Species of the ascomycete genus Mycosphaerella are regarded as some of the most destructive leaf pathogens of a large number of economically important crop plants. Amongst these, approximately 60 Mycosphaerella spp. have been identified from various Eucalyptus spp. where they cause leaf diseases collectively known as Mycosphaerella Leaf Disease (MLD). Species concepts for this group of fungi remain confused, and hence their species identification is notoriously difficult. Thus, the introduction of DNA sequence comparisons has become the definitive characteristic used to distinguish species of Mycosphaerella. Sequences of the Internal Transcribed Spacer (ITS) region of the ribosomal RNA operon have most commonly been used to consider species boundaries in Mycosphaerella. However, sequences for this gene region do not always provide sufficient resolution for cryptic taxa. The aim of this study was, therefore, to use DNA sequences for three loci, ITS, Elongation factor 1-alpha (EF-1alpha) and Actin (ACT) to reconsider species boundaries for Mycosphaerella spp. from Eucalyptus. A further aim was to study the anamorph concepts and resolve the deeper nodes of Mycosphaerella, for which part of the Large Subunit (LSU) of the nuclear rRNA operon was sequenced. The ITS and EF-1alpha gene regions were found to be useful, but the ACT gene region did not provide species-level resolution in Mycosphaerella. A phylogeny of the combined DNA datasets showed that species of Mycosphaerella from Eucalyptus cluster in two distinct groups, which might ultimately represent discrete genera.
Species of the ascomycete genus Mycosphaerella are regarded as some of the most destructive leaf pathogens of a large number of economically important crop plants. Amongst these, approximately 60 Mycosphaerella spp. have been identified from various Eucalyptus spp. where they cause leaf diseases collectively known as Mycosphaerella Leaf Disease (MLD). Species concepts for this group of fungi remain confused, and hence their species identification is notoriously difficult. Thus, the introduction of DNA sequence comparisons has become the definitive characteristic used to distinguish species of Mycosphaerella. Sequences of the Internal Transcribed Spacer (ITS) region of the ribosomal RNA operon have most commonly been used to consider species boundaries in Mycosphaerella. However, sequences for this gene region do not always provide sufficient resolution for cryptic taxa. The aim of this study was, therefore, to use DNA sequences for three loci, ITS, Elongation factor 1-alpha (EF-1alpha) and Actin (ACT) to reconsider species boundaries for Mycosphaerella spp. from Eucalyptus. A further aim was to study the anamorph concepts and resolve the deeper nodes of Mycosphaerella, for which part of the Large Subunit (LSU) of the nuclear rRNA operon was sequenced. The ITS and EF-1alpha gene regions were found to be useful, but the ACT gene region did not provide species-level resolution in Mycosphaerella. A phylogeny of the combined DNA datasets showed that species of Mycosphaerella from Eucalyptus cluster in two distinct groups, which might ultimately represent discrete genera.
Species of Eucalyptus are native to Australia with isolated
pockets of native Eucalyptus forests also occurring in Papua New
Guinea and the Philippines (Turnbull
2000). Many Eucalyptus spp. have been removed from these
centres of origin to new environments where they are typically propagated in
plantations for the production of paper, pulp and other wood products
(Wingfield 1999,
Turnbull 2000,
Wingfield ). In these non-native environments, Eucalyptus trees
are susceptible to many pests and diseases including those known in their
areas of origin and others that have undergone host shifts
(Wingfield 2003,
Slippers ). These pests and diseases cause significant annual losses to
Eucalyptus plantations resulting in decreased revenue for commercial
forestry companies.Mycosphaerella Johanson is one of the largest genera of the
ascomycetes, accommodating more than 2000 species. Approximately 60
Mycosphaerella spp. have been associated with leaf diseases of many
Eucalyptus spp., and these are collectively referred to as
Mycosphaerella Leaf Disease (MLD) (Crous
1998, Maxwell , Crous ). The disease is particularly prevalent on the juvenile
leaves and shoots of Eucalyptus trees, where infection results in
premature defoliation, twig cankers and stunting of tree growth
(Lundquist & Purnell 1987,
Crous 1998,
Park ).
However, several Mycosphaerella spp. can also infect adult
Eucalyptus foliage, and this has been attributed to their ability to
produce a proto-appressorium that enables direct cuticle penetration
(Ganapathi 1979,
Park & Keane 1982b). In
some situations, trees may thus be subjected to infection by a suite of
different Mycosphaerella spp.Identification of Mycosphaerella spp. based on morphology is known
to be difficult. This is because these fungi tend to produce very small
fruiting structures with highly conserved morphology, and they are
host-specific pathogens that grow poorly in culture. Traditionally,
morphological characters of the teleomorph and anamorph have been used in
species delimitation (Crous
1998). Park & Keane
(1982a) introduced ascospore
germination patterns as an additional characteristic to identify
Mycosphaerella spp., and Crous
(1998) subsequently identified
14 different ascospore germination patterns for the Mycosphaerella
spp. occurring on Eucalyptus. Crous
(1998) and Crous et
al. (2000) also
introduced features of these fungi growing in culture and especially anamorph
morphology as important and useful characteristics on which to base species
delimitation. DNA-based methods such as RAPDs and species-specific primers
have also been employed to distinguish between Mycosphaerella species
occurring on Eucalyptus (Carnegie
, Maxwell
).Comparisons of DNA sequence data have emerged as the most reliable
technique to identify Mycosphaerella spp. The majority of studies
employing DNA sequence data for species identification have relied on sequence
data from the Internal Transcribed Spacer (ITS) region of the ribosomal RNA
operon (Crous et al.
1999,
2001,
2004a,
b, Hunter et al.
2004a,
b). Although comparisons of
gene sequences for this region have been useful, the resolution provided by
this region is not uniformly adequate to discriminate between individuals of a
species complex or to effectively detect cryptic species
(Crous ).
Thus, recent studies have shown the importance of employing Multi-Locus
Sequence Typing (MLST) to effectively identify cryptic fungal species and to
study species concepts (Taylor &
Fischer 2003).A single morphological species does not always reflect a single
phylogenetic unit (Taylor ). Within Mycosphaerella, teleomorph morphology is
conserved and the anamorph morphology provides additional characteristics to
discriminate between taxa (Crous ). Yet the collective teleomorph and anamorph
morphology is often not congruent with phylogenetic data. Thus, recent
phylogenetic studies have led to the recognition of several species complexes
within Mycosphaerella (Crous et al.
2001,
2004b,
Braun ).
Most of these studies have been based on comparisons of sequences for the ITS
regions of the ribosomal DNA operon. Given the important data that have
emerged from them, it is well recognised that greater phylogenetic resolution
will be required for future taxonomic studies on Mycosphaerella
species.The aim of this study was to use MLST to consider species and anamorph
concepts in Mycosphaerella spp. occurring on Eucalyptus.
This was achieved by sequencing four nuclear gene regions, namely part of the
Large Subunit (D1–D3 of LSU) and ITS region of the nuclear rRNA operon,
and a portion of the Actin (ACT) and Elongation Factor 1-alpha (EF-1α)
gene regions.
