Toxigenic capacity and trichothecene production by Fusarium graminearum isolates from Argentina and their relationship with aggressiveness and fungal expansion in the wheat spike.

At least 20 epidemics of Fusarium head blight (FHB) of wheat have been registered in the last 50 years in Argentina, with variable intensity. Damage induced by the disease is further aggravated by the presence of mycotoxins in affected grains that may cause health problems to humans and animals. The trichothecene chemotype was analyzed for 112 isolates of Fusarium graminearum from Argentina by polymerase chain reaction and two field trials were conducted to study the aggressiveness of a subsample of 14 representative isolates and to analyze deoxynivalenol (DON) production in planta and in vitro. All isolates belonged to the 15-acetyl-DON chemotype. Significant differences were observed in both the symptom severity induced in wheat spikes and the in vivo DON production, and a close correlation was found between these two variables. However, in vitro toxigenic potential was not correlated with the capacity of F. graminearum isolates to produce DON under natural conditions. The progress of infection in the rachis of inoculated wheat spikes was analyzed and the pathogen presence verified in both symptomatic and symptomless spikes. Even isolates with a limited capacity to induce symptoms were able to colonize the vascular tissue and to produce considerable amounts of DON in planta.

Identification of Races 0 and 2 of Cladosporium fulvum (syn Passalora fulva) on Tomato in the Cinturón Hortícola de La Plata, Argentina.

Surveys aimed at evaluating the incidence and severity of a new disease that developed in greenhouses cultivated with tomato (Solanum lycopersicum L.) were performed during 2009 and 2010 in greenhouses of the cultivars Elpida (Enza Zaden) and Colibrí (Clause) in an area of tomato production known as the Cinturón Hortícola de La Plata (the "horticultural belt of La Plata"). The disease had a 100% prevalence and 90% incidence within the ten 250 m2 greenhouses that were monitored in 2009, 2010, and 2011. In two consecutive assays, severity was 40%. The wide distribution of the disease suggests that the tomato hybrids under use lack resistance genes. The upper surface of diseased leaves had pale green to yellowish, 1- to 1.5-cm spots with undefined margins that progressed to a yellowish brown color, while on the lower side they had pale brown to brown sporulation of fungal conidiophores and conidia. Monosporic fungal cultures were obtained by needle transfer of conidia from sporulating areas of leaves (n = 20) to water agar medium. On 2% potato dextrose agar (PDA) the colonies of the relatively low growing fungus were strongly pigmented, greenish grey, and black on the reverse of the plate. The fungus developed one-celled, pale olive-green, ovoid conidia on long, branched chains, which arose from pigmented conidiophores, corresponding to the description of Cladosporium fulvum made by Joosten and de Wit (1). The identity of two isolates was confirmed by amplifying the 580-bp ITS sequences by means of primers ITS4 (5'-TCCTCCGCTTATTGATATGC-3') and ITS5 (5'-GAATTCGGAAGTAAAAGTCGTAACAAGG-3') (ITS sequence Race 0 JQ768324.1 and Race 2 JQ768325.1). Both were 100% homologous to the ITS sequences of C. fulvum strains ATCC44962 (AF393700) and ATCC44960 (AF303701). Monosporic cultures of four isolates, each obtained from leaves collected from different plants growing in different greenhouses, were inoculated on a set of differential genotypes of tomato: cvs. Moneymaker, Cf-0, Cf-2, Cf-4, Cf-5, and Cf-9 (kindly provided by the Laboratory of Phytopathology of Wageningen University). Three plants of each tomato genotype at the 5 to 6 true leaf stage were inoculated by spraying a 105 conidia/ml conidial suspension of C. fulvum on the leaflets of the 3rd and 4th leaf. Inoculation tests of each isolate were repeated at least twice. After inoculation, plants were grown in the greenhouse at 13 to 29°C and 99% relative humidity. However, for the first 20 h after inoculation, plants were kept in the dark. They were regularly monitored and were scored as resistant or susceptible at 20 days after inoculation. Susceptible genotypes developed pale green to yellow spots on the abaxial leaf surface and pale brown to olivaceous brown sporulation on the adaxial side. Plants lacking disease symptoms were considered resistant. Inoculated fungi were reisolated from infected tissue and the identity of the fungal cultures confirmed based on morphology and the ITS sequence. Based on the reactions of the tomato genotypes, two races were identified, three isolates (race 2) developed symptoms only in cv. MM Cf-2, while the remaining isolate (race 0) provoked symptoms only in cv. MM Cf-0. Reference: (1) M. Joosten and P. de Wit. Annu Rev Phytopathol. 37:335, 1999.

