taxonomy is a dynamic and progressive discipline that constantly generates changes in its nomenclature. Traditionally, fungi are classified according to their morphology and sexual status; however, they have also been classified from an ecological and biological panorama (Guarro et al., 1999). Disputes to name species commonly occur, particularly when fungi have the ability to spread using different types of reproduction, which varies with the geographical zone in which the sample was collected, or simply with the time of collection (Shenoy et al., 2007). For this reason, there are many synonymous for some species and they are constantly reclassified. Also, the difficulty of the morphological identification causes frequent changes in the classification by genera, Ramularia and Cercosporella for example (Kirschner, 2009). Moreover, Tautz et al. (2003) mentioned that one of the disadvantages of the traditional taxonomy systems is the dependence on specialists whose skills are lost upon retirement; other is the difficulty to access the specialized literature.
In the present work, a genomic identification was done. Our isolated strain showed 100% genomic alignment with a nucleotide sequence of a strain CBS120252, isolated from Acroptilon repens in Turkey and identified as R. acroptili (GenBank accession numbers GU214689) (Crous et al., 2009). As a matter of fact, on February 2013, the GenBank accession numbers GU214689, corresponds to C. acroptili and there is no accession for R. cercosporelloides in the database nucleotide sequence. It is interesting to mention that both strains were isolated from Astarecea plants, which confirm the presence of the genera Ramularia in Astarecea. Berner et al. (2005) reported a fungal isolate from A. repens, tentatively identified as R. acroptili, but finally it was confirmed as C. acroptili. In our report, the isolate from C. tinctorius was tentatively identified as R. cercosporelloides but it was confirmed as C. acroptili.
These reports support the necessity for highly specific techniques for the identification of fungi in safflower and also for Mycosphaerella anamorphs (telemorph of Ramularia). Given the difficulties in the identification of species, Hibbett et al. (2007) suggested the use of DNA for identification, especially in isolates that cannot be easily distinguished or when they show low taxonomic differentiation.
For this reason, while further data is not available, we agree with Kirschner (2009) proposal in using several studies for the classification of a species. These may include morphological descriptions by simple light microscopy, ultrastructure's descriptions using scanning electron microscopy, molecular analysis, observations of interactions, and host-parasite infection.
The existing controversy in the names reported for the fungi genera isolated from false mildew in safflower Ramularia and Cercosporella, is a problem that is illustrated naming this isolate R. cercosporelloides as reported by Braun (Kirshner, 2009). However, the aim of the present study does not focus on the discussion of the methods and techniques for fungal identification; but this necessity is evident.
Moreover, our isolates showed slow growth and development in artificial media. However, for further studies, the use of ST medium, 18 °C, and photoperiods of 12 h is recommended. The use of sterile water to suspend the spores reduces the mycelium production time. This might be due to the beginning of the germination of spores in the presence of water or to the competition of the spores by the agglomeration over the culture medium.
On the other hand, with respect to the isolated fungi from the periphery of the spot leaf, the presence off Alternaría in safflower has been reported as a recurring contaminant in the field (Irwin 1976, Mortensen et al. 1983) and our studies have recently showed the presence of A. tenuissima in safflower seed (Quintana et al., 2011). Also, Cladosporium is a fungus phylogenetically related to the Ramularia genera (Kirshner 2009), and is described as an opportunistic fungus of secondary contamination in agricultural crops, and their spores are deposited on injuries caused by other phytopathogenic fungi (Crous et al. 2007). It is possible that in safflower, C. cladosporioides spores are deposited on the surface of leaves with false mildew.
The existence of either antagonistic or synergistic interactions between the fungi isolated in the present study is also possible. These interactions have been reported in other phytopathogenic fungi, for example C. cladosporioides and Sclerotia sclerotionum in bean (Phaseolus vulgaris L.) (Boland and Hunter, 1988). However, this hypothesis was not confirmed.
Conclusion
This first isolation of C. acroptili, A. tenussima, and C. cladosporium from false mildew infected safflower is reported. C. acroptili was isolated and genomically identified from false mildew infected safflower leaves planted and grown at the Yaqui Valley, Sonora, Mexico. However, we propose to name our isolation as R. cercosporelloides, until sufficient data for its proper identification be obtained.
Acknowledgements
To the National Council of Science and Technology (CONACYT) in Mexico, for financing the project 58249 and the graduate fellowship awarded to the author Quintana-Obregón No. EA 202460. To the University of Sonora for financing the number project IANTI07011.
