Combining Molecular Data with Classical Morphology for Uncultured Phagotrophic Euglenids (Excavata): A Single‐Cell Approach

Phagotrophic euglenids are one of the most diverse and important forms of heterotrophic flagellates in sediment systems, and are key to understanding the evolution of photosynthetic euglenids and ‘primary osmotrophs’, yet relatively little is known about their biodiversity and phylogenetic relationships. A wealth of light microscopy‐based information is available, but little progress has been made in associating this with molecular sequence data. We established a protocol to obtain light microscopy data and molecular data from single euglenid cells isolated from environmental samples. Individual cells from freshwater and marine benthic samples were isolated and rinsed by micropipetting, documented using high‐resolution photomicroscopy, then subjected to single‐cell nested PCR using taxon‐specific primers in combination with universal eukaryotic primers, generating > 75% or full‐length SSU rDNA sequences. As a proof‐of‐principle eight individuals were characterised and subjected to phylogenetic analyses. Many of these cells were identified as Anisonema or Dinema, and grouped with existing sequences assigned to these taxa, and with a ‘Peranema sp.’ sequence that we could now clearly demonstrate was misidentified or misannotated. Another cell is Heteronema c.f. exaratum, the first ‘skidding heteronemid’ for which sequence data are available. This is not closely related to Heteronema scaphurum, and intriguingly, branches as the sister group to primary osmotrophs. A cell similar to Ploeotia vitrea (the type of this genus), shows no particular phylogenetic affinity to Ploeotia costata, the best studied Ploeotia species. Our experimental protocol provides a useful starting point for future analyses on euglenid biodiversity (including environmental sequence surveys), and their evolution and systematics.     

Protist Biodiversity and Biogeography in Lakes From Four Brazilian River–Floodplain Systems

The biodiversity and biogeography of protists inhabiting many ecosystems have been intensely studied using different sequencing approaches, but tropical ecosystems are relatively under‐studied. Here, we sampled planktonic waters from 32 lakes associated with four different river–floodplains systems in Brazil, and sequenced the DNA using a metabarcoding approach with general eukaryotic primers. The lakes were dominated by the largely free‐living Discoba (mostly the Euglenida), Ciliophora, and Ochrophyta. There was low community similarity between lakes even within the same river–floodplain. The protists inhabiting these floodplain systems comprise part of the large and relatively undiscovered diversity in the tropics.     

NOVEL PELLICLE SURFACE PATTERNS ON EUGLENA OBTUSA (EUGLENOPHYTA) FROM THE MARINE BENTHIC ENVIRONMENT: IMPLICATIONS FOR PELLICLE DEVELOPMENT AND EVOLUTION1

Euglena obtusa F. Schmitz possesses novel pellicle surface patterns, including the greatest number of strips (120) and the most posterior subwhorls of strip reduction in any euglenid described so far. Although the subwhorls form a mathematically linear pattern of strip reduction, the pattern observed here differs from the linear pattern described for Euglena mutabilis F. Schmitz in that it contains seven linear subwhorls, rather than three, and is developmentally equivalent to three whorls of exponential reduction, rather than two. These properties imply that the seven‐subwhorled linear pattern observed in E. obtusa is evolutionarily derived from an ancestral bilinear pattern, rather than from a linear pattern, of strip reduction. Furthermore, analysis of the relative lateral positions of the strips forming the subwhorls in E. obtusa indicates that (1) the identity (relative length, lateral position, and maturity) of each strip in any mother cell specifies that strip’s identity in one of the daughter cells following pellicle duplication and cell division, (2) the relative length of any given pellicle strip regulates the length of the nascent strip it will produce during pellicle duplication, and (3) pellicle pores develop within the heels of the most mature pellicle strips. These observations suggest that continued research on pellicle development could eventually establish an ideal system for understanding mechanisms associated with the morphogenesis and evolution of related eukaryotic cells.     

