Unreported Post-harvest Disease of Apples Caused by Plenodomus collinsoniae in Korea

Research Article
Kallol Das1Yeong-Hwan Kim1Jingi Yoo2Leonid N. Ten1Sang-Jae Kang1In-Kyu Kang3Seung-Yeol Lee1,4*Hee-Young Jung1,4

Abstract

This study was conducted to isolate and identify the fungal pathogen caused unreported post-harvest disease on apples (cv. Fuji) fruit in Korea. The disease symptoms on apples appeared as irregular, light to dark brown, slightly sunken spots. The three fungal strains were isolated from infected tissues of apple fruits and their cultural and morphological characteristics were completely consistent with those of Plenodomus collinsoniae. The phylogenetic analysis using the internal transcribed spacer (ITS) regions, beta-tubulin (TUB), and the second largest subunit of RNA polymerase II (RPB2) sequences revealed the closest relationship of the isolates with Plenodomus collinsoniae at the species level. The pathogenicity test showed the same dark brown spots on Fuji apple cultivar. Therefore, P. collinsoniae is a newly reported fungal agent causing post-harvest disease on apples in Korea.

Keyword



Introduction

Apple (Malus domestica) is a commercially important and widely grown crop in the temperate regions of the world [1]. It is one of the world's leading fruits, with an estimated production of 89,329,179 tons [2]. Each country and region has local own cultivars and some cultivars are familiar all over the world [3]. However, post-harvest diseases of fruits cause heavy losses during storage resulting in considerable economic losses. To date, approximately 40 pathogens were identified as the causative agents of apple diseases [4], among them apple blotch, anthracnose, white rot, Alternaria leaf spot, and bacterial shoot blight have serious economic implication for apple cultivation [5]. Several causal agents of various diseases have been identified on apple fruits such as Colletotrichum spp. [6], Botryosphaeria dothidea [7], Marssonina coronaria [8], and Fusarium decemcellulare [9]. Recently, the abnormal fruit rot symptoms were observed during the screening of post-harvest diseases on apple fruits, which were collected from orchard located in Gunwi (36°16'27.1"N 128°28'17.6"E), Korea and stored under low-temperature conditions. In the present study, the isolated fungal strains are described and illustrated as a causal agent of newly recorded post-harvest disease on apples in Korea.

The symptoms of fruit rot disease were initially brown, later dark brown to dark red spots, irregular in shape (Fig. 1A-D), which were clearly differentiated from the typical symptoms of apple anthracnose, white rot, or Fusarium fruit rot. To isolate the causal agent from the abnormal spots, the surface of an apple was wiped with 70% ethanol and the diseased peel was removed using a sterilized blade. Then, the surface of the collected diseased tissues was sterilized for 30 seconds in 70% ethanol and 1% sodium hypochlorite and washed three times with sterilized double-distilled water. The surface-sterilized tissues were transferred onto potato dextrose agar (PDA; Difco, Detroit, MI, USA) plates and maintained in an incubator at 25℃ [10]. As the result, the three strains were isolated from the diseased apples and then designated as KNU-20-A1, KNU-20-A2, and KNU-20-A3. To analyze the cultural characters, PDA, oatmeal agar (OA; Difco, Detroit, MI, USA) and autoclaved pine needle on 2% water agar (PNA) were prepared for the detail description of the isolated fungal strains [11]. After 10 days of incubation on PDA at 25℃, the colonies were 23-25 mm in diameter, gray to dark gray with white margin, circular to irregular with yellow pigmented halo around the colonies, reverse brown to dark brown with white margin (Fig. 1E and F). On OA, the colonies were 36-38 mm in diameter, white to gray in center, floccose, reverse brown with yellow margin (Fig. 1G and H). After 4 weeks of incubation, pycnidia-like conidiomata structures were appeared on OA and PNA, round to irregular, solitary to aggregate, and dark brown to black, and with the diam. of 600-750 μm (Fig. 1M and N). However, no conidial structures were observed. The strains also produced wide hyphae, branched mycelium, septate, smooth, brown, and light brown chlamydospores on PDA (Fig. 1O and P). The cultural and morphological characteristics were found to be similar with those of previously identified Plenodomus collinosinae (Table 1) [12]. The type strain of Leptosphaeria collinsoniae (=Plenodomus collinsoniae) has been reported as a sexual morph on the host called Collinsonia canadensis, and after that the strain was also combined with the strain P. collinsoniae CBS 120227 isolated from Vitis coignetiae, with the Perithecia; scattered, gradually blackening the stems, covered by the cuticle, finally bare, globose-conic, rugose, papillate, Asci; terete, short-stipitate, Sporidia; amber colored, biseriate, 5-8-septate, mostly 6-nucleate, and the asexual morph was not determined [13].

