Phylogenetic relationships of glyptosternoid fishes (Siluriformes: Sisoridae) inferred from mitochondrial cytochrome b gene sequences

To explore phylogenetic relationships among glyptosternoid fishes, we determined nucleotide sequences of the complete mitochondrial cytochrome b gene region (1138 base pair). Thirteen species of glyptosternoid fishes and six species of non-glyptosternoids represent 10 sisorid genera were examined. Molecular phylogenetic trees were constructed using the maximum parsimony, minimum evolution, maximum likelihood, and Bayesian methods. Bayesian and maximum likelihood analyses support the monophyly of glyptosternoids, but our hypothesis of internal relationships differs from previous hypothesis. Results indicated that glyptosternoid is a monophyletic group and genera Glyptosternum and Exostoma are two basal species having a primitive position among it. Genera Euchiloglanis and Pareuchiloglanis form a sister-group. Then they form a sister-group with Pseudexostoma plus Oreoglanis. Our result also found that Pareuchiloglanis anteanalis might be considered as the synonyms of Parechiloglanis sinensis, and genus Euchiloglanis might have only one valid species, Euchiloglanis davidi.     

从细胞色素b基因序列探讨笛鲷属的分子系统发生关系

测定了9种中国南海的笛鲷属鱼类的细胞色素b基因的部分序列,结合来自GenBank中1种分布于菲律宾和9种分布于美国大西洋的笛鲷属鱼类的相应同源序列,用邻接法和最大简约法构建分子系统树。结果显示:红鳍笛鲷(Lutjanuserythropterus)与红笛鲷(L.sanguineus)之间的同源序列碱基差异百分率只有0.32%,支持二者是同种异名的观点;中国南海的笛鲷属鱼类间的平均碱基差异要高于美国大西洋笛鲷属鱼类。在MP和NJ树中,美国大西洋笛鲷表现为亲缘关系较近,来源于中国南海的笛鲷鱼类相对集中在树的基部,分歧较大。这与所研究的笛鲷地理分布和地理隔离基本相一致,同时也说明中国南海笛鲷分化较早并且分歧较大。     

Phylogenetic relationships among bumble bees (Bombus, latreille) inferred from mitochondrial cytochrome b and cytochrome oxidase I sequences

We conducted a molecular study intending to derive an estimate of the relationships within the genus Bombus (bumble bees) by comparing the mitochondrial cytochrome b and cytochrome oxidase I (COI) genes from 19 species, spanning 10 of approximately 16 European subgenera and 3 subgenera from North and South America. Our trees differ from the most recent classifications of bumble bees. Although bootstrap values for deep branches are low, our sequences show significant data structure and low homoplasy, and all trees share some groups and patterns. In all cases, the subgenus Bombus s. str. clusters among the most derived bumble bees, contrary to other molecular studies. In all trees, B. funebris is the sister taxon of B. robustus, and in five of the six trees, B. wurflenii is the sister taxon to this clade. B. nevadensis is basal to the other species in the analysis of the cytochrome b gene, but appears to be among the most derived according to the analysis of the COI region. The species representing the subgenera Thoracobombus and Fervidobombus are consistently among the earliest diverged. Species that appear in very different positions in different trees are B. nevadensis, B. mesomelas, B. balteatus, and B. hyperboreus. All subgenera with two representatives in our analysis are apparently monophyletic except Fervidobombus, Melanobombus, and Pyrobombus. The groups formed by pocket makers and non-pocket makers within Bombus also appear to be paraphyletic, and therefore some subgenera may not accurately reflect phylogeny.     

Phylogenetic relationships of elopomorph fishes inferred from mitochondrial ribosomal DNA sequences

The superorder Elopomorpha, a grouping which includes all teleost fishes that possess a specialized leptocephalous larva [true eels (Anguilliformes), gulpers and bobtail snipe eels (Saccopharyngiformes), bonefishes, spiny eels, and halosaurs (Albuliformes, including Notacanthiformes), ladyfishes and tarpons (Elopiformes, including Megalopiformes)] comprises >800 species for which phylogenetic relationships are poorly understood. In the present study, we analyzed mitochondrial DNA sequences in segments of the 12S and 16S rRNA genes in 33 elopomorph taxa encompassing all of the previously proposed orders, and 9 of the 15 currently recognized families of the Anguilliformes, as well as outgroup representatives from the superorders Osteoglossomorpha (nine species) and Clupeomorpha (three species), to develop phylogenetic hypotheses based on distance and parsimony methods. Both methods failed to support the monophyly of the Elopomorpha, casting doubt on the validity of the leptocephalus as an elopomorph synapomorphy. The orders Elopiformes, Albuliformes, and Anguilliformes, however, were resolved as monophyletic assemblages. Parsimony analysis supported the separation of the Anguilliformes into two groups (primitive and advanced) based on the presence of divided versus fused frontal bones. In addition, the molecular data indicated a close affinity of the anguilliform Thalassenchelys coheni (incertae sedis), known only from the leptocephalus, with the family Serrivomeridae. The implications of these data as regards the evolution of the elopomorph assemblage are discussed.     

