A vegetative storage protein improves drought tolerance in maize.

Vegetative storage proteins (VSPs) are known to serve as nitrogen reserves in many dicot plants but remain undiscovered in grasses, most widely grown group of crops globally. We identified and characterized a VSP in maize and demonstrated that its overexpression improved drought tolerance. Nitrogen supplementation selectively induced a mesophyll lipoxygenase (ZmLOX6), which was targeted to chloroplasts by a novel N-terminal transit peptide of 62 amino acids. When ectopically expressed under the control of various tissue-specific promoters, it accumulated to a fivefold higher level upon expression in the mesophyll cells than the wild-type plants. Constitutive expression or targeted expression specifically to the bundle sheath cells increased its accumulation by less than twofold. The overexpressed ZmLOX6 was remobilized from the leaves like other major proteins during grain development. Evaluated in the field over locations and years, transgenic hybrids overexpressing ZmLOX6 in the mesophyll cells significantly outyielded nontransgenic sibs under managed drought stress imposed at flowering. Additional storage of nitrogen as a VSP in maize leaves ameliorated the effect of drought on grain yield.

A pair of homoeolog ClpP5 genes underlies a virescent yellow-like mutant and its modifier in maize.

Gene-background interaction is a commonly observed phenomenon in many species, but the molecular mechanisms of such an interaction is less well understood. Here we report the cloning of a maize mutant gene and its modifier. A recessive mutant with a virescent yellow-like (vyl) phenotype was identified in an ethyl methanesulfonate-mutagenized population derived from the maize inbred line B73. Homozygous mutant maize plants exhibited a yellow leaf phenotype after emergence but gradually recovered and became indistinguishable from wild-type plants after approximately 2 weeks. Taking the positional cloning approach, the Chr.9_ClpP5 gene, one of the proteolytic subunits of the chloroplast Clp protease complex, was identified and validated as the candidate gene for vyl. When introgressed by backcross into the maize inbred line PH09B, the mutant phenotype of vyl lasted much longer in the greenhouse and was lethal in the field, implying the presence of a modifier(s) for vyl. A major modifier locus was identified on chromosome 1, and a paralogous ClpP5 gene was isolated and confirmed as the candidate for the vyl-modifier. Expression of Chr.1_ClpP5 is induced significantly in B73 by the vyl mutation, while the expression of Chr.1_ClpP5 in PH09B is not responsive to the vyl mutation. Moreover, expression and sequence analysis suggests that the PH09B Chr.1_ClpP5 allele is functionally weaker than the B73 allele. We propose that functional redundancy between duplicated paralogous genes is the molecular mechanism for the interaction between vyl and its modifier.

Utility of cytoplasmic fluorescent proteins for live-cell imaging of Magnaporthe grisea in planta.

The subcellular expression patterns and fluorescence intensities of cytoplasm-targeted, constitutively expressed blue-, cyano-, green-, yellow- and red-fluorescent protein were assessed in a number of transformants of the blast pathogen, Magnaporthe grisea. All transformants grew normally, remained pathogenic on barley, and, except for those expressing blue fluorescent protein, exhibited significant cytoplasmic fluorescence. The exceptionally intense brightness of some strains proved very useful for laser scanning confocal microscope imaging during invasion of host tissues. Acquisition of three-dimensional data sets from intact, individual, pathogen encounter sites in planta were generated during the time course of pathogenesis using non-invasive optical sectioning methods. Confocal and multiphoton microscopy imaging in conjunction with fluorescent protein expression allowed for the real time documentation of fungal colonization within plant cells and tissues with remarkable ease. These methods constitute valuable new tools for the investigation of plant disease.

Brittle stalk 2 encodes a putative glycosylphosphatidylinositol-anchored protein that affects mechanical strength of maize tissues by altering the composition and structure of secondary cell walls.