http://dam.zipot.com:8080/sites/kjom/images/N0320480415_image/Figure_KJOM_48_04_15_F1.png

Fig. 1.Disease symptoms, cultural and morphological characteristics, and pathogenicity test on apples (cv. Fuji) with inoculation using colony agar blocks of Plenodomus collinsoniae KNU-20-A1. (A-D): Primary symptoms; (E, F): Colony of strain KNU-20-A1 on potato dextrose agar (PDA) after 10 days; (G,H): Colony of strain KNU-20-A1 on oatmeal agar (OA) after 10 days; (I, J): Inoculation after 14 days; (K, L): Enlarged picture; M: After 30 days, pycnidia-like structures on PNA (pine needle agar); (N): After 30 days, pycnidia-like structures on OA agar; (O, P): Hyphal structures of P. collinsoniae KNU-20-A1 (scale bars: M, N=500 μm; O, P=10 μm).

Table 1. Morphological characteristics of the strain KNU-20-A1 with reference to P. collinsoniae. http://dam.zipot.com:8080/sites/kjom/images/N0320480415_image/Table_KJOM_48_04_15_T1.png

PDA: Potato dextrose agar; PNA: Pine needle agar; OA: Oatmeal agar.

a Fungal strain studied in this paper, b Source of the description [12].

For molecular identification, the total genomic DNA was extracted from the three above-mentioned strains using a HiGene Genomic DNA prep kit (BIOFACT, Daejeon, Korea) following the manufacturer's instructions. The ITS regions, beta-tubulin (TUB), and the second largest subunit of RNA polymerase II (RPB2) genes were amplified using the primer sets ITS1F/ITS4 [14,15], Btub2Fd/Btub4Rd [16], and RPB2-5F2/fRPB2-7cR [17], respectively. Amplified PCR products were purified with EXOSAP-IT (Thermo Fisher Scientific, Waltham, MA, USA) and sequenced by Macrogen Co., Ltd. (Daejeon, Korea). From the sequence analysis, sequences from the strains KNU-20-A1 (525, 344, and 1062 bp), KNU-20-A2 (567, 346, and 1046 bp), and KNU-20-A3 (553, 328, and 1035 bp) were obtained from the ITS regions, TUB, and RPB2 genes, accordingly. Comparative sequence analyses of the molecular markers of the three strains revealed high similarities of 99.8-100%, indicating their affiliation to the same species. A BLAST search of the NCBI database using sequences of ITS regions revealed the highest similarity of strains KNU-20-A1, KNU-20-A2, and KNU-20-A3 with Plenodomus collinsoniae CBS 120227 (99.6%). And the closest species P. influorescens CBS 143.84 and P. visci CPC 35316 showed maximum 92.1-92.5% and 90.4%, respectively from the ITS regions. The partial sequences of RPB2 gene of the three strains shared maximum 98.7% identity with that of P. collinsoniae CBS 120227, and only 89.4% and 90.7% similarities with the other closest relative, P. influorescens CBS 143.84 and P. visci CBS 122783, respectively. Based on the TUB gene sequence the three above-mentioned strains were close to P. collinsoniae CBS 120227 (97.9-98.2%), P. influorescens CBS 143.84 (85.4-86.1%), and P. visci CBS 122783 (86.8-87.5%). Using the three molecular markers, ITS regions, RPB2 and TUB genes, the closest neighbor of the three isolated strains were determined to be P. collinsoniae with the high values of the sequence similarities of 97.9-99.6% while no difference in sequences containing more or less base pairs between the markers from the isolated fungal strains. To confirm the relationship of the above-mentioned strains with P. collinsoniae at the species level, phylogenetic analysis using concatenated sequences of the ITS regions, TUB and RPB2 genes were performed. The sequences of allied species were retrieved from the National Center for Biotechnology Information (NCBI) (Table 2). Phylogenetic trees were constructed using neighbor-joining (NJ) [18], maximum-likelihood (ML) [19], and maximum-parsimony (MP) [20] methods, as implemented in MEGA7.0 [21]. The alignments were performed for each gene, and then the sequences were merged by using MEGA7.0 software program. The NJ analysis was performed using Kimura two-parameter distances [22] with gaps excluded from the analysis. A bootstrap analysis with 1000 replicate was performed to assess the support for clusters. In the phylogenetic tree (Fig. 2) all isolated strains occupied a position within the genus Plenodomus and clustered together with P. collinsoniae, indicating their closest relationship at the species level. Thus, strains KNU-20-A1, KNU-20-A2, and KNU-20-A3 were identified as P. collinosinae based on multi-locus phylogenetic analysis along with their cultural and morphological characteristics, which were completely consistent with those previously reported for this fungal species [12,13].

