D P Lawrence1, M T Nouri2, F P Trouillas1. 1. Department of Plant Pathology, University of California, One Shields Avenue, Davis, CA 95616, USA. 2. Department of Plant Pathology, University of California, Kearney Agricultural Research and Extension Center, Parlier, CA 93648, USA.
Abstract
Black foot disease is a common and destructive root disease of grapevine caused by a multitude of cylindrocarpon-like fungi in many viticultural areas of the world. This study identified 12 cylindrocarpon-like fungal species across five genera associated with black foot disease of grapevine and other diverse root diseases of fruit and nut crops in the Central Valley Region of California. Morphological observations paired with multi-locus sequence typing of four loci, internal transcribed spacer region of nuclear rDNA ITS1-5.8S-ITS2 (ITS), beta-tubulin (TUB2), translation elongation factor 1-alpha (TEF1), and histone (HIS), revealed 10 previously described species; Campylocarpon fasciculare, Dactylonectria alcacerensis, D. ecuadoriensis, D. macrodidyma, D. novozelandica, D. torresensis, D. valentina, Ilyonectria capensis, I. liriodendri, I. robusta, and two new species, Neonectria californica sp. nov., and Thelonectria aurea sp. nov. Phylogenetic analyses of the ITS+TUB2+TEF1 combined dataset, a commonly employed dataset used to identify filamentous ascomycete fungi, was unable to assign some species, with significant support, in the genus Dactylonectria, while all other species in other genera were confidently identified. The HIS marker was essential either singly or in conjunction with the aforementioned genes for accurate identification of most Dactylonectria species. Results from isolations of diseased plant tissues revealed potential new host associations for almost all fungi recovered in this study. This work is the basis for future studies on the epidemiology and biology of these important and destructive plant pathogens.
Black foot disease is a common and destructive root disease of grapevine caused by a multitude of cylindrocarpon-like fungi in many viticultural areas of the world. This study identified 12 cylindrocarpon-like fungal species across five genera associated with black foot disease of grapevine and other diverse root diseases of fruit and nut crops in the Central Valley Region of California. Morphological observations paired with multi-locus sequence typing of four loci, internal transcribed spacer region of nuclear rDNA ITS1-5.8S-ITS2 (ITS), beta-tubulin (TUB2), translation elongation factor 1-alpha (TEF1), and histone (HIS), revealed 10 previously described species; Campylocarpon fasciculare, Dactylonectria alcacerensis, D. ecuadoriensis, D. macrodidyma, D. novozelandica, D. torresensis, D. valentina, Ilyonectria capensis, I. liriodendri, I. robusta, and two new species, Neonectria californica sp. nov., and Thelonectria aurea sp. nov. Phylogenetic analyses of the ITS+TUB2+TEF1 combined dataset, a commonly employed dataset used to identify filamentous ascomycete fungi, was unable to assign some species, with significant support, in the genus Dactylonectria, while all other species in other genera were confidently identified. The HIS marker was essential either singly or in conjunction with the aforementioned genes for accurate identification of most Dactylonectria species. Results from isolations of diseased plant tissues revealed potential new host associations for almost all fungi recovered in this study. This work is the basis for future studies on the epidemiology and biology of these important and destructive plant pathogens.
Fungal genera with cylindrocarpon-like asexual morphs are cosmopolitan and may be isolated from soils as saprobes colonizing dead or dying plant material, as latent pathogens or endophytes, or as pathogens causing cankers and root rots of herbaceous and woody plant hosts (Samuels & Brayford 1994, Seifert , Halleen , 2006, Chaverri , Agustí-Brisach & Armengol 2013, Carlucci ). The asexual genus Cylindrocarpon (Sordariomycetes, Hypocreales, Nectriaceae) was described in 1913 with Cylindrocarpon cylindroides as the type species and has been linked to the sexual genus Neonectria (Rossman , Mantiri ), which is very closely related to Corinectria (González & Chaverri 2017). Booth (1966) first subdivided the genus Cylindrocarpon into four informal morphological groups based on the shape and septation of macroconidia and the presence/absence of microconidia and chlamydospores in culture. Based on Booth’s classification, Rossman transferred all reference strains of all Nectria groups with cylindrocarpon-like asexual morphs into the genus Neonectria. Three of Booth’s groups correlate strongly with the three clades proposed by Mantiri based on phylogenetic analysis of mitochondrial 18S rDNA sequences.Asexual morphs in the Neonectria
coccinea/galligena-group (clade I in Mantiri ) comprise Booth’s Cylindrocarpon group 1 (including the type specimen for the genus Neonectria; Neonectria ramulariae): macroconidia are 3–7(–9)-septate, cylindrical, generally straight, sometimes curved towards rounded ends, cultures generally produce microconidia but lack chlamydospores, with a few exceptions. Asexual morphs in the Neonectria
mammoidea/veuillotiana-group (clade II in Mantiri ) were placed in Booth’s Cylindrocarpon group 2: macroconidia are (3–)5–7(–9)-septate, fusiform to slightly curved with rounded ends, cultures generally lack microconidia and chlamydospores. Asexual morphs in the Neonectriaradicicola-group (clade III in Mantiri ) comprised Booth’s Cylindrocarpon group 3 which are characterized by 1–3-septate macroconidia, cylindrical, straight to slightly curved, apical cell bent slightly to one side, and cultures typically produce microconidia and chlamydospores.Subsequent molecular studies have shown that Neonectria/Cylindrocarpon species clustered into a monophyletic group based on phylogenetic analyses of the mitochondrial 18S ribosomal subunit (Mantiri , Brayford ). Both sets of authors indicated that distinct subclades existed within Neonectria, likely representing a generic complex, however neither described any new genera at that time. Halleen noticed great cultural and morphological variation among cylindrocarpon-like isolates collected from symptomatic and asymptomatic grapevine rootstocks in nurseries and vineyards in Australia, France, New Zealand, and South Africa. Phylogenetic analyses of three loci (ITS, 28S ribosomal large subunit, and TUB2) segregated cylindrocarpon-like asexual morphs from grapevines that produced curved macroconidia that are (1–)3–5(–6)-septate (average four septa), with microconidia and chlamydospores rarely produced in culture, as a unique lineage distant to Neonectria, which they described as Campylocarpon, based on C. fasciculare. Additionally, that study provided the first phylogenetic evidence that cylindrocarpon-like fungi were not monophyletic. This was the first formal taxonomic revision of divergent cylindrocarpon-like asexual morphs from the genus Cylindrocarpon.A detailed study on the taxonomy and phylogenetic position of cylindrocarpon-like asexual morphs was performed by Chaverri , whereby they described three new genera: (i) Ilyonectria (clade III Mantiri /Booth’s group 3): Ilyonectria species are generally characterized as producing cylindrical to straight to slightly bent macroconidia with 1–3 septa (rarely more than three septa), with rounded ends and a prominent basal hilum, microconidia are ellipsoidal with a prominent basal hilum, and abundant chlamydospores either singly or in chains; (ii) Rugonectria (clade II Mantiri /Booth’s group 2): Rugonectria species are characterized as producing fusarium-like macroconidia that are (3–)5–7(–9)-septate and tapered towards the ends, microconidia are ovoid to cylindrical and no chlamydospores; (iii) Thelonectria (clade II Mantiri /Booth’s group 2): Thelonectria species typically produce fusiform to curved macroconidia that are (3–)5–7(–9)-septate (average five septa), often broadest at upper third, with rounded apical cells and flattened or rounded basal