First Report of Tomato rugose yellow leaf curl virus Infecting Tomato in Argentina.

Tomato plants exhibiting typical symptoms of begomovirus infection, including leaf deformation, curling, and yellowing, were collected from cultivated fields in Lavalle Department, Corrientes, Argentina, in 2010. Although the number of affected plants was only 2% within a farm, the finding is of considerable importance since the white fly Bemisia tabaci is widely spread within the country, even in other southernmost areas such as the cinturón hortícola de Buenos Aires (horticultural belt around Buenos Aires). DNA isolated from infected tomato leaves collected from three symptomatic tomato plants was amplified by PCR with specific primers designed to amplify a region of component A and B of the Begomovirus genome (3). The amplified DNA fragment was sequenced and a new set of primers were designed based on the obtained sequences. A DNA fragment of about 1,300 bp was amplified and later the complete genome, which was 2,683 bp long. No fragments were obtained when template DNA was from non-infected leaf samples. The 2,683-bp fragment was annotated at the NCBI under Accession No. KC132844. Analysis by NCBI BLAST showed that it was highly homologous to DNA-A component of Begomovirus. Furthermore, the genome organization was typical of DNA-A component of bipartite New World begomovirus. The sequence had one open reading frame (ORF) on the viral-sense strand (AV1/CP) and four ORFs on the complementary-sense strand (AC1/Rep, AC2/TrAp, AC3/REn, and AC4). In order to confirm this finding, the viral genome was amplified by rolling circle amplification (RCA, TempliPhi 100 Amplification Kit, Amersham Biosciences) as described by the manufacturer instructions. The RCA full-length product was digested with XhoI generating a 2,700-bp DNA fragment, suggesting the presence of only one restriction site, in agreement with the bioinformatics analysis of the KC132844 sequence. This PCR product was used as template in PCR reactions with specific primers to DNA-A or DNA-B components. While the DNA-A primers generated the expected 1,300-bp fragment, those homologous to the DNA-B component did not generate amplifications. These results confirmed the identity of the DNA-A component of the isolate MT8. The full sequence of the DNA-A component was 94% homologous to the DNA-A sequence of the Uruguayan begomovirus Tomato Rugose Yellow Leaf Curl Virus-[U4.1] (JN381823.1). Therefore, considering our results and the criteria proposed by Fauquet (1), isolate MT8 is a new species of begomovirus described recently (2). This is the first report of TRYLCV in one of the main areas of tomato production in Argentina. This virus might be accompanying another begomovirus TYVSV that provoked yellow veins symptoms in tomato plants cultivated in the same area of Corrientes. These viruses appeared recently and concomitantly with the introduction of the white fly Bemisia spp. in the area, which is one of the main production areas of tomato and provides fresh tomatoes to the whole country, and in wintertime to the city of Buenos Aires, when the horticultural belt around Buenos Aires is not under production. References: (1) C. M. Fauquet et al. Arch Virol 153:783, 2008. (2) B. Márquez-Martín et al. Arch Virol 157:1137, 2012. (3) M. R. Rojas et al. Plant Dis. 77:340, 1993.

First Report of Races 11 and 12 of Cercospora sojina, the Causal Agent of Soybean Frogeye Leaf Spot, in Argentina.

