Passerea

Passerea is a proposed clade of neoavian birds, representing one of the two primary lineages within the diverse group Neoaves, which encompasses over 90% of extant bird species. Introduced through whole-genome analyses of 48 representative species, it was defined as the sister group to Columbea and named after its most speciose component, the Passeriformes (songbirds).^[1] The clade includes three main subgroups: core landbirds (Telluraves), which comprise perching birds like passerines, parrots, woodpeckers, and raptors such as falcons; core waterbirds (Aequornithia), encompassing diving and wading species including penguins, loons, petrels, herons, and pelicans; and Phaethontimorphae, featuring tropicbirds and the sunbittern.^[1] This configuration suggested that the common ancestor of Passerea was likely a terrestrial predator, with vocal learning evolving independently in multiple lineages, and it accounted for nearly all modern birds, highlighting the rapid post-Cretaceous-Paleogene diversification of Neoaves around 66 million years ago.^[1] Subsequent phylogenomic studies have challenged the monophyly of Passerea, attributing early Neoaves branching patterns to high levels of incomplete lineage sorting and rapid radiations that complicate resolution. For example, a targeted next-generation sequencing approach across 198 species and 259 nuclear loci recovered neither Passerea nor Columbea as monophyletic, instead identifying a series of successive sister clades such as nightjars and allies, cuckoos with pigeons, cranes, waterbirds, and landbirds (with hoatzin basal to the latter).^[2] More recent family-level genomic analyses using coalescent-based methods on 363 species further fragmented the proposed structure, resolving Neoaves into four major clades—Mirandornithes (flamingos and grebes), Columbaves (pigeons and relatives), Telluraves (core landbirds), and Elementaves (aequornithians with nightjars, hoatzin, and shorebirds)—without support for Passerea as a unified group.^[3] These findings underscore ongoing debates in avian systematics, where methodological differences in data types (e.g., coding vs. non-coding regions) influence deep-level relationships, yet consistently affirm the explosive evolutionary history of birds following the end-Cretaceous extinction.^[2]^[3]

Taxonomy

Etymology

The name Passerea derives from the Latin word passer, meaning "sparrow," which forms the root of Passeriformes, the order of perching birds (passerines) that constitutes the clade's most speciose group and exemplifies its dominant terrestrial lineages.^[1] This taxonomic term was formally proposed by Jarvis et al. in 2014 as part of their genome-scale phylogenetic analysis of modern birds, designating Passerea as one of two reciprocally monophyletic sister clades diverging early within Neoaves, the other being Columbea.^[1] The authors explicitly named it after Passeriformes to underscore the clade's inclusion of diverse landbirds allied with songbirds and vocal-learning taxa.^[1] By evoking the sparrow-like perching adaptations central to Passeriformes, the name emphasizes Passerea's focus on primarily terrestrial and arboreal birds, distinguishing it from Columbea, whose nomenclature highlights more aquatic and ground-dwelling forms like columbiforms.^[1]

Classification history

Prior to 2014, classifications of Neoaves often informally grouped birds into landbirds and waterbirds based on ecological and morphological similarities, but these assemblages were frequently polyphyletic and lacked formal cladistic definitions. For instance, DNA-DNA hybridization studies proposed a landbird clade encompassing diverse orders like raptors, woodpeckers, and passerines, while morphological analyses reinforced similar divisions without resolving deeper relationships.^[4] Mitochondrial genome data sometimes failed to support landbird monophyly, highlighting inconsistencies in pre-genomic era taxonomies.^[4] The clade Passerea was first formally proposed in 2014 through a genome-scale phylogenetic analysis of 48 bird species representing all Neoaves orders, marking the initial recognition of a monophyletic group uniting core landbirds (Telluraves) with elements of waterbirds (Aequornithia). This study, utilizing coalescent-based methods on thousands of genes, identified Passerea as one of two primary Neoaves lineages alongside Columbea, with strong bootstrap support for its monophyly. The name Passerea reflects the dominance of Passeriformes, the largest avian order, within the clade.^[5] Following the 2014 proposal, refinements and debates emerged regarding Passerea's exact boundaries and monophyly, particularly from a 2015 study analyzing targeted next-generation sequencing data from 198 bird species. This work challenged Passerea's monophyly, instead supporting a broad landbird assemblage termed Inopinaves that excluded certain waterbird elements included in the original definition, while affirming similar core groupings of raptors, parrots, and songbirds. Subsequent genomic analyses have shown mixed results, with some reinforcing Passerea-like structures in Neoaves divergences—such as a 2024 study attributing support to a region of suppressed recombination—though more comprehensive genome-wide analyses, including Stiller et al. (2024) resolving Neoaves into four major clades (Mirandornithes, Columbaves, Telluraves, and Elementaves) without Passerea, and a 2025 morphological study of the quadrate explicitly rejecting its monophyly, indicate ongoing challenges. It has not been universally integrated into major taxonomic lists like those of the IOC World Bird List, which favor alternative higher-level arrangements based on Prum et al. (2015). These debates underscore ongoing efforts to reconcile genome-scale data with denser taxon sampling for stable avian classification.^[6]^[7]^[3]^[8]

