Abstract
The mitochondrial genomes of six Phylloscopus species—small insectivores belonging to the Phylloscopidae family—were obtained using the Illumina sequencing platform. The mitogenomes were closed circular molecules 16,922–17,007 bp in size, containing 13 protein-coding genes, 22 tRNA genes, two rRNA genes, and two control regions (CR1 and remnant CR2). The gene orders were conserved in 35 sampled Phylloscopus mitogenomes in the GenBank database, with a gene rearrangement of cytb-trnT-CR1-trnP-nad6-trnE-remnant CR2-trnF-rrnS. The average base compositions of the six Phylloscopus mitogenomes were 29.43% A, 32.75% C, 14.68% G, and 23.10% T, with the A+T content slightly higher than that of G+C. ATG and TAA were the most frequent initiating and terminating codons, respectively. Several conserved boxes were identified in CR1, including C-string in domain I; F, E, D, and C boxes, as well as bird similarity and B boxes, in domain II; and CSB1 in domain III. Tandem repeats were observed in remnant CR2 of the Phylloscopus fuscatus and Phylloscopus proregulus mitogenomes. A phylogenetic analysis with maximum likelihood (ML) and Bayesian inference (BI) methods, based on 13 protein-coding genes and two rRNA genes, indicated that the Phylloscopus species was divided into two larger clades, with a splitting time approximately 11.06 million years ago (mya). The taxa of Phylloscopus coronatus/Phylloscopus burkii and Phylloscopus inornatus/P. proregulus were located at the basal position of the different clades. The phylogenetic result of the cox1 gene showed that Seicercus was nested within Phylloscopus. The complete set of mitogenomes of the Phylloscopus species provides potentially useful resources for the further exploration of the taxonomic status and phylogenetic history of Phylloscopidae.
Keywords: Phylloscopus, Mitogenome, Genome organization, Phylogeny, Divergence
Introduction
Leaf warblers (Phylloscopus) belong to the family Phylloscopidae of the order Passeriformes (Gill, Donsker & Rasmussen, 2022). These small insectivorous songbirds have a wide distribution in the Old World (Sun, Liu & Lu, 2020). Leaf warblers have the highest number in Asia (Alström et al., 2018), with the greatest diversity in the eastern Himalayas and southern China (Price, 2010). There are currently 81 recognized species in the genus Phylloscopus (Gill, Donsker & Rasmussen, 2022). Leaf warblers had been classified into two genera (Phylloscopus and Seicercus) (Clement, Alström & Madge, 2006); however, several phylogenetic studies have shown that traditional Seicercus is nested within Phylloscopus, and is also separated into two non-sister clades. Based on the phylogeny of mitochondrial and nuclear datasets, Alström et al. (2018) supported the synonymizing of Seicercus with Phylloscopus, leading to the synonymization of Seicercus and a monogeneric Phylloscopidae. The phylogenetic relationship and divergences of Phylloscopus have also been examined using multiple molecular markers such as mitochondrial genomes (mitogenomes) (Yu et al., 2022), mitochondrial genes combined with nuclear segments (Alström et al., 2018), and genome-wide data (Zhang et al., 2021). Other research has also been carried out on leaf warblers, in relation to topics such as their biogeographic history (Johansson et al., 2007), bioacoustic differentiation (Calviño Cancela, Piña & Martín-Herrero, 2022), and migratory behavior (Adams et al., 2022).
Several molecular markers, including mitogenomes, nuclear segments, ultra-conserved element (UCE) sequences, and genomic data, have been remodeled to study avian evolution (Hosner, Braun & Kimball, 2016; Mackiewicz et al., 2019; Oliveros et al., 2019; Qu et al., 2021; Zhang et al., 2021). Among them, mitochondrial DNA (mtDNA) has demonstrated maternal inheritance and haploidy, commonly containing 13 protein-coding genes (PCGs), two rRNA genes (rRNAs), 22 tRNA genes (tRNAs), and one non-coding region (control region (CR)) in the majority of birds. Mitogenome sequences have been widely used for evolution, phylogeny, population, and phylogeography studies of the genome characteristics of different bird orders such as Galliformes (Li, Huang & Lei, 2015), Charadriiformes (Hu et al., 2017), and Passeriformes (Mackiewicz et al., 2019), and have been effective markers for the exploration of evolutionary positions. By sampling ∼300 representatives of Passeriformes mitogenomes, Mackiewicz et al. (2019) analyzed four types of gene rearrangements, including a duplicated CR with adjacent genes, indicating that the duplication was the ancestral state and was maintained in early diverged lineages. Several complete mitogenomes of Phylloscopus are available in the GenBank database, such as those for Phylloscopus tenellipes (Sun, Liu & Lu, 2020; Yu et al., 2022) and Phylloscopus proregulus (Jiao et al., 2018), whose data have been used for the analysis of phylogenetic relationships of this genus and even the whole Passeriformes order.
In this study, the complete mitogenomes of six Phylloscopus species were sequenced using the Illumina sequencing platform. Based on these data, and by obtaining other Phylloscopus complete mitogenome sequence data from GenBank, we attempted to elucidate (a) the features and structures of the mitogenomes of six Phylloscopus species, and (b) the taxonomic status of the phylogenetic relationships and divergence times of the Phylloscopus species. The newly generated complete mitogenomes may be useful resources for further in-depth studies of the phylogenetic relationships of Phylloscopus, as well as Phylloscopidae.
Materials and Methods
Sample collection, DNA extraction, and sequencing
Samples of six Phylloscopus species (Phylloscopus burkii, Phylloscopus reguloides, Phylloscopus borealis, P. proregulus, Phylloscopus trochiloides, and Phylloscopus fuscatus) were naturally deceased adults (Table S1, Fig. S1). Muscle tissue was collected, preserved in 100% ethanol, and stored at −20 °C in the Shaanxi Institute of Zoology, Xi’an, China. Genomic DNA was extracted using a DNeasy kit, and the library reconstruction followed the methodology of previous studies (Yang et al., 2021; Yang et al., 2022). The mitogenomes were sequenced using the Illumina HiSeq2000 and Xten platforms, with a paired-end read of 150 bp.
