First report of southern blight of mung bean caused by Sclerotium rolfsii in China

Journal Pre-proof First report of southern blight of mung bean caused by Sclerotium rolfsii in China Suli Sun, Feifei Sun, Dong Deng, Xu Zhu, Canxing Duan, Zhendong Zhu PII:

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https://doi.org/10.1016/j.cropro.2019.105055

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JCRP 105055

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Crop Protection

Received Date: 10 July 2019 Revised Date:

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Accepted Date: 17 December 2019

Please cite this article as: Sun, S., Sun, F., Deng, D., Zhu, X., Duan, C., Zhu, Z., First report of southern blight of mung bean caused by Sclerotium rolfsii in China, Crop Protection (2020), doi: https:// doi.org/10.1016/j.cropro.2019.105055. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.

1

First report of southern blight of mung bean caused by Sclerotium rolfsii

2

in China

3 4

Suli Sun1, Feifei Sun1, Dong Deng1, Xu Zhu2, Canxing Duan1, Zhendong Zhu1*

5 6

1

7

Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing,

8

100081, China

9

2

National Key Facility for Crop Gene Resources and Genetic Improvement,

Nanyang Academy of Agricultural Sciences, Nanyang, Henan, 473083, China

10 11

*Correspondening author: Dr. Zhendong Zhu

12

Institute of Crop Sciences

13

Chinese Academy of Agricultural Sciences

14

12 Zhongguancun South Street

15

Beijing, 100081

16

The Republic of China

17

Tel.: +86-10-82109609

18

Fax: +86-10-82109608

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E-mail: [email protected]

20 21 22

1

1

Abstract

2

Mung bean (Vigna radiata) is an important legume crop in China. An emerging

3

mung bean disease with symptoms resembling southern blight was detected in

4

China. This study was conducted to confirm and characterize the responsible

5

pathogen through cultural and morphological characterization, and molecular

6

detection using multiple specific primers and multiple-clone sequence analysis

7

of the rDNA internal transcribed spacer (ITS) region and the translation

8

elongation factor 1α (EF1α) and RNA polymerase II subunit 2 (RPB2) genes.

9

All isolates obtained from mung bean were identified as Sclerotium rolfsii.

10

Interestingly, we found that rDNA ITS, EF1α, and RPB2 sequences of all

11

isolates consisted of two distinct types, which likely originated from different

12

nuclei. Our findings indicated that S. rolfsii isolates were heterokaryotic and

13

contain a heterozygous genome. Two trials of pathogenicity and host range

14

revealed that all S. rolfsii isolates were not only strongly virulent to mung bean

15

but also to several other important crops, indicating their potential threat to

16

future agricultural production. To our knowledge, this is the first report of S.

17

rolfsii causing southern blight on mung bean in China.

18

Keywords: Vigna radiata; Southern blight; Sclerotium rolfsii; Heterogeneity

2

1

1. Introduction

2

Mung bean [Vigna radiata (L.) R. Wilczek] is an important warm-season

3

legume crop that is mainly grown in tropical and subtropical regions in Asia,

4

including China, India, Pakistan, Thailand, Indonesia, and the Philippines (Nair

5

et al., 2013). In China, more than 20 mung bean diseases have been

6

documented to date (Cui et al., 2014; Li et al., 2016; Sun et al., 2016; Zhu and

7

Duan, 2012).

8

Sclerotium rolfsii Sacc. [teleomorph: Athelia rolfsii (Curzi) Tu & Kimbrough]

9

is a major soilborne plant pathogenic fungus with a worldwide distribution. It is

10

mainly present in warm-temperate, subtropical, and tropical regions, especially

11

under high humidity and warm conditions. S. rolfsii has a wide host range, and

12

can infect more than 500 monocotyledonous and dicotyledonous plant species,

13

commonly causing southern blight and leading to serious yield losses (Aycock,

14

1966; Punja, 1985; Punja, 1988). Recently, S. rolfsii has been continuously

15

detected on new plant hosts, including vegetables, ornamentals, grass, and

16

medicinal and leguminous crops (Galdames et al., 2010; Kwon et al., 2013;

17

Mahadevakumar et al., 2015; 2016; Shen et al., 2015; Pane et al., 2008). S.