During the growing seasons of 2008 to 2009 and 2009 to 2010, severe outbreaks of soybean (Glycine max (L.) Merr.) frogeye leaf spot, a disease caused by Cercospora sojina Hara, occurred in several areas in Argentina (1). Two surveys were conducted in soybean fields, one in 2008 that included the provinces of Buenos Aires, Córdoba, and Santa Fe, and another that was performed in 2009 in the same provinces plus three others: Entre Ríos, Santiago del Estero, and Tucumán. In both surveys, plants presented circular lesions with reddish brown-to-gray spots and bordered by typical, narrow, reddish purple margins (3). To promote sporulation and to enable identification of the causal agent, leaves of diseased plants were collected and placed in a moist chamber for 24 h with a 12-h light cycle at 25°C. Conidia were plated on potato dextrose agar medium amended with streptomycin and were incubated at 25°C and 12 h of fluorescent light. Isolated cultures sporulated in 10 days and, on the basis of their morphology, were identified as C. sojina. A total of 147 isolates were deposited at the Culture Collection of CEREMIC (Centro de Referencia de Micología). They produced one- to nine-septate hyaline, elongate to fusiform conidia that measured 54.9 ± 16.2 × 5.7 ± 1.0 µm. Six isolates of C. sojina, each representing a province, were inoculated on a set of 12 differential soybean cultivars: Lee, Davis, Hood, Richland, Lincoln, Kent, Tracy, S 100, Palmetto, Peking, CNS, and Blackhawk (2). Fifteen plants of each differential were sprayed at V3 growth stage with a suspension of 6 × 104 conidia/ml. The test was conducted twice in a complete randomized design with three replicates. Control plants were sprayed with sterile distilled water. After inoculation, plants were placed in a greenhouse bench humidity chamber at 26 to 28°C for 72 h. Disease was rated 14 days after inoculation; plants with numerous lesions were considered susceptible and each of the 15 plants was given a score of 1. Plants with small or no lesions were classified as resistant and given a score of 0. Control plants remained healthy. The pathogen was reisolated from symptomatic plants and morphological characteristics were consistent with C. sojina. Based on the response of the differentials to each isolate and on the race designations, the isolates from Buenos Aires, Córdoba, Santa Fe, and Tucumán belong to race 11, while those from Santiago del Estero and Entre Ríos province to race 12. The finding of these two races threatening soybean cultivars in Argentina may be indicative of additional races. Thus, the incorporation of multiple resistance genes may reduce the impact of the disease on soybean. To our knowledge, this is the first report of the identification of races of C. sojina in Argentina. References: (1) M. A. Carmona et al. Plant Dis. 93:966, 2009. (2) M. A. R. Mian et al. Crop Sci. 48:14, 2008. (3) D.V. Phillips. Page 20 in: Compendium of Soybean Diseases. 4th ed. APS Press, St. Paul, MN, 1999.

First Report of Agrobacterium rubi and A. rhizogenes Causing Crown and Root Gall and Hairy Root on Blueberry in Argentina.

From 2006 to 2009, crown gall and hairy root symptoms were observed on blueberry (Vaccinium corymbosum cvs. O'Neil, Millennia, and Misty) plants from six nurseries in Tucumán, Concordia, Pilar, Morón, and Baradero, Argentina. Bacteria were isolated from galls of all three cultivars and from hairy roots of Millenia and O'Neil onto D1 and D1M agar media at 27°C. Typical Agrobacterium colonies developed in 5 days (2). Seven bacterial strains (five from galls and two from hairy roots) were studied further. All were gram negative, aerobic, and catalase positive with rod-shaped cells that synthesized ß-galactosidase and metabolized D-glucose, D-arabinose, n-acetyl-glucosamine, maltose, mannitol, and malonate. Strains were negative for lysine decarboxylase, H2S production, indole, and 3-ketolactose production. While gall strains were urease positive and citrate variable (mostly positive), hairy root strains were urease negative, citrate positive, had poly-ß-hydroxybutyrate inclusion granules, and clarified acid on potato dextrose agar containing 0.5% CaCO3 (2). Agrobacterium tumefaciens ATCC 15955 and LBA 958 were included as controls. PCR with virA/C primers amplified a 338-bp product corresponding to the virD2 operon and confirmed that the strains harbored a pathogenic plasmid (1). Bacterial strains were assigned to biovars with a multiplex PCR assay targeting 23S rRNA sequences (3). Two strains produced PCR amplicons typical of A. rhizogenes bv. 2. The other five strains produced PCR amplicons typical of A. rubi, which were insensitive to agrocin in a bioassay with A. radiobacter strain K1026. Identity was confirmed by sequencing the 16S rDNA of strains F 266 (GenBank No. GU580894) and F 289 (No. GU580895), which had 99% homology to 16sRNA sequences of A. rubi ICMP 11833 (AY626395.1) and A. rhizogenes ATCC 11325 (AY945955.1), respectively. Pathogenicity of all seven strains was tested on V. corymbosum cv. Misty, Bryophyllum daigremontiana, tobacco cv. Xanthi, tomato cv. Presto, and pepper cv. California Wonder. Plants were inoculated by a needle stabbed into the stems with the appropriate cell suspension (108 CFU/ml) of each strain or with sterile distilled water (control treatment). Two plants of each species were tested per strain. Plants were grown for at least 45 days at 23 ± 3°C and symptoms were recorded. Inoculations with the five strains isolated from galls caused development of spherical, white to flesh-colored, rough, spongy wart-like galls at the inoculation sites. Root strains induced root proliferation on all inoculated plants as well as in a carrot disk bioassay (4). On blueberry plants, galls were dark brown to black, rough, and woody 6 months after inoculation. No lesions were observed on control plants. Bacteria were reisolated from symptomatic tissues of inoculated plants. Enterobacterial repetitive intergeneric consensus-PCR confirmed that the DNA fingerprints of the reisolated strains were identical to those of the original strains. To our knowledge, this is the first report of A. rubi and A. rhizogenes causing hairy root and crown gall on blueberry in Argentina. References: (1) J. H. Haas et. al. Appl. Environ. Microbiol. 61:2879,1995. (2) L. W. Moore et al. Page 17 in: Laboratory Guide for Identification of Plant Pathogenic Bacteria. 3rd ed. N. W. Schaad et al., eds. The American Phytopathological Society, St. Paul, MN, 2001. (3) J. Pulawska et al. Syst. Appl. Microbiol. 29:470, 2006. (4) M. H. Ryder et al. Plant Physiol. 77:215, 1985.