Phylogenetic relationships of neopterygian fishes, inferred from mitochondrial DNA sequences.

To investigate the relationships among the three main groups of extant neopterygian fishes--Amiidae, Lepisosteidae, and Teleostei--we sequenced fragments of three mitochondrial genes from 12 different actinopterygian fishes and translated the nucleotide sequences into amino acid sequences. When all three regions are considered together, Amiidae clusters with Lepisosteidae in the most parsimonious cladograms, but other clades, such as Neopterygii and Teleostei, that are well supported by morphological evidence fail to emerge as monophyletic. When the cytochrome b sequences are analyzed together with previously published sequences for other taxa, the majority-rule consensus tree is consistent with the monophyly of Teleostei and Neopterygii and marginally supports the Amiidae + Lepisosteidae clade. In either analysis, when Neopterygii and Teleostei are constrained to monophyly, all the most-parsimonious cladograms support the Amiidae + Lepisosteidae topology. Where molecules and morphology disagree, provisional morphology-based constraints on the analysis of molecular data offer a practical means of integrating the two types of data.     

Phylogenetic relationships of four species of floating gobies (Gymnogobius) as inferred from partial mitochondrial cytochrome b gene sequences

 To clarify the intra- and interspecific relationships of four Gymnogobius species, G. urotaenia, G. isaza, Gymnogobius sp. 1 (sumiukigori), and Gymnogobius sp. 2 (shimaukigori), partial mitochondrial cytochrome b gene sequences of 639 bp were obtained for a total of 31 specimens from Japan and Korea, plus 2 outgroup specimens. Twenty-nine haplotypes were identified in the ingroup, with a total of 122 variable sites (19.1%). The individuals regarded as the same species morphologically were monophyletic genetically. Sequence differences between amphidromous individuals of three species distributed in both Japan and Korea were relatively small (0.16–1.25%). The largest intraspecific sequence difference was observed between individuals of G. urotaenia from Lake Biwa and those from other localities (1.25–2.19%). Interspecific sequence differences ranged from 4.07% to 13.46%; neighbor-joining, maximum-parsimony, and maximum-likelihood methods indicated that Gymnogobius sp. 2 diverged first, followed by G. isaza, with Gymnogobius sp. 1 and G. urotaenia being monophyletic. The estimated divergence time of each species, based on estimated divergence rates for mitochondrial protein-coding genes already reported (0.8–2.8%/my), suggested that speciation occurred mainly in the Pliocene (possibly Miocene), with G. isaza (a Lake Biwa endemic) diverging significantly earlier (probably Lake Kouga stage) than estimated in previous studies. In contrast, according to the previous hypothesis, the substitution rates were highly overestimated to about 12–20%/my. Received: November 19, 2001 / Revised: May 20, 2002 / Accepted: June 18, 2002 Acknowledgments Special thanks are due to Katsutoshi Watanabe and Yuji Yamazaki for valuable advice and providing fish samples. We also thank Kouji Nakayama, Toshiyuki Ohkawa, Motoomi Yamaguchi, and members of the Laboratory of Marine Biology, Fukui Prefectural University, and members of the Laboratory of Molecular Marine Biology, Ocean Research Institute, University of Tokyo, and the Laboratory of Marine Stock Enhancement, University of Kyoto, for their help and advice during the present study. Correspondence to:Shigeo Harada     

Phylogenetic divergence in leatherside chub (Gila copei) inferred from mitochondrial cytochrome b sequences

We examined intra-specific phylogenetic relationships in leatherside chub, Gila copei. The complete mitochondrial (mt) cytochrome b gene (1140 bp) was sequenced for 30 individuals from 10 populations that span the geographical distribution of this species. Traditional phylogenetic analyses revealed two deeply divergent and evolutionarily distinct mtDNA clades that are geographically separated in northern and southern drainage basins. Interpopulation sequence variation between clades ranged from 7.7 to 8.1%. The northern clade was genetically more similar and phylogenetically more closely related to the selected out-group Lepidomeda m. mollispinus than to the southern clade, suggesting that the taxonomy of this species may require revision. Sequence variation among populations within clades ranged from 0 to 0.3% in the north and from 0 to 0.7% in the south. Statistical parsimony was used to construct phylogenetic networks of haplotypes within clades. Nested clade analysis revealed that geographical fragmentation has played an important role in genetic structuring within northern and southern clades.     