References
Berner, D.K., F.M. Eskandari, U. Braun, M.B. McMahon, D.G. Luster, 2005. Cercosporella acroptili and Cercosporela centaureicola sp. nov. Potential biological control agents of Russian knapweed and yellow starthistle, respectively. Mycologia 97: 1122-1128. [ Links ]
Boland, G.J., J.E. Hunter, 1988. Influence of Alternaría alternata and Cladosporium cladosporioides on white mold of bean caused by Sclerotibia sclerotiurum. Canadian Journal of Plant Pathology 10: 172-177. [ Links ]
Borbon-Garcia, A., X.M. Ochoa-Espinoza, L. Montoya-Coronado, J. Pérez Márquez, M.G. García Camarena, 2011. CIANO-LIN: nueva variedad de cártamo linoléica. Revista Mexicana de Ciencias Agrícolas 2: 791-794. [ Links ]
CESAVESON (Comité Estatal de Sanidad Vegetal Sonora), 2004. Informe técnico 2004. Caracterización fitosanitaria del cártamo. http://www.cesaveson.com/Cartamo.aspx (verified July 20, 2010). [ Links ]
CESAVESON (Comité Estatal de Sanidad Vegetal Sonora), 2006. Informe técnico 2006. Vigilancia Fitosanitaria, Falsa cenicilla del Cártamo. http://www.cesaveson.com/Cartamo.aspx (verified July 20, 2010). [ Links ]
Crous, P.W., U. Braun, K. Schubert, J.Z. Groenewald, 2007. Delimiting Cladosporium from morphologically similar genera. Studies in Mycology 58:33-56. [ Links ]
Crous P.W., C.L. Schoch, K.D. Hyde, A.R. Wood, C. Gueidan, G.S. de Hoog, J.Z. Groenewald, 2009. Phylogenetic lineages in the Capnodiales. Studies in Mycology 64: 17-47. [ Links ]
Guarro, J., J. Gené, A.M. Stchigel, 1999. Developments in fungal taxonomy. Clinical Microbiology Reviews 12: 454-500. [ Links ]
Heuser, T., W. Zimmer, 2002. Quantitative analysis of phytopathogenic ascomycota on leaves of pedunculate oaks (Quercus robur L.) by real-time PCR. FEMS Microbiology Letters 209: 295-299. [ Links ]
Hibbett, D.S., M. Binder, J.F. Bischoff, M. Blackwell, P.F. Cannon, O.E. Eriksson, S. Huhndorf, T. James, P.M. Kirk, R. Lücking, L.H. Thorsten, F. Lutzoni, M.P. Brandon, D.J. McLaughlin, M.J. Powell, S. Redhead, C.L. Schoch, J.W. Spatafora, J.A. Stalpers, R. Vilgalys, M.C. Aime, A. Aptroot, R. Bauer, D. Begerow, G.L. Bonny, L.A. Castlebury, P.W. Crous, Y.C. Dai, W. Gams, D.M. Geiser, G.W. Griffith, C. Gueidan, D.L. Hawksworth, G. Hestmark, K. Hosaka, R.A. Humber, K.D. Hyde, J.E. Ironside, U. Koljalg, C.P. Kurtzman, K-H. Larsson, R. Lichtwardt, J. Longcore, J. Miadlikowska, A. Miller, J.M. Moncalvo, S. Mozley-Standridge, F. Oberwinkler, E. Parmasto, V. Reeb, J.D. Rogers, C. Roux, L. Ryvarden, J.P. Sampaio, A. SchüBler, J. Sugiyama, R.G. Thorn, L. Tibell, W.A. Untereiner, C. Walker, Z. Wang, A. Weir, M. Weiss, M.M. White, K. Winka, Y.J. Yao, N. Zhang, 2007. A higher-level phylogenetic classification of the Fungi. Mycological Research 111:509-547. [ Links ]
Huerta-Espino J., O. Constantinescu, C. Velásquez, S.A. Herrera-Foessel, P. Figueroa-López, 2006. First report of Ramularia cercosporelloides on Carthamus tinctorius in Northwestern Mexico. Plant Disease 90: 1552. [ Links ]
Irwin, J.A.G., 1976. Alternaria carthami, a seed-borne pathogen of safflower. Australian Journal of Experimental Agriculture and Animal Husbandry 16: 921-925. [ Links ]
Kirschner, R., 2009. Cercosporella and Ramularia. Mycologia 101: 110-119. [ Links ]
Koike, S.T, A. Baameur, J.Z. Groenewald, P.W. Crous, 2011. Cercosporoid leaf pathogens from whorled milkweed and spineless safflower in California. IMAFungus 2: 7-12. [ Links ]
Montoya-Coronado L., F. Ochoa-Burgos, J. Wong-Pérez, M. Camarilla-Pulido, J Macías-Cervantes, 2008. CIANO-OL, CIANO-LIN, RC-1002-L, RC-1005-L y RC-1033-L variedades de cártamo altamente tolerantes a falsa cenicilla (Ramularia carthami). Folleto técnico numero 60. (ed.) Instituto Nacional de Investigaciones Forestales, Agrícolas y Pecuaria, Cd. Obregón, México. [ Links ]
Mortensen, K., J.W. Bergman, E.E. Burns, 1983. Importance of Alternaria carthami and A. alternata in causing leaf spot diseases of safflower. Plant Disease 67:1187-1190. [ Links ]
Muñoz-Valenzuela, S., M.G. Chanda, L. Montoya-Coronado, V.M. Rivera-Rojas, 2007. Evaluation of safflower genotypes in northwest México. In: Janick J. A. Whipkey (eds.), Issues in New Crops and New Uses, Alexandria: ASHS Press. pp 193-195. [ Links ]
Quintana, E.A., J. López, L.A. Cira, D. Sánchez, M. Plascencia, M.O. Cortez, 2011. Actividad antifúngica del quitosano contra Alternaría tenuissima in vitro y en semilla de cártamo. Revista Mexicana de Fitopatología 29:168-171. [ Links ]
Robert, V., G. Stegehuis, J. Stalpers, 2005. The MycoBank engine and related databases. http://www.mycobank.org (verified July 20, 2010). [ Links ]
Shenoy, B.D., R. Jeewon, K.D. Hyde, 2007. Impact of DNA sequence-data on the taxonomy of anamorphic fungi. Fungal Diversity 26:1-54. [ Links ]
Silveira-Gramont, M.I., M.L. Aldana-Madrid, L.A. Medina-Juárez, A. Serrano-Esquer, 2009. Situación de la producción de cártamo (Carthamus tinctorius L.) en Sonora, México y factores asociados. Biotecnia XI: 44-56. [ Links ]
Tautz, D., P. Arctander, A. Minelli, R. H. Thomas, A. P. Vogler, 2003. A plea for DNA taxonomy. Trends in Ecology & Evolution 18: 70-74. [ Links ]
Tuite, J., 1969. Plant pathological methods: fungi and bacteria. Burgess Publishing, Minnessota, 239 p. [ Links ]