Genome assembly and annotation
Mitogenome assembly was performed using MITOBim version 1.8 (Hahn, Bachmann & Chevreux, 2013) and MitoZ version 2.4 (Meng et al., 2019). Geneious version 11.1.3 was utilized for mitogenome sequence annotation (Kearse et al., 2012), with closely related species serving as references for comparison with the assembled results. Most tRNAs were identified using tRNAscan-SE version 1.21 (Lowe & Eddy, 1997), and the remaining tRNAs, rRNAs, and CRs were identified by comparison with other closely related species. The secondary structures of the tRNAs of P. fuscatus were referred to from the results of tRNAscan-SE version 1.21 (Lowe & Eddy, 1997) and other avian mitogenomes (Yang et al., 2021; Yang et al., 2022). The conserved elements in CR1 of P. fuscatus were analyzed by referencing previous studies (Yang et al., 2022).
Characteristic analysis
The circular structures of the mitogenomes were plotted using the CGView Server (Grant & Stothard, 2008). The genome size and nucleotide composition were calculated using Geneious version 11.1.3 (Kearse et al., 2012), with the nucleotide bias calculated using the following formulas: AT-skew = (A −T)/(A+T) and GC-skew = (G −C)/(G+C) (Perna & Kocher, 1995). The relative synonymous codon usage (RSCU) and p-distance were evaluated using MEGA version 11 (Tamura, Stecher & Kumar, 2021). Tandem repeat sequences in the CRs were analyzed using the Tandem Repeats Finder version 20.10.2022 (Benson, 1999).
Dataset construction, phylogeny, and divergence
On the basis of previous taxonomic relationships (Mackiewicz et al., 2019), 41 Phylloscopus individuals representing 19 species and one outgroup taxon (Aegithalos concinnus concinnus) mitogenome were downloaded from GenBank to construct the phylogenetic dataset (Table S2). The phylogenetic topologies were reconstructed using the two methods of maximum likelihood (ML) and Bayesian inference (BI) based on the combined 13 PCGs and 2 RNAs, with 14,005 bp after the alignment.
Each PCG was first aligned with amino acids using MUSCLE in MEGA version 11 (Tamura, Stecher & Kumar, 2021) and then transferred into nucleotide sequences. Two RNAs were also aligned using MUSCLE. The concatenated datasets were generated using SequenceMatrix version 1.7.8 (Vaidya, Lohman & Meier, 2011). The best-fit model (GTR+I+G) was used to reconstruct the phylogenetic trees. The ML tree was created using IQ-TREE version 2.2.0 (Nguyen et al., 2015), with 5000 bootstrap replicates. The BI tree was analyzed using MrBayes version 3.1.2 (Ronquist & Huelsenbeck, 2003), with parameter settings of 2 independent runs with four simultaneous Markov chains for 2,000,000 generations and sampling every 100 generations. The first 25% of the generations was discarded as burn-in. The effective sample size (ESS) values were estimated using Tracer version 1.5 (Rambaut, Suchard & Drummond, 2004) with an ESS >200.
To further explore the phylogenetic relationships of leaf warblers, the mitochondrial cox1 gene with a larger sampling size of 127 individuals belonging to 37 Phylloscopus species was analyzed using A. concinnus concinnus as the outgroup (Table S2). DNA sequences were aligned using MUSCLE, and Gblocks was employed to extract the conserved sites, which were used to construct the phylogenetic tree. The ML tree was reconstructed using IQ-TREE version 2.2.0 (Nguyen et al., 2015), with 5,000 bootstrap replicates.
The divergence time was estimated based on the cytb gene of the sampled Phylloscopus species. The Bayesian procedure was implemented using BEAST version 1.10.4 (Drummond & Rambaut, 2007). The calibration points were selected from the two major clades of the Phylloscopus species 11.7 million years ago (mya) (Alström et al., 2018) and 1.97 mya for Phylloscopus canariensis and Phylloscopus collybita using the TimeTree website (http://www.timetree.org/). The parameters were defined as the GTR+I+G substitution model, uncorrelated relaxed clock, lognormal relaxed distribution, and Yule prior in the analyses. The results of the runs executing 10,000,000 generations were used, with the first 25% discarded as burn-in values.
Results
Mitogenome structure and organization
The whole mitogenomes of six Phylloscopus species were sequenced (GenBank accession no. MG681101, OR030349 –OR030353); three Phylloscopus species (P. fuscatus, P. reguloides, and P. trochiloides) were the first new records for these species in the GenBank database. The three Phylloscopus species (P. burkii, P. borealis, P. proregulus) have been available in the GenBank database, with corresponding accession numbers of KX977449 in P. burkii, NC_045526 in P. borealis, and NC_037189 in P. proregulus, respectively (Table S2). Several contents, such as the length, nucleotide composition, and initiation and termination codon, were slightly different between sampled three species and that of the GenBank database. For example, the length of P. borealis was 16,898 bp in the sampled species, while 16,881 bp in the database, with corresponding nucleotide composition of 28.8% A and 33.4% C in this study, while 28.9% A and 33.3% C in the NC_037189. The initiation and termination codon of nad3 (ATG and TAA) in P. burkii were different with that of KX977449 (GTG and TAG).
The total length of the mitogenomes ranged from 16,922 bp (P. fuscatus) to 17,007 bp (P. reguloides), similar to those of the other 35 Phylloscopus mitogenomes in the GenBank database (16,875–16,979 bp; Table S2). The length variation in the mitogenomes was probably due to the variable length of the control region, which was consistent with previous avian mitogenomic studies (Kundu et al., 2022). The mitogenomes contained 37 genes, comprising 13 PCGs, 22 tRNAs, and two rRNAs, as well as two non-coding control regions (CR1 and remnant CR2) (Fig. 1). Among them, nine genes (nad6 and eight tRNAs) were identified on the N strand; the remaining 28 genes were identified on the J strand (Fig. 1). The gene order of the six Phylloscopus mitogenomes was identical, and similar to that identified in other birds, such as P. proregulus (Jiao et al., 2018) and Alaudala cheleensis (Yang et al., 2021). The base composition of the mitogenomes was C>A>T>G in the whole mitogenome (Fig. 2A), with average values of 29.43% A, 32.75% C, 14.68% G, and 23.10% T. The A+T content (ranging from 52.3% to 53.1%) was slightly higher than that of G+C, which is typical for avian mitogenomes.
Figure 1. The mitogenome organization of Phylloscopus.
Figure 2. The base composition of mitogenomes in six Phylloscopus species.
(A) The whole mitogenome, (B) PCGs, (C) rrnS, (D) rrnL.
