The evolution of the adenylate-forming protein family in beetles: multiple luciferase gene paralogues in fireflies and glow-worms

Bioluminescence in beetles is dependent upon the enzyme luciferase. It has been hypothesised luciferase evolved from a fatty acyl-CoA synthetase gene deriving a novel bioluminescent function (neofunctionalization) after a gene duplication event. We evaluated this hypothesis within a phylogenetic framework using independent evidence obtained from the genome of Tribolium castaneum, published luciferase genes and novel luciferase and luciferase-like sequences. This phylogenetic study provides evidence for a large gene family of luciferase and luciferase-like paralogues in bioluminescent and non-bioluminescent beetles. All luciferase sequences formed a clade supporting a protoluciferase existing prior to the divergence of the Lampyridae, Elateridae and Phengodidae (Elateroidea). Multiple luciferase genes were identified from members of the Photurinae and the Luciolinae indicating complex gene duplication events within lampyrid genomes. The majority of luciferase residues were identified to be under purifying selection as opposed to positive selection. We conclude that beetle luciferase may have arisen from a process of subfunctionalization as opposed to neofunctionalization early on in the evolution of the Elateroidea.     

Molecular phylogenetics of Elateriformia (Coleoptera): evolution of bioluminescence and neoteny

Phylogenetic relationships in the coleopteran Series Elateriformia (click beetles, jewel beetles, fireflies and allies) were investigated using > 3800 nucleotides of partial nuclear (small and large subunit rRNA genes) and mitochondrial (large subunit rRNA and cytochrome oxidase subunit I) gene sequences. The Elateriformia includes several soft‐bodied lineages, some of which retain larviform features in the adult stage (neoteny), and several major bioluminescent groups, including the families Lampyridae (fireflies), Phengodidae and Rhagophthalmidae whose relationships have been contentious. All recognized superfamilies (Elateroidea, Cantharoidea, Byrrhoidea, Buprestoidea, Dascilloidea, Scirtoidea) and 28 of the 37 families, represented in 112 individuals, were included in the analysis. Sequence alignment was based on static and dynamic homology assignments and partial removal of sequences of uncertain homology. Alignment variable regions caused a great deal of uncertainty but also contributed much of the phylogenetic signal that was insufficient to resolve deep relationships when these were removed. The main features of most analyses were the monophyly of Elateroidea + Cantharoidea (= Elateroidea sensu lato), with Omethidae + Telegeusidae frequently occupying the basal node in this group; the affinities of Dascilloidea, Buprestoidea and a (broadly paraphyletic) Byrrhoidea, with unclear relationships among them; and the monophyly of Scirtoidea (including Decliniidae) as a rather distant outgroup to all others. When mapped on the resulting trees, soft‐bodied lineages were polyphyletic, contradicting the former Cantharoidea that had been united by this trait. Transitions to neoteny were either simultaneous with, or subsequent to, the origin of soft‐bodiedness in a minimum of seven lineages. The bioluminescent groups Lampyridae (including the enigmatic genus Drilaster) and the tightly allied Phengodidae + Rhagophthalmidae were never monophyletic. The former showed close relationship to the species‐rich, soft‐bodied families Lycidae and Cantharidae, while the latter grouped with poorly resolved lineages at the base of Elateridae (click beetles). Hence, although key features as soft‐bodiedness, neoteny and bioluminescence in Coleoptera are largely confined to the Elateriformia, they appear to result from multiple origins, showing the propensity of closely related lineages to acquire similar features independently. © The Willi Hennig Society 2007.     

The phylogeny and limits of Elateridae (Insecta,Coleoptera): is there a common tendency of click beetles to soft‐bodiedness and neoteny?

