Agronomy and Crop Science

Abstract “ Candidatus Liberibacter solanacearum” (Lso), transmitted by the potato psyllid ( Bactericera cockerelli ), is the causal agent of potato zebra chip, but can also infect other solanaceous plants, including peppers. Studies were conducted to investigate whether Lso could be transmitted to the next generation of plants through seeds from infected pepper plants. In 2014, jalapeno pepper plants were infested with psyllids carrying a mixture of Lso A and B (AB) at the AgriLife Research Station at Bushland. The study was again conducted in 2019 and pepper plants were infested with psyllids carrying Lso B or Lso AB. In each of the studies, noninfested plants served as controls. At harvest, fruits were collected and tested for the presence of Lso using quantitative PCR. Seeds from infected fruits were then tested for Lso. Overall, the percentage of seeds that tested positive for Lso ranged from 33% to 70%. However, Lso detection in embryos ranged only from 0% to 8%. Seed samples from Lso‐positive fruits were planted in the greenhouse to determine the impact of Lso on emergence and the incidence of Lso in emerged plants. Although plant emergence differed between some of the seeds obtained from Lso‐positive and ‐negative fruits, the overall impact of Lso on plant emergence was not consistent. However, of the 182 plants that emerged from seeds collected from infected fruits, none was positive for Lso, suggesting that seeds are unlikely to serve as sources for new Lso infections and their impact on disease epidemiology is negligible.

Changes in physiological and biochemical patterns in lucerne plants caused by the presence of ‘Candidatus Phytoplasma australasia’, which is one of the significant pathogens causing yield losses in lucerne plants, were investigated. Significant differences were evident in total chlorophyll, chlorophyll a, chlorophyll b, and protein amounts between ‘Ca. Phytoplasma australasia’-positive and negative lucerne plants. Stress-related metabolites such as phenol, malondialdehyde, and proline accumulations in ‘Ca. Phytoplasma australasia’-positive plants were remarkably higher than those of phytoplasma-negative plants. As a response to disease attack, phytoplasma-positive plants exhibited higher antioxidant enzymes (peroxidase and catalase) and non-enzymatic metabolite responses such as jasmonic and salicylic acids. We state that partial disease responses were revealed for the first time to breed resistant lucerne lines infected by ‘Ca. Phytoplasma australasia’.

AbstractPeach trees showing witches’‐broom disease symptoms in the northwest of Iran were sampled for phytoplasma detection. PCR assays and Sanger sequence analyses indicated that ʻCandidatus Phytoplasma phoeniciumʼ was associated with peach witchesʼ‐broom disease. Virtual RFLP analyses of the 16S rRNA gene indicated that ʻCa. Phytoplasma phoeniciumʼ strain, which was prevalent in the northwest of Iran belonged to 16SrIX‐C subgroup. For the genomic characterization of Iranian ʻCa. Phytoplasma phoeniciumʼ strain, total DNA extracted from the infected peach trees was subjected to Illumina next‐generation sequencing. The NGS sequencing resulted in 41157647 read pairs of raw data. The raw reads length was 150 bp and the insert size was 350 bp. Assembly and genes clustering finally resulted in 750 contigs with a total size of 228345 bp. The GC content of sequence was 33.2%, N50 value was 259 and L50 value was 256. According to NCBI‐ PGAP annotation the genome of Prunus persica phytoplasma PP2 contained 410 genes including 377 CDSs with protein, 10 rRNAs, nine tRNAs and 14 pseudogenes.

AbstractPear decline, induced by the phytoplasma 'CandidatusPhytoplasma pyri', transmitted by pear psyllids, is one of the most devastating diseases onPyrus communisin Europe and North America. Investigations of pear psyllids in 4 pear orchards in lower Austria showed the presence ofCacopsylla pyri,C. pyricolaandC. pyrisugaat all locations. PCR analyses revealed overall phytoplasma infection rates forC. pyriof 5.4%, forC. pyricola,of 4.6%, forC. pyrisugaremigrants of 9.6% and forC. pyrisugaemigrants of 0%. The rates of PCR-positiveC. pyriandC. pyricolaindividuals varied greatly in the course of the year, and the highest infection rates were observed in late summer, autumn and in late winter. In transmission experiments with healthy pear seedlings, winterform individuals ofC. pyri and C. pyricolatransmitted the pathogen to 19.2% (5 out of 26) and 4.8% (2 out of 41) of the test plants, respectively. The vectoring ability ofC. pyrisugawas experimentally proven for the first time, and in transmission experiments with remigrants, 9.5% (2 out of 21) of the pear seedlings were infected. Our data indicate a significant risk of pathogen transmission in pear orchards during the greater part of the year, especially in late winter, early spring and autumn. Multilocus sequence analysis by aid of the genesaceFandimpallowed the discrimination between 15 phytoplasma types. Three so far undescribedaceFgenotypes and four undescribedimpgenotypes were identified.

Diaphorina citri is a serious insect pest of citrus and an insect vector of Candidatus Liberibacter asiaticus (CLas) that causes Huanglongbing disease (citrus greening). In this study, we investigated the effect of the CLas pathogen on the life history parameters of D. citri at different temperature regimes. Our results demonstrated that the survival rate of first to fifth instar CLas-positive and CLas-negative D. citri fluctuate with the change in temperature over the range of 16–35 °C. Meanwhile, the mean developmental time (52.5 d) (d = day(s)) and adult longevity (5.2 d) of the CLas-positive psyllids was longer as compared to CLas-negative psyllids mean developmental time (32.81 d) and adult longevity (3.50 d) at the low- and high-temperature regimes (16 and 35 °C). However, at high temperature regimes, the significant effect of CLas-bacteria on D. citri fecundity was higher than the corresponding non-significant effect on their survivorship when compared to non-vectored psyllids. These results indicate a long-term, stable evolutionary relationship among vector-pathogen and climate change.