cells, microconidia and chlamydospores are rarely produced in culture. Chaverri also established Neonectria s. str. (clade I Mantiri /Booth’s group 1), which typically produces cylindrical, generally straight, sometimes with slight curve towards the ends that are 3–7(–9)-septate (average five septa), with rounded ends and an inconspicuous hilum, microconidia are ellipsoidal to oblong, and chlamydospores may be produced by some species. These warranted revisions have helped to stabilize the taxonomy and to highlight the expansive biological and phylogenetic diversity within cylindrocarpon-like fungi.More recently, phylogenetic studies have revealed Ilyonectria and Thelonectria to be paraphyletic (Cabral , b, Salgado-Salazar ). Lombard resolved the paraphyletic nature of Ilyonectria by establishing the genus Dactylonectria. Dactylonectria differs morphologically from other cylindrocarpon-like fungi by producing abundant macro- and microconidia with chlamydospores found rarely in culture. Macroconidia of Dactylonectria are cylindrical, straight to slightly curved with 1–4 septa with the apical cell or apex typically bent slightly to one side, microconidia are ellipsoidal to ovoid, aseptate to 1-septate. Salgado-Salazar established Cinnamomeonectria, Macronectria, and Tumenectria as segregate genera based on phylogenetic and morphological data resolving the paraphyly of Thelonectria. In 2017, Aiello described the monotypic genus, Pleiocarpon, which was the sister taxon to Thelonectria.To date at least 24 species of cylindrocarpon-like fungi have been associated with black foot disease of grapevine (Lombard , Úrbez-Torres ) throughout the main viticultural regions of the world including Europe (Rego , Alániz ), the near East (Mohammadi ), Oceania (Halleen , Whitelaw-Weckert ), South Africa (Halleen ), and North and South America (Petit & Gubler 2005, Auger , Petit , Úrbez-Torres ). Symptoms of the disease include grapevine roots with necrotic root crowns, reduced root biomass, root rot, sunken root lesions, xylem necrosis, vascular streaking, and general decline of the canopy. Infected vines are often stunted with short internodes and leaves that appear scorched by water stress, eventually the entire vine is killed (Scheck ), resulting in costly economic losses due to removal and replanting of new vines. In many instances, black foot disease of grapevine is found in plants suffering stress conditions in the root system including poor planting (J rooting) and poor soil conditions such as poor water drainage (Petit & Gubler 2013).Beside the rather well-characterized black foot disease of grapevine, only a few additional root diseases of woody crops have been attributed to cylindrocarpon-like fungi and the biology and diversity of these fungi within fruit and nut crops remain overall poorly studied. A few species have been associated with root rot symptoms of avocado (Persea americana) in Italy (Vitale ), apple (Malus domestica) in Portugal (Cabral ) and South Africa (Tewoldemedhin ), kiwifruit (Actinidia
chienensis) in Turkey (Erper ), loquat (Eriobotrya japonica) in Spain (Agustí-Brisach et al. 2016), olive (Olea europeae) in California (Úrbez-Torres ), and walnut (Juglans regia) in Spain (Mora-Sala ). Additionally, species of Ilyonectria have been reported to cause cold storage rot of Prunus spp. in California (Marek ) and Canada (Traquair & White 1992), raising concerns among nurseries and growers. Synergistic interactions of cylindrocarpon-like fungi with nematodes and other fungi coupled with predisposing abiotic factors have been associated with Prunus replant disease in California (Bhat ).The aims of the present study were to elucidate the diversity and identity of cylindrocarpon-like species associated with black foot disease of grapevine and root rot symptoms in other perennial crops including almond, cherry, kiwi, olive, peach, pistachio, and walnut in California. Morphological observations coupled with multi-locus sequence typing will allow for accurate species diagnosis and potentially unveil new fungal species and host associations in the most productive agroecosystems within the Central Valley of California.
MATERIALS AND METHODS
Plant sampling and fungal isolation
Between 2014 and 2018, rotted roots from declining grapevines and various fruit and nut trees throughout the Central Valley Region of California were sampled for disease diagnosis. Common symptoms included poor growth and eventually wilting and collapse of entire plants. Roots of declining plants showed necrotic lesions, dark vascular streaking as well as root rot characterized by black discoloration of the root cortex, epidermis, and vascular tissues. Main perennial crops that were surveyed included almond (Prunus dulcis), cherry (Prunus avium), grape (Vitis vinifera), kiwi (Actinidia deliciosa), peach (Prunus persica), pistachio (Pistacia vera), olive (Olea europaea), and walnut (Juglans regia). On average, 2–3 symptomatic plants per vineyard and orchard were sampled. Fungal isolates were recovered from 10–12 necrotic root pieces (4 × 4 × 2 mm) per sample that were surface disinfested in 0.6 % sodium hypochlorite for 30 s, rinsed in two serial baths of sterile deionized water for 30 s, and plated on 2 % potato dextrose agar (PDA, Difco, Detroit, Michigan, USA.) plates amended with tetracycline (1 mg L−1). Petri dishes were incubated at 25 °C in the dark for up to 14 d. Fifty-five isolates with morphological characters of cylindrocarpon-like anamorphs, namely colonies with slow to medium growth with more-or-less consistent margin expansion, yellow to brown in color, were recovered in culture, from symptomatic plants in the Central Valley. All isolates were subsequently hyphal-tip purified to fresh PDA dishes for phylogenetic and morphological analyses. All isolates collected for this study are detailed in Table 1 and are maintained in the culture collection of the Department of Plant Pathology at Kearney Agricultural Research and Extension Center, Parlier, University of California, Davis, USA.
Table 1.
Fungal isolates used in this study and GenBank accession numbers.
Species
Isolatea
Host
Geographic origin
GenBank Accession No.b
ITS
TEF1
TUB2
HIS
Campylocarpon fasciculare
CBS 112613
Vitis vinifera
South Africa
AY677301
JF735691
AY677221
–
KARE1889
Vitis vinifera
Fresno Co., CA, USA
MK400278
MK409922
MK409845
–
KARE1890
Vitis vinifera
Fresno Co., CA, USA
MK400279
MK409923
MK409846
–
KARE1891
Vitis vinifera
Fresno Co., CA, USA
MK400280
MK409924
MK409847
–
KARE1892
Vitis vinifera
Fresno Co., CA, USA
MK400281
MK409925
MK409848
–
KARE1893
Vitis vinifera
Fresno Co., CA, USA
MK400282
MK409926
MK409849
–
KARE1894
Vitis vinifera
Fresno Co., CA, USA
MK400283
MK409927
MK409850
–
KARE1895
Vitis vinifera
Fresno Co., CA, USA
MK400284
MK409928
MK409851
–
Campylocarpon pseudofasciculare
CBS 112679
Vitis vinifera
South Africa
AY677306
JF735692
AY677214
–
Dactylonectria alcacerensis
CBS 129087
Vitis vinifera
Portugal
JF735333
JF735819
AM419111
JF735630
Cy133
Vitis vinifera
Spain
JF735331
JF735817
JF735459
JF735628
Cy134
Vitis vinifera
Spain
JF735332
JF735818
JF735629
JF735629
KARE413
Vitis vinifera
Fresno Co., CA, USA
MK400304
MK409948
MK409871
MK409906
KARE417
Vitis vinifera
Fresno Co., CA, USA
MK400305
MK409949
MK409872
MK409907
KARE418
Vitis vinifera
Fresno Co., CA, USA
MK400306
MK409950
MK409873
MK409908
Dactylonectria amazonica
MUCL55430
Rhizoplane, Piper sp.
Ecuador
MF683706
MF683664
MF683643
MF683685
MUCL55433
Root, Piper sp.
Ecuador
MF683707
MF683665
MF683644
MF683686
Dactylonectria anthuriicola
CBS 129085
Anthurium sp.
The Netherlands
JF735302
JF735768
JF735430
–
Dactylonectria ecuadoriensis
MUCL55424
Rhizoplane, Piper sp.
Ecuador
MF683704
MF683662
MF683641
MF683683
MUCL55205
Root, Piper sp.
Ecuador
MF683700
MF683658
MF683637
MF683679
MUCL55226
Root, Cyathea lasiosora
Ecuador
MF683703
MF683661
MF683640
MF683682
MUCL55432
Rhizoplane, Socratea exorrhiza
Ecuador
MF683702
MF683660
MF683639
MF683681
MUCL55431
Rhizoplane, Carludovica palmata
Ecuador
MF683701
MF683659
MF683638
MF683680
MUCL55425
Rhizoplane, Piper sp.