Kundrata, R. & Bocak, L. (2011). The phylogeny and limits of Elateridae (Insecta, Coleoptera): is there a common tendency of click beetles to soft‐bodiedness and neoteny? —Zoologica Scripta, 40, 364–378. Phylogenetic relationships in Elateroidea were investigated using partial 18S and 28S rDNA and rrnl and cox1 mtDNA sequences with special interest in the phylogeny of Elateridae and the position of soft‐bodied lineages Drilidae and Omalisidae that had been classified as families in the cantharoid lineage of Elateroidea until recently. Females in these groups are neotenic and almost completely larviform (Drilidae) or brachypterous (Omalisidae). The newly sequenced individuals of Elateridae, Drilidae, Omalisidae and Eucnemidae were merged with previously published datasets and analysed matrices include either 155 taxa with the complete representation of fragments or 210 taxa when some fragments were missing. The main feature of inferred phylogenetic trees was the monophyly of Phengodidae + Rhagophthalmidae + Omalisidae + Elateridae + Drilidae with Omalisidae regularly occupying a basal node in the group; Drilidae were embedded as a terminal lineage in the elaterid subfamily Agrypninae and soft‐bodied Cebrioninae were a part of Elaterinae. The soft‐bodied males and incompletely metamorphosed females originated at least three times within the wider Elateridae clade. Their atypical morphology has been considered as a result of long evolutionary history and they were given an inappropriately high rank in the previous classifications. The frequent origins of these modifications seem to be connected with modifications of the hormonal regulation of the metamorphosis. The superficial similarity with other soft‐bodied lineages, such as Cantharidae, Lycidae, Lampyridae, Phengodidae and Rhagophthalmidae is supposed to be a result of homoplasious modifications of the ancestral elateroid morphology due to the incomplete metamorphosis. The results of phylogenetic analyses are translated in the formal taxonomic classification. Most Drilidae are placed in Elateridae as a tribe Drilini in Agrypninae, whilst Pseudeuanoma and Euanoma are transferred from Drilidae to Omalisidae. The subfamily Cebrioninae is placed in Elaterinae as tribes Cebrionini and Aplastini. Oxynopterini, Pityobiini and Semiotini are lowered from the subfamily rank to tribes and classified in Denticollinae.     

Phylogenomic relationships of bioluminescent elateroids define the ‘lampyroid’ clade with clicking Sinopyrophoridae as its earliest member

Bioluminescence has been hypothesized as aposematic signalling, intersexual communication and a predatory strategy, but origins and relationships among bioluminescent beetles have been contentious. We reconstruct the phylogeny of the bioluminescent elateroid beetles (i.e. Elateridae, Lampyridae, Phengodidae and Rhagophthalmidae), analysing genomic data of Sinopyrophorus Bi & Li, and in light of our phylogenetic results, we erect Sinopyrophoridae Bi & Li, stat.n . as a clicking elaterid‐like sister group of the soft‐bodied bioluminescent elateroid beetles, that is, Lampyridae, Phengodidae and Rhagophthalmidae. We suggest a single origin of bioluminescence for these four families, designated as the ‘lampyroid clade’, and examine the origins of bioluminescence in the terminal lineages of click beetles (Elateridae). The soft‐bodied bioluminescent lineages originated from the fully sclerotized elateroids as a derived clade with clicking Sinopyrophorus and Elateridae as their serial sister groups. This relationship indicates that the bioluminescent soft‐bodied elateroids are modified click beetles. We assume that bioluminescence was not present in the most recent common ancestor of Elateridae and the lampyroid clade and it evolved among this group with some delay, at the latest in the mid‐Cretaceous period, presumably in eastern Laurasia. The delimitation and internal structure of the elaterid‐lampyroid clade provides a phylogenetic framework for further studies on the genomic variation underlying the evolution of bioluminescence.     