A spontaneous maize mutant, brittle stalk-2 (bk2-ref), exhibits dramatically reduced tissue mechanical strength. Reduction in mechanical strength in the stalk tissue was highly correlated with a reduction in the amount of cellulose and an uneven deposition of secondary cell wall material in the subepidermal and perivascular sclerenchyma fibers. Cell wall accounted for two-thirds of the observed reduction in dry matter content per unit length of the mutant stalk in comparison to the wildtype stalk. Although the cell wall composition was significantly altered in the mutant in comparison to the wildtype stalks, no compensation by lignin and cell wall matrix for reduced cellulose amount was observed. We demonstrate that Bk2 encodes a Cobra-like protein that is homologous to the rice Bc1 protein. In the bk2-ref gene, a 1 kb transposon-like element is inserted in the beginning of the second exon, disrupting the open reading frame. The Bk2 gene was expressed in the stalk, husk, root, and leaf tissues, but not in the embryo, endosperm, pollen, silk, or other tissues with comparatively few or no secondary cell wall containing cells. The highest expression was in the isolated vascular bundles. In agreement with its role in secondary wall formation, the expression pattern of the Bk2 gene was very similar to that of the ZmCesA10, ZmCesA11, and ZmCesA12 genes, which are known to be involved in secondary wall formation. We have isolated an independent Mutator-tagged allele of bk2, referred to as bk2-Mu7, the phenotype of which is similar to that of the spontaneous mutant. Our results demonstrate that mutations in the Bk2 gene affect stalk strength in maize by interfering with the deposition of cellulose in the secondary cell wall in fiber cells.

Live-cell imaging of tubulin in the filamentous fungus Magnaporthe grisea treated with anti-microtubule and anti-microfilament agents.

Microtubule dynamics were examined in live cells of the fungal plant pathogen Magnaporthe grisea transformed for constitutive expression of a fusion protein containing enhanced yellow-fluorescent protein and a Neurospora crassa benomyl-resistant allele of beta-tubulin. Transformants retained their ability to differentiate appressoria and cause disease but remained sensitive to benomyl. Linear microtubule arrays and low-level cytoplasmic fluorescence were observed in vegetative hyphae, conidia, germ tubes, and developing appressoria. Fluorescence within nuclei was conspicuously absent during interphase but increased rapidly at the onset of mitosis. Treatment with either benomyl or griseofulvin resulted in the appearance of prominent brightly fluorescent aggregates, including a large aggregate near the apex, with the concomitant disappearance of most cytoplasmic microtubules. Electron microscope imaging of treated cells indicated that the aggregates lacked any obvious profiles of intact microtubules. During these treatments, hyphal tip cells continued to elongate in a nonlinear and aerial fashion at a much slower rate than untreated cells. With subsequent removal of griseofulvin, distal aggregates disappeared rapidly but the apical aggregates persisted longer. Treatment with latrunculin A caused hyphal tip swelling without apparent effect on linear microtubule arrays. Simultaneous treatment with griseofulvin and latrunculin A resulted in depolymerization of microtubules and a cessation of growth, but near-apical fluorescent aggregates were not observed.

Reef coral fluorescent proteins for visualizing fungal pathogens.

The fluorescent proteins AmCyan, ZsGreen, ZsYellow, and AsRed, modified versions of proteins identified recently from several Anthozoa species of reef corals, were expressed for the first time in a heterologous system and used for imaging two different fungal plant pathogens. When driven by strong constitutive fungal promotors, expression of these reef coral fluorescent proteins yielded bright cytoplasmic fluorescence in Fusarium verticillioides and Magnaporthe grisea, and had no detectable effect on either growth rate or the ability to cause disease. Differential intracellular localization of the fluorescent proteins resulted in the discrimination of many subcellular organelles by confocal and multi-photon microscopy, and facilitated monitoring of such details as organelle dynamics and changes in the permeability of the nuclear envelope. AmCyan and ZsGreen were sufficiently excited at 855 and 880 nm, respectively, to allow for time-resolved in planta imaging by two-photon microscopy.