Phylogeny

Proposal and molecular evidence

The classification of Neoaves, the largest clade of modern birds, had long been hampered by unresolved deep phylogenetic branches, often attributed to incomplete lineage sorting and convergent evolution.^[1] In 2014, a landmark study by Jarvis et al. analyzed whole-genome sequences from 48 bird species, representing all orders of Neoaves, to resolve these early divergences. The researchers compiled a dataset comprising 8,251 protein-coding genes (approximately 41.8 million base pairs), including exons, introns, and 3,769 ultraconserved elements, drawn from nuclear genomes. To address challenges such as low phylogenetic signal in individual loci, they employed genome-scale phylogenomic methods, including maximum likelihood concatenation via ExaML and multispecies coalescent modeling with MP-EST*, supplemented by a statistical binning technique to group loci with similar phylogenetic signals and mitigate noise from incomplete lineage sorting.^[1] The analysis recovered a highly supported topology revealing the first major divergence within extant Neoaves into two reciprocally monophyletic sister clades: Passerea and Columbea. Passerea emerged as the larger basal Neoavian clade, positioned sister to Columbea, with 100% bootstrap support for this bipartition. According to the study, Passerea initially encompassed approximately 5,000 species, predominantly terrestrial neoavians such as core landbirds including passerines.^[1]

Support from subsequent studies

Subsequent phylogenomic studies have provided varying degrees of support for the Passerea clade proposed by Jarvis et al. in 2014, often refining its internal structure while addressing early uncertainties in neoavian relationships, though methodological differences continue to influence outcomes. Prum et al. analyzed over 390 nuclear loci from 198 bird species using targeted next-generation sequencing, yielding partial support for a Passerea-like grouping of perching birds, parrots, and related lineages, although the clade was not recovered as strictly monophyletic due to alternative arrangements among core landbirds and waterbirds.^[6] Subsequent reanalyses of non-coding portions from this dataset have strengthened evidence for Passerea's monophyly by mitigating biases in coding regions.^[9] Kuhl et al. analyzed 3'-untranslated region (3'-UTR) sequences from 233 bird species representing nearly 90% of avian families, resolving 91% of interfamily relationships with high bootstrap support; however, this study did not recover Passerea as monophyletic, instead supporting alternative neoavian groupings.^[10] Phylogenomic investigations from 2021 to 2024 have shown mixed results for Passerea, with support in some datasets emphasizing non-coding sequences or coalescent models but challenges in others due to incomplete lineage sorting during the Cretaceous-Paleogene radiation. For instance, combined analyses incorporating retroelement insertions have identified diagnostic synapomorphies supporting Passerea's monophyly, with emergent congruence to the Jarvis arrangement in total-evidence frameworks that integrate thousands of gene trees and over 2,000 insertions.^[11] A 2024 family-level genomic analysis of 363 species by Stiller et al., using coalescent-based methods, did not recover Passerea or Columbea as monophyletic; instead, it resolved Neoaves into four major clades—Mirandornithes (flamingos and grebes), Columbaves (pigeons and relatives), Telluraves (core landbirds), and Elementaves (aequornithians with nightjars, hoatzin, and shorebirds)—attributing discrepancies to a recombination-suppressed region on chromosome 4 that misleadingly supports the Jarvis topology.^[3] These findings highlight ongoing debates in avian systematics, where data types (e.g., coding vs. non-coding regions) and genomic regions influence deep-level relationships.^[7] Areas of debate persist regarding minor boundary adjustments within Passerea-like groupings, such as the precise placement of Strisores (encompassing nightjars and swifts), which some whole-genome studies position near the base of the clade while others suggest closer affinity to core landbirds based on specific recombination-suppressed regions.^[7]