Comparison of the thermostability of recombinant luciferases from Brazilian bioluminescent beetles: Relationship with kinetics and bioluminescence colours

Firefly luciferases have been used extensively as bioanalytical reagents and their cDNAs as reporter genes for biosensors and bioimaging, but they are in general unstable at temperatures above 30°C. In the past few years, efforts have been made to stabilize some firefly luciferases for better application as analytical reagents. Novel luciferases from different beetle families, displaying distinct bioluminescence colours and kinetics, may offer desirable alternatives to extend the range of applications. In the past years, our group has cloned the largest variety of luciferases from the three main families of bioluminescent beetles (Elateridae: P. termitilluminans, F. bruchi, P. angustus; Phengodidae: P. hirtus, P. vivianii; and Lampyridae: A. vivianii, C. distinctus and Macrolampis sp2) occurring in Brazilian biomes. We compared the thermostability of these recombinant luciferases and investigated their relationships with bioluminescence spectra and kinetics. The most thermostable luciferases were those of Pyrearinus termitilluminans larval click beetle (534 nm), Amydetes vivianii firefly (539 nm) and Phrixotrix vivianii railroad worm (546 nm), which are the most blue‐shifted examples in each family, confirming the trend that the most blue‐shifted emitting luciferases are also the most thermostable. Comparatively, commercial P. pyralis firefly luciferase was less thermostable than P. termitilluminans click beetle and A. vivianii firefly luciferases. The higher thermostability in these luciferases could be related to higher degree of hydrophobic packing and disulfide bond content (for firefly luciferases).     

Changes in the suprageneric classification of Lasiocampidae (Lepidoptera) based on the nucleotide sequence of gene EF-1α

The nucleotide sequences of nuclear gene EF-1α were determined for 49 species of Lasiocampidae from Eurasia and Africa. Based on these data, the phylogeny of the family was reconstructed using the minimum evolution, maximum parsimony, maximum likelihood, and Bayesian inference methods. The molecular genetic research confirms the monophyly of Malacosominae which is treated as a separate subfamily. The genus Euthrix appears to be paraphyletic. The group of genera similar to Arguda, previously united with Odonestis in the tribe Odonestini, proved to be a separate lineage; contrary to the earlier assumption, the genera do not seem to be related. On the other hand, the genera Argonestis and Odonestis were found to be closely related and therefore were placed in the same tribe. The position of the genus Macrothylacia remains obscure. The genus Stoermeriana de Fr. et Witt is also para- or polyphyletic and consists of several independent lineages whose status remains to be determined. The new classification supports synonymization of Pinarinae with Lasiocampinae. The rank of subfamily is not supported for the Neotropical Macromphaliinae, which is downgraded to a tribe, Macromphaliini stat. n., within Poecilocampinae. The genus Hypopacha, previously considered within Macromphaliinae, is transferred to Poecilocampini; the close relation between Poecilocampini and Macromphaliini is additionally supported by the presence of a member of Poecilocampini in the New World. A new tribe, Argudini Zolotuhin trib. n., is established.     

Cretophengodidae,a new Cretaceous beetle family,sheds light on the evolution of bioluminescence

Bioluminescent beetles of the superfamily Elateroidea (fireflies, fire beetles, glow-worms) are the most speciose group of terrestrial light-producing animals. The evolution of bioluminescence in elateroids is associated with unusual morphological modifications, such as soft-bodiedness and neoteny, but the fragmentary nature of the fossil record discloses little about the origin of these adaptations. We report the discovery of a new bioluminescent elateroid beetle family from the mid-Cretaceous of northern Myanmar (ca 99 Ma), Cretophengodidae fam. nov. Cretophengodes azari gen. et sp. nov. belongs to the bioluminescent lampyroid clade, and would appear to represent a transitional fossil linking the soft-bodied Phengodidae + Rhagophthalmidae clade and hard-bodied elateroids. The fossil male possesses a light organ on the abdomen which presumably served a defensive function, documenting a Cretaceous radiation of bioluminescent beetles coinciding with the diversification of major insectivore groups such as frogs and stem-group birds. The discovery adds a key branch to the elateroid tree of life and sheds light on the evolution of soft-bodiedness and the historical biogeography of elateroid beetles.     