Ecuador
MF683705
MF683663
MF683642
MF683684
KARE2108
Olea europaea
San Joaquin Co., CA, USA
MK400316
MK409960
MK409883
MK409918
KARE2110
Olea europaea
San Joaquin Co., CA, USA
MK400317
MK409961
MK409884
MK409919
KARE2113
Olea europaea
San Joaquin Co., CA, USA
MK400318
MK409962
MK409885
MK409920
KARE2114
Olea europaea
San Joaquin Co., CA, USA
MK400319
MK409963
MK409886
MK409921
Dactylonectria estremocencis
CBS 129085
Vitis vinifera
Portugal
JF735320
JF735806
JF735448
JF735617
CPC 13539
Picea glauca
Canada
JF735330
JF735816
JF735458
JF735627
Dactylonectria hispanica
CBS 142827
Pinus halepensis
Spain
KY676882
KY676870
KY676876
KY676864
Cy228
Ficus sp.
Portugal
JF735301
JF735767
JF735429
JF735578
Dactylonectria macrodidyma
CBS 112615
Vitis vinifera
South Africa
AY677284
JF735833
AY677229
JF735647
Cy123
Vitis vinifera
CA, USA
JF735341
JF735837
JF735470
JF735648
Cy139
Vitis sp.
Portugal
AM419071
JF735839
AM419106
JF735650
KARE423
Prunus dulcis
Fresno Co., CA, USA
MK400300
MK409944
MK409867
MK409902
KARE2109
Olea europaea
San Joaquin Co., CA, USA
MK400301
MK409945
MK409868
MK409903
KARE2039
Vitis vinifera
Stanislaus Co., CA, USA
MK400302
MK409946
MK409869
MK409904
KARE2127
Pistacia vera
Tulare Co., CA, USA
MK400303
MK409947
MK409870
MK409905
Dactylonectria novozelandica
CBS 113552
Vitis vinifera
New Zealand
JF735334
JF735822
AY677237
JF735633
Cy115
Vitis vinifera
CA, USA
JF735335
JF735823
JF735460
JF735634
Cy116
Vitis vinifera
CA, USA
AJ875322
JF735824
JF735461
JF735635
KARE192
Prunus avium
Fresno Co., CA, USA
MK400307
MK409951
MK409874
MK409909
KARE474
Prunus avium
Kern Co., CA, USA
MK400308
MK409952
MK409875
MK409910
KARE2036
Vitis vinifera
Stanislaus Co., CA, USA
MK400309
MK409953
MK409876
MK409911
KARE2037
Vitis vinifera
Stanislaus Co., CA, USA
MK400310
MK409954
MK409877
MK409912
KARE2038
Vitis vinifera
Stanislaus Co., CA, USA
MK400311
MK409955
MK409878
MK409913
KARE2125
Pistacia vera
Tulare Co., CA, USA
MK400312
MK409956
MK409879
MK409914
KARE2126
Pistacia vera
Tulare Co., CA, USA
MK400313
MK409957
MK409880
MK409915
Dactylonectria polyphaga
MUCL55209
Root, Costus sp.
Ecuador
MF683689
MF683647
MF683626
MF683668
MUCL54802
Root, Asplenium sp.
Ecuador
MF683698
MF683656
MF683635
MF683677
Dactylonectria torresensis
CBS 129086
Vitis vinifera
Portugal
JF735362
JF735870
JF735492
JF735681
Cy118
Vitis vinifera
CA, USA
JF735354
JF735859
JF735483
JF735670
Cy120
Vitis vinifera
CA, USA
AJ875320
JF735860
AJ875320
JF735671
KARE1173
Pistacia vera
Fresno Co., CA, USA
MK400298
MK409942
MK409865
MK409900
KARE1174
Pistacia vera
Fresno Co., CA, USA
MK400299
MK409943
MK409866
MK409901
Dactylonectria valentina
CBS 142826
Ilex aquifolium
Spain
KY676881
KY676869
KY676875
KY676863
KARE2111
Olea europaea
San Joaquin Co., CA, USA
MK400314
MK409958
MK409881
MK409916
KARE2112
Olea europaea
San Joaquin Co., CA, USA
MK400315
MK409959
MK409882
MK409917
Dactylonectria vitis
CBS 129082
Vitis vinifera
Portugal
JF735303
JF735769
JF735431
JF735580
Ilyonectria capensis
CBS 132815
Protea sp.
South Africa
JX231151
JX231119
JX231103
—
KARE1920
Prunus persica
Fresno Co., CA, USA
MK400330
MK409974
MK409897
—
KARE1921
Prunus persica
Fresno Co., CA, USA
MK400331
MK409975
MK409898
—
Ilyonectria crassa
CBS 139.30
Lilium sp.
The Netherlands
JF735275
JF735723
JF735393
—
Ilyonectria destuctans
CBS 264.65
Cyclamen persicum
Sweden
AY677273
JF735695
AY677256
—
Ilyonectria europaea
CBS 129078
Vitis vinifera
Portugal
JF735294
JF735756
JF735421
—
Ilyonectria liriodendri
CBS 110.81
Liriodendron tulipifera
Yolo Co., CA, USA
DQ178163
JF735696
DQ178170
—
KARE84
Prunus avium
Fresno Co., CA, USA
MK400322
MK409966
MK409889
—
KARE85
Prunus avium
Fresno Co., CA, USA
MK400323
MK409967
MK409890
—
KARE88
Prunus avium
Fresno Co., CA, USA
MK400324
MK409968
MK409891
—
KARE97
Prunus avium
Fresno Co., CA, USA
MK400325
MK409969
MK409892
—
KARE1206
Actinidia deliciosa
Tulare Co., CA, USA
MK400326
MK409970
MK409893
—
KARE1207
Actinidia deliciosa
Tulare Co., CA, USA
MK400327
MK409971
MK409894
—
KARE2046
Juglans regia
Tulare Co., CA, USA
MK400328
MK409972
MK409895
—
KARE2049
Juglans regia
Tulare Co., CA, USA
MK400329
MK409973
MK409896
—
Ilyonectria mors-panacis
CBS 306.35
Panax quinquefolium
Canada
JF735288
JF735746
JF735414
—
Ilyonectria palmarum
CBS 135754
Howea fosteriana
Italy
HF937431
HF922614
HF922608
—
Ilyonectria robusta
CBS 308.35
Panax quinquefolium
Canada
JF735264
JF735707
JF735377
—
KARE1740
Olea europaea
Glenn Co., CA, USA
MK400320
MK409964
MK409887
—
KARE1741
Olea europaea
Glenn Co., CA, USA
MK400321
MK409965
MK409888
—
Ilyonectria venezuelensis
CBS 102032
Unknown
Venezuela
AM419059
JF735760
AY677255
—
Nectria balansae
CBS 125119
Living woody vine
French Guiana
HM484857
HM484848
HM484874
—
Nectria cinnabarina
A.R. 4477
Aesculus sp.