First Report of Angular Leaf Spot Caused by Phaeoisariopsis griseola on Phaseolus coccineus in Argentina.

Angular leaf spot (ALS), caused by Phaeoisariopsis griseola (Sacc.) Ferraris, is one of the most destructive and widespread problems of common bean (Phaseolus vulgaris L.) in Tucumán and other northwestern provinces of Argentina (4). Symptoms similar to those of ALS were observed during April 2005 on most plants of runner bean (P. coccineus L.) in an 80-ha field in Tafí del Valle, Tucumán (2,000 m above sea level). Leaf lesions were brown to gray, irregular to angular to circular, and 0.5 to 1 cm in diameter. Lesions on pods were oval to circular with reddish brown centers surrounded by darker brown borders. Conidia in vivo were curved cylindrical to obclavate with one to five septa and measured 25 to 60 × 3.5 to 7 µm. The conidiophores were 100 to 250 µm high and clustered together to form synnemata measuring 20 to 50 µm in diameter. The pathogen was isolated by placing conidia from diseased leaves onto potato dextrose agar (PDA) at pH 6. Colonies measuring 2 to 3 mm in diameter composed of dense, dark olive mycelium developed after incubation in the dark at 24 ± 2°C for 3 to 4 days. Pathogenicity of the isolate was tested with conidia obtained from the second subculture of 14-day-old colonies on PDA. Conidial suspensions of 2 × 104 conidia per ml were sprayed onto the upper and lower surfaces of the first trifoliolate leaves of six runner bean plants, 18 days after planting. Inoculated and control plants (sprayed with distilled water) were placed in a growth chamber with a 12-h photoperiod at 24 ± 2°C and 95 to 100% relative humidity and 48 h later moved to the greenhouse. Disease symptoms were evaluated 18 days after inoculation. While control plants were healthy, all inoculated plants showed symptoms similar to those observed in the field. The fungus that was consistently reisolated from lesions in the inoculated plants was identified as Phaeoisariopsis griseola on the basis of fungal morphology (1), symptoms produced on leaves (3), and random amplified polymorphic DNA data with primer 5'-CAATCGCCGT-3' (2). Runner bean is a new crop in Tafí del Valle, which is a geographically isolated area. In a period of only 2 years, the area cultivated with beans increased approximately five-fold. Because of this, the presence of a pathogen like Phaeoisariopsis griseola, which causes considerable reduction in yield in most common bean-producing areas of Argentina, is of concern. To our knowledge, this is the first report of ALS occurring on P. coccineus in Argentina. This report may prompt the inclusion of regular testing of seeds for ALS in P. coccineus-production areas. A voucher culture has been deposited in the LPSC (Culture collection of the La Plata Spegazzini Institute) No. 844. References: (1) M. B. Ellis. Dematiaceous Hyphomycetes. CMI, Kew, Surrey, UK, 1971. (2) P. Guzmán et al. Plant Dis. 83:37, 1999. (3) A. W. Saettler. Pages 15-16 in: Compendium of Bean Diseases. R. Hall, ed, The American Phytopathological Society, St. Paul, 1991. (4) S. A. Stenglein et al. Pages 209-243 in: Advances in Applied Microbiology, Vol. 52. A. I. Laskin et al., eds, Academic Press, San Diego, 2003.