Protein-coding gene
The base composition of the PCGs (removing the termination codons) was C>A>T>G (Fig. 2B), with varied trends similar to those of whole mitogenomes. For different codon positions, the base composition C>A>G>T was observed in the first codons(Fig. S2A), T>C>A>G was observed in the second codons (Fig. S2B), and C>A>T>G was observed in the third codons (Fig. S2C).
All PCGs of the six Phylloscopus species were initiated with an ATG start codon (Fig. S3A). Eight PCGs (nad1, cox2, atp8, atp6, nad3, nad4L, cytb, and nad6) had TAA or TAG as their termination codon, whereas AGG was the termination codon of cox1 and cox3, AGA was the termination codon of nad5, GAA was the termination codon of nad3, incomplete TA was the termination codon of nad2, and T was the termination codon of nad4 (Fig. S3B). The initiation codon of ATG and the termination codon of TAA are widely present in avian mitogenomic PCGs (Morinha et al., 2016; Hu et al., 2017; Yang et al., 2022). The incomplete T of nad4 has also been observed in several avian PCGs such as Pyrrhocorax pyrrhocorax and Pyrrhocorax graculus (Morinha et al., 2016). The plausible explanation for incomplete codons is the post-transcriptional polyadenylation process, which adds 3′ A residues to the mRNA, generating a TAA stop codon (Ojala, Montoya & Attardi, 1981).
The RSCU values of the PCGs were similar in the six Phylloscopus species, with L2 having the highest value and L1 having the lowest value (Fig. S4). The whole RSCU content was similar to other avian mitogenomes (Yang et al., 2021). Codons ending with A and C were more frequent than those ending with U and G, as noted in previously reported research (Yang et al., 2021). CUA(L2), CGA(R), UCC(S2), and GCC(A) were the most frequently used codons (Fig. S4).
RNA gene
All six Phylloscopus mitogenomes contained rrnS and rrnL of rRNA, and were located between trnF and trnL (UUR) and separated by trnV (Fig. 1). The total length of rrnS ranged from 974 bp (P. fuscatus) to 988 bp (P. borealis), and rrnL from 1,598 bp (P. fuscatus) to 1,602 bp (P. burkii and P. borealis). The base composition varied trend was A>C>G>T in rrnS (Fig. 2C), and the A+T content ranged from 48.5% (P. borealis) to 50.9% (P. reguloides). The base composition varied trend was A>C>T>G in rrnL (Fig. 2D), and the A+T content ranged from 56.2% (P. trochiloides) to 55.3% (P. borealis).
The length of the tRNA genes of the six Phylloscopus mitogenomes ranged from 66 bp (trnS (AGY)) to 75 bp (trnL (UUR)). In total, 21 tRNAs were folded into a classical clover-leaf secondary structure in the P. fuscatus mitogenome (Fig. S5). trnS (AGY) lacked the dihydrouridine (DHU) arm, which is a common feature of avian mitogenomes in Passeriformes (Gao, Huang & Lei, 2013), Galliformes (Li, Huang & Lei, 2015), Charadriiformes (Hu et al., 2017), Piciformes (Bi et al., 2019), and Accipitriformes (Jiang et al., 2019). There were several pair mismatches in the stems; G-U was the most abundant type. Other patterns were observed, such as A-C in the amino acid accepter (AA) arm of trnF, C-C in the AA arm of trnV, and U-C in the anticodon (AC) arm of trnG (Fig. S5), which could be corrected by an RNA-editing process (Lavrov, Brown & Boore, 2000). When comparing all six Phylloscopus species, the loop sequences varied more often than those of the stems. Several stem sequences were completely conserved, such as the stems in trnL (UUR), trnI, trnQ, trnM, and trnS (UCN) (Fig. S6). The highest conserved site of the four arms of tRNA was the DHU arm, whereas the lowest was the AC arm (Fig. S6).
Control region
The nucleotide composition of CR1 was C>T>A>G (Fig. S7A); that of remnant CR2 was C>A>T>G (Fig. S7B). The A+T contents of CR1 and remnant CR2 were slightly higher than in G+C, which is similar to that of A. cheleensis (Yang et al., 2021). The base skew results show that CR1 had a slight T-skew and an obvious C-skew (Fig. S7C). Remnant CR2 contained a medium A-skew and an obvious C-skew (Fig. S7D). The base composition and skew were similar to other Sylvioidea species (Yang et al., 2021).
Tandem repeats have previously been identified in avian mitogenomic CRs (Ritchie & Lambert, 2000; Mundy & Helbig, 2004; Cho et al., 2009; Omote et al., 2013; Yang et al., 2021; Kundu et al., 2022). Unique tandem repeat sequences were identified in both Fregata minor and F. magnificens, which could be used as species-specific markers (Kundu et al., 2022). For the tandem repeat sequences in the CRs of the six Phylloscopus mitogenomes, a consensus size of 46 bp (CATTTCATTAAACTCGCAAAGCCTACCAAACAACCGCATTCACACC) was observed in remnant CR2 of P. fuscatus, with a copy number of 2.0. A consensus size of 45 bp (AACCAAACCTATCCCAAACCCCCCTCCCACTAAAAAACAAACAAA) was identified in remnant CR2 of P. proregulus, with a copy number of 2.3.
P. fuscatus CR1 could be divided into three domains, including ETAS (extended termination-associated sequence) domain I (nt 1–424), central conserved domain II (nt 425–859), and CSB (conserved sequence block) domain III (nt 860–1,104). This is similar to other avian mitogenomic CRs (Bi et al., 2019; Yang et al., 2021). Conserved box sequences have previously been identified in avian CRs (Randi & Lucchini, 1998; Li, Huang & Lei, 2015; Aleix-Mata et al., 2019). Several motifs have also been observed in P. fuscatus CR1, including C-string (CCCCCCCCCTCCCCCCCC) in domain I; F (GCGCTTCTCACGAGAACCGAGCTACTCAAT), E (GTTATTGGCGTCAGGGA CAT), D (CCTCCCGTGGTAACTTCAGGACCAT), C (CTGCCCTTCACTGATACTAGTGGTC GGTT), bird similarity (CACTGATGCACTTTG), and B (TCCCATTCATGGAC) boxes in domain II; and CSB1 (TATATAATGCAATGGTCACCGGACATG) in domain III. Sequences of the bird similarity box were completely conserved in CR1 of the six Phylloscopus species. Motifs of CSB2, CSB3, the origin of heavy-strand replication (O H), and light- and heavy-strand transcription promoters (LSP/HSP) were not identified in P. fuscatus CR1, which was similar to other birds (Gao, Huang & Lei, 2013).