France
HM484548
HM484527
HM484606
—
Neonectria californica
KARE1838/CBS 145774
Pistacia vera
Madera Co., CA, USA
MK400332
MK409976
MK409899
—
Neonectria ditissima
CBS 226.31
Fagus sylvatica
Fresno Co., CA, USA
JF735309
JF735783
DQ789869
—
Neonectria lugdunensis
CBS 125485
Populus fremontii
USA
KM231762
KM231887
KM232019
—
Neonectria major
CBS 240.29
Alnus incana
Norway
JF735308
JF735782
DQ789872
—
Neonectria neomacrospora
CBS 324.61
Abies concolor
Netherlands
JF735312
HM364352
DQ789875
—
Neonectria obtusispora
CBS 183.36
Solanum tuberosum
Germany
AM419061
JF735796
AM419085
—
Neonectria ramulariae
CBS 151.29
Malus sylvestris
England
JF735313
JF735791
JF735438
—
Thelonectria acrotyla
G.J.S. 90-171
Unknown
Venezuela
JQ403329
JQ394751
JQ394720
—
Thelonectria amamiensis
MAFF 239819
Pinus luchuensis
Japan
JQ403337
KJ022348
JQ394727
—
MAFF 239820
Pinus luchuensis
Japan
JQ403338
KJ022349
JQ394720
—
Thelonectria aurea
KARE1830/CBS 145584
Olea europaea
Glenn Co., CA, USA
MK400285
MK409929
MK409852
—
KARE98
Prunus avium
Fresno Co., CA, USA
MK400286
MK409930
MK409853
—
KARE1831
Olea europaea
Glenn Co., CA, USA
MK400287
MK409931
MK409854
—
KARE1832
Olea europaea
Glenn Co., CA, USA
MK400288
MK409932
MK409855
—
KARE1833
Olea europaea
Glenn Co., CA, USA
MK400289
MK409933
MK409856
—
KARE1834
Vitis vinifera
Fresno Co., CA, USA
MK400290
MK409934
MK409857
—
KARE1835
Vitis vinifera
Fresno Co., CA, USA
MK400291
MK409935
MK409858
—
KARE1836
Vitis vinifera
Fresno Co., CA, USA
MK400292
MK409936
MK409859
—
KARE1837
Vitis vinifera
Fresno Co., CA, USA
MK400293
MK409937
MK409860
—
KARE1839
Pistacia vera
Madera Co., CA, USA
MK400294
MK409938
MK409861
—
KARE1840
Pistacia vera
Madera Co., CA, USA
MK400295
MK409939
MK409862
—
KARE1841
Pistacia vera
Madera Co., CA, USA
MK400296
MK409940
MK409863
—
KARE1923
Prunus persica
Fresno Co., CA, USA
MK400297
MK409941
MK409864
—
Thelonectria blackeriella
BF142
Vitis vinifera
Italy
KX778711
—
KX778702
—
Thelonectria diademata
A.R. 4765
Unknown
Argentina
NR_137784
JQ394736
JQ394700
—
Thelonectria gongylodes
G.J.S. 04-171
Acer sp.
Tennessee, USA
JQ403318
JQ394744
JQ394710
—
Thelonectria nodosa
G.J.S. 04-155
Thuja canadiensis
Tennessee, USA
JQ403317
JQ394743
JQ394709
—
Thelonectria olida
CBS 215.67
Asparagus officinalis
Germany
KJ021982
—
KM232024
—
Thelonectria stemmata
C.T.R. 71-19
Unknown
Jamaica
JQ403312
JQ394739
JQ394704
—
Thelonectria torulosa
A.R. 4764
Unknown
Argentina
JQ403309
KJ022389
JQ394701
—
Thelonectria trachosa
CBS 112467
Bark of conifer
Scotland
KF529842
KF569860
KF569869
—
Thelonectria truncata
G.J.S. 04-357
Unknown
Tennessee, USA
JQ403319
JQ394745
KJ022324
—
MAFF241521
Unknown
Japan
JQ403339
KJ022325
JQ394757
—
Thelonectria veuillotiana
G.J.S. 92-24
Fagus sylvatica
France
JQ403335
JQ394755
JQ394725
—
CBS 132341
Eucalyptus sp.
Azores Island
JQ403305
JQ394734
JQ394698
—
aIsolates in bold represent ex-type specimens.
bGenBank accessions in bold were produced in this study.
Phylogenetic analyses
Total genomic DNA was isolated from mycelium scraped with a sterile scalpel from the surface of 14-d-old PDA cultures using the DNeasy Plant Kit (Qiagen, Valencia, California), following the manufacturer’s instructions. All PCR reactions utilized AccuPower™ PCR Premix (Bioneer, Alameda, California), following the manufacturer’s instructions. Amplification of ribosomal DNA (rDNA), including the intervening internal transcribed spacer regions and 5.8S rDNA (ITS1–5.8S–ITS2), using the primer set ITS1 and ITS4 followed the protocol of White . Amplification of translation elongation factor 1-α (TEF1) fragments utilized the primer set CYLEF-1 and CYLEF-R2 (Crous , Cabral ), histone gene (HIS) fragments utilized CYLH3F and CYLH3R (Crous ) (only for Dactylonectria isolates), and beta-tubulin (TUB2) utilized primers T1 and CYLTUB1R (O’Donnell & Ciglek 1997, Crous ), with a slightly modified PCR program for TEF1 and TUB2: [initial denaturation (94 °C, 5 min) followed by 35 cycles of denaturation (94 °C, 30 s), annealing (58 °C for TEF1 and 62 °C for TUB2, 30 s), extension (72 °C, 60 s), and a final extension (72 °C, 10 min)]. PCR products were visualized on a 1.5 % agarose gel (120 V for 25 min) stained with GelRed® (Biotium, Fremont, California), following the manufacturer’s instructions, to confirm presence and size of amplicons, purified via Exonuclease I and recombinant Shrimp Alkaline Phosphatase (Affymetrix, Santa Clara, California), and sequenced bidirectionally on an ABI 3730 Capillary Electrophoresis Genetic Analyzer (College of Biological Sciences Sequencing Facility, University of California, Davis).Forward and reverse nucleotide sequences were assembled, proofread, and edited in Sequencher v. 5 (Gene Codes Corporation, Ann Arbor, Michigan) and deposited in GenBank (Table 1). Homologous sequences with high similarity from type isolates and non-type isolates (n = 31 and n = 32, respectively; Table 1) were included for phylogenetic reference utilizing the BLASTn function in NCBI including the curated database TrunkDiseaseID.org (Lawrence ). Multiple sequence alignments were performed in MEGA v. 6 (Tamura ) and manually adjusted where necessary in Mesquite v. 3.10 (Maddison & Maddison 2016). Alignments were submitted to TreeBASE under accession number S22859. Phylogenetic analyses were performed for each individual locus, for four different three-gene combinations (ITS+TEF1+TUB2; ITS+TEF1+HIS; ITS+TUB2+HIS; and TEF1+TUB2+HIS) and a four-gene (ITS+TEF1+TUB2+HIS) concatenated dataset. Each dataset was analyzed using two different optimality search criteria, maximum parsimony (MP) and maximum likelihood (ML) in PAUP v. 4.0b162 and GARLI v. 0.951 (Swofford 2003, Zwickl ), respectively. For MP analyses, heuristic searches with 1 000 random sequence additions were implemented with the Tree-Bisection-Reconnection algorithm, gaps were treated as missing data. Bootstrap analyses with 1 000 replicates using a heuristic search with simple sequence addition were used to produce majority-rule consensus trees to estimate branch support. For ML analyses, MEGA was used to infer a model of nucleotide substitution for each dataset, using the Akaike Information Criterion (AIC). ML analyses were conducted according to the best fit model of nucleotide substitution using default parameters in GARLI. Branch stability was determined by 1 000 bootstrap replicates. Sequences of Nectria cinnabarina isolate A.R. 4477 and N. balansae isolate CBS 125119 served as the outgroup taxa in all analyses except for the analyses of HIS where Dactylonectria estremocensis isolates CBS 129085 and CPC 13539 served as the outgroup taxon.
Morphology
Mycelial plugs (5-mm-diam) were taken from the margin of selected, actively growing cultures based on phylogenetic results and transferred to triplicate 90-mm-diam Petri dishes containing 2 % PDA and incubated at room temperature (24 +/− 1 °C) under natural photoperiod in April 2018 for up to 21 d. Radial growth was measured on day 7 and 14 by taking two measurements perpendicular to each other. Assessments of colony color (Rayner 1970) and morphology were made on day 14. Conidiophores (n = 20), macro- and microconidial dimensions (n = 30), phialides (n = 20), and chlamydospores (n = 20) were measured at 400 × and 1 000 × magnification from approximately 10-d-old synthetic low-nutrient agar (SNA; Nirenberg 1976) cultures, incubated as above, by excising a 1 cm3 SNA cube and placing on a glass microscope slide followed by placing a glass coverslip (no stain was applied, thus the native pigments of each fungal species was preserved) and observed with a Leica DM500B microscope (Leica microsystems CMS GmbH, Wetzlar, Germany). Morphological measurements are represented by the mean in the center with minima and maxima rounded to the nearest half micron in parentheses, respectively. The optimal temperature for growth was determined using strains KARE1838 and KARE1830. A 5-mm mycelial plug taken from the margin of an actively growing colony was placed in the center of triplicate 90-mm-diam PDA Petri dishes. Cultures were incubated at temperatures of 10–30 °C in 5 °C increments in the dark and radial growth was measured as above.