MATERIALS AND METHODS
Mycosphaerella isolates
For this study, an attempt was made to obtain cultures of as many
Mycosphaerella spp. known to infect Eucalyptus leaves as
possible. All cultures used in the investigation are housed in culture
collections of the Forestry and Agricultural Biotechnology Institute (FABI),
University of Pretoria, South Africa and the Centraalbureau voor
Schimmelcultures (CBS), Utrecht, The Netherlands
(Table 1). All cultures were
grown on 2 % (w/v) malt extract agar (MEA) (Biolab, South Africa), at 25
°C for approximately 2–3 mo to obtain sufficient mycelial growth for
DNA extraction.
Table 1.
Isolates of Mycosphaerella used in this study for DNA sequencing
and phylogenetic analysis.
Teleomorph
Anamorph
Isolate
No.a
Host
Country
Collector
GenBank Accession No.
CMW
CBS
STEU
LSU
ITS
ACT
EF-1a
M. africana
Unknown
3026
CBS 116155
795
E. viminalis
South Africa
P.W. Crous
DQ246258
DQ267577
DQ147608
DQ235098
4945
CBS 116154
794
E. viminalis
South Africa
P.W. Crous
DQ246257
AF309602
DQ147609
DQ235099
M. ambiphylla
Phaeophleospora sp.
14180
CBS 110499
N/A
E. globulus
Australia
A. Maxwell
DQ246219
AY725530
DQ147669
DQ235103
M. aurantia
Unknown
14460
CBS 110500
N/A
E. globulus
Australia
A. Maxwell
DQ246256
AY725531
DQ147610
DQ235097
M. colombiensis
Pseudocercospora colombiensis
4944
CBS 110969
1106
E. urophylla
Colombia
M.J. Wingfield
DQ204744
AY752149
DQ147639
DQ211660
11255
CBS 110967
1104
E. urophylla
Colombia
M.J. Wingfield
DQ204745
AY752147
DQ147640
DQ211661
M. communis
Dissoconium commune
14672
CBS 114238
10440
E. globulus
Spain
J.P. Mansilla
DQ246262
AY725541
DQ147655
DQ235141
14673
CBS 110976
849
E. cladocalyx
South Africa
P.W. Crous
DQ246261
AY725537
DQ147654
DQ235140
M. cryptica
Colletogloeopsis nubilosum
3279
CBS 110975
936
E. globulus
Australia
A.J. Carnegie
DQ246222
AF309623
DQ147674
DQ235119
2732
N/A
355
Eucalyptus sp.
Chile
M.J. Wingfield
N/A
AF309622
N/A
N/A
M. crystallina
Pseudocercospora crystallina
3042
N/A
800
E. bicostata
South Africa
M.J. Wingfield
DQ204746
DQ267578
DQ147637
DQ211662
3033
CBS 681.95
802
E. bicostata
South Africa
M.J. Wingfield
DQ204747
AY490757
DQ147636
DQ211663
M. ellipsoidea
Uwebraunia ellipsoidea
4934
N/A
1224
Eucalyptus sp.
South Africa
Unknown
DQ246253
AF309592
DQ147647
DQ235129
5166
N/A
1225
Eucalyptus sp.
South Africa
Unknown
DQ246254
AF309593
DQ147648
DQ235127
M. endophytica
Pseudocercosporella endophytica
14912
CBS 111519
1191
Eucalyptus sp.
South Africa
P.W. Crous
DQ246255
DQ267579
DQ147646
DQ235131
5225
N/A
1192
Eucalyptus sp.
South Africa
P.W. Crous
DQ246252
DQ267580
DQ147649
DQ235128
M. flexuosa
Unknown
5224
CBS 111012
1109
E. globulus
Colombia
M.J. Wingfield
DQ246232
AF309603
DQ147653
DQ235126
M. fori
Pseudocercospora sp.
9095
N/A
N/A
E. grandis
South Africa
G.C. Hunter
DQ204748
AF468869
DQ147618
DQ211664
9096
N/A
N/A
E. grandis
South Africa
G.C. Hunter
DQ204749
DQ267581
DQ147619
DQ211665
M. gracilis
Pseudocercospora gracilis
14455
CBS 243.94
730
E. urophylla
Indonesia
A.C. Alfenas
DQ204750
DQ267582
DQ147616
DQ211666
M. grandis
Unknown
8557
N/A
N/A
E. globulus
Chile
A.Rotella
DQ246241
DQ267583
DQ147644
DQ235108
8554
N/A
N/A
E. globulus
Chile
M.J. Wingfield
DQ246240
DQ267584
DQ147643
DQ235107
M. gregaria
Unknown
14462
CBS 110501
N/A
E. globulus
Australia
A. Maxwell
DQ246251
DQ267585
DQ147650
DQ235130
M. heimii
Pseudocercospora heimii
4942
CBS 110682
760
Eucalyptus sp.
Madagascar
P.W. Crous
DQ204751
AF309606
DQ147638
DQ211667
M. heimioides
Pseudocercospora heimioides
14776
CBS 111364
N/A
Eucalyptus sp.
Indonesia
M.J. Wingfield
DQ204752
DQ267586
DQ147632
DQ211668
3046
CBS 111190
1312
Eucalyptus sp.
Indonesia
M.J. Wingfield
DQ204753
AF309609
DQ147633
DQ211669
M. intermedia
Unknown
7163
CBS 114356
10902
E. saligna
New Zealand
K. Dobbie
DQ246247
AY725546
N/A
N/A
7164
CBS 114415
10922
E. saligna
New Zealand
K. Dobbie
DQ246248
AY725547
DQ147627
DQ235132
M. irregulariramosa
Pseudocercospora irregulariramosa
4943
CBS 114774
1360
E. saligna
South Africa
M.J. Wingfield
DQ204754
AF309607
DQ147634
DQ211670
5223
N/A
1362
E. saligna
South Africa
M.J. Wingfield
DQ204755
AF309608
DQ147635
DQ211671
M. ohnowa
Unknown
4937
CBS 112896
1004
E. grandis
South Africa
M.J. Wingfield
N/A
AF309604
DQ147662
DQ235125
4936
CBS 112973
1005
E. grandis
South Africa
M.J. Wingfield
DQ246231
AF309605
DQ147661
DQ235124
M. keniensis
Unknown
5147
CBS 111001
1084
E. grandis
Kenya
T. Coutinho
DQ246259
AF309601
DQ147611
DQ235100
M. lateralis
Dissoconium dekkeri
14906
CBS 110748
825
E. grandis × E. saligna
South Africa
G. Kemp
DQ204768
AF173315
DQ147651
DQ211684
5164
CBS 111169
1232
E. globulus
Zambia
T. Coutinho
DQ246260
AY25550
DQ147652
DQ235139
M. madeirae
Pseudocercospora sp.