http://dam.zipot.com:8080/sites/kjom/images/N0320480415_image/Figure_KJOM_48_04_15_F2.png

Fig. 2.Neighbor-joining phylogenetic tree based on the concatenated sequences of the internal transcribed spacer (ITS) regions, beta-tubulin (TUB), and RNA polymerase II (RPB2) genes showing the phylogenetic position of the three isolated strains (KNU-20-A1, KNU-20-A2, KNU-20-A3) among Plenodomus species and other closely related taxa. Bootstrap values (based on 1000 replications) greater than 50% are shown at branch points. The isolated strains are shown in bold. Bar, 0.02 substitutions per nucleotide position.

Table 2. List of species used in phylogenetic analyses with the GenBank accession numbers. http://dam.zipot.com:8080/sites/kjom/images/N0320480415_image/Table_KJOM_48_04_15_T2.png

ITS: internal transcribed spacer; RPB2: RNA polymerase II; TUB: beta-tubulin.

The newly generated sequences indicated in bold.

To confirm the pathogenicity of P. collinosinae isolated in this study, KNU-20-A1 was selected as the representative from the three strains and inoculated into healthy apples (cv. Fuji) fruits with three replications. The inoculum was prepared using strain KNU-20-A1 cultured for 4 weeks on PDA. The surface of a healthy apple was wiped with 70% EtOH and then air-dried. Two points of apple were wounded using a sterilized needle and colony agar blocks were attached and sealed using foil. Apple fruits inoculated with sterilized water were used as the control. All the inoculated fruits were incubated at 25℃, and after 3 days the colony agar blocks were removed. After 14 days, brown with slightly sunken spots were observed on apples which were identical to typical primary symptoms (Fig. 1I-L) while no symptoms were observed in unwounded fruits (data not shown). From each of the inoculated fruits P. collinosinae was re-isolated and the cultural and morphological characteristics were compared with those of the inoculated strains, and all characteristics were found to be the same (Table 1).

In a previous study, the members of the Plenodomus seem to be cosmopolitan in distribution, since they have been recorded from both temperate and tropical countries (i.e. China, Greece, France, Japan, Netherlands, Peru, Spain, Taiwan) [23]. Until recent, 100 epithets of Plenodomus have been listed in the Index Fungorum database [24]. The host specificity of Plenodomus has not yet been clarified based on species from different plant families (Asteraceae, Lamiaceae, Liliaceae) [13]. P. meliloti was a low-temperature parasitic fungus found only in the provinces of Alberta and Saskatchewan in Canada [25], whereas, P. morganjonesii was obtained from partially degraded leaves from New Jersey [26]. P. chrysanthemi was isolated as an endophyte of Chenopodium album that represents a new host from Iran [27]. The causal agent of foot rot and storage tuber rot on sweet potato was identified as P. destruens from experimental fields in China [28]. A novel species, P. sinensis was introduced from Tamarindus indica L. (Fabaceae) and Plukenetia volubilis L. (Euphorbiaceae) in Yunnan Province, China [29]. Moreover, Brown root rot, caused by the fungal pathogen Phoma sclerotioides (=Plenodomus meliloti), was associated with winterkill, slow emergence from winter dormancy, and yield loss of alfalfa (Medicago sativa L.), and also was a problem with severe winters in Alaska and Alberta, Saskatchewan and Manitoba, Canada [30]. Although many fungal species belonging to the genus Plenodomus were isolated in several countries from diversified hosts, only P. destruens was reported as causing agent of storage tuber rot of sweet potato in Korea [31], but there are no studies of P. collinsoniae related to plant diseases in Korea. Recently, there are two species of Plenodomus, namely P. sinensis and P. collinsoniae that were isolated from a soil sample collected in abandoned apple orchard in Gyeongsangbuk-do, Korea [12]. Even, there is no enough information that the genus Plenodomus can cause diseases in apples, but there might be a relation or transfer of causal agents from soil to apples trees or fruits as well as causing disease. Furthermore, the genus Plenodomus includes several well-known important plant pathogens and is found as opportunistic fungi on several hosts. In this study, the strains were isolated from the infected disease apples (cv. Fuji) fruit and identified the fungal pathogen caused post-harvest disease on apples in Korea.

