Powdery mildew caused by Erysiphe corylacearum: An emerging problem on hazelnut in Italy.

Erysiphe corylacearum has recently been reported in northern Italy (Piedmont) and other European countries as the causal agent of a new emerging powdery mildew on hazelnut. This disease is much more dangerous than the common hazelnut powdery mildew caused by Phyllactinia guttata as it significantly reduces yield and quality of hazelnuts. This study aimed to perform morphological and molecular characterization of the fungal isolates from powdery mildew-infected plants in the Piedmont Italian region. Additionally, genetic diversity studies and pathogenicity tests were conducted. Thirty-six fungal isolates originating from symptomatic hazelnut plants exhibiting specific powdery mildew symptoms on the superior leaf side were identified morphologically as E. corylacearum. Single- and multilocus sequence typing of five loci (ITS, rpb2, CaM, GAPDH and GS) assigned all isolates as E. corylacearum. Multilocus and GAPDH phylogenetic studies resulted in the most efficient characterization of E. corylacearum. Studied fungal isolates were able to cause new emerging powdery mildew disease by fulfilling Koch's postulates. The emergence of powdery mildew disease in Italy revealed the E. corylacearum subgrouping, population expansion, and high nucleotide similarity with other recently identified E. corylacearum hazelnut isolates. To contain this harmful disease and inhibit the fungus spread into new geographical zones, it will be necessary to implement more rigorous monitoring in neighboring hazelnut plantations near infected hazelnuts, use sustainable fungicides and search for new biocontrol agents.

An Overview of the Emergence of Plant Pathogen 'Candidatus Liberibacter solanacearum' in Europe.

In this paper, a comprehensive overview of the 'Candidatus Liberibacter solanacearum' presence in Europe was provided. The analyzed findings revealed that, since the first appearance of this pathogen in Finland and Spain in 2008, it has spread to 13 new European countries. Therefore, 'Ca. L. solanacearum' has spread very quickly across the European continent, as evident from the emergence of new host plants within the Apiaceae, Urticaceae, and Polygonaceae families, as well as new haplotypes of this pathogen. Thus far, 5 of the 15 'Ca. L. solanacearum' haplotypes determined across the globe have been confirmed in Europe (haplotypes C, D, E, U, and H). Fully competent 'Ca. L. solanacearum' vectors include Bactericera cockerelli, Trioza apicalis, and B. trigonica; however, only T. apicalis and B. trigonica are presently established in Europe and are very important for plants from the Apiaceae family in particular. Moreover, psyllid species such as B. tremblayi, T. urticae, and T. anthrisci have also been confirmed positive for 'Ca. L. solanacearum'. Constant monitoring of its spread in the field (in both symptomatic and asymptomatic plants), use of sensitive molecular diagnostic techniques, and application of timely management strategies are, therefore, of utmost importance for the control of this destructive pathogen.

Xylella fastidiosa in Europe: From the Introduction to the Current Status.

Xylella fastidiosa is xylem-limited bacterium capable of infecting a wide range of host plants, resulting in Pierce's disease in grapevine, citrus variegated chlorosis, olive quick decline syndrome, peach phony disease, plum leaf scald, alfalfa dwarf, margin necrosis and leaf scorch affecting oleander, coffee, almond, pecan, mulberry, red maple, oak, and other types of cultivated and ornamental plants and forest trees. In the European Union, X. fastidiosa is listed as a quarantine organism. Since its first outbreak in the Apulia region of southern Italy in 2013 where it caused devastating disease on Olea europaea (called olive leaf scorch and quick decline), X. fastidiosa continued to spread and successfully established in some European countries (Corsica and PACA in France, Balearic Islands, Madrid and Comunitat Valenciana in Spain, and Porto in Portugal). The most recent data for Europe indicates that X. fastidiosa is present on 174 hosts, 25 of which were newly identified in 2021 (with further five hosts discovered in other parts of the world in the same year). From the six reported subspecies of X. fastidiosa worldwide, four have been recorded in European countries (fastidiosa, multiplex, pauca, and sandyi). Currently confirmed X. fastidiosa vector species are Philaenus spumarius, Neophilaenus campestris, and Philaenus italosignus, whereby only P. spumarius (which has been identified as the key vector in Apulia, Italy) is also present in Americas. X. fastidiosa control is currently based on pathogen-free propagation plant material, eradication, territory demarcation, and vector control, as well as use of resistant plant cultivars and bactericidal treatments.

Oxidative Stress and Antioxidative Activity in Leaves and Roots of Carrot Plants Induced by Candidatus Phytoplasma Solani.