18

rolfsii is usually characterized according to mycelial and sclerotial morphology

19

because its sexual stage (i.e., Athelia rolfsii) is not easily observed (Okabe et

20

al., 1998). However, S. rolfsii isolates originating from different hosts and

21

geographical areas frequently exhibit variable morphological characteristics

22

when cultured (Harlton et al., 1995; Okabe et al., 1998). Therefore, S. 3

1

rolfsii-specific primer pairs were recently designed based on the conserved

2

sequence within rDNA ITS regions (i.e., SCR-F/R and SRITSF/R) and within

3

the large-subunit (LSU) gene (i.e., D1–D2 region) (SRLSUF/R) (Jeeva et al.,

4

2010; Pravi et al., 2014; 2015; White et al., 1990). These three S.

5

rolfsii-specific primers could be used to accurately identify the pathogen to the

6

species level.

7

Several previous studies clarified the genetic variability in the rDNA ITS

8

regions of S. rolfsii and involved a comparison of the amplified ITS products,

9

analysis of the ITS-RFLP pattern, and construction of restriction maps (Harlton

10

et al., 1995; Okabe et al., 1998; Okabe et al., 2001; Okabe and Matsumoto,

11

2003). They indicated that field isolates of S. rolfsii may be heterokaryotic. The

12

ITS heterogeneity of S. rolfsii was also implied by the fact that the ITS regions

13

could not be directly sequenced (Nalim et al., 1995; Okabe et al., 2001).

14

The objective of the current study was to confirm the causal agent of an

15

emerging mung bean disease with the similar symptoms of southern blight,

16

using morphological and molecular characteristics of multiple genes (i.e.,

17

rDNA ITS, EF1α, and RPB2), and pathogenicity and host tests.

18 19

2. Material and methods

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2.1. Disease survey

21

In August 2017, a field disease survey of mung bean was conducted by

22

our research team in Nanyang City of Henan Province, China. The survey

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revealed the presence of southern blight symptoms similar to those caused by

24

S. rolfsii of mung bean plants in a field located in Xinye County. Incidence of 4

1

the diseased plants with symptoms is about 10% in the infected field. And the

2

diseased plants were distributed in a few spots in the field.

3

2.2. Isolation of pathogen from diseased plants

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To isolate pathogen, samples of diseased mung bean plants with typical

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southern blight symptoms or sclerotia were collected from Xinye County,

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Henan Province. Diseased basal stem sections and sclerotia were surface

7

disinfected and placed on potato dextrose agar (PDA; AoBoXing Bio-tech,

8

Beijing, China). Plates were incubated at 25 °C under a 12-h photoperiod for 2

9

to 3 days. Fungal isolates were purified by transferring single hyphal tips to

10

fresh medium.

11

2.3. Identification of the pathogen

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Five isolates were obtained and used to determine their identity. Mycelial

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plugs (diameter: 5 mm) were inoculated to the center of PDA plates (diameter:

14

9 cm). Radial mycelial growth was assessed following the overgrowth of the

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PDA plates. Young hyphae were stained with 0.03% safranin-O and 3% KOH

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aqueous solution according to the protocol described by Bandoni (1979). The

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nuclei in the stained hyphae were counted using an Olympus CX31

18

microscope (400× magnification) to determine whether cells were binucleate

19

or multinucleate. Sclerotial characteristics were also monitored after a 4-week

20

incubation, including form, size, and color. For each isolate, the diameters of

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30 randomly selected mature sclerotia were measured. Each isolate was

22

analyzed using three replicates.

23

Genomic DNA was extracted from the five fungal isolates using a CTAB

24

method with minor modifications (Allen et al., 2006). The PCR detection was

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conducted using three S. rolfsii-specific primer pairs (SCR-F/R, SRITSF/R and 5

1

SRLSUF/R) (Jeeva et al., 2010; Pravi et al., 2014; Pravi et al., 2015) (Table 1).