Furthermore, based on the results of pathogenicity test, the disease symptoms appeared very slowly on the inoculated apple fruits, so it is assumed that it can be observed in the long-term stored period in the low-temperature storage room condition. Still, there were no reported apple diseases caused by Plenodomus species in Korea. According to the results of the present study, P. collinsoniae can be a new fungal agent of the post-harvest disease of apple, and the ecology of P. collinsoniae should be further studied for the proper control. In conclusion, this is the first report of post-harvest disease on apple caused by P. collinsoniae in Korea.

Acknowledgements

This work was carried out with the support of Cooperative Research Program for Agriculture Science and Technology Development (Project No. PJ013827032020), funded by the Rural Development Administration, Republic of Korea.

References

1  1. Arseneault MH, Cline JA. A review of apple preharvest fruit drop and practices for horticultural management. Sci Hortic 2016;211:40-52.  

2 2. FAOSTAT. Food and agricultural organization statistical database. Rome: FAOSTAT; 2017.  

3 3. Sansavini S, Donati F, Costa F, Tartarini S. Advances in apple breeding for enhanced fruit quality and resistance to biotic stresses: New varieties for the European market. J Fruit Ornam Plant Res 2004;12:13-52.  

4 4. The Korean Society of Plant Pathology. List of plant diseases in Korea. 5th ed. Seoul: Korean Society of Plant Pathology; 2009.  

5 5. Cheon W, Jeon Y. Survey of major diseases occurred on apple in northern Gyeongbuk from 2013 to 2014. Res Plant Dis 2015;21:261-7.  

6 6. Lee DH, Kim D, Jeon Y, Uhm JY, Hong SB. Molecular and cultural characterization of Colletotrichum spp. causing bitter rot of apples in Korea. Plant Pathol J 2007;23:37-44.  

7 7. Uhm JY. Reduced fungicide spray program for major apple diseases Korea. Anyang: Agriculture and Horticulture Press; 2010.  

8 8. Back CG, Jung HY. Biological characterization of Marssonina coronaria infecting apple trees in Korea. Kor J Mycol 2014;42:183-90.  

9 9. Lee SY, Park SJ, Lee JJ, Back CG, Ten LN, Kang IK, Jung HY. First report of fruit rot caused by Fusarium decemcellulare in apples in Korea. Kor J Mycol 2017;45:54-62.  

10 10. Phookamsak R, Hyde KD, Jaewon R, Bhat DJ, Jones EBG, Maharachchikumbura SSN, Rasoe O, Karunarathna SC, Wanasinghe DN, Hongsanan S, et al. Fungal divers notes 929-1035: Taxonomic and phylogenetic contributions on genera and species of fungi. Fungal Divers 2019;95:1-273.  

11 11. Marin-Felix Y, Groenewold JZ, Cai L, Chen Q, Marincawitz S, Barnes L, Braun U, Camporesi E, Damm U, de Beer ZW, et al. Genera of phytopathogenic fungi: GOPHY 1. Stud Mycol 2017;86:99-216.  