14458
CBS 112895
3745
E. globulus
Madeira
S. Denman
DQ204756
AY725553
DQ147641
DQ211672
M. marksii
Unknown
14781
CBS 682.95
842
E. grandis
South Africa
G. Kemp
DQ246249
DQ267587
DQ147624
DQ235133
5150
CBS 110920
935
E. botryoides
Australia
A.J. Carnegie
DQ246250
AF309588
DQ147625
DQ235134
5230
N/A
782
E. botryoides
Australia
A.J. Carnegie
DQ246246
DQ267588
DQ147626
DQ235135
M. mexicana
Unknown
14461
CBS 110502
N/A
E. globulus
Australia
A. Maxwell
DQ246237
AY725558
DQ147660
DQ235123
M. readeriellophora
Readeriella readeriellophora
14233
CBS 114240
10375
E. globulus
Spain
J.P. Mansilla
DQ246238
AY725577
DQ147658
DQ235117
M. molleriana
Colletogloeopsis molleriana
4940
CBS 111164
1214
E. globulus
Portugal
S. McCrae
DQ246220
AF309620
DQ147671
DQ235104
2734
CBS 111132
784
E. globulus
U. S. A.
M.J. Wingfield
DQ246223
AF309619
DQ147670
DQ235105
M. nubilosa
Uwebraunia juvenis
3282
CBS 116005
937
E. globulus
Australia
A.J. Carnegie
DQ246228
AF309618
DQ147666
DQ235111
9003
CBS 114708
N/A
E. nitens
South Africa
G.C. Hunter
DQ246229
AF449099
DQ147667
DQ235112
M. parkii
Stenella parkii
14775
CBS 387.92
353
E. grandis
Brazil
M.J. Wingfield
DQ246245
AY626979
DQ147612
DQ235137
M. parva
Unknown
14459
CBS 110503
N/A
E. globulus
Australia
A. Maxwell
DQ246243
AY626980
DQ147645
DQ235110
14917
CBS 116289
10935
Eucalyptus sp.
South Africa
P.W. Crous
DQ246242
AY725576
DQ147642
DQ235109
M. suberosa
Unknown
5226
CBS 436.92
515
E. dunnii
Brazil
M.J. Wingfield
DQ246235
AY626985
DQ147656
DQ235101
7165
N/A
N/A
E. muelleriana
New Zealand
Unknown
DQ246236
DQ267589
DQ147657
DQ235102
M. suttonii
Phaeophleospora epicoccoides
5348
N/A
1346
Eucalyptus sp.
Indonesia
M.J. Wingfield
DQ246227
AF309621
DQ147673
DQ235116
M. vespa
Colletogloeopsis sp.
11558
CBS 117924
N/A
E. globulus
Tasmania
Unknown
DQ246221
DQ267590
DQ147668
DQ235106
M. tasmaniensis
Passalora tasmaniensis
14780
CBS 111687
1555
E. nitens
Tasmania
M.J. Wingfield
DQ246233
DQ267591
DQ147676
DQ235121
14663
CBS 114556
N/A
E. nitens
Tasmania
M.J. Wingfield
DQ246234
DQ267592
DQ147677
DQ235122
M. toledana
Phaeophleospora toledana
14457
CBS 113313
N/A
Eucalyptus sp.
Spain
P.W. Crous
DQ246230
AY725580
DQ147672
DQ235120
M. walkerii
Sonderhenia eucalypticola
20333
N/A
N/A
E. globulus
Chile
M.J. Wingfield
DQ267574
DQ267593
DQ147630
DQ235095
20334
N/A
N/A
E. globulus
Chile
M.J. Wingfield
DQ267575
DQ267594
DQ147631
DQ235096
Unknown
Passalora eucalypti
14907
CBS 111306
1457
E. saligna
Brazil
P.W. Crous
DQ246244
AF309617
DQ147678
DQ235138
Unknown
Passalora zambiae
14782
CBS 112971
1227
E. globulus
Zambia
T. Coutinho
DQ246264
AF725523
DQ147675
DQ235136
Unknown
Pseudocercospora epispermogonia
14778
CBS 110750
822
E. grandis × E. saligna
South Africa
G. Kemp
DQ204757
DQ267596
DQ147629
DQ211673
14786
CBS 110693
823
E. grandis × E. saligna
South Africa
G. Kemp
DQ204758
DQ267597
DQ147628
DQ211674
Unknown
Phaeophleospora eucalypti
11687
CBS 113992
N/A
E. nitens
New Zealand
M. Dick
DQ246225
DQ267598
DQ147664
DQ235115
14910
CBS 111692
1582
Eucalyptus sp.
New Zealand
M.J. Wingfield
DQ246224
DQ267599
DQ147663
DQ235114
Unknown
Pseudocercospora basitruncata
14914
CBS 114664
1202
E. grandis
Colombia
M.J. Wingfield
DQ204759
DQ267600
DQ147622
DQ211675
14785
CBS 111280
1203
E. grandis
Colombia
M.J. Wingfield
DQ204760
DQ267601
DQ147621
DQ211676
Unknown
Pseudocercospora basiramifera
5148
N/A
N/A
E. pellita
Thailand
M.J. Wingfield
DQ204761
AF309595
DQ147607
DQ211677
Unknown
Pseudocercospora eucalyptorum
5228
CBS 110777
16
E. nitens
South Africa
P.W. Crous
DQ204762
AF309598
DQ147614
DQ211678
Unknown
Pseudocercospora natalensis
14777
CBS 111069
1263
E. nitens
South Africa
T. Coutinho
DQ267576
N/A
DQ147620
N/A
14784
CBS 111070
1264
E. nitens
South Africa
T. Coutinho
DQ204763
AF309594
DQ147623
DQ211679
Unknown
Pseudocercospora paraguayensis
14779
CBS 111286
1459
E. nitens
Brazil
P.W. Crous
DQ204764
DQ267602
DQ147606
DQ211680
Unknown
Pseudocercospora pseudoeucalyptorum
14908
CBS 114242
10390
E. globulus
Spain
J.P. Mansilla
DQ204765
AY725526
DQ147613
DQ211681
14911
CBS 114243
10500
E. nitens
New Zealand
W. Gams
DQ204766
AY725527
DQ147615
DQ211682
Unknown
Pseudocercospora robusta
5151
CBS 111175
1269
E. robusta
Malaysia
M.J. Wingfield
DQ204767
AF309597
DQ147617
DQ211683
Unknown
Readeriella novaezelandiae
14913
CBS 114357
10895
E. botryoides
New Zealand
M.A. Dick
DQ246239
DQ267603
DQ147659
DQ235118
Botryosphaeria ribis
Fusicoccum ribis
7773
N/A
N/A
Ribus sp.
U. S. A.
G. Hudler.
DQ246263
DQ267604
DQ267605
DQ235142
CMW: Culture collection of the Forestry and Agricultural Biotechnology
Institute (FABI), University of Pretoria, South Africa.
CBS: Centraalbureau voor Schimmelcultures, Utrecht, The Netherlands.
STEU: Culture collection of Stellenbosch University, South Africa. Isolate
numbers from Crous (1998).
N/A: Not available
Isolates of Mycosphaerella used in this study for DNA sequencing
and phylogenetic analysis.CMW: Culture collection of the Forestry and Agricultural Biotechnology
Institute (FABI), University of Pretoria, South Africa.CBS: Centraalbureau voor Schimmelcultures, Utrecht, The Netherlands.STEU: Culture collection of Stellenbosch University, South Africa. Isolate
numbers from Crous (1998).N/A: Not available
DNA isolation
Mycelium from actively growing cultures was scraped from the surface of
cultures, freeze-dried for 24 h and then ground to a fine powder using liquid
nitrogen. DNA was isolated using the phenol: chloroform (1: 1) extraction
protocol as described in Hunter et al.