2

Next, PCR assays and partial sequence of three gene were conducted with

3

universal

4

EF1-983F/EF1-2218R primers in EF1α gene (Rehner and Buckley, 2005), and

5

fRPB2-5F/bRPB2-7R2 primers in the RPB2 gene (Liu et al., 1999). Then, we

6

applied a cloning method to generate sequence from the obtained amplicons

7

by

8

fRPB2-5F/bRPB2-7R2. The resulting sequences for each isolate were aligned

9

with

the

primers

three

Multalin

ITS1/ITS4

primer

pairs

in

ITS

region

ITS1/ITS4,

(White

et

al.,

EF1-983F/EF1-2218R

(http://multalin.toulouse.inra.fr/multalin/).

They

were

1990),

and

also

10

analyzed using the BLAST online tool in the GenBank database (National

11

Center for Biotechnology Information; NCBI) to compare sequence similarities.

12

2.4. Pathogenicity tests

13

Two pathogenicity trials were completed using mung bean seedlings (i.e.,

14

original host), and six other legumes [i.e., soybean (Glycine max), common

15

bean (Phaseolus vulgaris), cowpea (Vigna unguiculata), pea (Pisum sativum),

16

adzuki bean (Vigna angularis), and peanut (Arachis hypogaea)], and important

17

graminaceous species [i.e., maize (Zea mays) and wheat (Triticum aestivum)],

18

as well as one malvaceous species [i.e., cotton (Anemone vitifolia)]. All tested

19

crops were sown in 500-ml paper cups. The cups were randomly distributed on

20

a greenhouse bench and incubated at 25 ± 2 °C. The 10 to 12-day-old

21

seedlings were inoculated using the modified hypocotyl puncture technique

22

and root-drenching procedure. All plants inoculated with sterile medium were 6

1

used as negative controls. The treated plants were incubated in a misting room

2

at 25 °C under high humidity (> 90%) for 48 h and then transferred to a

3

greenhouse for an additional incubation at 25 ± 2 °C. Plants were monitored

4

every day for 4 weeks to detect symptoms caused by S. rolfsii. Pathogen was

5

re-isolated from inoculated plants to verify Koch’s postulates. All tests were

6

conducted twice.

7 8

3. Results and discussion

9

By the survey, the diseased plants of mung bean were observed with

10

symptoms similar to southern blight caused by S. rolfsii in the field. The first

11

observed above-ground symptoms on the infected plants involved the

12

yellowing of foliage (Fig. 1A) and the development of girdling stem lesions near

13

the soil line (Fig. 1B). Advanced disease development stages were

14

characterized by the growth of white mycelia on plants (Fig. 1C and D). During

15

the late disease stage, tan to brown sclerotia were produced on the basal stem

16

epidermis and on the soil surface surrounding infected plants at high moisture

17

levels (Fig. 1E). At last, infected plants gradually wilted and eventually died as

18

the disease progressed.

19

Five fungal isolates (i.e., MSB1 to MSB5) were obtained from diseased

20

mung bean plants. The mycelia of the five isolates were white in color with

21

even margins and a fluffy appearance (Fig. 2A). Colonies grew quickly and

22

covered the Petri dish (diameter: 9 cm) after 5 or 6 days. All five isolates

23

produced a considerable amount of calcium oxalate crystals, which formed a 7

1

wide halo (diameter: 5 - 6 mm) surrounding colonies (Fig. 2A). The shapes and

2

sizes of calcium oxalate crystals varied considerably, with prismatic, tetragonal,

3

druse, and irregular forms (Fig. 2B). Ansari and Agnihotri (2000) reported a

4

positive correlation between oxalic acid production and S. rolfsii virulence.

5

Their virulence may be associated with abundant oxalic acid production.

6

Colonies started to form sclerotia on the mycelia after 12 days incubation.

7

Sclerotia were initially white, but turned brown or dark brown at maturity.

8

Abundant spherical, subspherical, and irregularly shaped sclerotia were

9

observed after 28 days (Fig. 2C), with each plate containing 60 to 128 sclerotia

10

(diameter: 0.71 - 3.45 mm). Mycelia produced clamp connections, and were

11

observed to contain multiple nuclei (Fig. 2D). The observed morphology

12

characteristics were consistent with those of S. rolfsii Sacc. Previous studies

13

demonstrated a close affinity between S. rolfsii and S. delphinii (Okabe and

14

Matsumoto, 2003). In contrast, S. delphinii produces fewer (i.e., 20 to 30 per

15

plate) and larger (3 to 5 mm in diameter) sclerotia (Mahadevakumar et al.,

16

2016).

