A classification of the bird species of South America
South American Classification Committee
American Ornithologists' Union
(Part 6)
Part 6.
Suboscine Passeriformes, A (Eurylaimidae and Furnariidae) (below)
Part 1. Struthioniformes
to Cathartiformes (click)
Part 2. Accipitriformes to Charadriiformes (click)
Part 3. Columbiformes to Caprimulgiformes (click)
Part 4. Apodiformes (click)
Part 5. Trogoniformes to Piciformes (click)
Part 7. Suboscine Passeriformes, B (Thamnophilidae to Rhinocryptidae) (click)
Part 8. Suboscine Passeriformes, C (Tyrannidae to Tityridae) (click)
Part 9. Oscine Passeriformes, A (Vireonidae to Sturnidae) (click)
Part 10. Oscine Passeriformes, B (Motacillidae to Emberizidae) (click)
Part 11. Oscine Passeriformes, C (Cardinalidae to end) (click)
Hypothetical
List (click)
Hybrids and Dubious Taxa (click)
Literature Cited (click)
PASSERIFORMES
1
Suborder TYRANNI (SUBOSCINES) 2
1. Virtually all morphological and genetic
data support the monophyly of the order Passeriformes. Within the
Passeriformes, genetic data (e.g., Sibley & Ahlquist 1990, Edwards et al.
1991, Mindell et al. 1997, Garca-Moreno & Mindell 2000, Lovette &
Bermingham 2000, Irestedt et al. 2001, Prychitko & Moore 2003, Hackett et
al. 2008) support the traditional division of the order based on morphology
(see Ames 1971, Sibley & Ahlquist 1990) into suboscines (here Dendrocolaptidae
through Sapayoidae) and oscines (the rest of the families), with the exception
that the Acanthisittidae of New Zealand are basal to both groups (REF, Hackett
et al. 2008).
2. Within the suboscines, suborder Tyranni, two major divisions are
traditionally recognized and are supported by genetic data (Sibley &
Ahlquist 1985, 1990, Chesser 2004): (1) the New World families
("Tyrannides" of Sibley & Ahlquist 1990) and (2) the Old World
families (broadbills, pittas, and asities). Recent genetic data (Fjelds et al.
2003, Chesser 2004, Hackett et al. 2008) confirm that the Neotropical species Sapayoa
aenigma is the only New World member of the otherwise strictly Old World
group (see below). Within the New World "Tyrannides," two major
divisions are traditionally recognized and supported by genetic data (e.g.,
Chesser 2004, Hackett et al. 2008): (1) the woodcreepers, ovenbirds, antbirds,
gnateaters, and tapaculos, and (2) the tyrant-flycatchers, manakins, and
cotingas. For relationships among members within these two groups, see
appropriate family sections below.
EURYLAIMIDAE
(Sapayoa) 1
Sapayoa aenigma
Sapayoa 2
1. Sapayoa aenigma was
formerly (e.g., Meyer de Schauensee 1970) placed in the family Pipridae,
although that placement had been regarded as doubtful (e.g., Wetmore 1972).
Lanyon (1985) found not only that Sapayoa did not fit within the
Pipridae but also did not appear to be closely related to any groups in the New
World tyrannoid assemblage; Lanyon (1985) suggested that it might be more
closely related to Old World suboscines <check>. Sibley &
Ahlquist (1990) had similar results, leading Sibley & Monroe (1990) to
place Sapayoa as Incertae Sedis in the suboscines. < incorp.
Prum & Lanyon 1989, Prum 1990, Fjelds et al. 2003>. Treated in its own
monotypic family, Sapayoidae, by SACC until proposal below passed to place in
Eurylaimidae; spelled "Sapayoaidae" elsewhere (e.g., Dickinson 2003,
Snow 2004), but see Irestedt et al. (2006). Chesser (2004) and Hackett et al.
(2008) also clearly showed that Sapayoa is most closely related to the
Old World suboscines (broadbills, pittas, asities), and Irestedt et al. (2006)
and Moyle et al. (2006) further showed that it is embedded within the
Eurylaimidae as currently defined. SACC proposal passed
to place Sapayoa in Eurylaimidae. Irestedt
et al. (2006) further proposed breaking the Eurylaimidae into two families
(actually resurrecting the old family name Calyptomenidae for Smithornis
and Calyptomena to retain family-level rank for Sapayoidae. Proposal needed.
2. Sapayoa aenigma was
formerly called "Broad-billed Manakin" (e.g., Meyer de
Schauensee 1970). Called "Broad-billed Sapayoa" in Sibley &
Monroe (1990), Ridgely & Tudor (1994), and Ridgely & Greenfield (2001).
SACC proposal to
change to "Broad-billed Sapayoa" did not pass.
FURNARIIDAE
(OVENBIRDS) 1
Sclerurinae
Sclerurus mexicanus
Tawny-throated Leaftosser 1a, 99b
Sclerurus rufigularis Short-billed
Leaftosser
Sclerurus guatemalensis Scaly-throated
Leaftosser
Sclerurus caudacutus Black-tailed
Leaftosser
Sclerurus albigularis Gray-throated
Leaftosser
Sclerurus scansor Rufous-breasted
Leaftosser
Geositta peruviana Coastal Miner
3b
Geositta cunicularia Common Miner 3,
3a
Geositta tenuirostris Slender-billed Miner
4
Geositta antarctica Short-billed Miner
3a
Geositta isabellina Creamy-rumped Miner
Geositta saxicolina Dark-winged Miner
Geositta maritima Grayish Miner
3b
Geositta punensis Puna Miner 3c
Geositta rufipennis Rufous-banded Miner
3c, 4a
Geositta poeciloptera Campo Miner
1a, 2, 2a
Geositta crassirostris Thick-billed Miner
Furnariinae
Ochetorhynchus andaecola Rock
Earthcreeper 5a
Ochetorhynchus ruficaudus Straight-billed
Earthcreeper 5a, 6
Ochetorhynchus phoenicurus Band-tailed
Earthcreeper 5a, 9, 9a, 9b
Ochetorhynchus melanurus Crag Chilia
7, 9
Upucerthia saturatior Patagonian Forest
Earthcreeper 4b
Upucerthia dumetaria Scale-throated
Earthcreeper 4b
Upucerthia albigula White-throated
Earthcreeper
Upucerthia jelskii Plain-breasted
Earthcreeper 5
Upucerthia validirostris Buff-breasted
Earthcreeper 5
Upucerthia serrana Striated Earthcreeper
5a
Cinclodes excelsior Stout-billed Cinclodes
10, 10a, 10b
Cinclodes aricomae Royal Cinclodes 10a,
10b, 11
Cinclodes fuscus Bar-winged Cinclodes
12, 13a, 14a, 14b
Cinclodes comechingonus Cordoba Cinclodes
12, 13a
Cinclodes pabsti Long-tailed Cinclodes
13, 13a
Cinclodes olrogi Olrog's Cinclodes
14, 14a
Cinclodes oustaleti Gray-flanked Cinclodes
14a, 14c
Cinclodes patagonicus Dark-bellied Cinclodes
15b
Cinclodes taczanowskii Surf Cinclodes
15, 15a
Cinclodes nigrofumosus Seaside Cinclodes
15, 15a
Cinclodes antarcticus Blackish Cinclodes
10a, 15b
Cinclodes atacamensis White-winged Cinclodes
15c
Cinclodes palliatus White-bellied Cinclodes
15c
Furnarius figulus Wing-banded Hornero
16
Furnarius leucopus Pale-legged Hornero
17, 18
Furnarius torridus Pale-billed Hornero
18, 18a
Furnarius minor Lesser Hornero
Furnarius rufus Rufous Hornero
Furnarius cristatus Crested Hornero
Limnornis curvirostris Curve-billed
Reedhaunter 19
Limnoctites rectirostris Straight-billed
Reedhaunter 19
Phleocryptes melanops Wren-like Rushbird
19
Aphrastura spinicauda Thorn-tailed Rayadito
19a
Aphrastura masafuerae Masafuera Rayadito
Leptasthenura fuliginiceps Brown-capped
Tit-Spinetail 19a
Leptasthenura yanacensis Tawny Tit-Spinetail
19b
Leptasthenura platensis Tufted Tit-Spinetail
19b, 19c
Leptasthenura aegithaloides Plain-mantled
Tit-Spinetail 19c, 19d
Leptasthenura striolata Striolated
Tit-Spinetail
Leptasthenura pileata Rusty-crowned
Tit-Spinetail 20
Leptasthenura xenothorax White-browed
Tit-Spinetail 20
Leptasthenura striata Streaked Tit-Spinetail
21, 21a
Leptasthenura andicola Andean Tit-Spinetail
Leptasthenura setaria Araucaria Tit-Spinetail
22
Spartonoica maluroides Bay-capped
Wren-Spinetail 22a, 22b
Sylviorthorhynchus desmursii Des Murs's
Wiretail 22c
Schizoeaca perijana Perija Thistletail
23, 24
Schizoeaca coryi Ochre-browed Thistletail
24
Schizoeaca fuliginosa White-chinned Thistletail
24, 25
Schizoeaca griseomurina Mouse-colored
Thistletail 24
Schizoeaca palpebralis Eye-ringed
Thistletail 24
Schizoeaca vilcabambae Vilcabamba
Thistletail 24, 26
Schizoeaca helleri Puna Thistletail
24
Schizoeaca harterti Black-throated Thistletail
24
Oreophylax moreirae Itatiaia Spinetail
27
Schoeniophylax phryganophilus Chotoy
Spinetail 28, 28b
Synallaxis ruficapilla Rufous-capped
Spinetail 29
Synallaxis whitneyi Bahia Spinetail
29, 30
Synallaxis infuscata Pinto's Spinetail
29, 31
Synallaxis cinerascens Gray-bellied
Spinetail
Synallaxis subpudica Silvery-throated
Spinetail
Synallaxis frontalis Sooty-fronted
Spinetail 32, 32b
Synallaxis azarae Azara's Spinetail
33
Synallaxis courseni Apurimac Spinetail
34
Synallaxis albescens Pale-breasted Spinetail
34a
Synallaxis albigularis Dark-breasted
Spinetail 34a, 34b
Synallaxis spixi Spix's Spinetail 35
Synallaxis hypospodia Cinereous-breasted
Spinetail 36
Synallaxis rutilans Ruddy Spinetail
Synallaxis cherriei Chestnut-throated
Spinetail
Synallaxis unirufa Rufous Spinetail
37
Synallaxis castanea Black-throated Spinetail
37
Synallaxis fuscorufa Rusty-headed Spinetail
37
Synallaxis brachyura Slaty Spinetail
Synallaxis tithys Blackish-headed
Spinetail
Synallaxis propinqua White-bellied
Spinetail
Synallaxis macconnelli McConnell's
Spinetail 39, 40
Synallaxis moesta Dusky Spinetail 39,
38
Synallaxis cabanisi Cabanis's Spinetail
39
Synallaxis maranonica Maraon Spinetail
41
Synallaxis gujanensis Plain-crowned
Spinetail 41
Synallaxis albilora White-lored Spinetail
41, 42
Synallaxis scutata Ochre-cheeked Spinetail
43
Synallaxis candei White-whiskered Spinetail
43
Synallaxis kollari Hoary-throated Spinetail
43
Synallaxis cinnamomea Stripe-breasted
Spinetail
Synallaxis zimmeri Russet-bellied
Spinetail
Synallaxis stictothorax Necklaced
Spinetail 44, 44a
Siptornopsis hypochondriaca Great Spinetail
45, 45b
Gyalophylax hellmayri Red-shouldered
Spinetail 46
Hellmayrea gularis White-browed Spinetail
47
Cranioleuca marcapatae Marcapata Spinetail
48, 49