Phylogenetic and divergence analysis
The phylogenetic trees (ML and BI) revealed identical topologies that were supported by bootstrap values (BSs) in the ML tree (Fig. 3A) and posterior probabilities (PPs) in the BI tree at most nodes (Fig. 3B). The relationships of the genus Phylloscopus strongly supported a division into two major clades, including eight species contained in clade I (Phylloscopus coronatus, P. burkii, P. reguloides, P. trochiloides, Phylloscopus borealoides, Phylloscopus tenellipes, P. borealis, and Phylloscopus examinandus) and eleven species in clade II (Phylloscopus inornatus, P. proregulus, Phylloscopus sibilatrix, Phylloscopus occisinensis, Phylloscopus schwarzi, P. fuscatus, Phylloscopus trochilus, Phylloscopus ibericus, Phylloscopus sindianus, Phylloscopus collybita, and Phylloscopus canariensis) (Fig. 3). Compared with a previous study, the taxa included in clade I corresponded with clade α of the phylogenetic tree, based on one mitochondrial gene (cytb) and three nuclear segments (ODC, myoglobin, and GAPDH), whereas the taxa in clade II were consistent with clade β (Alström et al., 2018).
Figure 3. Phylogenetic trees reconstructed using PCG combining with RNA datasets.
(A) MI, (B) BI, the newly sequenced mitogenome sequences labelled with bold format.
For clade I, P. borealis and P. examinandus, P. borealoides and P. tenellipes, and P. coronatus and P. burkii formed sister groups, with relatively higher BSs and PPs (Fig. 3). P. burkii traditionally belonged to the genus Seicercus; this species formed a strongly supported sister group with P. coronatus (BS = 98; PP = 1.0), which indicated that P. burkii was nested within Phylloscopus. The clade of P. coronatus/P. burkii was located at the basal position of clade I (BS = 100 and PP = 1.00). For clade II, P. collybita and P. canariensis, P. occisinensis and P. schwarzi, and P. inornatus and P. proregulus formed sister groups; these also contained higher BSs and PPs in the phylogenetic trees. The clade of P. inornatus/P. proregulus was at the basal position of clade II (BS = 100 and PP = 1.00).
A further phylogenetic tree based on the cox1 gene also showed that two major cldaes contained in Phylloscopus, and the species traditionally classified within genus Seicercus was nested within that of Phylloscopus (Fig. S8). The clade containing Phylloscopus castaniceps and Phylloscopus grammiceps, which used to belong to the Seicercus genus, was grouped with the Phylloscopus species (BS = 100).
The lowest p-distance value based on the PCG dataset was found between P. borealis and P. examinandus (0.0338), while the highest value was identified between P. trochiloides and P. collybita (0.1483) (Table S3). The relatively lower genetic distance between P. borealis and P. examinandus, and between P. tenellipes and P. borealoides (0.0353) showed closely phylogenetic relationship (Table S3), which consistent with the result of phylogenetic tree based on the PCG+RNA dataset with sister groups, respectively (Fig. 3). In addition, the lowest p-distance value based on cox1 gene was identified between Phylloscopus cebuensis and P. borealis (0.00360), while the highest value was found between P. ibericus and Phylloscopus ijimae (0.16109) (Table S4). The relatively lower genetic distance between P. cebuensis and P. borealis, and between Phylloscopus valentini and P. burkii (0.01583) showed closely phylogenetic relationship (Table S4), which consistent with the result of phylogenetic tree based on cox1 gene with sister groups, respectively (Fig. S8).
The divergence time results were similar to those in previous studies (Fig. S9) (Alström et al., 2018). The two clades split at 11.06 mya during the Tortonian stage of the Miocene, with a 95% HPD of 7.53–14.77 mya. This is similar to other results based on mitochondrial genes and nuclear segments (Päckert et al., 2012; Alström et al., 2018). The divergence times of the clade containing P. canariensis, P. collybita, P. sindianus, P. ibericus, and P. trochilus in clade II were analyzed. The divergence time between P. canariensis and P. collybita was 1.75 mya; between P. sindianus and P. canariensis/P. collybit it was 1.94 mya; between P. ibericus and P. canariensis/P. collybit/P. sindianus it was 2.29 mya; and between P. trochilus and P. canariensis/P. collybita/P. sindianus/P. ibericus it was 5.59 mya. These results are similar to those of Alström et al. (2018).
The divergence times between the sister species ranged from 1.41 mya to 5.91 mya. In clade I, P. borealis and P. examinandus split at 1.64 mya, P. borealoides and P. tenellipes split at 1.41 mya, and P. coronatus and P. reguloides split at 5.91. In clade II, P. collybita and P. canariensis split at 1.75 mya, P. occisinensis and P. schwarzi split at 6.32 mya, and P. inornatus and P. proregulus split at 5.88 mya (Fig. S9). Among them, the sister groups between P. borealis and P. examinandus, P. borealoides and P. tenellipes, and P. collybita and P. canariensis represented relatively young Phylloscopus pairs, whereas those between P. coronatus and P. reguloides, between P. occisinensis and P. schwarzi, and between P. inornatus and P. proregulus were the old sister pairs.
Discussion
Gene rearrangements
We observed that a gene rearrangement of cytb-trnT-CR1-trnP-nad6-trnE-remnant CR2-trnF-rrnS existed in the six Phylloscopus mitogenomes, which was different from the typical cytb-trnT-trnP-nad6-trnE-CR-trnF-rrnS of the avian gene order (Urantówka et al., 2018; Mackiewicz et al., 2019) (e.g., Gallus gallus). Such gene rearrangements of the Phylloscopus species have also been observed in other birds (Mackiewicz et al., 2019; Urantówka, Kroczak & Mackiewicz, 2020; Yang et al., 2021). Avian mitogenomic gene rearrangements, which include several gene orders, have been identified in previous studies (Bensch & Härlid, 2000; Zhou et al., 2014; Eberhard & Wright, 2016; Caparroz et al., 2018; Kang et al., 2018; Urantówka, Kroczak & Mackiewicz, 2020; Yang et al., 2021; Kundu et al., 2022), such as for Psittaciformes and Passeriformes (Urantówka, Kroczak & Mackiewicz, 2020). This could be explained by the tandem duplication–random loss (TDRL) model; the tandem duplication of cytb-trnT-trnP-nad6-trnE-CR was consistent with previous studies (Yang et al., 2021). Mitochondrial gene rearrangement provides useful information, such as elucidating the evolution of avian groups and their evolutionary relationships (Kundu et al., 2022).