Identification of fast and slow growing rhizobia nodulating soybean (Glycine max [L.] Merr) by a multiplex PCR reaction.

Two DNA fragments, a 730-bp and a 900-bp fragment, one homologous to host cultivar specificity genes nolBT of Sinorhizobium fredii and the other one homologous to RSalpha, an insertion-like sequence present in Bradyrhizobium japonicum, were generated by polymerase chain reaction (PCR) with two pairs of primers. The amount of each fragment generated by the multiplex PCR was proportional to the amount of template DNA present. The amplification of the 900-bp RSalpha fragment was more sensitive, since it was amplified from a smaller amount of template DNA than the 730-bp nolBT fragment. By running the multiplex reaction in the presence of template DNA isolated from different sources, we confirmed that the reaction can discriminate between S. fredii, Bradyrhizobium japonicum and Sinorhizobium xinjiangensis.

Sinorhizobium fredii isolates can be specifically identified by a 260 bp fragment from the nolXWBTUV locus.

A pair of primers homologous to the nolXWBTUV locus generated a 260 bp fragment by PCR only in the presence of Sinorhizobium fredii template DNA of different quality. This resulted in a fast and accurate method for the identification of S. fredii either from pure DNA, whole bacterial cells or nodule extracts. By means of two PCR fragments, one specific for S. fredii (260-bp) and the other specific for Bradyrhizobium japonicum (RSalpha), we found that S. fredii strain SMH12 and B. japonicum E109 were equally efficient at developing nodules on soybean plants grown under controlled environmental conditions.

Activation of porcine oocytes via an exogenously introduced rat muscarinic M1 receptor.

Thirty hours after the beginning of in vitro maturation, porcine oocytes were microinjected with mRNA coding for the rat muscarinic M1 receptor. They were then incubated for 15 h to allow sufficient time for completing maturation, translation of the mRNA, and insertion of the receptor into the plasma membrane. They were then treated with acetylcholine, the receptor's agonist, and its effect on inducing various activation-related changes was examined. Acetylcholine treatment triggered the release of Ca2+ from internal stores that could be blocked by atropine, the receptor's antagonist. The Ca2+ release was probably mediated via a G protein, since prior injection of guanosine 5'-O-(2-thiodiphosphate) (GDP-beta-S) totally inhibited the effect of the agonist. Pertussis toxin (PT) had no effect on the Ca2+ transients induced by acetylcholine, suggesting that the signal transduction pathway involved a PT-insensitive G protein. Electron microscopy revealed that in the injected oocytes, acetylcholine induced cortical granule exocytosis. The oocytes were released from meiotic arrest as evidenced by the decrease in H1 kinase activity measured in the oocytes during the histone H1 kinase assay. After resuming meiosis they entered interphase: 58.8% of the injected oocytes formed pronuclei after incubation with the agonist. Injection without subsequent acetylcholine treatment, or acetylcholine incubation without prior injection with the receptor mRNA, did not cause these changes. The results provide further evidence that the components of a G protein-mediated signal transduction pathway exist in porcine oocytes and that the activation of this pathway via an exogenously supplied G protein-coupled receptor results in a full complement of oocyte activation events. Whether this pathway transduces the activating signal at sperm-induced oocyte activation requires further examination.

Proteins from cells of Rhizobium fredii bind to DNA sequences precedingnolX, a flavonoid-inducible nod gene that is not associated with a nod box.

Rhizobium fredii strains USDA257 and USDA191 both contain a set of nodulation genes termed nolXWBTUV. In the USDA257 background, nolX prevents infection of soybean cultivars such as McCall, and in both backgrounds, it blocks nodulation of Erythrina spp. We report here that expression of nolX is differentially responsive to a panel of flavonoids, and that the most potent inducers are also the most active inducers of nodC, a conventional, nod box-associated gene. Cell-free protein extracts from uninduced and flavonoid-induced cells of strains USDA191 and USDA257 retard the electrophoretic mobility of DNA sequences that lie upstream of nolX. Binding is dependent both on nodD1 and nodD2, and it is abolished by the presence of a double-stranded, 23-bp oligonucleotide that lies within a 114-bp TaqI/SacII restriction fragment. This oligomer has significant sequence homology to A3, a putative negative regulatory element from R.leguminosarum bv. viciae. Deletion of the A3-homologous sequences elevates the basal and flavonoid-inducible expression of nolX by about 50%.