Cranioleuca albiceps Light-crowned Spinetail
49
Cranioleuca vulpina Rusty-backed Spinetail
49b
Cranioleuca vulpecula Parker's Spinetail
50
Cranioleuca sulphurifera Sulphur-throated
Spinetail
Cranioleuca subcristata Crested
Spinetail
Cranioleuca pyrrhophia Stripe-crowned
Spinetail 51
Cranioleuca henricae Bolivian Spinetail
51, 52
Cranioleuca obsoleta Olive Spinetail
51, 53
Cranioleuca pallida Pallid Spinetail
Cranioleuca semicinerea Gray-headed
Spinetail
Cranioleuca albicapilla Creamy-crested
Spinetail
Cranioleuca erythrops Red-faced
Spinetail 54
Cranioleuca demissa Tepui Spinetail
54
Cranioleuca hellmayri Streak-capped
Spinetail 54
Cranioleuca curtata Ash-browed Spinetail
54, 54a, 55, 55b
Cranioleuca antisiensis Line-cheeked
Spinetail 51, 54
Cranioleuca baroni Baron's Spinetail
51, 54, 56
Cranioleuca gutturata Speckled Spinetail
Cranioleuca muelleri Scaled Spinetail
Certhiaxis cinnamomeus Yellow-chinned
Spinetail 57, 58, 58a
Certhiaxis mustelinus Red-and-white
Spinetail 57
Thripophaga macroura Striated Softtail
59, 59a
Thripophaga cherriei Orinoco Softtail
Thripophaga fusciceps Plain Softtail
60
Thripophaga berlepschi Russet-mantled
Softtail 60
Asthenes pudibunda Canyon Canastero
61, 61a
Asthenes ottonis Rusty-fronted Canastero
61a
Asthenes heterura Maquis Canastero
61a
Asthenes modesta Cordilleran Canastero
62
Asthenes cactorum Cactus Canastero 62
Asthenes humilis Streak-throated Canastero
Asthenes wyatti Streak-backed
Canastero 63
Asthenes sclateri Puna Canastero 63,
64
Asthenes anthoides Austral Canastero
63
Asthenes hudsoni Hudson's Canastero
Asthenes urubambensis Line-fronted
Canastero
Asthenes flammulata Many-striped
Canastero 65
Asthenes virgata Junin Canastero 65
Asthenes maculicauda Scribble-tailed
Canastero 65
Asthenes pyrrholeuca Sharp-billed Canastero
66, 66a, 67
Asthenes humicola Dusky-tailed Canastero
67
Asthenes dorbignyi Creamy-breasted Canastero
67, 68
Asthenes berlepschi Berlepsch's Canastero
67, 69
Asthenes steinbachi Steinbach's Canastero
67, 70
Asthenes baeri Short-billed Canastero
66a, 67
Asthenes luizae Cipo Canastero 67, 71
Asthenes patagonica Patagonian Canastero
67
Phacellodomus rufifrons Rufous-fronted
Thornbird 72, 72a, 72b
Phacellodomus sibilatrix Little Thornbird
72b
Phacellodomus striaticeps Streak-fronted
Thornbird
Phacellodomus maculipectus Spot-breasted
Thornbird 73
Phacellodomus striaticollis Freckle-breasted
Thornbird 73
Phacellodomus dorsalis Chestnut-backed
Thornbird
Phacellodomus ruber Greater Thornbird
Phacellodomus erythrophthalmus Orange-eyed
Thornbird 74, 74a
Phacellodomus ferrugineigula. Orange-breasted
Thornbird 74, 74a
Clibanornis dendrocolaptoides Canebrake
Groundcreeper 75
Anumbius annumbi Firewood-gatherer
74b
Coryphistera alaudina Lark-like Brushrunner 74b
Siptornis striaticollis Spectacled
Prickletail
Metopothrix aurantiaca Orange-fronted
Plushcrown 75a, 75b
Acrobatornis fonsecai Pink-legged Graveteiro
76
Xenerpestes minlosi Double-banded Graytail
76a, 76b, 76c
Xenerpestes singularis Equatorial Graytail
76a, 76b
Premnornis guttuligera Rusty-winged Barbtail
78a
Premnoplex brunnescens Spotted Barbtail
78a, 77
Premnoplex tatei White-throated Barbtail
78a, 77
Roraimia adusta Roraiman Barbtail 78b
Margarornis stellatus Fulvous-dotted
Treerunner 79
Margarornis squamiger Pearled Treerunner
79a
Pseudoseisura cristata Caatinga Cacholote
22a, 80
Pseudoseisura unirufa Rufous Cacholote
80
Pseudoseisura lophotes Brown Cacholote
Pseudoseisura gutturalis White-throated
Cacholote
Pseudocolaptes lawrencii Buffy
Tuftedcheek 78a, 81, 81a, 81b
Pseudocolaptes boissonneautii Streaked
Tuftedcheek 81
Tarphonomus harterti Bolivian Earthcreeper
7, 8
Tarphonomus certhioides Chaco Earthcreeper
7, 8
Berlepschia rikeri Point-tailed Palmcreeper
Anabacerthia variegaticeps Scaly-throated
Foliage-gleaner 82, 82a, 82aa, 83, 83a, 85a
Anabacerthia striaticollis Montane
Foliage-gleaner 82a, 82aa, 82b
Anabacerthia amaurotis White-browed
Foliage-gleaner 82a, 82c
Syndactyla guttulata Guttulate
Foliage-gleaner 84, 85, 85aa
Syndactyla subalaris Lineated
Foliage-gleaner 85, 85a
Syndactyla rufosuperciliata Buff-browed
Foliage-gleaner
Syndactyla ruficollis Rufous-necked
Foliage-gleaner 86
Syndactyla dimidiata Russet-mantled
Foliage-gleaner 90, 90b, 92, 92a, 92b
Syndactyla roraimae White-throated
Foliage-gleaner 97a, 97b, 97c
Simoxenops ucayalae Peruvian Recurvebill
87, 87b
Simoxenops striatus Bolivian Recurvebill
87
Ancistrops strigilatus Chestnut-winged
Hookbill 88
Hyloctistes subulatus Striped Woodhaunter
85a, 89, 89a, 89b
Philydor ruficaudatum Rufous-tailed
Foliage-gleaner 85a, 90, 90aa
Philydor fuscipenne Slaty-winged
Foliage-gleaner 90, 91, 90aaa
Philydor erythrocercum Rufous-rumped
Foliage-gleaner 90, 90a, 90bb
Philydor erythropterum Chestnut-winged
Foliage-gleaner 90
Philydor lichtensteini Ochre-breasted
Foliage-gleaner
Philydor novaesi Alagoas
Foliage-gleaner 90c, 90d
Philydor atricapillus Black-capped
Foliage-gleaner 90d
Philydor rufum Buff-fronted Foliage-gleaner
90
Philydor pyrrhodes Cinnamon-rumped
Foliage-gleaner 90b
Anabazenops dorsalis Dusky-cheeked
Foliage-gleaner 92c, 93, 93a
Anabazenops fuscus White-collared
Foliage-gleaner
Cichlocolaptes leucophrus Pale-browed
Treehunter 93b
Thripadectes ignobilis Uniform Treehunter
85a
Thripadectes melanorhynchus Black-billed
Treehunter
Thripadectes holostictus Striped
Treehunter
Thripadectes virgaticeps Streak-capped
Treehunter
Thripadectes flammulatus Flammulated
Treehunter 94
Thripadectes scrutator Rufous-backed
Treehunter 94, 95
Automolus ochrolaemus Buff-throated
Foliage-gleaner 85a
Automolus infuscatus Olive-backed
Foliage-gleaner 96, 96a
Automolus paraensis Para Foliage-gleaner
96, 96a
Automolus lammi Pernambuco Foliage-gleaner
96a, 96b
Automolus leucophthalmus White-eyed
Foliage-gleaner 96a, 96b
Automolus melanopezus Brown-rumped
Foliage-gleaner
Automolus rubiginosus Ruddy
Foliage-gleaner 97d
Automolus rufipileatus Chestnut-crowned Foliage-gleaner
Automolus rufipectus Santa Marta
Foliage-gleaner 97d
Hylocryptus erythrocephalus Henna-hooded
Foliage-gleaner 98
Hylocryptus rectirostris Chestnut-capped
Foliage-gleaner 99, 99a
Lochmias nematura Sharp-tailed Streamcreeper
100, 100a, 100b
Heliobletus contaminatus Sharp-billed
Treehunter 101
Megaxenops parnaguae Great Xenops 103
Pygarrhichas albogularis White-throated
Treerunner 104
Xenops milleri Rufous-tailed Xenops
102, 102a
Xenops tenuirostris Slender-billed Xenops
Xenops minutus Plain Xenops
Xenops rutilans Streaked Xenops
Dendrocolaptinae 105
Dendrocincla tyrannina Tyrannine
Woodcreeper 105a
Dendrocincla fuliginosa Plain-brown
Woodcreeper 106, 107
Dendrocincla merula White-chinned
Woodcreeper 108
Dendrocincla homochroa Ruddy
Woodcreeper
Deconychura longicauda Long-tailed
Woodcreeper 109
Deconychura stictolaema Spot-throated
Woodcreeper 109, 110
Sittasomus griseicapillus Olivaceous
Woodcreeper 111
Glyphorynchus spirurus Wedge-billed
Woodcreeper 112, 113, 114
Drymornis bridgesii Scimitar-billed
Woodcreeper 115
Nasica longirostris Long-billed
Woodcreeper
Dendrexetastes rufigula Cinnamon-throated
Woodcreeper 116, 117
Hylexetastes stresemanni Bar-bellied
Woodcreeper 118
Hylexetastes perrotii Red-billed
Woodcreeper 118
Xiphocolaptes promeropirhynchus Strong-billed
Woodcreeper 119, 120
Xiphocolaptes falcirostris Moustached
Woodcreeper 119, 121
Xiphocolaptes albicollis White-throated
Woodcreeper 119, 122
Xiphocolaptes major Great Rufous
Woodcreeper
Dendrocolaptes sanctithomae Northern
Barred-Woodcreeper 123, 124
Dendrocolaptes certhia Amazonian
Barred-Woodcreeper 123, 125
Dendrocolaptes picumnus Black-banded
Woodcreeper 126, 127
Dendrocolaptes hoffmannsi Hoffmanns's
Woodcreeper 126
Dendrocolaptes platyrostris Planalto
Woodcreeper 126
Dendroplex picus Straight-billed
Woodcreeper 128, 129
Dendroplex kienerii Zimmer's Woodcreeper 128, 130
Xiphorhynchus obsoletus Striped
Woodcreeper
Xiphorhynchus fuscus Lesser
Woodcreeper 131
Xiphorhynchus ocellatus Ocellated
Woodcreeper 132, 134
Xiphorhynchus elegans Elegant
Woodcreeper 133, 134
Xiphorhynchus spixii Spix's
Woodcreeper 133, 134
Xiphorhynchus pardalotus Chestnut-rumped
Woodcreeper 134
Xiphorhynchus susurrans Cocoa
Woodcreeper 135
Xiphorhynchus guttatus Buff-throated
Woodcreeper 135
Xiphorhynchus lachrymosus Black-striped
Woodcreeper
Xiphorhynchus erythropygius Spotted
Woodcreeper 136
Xiphorhynchus triangularis Olive-backed
Woodcreeper 136
Lepidocolaptes souleyetii Streak-headed
Woodcreeper
Lepidocolaptes angustirostris Narrow-billed
Woodcreeper
Lepidocolaptes lacrymiger Montane
Woodcreeper 137
Lepidocolaptes squamatus Scaled
Woodcreeper
Lepidocolaptes falcinellus Scalloped
Woodcreeper 138
Lepidocolaptes albolineatus Lineated
Woodcreeper 139
Campylorhamphus pucherani Greater
Scythebill
Campylorhamphus trochilirostris Red-billed
Scythebill 140
Campylorhamphus falcularius Black-billed
Scythebill 140
Campylorhamphus procurvoides Curve-billed
Scythebill 141
Campylorhamphus pusillus Brown-billed
Scythebill 142
1. This classification treats the
woodcreepers (formerly Dendrocolaptidae) and the ovenbirds (Furnariidae) as
members of a single family. Whether the two groups are sister taxa has never
seriously been questioned (see Sibley & Ahlquist 1990, Marantz et al. 2003,
Remsen 2003). Historically, the controversy centered around the taxonomic
ranking of the two groups, with some authors treating them as subfamilies of
the same family, whereas others treated them each as separate families.
