Colletotrichum shisoi sp. nov., an anthracnose pathogen of Perilla frutescens in Japan: molecular phylogenetic, morphological and genomic evidence.

Species of the fungal genus Colletotrichum are among the most devastating pathogens of agricultural crops in the world. Based on DNA sequence data (ITS, GAPDH, CHS-1, ACT, TUB2) and morphology, we revealed Colletotrichum isolates infecting the oil crop Perilla frutescens, commonly known as shiso, to represent a previously unknown species of the C. destructivum species complex and described it as C. shisoi. We found that C. shisoi appears to be able to adopt a hemibiotrophic lifestyle, characterised by the formation of biotrophic hyphae followed by severe necrotic lesions on P. frutescens, but is less virulent on Arabidopsis, compared to its close relative C. higginsianum which also belongs to the C. destructivum species complex. The genome of C. shisoi was sequenced, annotated and its predicted proteome compared with four other Colletotrichum species. The predicted proteomes of C. shisoi and C. higginsianum, share many candidate effectors, which are small, secreted proteins that may contribute to infection. Interestingly, C. destructivum species complex-specific secreted proteins showed evidence of increased diversifying selection which may be related to their host specificities.

Genome Sequence Resources for Four Phytopathogenic Fungi from the Colletotrichum orbiculare Species Complex.

Colletotrichum orbiculare species complex fungi are hemibiotrophic plant pathogens that cause anthracnose of field crops and weeds. Members of this group have genomes that are remarkably expanded relative to other Colletotrichum fungi and compartmentalized into AT-rich, gene-poor and GC-rich, gene-rich regions. Here, we present an updated version of the C. orbiculare genome, as well as draft genomes of three other members from the C. orbiculare species complex: the alfalfa pathogen C. trifolii, the prickly mallow pathogen C. sidae, and the burweed pathogen C. spinosum. The data reported here will be important for comparative genomics analyses to identify factors that play a role in the evolution and maintenance of the expanded, compartmentalized genomes of these fungi, which may contribute to their pathogenicity.

Draft Genome Assembly of Colletotrichum chlorophyti, a Pathogen of Herbaceous Plants.

Colletotrichum chlorophyti is a fungal pathogen that infects various herbaceous plants, including crops such as legumes, tomato, and soybean. Here, we present the genome of C. chlorophyti NTL11, isolated from tomato. Analysis of this genome will allow a clearer understanding of the molecular mechanisms underlying fungal host range and pathogenicity.

In vitro random mutagenesis of the D1 protein of the photosystem II reaction center confers phototolerance on the cyanobacterium Synechocystis sp. PCC 6803.

The D1 protein of the photosystem II reaction center is thought to be the most light-sensitive component of the photosynthetic machinery. To understand the mechanisms underlying the light sensitivity of D1, we performed in vitro random mutagenesis of the psbA gene that codes for D1, transformed the unicellular cyanobacterium Synechocystis sp. PCC 6803 with mutated psbA, and selected phototolerant transformants that did not bleach in high intensity light. A region of psbA2 coding for 178 amino acids of the carboxyl-terminal portion of the peptide was subjected to random mutagenesis by low fidelity polymerase chain reaction amplification or by hydroxylamine treatment. This region contains the binding sites for Q(B), D2 (through Fe), and P680. Eighteen phototolerant mutants with single and multiple amino acid substitutions were selected from a half million transformants exposed to white light at 320 micromol m(-2) s(-1). A strain transformed with non-mutagenized psbA2 became bleached under the same conditions. Site-directed mutagenesis has confirmed that one or more substitutions of amino acids at residues 234, 254, 260, 267, 322, 326, and 328 confers phototolerance. The rate of degradation of D1 protein was not appreciably affected by the mutations. Reduced bleaching of mutant cyanobacterial cells may result from continued buildup of photosynthetic pigment systems caused by changes in redox signals originating from D1.

Comparison of local and systemic induction of acquired disease resistance in cucumber plants treated with benzothiadiazoles or salicylic acid.

The accumulation of chitinase and its involvement in systemic acquired disease resistance was analyzed using acibenzolar-S-methyl and salicylic acid (SA). Resistance against scab (pathogen: Cladosporium cucumerinum) and the accumulation of chitinase were rapidly induced in cucumber plants after treatment with acibenzolar-S-methyl. In contrast, SA protected the plants from C. cucumerinum and the accumulation of chitinase was induced only on the treated leaves. The accumulation of chitinase in response to inoculation with the pathogen was induced more rapidly in cucumber plants previously treated with acibenzolar-S-methyl than in plants pretreated with SA or water. Thus, it appears that a prospective signal(s), that induces systemic resistance, can be transferred from leaves treated with acibenzolar-S-methyl to the untreated upper and lower leaves where systemic resistance is elicited. In contrast, exogenously applied SA is not likely to function as a mobile, systemic resistance-inducing signal, because SA only induces localized acquired resistance.

Electron transfer between QA and QB in photosystem II is thermodynamically perturbed in phototolerant mutants of Synechocystis sp. PCC 6803.

Several random mutations have been generated in the psbA2 gene of Synechocystis sp. PCC 6803 [Narusaka, Y., Murakami, A., Saeki, J., Kobayashi, H., and Satoh, K. (1996) Plant Sci. 115, 261-266]. The phototolerant mutant (I6) carrying all the amino acid substitutions in the lumenal side of D1 protein (S322I, I326F, and F328S) and a site-directed mutant of the same phenotype (NDFS) substituted in the stromal side of the protein (N234D and F260S) were characterized by thermoluminescence measurements. We observed (1) no significant differences in their growth rates at either low or high light irradiance, (2) a downshifted B-band in the NDFS mutant, (3) an upshifted Q-band in the I6 mutant, and (4) a damped period four oscillation of thermoluminescence in the B-band of both mutants. By examining the possible implications of these results on the redox properties of the PS II components in the mutants, we concluded that equilibrium constants for sharing an electron between the primary (QA) and secondary acceptor plastoquinones (QB) are decreased in both mutants.

The herbicide-resistant species of the cyanobacterial D1 protein obtained by thorough and random in vitro mutagenesis.

Random mutations were introduced into the DNA fragment of the psbA2 gene of Synechocystis sp. PCC 6803, which encodes the carboxyl-terminal 178 amino acid region of the D1 protein of the PSII reaction center, by in vitro random mutagenesis to obtain D1 species resistant to herbicides and to understand the protein-herbicide interactions. The mutants were screened on the criterion of resistance to either 1 microM DCMU or 10 microM atrazine. In these mutants, amino acid substitutions were distributed throughout the entire area of the targeted region in the D1 protein. However, in every mutant, except for one case, the substitution was present in the region described as the "herbicide-binding niche", i.e., between Phe211 and Leu275, although some amino acid substitutions which were not previously described were found at residues known to be involved with herbicide affinity. Thus, the result of random mutagenesis basically supports the validity of the proposed structural model for the D1 protein, as well as of the herbicide-binding niche. Preliminary characterization of the herbicide-resistant mutants obtained in this study has also been conducted.