17

PCR products amplified by three specific primers (SCR-F/R, SRITSF/R

18

and SRLSUF/R) from all five isolates revealed consistent fragments of 540,

19

500, and 360 bp, respectively (Jeeva et al. 2010; Pravi et al. 2014; Pravi et al.

20

2015) (Fig. 3). The amplicons generated using the primers ITS1/ITS4,

21

EF1-983F/EF1-2218R, and fRPB2-5F/bRPB2-7R2 were approximately 700,

22

1,200, and 1,100 bp fragments, respectively (Fig. 3). Based on 10 clone 8

1

sequence alignments, all five isolates were determined to contain two distinct

2

sequence types (i.e., type 1 and type 2) for the ITS (type1: MN609999,

3

MN610001,

4

MN610002, MN610004, MN610006, MN610008), EF1α, and RPB2 regions

5

(Supplementary Fig. 1; Figs. 4 and 5). A BLASTn analysis revealed the

6

consensus ITS type 1 and type 2 sequences were 99% identical to dozens of

7

S. rolfsii (Athelia rolfsii) sequences in the NCBI GenBank database (e.g., type

8

1: HQ420816, KX186998, KU760984, JN017199, and KJ546416; type 2:

9

HM355751, GU4567776, JF966208, KT222899, and KJ552090). The BLASTn

10

analysis of the EF1α and RPB2 sequences indicated that obtained EF1α type

11

1 and type 2 sequences were highly homologous to two S. rolfsii sequences

12

(i.e., 99 and 96%) (Accession numbers: KP982854 and GU187681), and

13

obtained RPB2 type 1 and type 2 sequences were highly homologous to one S.

14

rolfsii sequence (i.e., 95 and 99%) (Accession number: GU187821). All

15

morphological and molecular characteristics confirmed that all five isolates

16

were S. rolfsii Sacc. Previous studies proved that S. rolfsii isolates contain two

17

sequence types only in the ITS region (Okabe, 2001; Okabe and Matsumoto,

18

2003). In contrast, our study firstly revealed that two sequence types are also

19

observed in the EF1α and RPB2 genes of S. rolfsii isolates based on multiple

20

cloned sequences (Figs. 4 and 5). Our results suggest that all five analyzed S.

21

rolfsii isolates contain two heterokaryotic nuclei, resulting from a distinct

22

phylogenetic history, which may have different origins via hybridization or

MN610003,

MN610005,

9

MN610007;

type2:

MN610000,

1

hyphae anastomosis between species or subgroups carrying different genome

2

types.

3

In two pathogenicity trials, all five isolates induced symptoms resembling

4

southern blight on the original host (i.e., mung bean) (Fig. 6) and other tested

5

crops, except for maize (Supplementary Fig. 2). Plants started wilting at 4 and

6

7 days after inoculation by hypocotyl puncture and mycelia root-drenching

7

procedures, respectively. Inoculated plants of all tested crops, except for

8

maize, seriously wilted and eventually died. In contrast, maize plants exhibited

9

mild symptoms, including dwarfism (Supplementary Fig. 2). Sclerotia were

10

produced at the base of stems and on the soil surface surrounding plants of all

11

inoculated crop species except for pea, adzuki bean, and maize plants (Fig. 6).

12

The five isolates were also re-isolated from symptomatic lesions in all tested

13

crops, which fulfilled Koch’s postulates. Control plants remained healthy and

14

no symptoms shown and pathogen isolation. Our pathogenicity tests indicate

15

that S. rolfsii isolates from mung bean will be a potential threat to other

16

important crops, especially legumes. It should be noted that our surveyed

17

mung bean fields represent peanut cultivation sites in China. Peanut is one of

18

the hosts of S. rolfsii and may have contributed to the accumulation of

19

pathogen inocula on mung bean (Fig. 6).

20

S. rolfsii is an important pathogenic fungus for legumes, which is the

21

causative agent of southern blight on several leguminous hosts, including

22

soybean (G. max) (Hartman et al., 1999), common bean (P. vulgaris) (Rusuku 10

1

et al., 1997), chickpea (C. arietinum) (Kokub et al., 2007), cowpea (V.