Feduccia (1973) proposed that the woodcreepers were embedded within the Furnariidae,
thus making that family paraphyletic. Genetic data (Irestedt et al. 2002, 2006,
Chesser 2004a, Fjelds et al. 2005, Moyle et al. 2009) strongly support the
latter, with the genera Geositta and Sclerurus basal to all other
ovenbirds plus woodcreepers. SACC proposal passed
to merge Dendrocolaptidae and Furnariidae into single family without subfamily
rankings. If family or subfamily ranks are retained within this group,
then a third group, Geositta plus Sclerurus, must also be
accorded taxonomic rank; the linear sequence here simply places the
woodcreepers at the end. SACC proposal passed
to add subfamily ranks. An
alternative classification would be to recognize all three major groups as
families, i.e., Scleruridae, Furnariidae, and Dendrocolaptidae (see Moyle et
al. 2009).
1a. Genetic data (Irestedt et al. 2002, 2006,
Chesser 2004a. Moyle et al. 2009) indicate that Geositta and Sclerurus
are sister genera that are basal to other Furnariidae (including
dendrocolaptids). SACC proposal passed
to change linear sequence.
2. Vaurie (1980) proposed that Geositta
consisted of three major groups based on bill shape and distribution. Cheviron
et al. (2005) found that none of these groups is monophyletic, but that within
the genus, there are two main groups: (1) cunicularia + tenuirostris
+ peruviana, and (2) all other species. Within the second group,
Cheviron et al. (2005) found strong support for two groups: (3) antarctica
+ isabellina + saxicolina + maritima, and (4) punensis
+ rufipennis + poeciloptera + crassirostris. SACC proposal passed
to modify linear sequence of species.
2a. Geositta poeciloptera was formerly
(e.g., Cory & Hellmayr 1925, Pinto 1937, Peters
1951, Meyer de Schauensee 1970, Sibley & Monroe 1990) placed in the
monotypic genus Geobates, but see Vaurie (1980) and Remsen (2003).
Genetic data (Cheviron et al. 2005) indicate that poeciloptera is
embedded within Geositta.
3. Fjelds & Krabbe (1990) suggested that
vocal differences between lowland nominate cunicularia and Andean subspecies
indicate that at least two species are involved in Geositta cunicularia.
Genetic data (Cheviron et al. 2005) also suggest that more than one species is
involved.
3a. Vaurie (1980) tentatively considered Geositta
maritima and G. peruviana to be sister species because of their
lowland distribution, small size, and plumage similarities, but he also
suspected that these similarities might be due to convergence. Cheviron et al.
(2005) corroborated the convergence hypothesis; these two species belong in different
clades within the genus.
3b. Geositta cunicularia and G.
antarctica have been considered to be closely related because of their
similarity in plumage (Vaurie 1980, Vuilleumier 1991), but genetic data
indicate that they are only distantly related within the genus (Cheviron et al.
2005).
3c. Genetic data (Cheviron et al. 2005)
indicate that Geositta punensis and G. rufipennis are sister
species.
4. Geositta tenuirostris is
traditionally (e.g., Meyer de Schauensee 1970) placed near the end of the
linear sequence of species in the genus because of its unusually long and
decurved bill. However, bill curvature and length are notoriously labile
characters; the plumage pattern of tenuirostris suggests a close
relationship to G. cunicularia (Remsen 2003). Genetic data
(Cheviron et al. 2005) indicate that G. tenuirostris and G.
cunicularia are sister species.
4a. Geositta rufipennis may consist of
more than one species (Jaramillo 2003, Remsen 2003).
4b. Esteban (1951) provided rationale for
considering the taxon saturatior a separate species from Upucerthia
dumetaria, but this has not been followed by subsequent authors. Areta and Pearman (2009), however,
provided evidence of parapatry without intergradation as well as documented
differences in song, bare parts colors, morphology, plumage, habitat, and
migratory patterns that validate EstebanĠs (1951) original assessment. SACC proposal passed to elevate saturatior to species rank.
5. Although Upucerthia jelskii
is considered separate species from U. validirostris in most
recent classifications (e.g., Meyer de Schauensee 1970, Ridgely & Tudor
1994), evidence for their treatment as such is weak (Remsen 2003), and perhaps
a return to earlier classifications that treated them as conspecific (e.g.,
Cory & Hellmayr 1925, Peters 1951) is warranted. They form a superspecies
(Sibley & Monroe 1990). A report of sympatry in southern Bolivia (Cabot
1990) is based on a misidentification (Remsen 2003). Genetic data (Chesser et
al. 2007, Fjelds et al. 2007) confirm that they are sister taxa. Areta and Pearman (2009) found no
differences in their voices. proposal needed?
5a. Fjelds (1992) proposed that Upucerthia
serrana and U. andaecola were sister species, based on plumage and
voice, and that they formed a monophyletic group with U. ruficaudus and Eremobius
phoenicurus, despite the unusual nest of the latter that has led in part to
its placement in a monotypic genus. However, Chesser et al. (2007) and Fjelds
et al. (2007) found that serrana is not closely related to andaecola,
or to other species currently placed in Upucerthia. See also Notes 7 and 9. Chesser et al. (2009) described a new genus, Geocerthia, for serrana. SACC proposal
badly needed.
6. Correct spelling
for species name is ruficaudus, not ruficauda (David &
Gosselin 2002a).
7. The genus Ochetorhynchus was used
for U. harterti and U. certhioides by Ridgely &
Tudor (1994) to recognize the distinctiveness of these two species from other Upucerthia
(especially with respect to nest type); however, the type species of Ochetorhynchus
is ruficaudus, making that name unavailable for harterti + certhioides
unless ruficaudus is also included (Remsen 2003). Peters (1951) treated
those three species in Ochetorhynchus. The genus Upucerthia is
highly polyphyletic (Chesser et al. 2007, Fjelds et al. 2007, Moyle et al.
2009), with (a) harterti and certhioides in a group with Pseudocolaptes
and Premnornis, (b) andaecola and ruficaudus in a group
with Eremobius and Chilia [see Note 9], (c) serrana basal
to a group that includes Cinclodes and the remaining Upucerthia (dumetaria,
albigula, jelskii, and validirostris).
Chesser and Brumfield (2007) named
a new genus Tarphonomus for certhioides + harterti. SACC proposal passed
to recognize Tarphonomus.
8. Vaurie (1980) considered harterti
and certhioides as conspecific, but see Kratter et al. (1993) and
Ridgely & Tudor (1994) for rationale for maintaining as separate species
until more data are available; they form a superspecies (Sibley & Monroe
1990, Remsen 2003) and are sister taxa (Chesser et al. 2007, Fjelds et al.
2007).
9. Fjelds & Krabbe (1990) and Ridgely
& Tudor (1994) proposed that Eremobius is probably more closely
related to Upucerthia than to the genera near which often placed in
linear sequences, but nest structure much more like synallaxine spinetails
(Zyskowski and Prum 1989). Chesser et al. (2007) and Fjelds et al. (2007)
found that Eremobius is the sister taxon to U. ruficaudus.
Chesser et al. (2007) further recommended that Ochetorhynchus be revived
for ruficaudus and that Eremobius be merged into it, as well as Chilia.
See also Notes 5a and 7. SACC proposal passed to
reinstate Ochetorhynchus.
9a. Eremobius phoenicurus was formerly
(e.g., Cory & Hellmayr 1925) treated in the genus Enicornis.
9b. Called "Band-tailed Eremobius"
in " in Mazar Barnett & Pearman (2001).
10. ChaserĠs (2004b) phylogeny indicates that
the traditional linear sequence within Cinclodes requires modification. SACC proposal pending to
change linear sequence.
10a. Cinclodes excelsior and C.
aricomae were placed by Vaurie (1980) in Geositta, which is
certainly incorrect (Fjelds & Krabbe 1990). Likewise, Cory &
Hellmayr's (1925) placement of excelsior in Upucerthia is almost
certainly incorrect.
10b. Fjelds (1992) proposed that Cinclodes
antarcticus is the sister taxon to C. excelsior and C. aricomae,
based on plumage similarities. Genetic data, however, indicate that C.
antarcticus and C. fuscus are sister species (Chesser 2004).
11. Cinclodes aricomae is often
considered conspecific with C. excelsior (e.g., Peters 1951,
Meyer de Schauensee 1970), and evidence for treating them as separate species
(e.g., Fjelds & Krabbe 1990, Remsen 2003) is weak. Proposal needed.
12. Cinclodes comechingonus is considered
by some (e.g., Mayr 1957<?>, Meyer de Schauensee 1966, 1970, Navas &
B 1987) to be a subspecies of C. fuscus; sympatry is only during
nonbreeding season; they were considered to form a superspecies by Sibley &
Monroe (1990). Genetic data, however, indicate that C. fuscus and C.
antarcticus are sister species, and that C. comechingonus is the
sister to C. olrogi + C. oustaleti (Chesser 2004); therefore,
treatment as a species-level taxon is strongly supported. See also Note 14b.
13. Recently described: Sick (1969).
13a. Sibley & Monroe (1990) considered Cinclodes
pabsti to form a superspecies with C. fuscus and C. comechingonus.
Genetic data, however, indicate that C. pabsti is basal in the genus and
not particularly closely related to any other Cinclodes species.
14. Recently described: Nores & Yzurieta
(1979).
14a. Nores (1986) considered Cinclodes
olrogi to be a subspecies of C. fuscus; others (Olrog 1979, Navas
& B 1987, Vuilleumier & Mayr 1987, Mazar Barnett & Pearman 2001)
considered it more likely to be closely related to C. oustaleti. Genetic
data support the latter relationship (Chesser 2004). See also Note 14b.
14b. Jaramillo (2003) suggested that the albiventris
group might warrant recognition as a separate species from Cinclodes fuscus.
Unfortunately, Chesser's (2004) sampling did not include populations of C.
fuscus from the Andes north of Argentina. Sann et al. (2009) sampled C. fuscus from throughout its range and found that it was
polyphyletic, with various populations more closely related to C. olrogi, C. oustaleti, C.
comechingonus, and C. antarcticus.
SACC proposal
pending to elevate the albiventris
and albidiventris groups to species
rank.
14c. Called "Oustalet's Cinclodes"
in Mazar Barnett & Pearman (2001).
15. Cinclodes taczanowskii and C.
nigrofumosus were considered conspecific by Meyer de Schauensee (1966,
1970), although previously (e.g., Hellmayr 1925, Peters 1951) considered
separate species; justification for treating them as separate species is weak
(Remsen 2003); they form a superspecies (Sibley & Monroe 1990, Remsen
2003), and genetic data (Chesser 2004) show that they are weakly differentiated
sister taxa. SACC proposal to lump
these two species did not pass because of insufficient published data.
15a. Called "Peruvian
Seaside-Cinclodes" and "Chilean Seaside-Cinclodes" in Ridgely
& Tudor (1994). SACC proposal to change
English names did not pass.