Phylogenetic relationships among atheriniform fishes (Teleostei: Atherinomorpha)

We present evidence from adult and larval morphology for the monophyly and relationships of Atheriniformes, using other atherinomorphs, mugilids and acanthomorph fishes as outgroups. Atheriniformes is diagnosed by ten characters (larval: short preanal length, single mid-dorsal row of melanophores; adult: vomerine ventral face concave, long Al muscle tendon to lacrimal, two anterior infraorbital bones, pelvic-rib ligament, pelvic medial plate not extended to anterior end, and second dorsal-fin spine flexible). We recognize six families within the order, the hierarchical relationships among which are: (Atherinopsidae (Notocheiridae (Melanotaeniidae (Atherionidae (Phallostethidae, Atherinidae))))). Other major conclusions include: (1) Atherinopsidae (Menidiinae, Atherinopsinae) is diagnosed by 20 characters (e.g. ethmomaxillary ligament attached to palatine dorsal process, ventral postcleithrum with two dorsal rami); (2) Melanotaeniidae (Bedotiinae (Melanotaeniinae (Telmatherinini, Pseudomugilini))) is diagnosed by six characters (e.g. absence of second dorsal-fin spine, sexual dimorphism in body colour and median-fin development, greater body depth); (3) Dentatherina is in Phallostethidae; (4) Atherinidae (Atherinomorinae (Craterocephalinae, Atherininae)) is diagnosed by three characters (lacrimal notch, ventral postcleithrum between first and second pleural ribs, pelvic ventral spine); (5) Atherinidae and Phallostethidae form the Atherinoidea clade diagnosed by seven characters (e.g. interopercle dorsal process absent, dorsal wings of urohyal absent, ventral postcleithrum laminar, pelvic medial plate extended to anterior end, presence of anal plate). Bedotia, Rhodes , and melanotaeniines are shown to be derived within atheriniforms rather than the plesiomorphic sister groups to a paraphyletic 'atherinoid' group. We also demonstrate that groups traditionally placed in Atherinidae (Menidiinae, Atherininae, Atherioninae, etc.) comprise a paraphyletic assemblage.     

Phylogenetic relationships ofSphaerophoraceae (Ascomycetes) inferred from SSU rDNA sequences

SSU rDNA was sequenced from the lichenized fungiBunodophoron scrobiculatum andLeifidium tenerum (Sphaerophoraceae), andStereocaulon ramulosum andPilophorus acicularis (Stereocaulaceae) and analysed by maximum parsimony with 44 homologous ascomycete sequences in a cladistic study. A small insertion (c. 60 nt.) was found in the sequence ofLeifidium tenerum. Sphaerophoraceae constitutes a strongly supported monophyletic group which groups together withLecanora dispersa and theStereocaulaceae. Together withPorpidia crustulata, this larger group is a sistergroup to thePeltigerineae. This analysis thus supports theLecanorales as monophyletic, includingSphaerophoraceae and thePeltigerineae, but does not provide strong support for this monophyly. The analysis also suggests that the prototunicate ascus in theSphaerophoraceae is a reversion to the plesiomorphic state. Based on morphological, anatomical and chemical reasons,Sphaerophoraceae is proposed to belong to one of the groups presently included in the paraphyletic suborderCladoniineae within theLecanorales.     