Molecular phylogenetic relationships of China Seas groupers based on cytochrome <Emphasis Type="Italic">b</Emphasis> gene fragment sequences

The classification and evolutionary relationships are important issues in the study of the groupers. Cytochrome b gene fragment of twenty-eight grouper species within six genera of subfamily Epinephelinae was amplified using PCR techniques and the sequences were analyzed to derive the phylogenetic relationships of the groupers from the China Seas. Genetic information indexes, including Kimura-2 parameter genetic distance and T _S/T _V ratios, were generated by using a variety of biology softwares. With Niphon spinosus, Pagrus major and Pagrus auriga as the designated outgroups, phylogenetic trees, which invoke additional homologous sequences of other Epinephelus fishes from GenBank, were constructed based on the neighbor-joining (NJ), maximum-parsimony (MP), maximum-likelihood (ML) and minimum-evolution (ME) methods. Several conclusions were drawn from the DNA sequences analysis: (1) genus Plectropomus, which was early diverged, is the most primitive group in the subfamily Epinephelinae; (2) genus Variola is more closely related to genus Cephalopolis than the other four genera; (3) genus Cephalopolis is a monophyletic group and more primitive than genus Epinephelus; (4) Promicrops lanceolatus and Cromileptes altivelis should be included in genus Epinephelus; (5) there exist two sister groups in genus Epinephelus.     

Species delimitation in Neotropical fishes of the genus Characidium (Teleostei,Characiformes)

Neotropical darters of the genus Characidium have a complex systematic history with several examples of sympatry throughout their distribution range in Neotropical freshwaters. Although various species within the genus have been used as models to investigate chromosomal evolution and biogeography, species boundaries and relationships still remain uncertain. Here, we use mitochondrial DNA sequences to perform species delimitation analyses within Characidium and test previous hypotheses of species richness within the Characidium zebra complex and among sympatric morphotypes of C. alipioi. Results indicate high genetic distances within tested species complexes and revealed the presence of strongly supported lineages such as the large C. lauroi group from southeastern Brazil. This suggests that the evolutionary history of these groups may be correlated with biogeographic history. Analyses also reveal that three geographically isolated populations of C. zebra represent a single species, leading us to reject prior hypothesis of multiple species. Species delimitation using mitochondrial data strongly supports the presence of two sympatric species within C. alipioi in southeastern Brazil despite limited morphological variation and conserved chromosomal patterns. These results provide a framework to further the study of systematics and evolution within Characidium.     

The evolutionary process of bioluminescence and aposematism in cantharoid beetles (Coleoptera: Elateroidea) inferred by the analysis of 18S ribosomal DNA

Cantharoid beetles are distinctive for their leathery soft elytra and conspicuous color or bioluminescence, and many of the members are equipped with chemical defenses. Thus, the vivid coloration of Cantharidae and Lycidae and the bioluminescence in Lampyridae and Phengodidae appear to be aposematic signals. However, the evolutionary aspect of their aposematism is not well understood, because the classification of the families remains controversial. In this study, we performed molecular phylogenetic analyses of species from cantharoid families, based on nucleotide sequence comparisons of nuclear 18S ribosomal DNA. The results shows that the luminous species Rhagophthalmus ohbai, which had sometimes been classified in Lampyridae, is excluded from a lampyrid clade and associates with the taxa of Phengodidae. The molecular data also suggests that four major subfamilies of Cantharidae (Cantharinae, Chauliognathinae, Malthininae, and Silinae) form a clade. The six subfamilies of Lampyridae are grouped and classified into two sublineages: Amydetinae + Lampyrinae + Photurinae and Cyphonocerinae + Luciolinae +Ototretinae. Genera Drilaster and Stenocladius are the members of Ototretinae in Lampyridae. These results conform to traditional taxonomy but disagree with more recent cladistic analyses. Based on these findings, we propose an evolutionary process of bioluminescence and aposematism in cantharoids: the clades of Cantharidae, Lampyridae, Lycidae, and Phengodidae have evolved aposematic coloration; subsequently Lampyridae and Phengodidae acquired bioluminescence; and these four major cantharoid families achieved their current adaptive diversities.     