(2004a,
b). DNA was precipitated by
the addition of absolute ethanol (100 % EtOH). Isolated DNA was cleaned by
washing with 70 % Ethanol (70 % EtOH) and dried under vacuum. SABAX water was
used to resuspend the isolated DNA. RNaseA (10 μg/μL) was added to the
resuspended DNA and incubated at 37 °C for approximately 2 h to digest any
residual RNA. Isolated DNA was visualised in a 1 % agarose gel (w/v) (Roche
Diagnostics, Mannheim), stained with ethidium bromide and visualised under
ultra-violet light.
PCR amplification and purification
DNA (ca. 20 ng) isolated from the Mycosphaerella spp.
used in this study was used as a template for amplification using the
Polymerase Chain Reaction (PCR). All PCR reactions were mixed in a total
volume of 25 μL containing 10× PCR Buffer (5 mM Tris-HCl, 0.75 mM
MgCl2, 25 mM KCl, pH 8.3) (Roche Diagnostics, South Africa), 2.5 mM
of each dNTP (dATP, dTTP, dCTP, dGTP) (Roche Diagnostics, South Africa), 0.2
μM of forward and reverse primers (Inqaba Biotech, South Africa) and 1.25 U
Taq DNA Polymerase (Roche Diagnostics, South Africa) and DNA (20 ng/μL).
Sterilised distilled water was added to obtain a final volume of 25 μL.The ITS-1, ITS-2 and the 5.8 S gene regions of the ITS region of the rRNA
operon were amplified using primers ITS-1 (5′– TCC GTA GGT GAA CCT
GCG G –3′) and LR-1 (5′- GGT TGG TTT CTT TTC CT –
3′) (Vilgalys & Hester
1990, White ). Reaction conditions for the ITS gene regions followed those
of Crous et al.
(2004a) and Hunter et
al. (2004a,
b).A portion of the LSU (including domains D1–D3) of the rRNA operon was
amplified using primers LR0R (5'-ACC CGC TGA ACT TAA GC-3')
(Moncalvo ) and LR7 (5'-TAC TAC CAC CAA GAT CT-3')
(Vilgalys & Hester 1990).
PCR cycling conditions were as follows: an initial denaturation step of 96
°C for 2 min, followed by 35 cycles of denaturation at 94 °C for 30 s,
primer annealing at 62 °C for 30 s, primer extension at 72°C for 1 min
and a final elongation step at 72 °C for 7 min.A portion of the EF-1α was amplified using the primers EF1-728F
(5'-CAT CGA GAA GTT CGA GAA GG-3') and EF1-986R (5'-TAC TTG AAG GAA CCC TTA
CC-3') (Carbone & Kohn
1999). Reaction conditions were: an initial denaturation step of
96 °C for 2 min, followed by 35 cycles of denaturation at 94 °C for 30
s, primer annealing at 56 °C for 30 s and primer extension at 72 °C
for 30 s. The reaction was completed with a final extension at 72 °C for 7
min.A portion of the ACT gene was amplified using the primers ACT-512F (5'-ATG
TGC AAG GCC GGT TTC GC-3') and ACT-783R (5'-TAC GAG TCC TTC TGG CCC AT-3')
(Carbone & Kohn 1999). PCR
reaction conditions were: an initial denaturation step at 96 °C for 2 min,
followed by 10 cycles of denaturation at 94 °C for 30 s, primer annealing
at 61 °C for 45 s and extension at 72 °C for 45 s. This was followed
by 25 cycles of denaturation at 94 °C for 30 s, primer annealing at 61
°C and elongation at 72 °C for 45 s with an increase of 5 s per cycle.
The reaction was completed with a final elongation step at 72 °C for 7
min.All PCR products were visualised in 1.5 % agarose gels (wt/v) stained with
ethidium bromide and viewed under ultra-violet light. Sizes of PCR amplicons
were estimated by comparison against a 100 bp molecular weight marker (O'
RangeRuler™ 100 bp DNA ladder) (Fermentas Life Sciences, U.S.A.). Prior
to DNA sequencing, PCR products were purified through Centrisep spin columns
(Princeton Separations, Adelphia, NJ) containing Sephadex G-50 (Sigma Aldrich,
St. Louis, MO) as outlined by the manufacturer.
DNA sequencing and phylogenetic analysis
Purified PCR products were used as template DNA for sequencing reactions on
an ABI PRISM™ 3100 Automated DNA sequencer (Applied Biosystems, Foster
City, CA). The ABI Prism Big Dye Terminator Cycle sequencing reaction kit v.
3.1 (Applied Biosystems, Foster City, CA) was used for sequencing reactions
following the manufacturer's instructions. Most sequencing reactions were
performed with the same primers used for PCR reactions. Exceptions were in the
case of the ITS region where two internal primers ITS-2 (5'-GCT GCG TTC TTC
ATC GAT GC-3') and ITS-3 (5'-GCA TCG ATG AAG AAC GCA GC-3')
(White )
were included for the sequencing reactions. Similarly, for the LSU region two
internal primers LR3R (5'-GTC TTG AAA CAC GGA CC-3') and LR-16 (5'-TTC CAC CCA
AAC ACT CG-3') were used for the sequencing reactions.All resulting sequences were analysed with Sequence Navigator v. 1.0.1
(Applied Biosystems, Foster City, CA). Sequence alignments were done using
MAFFT (Multiple alignment program for amino acid or nucleotide sequences) v.
5.667 (Katoh ) and manually adjusted where necessary. Phylogenetic analyses
and most parsimonious trees were generated in PAUP v. 4.0b10
(Swofford 2002) by heuristic
searches with starting trees obtained through stepwise addition with simple
addition sequence and with the MULPAR function enabled. Tree Bisection
Reconnection (TBR) was employed as the swapping algorithm. All gaps were coded
as missing data and characters were assigned equal weight. Branch support for
nodes was obtained by performing 1000 bootstrap replicates of the aligned
sequences. For parsimony analyses, measures that were calculated include tree
length (TL), retention index (RI), consistency index (CI), rescaled
consistency index (RC) and homoplasy index (HI). Botryosphaeria ribis
Grossenb. & Duggar was used as the outgroup to root all trees.A Partition Homogeneity Test (Farris
), of all possible combinations, consisting of
1000 replicates on all informative characters was conducted in PAUP to
determine if the LSU, ITS and EF-1α data sets were combinable. All
sequences of Mycosphaerella spp. used in this study have been
deposited in GenBank (Table.
1). Sequence alignments and trees of the LSU, ITS, EF-1α and
ACT have been deposited in TreeBASE (accession numbers: LSU = SN2535, ITS =
SN2534, EF-1α = SN2536, ACT = SN2537).Parsimony and distance analyses of combined DNA sequence alignments were
conducted in PAUP. Parsimony analyses of all DNA sequence alignments were
identical to those described earlier. For distance analyses, Modeltest v. 3.04
(Posada & Crandall 1998)
was used to determine the best evolutionary model to fit the combined DNA
sequence alignment. A neighbour-joining analysis with an evolutionary model
was conducted in PAUP. Here, the distance measure was a general
time-reversible (GTR) and the proportion of sites assumed to be invariable (I)
was 0.4919, identical sites were removed proportionally to base frequencies
estimated from all sites, rates of variable sites assumed to follow a gamma
distribution (G) with shape parameter of 0.6198. Ties (if encountered) were
broken randomly.