RESULTS
For delimiting the taxonomy of cylindrocarpon-like fungi, 118 strains were included in the alignment. The alignment parameters and unique site patterns of the different gene regions, gene combinations, and phylogenetic methods analyzed are presented in Table 2. The clade support values for genus/species identifications based on the different gene regions, gene combinations, and phylogenetic methods are plotted in a heat map in Table 3. The ITS, TEF1, and TUB2 individual phylogenies displayed low to moderate resolution of species boundaries within the genera Dactylonectria, Neonectria, and Thelonectria (Table 3), while TEF1 and TUB2 confidently identified Campylocarpon fasciculare and Ilyonectria capensis, I. liriodendri, and I. robusta. The HIS phylogeny strongly to moderately (≥ 84 % / ≥ 78 %, MP and ML bootstrap supports, respectively) supported all species in Dactylonectria, with the exception of D. ecuadoriensis (<70 % / < 70 %) (Table 3). The analysis of the four different three-gene dataset combinations yielded varying levels of support for Dactylonectria species. The ITS+TEF1+HIS and TEF1+TUB2+HIS datasets produced the strongest levels of support (≥ 88 % / ≥ 87 %) for six Dactylonectria species including four members of the former ‘macrodidyma’ species-complex (D. alcacerensis, D. macrodidyma, D. novozelandica, and D. torresensis) and two species that are closely related to D. vitis (D. ecuadoriensis and D. valentina). Furthermore, the clade supports from the four-gene analyses (ITS+TEF1+TUB2+HIS; Fig. 1) did not differ as compared to the aforementioned two three-gene analyses (ITS+TEF1+HIS and TEF1+TUB2+HIS; Table 3). The analysis of the datasets ITS+TEF1+TUB2 and ITS+TUB2+HIS provided variable support for four Dactylonectria species in the ‘macrodidyma’ species-complex and for the closely related species D. ecuadoriensis and D. valentina (Table 3). The commonly employed ITS+TEF1+TUB2 dataset was able to confidently identify (100 % / 100 %) three Ilyonectria species (I. capensis (two isolates), I. liriodendri (eight isolates), and I. robusta (two isolates), a monotypic lineage that clusters in Neonectria, with no apparent type or non-type association, close to N. neomacrospora CBS 324.61, the ex-type specimens of N. major CBS 240.29 and N. ditissima CBS 226.31. This lineage thus represented a potentially novel phylogenetic species, hereinafter identified as Neonectria californica sp. nov. (Table 3; Fig. 1), and 13 isolates clustered in the recently proposed genus Thelonectria with no apparent type or non-type association. Therefore these 13 isolates are hereinafter identified as Thelonectria aurea sp. nov. (Table 3; Fig. 1), which is closely related to T. truncata. The use of only two genes in any combination failed to properly support T. aurea (Table 3), however the three-gene combination as mentioned above robustly separates the two lineages (Fig. 1). The commonly employed dataset ITS+TEF1+TUB2 was unable to robustly identify several species in Dactylonectria, providing only low to moderate support for, D. ecuadoriensis (74 % / 72 %), D. macrodidyma (76 % / 82 %), D. valentina (77 %/78 %), and no support for D. novozelandica (< 70 % / < 70 %), (Table 3).
Table 2.
Statistical information on phylogenetic datasets analyzed in this study.
Individual gene datasets
Three-gene datasets
Four-gene dataset
ITS
TEF1
TUB2
HISa
ITS+TEF1+TUB2
ITS+TEF1+HISa
ITS+TUB2+HISa
TEF1+TUB2+HISa
ITS+TEF1+TUB2+HISa
Aligned characters (gaps included)
629
795
750
541
2174
1965
1920
2086
2715
Equally most parsimonious trees retained
100
100
100
6
100
36
100
100
100
Tree length
507
946
988
175
2543
1682
1704
2185
2723
Consistency index (CI)
0.659
0.636
0.613
0.771
0.606
0.637
0.631
0.615
0.616
Retention index (RI)
0.955
0.950
0.941
0.963
0.942
0.948
0.945
0.941
0.943
Rescaled Consistency index (RC)
0.629
0.604
0.577
0.743
0.571
0.604
0.596
0.579
0.581
Constant characters
414
408
368
425
1190
1247
1207
1201
1615
Parimony-uninformative characters
30
77
59
15
166
122
104
151
181
Parsimony-informative characters
185
310
323
101
818
596
609
734
919
Nucleotide substitution model
TN93+G
HKY+G
GTR+G+I
TN93+G
Assigned accordingly
Assigned accordingly
Assigned accordingly
Assigned accordingly
Assigned accordingly
Log likelihood of most likely tree
-3291.744
-5448.788
-5518.968
-1539.751
-15443.408
-10781.305
-11019.718
-13306.448
-17539.415
a Only includes Dactylonectria spp.
Table 3.
Clade support values plotted as a heat map for individual and combined datasets for species recovered in this study.
Fig. 1.
One of 100 equally most parsimonious trees generated from maximum parsimony analysis of the four-gene (ITS+TEF1+TUB2+HIS) combined dataset. Numbers in front and after the slash represent parsimony and likelihood bootstrap values from 1 000 replicates, respectively. Values represented by an asterisk were less than 70 % for the bootstrap analyses. The scale bar indicates the number of nucleotide changes.
Morphological characteristics of the fungal isolates recovered were similar to the descriptions of species in the genera Campylocarpon, Dactylonectria, Ilyonectria, Neonectria, and Thelonectria (Halleen , Chaverri , Lombard ). Morphological characteristics of novel taxa are reported in the taxonomy section below.Despite several media tested (PDA and SNA), no isolates molecularly identified as Campylocarpon fasciculare produced spores. Campylocarpon fasciculare isolate KARE1890 colonies after 14 d average 43.8 mm on PDA. Center of colony on PDA is livid red to dark vinaceous, with copious aerial hyphae, the inner margin is pale luteous and the outer margin is smooth, submerged, and white to off-white. Fascicles of hyphae extend from the colony center (Fig. 2).
Fig. 2.
Culture morphology of Campylocarpon fasciculare (KARE1890) recovered in this study.
Dactylonectria alcacerensis isolate KARE417 colonies after 14 d average 73.5 mm on PDA, fast-growing with mostly even margin expansion (Fig. 3A). Center of colony on PDA is buff with felty appearance with radial furrows and small sporulation centers and a flat, submerged, and violet colored inner margin and coral colored outer margin. Conidiophores (60.5–)88(–124.5) μm, simple or complex, long, slender, arising from aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (27.5–)51(–88.5) μm long, wider at the base (1.5–)2.5(–3.5) μm and tapering toward the apex (1.5–)1.5(–2) μm. Macroconidia cylindrical, straight to slightly bent toward the apical cell, 1–3-septate (Fig. 3B); 1-septate conidia (9.5–)14.5(–29.1) × (2.5–)3.5(–5.5) μm; 2-septate conidia (23–)29(–34) × (3.5–)5(–6.5) μm; 3-septate conidia (28.5–)36.5(–44) × (4–)5.5(–8) μm. Microconidia elliptical (5.5–)8.5(–15.5) × (2.5–)3(–4) μm. Chlamydospores not observed on SNA.
Fig. 3.
Culture morphology and conidia of Dactylonectria species recovered in this study. A–B.
Dactylonectria alcacerensis (KARE417). C–D.
Dactylonectria ecuadoriensis (KARE2113). E–F.
Dactylonectria macrodidyma (KARE423). G–H.
Dactylonectria novozelandica (KARE474). I–J.
Dactylonectria torresensis (KARE1173). K–L.
Dactylonectria valentina (KARE2111). Scale bars = 20 μm.