The present study examined the effects of Candidatus Phytoplasma solani infection on antioxidative metabolism in leaves and roots of carrot (Daucus carota L.). Disease symptoms appeared at the end of June in the form of the chlorosis on some of the leaves, which became intensely red one week later, while the previously healthy leaves from the same branch becme chlorotic. A few days later, all leaves from the infected leaf branch were intensely red. Infected plants also had slower growth compared to the healthy ones with fewer leaf branches developed. The roots of infected plants were less developed, seared, or gummy with or without brown-colored root hair. The presence of the pathogen was detected by sequencing the 16S rRNA. National Center for Biotechnology Information (NCBI) BLAST analyses of the obtained sequence revealed 100% identity of tested strain with deposited Ca. Phytoplasma solani strains from various countries and hosts, all belonging to the "stolbur" group (16SrXII-A). Identity of 99.74% was found when the tested Serbian strain (MF503627) was compared with the reference stolbur strain STOL11 (AF248959). The oxidative damage of membranes in carrot cells was accompanied by a decrease in the content of photosynthetic pigments. Furthermore, for the determination of specific scavenging properties of the extracts, in vitro antioxidant assay was performed. In phytoplasma-infected carrot leaves, there was a greater reduction in the level of glutathione content (GSH); however; flavonoids and anthocyanidins seem to be responsible for the accompanied increased antioxidative capacity against hydroxyl radical and hydrogen peroxide.

First report of 'Candidatus Liberibacter solanacearum' on carrot in Serbia.

At the beginning of July 2020, three-month-old carrot plants (Daucus carota L. variety Maestro F1) grown in a commercial field 1.2 ha in size at the Begec locality (45°14'30.38" N 19°36'44.82" E) in southern part of the Backa region, Vojvodina, Serbia, exhibited symptoms of yellowing and reddish leaf discoloration. At the end of July, leaves on the infected plants became bronze and purplish, while their shoots and roots were stunted due to dehydration, with pronounced proliferation. In some cases, the damage was so extensive that it led to plant decay. The disease incidence of 0.5-1% recorded early in July rapidly escalated, reaching 10-15% in the first ten days of August. The observed symptoms resembled those caused by 'Candidatus Liberibacter solanacearum' (CaLso), a phloem-limited proteobacterium (1). To detect and identify CaLso, 15 symptomatic diseased and 5 asymptomatic healthy carrot plants were subjected to conventional polymerase chain reactions (PCR) using two primer sets specific to CaLso, and positive PCR products were further sequenced using commercial facilities (Macrogen Europe). Total DNA was extracted from petiole and root tissues using a commercial kit (Qiagen DNEasy Plant Mini Kit) following the manufacturer-recommended protocol. In the first PCR, using the Lso TX 16/23 F/R primer pair that targets the 16S-23S rRNA IGS region specific to CaLso (2), all 15 diseased samples yielded a band of 383 bp size. After sequencing, 100% homology was noted among tested isolates; therefore, one isolate coded as 1842/20 was chosen as representative and was deposited in NCBI GenBank under Accession number MT948144. BLAST analysis showed 99.70% identity of Serbian carrot isolates with those of the CaLso isolate 80022 originating from celery seed in Slovenia or Italy (Acc. no. KY619977) (3), as well as 99.41% identity with isolate GBBC_Clso_03 from carrot in Belgium (Acc. no. MH734515) and 98.22% identity with the sequence of the CaLso reference strain NZ082226 (Acc. no. EU834130) isolated from tomato in New Zealand (4). In the second PCR, species-specific forward primer LsoF empirically designed at the signature region of the 16S rRNA sequence of CaLso (5) in combination with the universal liberibacter reverse primer OI2c (6) yielded a target of 1163 bp size in all 15 diseased symptomatic carrot samples. Representative isolate 1842/20 was deposited in NCBI GenBank under Acc. no. MW187524. Based on the nucleotide BLAST analysis, the sequence of Serbian carrot isolate showed 100% identity with CaLso strains 16-004 and 16-011 originating from carrot in Finland (Acc. no. MG701014 and MG701015, respectively) and 99.64% identity with CaLso reference strain NZ082226 (Acc. no. EU834130). Five healthy asymptomatic carrot plant samples were negative for the presence of CaLso in both PCR tests employed in this work. To our knowledge, this is the first report of CaLso causing the disease in carrot in Serbia. These results suggest a wider distribution of this pathogen than previously reported in Europe. In 2014, Psyllid Bactericera trigonica (Hemiptera, Triozidae) was described for the first time as a potential vector for CaLso transmission in few localities, including Begec (7). Considering that its vectors are presently unidentified, certain aspects of CaLso genomics, diversity, epidemiology and vector dynamics will be studied further in future investigations.