RESULTS
Large Subunit (LSU) phylogeny: The LSU alignment had a total
length of 1714 characters. An indel of 383 bp present in M. ohnowa
Crous & M.J. Wingf. (CBS
112973) and Mycosphaerella mexicana Crous
(CBS 110502) was
excluded from the analyses. In the LSU data set, 1075 characters were constant
while 77 characters were parsimony-uninformative and 179 characters were
parsimony-informative. Parsimony analysis of the LSU data set resulted in the
retention of thirty most parsimonious trees (TL = 663, CI = 0.519, RI = 0.878,
RC = 0.456). One of these trees (Fig.
1) could be resolved into two clades (Clades 1–2). Clade 1,
supported with a bootstrap value of 70 %, included Mycosphaerella
isolates characterised by Phaeophleospora Rangel (M.
ambiphylla A. Maxwell, M. suttoniae Crous & M.J. Wingf.),
Colletogloeopsis Crous & M.J. Wingf. [M. molleriana
(Thüm.) Lindau, M. vespa Carnegie & Keane, M.
cryptica (Cooke) Hansf.], Uwebraunia Crous & M.J. Wingf.
[M. nubilosa (Cooke) Hansf.], M. ohnowa, Readeriella Syd.
& P. Syd. (M. readeriellophora Crous & J.P. Mansilla), and
Passalora Fr. (M. tasmaniensis Crous & M.J. Wingf.)
anamorphs.
Fig. 1.
Phylogram obtained from the Large Subunit (LSU) rDNA sequence alignment of
Mycosphaerella spp. occurring on Eucalyptus leaves showing
two well-supported main clades (Clades 1–2). Tree length = 663, CI =
0.519, RI = 0.878, RC = 0.456. Bootstrap values based on 1000 replicates are
indicated above branches. Anamorph affinities are indicated next to the
vertical lines.
The second major clade (Clade 2) resolved in the LSU tree was
well-supported with a bootstrap value of 98 %. Mycosphaerella species
in this clade also grouped strongly following their anamorph associations.
Here Mycosphaerella isolates could be resolved into several
sub-clades also characterised by their anamorph associations. These were
Sonderhenia (M. walkeri R.F. Park & Keane.),
Pseudocercospora Speg. [M. heimioides Crous & M.J.
Wingf., M. heimii Crous, M. crystallina Crous & M.J.
Wingf., M. irregulariramosa Crous & M.J. Wingf., M.
colombiensis Crous & M.J. Wingf., M. gracilis Crous &
Alfenas, Pseudocercospora robusta Crous & M.J. Wingf., Ps.
natalensis Crous & T. Coutinho, M. fori G.C. Hunter, Crous
& M.J. Wingf., Ps. basitruncata Crous, Ps.
pseudoeucalyptorum Crous, Ps. eucalyptorum Crous, M.J. Wingf.,
Marasas & B. Sutton., Ps. paraguayensis (Koboyashi) Crous,
Ps. basiramifera Crous] Passalora [Pass. eucalypti
(Crous & Alfenas) Crous & U. Braun, Pass. zambiae Crous &
T. Coutinho], and Dissoconium (M. lateralis Crous & M.J.
Wingf., M. communis Crous & J.P. Mansilla).Internal Transcribed Spacer Region (ITS) phylogeny: The ITS
sequence alignment consisted of a total of 793 characters. Of these 499
characters were constant, 62 characters were variable and
parsimony-uninformative and 232 characters were parsimony-informative. A 185
bp indel was observed in isolates of M. gregaria Carnegie & Keane
(CBS 110501),
M. endophytica Crous & H. Smith
(CBS 111519) and
M. endophytica (CMW 5225) and was excluded in the phylogenetic
analysis.A heuristic search of the ITS data set resulted in the retention of four
most parsimonious trees (TL = 871, RI = 0.782, CI = 0.358, RC = 0.280). One of
these phylogenetic trees (Fig.
2) generated by parsimony analysis of the ITS alignment could be
resolved into two monophyletic clades (Clades 1–2). Clade 1 was only
weakly supported with a bootstrap value of 50 % after 1000 bootstrap
replicates. Clade 1 could be further resolved into several smaller sub-clades
where isolates grouped strongly based on their anamorph affiliations. These
included Sonderhenia, Pseudocercospora, Passalora,
Uwebraunia/Pseudocercosporella, Stenella, Readeriella,
Phaeophleospora and Colletogloeopsis. The second monophyletic
clade (Clade 2) grouped sister to the first larger monophyletic clade and
contained isolates of M. lateralis and M. communis
(Dissoconium anamorphs). This clade was well-supported with a
bootstrap value of 100 % after 1000 bootstrap replicates.
Fig. 2.
Phylogram obtained from the Internal Transcribed Spacer (ITS) DNA sequence
alignment of Mycosphaerella spp. occurring on Eucalyptus leaves
indicating two monophyletic clades (Clades 1–2). Tree length = 871, CI =
0.358, RI = 0.782, RC = 0.280.
Phylogram obtained from the Large Subunit (LSU) rDNA sequence alignment of
Mycosphaerella spp. occurring on Eucalyptus leaves showing
two well-supported main clades (Clades 1–2). Tree length = 663, CI =
0.519, RI = 0.878, RC = 0.456. Bootstrap values based on 1000 replicates are
indicated above branches. Anamorph affinities are indicated next to the
vertical lines.Translation Elongation factor 1-alpha (EF -1α) phylogeny:
The EF-1α alignment contained 373 characters. Of these, 41 characters
were constant, 23 characters were variable and parsimony-uninformative and 309
characters were parsimony-informative. Heuristic searches resulted in the
retention of six most parsimonious trees (TL = 3194, RI = 0.777, CI = 0.345,
RC = 0.268), one of which is shown (Fig.
3). Species of Mycosphaerella could be resolved into
three clades (Clades 1–3).
Fig. 3.
Phylogram obtained from the Elongation factor 1-alpha (EF-1α) DNA
sequence alignment of Mycosphaerella spp. occurring on
Eucalyptus leaves showing three main clades. Tree length = 3194, CI =
0.345, RI = 0.777, RC = 0.268.