Two major clades and hierarchical nested structure
In clade I, the closer relationship of the sister group between P. borealoides and P. tenellipes (BS = 100; PP = 1.00) was consistent with previous studies based on mitochondrial genes and nuclear segments (Johansson et al., 2007; Alström et al., 2018; Sun, Liu & Lu, 2020; Yu et al., 2022). The sister group between P. borealis and P. examinandus (BS = 100; PP = 1.00) agreed with previous studies (Alström et al., 2018). Within clade II, a closer relationship between P. inornatus and P. proregulus (BS = 100; PP = 1.00) was observed, consistent with previous analyses utilizing concatenated mitochondrial gene datasets (Jiao et al., 2018; Yu et al., 2022). Furthermore, the genus Seicercus was nested within Phylloscopus (Fig. S8), which was consistent with previous studies (Alström et al., 2018).
Divergence times
For Passeriformes birds, based on data for 4,060 nuclear loci and 137 families, Oliveros et al. (2019) observed that passerines originated on the Australian landmass (∼47 mya); the subsequent dispersal and diversification were affected by several climatological and geological events. For the Phylloscopus species, divergences have been analyzed in previous studies using a combination of mitochondrial genes and nuclear segments (Moyle & Marks, 2006; Price, 2010; Alström et al., 2018). According to previous studies, the diversification of leaf warblers took place ∼11–12 mya (Johansson et al., 2007). The main two clades (α and β) of Phylloscopus split approximately 11.7 mya (95% highest posterior density (HPD) = 9.8–13.7 mya) on the basis of the cytb gene. Phylloscopus emeiensis, Phylloscopus neglectus, and Phylloscopus tytleri are the oldest single-species lineages (7.3–8.3 mya) (Alström et al., 2018).
The divergence times between the sister species of Phylloscopus ranged from 0.5 mya to 6.1 mya, with the three youngest Phylloscopus pairs of sister species splitting at 0.5 mya, 0.8 mya, and 1.1 mya, respectively, and the three oldest strongly supported sister pairs splitting at 4.1 mya, 4.1 mya, and 6.1 mya, respectively (Alström et al., 2018). The differences may have been due to the sampling strategies and the lack of available whole mitogenome sequences of several Phylloscopus species, which resulted in a greater number of Phylloscopus mitogenomes being required to infer their separation events.
Conclusions
We revisited the mitogenome features of six Phylloscopus species (P. burkii, P. reguloides, P. borealis, P. proregulus, P. trochiloides, and P. fuscatus), and investigated the evolutionary characteristics of the gene order with a gene rearrangement of cytb-trnT-CR1-trnP-nad6-trnE-remnant CR2-trnF-rrnS. As well as the phylogeny in combination with other available Phylloscopus mitogenomes to analyze the evolution of Phylloscopus, the result indicated that the Phylloscopus species was divided into two larger clades, with a splitting time approximately 11.06 million years ago (mya). The phylogenetic result of the cox1 gene showed that Seicercus was nested within Phylloscopus. Divergence times analyses investigated the differences of infer their separation events between young and old Phylloscopus sister pairs may have been due to the sampling strategies and the lack of available whole mitogenome sequences of several Phylloscopus species.
Supplemental Information
Note: (A): P. borealis, (B): P. trochiloides, (C): P. proregulus, (D): P. fuscatus. Photos of P. burki and P. reguloides were not obtained.
Note: (A): the first codons, (B): the second codons, (C): the third codons.
Note: (A): initiation codon, (B): termination codon.
Note: (A), (C): CR1, (B), (D): remnant CR2.
Note: the newly sequenced mitochondrial sequences labelled with bold format.
Note: (A): mitogenome sequences, (B): cox1 gene.
Acknowledgments
We would like to special thanks to Fumin Lei of the Chinese Academy of Sciences for some sampling collection.
Funding Statement
This work was supported by the National Natural Science Foundation of China (Grant No. 31601846), the China Scholarship Council (202106875010), the Fundamental Research Funds for the Central Universities, China (Grant No. GK202304021), the China Postdoctoral Science Foundation (Grant No. 2016M602760), and the Western Young Scholars Projects of Chinese Academy of Sciences (Grant No. XAB2021YW01). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Additional Information and Declarations
Competing Interests
The authors declare there are no competing interests.
Author Contributions
Chao Yang conceived and designed the experiments, analyzed the data, prepared figures and/or tables, authored or reviewed drafts of the article, and approved the final draft.
Xiaomei Dong performed the experiments, analyzed the data, prepared figures and/or tables, and approved the final draft.
Qingxiong Wang performed the experiments, prepared figures and/or tables, and approved the final draft.
Xiang Hou performed the experiments, prepared figures and/or tables, and approved the final draft.
Hao Yuan analyzed the data, authored or reviewed drafts of the article, and approved the final draft.
Xuejuan Li conceived and designed the experiments, analyzed the data, authored or reviewed drafts of the article, and approved the final draft.
Ethics
The following information was supplied relating to ethical approvals (i.e., approving body and any reference numbers):
We have adhered to all local, national, and international regulations and conventions, and we respect normal scientific ethical practices. The specimens used in this study collected from adult individuals that died naturally during field investigation, and have carried out harmless treatment. The animal experiment program of this project has been reviewed by animal Ethics Committee of Shaanxi Institute of Zoology (Xi’an, China), and conforms to animal protection, animal welfare and ethical principles, as well as relevant regulations of national ethical welfare of experimental animals.
Data Availability
New Species Registration
The following information was supplied regarding the registration of a newly described species:
The Phylloscopus species was divided into two larger clades, with a splitting time approximately 11.06 million years ago (mya). The taxa of P. coronatus/P. burkii and P. inornatus/P. proregulus were located at the basal position of the different clades. The phylogenetic result of the cox1 gene showed that Seicercus was nested within Phylloscopus.
