Leaf rust of barley is caused by the macrocyclic, heteroecious rust pathogen Puccinia hordei, with aecia reported from selected species of the genera Ornithogalum, Leopoldia, and Dipcadi, and uredinia and telia occurring on Hordeum vulgare, H. vulgare ssp. spontaneum, Hordeum bulbosum, and Hordeum murinum, on which distinct parasitic specialization occurs. Although Puccinia hordei is sporadic in its occurrence, it is probably the most common and widely distributed rust disease of barley. Leaf rust has increased in importance in recent decades in temperate barley-growing regions, presumably because of more intensive agricultural practices. Although total crop loss does not occur, under epidemic conditions yield reductions of up to 62% have been reported in susceptible varieties. Leaf rust is primarily controlled by the use of resistant cultivars, and, to date, 21 seedling resistance genes and two adult plant resistance (APR) genes have been identified. Virulence has been detected for most seedling resistance genes but is unknown for the APR genes Rph20 and Rph23. Other potentially new sources of APR have been reported, and additivity has been described for some of these resistances. Approaches to achieving durable resistance to leaf rust in barley are discussed.
Austropuccinia psidii, originating in South America, is a globally invasive plant pathogen causing rust disease on Myrtaceae. Several biotypes are recognized with the most widely distributed pandemic strain spreading throughout the Asia-Pacific and Oceania regions within the last decade. Austropuccinia psidii has a broad host range (currently 480 myrtaceous species), making it a particularly dangerous plant pathogen. In the nine years since the pandemic biotype was first found in Australia in 2010, the pathogen has caused the near extinction of at least three species, the decline of at least one keystone species, and negatively affected commercial production of several Myrtaceae. To enable molecular and genomic studies into A. psidii pathogenicity, we assembled a highly contiguous genome for the pandemic biotype based on PacBio sequence data and scaffolding with Hi-C technology. With an estimated haploid genome size of just over 1 Gbp, it is the largest assembled fungal genome to date. We found the A. psidii genome to have a lower GC content (33.8 %), greatly expanded telomeric and intergenic regions and more repetitive regions (> 90 %) compared to other genomes of species in the Pucciniales, however numbers of predicted coding regions (18,875) are comparable. Most of the increase in genome size is caused by a recent expansion of transposable elements belonging to the Gypsy superfamily. Post-inoculation mRNA sequence capture from a susceptible host provides expression evidence for 10,613 predicted coding genes, including 210 of the 367 putative effectors. The completeness of the genome provides a greatly needed resource for strategic approaches to combat disease spread.3
Plants have developed complex defense mechanisms to protect themselves against pathogens. A wide-host-range fungus, Austropuccinia psidii, which has caused severe damage to ecosystems and plantations worldwide, is a major threat to Australian ecosystems dominated by members of the family Myrtaceae. In particular, the east coast wetland foundation tree species Melaleuca quinquenervia, appears to be variably susceptible to this pathogen. Understanding the molecular basis of host resistance would enable better management of this rust disease. We identified resistant and susceptible individuals of M. quinquenervia and explored their differential gene expression in order to discover the molecular basis of resistance against A. psidii. Rust screening of germplasm showed a varying degree of response, with fully resistant to highly susceptible individuals. We used transcriptome profiling in samples collected before and at 5 days postinoculation (dpi). Differential gene expression analysis showed that numerous defense-related genes were induced in susceptible plants at 5 dpi. Mapping reads against the A. psidii genome showed that only susceptible plants contained fungal-derived transcripts. Resistant plants exhibited an overexpression of candidate A. psidii resistance-related genes such as receptor-like kinases, nucleotide-binding site leucine-rich repeat proteins, glutathione S-transferases, WRKY transcriptional regulators, and pathogenesis-related proteins. We identified large differences in the expression of defense-related genes among resistant individuals.
A non-native rust of Myrtaceae was first detected in Australia in 2010, and was later identified as Puccinia psidii. The presence of many native species of Myrtaceae and a lack of understanding of genetic variability in P. psidii in Australia led to the current study. Low coverage genome sequencing of P. psidii suggested a genome size of c. 142 Mb. A set of 240 simple sequence repeat (SSR) primers was designed based on the genome sequence information generated. Seventeen isolates of P. psidii comprising 14 from Australia, two from Brazil and one from Hawaii were selected to study genetic variation in the pathogen. Out of 240 initially screened markers, 74% showed amplification among P. psidii isolates and 38% were polymorphic. Primers were fluorescently labelled and genotyping revealed three distinct genotypes among the isolates: one comprising Australian isolates and an isolate from Hawaii, and the second and third comprising two Brazilian isolates. Locus USYD_Pp151 produced a fourth genotype for the Hawaiian isolate of P. psidii. Markers revealed that all Australian isolates were genetically similar to the one from Hawaii. There was no genetic variation among the Australian isolates of P. psidii, supporting the hypothesis that only one genotype of P. psidii was introduced into Australia. The SSR markers developed in this study are highly specific to P. psidii and can be used confidently as a new profiling tool to monitor evolution of P. psidii in Australia and elsewhere.
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