Clade 1 was weakly supported with a bootstrap value of 67 %. This clade
contained Mycosphaerella isolates represented by
Pseudocercospora, Sonderhenia, Phaeophleospora, Colletogloeopsis,
Uwebraunia, Readeriella and Passalora anamorphs. Clade 2 was
sister to Clade 1 and had a higher bootstrap support of 80 %. Within this
clade, Mycosphaerella isolates could be separated into three
sub-clades that were well-supported. These three sub-clades contained species
of Mycosphaerella that produced Pseudocercosporella, Uwebraunia,
Pseudocercospora, Passalora and Stenella anamorphs. Clade 3 with
bootstrap support of 80 % included isolates of M. lateralis and
M. communis and was basal to Clades 1 and 2.Actin (ACT) phylogeny: The aligned ACT sequence dataset contained
a total of 294 characters. Of these, 135 characters were constant, 30
characters were variable and parsimony-uninformative and 129 characters were
parsimony-informative. Heuristic searches of the aligned ACT dataset resulted
in the retention of six most parsimonious trees (TL = 1007, RI = 0.682, CI =
0.235, RC = 0.160). One of these trees, shown in
Fig. 4, was very poorly
resolved and all deeper nodes were present in a basal polytomy. However,
certain smaller clades were resolved and these included a clade including
M. fori, M. gracilis, Ps. eucalyptorum, Ps. pseudoeucalyptorum, Ps.
robusta, Ps. basitruncata, Ps. natalensis, Ps. basiramifera and Ps.
paraguayensis. This clade was supported with a bootstrap value of only 67
%. Another clade supported with a bootstrap value of 100 % contained isolates
of M. ellipsoidea Crous & M.J. Wingf., M. endophytica
and M. gregaria. Isolates of M. ambiphylla, M. molleriana
and M. vespa also clustered together with 100 % bootstrap support.
Isolates of M. intermedia M.A. Dick & Dobbie, M. marksii
Carnegie & Keane and Pseudocercospora epispermogonia Crous &
M. J. Wingf. grouped together in a clade that was supported with a bootstrap
value of 84 %. Isolates of M. flexuosa Crous & M.J. Wingf.,
M. lateralis and M. communis were also accommodated in a
well-supported clade with a bootstrap value of 99 %. Isolates of M.
grandis Carnegie & Keane and M. parva R.F. Park & Keane
were also resolved into a clade with a bootstrap value of 99 %.
Fig. 4.
Phylogram obtained from the Actin (ACT) DNA sequence alignment of
Mycosphaerella spp. occurring on Eucalyptus leaves. Tree
length = 1007, CI = 0.235, RI = 0.682, RC = 0.160.
Phylogram obtained from the Internal Transcribed Spacer (ITS) DNA sequence
alignment of Mycosphaerella spp. occurring on Eucalyptus leaves
indicating two monophyletic clades (Clades 1–2). Tree length = 871, CI =
0.358, RI = 0.782, RC = 0.280.Phylogeny of combined data set: A partition homogeneity test of
the combined LSU, ITS and EF-1α alignment conducted in PAUP resulted in
a P-value of 0.001 for all possible combinations of the LSU, ITS and
EF-1α DNA alignments. This value is less than the conventionally
accepted P-value of P > 0.05 required to combine data. However, several
studies have accepted a P-value of 0.001 or greater and have further stated
that the conventional P-value of 0.005 is inordinately conservative
(Cunningham 1997,
Darlu & Lecointre 2002,
Dettman ).
Thus, the LSU, ITS and EF-1α DNA sequence data sets were combined. The
ACT dataset was omitted from the combined data set due to the lack of
resolution among species of Mycosphaerella. Therefore, the combined
LSU, ITS and EF-1α data set had a total length of 2880 characters. Of
these, 1459 were constant, 150 were variable and parsimony-uninformative and
701 characters were parsimony-informative. An indel of 382 bp was excluded for
M. ohnowa CBS
112973 and M. mexicana
CBS 110502 and
another indel of 186 bp was excluded for M. gregaria
CBS 110501 and
M. endophytica CMW 5225 and
CBS 111519. A
parsimony analysis resulted in the retention of ten most parsimonious trees
(TL = 1677, CI = 0.384, RI = 0.817, RC = 0.314, HI = 0.616). One of these
trees (Fig. 5) exhibited a
similar topology to that obtained from the LSU alignment. From the analysis of
the combined data set, isolates of Mycosphaerella could again be
resolved into two clades (Clades 1–2)
(Fig. 5). Clade 1 was poorly
supported with a bootstrap value of only 66 % and the same isolates were
contained in this clade as in the LSU Clade 1
(Fig. 1). Clade 2 of the
combined phylogenetic tree was well-supported with a bootstrap value of 81 %.
This clade could be further resolved into several smaller well-supported
sub-clades containing Mycosphaerella isolates that grouped according
to their anamorph associations (Fig.
5). Neighbour-joining analysis yielded a phylogenetic tree with
the same topology as the most parsimonious trees (data not shown). Here, all
Mycosphaerella spp. could be resolved into two main clades (Clade
1–2), similar to those of the parsimony analysis
(Fig. 5).
Mycosphaerella spp. could be further sub-divided into several
sub-clades corresponding to their anamorph associations, similar to those
observed for the parsimony analysis.
Fig. 5.
Phylogram obtained from the combined LSU, ITS and EF-1α DNA sequence
alignment of Mycosphaerella spp. occurring on Eucalyptus
leaves showing two main clades. Tree length = 1677, CI = 0.384, RI = 0.817, RC
= 0.314.
Phylogram obtained from the Elongation factor 1-alpha (EF-1α) DNA
sequence alignment of Mycosphaerella spp. occurring on
Eucalyptus leaves showing three main clades. Tree length = 3194, CI =
0.345, RI = 0.777, RC = 0.268.Phylogram obtained from the Actin (ACT) DNA sequence alignment of
Mycosphaerella spp. occurring on Eucalyptus leaves. Tree
length = 1007, CI = 0.235, RI = 0.682, RC = 0.160.
DISCUSSION
Results of this study represent the first attempt to employ DNA sequence
data from a relatively large number of nuclear gene regions in order to
consider the phylogenetic relationships for Mycosphaerella spp.
occurring on Eucalyptus leaves. Other similar studies have relied
entirely on sequence data of the ITS region (Crous et al.
1999,
2001,
2004a, and
2006 – this volume,
Hunter ).
Although the ITS region offers sufficient resolution to distinguish most taxa,
it has not been adequate to separate cryptic taxa in Mycosphaerella
(Crous ).
Results of the present study showed that combined DNA sequence data from the
LSU, ITS, EF-1α gene regions offer increased genetic resolution to study
species concepts in Mycosphaerella. However, genes such as the ACT,
did not support data emerging from the other loci sequenced, and indicated
variation within some clades that were well supported by sequences of other
loci and morphological characteristics. These observations led us to exclude
ACT data from the final analyses. A similar finding has also emerged from
other studies including greater numbers of Mycosphaerella species
(Crous & Groenewald, unpubl. data).Mycosphaerella ambiphylla, M. molleriana and M. vespa
grouped together in a well-supported clade in the phylogeny emerging from the
combined alignment. This was also true for the ITS, EF-1α and ACT
phylogenies where these isolates grouped in a distinct clade with a 100 %
bootstrap support. Mycosphaerella molleriana and M. vespa
both have Colletogloeopsis anamorphs, however, M. ambiphylla
produces a Phaeophleospora anamorph
(Crous & Wingfield 1997a,
Maxwell ).