Dactylonectria ecuadoriensis isolate KARE2113 colonies after 14 d average 72.2 mm on PDA, fast-growing with even margin expansion (Fig. 3C). Center of colony on PDA is buff with copious glaucous blue green felty aerial hyphae and a smooth, submerged, pale violet mostly entire, margin. Conidiophores (27.5–)22(–82.5) μm, simple or complex, long, slender, arising from aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (11.5–)25.5(–41.5) μm long, wider at the base (2–)2.5(–3.5) μm and tapering toward the apex (1.5–)2(–2.5) μm. Macroconidia cylindrical to slightly bent 1(–3)-septate (Fig. 3D); 1-septate (22.5–)25(–28.5) × (4–)5(–6.5) μm; 2-septate (24.5–)28.5(–32.5) × (4.5–)5(–5.5) μm, and 3-septate (31.5–)36(–41) × (5.5–)6.5(–7). Microconidia elliptical, not common, (5.5–)7.5(–8.5) × (2.5–)3(–4) μm. Chlamydospores not observed on SNA.Dactylonectria macrodidyma isolate KARE423 colonies after 14 d average 46.5 mm on PDA, medium-growing with slight uneven margin expansion (Fig. 3E). Center of colony on PDA is buff with copious felty aerial hyphae and a flat honey margin, submerged, with fairly even growth. Conidiophores (51–)82(–121) μm, simple or complex, long, slender, arising from aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (26–)50.5(–85) μm long, wider at the base (1.5–)2(–2.5) μm and tapering toward the apex (1–)1.5(–2) μm. Macroconidia cylindrical 1(–3)-septate (Fig. 3F); 1-septate (8.5–) 12(–15.5) × (2–)3(–3) μm; 2–3-septate conidia uncommon. Microconidia elliptical, copious, (4–)5.5(–8) × (1.5–)2(–2.5) μm. Chlamydospores not observed on SNA.Dactylonectria novozelandica isolate KARE474 colonies after 14 d average 62.2 mm on PDA, medium-growing with even margin expansion (Fig. 3G). Center of colony on PDA is ochreous to coral with felty aerial hyphae and amber to apricot margin, flat and submerged. Conidiophores (42–)89(–148.5) μm, arise from long, slender, aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (18.5–)32(–49.5) μm, wider at the base (2–)2.5(–3) μm and tapering toward the apex (1.5–)2(–3) μm. Macroconidia cylindrical, 1–3-septate (Fig. 3H); 1-septate conidia (8–)12(–17.5) × (2–)2.5(–3.5) μm; 2-septate conidia (23–)27(–34) × (3–)4(–4.5) μm; 3-septate conidia (28.5–) 34(–46.5) × (3.5–)4.5(–6) μm. Microconidia elliptical, (7–)9.5(–11.5) × (2–)3(–4) μm. Chlamydospores not observed on SNA.Dactylonectria torresensis isolate KARE1173 colonies after 14 d average 59.7 mm on PDA, medium-growing with even margin expansion (Fig. 3I). Center of colony on PDA is ochreous to umber with copious coral to apricot aerial hyphae and luteous margin, flat and submerged. Conidiophores (58.5–) 94(–127) μm, simple or complex, long, slender, arising from aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (29.5–)59(–126) μm, wider at the base (2–)2.5(–3.5) μm and tapering toward the apex (1.5–)2(–2.5) μm. Macroconidia cylindrical, (1–)3-septate (Fig. 3J); 1-septate conidia (13–)26.5(–37) × (3.5–)5(–7) μm; 2-septate conidia (21–)31.5(–35.5) × (3–)5(–6) μm; and 3-septate conidia (32.5–) 35.5(–38) × (3.5–)5(–6.5) μm. Microconidia elliptical, aseptate, (7–)10(–15) × (2–)2.5(–3.5) μm. Chlamydospores not observed on SNA.Dactylonectria valentina isolate KARE2111 colonies after 14 d average 79.5 mm on PDA, fast-growing with even margin expansion (Fig. 3K). Center of colony on PDA is buff to honey with copious purple felty aerial hyphae with a flat and submerged flesh-colored margin. Conidiophores (34–)50.5(–79.5) μm, simple or complex, long, slender, arising from aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (16.5–)27(–42) μm, wider at the base (1.5–) 2.5(–3.5) μm and tapering toward the apex (1.5–)2(–2) μm. Macroconidia cylindrical, (1–)3-septate (Fig. 3L); 1-septate conidia (19.5–)23.5(–28) × (3.5–)4.5(–5) μm; 2-septate conidia (24.5–)27.5(–31) × (4.5–)5(–5.5) μm; and 3-septate conidia (25.5–)40(–39) × (4–)5(–6.5) μm. Microconidia elliptical, aseptate, (5.5–)9.5(–14.5) × (2–)2.5(–3.5) μm. Chlamydospores not observed on SNA.Ilyonectria capensis isolate KARE1920 colonies after 14 d average 75.8 mm on PDA, fast-growing with uneven margin (Fig. 4A). Center of colony on PDA is honey to buff with abundant aerial hyphae and a hazel margin, slightly raised and uneven. Conidiophores (36–)70.5(–109.5) μm, simple or complex, long, slender, arising from aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (16–)24.5(–43.5) μm, wider at the base (1.5–)2(–2.5) μm and tapering toward the apex (1.5–)1.5(–2) μm. Macroconidia cylindrical, straight to slightly bent toward the apical cell, 0–1(–3)-septate (Fig. 4B); 0–1-septate conidia (9.5–)12(–14) × (1.5–)2(–2.5) μm; 2–3-septate conidia rarely observed. Microconidia predominating, aseptate, ovoid to ellipsoid, (4.5–)6(–9.5) × (2–) 2.5(–4) μm. Chlamydospores not observed on SNA.
Fig. 4.
Culture morphology and conidia of Ilyonectria species recovered in this study. A–B.
Ilyonectria capensis (KARE1920). C–D.
Ilyonectria liriodendri (KARE1207). E–F.
Ilyonectria robusta (KARE1741). Scale bars: B = 30 μm; D and F = 20 μm.
Ilyonectria liriodendri isolate KARE1207 colonies after 14 d average 50.3 mm on PDA, medium-growing with some unevenness (Fig. 4C). Center of colony on PDA is buff with felty aerial hyphae and buff margin, flat and submerged. Conidiophores (29–)63(–88) μm, long, slender, mainly from aerial hyphae, and as sporodochial pulvinate domes of slimy masses on SNA. Phialides (13.5–)21.5(–32.5) μm, wider at the base (1.5–)2(–3) μm and tapering at the apex (1–)1.5(–2) μm. Macroconidia cylindrical, straight to slightly bent toward the apical cell, 1–3-septate (Fig. 4D); 1-septate conidia (11.5–)17 (–24.5) × (2–)3(–3.5) μm; 2-septate conidia (11.5–)15.5(–20.5) × (2.5–)3(–4.5) μm; 3-septate conidia (13–)18.5(–24) × (2.5–)3.5(–4.5) μm. Microconidia abundant, aseptate, elliptical, (4.5–)6(–8) × (1.5–)2(–3) μm. Chlamydospores globose to subglobose, (7.5–)13.5(–19) × (6.5–)12(–15.5) μm, mostly smooth some appear rough with deposits, thick-walled, formed singly or more commonly in short chains of up to four to five, becoming brown with age.Ilyonectria robusta isolate KARE1741 colonies after 14 d average 82 mm on PDA, medium-growing with even margin expansion (Fig. 4E). Center of colony on PDA is rust-colored with abundant felty aerial hyphae with a buff margin, flat and submerged. Conidiophores (54–)77.5(–112.5) μm, long, slender, mainly from aerial hyphae, also as sporodochial pulvinate domes of slimy masses on SNA. Phialides (13.5–)21.5(–32.5) μm, wider at the base (1.5–)2(–3) μm and tapering at the apex (1–)1.5(–2) μm. Macroconidia cylindrical, straight to slightly bent to one side near the apical cell, (1–)3-septate (Fig. 4F); 1-septate conidia (11.5–)17(–24.5) × (2–)3(–3.5) μm; 2-septate conidia (11.5–) 15.5(–20.5) × (2.5–)3(–4.5) μm; 3-septate conidia (13–)18.5(–24) × (2.5–)3.5(–4.5) μm. Microconidia abundant, aseptate, elliptical, (4.5–)6(–8) × (1.5–)2(–3) μm. Chlamydospores globose to subglobose, (6.5–)10.5(–14) × (6–)9(–12.5) μm, mostly smooth some appear rough with deposits, thick-walled, mostly occurring in concatenated chains of up to four to five, becoming golden-brown with age. No sexual morphs were observed on PDA nor SNA after 60 d.