References
- Adams et al. (2022).Adams EM, Stenhouse IJ, Gilbert AT, Boelsma J, Gress G, Weidensaul CS, Grigsby C, Williams EJ, Phillips L, McIntyre CL. The first documentation of the Nearctic-Paleotropical migratory route of the Arctic Warbler. Ecology and Evolution. 2022;12(9):e9223. doi: 10.1002/ece3.9223. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Aleix-Mata et al. (2019).Aleix-Mata G, Ruiz-Ruano FJ, Pérez JM, Sarasa M, Sánchez A. Complete mitochondrial genome of the Western Capercaillie Tetrao urogallus (Phasianidae, Tetraoninae) Zootaxa. 2019;4550(4):585–593. doi: 10.11646/zootaxa.4550.4.9. [DOI] [PubMed] [Google Scholar]
- Alström et al. (2018).Alström P, Rheindt FE, Zhang RY, Zhao M, Wang J, Zhu XJ, Gwee CY, Hao Y, Ohlson J, Jia CX, Prawiradilaga DM, Ericson PGP, Lei FM, Olsson U. Complete species-level phylogeny of the leaf warbler (Aves: Phylloscopidae) radiation. Molecular Phylogenetics and Evolution. 2018;126:141–152. doi: 10.1016/j.ympev.2018.03.031. [DOI] [PubMed] [Google Scholar]
- Bensch & Härlid (2000).Bensch S, Härlid A. Mitochondrial genomic rearrangements in songbirds. Molecular Biology and Evolution. 2000;17(1):107–113. doi: 10.1093/oxfordjournals.molbev.a026223. [DOI] [PubMed] [Google Scholar]
- Benson (1999).Benson G. Tandem repeats finder: a program to analyze DNA sequences. Nucleic Acids Research. 1999;27(2):573–580. doi: 10.1093/nar/27.2.573. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Bi et al. (2019).Bi D, Ding HW, Wang QQ, Jiang L, Lu WK, Wu X, Zhu R, Zeng JH, Zhou SB, Yang XJ, Kan XZ. Two new mitogenomes of Picidae (Aves, Piciformes): sequence, structure and phylogenetic analyses. International Journal of Biological Macromolecules. 2019;133:683–692. doi: 10.1016/j.ijbiomac.2019.04.157. [DOI] [PubMed] [Google Scholar]
- Calviño Cancela, Piña & Martín-Herrero (2022).Calviño Cancela M, Piña L, Martín-Herrero J. Bioacoustic differentiation of calls in the chiffchaff complex. PeerJ. 2022;10:e14261. doi: 10.7717/peerj.14261. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Caparroz et al. (2018).Caparroz R, Rocha AV, Cabanne GS, Tubaro P, Aleixo A, Lemmon EM, Lemmon AR. Mitogenomes of two neotropical bird species and the multiple independent origin of mitochondrial gene orders in Passeriformes. Molecular Biology Reports. 2018;45(3):279–285. doi: 10.1007/s11033-018-4160-5. [DOI] [PubMed] [Google Scholar]
- Cho et al. (2009).Cho HJ, Eda M, Nishida S, Yasukochi Y, Chong JR, Koike H. Tandem duplication of mitochondrial DNA in the black-faced spoonbill, Platalea minor. Genes and Genetic Systems. 2009;84(4):297–305. doi: 10.1266/ggs.84.297. [DOI] [PubMed] [Google Scholar]
- Clement, Alström & Madge (2006).Clement P, Alström P, Madge SC. Handbook of birds of the world: old world flycatchers to old world warblers. Vol. 11. Lynx Editions; Barcelona: 2006. Species accounts of Sylviidae; pp. 647–679. [Google Scholar]
- Drummond & Rambaut (2007).Drummond AJ, Rambaut A. BEAST: bayesian evolutionary analysis by sampling trees. BMC Evolutionary Biology. 2007;7:214. doi: 10.1186/1471-2148-7-214. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Eberhard & Wright (2016).Eberhard JR, Wright TF. Rearrangement and evolution of mitochondrial genomes in parrots. Molecular Phylogenetics and Evolution. 2016;94(Pt A):34–46. doi: 10.1016/j.ympev.2015.08.011. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Gao, Huang & Lei (2013).Gao RR, Huang Y, Lei FM. Sequencing and analysis of the complete mitochondrial genome of Remiz consobrinus. Zoological Research. 2013;34(3):228–237. [PubMed] [Google Scholar]
- Gill, Donsker & Rasmussen (2022).Gill F, Donsker D, Rasmussen P. IOC world bird list (v 12.1) 2022. http://www.worldbirdnames.org/ http://www.worldbirdnames.org/
- Grant & Stothard (2008).Grant JR, Stothard P. The CGView server: a comparative genomics tool for circular genomes. Nucleic Acids Research. 2008;36(Web Server issue):181–184. doi: 10.1093/nar/gkn179. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Hahn, Bachmann & Chevreux (2013).Hahn C, Bachmann L, Chevreux B. Reconstructing mitochondrial genomes directly from genomic next-generation sequencing reads–a baiting and iterative mapping approach. Nucleic Acids Research. 2013;41(13):e129. doi: 10.1093/nar/gkt371. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Hosner, Braun & Kimball (2016).Hosner PA, Braun EL, Kimball RT. Rapid and recent diversification of curassows, guans, and chachalacas (Galliformes: Cracidae) out of Mesoamerica: phylogeny inferred from mitochondrial, intron, and ultraconserved element sequences. Molecular Phylogenetics and Evolution. 2016;102:320–330. doi: 10.1016/j.ympev.2016.06.006. [DOI] [PubMed] [Google Scholar]
- Hu et al. (2017).Hu CC, Zhang CL, Sun L, Zhang Y, Xie WL, Zhang BW, Chang Q. The mitochondrial genome of pin-tailed snipe Gallinago stenura, and its implications for the phylogeny of Charadriiformes. PLOS ONE. 2017;12(4):e0175244. doi: 10.1371/journal.pone.0175244. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Jiang et al. (2019).Jiang LC, Peng LQ, Tang M, You ZQ, Zhang M, West A, Ruan QP, Chen W, Merilä J. Complete mitochondrial genome sequence of the Himalayan Griffon, Gyps himalayensis (Accipitriformes: Accipitridae): sequence, structure, and phylogenetic analyses. Ecology and Evolution. 2019;9(15):8813–8828. doi: 10.1002/ece3.5433. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Jiao et al. (2018).Jiao SY, Liu ZX, Yu F, Yao JY, Li YM, Yan SQ. Complete mitochondrial genome of Pallas’s Leaf Warbler (Phylloscopus proregulus) Mitochondrial DNA B Resources. 2018;3(1):211–212. doi: 10.1080/23802359.2017.1403867. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Johansson et al. (2007).Johansson US, Alström P, Olsson U, Ericson PG, Sundberg P, Price TD. Build-up of the Himalayan avifauna through immigration: a biogeographical analysis of the Phylloscopus and Seicercus warblers. Evolution. 2007;61(2):324–333. doi: 10.1111/j.1558-5646.2007.00024.x. [DOI] [PubMed] [Google Scholar]