Cladogram and relationships

Passerea forms one of the two primary clades within Neoaves as proposed in 2014, positioned as the sister group to Columbea, with this basal split supported at 100% bootstrap in the original genomic analyses. The clade is monophyletic in that topology, encompassing the majority of landbird lineages, and originated through a divergence approximately 66 million years ago, shortly after the Cretaceous-Paleogene (K-Pg) extinction event. A cladogram based on the Jarvis et al. (2014) whole-genome phylogenomics places Passerea as follows within Neoaves:

Neoaves

Recent phylogenomic syntheses show conflicts in relationships, including variable placement of Strisores and overall support for Passerea.^[12] One 2024 analysis using intergenic loci proposes an alternative Neoaves structure with Elementaves incorporating Strisores and diverging from the Passerea-Columbea dichotomy, rendering Passerea paraphyletic, while upholding the Telluraves split into Afroaves and Australaves.^[3]

Composition

Major subclades

Passerea was proposed to comprise three primary subclades reflecting its early diversification following the Cretaceous–Paleogene extinction event: core landbirds (Telluraves), core waterbirds (Aequornithia), and Phaethontimorphae.^[1] These divisions were supported by the original genome-scale phylogenetic analyses of Jarvis et al. (2015), which resolved Passerea as a monophyletic group within Neoaves, though subsequent studies have challenged this monophyly.^[1] Telluraves forms the core landbird assemblage within the proposed Passerea, comprising predominantly diurnal, perching species adapted to terrestrial and arboreal habitats.^[1] It is subdivided into two main branches: Australaves, which includes raptorial and perching forms like seriemas (Cariamiformes), falcons (Falconiformes), parrots (Psittaciformes), and passerines (Passeriformes); and Afroaves, encompassing diverse lineages such as owls (Strigiformes), woodpeckers (Piciformes), and mousebirds (Coliiformes).^[1] The divergence of Telluraves from the other Passerea lineages was estimated at approximately 55 Ma in the 2015 analysis.^[1] Aequornithia represents the core waterbird subclade, encompassing diving and wading species such as penguins (Sphenisciformes), loons (Gaviiformes), petrels and albatrosses (Procellariiformes), herons and egrets (Ardeidae within Pelecaniformes), pelicans (Pelecanidae), and cormorants (Phalacrocoracidae within Suliformes).^[1] This group is characterized by adaptations for aquatic lifestyles, with its separation from landbirds highlighting parallel radiations in marine and freshwater environments post-extinction. Phaethontimorphae is the smallest subclade, featuring tropicbirds (Phaethontiformes) as sister to the sunbittern (Eurypygiformes).^[1] These aerial and coastal specialists diverged early within Passerea, with molecular evidence placing their split around 60-70 Ma.^[1]

Included orders and families

The proposed Passerea encompasses approximately 5,000–6,000 species across more than 20 orders, accounting for roughly half of all extant bird species (as of 2023 estimates).^[1] This diversity is dominated by the order Passeriformes, which includes over 6,000 species in about 140 families. The clade focuses on landbird and waterbird lineages, excluding those in the sister clade Columbea such as Columbiformes (pigeons) and Cuculiformes (cuckoos). The major orders and selected key families are outlined below, organized by representative subclades. These groupings reflect the molecular phylogenetic evidence from the 2015 proposal supporting Passerea's composition.^[1]

Order	Approximate Species Count	Key Families (Examples)	Subclade
Passeriformes	6,000+	Tyrannidae (tyrant flycatchers), Fringillidae (finches), Corvidae (crows and jays)	Telluraves
Psittaciformes	400	Psittacidae (true parrots), Cacatuidae (cockatoos)	Telluraves
Piciformes	450	Picidae (woodpeckers), Ramphastidae (toucans)	Telluraves
Strigiformes	250	Strigidae (true owls), Tytonidae (barn owls)	Telluraves
Accipitriformes	260	Accipitridae (hawks, eagles, Old World vultures)	Telluraves
Falconiformes	70	Falconidae (falcons and caracaras)	Telluraves
Coraciiformes	120	Coraciidae (rollers), Alcedinidae (kingfishers)	Telluraves
Bucerotiformes	70	Bucerotidae (hornbills)	Telluraves
Trogoniformes	45	Trogonidae (trogons and quetzals)	Telluraves
Coliiformes	6	Coliidae (mousebirds)	Telluraves
Cariamiformes	7	Cariamidae (seriemas)	Telluraves
Procellariiformes	130	Procellariidae (petrels), Diomedeidae (albatrosses)	Aequornithia
Pelecaniformes	75	Ardeidae (herons, egrets), Pelecanidae (pelicans)	Aequornithia
Suliformes	200	Phalacrocoracidae (cormorants), Sulidae (gannets, boobies)	Aequornithia
Sphenisciformes	20	Spheniscidae (penguins)	Aequornithia
Gaviiformes	5	Gaviidae (loons)	Aequornithia
Phaethontiformes	3	Phaethontidae (tropicbirds)	Phaethontimorphae
Eurypygiformes	1	Eurypygidae (sunbittern)	Phaethontimorphae