Taxonomy
Morphological comparisons coupled with multi-locus phylogenetic analyses (MP and ML) of the combined multi-locus dataset identified two distinct and well-supported lineages for which no apparent species names exist. Thus, we propose the following new species binomials to properly circumscribe these unique species that were isolated from diseased roots of perennial fruit and nut crops in this study.D.P. Lawr. & Trouillas, MycoBank MB829442. Figs 1, 5.
Fig. 5.
Neonectria californica
sp. nov. (holotype BPI 910947, ex-type culture CBS 145774). A. Fourteen-day-old PDA culture. B. Macroconidia. C. Conidiophores. D. Sporodochial pulvinate dome of slimy masses of macroconidia. Scale bars: B–C = 30 μm; D = 65 μm.
Etymology: californica, named after the State of California, where the ex-type strain was collected.Sexual morph: Undetermined. Asexual morph: Conidiophores simple or complex. Simple conidiophores short and sparsely branched, (30–)62.5(–86.5) μm long terminating in a whorl of phialides. Phialides monophialidic, cylindrical, tapering toward the apex, (12–)19(–29) μm long, (1.5–)2.5(–2.5) μm wide at the base, and (1.5–)1.5(–1.5) μm wide at the apex. Macroconidia on SNA produced predominately in sporodochial pulvinate domes of slimy masses, (1–)3-septate, generally cylindrical, smooth-walled, some slightly curved, slightly wider at the base, with rounded end cells; 1-septate conidia (17.5–)20(–22.5) × (2.5–) 3.5(–4.5) μm; 2-septate conidia (18–)21.5(–23.5) × (2.5–)3.5(–4) μm; 3-septate conidia (21–)23.5(–27.5) × (3–)3.5(–4.5) μm. Microconidia and chlamydospores not observed on SNA.Culture characteristics: Colonies after 14 d average 55.3 mm on PDA, medium-growing with even margin expansion. Center of colony on PDA is white with abundant floccose aerial hyphae producing a cottony texture with a flat and submerged off-white margin with sparse aerial hyphae emerging directly behind the advancing front. Optimal growth temperature was 20 °C.Host: Pistacia vera.Distribution: Madera County, California, USA.Specimen examined: USA, California, Madera County, isolated from symptomatic roots (necrotic lesions and black discoloration of the root cortex, epidermis, and vascular tissues) of Pistacia vera, 13 Jun. 2017, F.P. Trouillas (holotype BPI 910947, culture ex-type CBS 145774).Notes: Phylogenetic analyses of the ITS+TEF1+TUB2 combined three-gene dataset suggests that N. neomacrospora, N. ditissima, and N. major are the closest relatives of N. californica. Neonectria ditissima, N. major, and N. neomacrospora produce microconidia (Castlebury , Schmitz ), whereas N. californica does not. Macroconidia of N. ditissima, N. major, and N. neomacrospora range from 3–8 -septate, whereas only 3-septate macroconidia were observed for N. californica.D.P. Lawr. & Trouillas, MycoBank MB829441. Figs 1, 6.
Fig. 6.
Thelonectria aurea sp. nov. (holotype BPI 910948, ex-type culture CBS 145584). A. Fourteen-day-old PDA culture. B. Macroconidia. C. Conidiophores and conidia. D. Macroconidia. Scale bars: B = 35 μm; C–D = 30 μm.
Etymology: aurea, named after the golden color of the colony produced on PDA.Sexual morph: Undetermined. Asexual morph: Phialides mostly emerge directly from hyphae some are borne apically on irregularly branching groups of cells, cylindrical to slightly swollen, (11–)15(–18.5) μm long, (2–)2(–2.5) μm wide at the base and (1.5–)1.5(–2.5) μm towards the apex. Macroconidia on SNA produced predominately in concentric rings of slimy pulvinate masses, 3-septate, cylindrical to slightly fusiform with curved or rounded end cells, (24–)31(–37) × (4–)4.5(–5.5) μm, most segments have internal spherical occlusions. Microconidia and chlamydospores not observed on SNA.Culture characteristics: Colonies after 14 d average 37.4 mm on PDA, medium- to slow-growing with even margin expansion. Center of colony on PDA is pure yellow to amber with some aerial hyphae and margin of colony is white and flat with sparse aerial hyphae emerging directly behind the advancing front. Optimal growth temperature was 25 °C.Hosts: Olea europaea, Pistacia vera, Prunus avium, Prunus persica, and Vitis vinifera.Distribution: Glenn, Fresno, and Madera Counties, California, USA.Specimen examined: USA, California, Glenn County, isolated from symptomatic roots (necrotic lesions and black discoloration of the root cortex, epidermis, and vascular tissues) of Olea europaea, 13 Apr. 2017, F.P. Trouillas (holotype BPI 910948, culture ex-type CBS 145584).Additional material examined: USA, California, Fresno County, isolated from symptomatic roots (necrotic lesions and black discoloration of the root cortex, epidermis, and vascular tissues) of Prunus persica (peach), 19 Sept. 2017, M.T. Nouri (KARE1923).Notes: Thelonectria aurea clusters in a well-supported clade closely related to T. truncata and distantly related to members of the T. coronata and T. veuillotiana complexes. Thelonectria aurea only produced three-septate conidia which were on average, (31 × 4.5 μm), shorter than the minimum length reported for T. truncata three-septate conidia, (40.5–)46.9(–71.4) μm (Salazar-Salgado ), thereby morphologically distinguishing the two taxa.