Interestingly, the Phaeophleospora anamorph of M. ambiphylla
was differentiated from Colletogloeopsis only by the fact that
conidia are produced in a pycnidium as opposed to an acervulus
(Maxwell ). Application of conidiomatal structure to differentiate
anamorphs of Mycosphaerella has previously been viewed with
circumspection especially because Mycosphaerella anamorphs can
produce different conidiomatal forms under differing environmental conditions
(Crous ,
Cortinas
– this volume). Therefore, the placement of the M. ambiphylla
anamorph in Phaeophleospora is questioned and it should be
re-evaluated in terms of its morphological similarities to
Colletogloeopsis.Phylogram obtained from the combined LSU, ITS and EF-1α DNA sequence
alignment of Mycosphaerella spp. occurring on Eucalyptus
leaves showing two main clades. Tree length = 1677, CI = 0.384, RI = 0.817, RC
= 0.314.Ascospore germination patterns of M. ambiphylla, M. molleriana and
M. vespa are all similar, with germ tubes that grow parallel to the
long axis of the spore and ascospores with a slight constriction at the median
septum, typical of a type C ascospore germination pattern
(Crous 1998,
Carnegie & Keane 1998,
Maxwell ).
Furthermore, overlap is seen in ascospore dimensions of the three species
where those of M. molleriana are (11–)12–14(–17)
× (2.5–)3.5–4(–4.5) μm, those of M.
ambiphylla are (12–)14–15(–22)
×(3.5–)4.5–5(–6) μm and those of M. vespa
9.5–16.5 × 2.5–4 μm
(Crous 1998,
Carnegie & Keane 1998,
Maxwell ).
Leaf lesions of the three species are also similar, pale brown to dark
red-brown with lesions of M. vespa and M. ambiphylla often
producing a red margin that was, however, not observed in M.
molleriana (Crous 1998,
Carnegie & Keane 1998,
Maxwell ).
Morphological features of M. ambiphylla, M. molleriana and M.
vespa are also very similar. This is supported in the DNA phylogeny of
the present study where these three species appear to represent a single taxon
and therefore suggest that M. ambiphylla, M. molleriana and M.
vespa should be synonomised under M. molleriana, which is the
oldest epithet. We therefore reduce M. ambiphylla and M.
vespa to synonymy with M. molleriana as follows:(Thüm.) Lindau,
Natürliche Pfanzenfamilie, 1: 424. 1897.≡ Sphaerella molleriana Thüm., Revista Inst. Sci. Lit.
Coimbra 28: 31. 1881.= Mycosphaerella vespa Carnegie & Keane, Mycol. Res. 102:
1275. 1998.= Mycosphaerella ambiphylla A. Maxwell, Mycol. Res. 107: 354.
2003.Anamorph: Colletogloeopsis molleriana Crous & M.J.
Wingf., Canad. J. Bot. 75: 670. 1997.Mycosphaerella flexuosa has no known anamorph
(Crous 1998). An isolate of
this fungus included in the present study grouped together with isolates of
M. ohnowa in the LSU, ITS, EF-1α and combined data set with
high bootstrap support. This similarity was also observed in a recent study of
Mycosphaerella spp. on Eucalyptus based on ITS sequence data
(Crous ).
Mycosphaerella ohnowa is also not known to produce an anamorph
(Crous ).
Although these two species are phylogenetically similar, they can be
distinguished from one another based on different ascus and ascospore
dimensions, ascospore germination patterns and cultural characteristics
(Crous 1998,
Crous ).
Although morphologically distinct, it is interesting that these two taxa are
phylogenetically so closely related and might suggest a recent speciation
event.Isolates of M. grandis and M. parva consistently grouped
together in a separate clade in all of the DNA sequence data sets in this
study. This has also been shown by Crous et al.
(2004a), where isolates of
these two species grouped together in a distinct clade based on ITS DNA
sequences. Mycosphaerella grandis was originally described from
E. grandis in Australia, and recognised as a distinct species of
Mycosphaerella due to its lesion characteristics, and ascospore
morphology (Carnegie & Keane
1994). However, Crous
(1998) examined the type of
M. grandis and M. parva and found the two species to be
congeneric, and reduced them to synonymy under M. parva. Results from
the present study support the synonymy.Mycosphaerella lateralis and M. communis, both known to
have Dissoconium anamorphs, showed various phylogenetic placements in
this study. From the LSU phylogeny, M. lateralis and M.
communis were situated within a large Mycosphaerella clade
sister to a Pseudocercospora sub-clade. However, in the ITS and
EF-1α phylogenies the Dissoconium clade was situated basal to
the larger Mycosphaerella clade. This is consistent with findings of
Crous et al. (1999,
2000) where the
Dissoconium clade also resided outside the larger monophyletic
Mycosphaerella clade. The LSU gene region is well-known to be
conserved and to show less nucleotide differences than the ITS and EF-1α
gene regions. Although the house-keeping genes investigated here lead to the
conclusion that Dissoconium could be different from
Mycosphaerella s. str., this proved not to be the case when LSU data
were considered. Dissoconium is morphologically identical to
Uwebraunia, and the separation of these two genera no longer seems
tenable. Only two species, M. ellipsoidea and M. nubilosa,
have Uwebraunia anamorphs (Crous
). However, cultures of both species produced
these anamorphs only upon initial isolation, and those that are currently
available are sterile. In contrast, strains with Dissoconium
anamorphs readily produce those in culture, and they usually sporulate
profusely. It appears that the status of Uwebraunia will only be
resolved once fresh, sporulating collections of either M. ellipsoidea
or M. nubilosa can be obtained.Mycosphaerella spp. with Pseudocercospora anamorphs
grouped into three clades in all of the phylogenies generated in this study.
Species in the Pseudocercospora clades have short branch lengths
arising from a common internode, suggesting that they have speciated
relatively recently from a common ancestor
(Ávila ) and, most likely have co-evolved with their
Eucalyptus hosts as suggested by Crous et al.
(2000). Ávila et
al. (2005) suggested that
Pseudocercospora may represent a monophyletic lineage. But, results
of this and other studies (Ayala-Escobar
) have shown that Pseudocercospora is
paraphyletic in Mycosphaerella and has evolved more than once in the
genus. The availability of new DNA datasets for several gene regions are
likely to resolve cryptic species and species complexes within
Pseudocercospora, as has already been shown for the M.
heimii and the P. eucalyptorum species complexes (Crous et
al. 2000,
2004a).Mycosphaerella heimioides, M. heimii, M. crystallina and M.
irregulariramosa are all morphologically similar and are regarded as
members of the M. heimii species complex
(Crous & Wingfield 1997b,
Crous ).
Previous studies based on ITS DNA sequence data have demonstrated the
phylogenetic relatedness of these four species
(Crous ,
Crous ).
However, bootstrap support for their phylogenetic placement was low
(Crous ).
The phylogeny of combined DNA sequence data in this study showed that the four
species in the M. heimii complex reside in a well-supported clade
(bootstrap support 97 %). The short branch lengths indicate that the four
species have also recently diverged from a common ancestor.In the phylogeny based on the combined sequence data sets, M.
gracilis grouped in a well-supported Pseudocercospora clade that
also included isolates of Ps. robusta, M. fori, Ps. pseudoeucalyptorum,
Ps. eucalyptorum, Ps. basitruncata, Ps. natalensis, Ps. paraguayensis and
Ps. basiramifera. This is the first study in which DNA sequence data
for M. gracilis have been incorporated into a phylogeny. In the ITS,
EF-1α and ACT phylogenies, M. gracilis was phylogenetically
most closely related to Ps. pseudoeucalyptorum. However, M.
gracilis (anamorph: Pseudocercospora gracilis Crous &
Alfenas) can be distinguished from Ps. pseudoeucalyptorum by its
single conidiophores arising exclusively from secondary mycelium, which is
different to Ps. pseudoeucalyptorum in which conidiophores arise from
loose or dense fascicles of a stroma
(Crous 1998,
Crous ).