- Kang et al. (2018).Kang H, Li B, Ma XN, Xu YC. Evolutionary progression of mitochondrial gene rearrangements and phylogenetic relationships in Strigidae (Strigiformes) Gene. 2018;674:8–14. doi: 10.1016/j.gene.2018.06.066. [DOI] [PubMed] [Google Scholar]
- Kearse et al. (2012).Kearse M, Moir R, Wilson A, Stones-Havas S, Cheung M, Sturrock S, Buxton S, Cooper A, Markowitz S, Duran C, Thierer T, Ashton B, Meintjes P, Drummond A. Geneious basic: an integrated and extendable desktop software platform for the organization and analysis of sequence data. Bioinformatics. 2012;28(12):1647–1649. doi: 10.1093/bioinformatics/bts199. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Kundu et al. (2022).Kundu S, Alam I, Maheswaran G, Tyagi K, Kumar V. Complete mitochondrial genome of great frigatebird (Fregata minor): phylogenetic position and gene rearrangement. Biochemical Genetics. 2022;60(4):1177–1188. doi: 10.1007/s10528-021-10156-6. [DOI] [PubMed] [Google Scholar]
- Lavrov, Brown & Boore (2000).Lavrov DV, Brown WM, Boore JL. A novel type of RNA editing occurs in the mitochondrial tRNAs of the centipede Lithobius forficatus. Proceedings of the National Academy of Sciences of the United States of America. 2000;97(25):13738–13742. doi: 10.1073/pnas.250402997. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Li, Huang & Lei (2015).Li XJ, Huang Y, Lei FM. Comparative mitochondrial genomics and phylogenetic relationships of the Crossoptilon species (Phasianidae, Galliformes) BMC Genomics. 2015;16(1):42. doi: 10.1186/s12864-015-1234-9. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Lowe & Eddy (1997).Lowe TM, Eddy SR. tRNAscan-SE: a program for improved detection of transfer RNA genes in genomic sequence. Nucleic Acids Research. 1997;25(5):955–964. doi: 10.1093/nar/25.5.955. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Mackiewicz et al. (2019).Mackiewicz P, Urantówka AD, Kroczak A, Mackiewicz D. Resolving phylogenetic relationships within Passeriformes based on mitochondrial genes and inferring the evolution of their mitogenomes in terms of duplications. Genome Biology and Evolution. 2019;11(10):2824–2849. doi: 10.1093/gbe/evz209. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Meng et al. (2019).Meng GL, Li YY, Yang CT, Liu SL. MitoZ: a toolkit for animal mitochondrial genome assembly, annotation and visualization. Nucleic Acids Research. 2019;47(11):e63. doi: 10.1093/nar/gkz173. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Morinha et al. (2016).Morinha F, Clemente C, Cabral JA, Lewicka MM, Travassos P, Carvalho D, Dávila JA, Santos M, Blanco G, Bastos E. Next-generation sequencing and comparative analysis of Pyrrhocorax pyrrhocorax and Pyrrhocorax graculus (Passeriformes: Corvidae) mitochondrial genomes. Mitochondrial DNA Part A: DNA Mapping, Sequencing, and Analysis. 2016;27(3):2278–2281. doi: 10.3109/19401736.2014.984179. [DOI] [PubMed] [Google Scholar]
- Moyle & Marks (2006).Moyle RG, Marks BD. Phylogenetic relationships of the bulbuls (Aves: Pycnonotidae) based on mitochondrial and nuclear DNA sequence data. Molecular Phylogenetics and Evolution. 2006;40(3):687–695. doi: 10.1016/j.ympev.2006.04.015. [DOI] [PubMed] [Google Scholar]
- Mundy & Helbig (2004).Mundy NI, Helbig AJ. Origin and evolution of tandem repeats in the mitochondrial DNA control region of shrikes (Lanius spp) Journal of Molecular Evolution. 2004;59(2):250–257. doi: 10.1007/s00239-004-2619-6. [DOI] [PubMed] [Google Scholar]
- Nguyen et al. (2015).Nguyen LT, Schmidt HA, von Haeseler A, Minh BQ. IQ-TREE: a fast and effective stochastic algorithm for estimating maximum-likelihood phylogenies. Molecular Biology and Evolution. 2015;32(1):268–274. doi: 10.1093/molbev/msu300. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Ojala, Montoya & Attardi (1981).Ojala D, Montoya J, Attardi G. tRNA punctuation model of RNA processing in human mitochondria. Nature. 1981;290(5806):470–474. doi: 10.1038/290470a0. [DOI] [PubMed] [Google Scholar]
- Oliveros et al. (2019).Oliveros CH, Field DJ, Ksepka DT, Barker FK, Aleixo A, Andersen MJ, Alström P, Benz BW, Braun EL, Braun MJ, Bravo G, Brumfield RT, Chesser RT, Claramunt S, Cracraft J, Cuervo AM, Derryberry EP, Glenn TC, Harvey MG, Hosner PA, Joseph L, Kimball RT, Mack AL, Miskelly CM, Peterson AT, Robbins MB, Sheldon FH, Silveira LF, Smith BT, White ND, Moyle RG, Faircloth BC. Earth history and the passerine superradiation. Proceedings of the National Academy of Sciences of the United States of America. 2019;116(16):7916–7925. doi: 10.1073/pnas.1813206116. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Omote et al. (2013).Omote K, Nishida C, Dick MH, Masuda R. Limited phylogenetic distribution of a long tandem-repeat cluster in the mitochondrial control region in Bubo (Aves, Strigidae) and cluster variation in Blakiston’s fish owl (Bubo blakistoni) Molecular Phylogenetics and Evolution. 2013;66(3):889–897. doi: 10.1016/j.ympev.2012.11.015. [DOI] [PubMed] [Google Scholar]
- Päckert et al. (2012).Päckert M, Martens J, Sun YH, Severinghaus LL, Nazarenko AA, Ting J, Töpfer T, Tietze DT. Horizontal and elevational phylogeographic patterns of Himalayan and Southeast Asian forest passerines (Aves: Passeriformes) Journal of Biogeography. 2012;39(3):556–573. doi: 10.1111/j.1365-2699.2011.02606.x. [DOI] [Google Scholar]
