Huanglongbing (HLB, Asian Citrus Greening), the most devastating disease of citrus has not been detected in southern Africa (Gottwald, 2010). HLB is associated with 'Candidatus Liberibacter asiaticus' (CLas), a phloem-limited bacterium vectored by Diaphorina citri Kuwayama (Hemiptera: Liviidae), the Asian Citrus Psyllid (ACP). African Citrus Greening, associated with 'Candidatus Liberibacter africanus' (CLaf) and its vector the African Citrus Triozid, Trioza erytreae (Del Guercio) (Hemiptera: Triozidae), are endemic to Africa, although not previously reported from Angola. African Greening is less severe than HLB, largely due to heat sensitivity of CLaf and its vector. Introduction of HLB into southern Africa would be devastating to citrus production in commercial and informal sectors. Concern was raised that CLas or ACP might hae inadvertently been introduced into Angola. In July 2019, a survey was conducted in two citrus nurseries in Luanda and Caxito and in different orchards on 7 farms surrounding Calulo and Quibala. Yellow sticky traps for insects were placed at the various localities and collected after c. 3 weeks. Breeding signs of T. erytreae (pit galls) were observed on citrus in some locations, but no insect vectors were detected on traps. Trees were inspected for signs and symptoms of citrus pests and diseases, particularly those that resemble HLB (foliar blotchy mottle, shoot chlorosis, vein yellowing and corking, lopsided fruit with aborted seeds and colour inversion) and its vectors (pit galls on leaves or waxy exudates). Leaves and shoots with suspect symptoms were sampled for laboratory analysis (43 samples). DNA was extracted from petiole and midrib tissue of leaves using a modified CTAB extraction protocol of Doyle and Doyle (1990). Real-time PCR was done using universal Liberibacter primers of Roberts et al. (2015), CLaf specific primers of Li et al. (2006) and CLas specific primers of Bao et al. (2019). All real-time PCR protocols indicated the presence of CLaf in 6 samples (Tab. S1). CLas or other citrus Liberibacter species were not detected. The presence of CLaf in sample 37 was confirmed by constructing a library (NEXTFLEX® DNA Sequencing Kit, PerkinElmer) with extracted DNA and performing high-throughput sequencing on an Ion Torrent™ S5™ platform (Central Analytical Facility, Stellenbosch University). To improve the quality of the reads, all 233,617,700 obtained reads were trimmed from the 3' end to a maximum length of 240 nt using Trimmomatic (Bolger et al. 2014). The high quality reads were mapped to the Citrus sinensis reference genome (NC_023046.1) using Bowtie 2.3.4 (Langmead and Salzberg 2012) to subtract all the reads that had high identity to the host plant (number of mismatches allowed in the seed was set to 1). The 14,691,369 unmapped reads (6.2% of original data) were mapped to the CLaf reference genome NZ_CP004021.1 using CLC Genomics Workbench 10.1.1 (Qiagen) (Length fraction = 0.8; Similarity fraction = 0.9). A CLaf consensus genome was generated that spanned 99.7% of the reference genome and the 163001 mapped reads had a 22.9 mean read coverage. The consensus sequence was 99.7% identical to NZ_CP004021.1 and was submitted to Genbank as accession: CP054879. The positive CLaf detections were from trees with typical HLB or African Citrus Greening symptoms, viz. lopsided fruit with green stylar ends, aborted seed and stained columella at base of fruit button; yellow shoots with leaves showing symptoms of blotchy mottle and vein yellowing and corking (Fig. S1) in a commercial citrus farm outside Calulo and included 2 'Ponkan' mandarin (C. reticulata), 2 Valencia and 1 'Navelina' tree (C. sinensis), and a citrus nursery in Luanda (1 lime tree; C. aurantifolia) (Tab. S1). This first report of CLaf in Angola highlights the need to prevent spread by removing infected trees and managing the insect vector, as well as the need for further surveys to determine the occurrence of African Greening and its vectors in other provinces and to confirm the absence of exotic citrus pests and diseases. References Bao, M. et al. 2020. Plant Dis. 104:527 Bolger, A. M. et al. 2014. Bioinformatics. 30:2114-2120. Doyle, J.J. and Doyle, J.L. 1990. Focus 12:13 Gottwald, T.R. 2010. Annu. Rev. Phytopathol. 48:119 Langmead, B. and Salzberg, S. 2012. Nature Methods. 9:357-359. Li, W. et al. 2006. Jnl. Microbiol. Methods 66:104 Roberts, R. et al. 2015. Int. J. Syst. Evol. Micr. 65:723.
Read full abstract