These orders represent the core proposed composition of Passerea, with Passeriformes and waterbird orders exemplifying the clade's adaptive radiation among perching, terrestrial, and aquatic birds.^[1]

Characteristics

Shared morphological traits

Passerea, as proposed, encompasses a diverse array of bird lineages within Neoaves, many of which—particularly in core landbirds (Telluraves)—share morphological traits adapted to perching, climbing, and diverse feeding strategies. A key feature in Telluraves is the anisodactyl foot structure, consisting of four toes with three directed forward (digits II, III, IV) and one backward (hallux), which provides strong grasping ability for perching on branches and terrestrial locomotion.^[13] Vocalization capabilities are enhanced in numerous Passerea lineages through modifications to the syrinx, the avian vocal organ located at the base of the trachea. In passerines, the dominant group within Passerea, the syrinx features complex intrinsic musculature—up to six pairs of syringeal muscles in oscines—enabling precise control over sound production for learned songs and calls, though this complexity is less pronounced in other subclades like suboscines. These modifications support diverse acoustic repertoires but are not universal across all proposed Passerea members, with vocal learning evolving independently in lineages such as songbirds and parrots. Cranial kinesis, the flexibility of the avian skull allowing independent movement of the upper jaw relative to the braincase, is prominent in many neoavian birds including those in Passerea and facilitates a broad spectrum of feeding behaviors, from probing for insects to cracking fruits. This kinetic mechanism, powered by specialized ligaments and muscles, enhances manipulative dexterity in the rostrum, enabling dietary versatility observed in groups ranging from insectivorous flycatchers to frugivorous parrots. Wing and foot adaptations within Passerea show variation suited to specific lifestyles, with zygodactyl or semi-zygodactyl configurations—two toes forward and two backward—common in subclades such as parrots (Psittaciformes) and woodpeckers (Piciformes), aiding in vertical climbing along tree trunks and precise object manipulation.^[14] These traits, while not uniform across the proposed clade, highlight convergent evolutionary solutions to arboreal challenges among its diverse orders. Given ongoing debates about Passerea's monophyly, some shared traits may reflect broader neoavian ancestry or convergence rather than unique synapomorphies.

Evolutionary adaptations

The evolutionary adaptations of the proposed Passerea are closely tied to the rapid radiation of Neoaves following the Cretaceous-Paleogene (K-Pg) mass extinction approximately 66 million years ago. In the original proposal, the common ancestor of Passerea was inferred as an apex predator, with subsequent lineage-specific losses and gains of traits enabling diversification into diverse ecological niches, including terrestrial, arboreal, and aquatic habitats.^[1] This ancestral predatory morphology facilitated early survival in post-extinction ecosystems, where reduced competition allowed for the evolution of specialized forms within subclades like Telluraves (landbirds) and Aequornithia (waterbirds).^[15] Key adaptations across Neoaves, including components of Passerea, involve shifts in life-history traits, particularly a reduction in adult body mass and increased altriciality (helplessness at hatching), which are linked to molecular evolutionary changes near the K-Pg boundary. These shifts, detected through Ornstein-Uhlenbeck models on phylogenetic trees, suggest a "Lilliput effect" where smaller body sizes became optimal, enhancing reproductive rates and evasion of predators in fragmented habitats.^[16] In Aequornithia, convergent ecological traits such as foot-propelled diving and wading-feeding mechanisms evolved independently.^[1] Within Telluraves, a prominent adaptation is the independent evolution of vocal learning in multiple lineages, including passerines (songbirds) and parrots, supported by accelerated evolution in 227 genes associated with neural circuits for sound production and learning.^[15] These genomic changes, often in non-coding regions, enabled complex communication and social behaviors, contributing to the clade's high species diversity—over 6,000 species in Passeriformes alone. Overall, adaptations in Passerea components highlight a burst of genomic heterogeneity post-K-Pg across Neoaves, with 15 of 17 detected molecular rate shifts occurring in exons and influencing base composition, thereby facilitating rapid morphological and ecological divergence.^[16]