- Perna & Kocher (1995).Perna NT, Kocher TD. Patterns of nucleotide composition at fourfold degenerate sites of animal mitochondrial genomes. Journal of Molecular Evolution. 1995;41(3):353–358. doi: 10.1007/BF01215182. [DOI] [PubMed] [Google Scholar]
- Price (2010).Price TD. The roles of time and ecology in the continental radiation of the Old World leaf warblers (Phylloscopus and Seicercus) Philosophical transactions of the Royal Society B: Biological sciences. 2010;365(1547):1749–1762. doi: 10.1098/rstb.2009.0269. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Qu et al. (2021).Qu YH, Chen CH, Chen XM, Hao Y, She HS, Wang MX, Ericson PGP, Lin HY, Cai TL, Song G, Jia CX, Chen CY, Zhang HL, Li J, Liang LP, Wu TY, Zhao JY, Gao Q, Zhang GJ, Zhai WW, Zhang C, Zhang YE, Lei FM. The evolution of ancestral and species-specific adaptations in snowfinches at the Qinghai-Tibet Plateau. Proceedings of the National Academy of Sciences of the United States of America. 2021;118(13):e2012398118. doi: 10.1073/pnas.2012398118. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Rambaut, Suchard & Drummond (2004).Rambaut A, Suchard M, Drummond A. Tracer. 2004. [30 November 2009]. http://tree.bio.ed.ac.uk/software/tracer/ http://tree.bio.ed.ac.uk/software/tracer/
- Randi & Lucchini (1998).Randi E, Lucchini V. Organization and evolution of the mitochondrial DNA control region in the avian genus Alectoris. Journal of Molecular Evolution. 1998;47(4):449–462. doi: 10.1007/PL00006402. [DOI] [PubMed] [Google Scholar]
- Ritchie & Lambert (2000).Ritchie PA, Lambert DM. A repeat complex in the mitochondrial control region of Adélie penguins from Antarctica. Genome. 2000;43(4):613–618. doi: 10.1139/g00-018. [DOI] [PubMed] [Google Scholar]
- Ronquist & Huelsenbeck (2003).Ronquist F, Huelsenbeck JP. MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics. 2003;9(12):1572–1574. doi: 10.1093/bioinformatics/btg180. [DOI] [PubMed] [Google Scholar]
- Sun, Liu & Lu (2020).Sun CH, Liu HY, Lu CH. Five new mitogenomes of Phylloscopus (Passeriformes, Phylloscopidae): Sequence, structure, and phylogenetic analyses. International Journal of Biological Macromolecules. 2020;146:638–647. doi: 10.1016/j.ijbiomac.2019.12.253. [DOI] [PubMed] [Google Scholar]
- Tamura, Stecher & Kumar (2021).Tamura K, Stecher G, Kumar S. MEGA11: molecular evolutionary genetics analysis version 11. Molecular Biology and Evolution. 2021;38(7):3022–3027. doi: 10.1093/molbev/msab120. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Urantówka, Kroczak & Mackiewicz (2020).Urantówka AD, Kroczak A, Mackiewicz P. New view on the organization and evolution of Palaeognathae mitogenomes poses the question on the ancestral gene rearrangement in Aves. BMC Genomics. 2020;21(1):874. doi: 10.1186/s12864-020-07284-5. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Urantówka et al. (2018).Urantówka AD, Kroczak A, Silva T, Padrón RZ, Gallardo NF, Blanch J, Blanch B, Mackiewicz P. New insight into parrots’ mitogenomes indicates that their ancestor contained a duplicated region. Molecular Biology and Evolution. 2018;35(12):2989–3009. doi: 10.1093/molbev/msy189. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Vaidya, Lohman & Meier (2011).Vaidya G, Lohman DJ, Meier R. SequenceMatrix: concatenation software for the fast assembly of multi-gene datasets with character set and codon information. Cladistics. 2011;27(2):171–180. doi: 10.1111/j.1096-0031.2010.00329.x. [DOI] [PubMed] [Google Scholar]
- Yang et al. (2022).Yang C, Du XJ, Liu YX, Yuan H, Wang QX, Hou X, Gong HS, Wang Y, Huang Y, Li XJ, Ye HY. Comparative mitogenomics of the genus Motacilla (Aves, Passeriformes) and its phylogenetic implications. Zookeys. 2022;1109:49–65. doi: 10.3897/zookeys.1109.81125. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Yang et al. (2021).Yang C, Zhao L, Wang QX, Yuan H, Li XJ, Wang Y. Mitogenome of Alaudala emcheleensis (Passeriformes: Alaudidae) and comparative analyses of Sylvioidea mitogenomes. Zootaxa. 2021;4952(2):331–353. doi: 10.11646/zootaxa.4952.2.7. [DOI] [PubMed] [Google Scholar]
- Yu et al. (2022).Yu W, Cui S, Chen JD, Meng DH, Zhou XY, Teng LW, Liu ZS. The complete mitochondrial genome of the Pale-legged Leaf-Warbler Phylloscopus tenellipes (Aves: Phylloscopidae) from Maor Mountain. Mitochondrial DNA B Resources. 2022;7(7):1367–1368. doi: 10.1080/23802359.2022.2100290. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Zhang et al. (2021).Zhang DZ, Rheindt FE, She HS, Cheng YL, Song G, Jia CX, Qu YH, Alström P, Lei FM. Most genomic loci misrepresent the phylogeny of an avian radiation because of ancient gene flow. Systematic Biology. 2021;70(5):961–975. doi: 10.1093/sysbio/syab024. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Zhou et al. (2014).Zhou XP, Lin QX, Fang WZ, Chen XL. The complete mitochondrial genomes of sixteen ardeid birds revealing the evolutionary process of the gene rearrangements. BMC Genomics. 2014;15(1):573. doi: 10.1186/1471-2164-15-573. [DOI] [PMC free article] [PubMed] [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Note: (A): P. borealis, (B): P. trochiloides, (C): P. proregulus, (D): P. fuscatus. Photos of P. burki and P. reguloides were not obtained.
Note: (A): the first codons, (B): the second codons, (C): the third codons.
Note: (A): initiation codon, (B): termination codon.
Note: (A), (C): CR1, (B), (D): remnant CR2.
Note: the newly sequenced mitochondrial sequences labelled with bold format.
Note: (A): mitogenome sequences, (B): cox1 gene.
Data Availability Statement
The following information was supplied regarding data availability:
The mitogenome sequence data are available at NCBI GenBank: MG681101, OR030349 –OR030353.