15b. Sibley & Monroe (1990) suggested
that Cinclodes antarcticus may be part of a superspecies with C.
taczanowskii and C. nigrofumosus, but genetic data show that they
are not closely related and that their maritime habits have evolved
independently (Chesser 2004). Cinclodes patagonicus is the sister
species to C. taczanowskii + C. nigrofumosus.
15c. Genetic data (Chesser 2004) show that C.
atacamensis and C. palliatus are sister species, consistent with
their traditional classification.
16. Called "Band-tailed Hornero" by
Ridgely & Tudor (1994). SACC proposal to change
English name did not pass.
17. The subspecies cinnamomeus of W.
Ecuador and NW. Peru may deserve recognition as a separate species from F.
leucopus (Ridgely & Tudor 1994) and was treated as such by Parker &
Carr (1992) and Ridgely & Greenfield (2001). The subspecies longirostris
was also treated as a separate species by Ridgely & Greenfield (2001) and
Hilty (2003). Although vocal and behavioral differences have been reported, no
real analysis has been published to support these splits. SACC proposal to
elevate cinnamomeus to species rank did not pass because of insufficient
published data.
18. Cory & Hellmayr (1925) considered Furnarius
torridus to be a subspecies of F. leucopus, and Vaurie (1973)
considered F. torridus to be a color morph of F. leucopus. Zimmer
(1936) presented evidence that torridus was a separate species, and this
has been followed by most subsequent authors (e.g., Peters 1951, Meyer de
Schauensee 1970). Sibley & Monroe (1990) considered them to form a
superspecies, but they are widely sympatric.
18a. Called "Bay Hornero" in
Ridgely & Tudor (1994). SACC proposal to change
English name did not pass.
19. Vaurie (1980) and Sibley & Monroe
(1990) merged Limnoctites into Limnornis; this was followed by
Dickinson (2003), but see Ridgely & Tudor (1994) and Remsen (2003). Olson
et al. (2005) have shown that Limnornis and Limnoctites are not
particularly closely related, with Limnoctites embedded within Cranioleuca,
and with Limnornis closely related to Phleocryptes (see also
Irestedt et al. 2006, Moyle et al. 2009). However, taxon-sampling still so
incomplete within the genus that although C. sulphurifera and Limnoctites
are almost certainly sisters, their inclusion together in Cranioleuca is
uncertain. SACC proposal to merge
Limnoctites into Cranioleuca did not pass.
19a. Vaurie (1980) and Fjelds (1992)
proposed that morphological similarities indicate that Aphrastura and Leptasthenura
are sister genera, but genetic data (Moyle et al. 2009) do not support this.
19b. Fjelds (1992) proposed that Leptasthenura
fuliginiceps and L. yanacensis were sister species, based on plumage
similarities, as reflected in their placement in traditional linear sequences.
19c. Fjelds (1992) proposed that Leptasthenura
platensis and L. aegithaloides were sister species, as reflected in
their placement in traditional linear sequences.
19d. Jaramillo (2003) suggested that Leptasthenura
aegithaloides might consist of more than one species.
20. Leptasthenura xenothorax was
considered a subspecies of L. pileata by Vaurie (1980); they are
generally considered to be sister species (e.g., Fjelds 1992) and form a
superspecies (Sibley & Monroe 1990, Remsen 2003).
21. Called "Streak-backed
Tit-Spinetail" by <REF>.
21a. Fjelds (1992) proposed that Leptasthenura
striata was the sister taxon to L. pileata/L. xenothorax, based on
plumage similarities, as reflected in their placement in traditional linear
sequences.
22. Leptasthenura setaria was formerly
(e.g., Cory & Hellmayr 1925, Pinto 1937)
treated in the monotypic genus Dendrophylax.
22a. Spartonoica was formerly (e.g.,
Cory & Hellmayr 1925, Pinto 1937) included
in Asthenes. Genetic data
(Moyle et al. 2009) indicate that it is the sister to Pseudoseisura. SACC proposal needed to change linear sequence <Remsen working on one>.
22b. Spartonoica was misspelled (as
"Spartanoica") in Meyer de Schauensee (1966, 1970) and
elsewhere.
22c. Remsen (2003) noted that similarities in
general morphology and tail structure suggested a possible relationship of Sylviorthorhynchus
to Schizoeaca. However, recent genetic data (Gonzalez and Wink 2008,
Moyle et al. 2009) indicate a close relationship to Leptasthenura.
23. Recently described: Phelps (1977).
24. Vaurie (1980) considered all Schizoeaca
conspecific, but see Remsen (1981), Fjelds & Krabbe (1990), Ridgely &
Tudor (1994), and Remsen (2003) for maintaining traditional species limits, as,
for example, in Peters (1951) and Meyer de Schauensee (1966, 1970); they form a
superspecies (Sibley & Monroe 1990).
25. It seems likely that Schizoeaca fuliginosa
is a paraphyletic species with respect to S. griseomurina, whose
range interrupts the two northern subspecies, nominate fuliginosa and fumigata,
and the two southern subspecies, peruviana and plengei (Remsen
2003).
26. Recently described (as subspecies of S.
fuliginosa): Vaurie et al. (1972).
27. The genus Oreophylax was included
in Schizoeaca by Vaurie (1980) and Sibley & Monroe (1990), but see
Ridgely & Tudor (1994). Recent genetic data confirm that they are closely
related and probably sister taxa (Irestedt et al. 2006).
28. Vaurie (1980) included Schoeniophylax
in Synallaxis, but see Ridgely & Tudor (1994) and Remsen (2003).
Recent genetic data confirm that they are closely related and probably sister
taxa (Irestedt et al. 2006).
28b. Schoeniophylax is masculine, so
the correct spelling of the species name is phryganophilus (David &
Gosselin 2002b).
29. Synallaxis ruficapilla, S. cinerea,
and S. infuscata form a superspecies (Pacheco & Gonzaga
1995).
30. Synallaxis whitneyi/cinerea
was formerly (e.g., Meyer de Schauensee 1970 <trace>) considered a junior
synonym of S. ruficapilla. Pacheco and Gonzaga (1995) showed that
this population merits species rank, which they named S. whitneyi.
Whitney & Pacheco (2001) then showed that whitneyi was a synonym of cinerea.
More recently, however, Stopiglia and Raposo (2006) proposed that whitneyi
is indeed the correct name. SACC proposal passed
to change back to S. whitneyi. For an opinion on this from Edward Dickinson, see: whitneyi.
31. Synallaxis infuscata was formerly
(e.g., Meyer de Schauensee 1970) considered a subspecies of S. ruficapilla,
but see Vaurie (1980) and Pacheco & Gonzaga (1995) for evidence for
treating as a separate species.
32. The taxon Synallaxis poliophrys
("Gray-browed Spinetail"), long treated as a species (e.g., Cory
& Hellmayr 1925, Peters 1951, Meyer de Schauensee 1970), is a synonym of S.
frontalis (Vaurie 1971b).
32b. "Synallaxis poliophrys,"
was formerly treated as a species (e.g., Meyer de Schauensee 1970), but
Vaurie (1971b) determined that it is a synonym of S. frontalis.
See Hybrids and
Dubious Taxa.
33. The superciliosa subspecies group
was formerly (e.g., Cory & Hellmayr 1925, Peters 1951, Meyer de Schauensee
1970) considered a separate species ("Buff-browed Spinetail") from S.
azarae, but see Remsen et al. (1988). Vaurie (1980) treated the elegantior
subspecies group as a species separate from S. azarae, and this
was followed by Fjelds & Krabbe (1990); see Ridgely & Tudor (1994) for
a return to the treatment of the elegantior group as conspecific with S.
azarae.
34. Recently described: Blake (1971). Fjelds
and Krabbe (1990) noted that Synallaxis courseni is most closely related
to S. azarae and perhaps best considered a subspecies of S.
azarae; it was originally thought to be closest to S. brachyura.
34a. Synallaxis albigularis was
formerly (e.g., Cory & Hellmayr 1925, Pinto 1937)
considered conspecific with S. albescens, but see Chapman (1931) and
Zimmer (1936b).
34b. Hilty and Ascanio (2009) described a new
species, Synallaxis beverlyae, from
Venezuela, whose vocalizations are closest to those of S. albigularis, S. hypospodia,
and S. spixi, but most similar in
plumage to S. albescens. SACC
proposal pending to recognize S.
beverlyae.
35. Synallaxis spixi was formerly
(e.g., Meyer de Schauensee 1970, Sibley & Monroe 1990) known as
"Chicli Spinetail," but see Ridgely & Tudor (1994).
36. Synallaxis hypospodia was formerly
(e.g., Cory & Hellmayr 1925) considered a subspecies of S. spixi,
but see Zimmer (1936b).
37. Synallaxis castanea was formerly
(e.g., Cory & Hellmayr 1925, Peters 1951, Phelps & Phelps 1950a, Meyer
de Schauensee 1970) considered a subspecies of S. unirufa, but
see Vaurie and Schwartz (1972) for rationale for considering it a separate
species; they form a superspecies (Sibley & Monroe 1990) that presumably
also includes S. fuscorufa (Remsen 2003).
38. The subspecies brunneicaudalis was
formerly (e.g., Cory & Hellmayr 1925) treated as a separate species from Synallaxis
moesta.
39. Synallaxis macconnelli was
formerly (e.g., Zimmer 1936b, Phelps & Phelps 1950a, Peters 1951, Meyer de
Schauensee 1970) considered conspecific with S. cabanisi, but
see Vaurie (1980) and Ridgely & Tudor (1994) for rationale for treating macconnelli
as a separate species; Synallaxis macconnelli, S. cabanisi,
and S. moesta form a superspecies.
40. English name often given incorrectly as
"MacConnell's Spinetail"; it was named for F. V. McConnell.
41. Synallaxis maranonica and S.
albilora were formerly (e.g., Zimmer 1936b, Peters 1951, Meyer de
Schauensee 1970) considered conspecific with S. gujanensis, but
see Vaurie (1980) and Ridgely & Tudor (1994) for rationale for treating
them as separate species (as presaged by Meyer de Schauensee 1966). Cory &
Hellmayr (1925) considered maranonica to be a separate species from S.
gujanensis, but not albilora. These three taxa constitute a
superspecies, although Sibley & Monroe (1990) excluded maranonica.
The boundary between albilora and gujanensis, based on plumage,
does not correspond to the boundary in vocal types (Remsen 2003). SACC proposal to treat albilora as
conspecific with S. gujanensis did not pass.
42. Called "Ochre-breasted
Spinetail" in Meyer de Schauensee (1966).
43. The genus Poecilurus (for candei,
kollari, and scutatus) was merged into Synallaxis by
Vaurie (1980), and this merger has been followed by some (Sibley & Monroe
1990, Hilty 2003) but not others (Ridgely & Tudor 1994). Cory &
Hellmayr (1925) and Pinto (1937) recognized Poecilurus
for candei and kollari, but placed scutatus in Synallaxis.
In terms of voice and plumage at least, P. scutatus is certainly
well within the range of variation of Synallaxis, and the nests of P.
candei are essentially identical to those of S. erythrothorax;
there is no way to characterize Poecilurus as a genus other than as a
composite of the plumage features of the component species, and it is not
certain whether the three species form a monophyletic group (Remsen 2003). Synallaxis is feminine (N. David, pers.
comm.), so scutatus becomes scutata.
44. Synallaxis stictothorax may be
more closely related to Siptornopsis or Cranioleuca than to other
Synallaxis; see Ridgely & Tudor (1994), Ridgely & Greenfield
(2001), and Remsen (2003).
44a. Ridgely & Tudor (1994) and Ridgely
& Greenfield (2001) considered the upper Maraon population chinchipensis
as a separate species, but no analysis or data published. SACC proposal to elevate chinchipensis
to species rank did not pass because of insufficient published data.