Transcriptional organization and expression of noIXWBTUV, a locus that regulates cultivar-specific nodulation of soybean by Rhizobium fredii USDA257.

Rhizobium fredii is a nitrogen-fixing bacterial symbiont of soybean and a number of other legume species. We have studied the transcriptional organization of a Sym plasmid locus that restricts the host range of R. fredii USDA257 at both the host species and cultivar level. The genes of this host-specificity locus, noIXWBTUV, are transcribed from three promoters. Two of these, which are upstream of noIW and noIBTUV, are oriented face to face and initiate transcription at sites that are 14 bp apart. The third lies upstream from noIX. The noIW promoter is constitutive, whereas the noIB and noIX promoters are inducible by flavonoid signals. We have attempted to express genes from this locus in Escherichia coli systems, both in vivo and in vitro. We detected the insert- and orientation-specific expression of two genes, noIX and noIW, but we were unable to obtain expression of noIBTUV. Antiserum raised against NoIT nevertheless detected an abundantly expressed polypeptide of the predicted size in protein extracts of USDA257. This observation, as well as RNA dot blot data from a series of mutants, indicates that noIBTUV is expressed as a single transcriptional unit in R. fredii. Immunological detection of NoIT, and of a second protein, NoIX, was strictly dependent on flavonoid induction. The NoIX protein was larger than the size predicted from the previously published nucleotide sequence, and this led to resequencing and revision of the open reading frame.

Molecular cloning and characterization of a sym plasmid locus that regulates cultivar-specific nodulation of soybean by Rhizobium fredii USDA257.

Rhizobium fredii strain USDA257 produces nitrogen-fixing nodules on primitive soybean cultivars such as Peking but fails to nodulate agronomically improved cultivars such as McCall. Transposon-mutant 257DH4 has two new phenotypes: it nodulates McCall, and its ability to do so is sensitive to the presence of parental strain USDA257, i.e. it is subject to competitive nodulation blocking. We have isolated a cosmid containing DNA that corresponds to the site of transposon insertion in 257DH4 and have localized Tn5 on an 8.0 kb EcoRI fragment. The 5596 bp DNA sequence that surrounds the insertion site contains seven open reading frames. Five of these, designated nolBTU, ORF4, and nolV, are closely spaced and of the same polarity. nolW and nolX are of the opposite polarity. The initiation codon for nolW lies 155 bp upstream from that of nolB, and its is separated from nolX by 281 bp. The predicted NolT and NolW proteins have putative membrane-spanning regions. The N-terminus of the hypothetical NolW protein also has limited homology to NodH of Rhizobium meliloti, but none of the deduced protein sequences has significant homology to known nodulation gene products. Site-directed mutagenesis with mudII1734 confirms that inactivation of nolB, nolT, nolU, nolV, nolW, or nolX extends host range for nodulation to McCall soybean. This phenotype could not be genetically dissected from sensitivity to competitive nodulation blocking. Expression of nolBTU and nolX is induced as much as 30-fold by flavonoid signal molecules, even though these genes lack nod-box promoters. Histochemical staining of McCall roots inoculated with nolB-, nolU-, or nolX-lacZ fusions verifies that these genes are expressed continuously from preinfection to the stage of the functional nodule. Although a nolU-ORF4-nolV clone hybridizes to a single 8.0 kb EcoRI fragment from 10 strains of R. fredii and broad-host-range Rhizobium sp. NGR234, hybridizing sequences are not detectable in other rhizobia.

Cultivar-Specific Interactions of Soybean with Rhizobium fredii Are Regulated by the Genotype of the Root.