Phylogenetic analysis of hampala fishes (subfamily Cyprininae) in Malaysia inferred from partial mitochondrial cytochrome B DNA sequences

This study examined 396 base pairs of the mitochondrial cytochrome b gene from 110 individuals belonging to the genus Hampala, a group of freshwater cyprinids that inhabit Southeast Asia. The samples were taken from various locations throughout Sarawak, Sabah, and peninsular Malaysia. The nucleotide sequences were subjected to phylogenetic analyses by using the neighbor-joining, maximum parsimony, and maximum likelihood methods. All three methods revealed the reciprocally monophyletic relationship of Hampala macrolepidota to the other Hampala forms, thus strongly supporting its status as a distinct species. Phylogenetic analysis also discovered the existence of two H. bimaculata lineages endemic to Borneo: (1) a newly identified species from the southern and central part of Sarawak assigned as H. bimaculata Type A and (2) the previously described H. bimaculata from northern Sarawak and the west coast of Sabah assigned as H. bimaculata Type B. However, the status of H. sabana and an intermediate form were not elucidated. The results suggest that the intermediate form from the Tawau population is actually a subpopulation of H. sabana, while the highly divergent intermediate form from Kalabakan could represent a cryptic species. The sharing of H. macrolepidota haplotypes in the southern peninsular Malaysia and southern and central Sarawak samples (Hm1 and Hm2) reflected the recent disconnection of the two regions, during the late Pleistocene. Overall, the partial sequence of the mitochondrial cytochrome b gene was useful for resolving the phylogenetic relationships among Hampala fishes in Malaysia.     

Phylogenetic relationships among four species of Mullidae (Perciformes) inferred from DNA sequences of mitochondrial cytochrome b and 16S rRNA genes

DNA sequence comparisons of two mitochondrial DNA genes were used to infer phylogenetic relationships among four species of mullids. Approximately 238 bp of the mitochondrial 16S ribosomal RNA (rRNA) and 261 bp of the cytochrome b (cytb) genes were sequenced from representatives of three mullid genera (Mullus, Upeneus, Pseudopeneus), present in the Mediterranean Sea. Trees were constructed using three methods: maximum likelihood (ML), neighbor joining (NJ) and parsimony (MP). The results of the analyses of these data together with published data of the same mtDNA segments of two other perciform species (Sparus aurata, Perca fluviatilis), support the previous taxonomic classification of the three genera examined, as well as the classification of the two red mullet species in the same genus.     

Phylogenetic relations among percid fishes as inferred from mitochondrial cytochrome b DNA sequence data

Hypotheses of relationship among genera of Percidae have been conflicting. Based on different phylogenetic premises, the evolution of small benthic forms in Percidae has been interpreted as resulting from either convergence or common ancestry. In order to assess various phylogenetic hypotheses of Percidae we collected complete sequences (1140 bp) of mitochondrially encoded cytochrome b for 21 species of percids. Seven species representing four additional families of Perciformes were used as outgroups. Maximum parsimony and minimum evolution analyses both recovered single shortest trees, and the results of these analyses were generally congruent with one another. All analyses consistently recovered three monophyletic groups in Percidae: Etheostomatinae (Ammocrypta, Crystallaria, Etheostoma, and Percina), Percinae (Perca and Gymnocephalus), and Luciopercinae (Stizostedion, Zingel, and Romanichthys). As a result of this analysis we present a revised classification of Percidae and discuss the phylogenetic evidence for the independent evolution of small benthic species within Etheostomatinae and Luciopercinae.     

Phylogenetic structure of Zacco platypus (Teleostei, Cyprinidae) populations on the upper and middle Chang Jiang (=Yangtze) drainage inferred from cytochrome b sequences

We examined the genetic structure and phylogenetic relationships of some Chinese populations from the Chang Jiang (=Yangtze) drainage of the cyprinid Zacco platypus. We sequenced the complete mitochondrial cytochrome b gene of 64 individuals from 6 upper and middle tributaries of the Sichuan and Hunan Provinces to assess their population structure and systematics. The combined analyses of the phylogenetic information and the population structure suggested that Chinese Z. platypus consist of four distinct mtDNA lineages which exhibit high genetic variation and haplotypic diversity (Zacco A-D). The high molecular divergence observed among Zacco A-D mtDNA lineages (TrN+I (0.76) distance, mean 8.9%+/-1.7%) and their phylogeographic structure indicate that all four lineages have evolved independently. Analysis of molecular variance (AMOVA) indicates that most of the genetic variation observed is found among the four Zacco mtDNA lineages (thetaCT = 0.94) suggesting restricted gene flow among the Chang Jiang populations. Long-term interruption of gene flow was also evidenced by thetaST values higher than 0.9 that could be favoured by the discontinuous distributions of the lineages inhabiting upper (Sichuan Province) and middle (Hunan Province) Chang Jiang tributaries. The significant correlation between the geographic and genetic distances provide support for the importance of geographic discontinuity in shaping the Zacco genetic structure. Nested clade analysis (NCA) results were congruent with phylogenetic relationships recovered and confirm the genetic distinctiveness of four independent Zacco groups. These four groups correspond to the four Zacco A-D mtDNA lineages recovered in the phylogeny and were defined by nucleotide synapomorphies permitting bootstrapped and Bayesian confidence of 95% or greater. The high level of mitochondrial sequence divergence separating all Zacco mtDNA lineages suggested that the Z. platypus populations from the Chang Jiang drainage probably correspond to four different species.     