45. Vaurie (1980) merged Siptornopsis
into Cranioleuca.
45b. Siptornopsis is feminine, so the
correct spelling of the species name is hypochondriaca (David &
Gosselin 2002b), as in Cory & Hellmayr (1925).
46. Vaurie (1980) merged Gyalophylax into
Synallaxis; Cory & Hellmayr (1925) and Pinto
(1937) included it in Asthenes. See Whitney & Pacheco (1994)
for continued recognition as monotypic genus until relationships clarified. Genetic data (Moyle et al. 2009) are
consistent with a merger into Synallaxis,
but broader taxon-sampling is needed.
47. Hellmayrea was formerly included
in Synallaxis (e.g., Cory & Hellmayr 1925, Meyer de Schauensee 1970)
or in Cranioleuca (Vaurie 1980). Braun and Parker (1985) provided
evidence for why Hellmayrea should be maintained as a monotypic genus,
as in Phelps & Phelps (1950a) and Peters (1951). Recent genetic data
confirm that Hellmayrea is not closely related to Synallaxis
(Irestedt et al. 2006, Moyle et al. 2009).
48. Sequence of species in Cranioleuca
incorporates the genetic data from Garca-Moreno et al. (1999b). Vaurie (1980)
included Cranioleuca in Certhiaxis, but this has not been
followed by most subsequent authors (e.g., see Wetmore 1972, Fitzpatrick REF).
49. The superspecies relationship proposed
for Cranioleuca marcapatae and C. albiceps (e.g.,
Remsen 1984) is corroborated by genetic data (Garca-Moreno et al. 1999b);
Fjelds & Krabbe (1990) proposed that they might be best treated as
conspecific.
49b. "Cranioleuca solimonensis,"
described from a single specimen from Amazonian Brazil, is now considered a
synonym of Cranioleuca vulpina alopecias (Peters 1951). See Hybrids and
Dubious Taxa.
50. Cranioleuca vulpecula was formerly
(e.g., Cory & Hellmayr 1925, Pinto 1937, Peters
1951, Meyer de Schauensee 1970, Ridgely & Tudor 1994) considered a
subspecies of C. vulpina, but see Zimmer (1997) for evidence for
treating C. vulpecula as a separate species.
51. Genetic data (Garca-Moreno et al. 1999b)
are consistent with the proposal that Cranioleuca henricae, C.
pyrrhophia, and C. obsoleta form a superspecies (Sibley
& Monroe 1990, Maijer and Fjelds 1997). Fjelds & Krabbe (1990)
proposed that C. pyrrhophia might form a superspecies with C.
antisiensis/C. baroni.
52. Recently described: Maijer and Fjelds
(1997).
53. Belton (1985) suggested that Cranioleuca
obsoleta was a subspecies of C. pyrrhophia based on specimens
from Rio Grande do Sul that he considered intermediate. Ridgely & Tudor
(1994) acknowledged specimens showing some intermediate characters, but
continued to recognize obsoleta as a distinct species, as do other
authors (e.g., see Hayes 1995). Claramunt (2002) showed that evidence for free
interbreeding between the two was weak at best.
54. Cranioleuca hellmayri and C.
demissa were once considered conspecific (e.g., REF), but recent
authors have followed Vaurie (1971b) in treating them as separate species; they
form a superspecies (Sibley & Monroe 1990), which may also include Cranioleuca
erythrops, C. curtata, C. antisiensis, and C. baroni (REF). Fjelds
& Krabbe (1990) proposed that C. curtata might be best treated as
conspecific with C. erythrops.
54a. The subspecies cisandina was
formerly (e.g., Cory & Hellmayr 1925) treated as a separate species from Cranioleuca
curtata, but Peters (1951) treated them as conspecific; this has been
followed by all subsequent authors.
55. As suspected by Meyer de Schauensee
(1966), the taxon "Cranioleuca furcata," formerly (e.g., Cory
& Hellmayr 1925, Peters 1951) considered a valid species, has been shown to
be a juvenal/immature plumage of C. curtata (Graves 1986b), despite
earlier claims to the contrary (Vaurie 1971c, 1980).
55b. "Cranioleuca furcata,"
formerly treated as a species (e.g., Vaurie 1980), is now considered to
represent a juvenal/immature plumage of C. curtata (Graves 1986b). See Hybrids and
Dubious Taxa.
56. Cranioleuca baroni was considered
conspecific with C. antisiensis by Meyer de Schauensee (1966,
1970), following Koepcke (1961a); it had formerly (e.g., Cory & Hellmayr
1925, Peters 1951) been considered a separate species. Although most current
references (e.g., Ridgely & Tudor 1994) treat baroni as a species,
evidence for considering this species separate from C. antisiensis is
exceptionally weak; as noted by Koepcke (1961), the closest populations,
geographically, of antisiensis and baroni are more similar to one
another than they are to other subspecies within their respective
"species", and drawing a line between these two is arbitrary, even
though the extremes differ radically (Remsen 2003).
57. Certhiaxis is masculine, so the
correct spellings of the species names are cinnamomeus and mustelinus
(David & Gosselin 2002b).
58. Recent genetic data indicate that Certhiaxis
is closely related to and probably the sister taxon to Synallaxis + Schoeniophylax
(Irestedt et al. 2006, Moyle et al. 2009) and not close to Cranioleuca (merged with it by Vaurie 1980)
58a. Certhiaxis cinnamomea was called
"Yellow-throated Spinetail" in Meyer de Schauensee (1970), but see
Ridgely & Tudor (1994). SACC proposal to change
English name did not pass.
59. The genus Thripophaga is suspected
by several authors (e.g., Ridgely & Tudor 1994) of being a non-monophyletic
genus.
59a. SACC proposal to
hyphenate the English name to make it "Soft-tail" did not pass.
60. Vaurie (1980) considered Thripophaga
fusciceps and T. berlepschi to belong in Phacellodomus.
Check
61. Recent genetic data suggest that Asthenes
is a polyphyletic genus (Irestedt et al. 2006, Moyle et al. 2009).
61a. Asthenes heterura was
considered a subspecies of A. pudibunda by Meyer de Schauensee (1966,
1970) , but see Vaurie (1971a, 1980) for treatment as a separate species, as
was done previously by Cory & Hellmayr (1925) and Peters (1951); it is more
likely to be closer to A. ottonis (Vaurie 1971a, Fjelds & Krabbe
1990), which was considered a subspecies of A. pudibunda by Cory &
Hellmayr (1925). Called "Iquico Canastero" in Cory & Hellmayr
(1925) and Meyer de Schauensee (1966). Asthenes pudibunda, A. ottonis,
and A. heterura are considered to form a superspecies (Sibley &
Monroe 1990).
62. Asthenes cactorum was considered a
subspecies of A. modesta by REF; they form a superspecies (Sibley &
Monroe 1990).
63. Species limits in this group have been
fluid and confusing and have spanned virtually every permutation of
combinations of taxa. Cory & Hellmayr (1925) recognized three species, Asthenes
wyatti, A. punensis (including subspecies cuchacanchae and
lilloi), and A. anthoides, and considered A. sclateri to
be a synonym of A. hudsoni. Peters (1951) considered the punensis
subspecies group to be conspecific with A. wyatti, and elevated sclateri
to species rank, but considered it (by implication) not closely related to A.
wyatti. Meyer de Schauensee (1966, 1970) followed Peters (1951) except that
he considered the punensis group to be conspecific with A. anthoides
based on tail patterns. Fjelds & Krabbe (1990) and Sibley & Monroe
(1990) treated the four major groups as four species: Asthenes wyatti,
A. punensis, A. sclateri, and A. anthoides. Navas & Bo
(1982) followed Meyer de Schauensee (1966, 1970) except that they treated the punensis
group to be conspecific with A. sclateri rather than A. anthoides;
this treatment, the one used here, was followed by Ridgely & Tudor (1994)
and Remsen (2003). However, evidence for considering Asthenes wyatti as
separate species from A. sclateri is weak; they may intergrade in
Titicaca basin (Fjelds & Krabbe 1990), and the northern group of
subspecies differs more in plumage from southern group than the latter does
from adjacent A. sclateri subspecies (Ridgely & Tudor 1994). Asthenes
wyatti and A. sclateri form a superspecies, in which A. anthoides
is presumably also included (Olrog REF, Fjelds & Krabbe 1990, Sibley &
Monroe 1990); some authors (check Olrog REF) consider them all conspecific.
64. See Ridgely & Tudor (1994) for the
use of "Puna Canastero" for this species.
65. Asthenes virgata was considered a
subspecies of A. flammulata by Vuilleumier (1968), but see Vaurie
(1980); evidence for either treatment is weak. Meyer de Schauensee (1966)
suggested that A. maculicauda might be considered a subspecies of
A. flammulata. Asthenes flammulata, A. virgata, and A.
maculicauda form a superspecies (Sibley & Monroe 1990); Fjelds
& Krabbe (1990) suggested that all three could be considered conspecific.
66. Called "Lesser Canastero" in
Meyer de Schauensee (1970).
66a. Sibley & Monroe (1990) considered Asthenes
pyrrholeuca and A. baeri to form a superspecies, but no other
authors consider this likely.
67. Asthenes dorbignyi
presumably forms a superspecies with A. berlepschi, A. baeri,
and perhaps A. steinbachi, A. luizae, and A.
patagonica; except for their throat patches, they are closer to the
smaller Phacellodomus in several aspects of plumage, voice, and nest
structure than they are to other Asthenes; A. pyrrholeuca and A.
humicola may also belong in this group (Fjelds 1992, Whitney et al. [REF],
Remsen 2003). Asthenes steinbachi and A. baeri are close enough that A. b.
neiffi was initially described as a subspecies of A. steinbachi
(Navas and B 1987). Asthenes steinbachi has also been considered
conspecific with A. dorbignyi (e.g., Olrog 1963), but see Vaurie (1980)
and Ridgely & Tudor (1994).
68. The subspecies huancavelicae and arequipae
were considered separate species ("Pale-tailed Canastero" and "
Dark-winged Canastero") from Asthenes dorbignyi by Fjelds &
Krabbe (1990) and Ridgely & Tudor (1994). SACC proposal to
recognize huancavelicae and arequipae as separate species did not
pass because published data are incomplete and insufficient.
69. Asthenes berlepschi may best be
treated as a subspecies of A. dorbignyi (Sibley & Monroe 1990,
Fjelds & Krabbe 1990, Ridgely & Tudor 1994, Remsen 2003); it differs
less in plumage from A. dorbignyi than do taxa treated as
subspecies within A. dorbignyi do from one another.
70. Called "Chestnut Canastero" in
Meyer de Schauensee (1966, 1970).
71. Recently described: Vielliard (1990).
72. Ridgely & Greenfield (2001)
considered northern inornatus (with castilloi) a separate species
from Phacellodomus rufifrons, and this was followed by and Hilty (2003);
vocalizations are reported to differ, but no analysis or data have been
published. SACC proposal to
recognize inornatus as separate species did not pass because of
insufficient published data. Ridgely & Greenfield (2001) also
suggested that the subspecies peruvianus of the Maraon valley deserved
recognition as a separate species.
72a. Called "Common Thornbird" by
Ridgely & Tudor (1994).
72b. Sibley & Monroe (1990) considered Phacellodomus
rufifrons and P. sibilatrix to form a superspecies.
73. Phacellodomus maculipectus was
formerly (e.g., Peters, 1951, Meyer de Schauensee 1970) considered a subspecies
of P. striaticollis. Ridgely & Tudor (1994), based on Nores
and Yzurieta, considered the subspecies maculipectus to be a separate
species from striaticollis. SACC proposal passed to
recognize maculipectus as a separate species. They presumably constitute a superspecies.