Molecular phylogenetic relationships of China Seas groupers based on cytochrome b gene fragment sequences

The classification and evolutionary relationships are important issues in the study of the groupers. Cytochrome b gene fragment of twenty-eight grouper species within six genera of subfamily Epinephelinae was amplified using PCR techniques and the sequences were analyzed to derive the phylogenetic relationships of the groupers from the China Seas. Genetic information indexes, including Kimura-2 parameter genetic distance and T _S/T _V ratios, were generated by using a variety of biology softwares. With Niphon spinosus, Pagrus major and Pagrus auriga as the designated outgroups, phylogenetic trees, which invoke additional homologous sequences of other Epinephelus fishes from GenBank, were constructed based on the neighbor-joining (NJ), maximum-parsimony (MP), maximum-likelihood (ML) and minimum-evolution (ME) methods. Several conclusions were drawn from the DNA sequences analysis: (1) genus Plectropomus, which was early diverged, is the most primitive group in the subfamily Epinephelinae; (2) genus Variola is more closely related to genus Cephalopolis than the other four genera; (3) genus Cephalopolis is a monophyletic group and more primitive than genus Epinephelus; (4) Promicrops lanceolatus and Cromileptes altivelis should be included in genus Epinephelus; (5) there exist two sister groups in genus Epinephelus. These authors contributed equally to this work.     

OLIGONUCLEOTIDE PRIMERS FOR THE DETECTION OF BIOLUMINESCENT DINOFLAGELLATES REVEAL NOVEL LUCIFERASE SEQUENCES AND INFORMATION ON THE MOLECULAR EVOLUTION OF THIS GENE1

Bioluminescence is reported in members of 18 dinoflagellate genera. Species of dinoflagellates are known to have different bioluminescent signatures, making it difficult to assess the presence of particular species in the water column using optical tools, particularly when bioluminescent populations are in nonbloom conditions. A “universal” oligonucleotide primer set, along with species and genus‐specific primers specific to the luciferase gene were developed for the detection of bioluminescent dinoflagellates. These primers amplified luciferase sequences from bioluminescent dinoflagellate cultures and from environmental samples containing bioluminescent dinoflagellate populations. Novel luciferase sequences were obtained for strains of Alexandrium cf. catenella (Whedon et Kof.) Balech and Alexandrium fundyense Balech, and also from a strain of Gonyaulax spinifera (Clap. et Whitting) Diesing, which produces bioluminescence undetectable to the naked eye. The phylogeny of partial luciferase sequences revealed five significant clades of the dinoflagellate luciferase gene, suggesting divergence among some species and providing clues on their molecular evolution. We propose that the primers developed in this study will allow further detection of low‐light‐emitting bioluminescent dinoflagellate species and will have applications as robust indicators of dinoflagellate bioluminescence in natural water samples.     

Evolutionary and biogeographic history of the subfamily Neoplecostominae (Siluriformes: Loricariidae)

Freshwater fish evolution has been shaped by changes in the earth's surface involving changes in the courses of rivers and fluctuations in sea level. The main objective of this study is to improve our knowledge of the evolution of loricariids, a numerous and adaptive group of freshwater catfish species, and the role of geological changes in their evolution. We use a number of different phylogenetic methods to test the relationships among 52 representative taxa within the Neoplecostominae using 4676 bps of mitochondrial and nuclear DNA. Our analysis revealed that the subfamily Neoplecostominae is monophyletic, including Pseudotocinclus, with three lineages recognized. The first lineage is composed of part of Pareiorhina rudolphi, P. cf. rudolphi, and Pseudotocinclus; the second is composed of Isbrueckerichthys, Pareiorhaphis, Kronichthys, and the species Neoplecostomus ribeirensis; and the third is composed of Pareiorhina carrancas, P. cf. carrancas, Pareiorhina sp. 1, a new genus, and all the species of the genus Neoplecostomus, except N. ribeirensis. The relaxed molecular clock calibration provides a temporal framework for the evolution of the group, which we use for a likelihood‐based historical biogeographic analysis to test relevant hypotheses on the formation of southeast Brazil. We hypothesize that headwater capture events and marine regressions have shaped the patterns of distribution within the subfamily Neoplecostominae throughout the distinct basins of southeast Brazil.     