Rhizobium fredii USDA257 forms nitrogen-fixing nodules on soybean cultivar Peking, but not on cultivar McCall. This pattern of nodulation persists when McCall and Peking seedlings are cultivated together in plastic growth pouches. Reciprocal grafting experiments confirm that the root genotype, and not that of the shoot, regulates such cultivar specificity. When Peking roots are grafted onto McCall seedlings, the nodulation responses of roots similarly remain unaffected. Transposon-mutant 257DH4, which is derived from USDA257, can form nitrogen-fixing nodules on McCall. Such nodulation is blocked by the presence of USDA257 in the inoculum. Grafting experiments indicate that blocking is not due to a translocatable inhibitor produced by McCall roots or triggered by their interaction with USDA257. Thus, neither freely diffusible nor graft-transmissible substances are involved in cultivar-specific interactions of soybean with R. fredii and its derivatives.

Nodulation of Soybean by a Transposon-Mutant of Rhizobium fredii USDA257 Is Subject to Competitive Nodulation Blocking by Other Rhizobia.

Rhizobium fredii USDA257 fails to nodulate the improved soybean [Glycine max (L.)Merr.] cultivar McCall in plastic growth pouches. Mutant 257DH4, which was derived from USDA257 by transposon mutagenesis, forms nitrogen fixing nodules under these conditions. If USDA257 is present in inocula containing the mutant, most infections are arrested prior to organization of the nodule meristem, and nodule number is reduced by 95%. The improved cultivars Essex, Harosoy, Hodgson 78, and Viçoja, as well as a supernodulating mutant of Williams, respond like McCall to inoculation with such mixtures of bacteria. Nodulation blocking on McCall can be elicited by rhizobia other than USDA257, provided that they meet two criteria: Blocking strains must themselves be able to induce cortical cells of McCall to divide, and such divisions must proceed to the stage of nodule meristem formation. Nodulation by the mutant remains sensitive to a challenge inoculation with USDA257 for only the first 6 to 12 hours after inoculation. Nodulation blocking involving mutant 257DH4 thus appears to be a rapid, generalized process.

Interaction of Rhizobium fredii USDA257 and nodulation mutants derived from it with the agronomically improved soybean cultivar McCall.

Rhizobium fredii USDA257 does not nodulate McCall soybean (Glycine max (L.) Merr.), but two transposon-mutants derived from it, 257DH4 and 257DH5, do. All three organisms cause curling of McCall root hairs and induce the formation of underlying cortical cell divisions. The mutants produce infection threads, and many of the meristematic foci develop into nodules. In contrast, root hairs that deform in response to USDA257 lack infection threads, and meristematic activity ceases prior to the appearance of nodule meristems. Root systems nodulated by mutant 257DH4 reduce acetylene at rates similar to those of roots nodulated by reference R. fredii strain USDA191. The presence of living cells of USDA257 in inocula leads to strong inhibition of nodulation by 257DH4 but not by 257DH5. This blocking effect depends on the ratio of USDA257 cells to 257DH4 cells in the inoculum; nodules that form contain cells of 257DH4, but not those of parental strain USDA257.

Nodulation and nitrogen fixation on vegetative soybean plants as affected by photoperiod and gibberellic acid.

Long-day photoperiods and applications of gibberellic acid promoted shoot growth by stimulating leaf enlargement as a result of increasing avaliable photosynthates, which was also reflected in the higher leaf, stem and nodule plant dry weights. Short-day plants had more nodules, but they were smaller (by weight) than those of long-day plants. Gibberellic acid at 1.5×10(-6) M enhanced nodule growth without preventing nodule formation. Factors other than just gibberellic acid are concluded to be involved in the responses of nodulation and nitrogen fixation to day length.

Role of Ethylene in the Geotropic Response of Bermudagrass (Cynodon dactylon L. Pers.) Stolons.

We studied the relationship between ethylene and gravity-induced upward bending of bermudagrass (Cynodon dactylon L. Pers.) stolons. Ethylene production begins within 3 hours of the onset of gravistimulation, and increases thereafter until the 15th hour, after which it declines. There is a close positive relationship between ethylene production and upward bending during the first 12 hours of gravistimulation. Incubation of stolons with AgNO(3) did not prevent ethylene evolution but delayed upward bending. In addition, ethylene production was 10-fold greater and peaked earlier in gravistimulated nodes incubated with 1-aminocyclopropane 1-carboxylic acid. The gravitational stimulation could be due to an increase in both 1-aminocyclopropane 1-carboxylic acid synthase and the ethylene forming enzyme. The results suggest that ethylene promotes the activity of indoleacetic acid.