Fig rust caused by Phakopsora nishidana in South Africa

Fig rust, caused by Cerotelium fici, was first recorded in South Africa in 1927. Recent observations have revealed high incidence of rust and untimely defoliation of fig trees (Ficus carica) in residential gardens and commercial orchards. Using phylogenetic analysis, the causal organism of a fig rust isolate (PREM63073) collected in 2020 was confirmed as Phakopsora nishidana. Inoculation and microscope studies showed that mulberry plants were immune to P. nishidana isolate PREM63073. Infection of fig leaves occurred through stomata on the abaxial leaf surfaces. Very long germ tubes were observed for P. nishidana, often with no clear contact with the leaf surfaces and an apparent lack of directional growth towards stomata. Inoculated plants from 15 fig cultivars varied in their severity of leaf infection, whereas fruit of the cultivar Kadota developed reddish-brown blemishes without sporulation. Currently, C. fici and P. nishidana are recognised as occurring on F. carica in South Africa. This suggests a need to resolve the worldwide distribution and identity of the rust species involved

Potential for re-emergence of wheat stem rust in the United Kingdom

Wheat stem rust, a devastating disease of wheat and barley caused by the fungal pathogen Puccinia graminis f. sp. tritici, was largely eradicated in Western Europe during the mid-to-late twentieth century. However, isolated outbreaks have occurred in recent years. Here we investigate whether a lack of resistance in modern European varieties, increased presence of its alternate host barberry and changes in climatic conditions could be facilitating its resurgence. We report the first wheat stem rust occurrence in the United Kingdom in nearly 60 years, with only 20% of UK wheat varieties resistant to this strain. Climate changes over the past 25 years also suggest increasingly conducive conditions for infection. Furthermore, we document the first occurrence in decades of P. graminis on barberry in the UK. Our data illustrate that wheat stem rust does occur in the UK and, when climatic conditions are conducive, could severely harm wheat and barley production.</p

Language endangerment and language documentation in Africa

Non peer reviewe

Characterization of an Arabidopsis thaliana receptor like protein kinase gene activated by salicylic acid and hypo-osmotic and oxidative stresses

info:eu-repo/semantics/publishe

Development of a Diagnostic Assay for Differentiation Between Genetic Groups in Clades I, II, III, and IV of <i>Puccinia graminis</i> f. sp. <i>tritici</i>

Wheat stem rust has reemerged as a serious disease caused by new variants of Puccinia graminis f. sp. tritici. Variants with significant virulence and broad geographic distribution (Africa, Central Asia, and Europe) include the Ug99 race group, race TTRTF, and TKTTF race group. Genetic analysis has placed isolates representing these critical new virulent races into 12 genetic groups that make up clades I to IV. Development of molecular diagnostic assays for these 12 genetic groups will be an important component of global surveillance efforts. A single-nucleotide polymorphism database was mined for candidate markers that would differentiate between these 12 genetic groups. Thirty-five candidate markers were screened, and a core set of 17 markers was tested against a set of 94 isolates representing a broad range of genotypes and race phenotypes. These core markers were 100% accurate in identifying the 12 genetic groups for 52 isolates in clades I to IV, and no false positives were observed with nontarget isolates. The assay has built-in redundancy so that minor genetic changes or errors in genotyping calling will not affect the accuracy of the results. This assay is also effective in identifying the genetic groups in clade V from Germany and Georgia, the three main subgroups in North American clade VI, and clade VII consisting of race TTTTF found in North and South America. This assay provides a rapid diagnostic tool for both living and nonliving samples to detect these critical new races or race groups of P. graminis f. sp. tritici. [Formula: see text] Copyright © 2022 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license . </jats:p

Historical Development of the <i>Puccinia triticina</i> Population in South Africa

In contrast to many other countries, the virulence and genetic diversity of the South African Puccinia triticina population before 1980 is unknown, because of the absence of regular and systematic race analysis data and viable rust cultures. Herbarium specimens housed at the National Collection of Fungi, Biosystematics Unit, Plant Health and Protection, Agricultural Research Council, Pretoria, South Africa (SA), provided the opportunity to investigate the genetic development of the population using isolates collected between 1906 and 2010. Five subpopulations that survived between 21 and 82 years in the field were found. While three of these could represent the original races that entered SA during European settlement, two appear to be recent exotic introductions into SA, most probably from other African countries. The demise of the three oldest subpopulations might be from the release of resistant wheat cultivars. The population is clonal, where new virulence develops through single step mutations and selection for virulence. Although a possible case of somatic hybridization was found, sexual reproduction appears to be absent in SA. This study confirmed the importance of annual surveys in SA and its neighboring countries for the timely detection of new virulent races that could threaten wheat production in SA. </jats:p

Accomplishments in wheat rust research in South Africa

Rust diseases, although seasonal, have been severe constraints in wheat production in South Africa for almost 300 years. Rust research gained momentum with the institution of annual surveys in the 1980s, followed by race identification, an understanding of rust epidemiology, and eventually a focused collaboration amongst pathologists, breeders and geneticists. Diversity in South African populations of Puccinia triticina, P. graminis f. sp. tritici and P. striiformis f. sp. tritici has been described and isolates are available to accurately phenotype wheat germplasm and study pathogen populations at national, regional and global levels. Sources of resistance have been, and still are, methodically analysed and molecular marker systems were developed to incorporate, stack and verify complex resistance gene combinations in breeding lines and cultivars. Vigilance, capacity, new technologies, collaboration and sustained funding are critical for maintaining and improving the current research impetus for future management of these important diseases. Significance: Rust diseases threaten wheat crops worldwide, including in South Africa. Management of rusts includes regular surveillance, pathogen diversity studies, rigorous screening of wheat germplasm, and efficient breeding and selection for resistance. Collaboration among plant pathologists, geneticists and breeders has provided momentum in rust research and control in South Africa in recent years