Historical biogeography and diversification within the Neotropical parrot genus Pionopsitta (Aves: Psittacidae)

Aim We investigate spatial and temporal patterns of diversification within the Neotropical avifauna using the phylogenetic history of parrots traditionally belonging to the genus Pionopsitta Bonaparte 1854. This genus has long been of interest for those studying Neotropical biogeography and diversity, as it encompasses species that occur in most Neotropical forest areas of endemism. Location The Neotropical lowland forests in South and Central America. Methods Phylogenetic relationships were investigated for all species of the genus Pionopsitta and five other short‐tailed parrot genera using complete sequences of the mitochondrial genes cyt b and ND2 as well as 26 plumage characters. The resulting phylogeny was used to test the monophyly of the genus, investigate species limits, and as a framework for reconstructing their historical biogeography and patterns of diversification. Results We found that the genus Pionopsitta, as previously defined, is not monophyletic and thus the Chocó, Central American and Amazonian species will now have to be placed in the genus Gypopsitta. The molecular and morphological phylogenies are largely congruent, but disagree on the position of one of the Amazon basin taxa. Using molecular sequence data, we estimate that species within Gypopsitta diversified between 8.7 and 0.6 Ma, with the main divergences occurring between 3.3 and 6.4 Ma. These temporal results are compared to other taxa showing similar vicariance patterns. Main conclusions The results suggest that diversification in Gypopsitta was influenced mainly by geotectonic events, marine transgressions and river dynamics, whereas Quaternary glacial cycles of forest change seem to have played a minor role in the origination of the currently recognized species.     

Phylogenetic Position of the Genus Cyrtostrombidium,with a Description of Cyrtostrombidium paralongisomum nov. spec. and a Redescription of Cyrtostrombidium longisomum Lynn & Gilron, 1993 (Protozoa,Ciliophora) Based on Live Observation,Protargol Impregnation,and 18S rDNA Sequences

We redescribe Cyrtostrombidium longisomum Lynn & Gilron, 1993, the type species of the genus Cyrtostrombidium, and describe the new species Cyrtostrombidium paralongisomum n. sp. using live observation, protargol staining and molecular data. The morphological characters of these two species are clearly distinct, i.e., dikinetid numbers in the girdle and ventral kineties; however, it is difficult to separate them by 18S rDNA sequences because they differ by only 8 bp, indicating that 18S rDNA sequences are insufficient for separating different species in the genus Cyrtostrombidium. We not only observed the position of the oral primordium in the genus Cyrtostrombidium but also observed a possibly homoplasious trait, a dorsal split in the girdle kinety, in (1) Apostrombidium, (2) Varistrombidium, and (3) Cyrtostrombidium/Williophrya. This partially supports the hypothesis of somatic ciliary pattern evolution recently put forth by Agatha and Strüder‐Kypke.     