Furthermore, conidia of Ps. gracilis are more septate, longer, and
more uniformly cylindrical in shape than those of Ps.
pseudoeucalyptorum (Crous
1998, Crous ). Results of the present study clearly emphasise the fact
that species which are morphologically distinct, can be very closely
related.An interesting result emerging from the phylogenetic analyses in this study
was the placement of Pseudocercospora epispermogonia in relation to
Mycosphaerella marksii and Mycosphaerella intermedia.
Sequences for all but the ACT gene region showed that these three taxa
represent the same phylogenetic species. Although it has previously been
suggested that M. marksii should have a Stenella anamorph
because of its proximity to M. parkii
(Crous ),
the current data suggest that this anamorph could be Ps.
epispermogonia. Crous & Wingfield
(1996) described Ps.
epispermogonia from spermatogonia on lesions colonised by M.
marksii, but failed to link the two states because single-ascospore
cultures did not form an anamorph in culture. Mycosphaerella
intermedia is morphologically similar to M. marksii, and
probably represents the same taxon. We therefore reduce M. intermedia
to synonymy with M. marksii as follows:Carnegie & Keane, Mycol. Res.
98: 413–416. 1994.= Mycosphaerella intermedia M. A. Dick & Dobbie, New Zealand
J. Bot. 39: 270. 2001.Anamorph: Pseudocercospora epispermogonia Crous &
M.J. Wingf., Mycologia 88: 456. 1996.Mycosphaerella africana, M. aurantia and M. keniensis
have no known anamorphs. Previous studies based on ITS sequence data have
suggested that M. africana and M. keniensis grouped close to
Mycosphaerella spp. with Passalora anamorphs. It has thus
been assumed that M. africana and M. keniensis would have
Passalora anamorphs if they were to be found
(Crous ).
However, the phylogenies emerging from LSU, ITS and EF-1α sequences and
the combined data for the three regions showed that M. africana, M.
keniensis and M. aurantia consistently group separately from the
Passalora anamorphs, close to a clade of isolates with
Uwebraunia and Pseudocercosporella anamorphs. The
association of these three taxa to Passalora is thus doubted.
Furthermore, the clade containing M. africana, M. aurantia and M.
keniensis is also well-supported and seems to represent a single evolving
lineage.Moreover, results of the present study show that M. aurantia and
M. africana represent a single phylogenetic species. These two
species consistently grouped together in all phylogenies with M.
keniensis grouping as a sister. Mycosphaerella aurantia was
described from leaves of E. globulus in south-western Australia and
is known only from this location (Maxwell
). Morphologically, M. aurantia
produces asci and ascospores that are similar in size and morphology to M.
africana. However, the ascospores of M. aurantia are not
constricted at the median septum whereas those of M. africana had
such constrictions, and ascospores of M. aurantia are longer
(9–)11–12(–15) μm than those of M. africana
(7–)8–10(–11) μm
(Crous 1998,
Maxwell ).
Furthermore, M. aurantia produces lateral hyaline germ tubes that
grow parallel to the long axis of the ascospore and become slightly verrucose
to produce lateral branches upon prolonged incubation
(Maxwell ). This is in contrast to ascospores of M. africana
that germinate in an irregular fashion producing distinctly dark verrucose
germ tubes from different positions of the distorted ascospore
(Crous 1998). It is intriguing
that these two species, which are morphologically quite distinct, would
represent a single phylogenetic species. Additional isolates of these species
are required to determine whether they represent two distinct taxa or are
conspecific.Mycosphaerella gregaria was described from leaves of E.
grandis in Victoria, Australia
(Carnegie & Keane 1997). No
anamorph has been observed for this species
(Carnegie & Keane 1997,
Crous 1998). An isolate of
M. gregaria, collected from E. globulus in Australia,
consistently grouped in a clade with isolates of M. endophytica and
M. ellipsoidea. Mycosphaerella endophytica and M.
ellipsoidea are known to have Pseudocercosporella and
Uwebraunia anamorphs, respectively
(Crous 1998). Based on
previous studies employing ITS sequence data, isolates of M.
endophytica grouped sister to isolates of M. aurantia, M.
ellipsoidea and M. africana
(Crous ).
However, based on sequence data from the four gene regions employed in this
study, isolates of M. endophytica grouped in a distinct
well-supported clade with M. ellipsoidea. This is interesting because
M. ellipsoidea has an Uwebraunia anamorph
(Crous & Wingfield 1996).
Mycosphaerella endophytica and M. pseudoendophytica
Crous & G. Hunter are the only Mycosphaerella spp. occurring on
Eucalyptus that are known to have Pseudocercosporella
anamorphs (Crous 1998,
Crous
– this volume).Phylogenies emerging from analyses of sequences for the four gene regions
considered in this study suggest that Mycosphaerella constitutes
heterogenous groups of which only a few are closely linked to certain anamorph
genera. It is evident that for the larger part the evolution of the anamorph
genera within Mycosphaerella has been polyphyletic, and not
monophyletic as previously suggested. This can be seen by the multiple
evolution of anamorph genera such as Passalora, Pseudocercospora,
Phaeophleospora and Stenella within Mycosphaerella
(Crous ).
It would thus not be advisable to predict anamorph relationships based on the
phylogenetic position within Mycosphaerella. Not only has the same
morphology evolved more than once in the group, but disjunct anamorph
morphologies also frequently cluster together (Crous et al.
2000,
2004a,
2006). This makes the
interpretation difficult, and predictions based on position in clades
unreliable.The production of four nucleotide sequence data sets for species of
Mycosphaerella occurring on Eucalyptus leaves should serve
as a framework for the more accurate taxonomic placement of these fungi in
future. The importance of species complexes in Mycosphaerella has
become more evident in this genus in recent years (Crous et al.
2004a,
b,
2006 – this volume). To
study species complexes, variable gene regions must be studied and the
generation of greater numbers of data sets should allow for increased
resolution at the species level. This in turn will aid in the resolution of
species complexes and cryptic speciation. Studies of the deeper branches for
groups in Mycosphaerella can in future utilise sequence data for the
LSU region that have not previously been available. These should provide a
more lucid indication and support for phenotypic characters that are
phylogenetically informative.
Authors: J W Taylor; D J Jacobson; S Kroken; T Kasuga; D M Geiser; D S Hibbett; M C Fisher Journal: Fungal Genet Biol Date: 2000-10 Impact factor: 3.495
Authors: P W Crous; B A Summerell; A J Carnegie; M J Wingfield; G C Hunter; T I Burgess; V Andjic; P A Barber; J Z Groenewald Journal: Persoonia Date: 2009-10-29 Impact factor: 11.051
Authors: M Arzanlou; J Z Groenewald; R A Fullerton; E C A Abeln; J Carlier; M-F Zapater; I W Buddenhagen; A Viljoen; P W Crous Journal: Persoonia Date: 2008-03-21 Impact factor: 11.051
Fig. 1.
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Fig. 5.