Phylogenetic relationships within parrots (Psittacidae) inferred from mitochondrial cytochrome-b gene sequences

Blood and tissue samples of 40 individuals including 27 parrot species (15 genera; 3 subfamilies) were collected in Indonesia. Their phylogenetic relationships were inferred from 907 bp of the mitochondrial cytochrome-b gene, using the maximum-parsimony method, the maximum-likelihood method and the neighbor-joining method with Kimura two-parameter distance. The phylogenetic analysis revealed that (1) cockatoos (subfamily Cacatuinae) form a monophyletic sister group to other parrot groups; (2) within the genus Cacatua, C. goffini and C. sanguinea form a sister group to a clade containing other congeners; (3) subfamily Psittacinae emerged as paraphyletic, consisting of three clades, with a clade of Psittaculirostris grouping with subfamily Loriinae rather than with other Psittacinae; (4) lories and lorikeets (subfamily Loriinae) emerged as monophyletic, with Charmosyna placentis a basal sister group to other Loriinae, which comprised the subclades Lorius; Trichoglossus+Eos; and Chalcopsitta+ Pseudeos.     

Phylogenetic relationships of major clades of Catostomidae (Teleostei: Cypriniformes) as inferred from mitochondrial SSU and LSU rDNA sequences

Suckers (Family Catostomidae) are holarctic in distribution and include 76 recent species in 14 genera, with 13 genera and 75 species occurring in North and Central America and Siberia. Although this group constitutes a significant component of many aquatic ecosystems, most historic systematic effort has been either alpha- or limited beta-level studies focusing on the two largest tribes within the family, the Catostomini and the Moxostomatini. A recent phylogenetic study based on morphological, biochemical, and early life history characters has advanced current understanding of relationships among catostomid fishes. To further examine phylogenetic relationships among basal lineages of catostomids, we sequenced the entire mitochondrial (mt) SSU and LSU rRNA genes from genera representing all subfamilies and tribes within Catostomidae. Phylogenetic analysis of gene sequences yielded monophyletic Catostomidae, Ictiobinae, and Catostominae and para- or polyphyletic Cycleptinae, with Myxocyprinus as the basal-most taxon and Cycleptus as either the next most-basal taxon or the taxon basal to the Catostominae. Relationships within the Catostominae were generally consistent with those proposed in the above-noted recent phylogenetic study although Thoburnia and Hypentelium were either a clade sister to or a grade group relative to Moxostoma and Scartomyzon. In all trees, Scartomyzon was paraphyletic and embedded within Moxostoma. Phylogenetic affinities of Erimyzon and Minytrema varied depending on data set and character weighting scheme employed. To better reflect phylogenetic relationships resolved in this extensive analysis, we propose the following changes to the classification of catostomids: formation of the new subfamily Myxocyprininae, containing Myxocyprinus from China; restriction of the Cycleptinae to the two species of Cycleptus from North America; restriction of the tribe Moxostomatini to Moxostoma and Scartomyzon; Erimyzon and Minytrema are incertae sedis within Catostominae; and resurrection of the tribe Thoburniini, containing Thoburnia and expanded to include Hypentelium.     

Phylogenetic relationships of fossil and Recent gonorynchiform fishes (Teleostei: Ostariophysi)