74. Phacellodomus erythrophthalmus
(including ferrugineigula) was formerly (e.g., Cory & Hellmayr 1925,
Pinto 1937) placed in the monotypic genus Drioctistes,
but this was merged into Phacellodomus by Peters (1951). Given
distinctions in voice, plumage and nest architecture compared to other Phacellodomus,
it may merit such separation (Ridgely & Tudor 1994).
74a. The southern race ferrugineigula
has recently been shown to be a separate species from Phacellodomus
erythrophthalmus by the discovery of their sympatry (Simon et al. 2008). SACC proposal passed
to treat ferrugineigula as a
separate species. SACC proposal passed on
English names.
74b. Recent genetic data (Irestedt et al.
2006, Moyle et al. 2009) support the close relationship, presumably as sister
taxa, between Coryphistera and Anumbius.
75. Vaurie (1980) included Clibanornis in
Phacellodomus.
75a. The coloration of Metopothrix is
so unusual that it was long questioned whether it belonged it the Furnariidae
(e.g., Meyer de Schauensee 1966), but see Feduccia (1970), <>Traylor
(1972). Genetic data (Moyle et al.
2009) indicate that it is the sister genus to Xenerpestes. SACC proposal
needed to change linear sequence <Remsen working on one>.
75b. Metopothrix is feminine, so the
correct spelling of the species name is aurantiaca (David & Gosselin
2002b).
76. Recently described: Pacheco et al.
(1996).
76a. Whether Xenerpestes belongs in
the Furnariidae has been questioned (Peters 1951, Meyer de Schauensee 1966),
but see Vaurie (1971d). Genetic
data (Moyle et al. 2009) indicate that it is the sister genus to Metopothrix. SACC proposal needed to change
linear sequence <Remsen
working on one>.
76b. Xenerpestes minlosi and X.
singularis form a superspecies (Sibley & Monroe 1990).
76c. Called "Double-banded
Soft-tail" in Wetmore (1972).
77. Cory & Hellmayr (1925), Phelps &
Phelps (1950a), Peters (1951), and Vaurie (1980) treated tatei as a
subspecies of Premnoplex brunnescens, but Meyer de Schauensee
(1966, 1970) elevated it to species rank, as it was originally described; published
evidence for treatment as separate species is weak (Remsen 2003); they form
a superspecies (AOU 1983, 1998).
78a. Vaurie (1980) included Premnornis
and Premnoplex in Margarornis. Genetic data (Irestedt et al.
2006), however, indicate that Premnornis is not closely related to Premnoplex
+ Margarornis, but may be the sister taxon to Pseudocolaptes. Moyle et al. (2009) confirmed this but
found that Tarphonomus is the sister to Premnornis,
with Pseudocolaptes sister to that
pair. SACC proposal needed <Remsen working on one>.
78b. Vaurie (1980)
included Roraimia in Margarornis; see Rudge & Raikow (1992)
for maintaining it as a monotypic genus.
Genetic data (Moyle et al. 2009) indicate that it so not a member of the
ÒMargarornis groupÓ and that it is
sister to Thripophaga (T. fusciceps). SACC proposal needed to change
linear sequence <Remsen
working on one>.
79. Margarornis stellatus was called
"Star-chested Treerunner" by Ridgely & Tudor (1994) and Ridgely
& Greenfield (2001). Considered to form a superspecies with Middle American
M. rubiginosus by AOU (1983). SACC proposal to change
English name did not pass.
79a. Margarornis squamiger forms a
superspecies with M. bellulus of Darin, Panama (AOU 1998, Sibley &
Monroe 1990, Remsen 2003); reasons for maintaining bellulus as a
separate species are weak (Remsen 2003).
80. Pseudoseisura unirufa was formerly
(e.g., Cory & Hellmayr 1925, Pinto 1937, Peters,
1951, Meyer de Schauensee 1970, Ridgely & Tudor 1994) considered a
subspecies of P. cristata, but see Zimmer & Whittaker (2000)
for evidence for considering P. unirufa as a separate species; they form
a superspecies (Remsen 2003).
81. Pseudocolaptes lawrencii and P.
boissonneautii form a superspecies (AOU 1983, 1998, Sibley & Monroe
1990, Remsen 2003); they were formerly (e.g., Cory & Hellmayr 1925)
considered conspecific, but Peters (1951) and subsequent authors treated them
as separate species.
81a. The subspecies johnsoni may
deserve recognition as a separate species from Pseudocolaptes lawrencii
(Robbins and Ridgely 1990, Ridgely & Tudor 1994); see Zimmer (1936c) for
recognition of johnsoni as a distinct taxon and its presumed
relationship to P. lawrencii. SACC proposal to
recognize johnsoni as a separate species did not pass because published
data are insufficient.
81b. Formerly known as "Lawrence's
Tuftedcheek" (e.g., Wetmore 1972).
82. Moyle et al. (2009) found strong support
for the monophyly of a group that consists of the foliage-gleaner genera Anabacerthia, Syndactyla, Simoxenops,
Megaxenops, Anabazenops, Heliobletus, Philydor, Ancistrops, Thripadectes,
Hyloctistes, and Automolus (Cichlocolaptes not sampled).
82a. Vaurie (1980) included Anabacerthia in
Philydor; Hilty (2003) suspected that Anabacerthia
might even belong in narrowly defined Philydor. Genetic data (Moyle et al. 2009), however, indicate that they are not sister
genera.
82aa. Anabacerthia variegaticeps and A.
striaticollis have been considered conspecific (e.g., Cory & Hellmayr
1925, Peters 1951), but most authors have followed Wetmore (1972) in treating
them as separate species, based mainly on differences in plumage pattern; they
constitute a superspecies (AOU 1983, 1998, Remsen 2003).
82b. The species name formerly (e.g., Cory
& Hellmayr 1925) used for Anabacerthia striaticollis was montanus,
but striaticollis has priority (Peters 1951).
82c. Anabacerthia amaurotis was
considered more closely related to Philydor sensu stricto, especially P.
lichtensteini, than to the other two Anabacerthia species by
Vaurie (1980), and was treated in Philydor by Sibley & Monroe
(1990).
83. Ridgely & Greenfield (2001) suggested
that the subspecies temporalis of the Western Andes should be recognized
as a separate species from Anabacerthia variegaticeps, as it had been
previously treated by Peters (1951).
83a. Called "Spectacled
Foliage-gleaner" in <REF>, but see Remsen (1997a).
84. Vaurie (1980) included Syndactyla in
Philydor; the former name for the genus was Xenoctistes (e.g.,
Cory & Hellmayr 1925), but see Zimmer (1935).
85. Syndactyla guttulata and S.
subalaris constitute a superspecies (AOU 1983, Remsen 2003).
85a. Wetmore (1972) used
"Leaf-gleaner" as the English name for species in the genera Anabacerthia,
Syndactyla, Hyloctistes, Philydor, Automolus, and Thripadectes.
85aa. Formerly known as "Guttulated
Foliage-gleaner." There is no such word as "Guttulated", and the
proper adjectival form is "guttulate." SACC proposal passed
to change English name.
86. Syndactyla ruficollis was formerly
(e.g., Cory & Hellmayr 1925, Zimmer 1935, Peters 1951, Meyer de Schauensee
1970) placed in Automolus, but see Parker et al. (1985) and Ridgely
& Tudor (1994).
87. Vaurie (1980) included Simoxenops in
Philydor. Robbins & Zimmer (2005) recommended the merger of Simoxenops
and Syndactyla based on voice and morphology.
87a. Some authors (REFS) have considered Simoxenops
ucayalae and S. striatus to be conspecific; Sibley & Monroe
(1990) considered them to form a superspecies; substantial differences in bill
shape and habitat (Remsen 2003), however, make this unlikely.
87b. "Megaxenops ferrugineus,"
described from Madre de Dios, Peru, is a synonym of Simoxenops ucayalae
(Meyer de Schauensee 1966, Vaurie 1980). See Hybrids and
Dubious Taxa.
88. Vaurie (1980) included Ancistrops in
a broadly defined Philydor, but this is not consistent with genetic data
(Moyle et al. 2009).
89. Vaurie (1980) included Hyloctistes in
Philydor, but genetic data (Moyle et al. 2009) indicate that Hyloctistes is sister to Automolus. SACC proposal needed to change
linear sequence <Remsen
working on one>.
89a. Ridgely & Tudor (1994) suggested
that Trans-Andean populations (virgatus group) and Amazonian populations
might merit species rank based on vocal differences; Ridgely & Tudor (2001)
and Hilty (2003) treated them as separate species. SACC
proposal to
elevate virgatus to species rank did not pass because of insufficient
published data.
89b. Called "Striped Foliage-gleaner"
in REFS and Stiles & Skutch (1989).
90. Philydor is neuter, so the correct
spellings of the species names are ruficaudatum, fuscipenne, erythrocercum,
erythropterum, and rufum (David & Gosselin 2002b).
90a. The montane subspecies ochrogaster
is likely a separate species from Philydor erythrocercum, and were
treated that way by Sibley & Monroe (1990), but the contact with lowland
populations needs to be investigated in greater detail. See Zimmer (1935) for
rationale for treatment of ochrogaster as subspecies of P.
erythrocercum.
90aa. Zimmer (1935) considered Philydor
ruficaudatum to have no close relatives in the genus and that it shared
some characters with Anabacerthia.
90aaa. The subspecies erythronotum was
formerly (e.g., Cory & Hellmayr 1925) treated as separate species from Philydor
fuscipenne/P. erythrocercum, but see Zimmer (1935).
90b. Sibley & Monroe (1990) considered Philydor
pyrrhodes and "P." dimidiatum to form a superspecies, but
other authors consider this unlikely. In fact, Robbins & Zimmer (2005)
provided evidence that "Philydor" dimidiatum should be
transferred to the genus Syndactyla. SACC proposal passed
to transfer to Syndactyla. Pinto (1937) placed dimidiatum in
the genus Pseudoxenops Pinto, 1932.
90bb. The subspecies subfulvum was
formerly (e.g., Cory & Hellmayr 1925) treated as separate species from Philydor
erythrocercum, but see Zimmer (1935).
90c. Recently described: Teixeira &
Gonzaga (1983a).
90d. Philydor novaesi and P.
atricapillus are considered to form a superspecies (Teixeira & Gonzaga
1983a, Sibley & Monroe 1990).
91. Philydor fuscipenne was formerly
(e.g., Zimmer 1935, Peters 1951, Meyer de Schauensee 1970, Wetmore 1972, AOU
1983) considered conspecific with P. erythrocercum, but see Hilty
& Brown (1986) and Ridgely & Tudor (1994) for rationale for treating it
as a separate species, thus returning to the classification of Cory &
Hellmayr (1925).
92. Called "Planalto
Foliage-gleaner" in Ridgely & Tudor (1994). Proposal
needed.
92a. The subspecies baeri was formerly
(e.g., Cory & Hellmayr 1925, Pinto 1937, Peters
1951) considered a separate species from Philydor dimidiatum,; Meyer de
Schauensee (1966) considered them conspecific, and this has been followed by
subsequent authors. <incorp. Pinto & Camargo 1955>
92b. "Syndactyla mirandae,"
described from Gois and treated as a valid species by Peters (1951), is a
synonym of Syndactyla dimidiatus (Novaes 1953, Meyer de Schauensee 1966,
Vaurie 1980). See Hybrids and
Dubious Taxa.
92c. Anabazenops was included in Philydor
by Vaurie (1980), but this is not consistent with genetic data (Moyle et al.
2009).
93. Anabazenops dorsalis (e.g., Zimmer
1935, Peters 1951, Meyer de Schauensee 1970, Ridgely & Tudor 1994) was
formerly placed in Automolus, but see Kratter & Parker (1997) for
including dorsalis in Anabazenops.