2

unguiculata) (Adandonon et al., 2004), lentil (Lens culinaris) (Shahid et al.,

3

1990), and peanut (A. hypogaea) (Bowen et al., 1992). In China, southern

4

blight caused by S. rolfsii has recently been detected on Canadian goldenrod

5

(Solidago canadensis) and Macleaya cordata (Tang et al., 2010; You et al.,

6

2015). However, there have been no reports of S. rolfsii on mung bean. To the

7

best of our knowledge, this is the first study of S. rolfsii causing southern blight

8

on mung bean in China. Our findings indicate that S. rolfsii may be a new

9

threat to mung bean and other crops, which should be carefully monitored in

10

China.

11 12

Acknowledgments

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This study was supported by the Modern Agro-industry Technology Research

14

System (CARS-09), the Crop Germplasm Conservation and Utilization

15

Program (2019NWB036-12), the National Infrastructure for Crop Germplasm

16

Resources (NICGR2019-008), and the Scientific Innovation Program of the

17

Chinese Academy of Agricultural Sciences.

18

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Sclerotium rolfsii on Macleaya cordata in China. Plant Dis. 100, 530.

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Zhu, Z.D., Duan, C.X., 2012. Identification and control of diseases and pests in

14

mung bean. Beijing, China Agriculture Science and Technology Press (in

15

Chinese).

16 17

16

1 2

Table 1. Details of six primer pairs used to detect Sclerotium rolfsii and clone fragments for subsequent sequence analyses. Primer name SCR-F/SCR-R SRITSF/SRITSR

Primer sequence (5′—3′) CGTAGGTGAACCTGCGGA / CATACAAGCTAGAATCCC TACACCTGTGAACCAACTG / CATACAAGCTAGAATCCC

Denature temperature

PCR product size

Target region gene

54℃

540bp

ITS

Jeeva et al. 2010

50℃

500bp

ITS

Pravi et al. 2014

D1/D2 domain LSU

or

SRLSUF/SRLSUR

AGTGTTTTCTGTGCTGGG / ACCTTCCTCTGGCCTTTTTC

62℃

360bp

ITS1/ITS4

TCCGTAGGTGAACCTGCGG / TCCTCCGCTTATTGATATGC

55℃

700bp

ITS

EF1-983F/EF1-2218R

GCYCCYGGHCAYCGTGAYTTYAT /ATGACACCRACRGCRACRGTYTG

60℃

1200bp

EF1α

fRPB2-5F/bRPB2-7R2

GAYGAYMGWGATCAYTTYGG /ACYTGRTTRTGRTCNGGRAANGG

62℃

1100bp

5-7 domain of RPB2

3 4

17

of

Reference

Pravi et al. 2015 White et al. 1990 Rehner and Buckley 2005; Matheny et al. 2007 Liu et al. 1999; Matheny et al. 2007

1

Figure Legends

2 3

Fig. 1. Southern blight symptoms caused by Sclerotium rolfsii on field-grown mung

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bean plants. A, Overview of the occurrence of southern blight on mung bean plants.

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The foliage of infected plants turned yellow. B, White mycelial initials near the soil line

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of infected plants. C and D, Characteristic southern blight symptoms with abundant

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white mycelial growth on basal stems. e, White and brown sclerotia on the surface of

8

basal stems.

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Fig. 2. Morphology of Sclerotium rolfsii isolates from diseased mung bean plants. A,

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Two-day-old colony with white and fluffy mycelia with even margins and a halo formed

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by calcium oxalate crystals. B, A 4-week-old colony produced prismatic, tetragonal, or

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irregular shaped calcium oxalate crystals. C, Tan to brown sclerotia were produced on

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potato dextrose agar. D, Mycelia produced clamp connections, and multinucleate

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cells were observed in the stained mycelia (scale bar: 10 µm).