Molecular phylogeny of Eois (Lepidoptera,Geometridae): evolution of wing patterns and host plant use in a species‐rich group of Neotropical moths

Strutzenberger, P., Brehm, G., Bodner, F. & Fiedler K. (2010). Molecular phylogeny of Eois (Lepidoptera, Geometridae): evolution of wing patterns and host plant use in a species‐rich group of Neotropical moths. —Zoologica Scripta, 39, 603–620. Eois is a pantropical genus of Geometridae moths with currently 250 valid described species, the majority of which occur in the Neotropics. Eois is a prominent component of Andean moth communities locally accounting for up to ～10% of geometrid individuals. We address the evolution of wing patterns and host plant use in Neotropical Eois and provide a preliminary assessment on the monophyly and biogeographic history of the entire genus as well as affinities within the subfamily Larentiinae. We applied Bayesian, maximum likelihood and maximum parsimony methods of phylogenetic reconstruction to a 142 taxon dataset of partial COI (1220 bp) and Ef1α (1066 bp) sequences resulting in the largest taxon set of geometrid moths analyzed in a molecular phylogenetic study so far. Monophyly of Eois was always strongly supported. Ten monophyletic clades were found with good support, seven of which have characteristic wing pattern phenotypes. Only one wing pattern type occurs in two clades. Trophic associations with representatives of the family Piperaceae occur in all 8 (of 9) Neotropical clades for which host information is available. Apart from feeding on Piper, at least two Eois species in Ecuador feed on Peperomia, and one on Manekia (all Piperaceae); two further species live on Hedyosmum (Chloranthaceae). Species feeding on Peperomia, Manekia and Hedyosmum are usually nested in Piper‐associated clades. Single records of associations with Gesneriaceae and Monimiaceae are scattered in otherwise Piperaceae‐associated clades. These patterns suggest multiple parallel host shifts away from Piper as ancestral food plant. Old World Eois were recovered as monophylum and sister to Neotropical Eois. Within the subfamily Larentiinae the genus Eois has previously been placed close to the tribe Eupitheciini, but this was not supported in our phylogenetic analyses.     

REVISION OF THE MASTOPHOROIDEAE (CORALLINALES,RHODOPHYTA) AND POLYPHYLY IN NONGENICULATE SPECIES WIDELY DISTRIBUTED ON PACIFIC CORAL REEFS1

The subfamily Mastophoroideae (Corallinaceae, Rhodophyta) is characterized by species possessing nongeniculate, uniporate tetrasporangial conceptacles without apical plugs, the presence of cell fusions, and the absence of secondary pit connections. However, molecular phylogenetic studies not including the type genus Mastophora indicated that the Mastophoroideae was polyphyletic. Our molecular phylogenetic analysis of the subfamily including the type genus using DNA sequences of SSU rDNA and plastid‐encoded gene of PSII reaction center protein D1 (psbA) revealed that Mastophora formed a robust clade only with Metamastophora. The other mastophoroid genera were divided into six lineages within the family Corallinaceae. Five supported lineages—(i) Pneophyllum; (ii) Hydrolithon gardineri (Foslie) Verheij et Prud’homme, Hydrolithon onkodes (Heydr.) Penrose et Woelk., and Hydrolithon pachydermum (Foslie) J. C. Bailey, J. E. Gabel et Freshwater; (iii) Hydrolithon reinboldii (Weber Bosse et Foslie) Foslie; (iv) Spongites; and (v) Neogoniolithon—were clearly distinguished by the combination of characters including the presence or absence of palisade cells and trichocytes in large, tightly packed horizontal fields and features of tetrasporangial and spermatangial conceptacles. Therefore, we amend the Mastophoroideae to be limited to Mastophora and Metamastophora with a thin thallus with basal filaments comprised of palisade cells, tetrasporangial conceptacles formed by filaments peripheral to fertile areas, and spermatangia derived only from the floor of male conceptacles. This emendation supports Setchell’s (1943) original definition of the Mastophoroideae as having thin thalli. We also propose the establishment of three new subfamilies, Hydrolithoideae subfam. nov. including Hydrolithon, Porolithoideae subfam. nov. including the resurrected genus Porolithon, and Neogoniolithoideae subfam. nov. including Neogoniolithon. Taxonomic revisions of Pneophyllum and Spongites were not made because we did not examine their type species.