DISCUSSION
This study represents the first comprehensive molecular phylogeny to elucidate the identity and diversity of cylindrocarpon-like fungi associated with black foot disease of grapevine and root rot symptoms in other diverse economically important perennial fruit and nut crops in California. Multi-locus sequence typing along with morphological studies unveiled the identity of 10 previously described pathogenic cylindrocarpon-like species associated with diseased roots of perennial crops in California. These included Campylocarpon
fasciculare, grape; Dactylonectria
alcacerensis, grape; D. ecuadoriensis, olive; D. macrodidyma, almond, grape, pistachio, and olive; D. novozelandica, cherry, grape, and pistachio; D. torresensis, pistachio; D. valentina, olive; Ilyonectria
capensis, peach; I. liriodendri, cherry, kiwi, and walnut; and I. robusta, olive. All associations except C. fasciculare on grape (Halleen , Correia , Akgul ), D. novozelandica on grape (Cabral , b), and I. liriodendri on kiwi (Erper et al. 2011) are reported from California, to the best of our knowledge, for the first time.Morphological assessments revealed that Dactylonectria and Ilyonectria conidia are very similar in terms of shape, septation, and dimensions amongst and within both genera as noted in previous studies (Cabral , b, Lombard ). Both colony and conidial morphology have been extensively used to delimit fungal species associated with black foot disease of grapevine (Halleen , Petit & Gubler 2005, Schroers ), some with limited success. For example, Halleen noticed cultural and conidial differences amongst a collection of fungi isolated from asymptomatic and black foot affected grapevines from nurseries and vineyards in major viticultural areas of the world including Australia, France, New Zealand, and South Africa. Results of morphological observations revealed that Campylocarpon with large robust macroconidia that are mostly 3–4-septate, cylindrical, and slightly to moderately curved could be easily distinguished from those of I. destructans (formerly C. destructans) and D. macrodidyma (formerly C. macrodidymum/I. macrodidyma). Furthermore, Halleen stated that molecularly determined I. destructans isolates were morphologically indistinguishable from previously described I. destructans isolates (Booth 1966, Samuels & Brayford 1990) and thus distinguishable from D. macrodidyma macroconidia which are characterized as 1–3(–4)-septate, straight or sometimes slightly curved, cylindrical or typically minutely widening toward the tip, with apical cell typically slightly bent to one side. Petit & Gubler (2005) revealed that the cylindrocarpon-like fungi I. destructans and D. macrodidyma (previously known as Cylindrocarpon macrodidymum/Ilyonectria macrodidyma) associated with black foot disease in California were genetically distinct based on three separate loci (ITS, mitochondrial small subunit, and TUB2), however morphological comparisons of the two species could not distinguish them confidently. The statistical analysis by Petit & Gubler (2005) revealed that D. macrodidyma conidia were significantly larger than those of I. destructans, but the mean values of conidial dimensions were similar and their distributions largely overlapped, therefore they determined that conidial characters were unable to properly disentangle these two species (which have been shown to reside in different genera), which is in strong accord with Cabral , b and Lombard who strongly suggests that molecular data are necessary to obtain a confident species diagnosis when working with species in the genera Dactylonectria and Ilyonectria.Several gene fragments namely, ITS, TEF1, and TUB2, have been used extensively in molecular phylogenetic analyses of plant pathogenic ascomycetes either as single-gene or combined multi-gene analyses. However, some serious conflicts were disclosed in this study by comparing the commonly employed three-gene dataset, ITS+TEF1+TUB2, versus other three-gene combinations (Table 3) and the four-gene dataset (ITS+TEF1+TUB2+HIS) in relation to accurate identification of Dactylonectria species. In this study, the three-gene analyses of ITS+TEF1+TUB2 provided low to moderate support for D. ecuadoriensis (74 % / 72 %), D. macrodidyma (76 % / 82 %), D. valentina (77 % / 78 %), and no support for D. novozelandica (<70 %/<70 %). Similarly, Úrbez-Torres recovered Dactylonectria isolates from black foot disease associated grapevines in British Columbia, Canada, however their identity remains unresolved, based on the analysis of the three-gene dataset (ITS+TEF1+TUB2).The HIS locus has been shown to be a powerful marker for species delimitation especially within cylindrocarpon-like asexual morphs (Cabral , b) by resolving the former ‘macrodidyma’ species-complex into four very closely related lineages (Cabral ) and close relatives of D. vitis described from Ecuador (D. ecuadoriensis) and Spain (D. valentina), respectively (Gordillo , Mora-Sala ). Results from this study corroborate the increased accuracy of Dactylonectria species identification by incorporating the HIS locus into multi-locus analyses that include TEF1 and TUB2 data (Cabral , b).These results strongly suggest that the previous identifications of Dactylonectria
macrodidyma (former Cylindrocarpon macrodidymum/Ilyonectria macrodidyma) isolates associated with black foot disease of grapevine (Petit & Gubler 2005, Petit , Úrbez-Torres ) and olive root rot (Úrbez-Torres ), at least in North America, are uncertain. Most of the aforementioned studies were conducted before the utility of HIS was widely realized; therefore, the species diversity of Dactylonectria in North America has likely been underestimated. For instance, Cabral , b) revealed that isolates previously identified as “Cylindrocarpon marcrodidymum”, from black foot affected vines in California, indeed comprised three phylogenetic species recognized in the ‘macrodidyma’ species-complex (i.e.
D. macrodidyma, D. novozelandica, and D. torresensis). The current study has revealed that the fourth species in the ‘macrodidyma’ species-complex, D. alcacerensis, is also present in California vineyards. All previously reported isolates/species in this complex, in North America, will need to be re-examined with the addition of the HIS locus to refine and confirm their species identity. Similarly, the identification of Cylindrocarpon destructans (i.e.
Ilyonectria destructans/radicicola), originally identified as the causal agent of black foot disease (Maluta & Larignon 1991), in North America are likely erroneous. Cylindrocarpon destructans isolates previously identified from French and Portuguese vineyards were later shown to actually be I. liriodendri, based on morphological and molecular data (Halleen ). The same results have also been reported from vineyards in Spain, (Alaniz ), Australia (Whitelaw-Weckert ), Uruguay (Abreo ), and in California (Petit & Gubler 2007). Therefore, all previously collected isolates of C. destructans (syn. C. radicicola), at least in North America, should be re-examined in order to confirm their identity.Like Halleen we noticed morphological variation in appearances of cultures and micro-morphological assessments of conidia for some cylindrocarpon-like fungal isolates. A single isolate (KARE1838), now referred to as N. californica and a group of 13 isolates (KARE98, KARE1830–KARE1837, KARE1839–KARE1841, and KARE1923), now referred to as T. aurea, were also evaluated morphologically and phylogenetically. Colony morphology, macroconidial characteristics, and lack of microconidia and chlamydospore production of isolate KARE1838 resembled members of the genus Neonectria (Booth 1966, Rossman , Chaverri ). Neonectria californica clustered strongly in the genus Neonectria based on the three-gene combined analyses (ITS+TEF1+TUB2) with no evidence of systematic error. Typically, Neonectria species produce straight, cylindrical, 5-septate macroconidia with rounded end cells, microconidia or chlamydospores but not both. Neonectria species are known from temperate regions generally associated with woody substrata and may cause cankers, and are rarely found in the soil (Chaverri ), which may explain why we only recovered a single isolate of N. californica associated with symptomatic pistachio tree roots. The closest relatives of N. californica (i.e.
N. neomacrospora, N. major, and N. ditissima) have been associated with bark cankers of broad-leaf or coniferous trees in Europe and in North America (Castlebury ). Neonectria ditissima has been shown to be highly pathogenic to apple and pear trees causing cankers that limit the longevity and productivity of orchards (Castlebury ). Therefore, it is likely that the new species, N. californica, recovered in this study may be an opportunistic pathogen of woody substrates including plant roots. Future pathogenicity trials will test this hypothesis.Members of the genus Thelonectria are cosmopolitan and abundant in temperate, subtropical, and tropical regions including the Mediterranean-like climate in California with mild to cool, wet, winter seasons and hot and dry during the summer months. Thelonectria aurea resembles other Thelonectria species except that only 3-septate macroconidia were observed, whereas many other Thelonectria species produce, on average, 5-septate macroconidia with rounded end cells that may superficially resemble Campylocarpon species (Chaverri ). This has led some authors to speculate that these two genera are closely related (Halleen ). Indeed, Lombard provided strong evidence that the cylindrocarpon-like genera Dactylonectria, Ilyonectria, and Neonectria were more closely related to each other than to either Campylocarpon or Thelonectria. Chaverri stated that the only morphological differences between Campylocarpon and Thelonectria were the number of septa in macroconidia with four in Campylocarpon and five in Thelonectria, however this has now been shown to be an inadequate diagnostic character for these fungi as T. lucida, T. trachosa, and T. truncata have been reported to produce 3-sepatate macroconidia (Salgado-Salazar ), and now too T. aurea. Molecular phylogenetic analyses easily separate these two genera based on DNA data.Thelonectria species have been collected mainly from the bark of recently killed or dying broad-leaf and coniferous trees often causing small cankers and rarely occurring in the soil (Chaverri ). However, Thelonectria aurea isolates recovered in this study were routinely isolated from symptomatic root rots of diverse fruit trees including almond, cherry, olive, peach, pistachio, and including grapevine. Until now, T. blackeriella, from Italy was the only reported Thelonectria species known to cause black foot disease in grapevines (Carlucci ). However, Petit reported an isolate of undetermined identity belonging to the “Neonectria mammoidea group” (now Thelonectria) based on DNA sequences of ITS and TUB2 from symptomatic grapevines in Canada and New York, USA. BLASTn analyses suggest that this undetermined species is T. olida or a close relative, which is, interestingly, sister to T. blackeriella. Thelonectria aurea seems to have a broad host range as suggested by the isolation of this fungus from five different perennial cropping systems in central California.This study has resulted in several new putative fungal-host associations across diverse perennial crops in California. This is particularly alarming as some of these associations may likely represent emerging or re-emerging threats to sustainable crop production in California. Future pathogenicity trials will attempt to elucidate the virulence, host ranges, and host preferences as several cylindrocarpon-like species were isolated from different host plants, thereby contributing to a better understanding of cylindrocarpon-like fungal ecology and natural history.
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