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Fig. 3. Polymerase chain reaction amplification patterns of five Sclerotium rolfsii

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isolates. A, Amplification products for five S. rolfsii isolates using the SCR-F/R,

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SRITSF/R, and SRLSUF/R three species-specific primer pairs. B, Amplification

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products for five S. rolfsii isolates using three primer pairs for the rDNA ITS, EF1α,

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and RPB2 sequences, which were used for sequencing by cloning. (M: marker ladder;

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1: MSB1; 2: MSB2; 3: MSB3; 4: MSB4; 5: MSB5)

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Fig. 4. Comparison of the sequences of 10 EF1α clone fragments from Sclerotium

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rolfsii

isolate

MSB1

amplified

by

polymerase 18

chain

reaction

using

the

1

EF1-983F/EF1-2218R primer pair. The comparison revealed two distinct sequence

2

types, with three type 1 and seven type 2 sequences, respectively.

3 4

Fig. 5. Comparison of the sequences of 10 RPB2 clone fragments from Sclerotium

5

rolfsii

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fRPB2-5F/bRPB2-7R2 primer pair. The sequences spanned domains 5 to 7 of RPB2

7

gene. The comparison revealed two distinct sequence types, with four type 1 and

8

six type 2 sequences.

isolate

MSB1

amplified

by

polymerase

chain

reaction

using

the

9 10

Fig. 6. Pathogenicity tests on mung bean (A) and peanut (B) seedlings inoculated

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with Sclerotium rolfsii isolate MSB1 using a mycelia root-drenching procedure.

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Inoculated mung bean and peanut plants wilted and died. Brown to dark brown

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sclerotia were produced on the basal stems and on the soil surface surrounding

14

infected plants.

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Fig. 1. Southern blight symptoms caused by Sclerotium rolfsii on field-grown mung bean plants. A, Overview of the occurrence of southern blight on mung bean plants. The foliage of infected plants turned yellow. B, White mycelial initials near the soil line of infected plants. C and D, Characteristic southern blight symptoms with abundant white mycelial growth on basal stems. e, White and brown sclerotia on the surface of basal stems.

Fig. 2. Morphology of Sclerotium rolfsii isolates from diseased mung bean plants. A, Two-day-old colony with white and fluffy mycelia with even margins and a halo formed by calcium oxalate crystals. B, A 4-week-old colony produced prismatic, tetragonal, or irregular shaped calcium oxalate crystals. C, Tan to brown sclerotia were produced on potato dextrose agar. D, Mycelia produced clamp connections, and multinucleate cells were observed in the stained mycelia (scale bar: 10 µm).

Fig. 3. Polymerase chain reaction amplification patterns of five Sclerotium rolfsii isolates. A, Amplification products for five S. rolfsii isolates using the SCR-F/R, SRITSF/R, and SRLSUF/R three species-specific primer pairs. B, Amplification products for five S. rolfsii isolates using three primer pairs for the rDNA ITS, EF1α, and RPB2 sequences, which were used for sequencing by cloning. (M: marker ladder; 1: MSB1; 2: MSB2; 3: MSB3; 4: MSB4; 5: MSB5)

Fig. 4. Comparison of the sequences of 10 EF1α clone fragments from Sclerotium rolfsii isolate MSB1 amplified by polymerase chain reaction using the EF1-983F/EF1-2218R primer pair. The comparison revealed two distinct sequence types, with three type 1 and seven type 2 sequences, respectively.

Fig. 5. Comparison of the sequences of 10 RPB2 clone fragments from Sclerotium rolfsii isolate MSB1 amplified by polymerase chain reaction using the fRPB2-5F/bRPB2-7R2 primer pair. The sequences spanned domains 5 to 7 of RPB2 gene. The comparison revealed two distinct sequence types, with four type 1 and

six type 2 sequences.

Fig. 6. Pathogenicity tests on mung bean (A) and peanut (B) seedlings inoculated with Sclerotium rolfsii isolate MSB1 using a mycelia root-drenching procedure. Inoculated mung bean and peanut plants wilted and died. Brown to dark brown sclerotia were produced on the basal stems and on the soil surface surrounding infected plants.

Highlights This study is the first report of S. rolfsii causing southern blight on mung bean in China. Characterization of S. rolfsii was confirmed by morphological and molecular identification. This study proved S. rolfsii isolates were heterokaryotic and contain a heterozygous genome. Pathogenicity and host range tests indicated S. rolfsii had a wide host range.

Conflict of interest: All authors declare that they have no conflict of interest.