12 12. Moe TN, Das K, Kang IK, Lee SY, Jung HY. Morphological and phylogeny of Plenodomus sinensis and P. collinsoniae, two unreported species isolated from soil in Korea. Kor J Mycol 2020;48:187-95.  

13 13. De Gruyter J, Woudenberg JHC, Aveskamp MM, Verkley GJM, Groenewald JZ, Crous PW. Redisposition of Phoma like anamorphs in Pleosporales. Stud Mycol 2013;75:1-36.  

14 14. Gardes M, Bruns T. ITS primers with enhanced specificity for basidiomycetes-application to the identification of mycorrhizae and rusts. Mol Ecol 1993;2:113-8.  

15 15. White TJ, Bruns T, Lee S, Taylor JW. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. Innis MA, Gelfand DH, Sninsky JJ, White TJ, editors. PCR Protocols: A guide to methods and applications. San Diego: Academic Press; 1990. p. 315-22.  

16 16. Woudenberg JH, Aveskamp MM, de Gruyter J, Spiers AG, Crous PW. Multiple Didymella teleomorphs are linked to the Phoma clematidina morphotype. Persoonia 2009;22:56-62.  

17 17. Liu YJ, Whelen S, Hall BD. Phylogenetic relationships among ascomycetes: evidence from an RNA Polymerase II subunit. Mol Biol Evol 1999;16:1799-808.  

18 18. Saitou N, Nei M. The neighbor-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol 1987;4:406-25.  

19 19. Felsenstein J. Evolutionary trees from DNA sequences: A maximum likelihood approach. J Mol Evol 1981;17:368-76.  

20 20. Fitch WM. Toward defining the course of evolution: Minimum change for a specific tree topology. Syst Zool 1971;20:406-16.  

21 21. Kumar S, Stecher G, Tamura K. MEGA7: Molecular evolutionary genetics analysis version 7.0 for bigger datasets. Mol Biol Evol 2016;33:1870-4.  

22 22. Kimura M. A simple method for estimating evolutionary rates of base substitutions through comparative studies of nucleotide sequences. J Mol Evol 1980;16:111-20.  

23 23. Farr DF, Rossman AY. Fungal databases, systematic mycology and microbiology laboratory. Maryland: ARS, USDA; 2017.  

24 24. Index Fungorum. Index Fungorum [Internet]. Kew: Royal Botanic Gardens Kew; 2020 [cited 2020 Apr 20]. Available from: http://www.indexfungorum.org.  

25 25. Sanfordg B. A root rot of sweet clover and related crops caused by Plenodomus meliloti Dearness and Sanford. Can J Res 1933;8:337-48. 26. Torres MS, Bergen M, Singh S, Bischoff J, Sullivan RF, White Jr JE. Plenodomus morganjonesii sp. nov. and a discussion of the genus Plenodomus. Mycotaxon 2005;93:333-44.  

26 26. Torres MS, Bergen M, Singh S, Bischoff J, Sullivan RF, White Jr JE. Plenodomus morganjonesii sp. nov. and a discussion of the genus Plenodomus. Mycotaxon 2005;93:333-44.  

27 27. Khodaei S, Arzanlou M, Pertot I. Multigene phylogeny and morphology reveals novel records and hosts for coelomycetous fungi in Iran. Nova Hedwigia 2020;110:157-73.  

28 28. Gai Y, Ma H, Chen X, Zheng J, Chen H, Li H. Stem blight, foot rot and storage tuber rot of sweet potato caused by Plenodomus destruens in China. J Gen Plant Pathol 2016;82:181-5.  

29 29. Tennakoon DS, Phookamsak R, Wanasinghe DN, Yang JB, Lumyong S, Hyde KD. Morphological and phylogenetic insights resolve Plenodomus sinensis (Leptosphaeriaceae) as a new species. Phytotaxa 2017;324:73-82.  

30 30. Wunsch MJ, Dillon MA, Torres R, Schwartz HF, Bergstrom GC. First report of brown root rot of alfalfa caused by Phoma sclerotioides in Colorado and New Mexico. Plant Dis 2008;92:653.  

31 31. Paul NC, Nam SS, Park W, Yang JW, Kachroo A. First report of storage tuber rot in sweet potato (Ipomoea batatas) caused by Plenodomus destruens in Korea. Plant Dis 2019;103:1020.