This paper represents the first cladistic analysis of the interrelationships of all nominal fossil and living gonorynchiform genera. Gonorynchiformes is the basal group of the superorder Ostariophysi, and is confirmed as monophyletic on the basis of 12 synapomorphies. The Gonorynchiformes is be subdivided into two monophyletic suborders, Chanoidei and Gonorynchoidei. The Chanoidei includes the family Chanidae, which in turn includes the Recent Chanos plus five fossil genera, grouped in two subfamilies: Chaninae (( Chanos +† Tharrhiai) + † Parachanos +† Dastilbe ) and † Rubiesichthyinae († Rubiesichthys +† Gordichthys ). † Aethalionopsis is the sister-group to the Chanidae. Gonorynchoidei includes two families Gonorynchidae and Kneriidae. Gonorynchidae is formed by ( Gonorynchus, † Notogoneus ) and four fossil taxa of uncertain definition and interrelationships: †Charitosomus, † Charitopsis, † Ramallichthys, and †fudeichthys. The last four genera were previously included in the families †Charitosomidae and †Judeichthyidae, which could not be supported as monophyletic in this analysis. Kneriidae consists of two subfamilies Phractolaeminae with one genus Phractolaemus, and Kneriinae which includes (( Kneria + Parakneria ) + ( Grasseichthys + Cromeria )), the latter two being paedomorphic forms. The Phractolaeminae and the Kneriinae are freshwater African taxa with no known fossil record. The order Gonorynchiformes is represented herein by 18 genera, extending back to the Early Cretaceous. More work is required to clarify the interrelationships of the Gonorynchidae and the paedomorphic characters that apparently played an important role in the evolution of this morphologically diverse group of fishes.     

Biogeography and molecular phylogeny of the genus Schizothorax (Teleostei: Cyprinidae) in China inferred from cytochrome b sequences

Aim To test a vicariant speciation hypothesis derived from geological evidence of large‐scale changes in drainage patterns in the late Miocene that affected the drainages in the south‐eastern Tibetan Plateau. Location The Tibetan Plateau and adjacent areas. Methods The cytochrome b DNA sequences of 30 species of the genus Schizothorax from nine different river systems were analysed. These DNA sequences were analysed using parsimony, maximum likelihood and Bayesian methods. The approximately unbiased and Shimodaira–Hasegawa tests were applied to evaluate the statistical significance of the shortest trees relative to alternative hypotheses. Dates of divergences between lineages were estimated using the nonparametric rate smoothing method, and confidence intervals of dates were obtained by parametric bootstrapping. Results The phylogenetic relationships recovered from molecular data were inconsistent with traditional taxonomy, but apparently reflected geographical associations with rivers. Within the genus Schizothorax, we observed a divergence between the lineages from the Irrawaddy–Lhuit and Tsangpo–Parlung rivers, and tentatively dated this vicariant event back to the late Miocene (7.3–6.8 Ma). We also observed approximately simultaneous geographical splits within drainages of the south‐eastern Tibetan Plateau, the Irrawaddy, the Yangtze and the Mekong–Salween rivers in the late Miocene (7.1–6.2 Ma). Main conclusions Our molecular evidence tentatively highlights the importance of palaeoriver connections and the uplift of the Tibetan Plateau in understanding the evolution of the genus Schizothorax. Molecular estimates of divergence times allowed us to date these vicariant scenarios back to the late Miocene, which agrees with geological suggestions for the separation of these drainages caused by tectonic uplift in south‐eastern Tibet. Our results indicated the substantial role of vicariant‐based speciation in shaping the current distribution pattern of the genus Schizothorax.     

Phylogenetic relationships in family Magnoliaceae inferred from ndhF sequences

The ndhF sequences of 99 taxa, representing all sections in extant Magnoliaceae, were analyzed to address phylogenetic questions in the family. Magnolia macrophylla and M. dealbata, North American species of Magnolia section Rytidospermum, are placed at the base in the subfamily Magnolioideae although its supporting value is low. In the remaining taxa, several distinctive lineages are recognized: (1) Magnolia, the biggest genus in the family, is not monophyletic; (2) Michelia, including section Maingola of Magnolia subgenus Magnolia, is closely related with Elmerrillia and sections Alcimandra and Aromadendron of Magnolia subgenus Magnolia; (3) the associates of Michelia are grouped with Magnolia subgenus Yulania and section Gynopodium of Magnolia subgenus Magnolia; (4) Pachylarnax forms a clade with sections Manglietiastrum and Gynopodium of Magnolia; (5) a well-supported Manglietia clade is recognized; (6) Caribbean species of section Theorhodon of Magnolia subgenus Magnolia, which are section Splendentes sensu Vázquez-Garcia, are closely allied with New World members of Magnolia subgenus Talauma; and (7) section Rytidospermum of Magnolia subgenus Magnolia and subgenus Talauma are polyphyletic. The separated clades in the molecular tree are considerably different from traditional taxonomic dispositions in the family. The molecular data strongly suggest that a taxonomic realignment of infrafamilial delimitations and compositions should be considered.