93a. Called "Crested
Foliage-gleaner" in Meyer de Schauensee (1970) and Hilty & Brown
(1986), but see Ridgely & Tudor (1994). Called "Bamboo
Foliage-gleaner" in Ridgely & Greenfield (2001). SACC proposal to change
English name did not pass.
93b. Cichlocolaptes was included in Philydor
by Vaurie (1980).
94. Thripadectes flammulatus and T.
scrutator form a superspecies (Parker et al. 1985, Sibley & Monroe
1990, Remsen 2003); Fjelds & Krabbe (1990) suggested that they should be
considered conspecific.
95. Thripadectes scrutator was called
"Buff-throated Treehunter" in Meyer de Schauensee (1970) and
"Peruvian Treehunter" in Ridgely & Tudor (1994).
96. Zimmer (2002) provided evidence, mainly
vocal, that the taxon paraensis of southeastern Amazonia should be
ranked at the species level. SACC proposal passed to
recognize paraensis as separate species based on Zimmer (2002). They form a superspecies.
96a. Automolus infuscatus,
A. paraensis, A. lammi, and A.
leucophthalmus form a superspecies (Sibley & Monroe 1990, Zimmer 2002, Remsen
2003).
96b. Zimmer (2008) presented data on
vocalizations that suggest that the subspecies lammi should be ranked as
a separate species from Automolus leucophthalmus. SACC proposal passed
to recognize lammi as a species.
97. Automolus roraimae was listed as A.
albigularis by Peters (1951), but see Cory & Hellmayr (1925), Meyer de Schauensee (1966), and Vaurie (1980).
97a. "Philydor hylobius,"
formerly (e.g., Meyer de Schauensee 1970) treated as a valid species (and even
treated as a subspecies of Philydor atricapillus by Vaurie 1980),
represents the juvenal plumage of Automolus roraimae (Dickerman et al.
1986). See Hybrids
and Dubious Taxa.
97b. Called "Tepui Foliage-gleaner"
in Hilty (2003). SACC proposal to change
English name did not pass.
97c. Syndactyla
roraimae was formerly considered a member of the genus Automolus, but was considered by several authors unlikely
to be a member of that genus (Ridgely & Tudor 1994, Kratter & Parker
1997, Hilty 2003). Zimmer et al. (2008) used multiple lines of evidence to show
that it was not an Automolus,
but rather a Syndactyla. SACC proposal passed
to transfer to Syndactyla.
97d. Automolus rubiginosus likely
includes several species-level taxa (AOU 1998, Hilty 2003, Remsen 2003). The
subspecies nigricauda (with saturatus) was formerly (e.g., Cory
& Hellmayr 1925) considered a separate species, but they were treated as
conspecific by Peters (1951) and all subsequent authors. Krabbe (2008) provided evidence that
the subspecies rufipectus of the
Santa Marta Mountains merits species rank and pointed out its close resemblance to Hylocryptus erythrocephalus in voice and habitat. SACC proposal
passed to treat rufipectus as a
separate species.
98. Vaurie (1980) included Hylocryptus
in Automolus.
99. Cory & Hellmayr (1925) and Pinto (1937) included Hylocryptus rectirostris
in Automolus (while recognizing Hylocryptus as a monotypic genus
for erythrocephalus), but noted the possibility that rectirostris
was most closely related to H. erythrocephalus; see Zimmer (1936c) for
rationale for the transfer of rectirostris to Hylocryptus.
99a. Ridgely & Tudor (1994) called this
species "Henna-capped Foliage-gleaner." SACC
proposal to
change English name did not pass.
99b. Species in the genus Sclerurus
were formerly (e.g., Wetmore 1972) known as "Leaf-scrapers."
100. The relationships of Lochmias
within the family are controversial; general morphology has usually (e.g.,
Peters 1951, Meyer de Schauensee 1970, Wetmore 1972) led to its placement in
linear sequences near Sclerurus, but see Vaurie (1971a). Genetic data
(Irestedt et al. 2006, Moyle et al. 2009) indicate that Sclerurus and Lochmias
are in separate branches of the Furnariidae, with Lochmias clustering
with a group of genera that includes Furnarius, Cinclodes, Upucerthia,
Phleocryptes, and Limnornis.
100a. [potential Lochmias species
split]
100b. Called "Sharp-tailed Creeper"
in Wetmore (1972) and "Streamside Lochmias" in AOU (1983).
101. Vaurie (1980) included Heliobletus in
Xenops; plumage pattern of this species remarkably similar
to that of X. milleri. However, genetic data (Irestedt et al. 2006,
Moyle et al. 2009) indicate that Heliobletus and Xenops are in
separate branches of the Furnariidae, with Heliobletus clustering with Philydor. SACC proposal
badly needed to change linear sequence <Remsen working on one>.
102. Xenops milleri was formerly
(e.g., Cory & Hellmayr 1925, Pinto 1937, Phelps
& Phelps 1950a) placed in monotypic genus Microxenops; it lacks
wedge-shaped bill and complex tail pattern of congeners. Peters (1951) merged
it into Xenops, and this has been followed by subsequent authors. Genetic data (Moyle et al. 2009) indicate
that milleri is sister to Eremobius and Chilia (now included in Ochetorhynchus) and thus not
particularly close to Xenops. SACC proposal
badly needed to restore Microxenops
<Remsen working on one>.
102a. Some genetic data (Fjelds et al. 2005,
Irestedt et al. 2006) indicated that Xenops may be the sister taxon to
the dendrocolaptid woodcreepers, but this has been shown to be incorrect (Moyle
et al. 2009).
103. Foraging behavior suggests that Megaxenops
is not closely related to Xenops, and that bill shape similarity is due
to convergence (Remsen 2003). In fact, genetic data (Irestedt et al. 2006,
Moyle et al. 2009) indicate that Megaxenops and Xenops are in
separate branches of the Furnariidae, with Megaxenops clustering with Syndactyla
and Anabacerthia. SACC proposal badly needed to change linear sequence <Remsen working on one>.
104. Traditional linear sequences place Pygarrhichas
at the end, near Xenops, but this placement is almost certainly due to
convergence on climbing behavior -- otherwise, nothing supports this
relationship, which seems highly unlikely biogeographically (Remsen 2003).
Genetic data (Fjelds et al. 2005, Irestedt et al. 2006, Moyle et al. 2009)
indicate that Pygarrhichas and Xenops are in separate branches of
the Furnariidae. Irestedt et al. (2006)
found that it clustered with Margarornis
and Premnoplex, but more
thorough analyses indicate that it is sister to a group that includes ÒXenopsÓ
milleri and Ochetorhynchus (Moyle et al. 2009). SACC proposal
badly needed to modify linear sequence <Remsen working on one>.
Moyle et al. (2009) proposed that these genera be recognized as a
subfamily, Pygarrhichinae.
105. Although the monophyly of the former
Dendrocolaptidae seems reasonably well established (Feduccia 1973, Raikow 1994,
Clench 1995, Sibley & Ahlquist 1990, Marantz et al. 2003), whether it is
embedded within the Furnariidae (as proposed by Feduccia 1973) or sister to all
Furnariidae (Clench 1995, Sibley & Ahlquist 1990) has been controversial.
Genetic data (Irestedt et al. 2002, 2006, Chesser 2004, Fjelds et al. 2005.
Moyle et al. 2009) data strongly support the former, with the genera Geositta
and Sclerurus basal to all other ovenbirds plus woodcreepers. Some
authors had previously treated the Dendrocolaptidae as a subfamily of the
Furnariidae (e.g., REFS <check Mayr & Amadon, 1951,
AMNov1496.> <incorp. Irestedt et al. 2004>. If family or
subfamily ranks are retained within this group, then a third group, Geositta
plus Sclerurus, must also be accorded taxonomic rank. SACC proposal passed
to merge Dendrocolaptidae and Furnariidae into single family without subfamily
rankings. <relationships among genera in
dendrocolaptids; incorp. Aleixo 2002, Irestedt et al. 2006>. Moyle et al. (2009)
found that (a) the woodcreepers consisted of two divergent branches, with Dendrocincla, Deconychura, and Sittasomus
sister to all other genera; (b) within the latter, Glyphorynchus was sister to the remaining genera; (c) the remaining
genera consisted of two major groups, with one consisting of Xiphorhynchus [Dendroplex picus] +(Campylorhamphus
+(Drymornis + Lepidocolaptes)), and the other (Nasica + Dendrexetastes)
+ (Dendrocolaptes + (Hylexetastes + Xiphocolaptes)).
Additional taxon-sampling is needed before changes to linear sequence
are implemented.
105a. "Dendrocincla macrorhyncha,"
known from two specimens from Ecuador, is considered to represent aberrant
individuals of D. tyrannina (Meyer de Schauensee 1966, Fjelds
& Krabbe 1986, Marantz et al. 2003). See Hybrids and
Dubious Taxa.
106. Cory & Hellmayr (1925) treated the
subspecies turdina and atrirostris each as separate species from Dendrocincla
fuliginosa; Pinto (1937) treated turdina
as a separate species but not atrirostris; Peters (1951) and Meyer de
Schauensee (1970) considered them all conspecific. Sibley & Monroe (1990),
Ridgely & Tudor (1994), and Marantz et al. (2003) treated turdina as
a separate species ("Plain-winged Woodcreeper") based largely on
Willis (1983); proposal badly needed. <check
Todd (1948) for treatment of meruloides as species, formerly placed in merula;
Marantz et al. 2003>
107. Called "Brown Woodcreeper" in
Wetmore (1972).
108. Marantz et al. (2003) noted that
differences in voice and iris color between nominate merula (with obidensis)
and the rest of the subspecies suggested that more than one species might be
involved; see also Hilty (2003).
109. The subspecies typica was formerly
(e.g., Cory & Hellmayr 1925) treated (with minor) as a separate
species from Deconychura longicauda. Marantz et al. (2003) indicated
that vocal differences among populations suggest that more than one species
might be involved, with the typica group possibly more closely related
to D. stictolaema than to Amazonian longicauda group.
110. The subspecies secunda was
formerly (e.g., Cory & Hellmayr 1925) treated as a separate species from Deconychura
stictolaema.
111. Sittasomus griseicapillus almost
certainly consists of multiple species (Hardy et al. 1991, Ridgely & Tudor
1994, Parker et al. 1995, Ridgely & Greenfield 2001, Hilty 2003), with at
least five subspecies groups possibly deserving separate species status
(Marantz et al. 2003).
112. Marantz et al. (2003) noted that vocal
differences among populations of Glyphorynchus spirurus suggest that
more than one species might be involved.
113. Genetic data (Irestedt et al. 2004)
suggest that Glyphorynchus is the basal taxon in the family. Proposal needed to change linear sequence. <wait
until Aleixo Evolution paper published.>
114. Glyphorynchus is regularly
misspelled as "Glyphorhynchus."
115. Drymornis bridgesii differs from
all other woodcreepers in syringeal structure (Ames 1971), mallophagans (Kudon 1982),
and foraging behavior (semiterrestrial), and Raikow (1994) suggested that it
and Nasica might be the outgroup taxa to all other Dendrocolaptidae.
Genetic data (Irestedt et al. 2004), however, indicate that the traditional
placement of Drymornis with a group of genera that includes Nasica,
Hylexetastes, Hylexetastes, Xiphocolaptes, and Dendrocolaptes
(Aleixo 2002) is correct; its sister genus is
likely Campylorhamphus. <incorp.
Moyle et al. 2009>
116. Raikow (1994) proposed that Dendrexetastes
is closely related to Campylorhamphus, contrary to their traditional
placements in linear sequences, but this is not corroborated by genetic data
(Irestedt et al. 2004, Moyle et al. 2009).
117. The subspecies devillei was
considered a separate species from Dendrexetastes rufigula by REF, but
their voices are similar (Marantz et al. 2003).
118. The two species of Hylexetastes
form a superspecies (Sibley & Monroe 1990); Marantz et al.
(2003) suggest that vocal similarities and intermediate plumage of subspecies insignis
suggests that they could be considered conspecific, as suspected by Zimmer
(1934c). The subspecies uniformis was treated as a species
separate from H. perrotii by Ridgely & Tudor (1994). Silva
(1995) found no evidence for hybridization among various Hylexetastes
taxa in areas where potentially parapatric and thus ranked all four taxa,
including newly described brigidai (Silva et al. 1995), as species.
Marantz et al. (2003), however, noted that voices of perrotii, uniformis,
and brigidai are all quite similar. Proposal
badly needed.
119. Sibley & Monroe (1990) considered X.
promeropirhynchus and X. albicollis to form a superspecies; X.
falcirostris should perhaps be included (?REF).
120. The orenocensis subspecies group
was formerly (e.g., Cory & Hellmayr 1925, AOU 1983) treated as a separate
species from Xiphocolaptes promeropirhynchus, and Ridgely &
Tudor (1994) suggested that this would be found to be the correct treatment.
The emigrans subspecies group of Middle America was also formerly (e.g.,
Ridgway 1911) considered a separate species. Zimmer (1934c), however, was
unable to find a clear demarcation in plumage between the two groups, and
Marantz et al. (2003) noted that voices were remarkably similar among these
forms, given their pronounced plumage differences; clearly, a thorough analysis
is required. Proposal needed?
121. The taxon franciscanus was
formerly (e.g., Pinto 1937, Peters 1951, Meyer
de Schauensee 1970) treated as a separate species ("Snethlage's
Woodcreeper"); here it is treated as subspecies of X. falcirostris,
following Teixeira et al. (1989), Teixeira (1990), and Silva and Oren (1997);
see also Ridgely & Tudor (1994) and Marantz et al. (2003). Pinto (1952)
suggested that franciscanus was a subspecies of X. albicollis.
122. Here villanovae treated as
subspecies of Xiphocolaptes albicollis, following Marantz et al. (2003),
but it may warrant species rank (Pinto & Camargo 1961); villanovae
is not a subspecies of X. falcirostris, where placed by Cory &
Hellmayr (1925) and Clements (2000).
123. Dendrocolaptes sanctithomae was
formerly (e.g., Peters 1951, Meyer de Schauensee 1970) considered conspecific
with D. certhia, but Willis (1992) and Marantz (1997) provided
evidence that they should be treated as separate species; they constitute a superspecies.
124. Marantz et al. (2003) noted that the
southeastern subspecies punctipectus might also deserve treatment as a
separate species from Dendrocolaptes sanctithomae.
125. The taxon concolor was formerly
(e.g., Todd 1948, Peters 1951, Meyer de Schauensee 1970) treated as a separate
species ("Concolor Woodcreeper"); here it is treated as
subspecies of D. certhia, following Cory & Hellmayr (1925),
Pinto (1937), Willis & Oniki (1978), Willis (1992), Marantz (1997), and
Marantz et al. (2003). <incorp. Ridgely & Tudor 1994>
126. The relationships of Dendrocolaptes
picumnus, D. hoffmannsi, and D. platyrostris are
controversial. Pinto (1937) treated D.
hoffmannsi as a subspecies of D. picumnus, but subsequently (Pinto
1978) considered D. hoffmannsi to be a subspecies of D.
pallescens, a taxon usually treated as a subspecies of D. picumnus
(e.g., Pinto 1937, Peters 1951, Meyer de
Schauensee 1966, 1970). Willis (1982) suggested that D. hoffmannsi and D.
platyrostris were perhaps best treated as conspecific with D. picumnus (followed
by AOU 1983). The three species presumably form a superspecies (Marantz et al.
2003); Sibley & Monroe (1990) considered D.
picumnus and D. platyrostris to form a superspecies but did not
include D. hoffmannsi. Raikow (1994) and Marantz (1997) proposed
that D. hoffmannsi was closer to D. sanctithomae/D. certhia
than to D. picumnus/D. platyrostris, but vocal characters and
biogeography suggest that this is not correct (Marantz et al. 2003).
127. The subspecies pallescens and transfasciatus
were formerly (e.g., Cory & Hellmayr 1925) each considered separate species
from Dendrocolaptes picumnus, but they were considered conspecific by
Peters (1951).
128 Xiphorhynchus picus and X. kienerii (= necopinus)
were formerly (e.g., Cory & Hellmayr 1925, Zimmer 1934c, Pinto 1937, Phelps & Phelps 1950a) treated in a separate genus, Dendroplex, but this was
merged into Xiphorhynchus by Peters (1951).
Wetmore (1972), however, maintained Dendroplex as a separate genus based
not only on bill shape but also on (unstated) cranial characters. Aleixo et al.
(2007) summarized rationale for validity of Dendroplex and for its usage
for these two species. SACC proposal passed
to resurrect Dendroplex for these two species.
129. The northern picirostris subspecies group was formerly (e.g.,
Cory & Hellmayr 1925) treated as a separate species from Xiphorhynchus
picus, but they were considered conspecific by Peters (1951).
130. Aleixo &
Whitney (2002) showed that kienerii is a synonym of, and has priority
over, necopinus. SACC proposal passed to
change name from X. necopinus to X. kienerii.
131. Xiphorhynchus fuscus was formerly
(e.g., Pinto 1937, Peters 1951, Meyer de
Schauensee 1970, Ridgely & Tudor 1994) considered to be a member of the
genus Lepidocolaptes, but genetic and morphological data clearly place
it within Xiphorhynchus (Raikow 1994, Garca-Moreno & Silva 1998,
Aleixo 2002, Irestedt et al. 2004).
132. The subspecies chunchotambo
of the Andean foothills was formerly (e.g., Cory & Hellmayr 1925) treated as a separate species from Xiphorhynchus
ocellatus, but they were considered conspecific by Peters (1951). Aleixo (2002) found that Xiphorhynchus ocellatus is
paraphyletic with respect to X. pardalotus, and suggested that X.
chunchotambo of the foothills of the Andes be recognized as a separate
species from lowland X. ocellatus; this was followed by Marantz et al.
(2003), who treated chunchotambo (with napensis and brevirostris)
as a separate species ("Tschudi's Woodcreeper"). <incorp.
Aleixo 2004> Proposal badly needed.
133. Zimmer (1934d), Pinto
(1937), Ridgely & Tudor (1994), and Ridgely & Greenfield (2001)
considered Xiphorhynchus elegans and X. spixii
conspecific, but see Haffer (1997) for rationale for treating them as separate
species, as in Peters (1951) and Meyer de Schauensee (1970). Aleixo (2002) also
found molecular support for treating nominate spixii as a separate species
from all other taxa in the group; they constitute a superspecies. Cory &
Hellmayr (1925) treated the subspecies juruanus and insignis as
separate species from X. spixii, and Pinto (1947) also maintained juruanus
as a separate species; but they were considered conspecific by Zimmer (1934d)
and Peters (1951). <incorp. Aleixo 2004>
134. Genetic data (Aleixo 2002)
indicate that Xiphorhynchus pardalotus, sometimes
considered a member of the X. spixii superspecies, and X.
ocellatus are sister species, as proposed by Zimmer (1934d); Aleixo (2002)
found that pardalotus is embedded within taxa currently treated under X.
ocellatus; see Note 21), and this should be reflected in linear
sequence: Proposal badly needed.
135. The relationships among taxa included in
Xiphorhynchus susurrans and X. guttatus are complex and need much
additional work. Xiphorhynchus susurrans was formerly (e.g., Zimmer
1934d, Phelps & Phelps 1950a, Peters 1951, Meyer de Schauensee 1970)
considered conspecific with X. guttatus, but Willis (1983)
provided evidence that it should be treated as a separate species; this
treatment was followed by Ridgely & Tudor (1994) and AOU (1998); they
constitute a superspecies. Xiphorhynchus susurrans had previously been
treated as a species by Cory & Hellmayr (1925), who also treated the
subspecies polystictus (= sororius) as a separate species; this
was considered conspecific with X. guttatus by Zimmer (1934d) and Peters
(1951). However, Aleixo (2002) found that treating X. susurrans at the
species level makes Xiphorhynchus guttatus paraphyletic with respect to
Amazonian guttatoides group of western and southwestern Amazonia (guttatoides,
dorbignyianus, eytoni, and vicinalis) and eastern
Amazonian guttatus group (guttatus, polystictus, and
provisionally, connectens). Marantz et al. (2003) also emphasized that
the current assignment of subspecies to either X. susurrans or X.
guttatus does not correspond to the boundaries in vocalizations.
Furthermore, the eytoni subspecies group was formerly (e.g., Todd 1948,
Meyer de Schauensee 1966, 1970) considered a separate species
("Dusky-billed Woodcreeper") from X. guttatus; here it
is treated as subspecies of guttatus following Cory & Hellmayr
(1925), Zimmer (1934d), Pinto (1937), Peters
(1951), and Ridgely & Tudor (1994), but Marantz et al. (2003) noted that
this group differed in vocalizations from other taxa included in X. guttatus.
Proposal needed? <to
lump all into broad guttatus until relationships worked out>
136. Xiphorhynchus erythropygius
and X. triangularis were formerly (e.g., Cory & Hellmayr
1925) considered conspecific; they were treated as separate species by Peters
(1951). Wetmore (1972) summarized the strong plumage differences between the
two and noted sympatry in depto. Antioquia, Colombia; see also Marantz et al.
(2003) for synopsis of evidence for considering them as separate species; they
form a superspecies (AOU 1983, Fjelds & Krabbe 1990, Sibley & Monroe
1990).
137. Lepidocolaptes lacrymiger was
formerly (e.g., Peters 1951, Meyer de Schauensee 1970, AOU 1983, 1998, Sibley
& Monroe 1990) considered conspecific with Middle American L. affinis (Spot-crowned
Woodcreeper), but recent treatments (e.g., Ridgely & Tudor 1994,
Hilty 2003) usually follow Cory & Hellmayr (1925), Zimmer (1934c), and
Phelps & Phelps (1950a) in treating them as separate species. Their
vocalizations differ strongly, although a formal analysis has not been
published; they constitute a superspecies.
138. Lepidocolaptes falcinellus was
formerly (e.g., Pinto 1937, Peters 1951,
Meyer de Schauensee 1970, Sibley & Monroe 1990, Ridgely & Tudor 1994)
considered a subspecies of L. squamatus, but Silva & Straube
(1996) provided evidence for why it should be treated as a species, and this
was followed by Marantz et al. (2003).
139. The Amazonian fuscicapillus
subspecies group (with madeirae and layardi) was formerly (e.g.,
Cory & Hellmayr 1925) treated as a separate species from Lepidocolaptes
albolineatus, but recent authors have followed Zimmer (1934c) in treating
them as conspecific; Hilty (2003) suspected that this treatment will be
shown to be correct.
140. Campylorhamphus trochilirostris
and C. falcularius form a superspecies (Sibley & Monroe 1990); they
were considered conspecific by Pinto (1937) and Peters
(1951).
141. The multostriatus subspecies
group was formerly (e.g., Cory & Hellmayr 1925) considered a separate
species from Campylorhamphus procurvoides, but they were treated as
conspecific by Zimmer (1934b) and Peters (1951); however, Marantz et al. (2003)
noted that multostriatus group is closer vocally to C. trochilirostris
than to nominate procurvoides group.
142. The borealis subspecies group of
Central America was considered a separate species from Campylorhamphus
pusillus by Ridgway (1911).
Part 7. Suboscine Passeriformes, B (Thamnophilidae to Rhinocryptidae) (click)