TRENDS IN THE EVOLUTION OF THE EUGLENID PELLICLE

Abstract Trends in the evolution of the euglenid pellicle were described using phylogenetic methods on 18S rDNA, morphological, and combined data from 25 mostly phototrophic taxa. The tree topology from a total‐evidence analysis formed a template for a synthetic tree that took into account conflicting results derived from the partitioned datasets. Pellicle character states that can only be observed with the assistance of transmission and scanning electron microscopy were phylogenetically mapped onto the synthetic tree to test a set of previously established homology statements (inferences made independently from a cladogram). The results permitted us to more confidently infer the ancestral‐derived polarities of character state transformations and provided a framework for understanding the key cytoskeletal innovations associated with the evolution of phototrophic euglenids. We specifically addressed the character evolution of (1) the maximum number of pellicle strips around the cell periphery; (2) the patterns of terminating strips near the cell posterior end; (3) the substructural morphology of pellicle strips; (4) the morphology of the cell posterior tip; and (5) patterns of pellicle pores on the cell surface.     

PHYLOGENY AND SYSTEMATICS OF THE GENUS MONOMORPHINA (EUGLENACEAE) BASED ON MORPHOLOGICAL AND MOLECULAR DATA1

Morphological studies of 16 strains belonging to the genus Monomorphina revealed a single, parietal, orbicular chloroplast in their cells. The chloroplast has a tendency to be perforated and disintegrates in aging populations and thus may appear to be many chloroplasts under the light microscope. A single chloroplast in the cells of Cryptoglena skujae is also parietally located and highly perforated. It never forms a globular and closed structure, but is open from the side of the furrow, resembling the letter C. We have verified the Monomorphina pyrum group (M. pyrum–like) on the basis of phylogenetic analysis of SSU rDNA and morphological data. The strain CCAC 0093 (misidentified as M. reeuwykiana) diverges first on the SSU rDNA phylogenetic tree. The rest of the M. pyrum–like strains form a tight cluster, subdivided into several smaller ones. Because morphological differences between the M. pyrum–like strains (including the strain CCAC 0093) do not conform to the tree topology, we suggest that they all (except the strain CCAC 0093) belong to M. pyrum. We designate a new species, M. pseudopyrum, for the strain CCAC 0093, solely on the basis of molecular characters. We also suggest that M. reeuwykiana and similar species should stay in Phacus and Lepocinclis unless detailed molecular and morphological studies show otherwise. Emended diagnoses of the genera Monomorphina and Cryptoglena and the species M. aenigmatica are also proposed, as well as the delimitation of an epitype for M. pyrum, the type species for the genus Monomorphina.     

Morphological and molecular examination of relationships and epitype establishment of Phacus pleuronectes,Phacus orbicularis,and Phacus hamelii1

Verification of morphological diagnostic features and the establishment of three epitypes for three species of Phacus Dujardin—Phacus pleuronectes (O. F. Müll.) Dujardin, Phacus orbicularis Hübner, and Phacus hamelii Allorge et Lefèvre—was performed based on literature studies and analysis of morphological (cell shape, cell size, and periplast ornamentation) as well as molecular (18S rDNA) characters. Periplast ornamentation was recognized as a main diagnostic character, distinguishing P. orbicularis from P. pleuronectes and P. hamelii. Phacus orbicularis has struts running perpendicular to the longitudinal axis of the strips, while P. pleuronectes and P. hamelii do not. On the SSU rDNA tree, obtained by the Bayesian method, P. orbicularis, P. pleuronectes, and P. hamelii belong to three distinct clades. Some of the phylogenetic relationships are not resolved, but there are at least three Phacus species (P. hamatus, P. platyaulax, P. longicauda; for taxonomic authors, see Introduction) that are more closely related to P. orbicularis than is P. pleuronectes. Phacus hamelii is more closely related to P. ranula and the assemblage of several species of Phacus, which have small cells, than to P. orbicularis or P. pleuronectes.     

The Chloroplast Genome of Euglena mutabilis—Cluster Arrangement,Intron Analysis,and Intrageneric Trends

A comparative analysis of the chloroplast genome of Euglena mutabilis underlined a high diversity in the evolution of plastids in euglenids. Gene clusters in more derived Euglenales increased in complexity with only a few, but remarkable changes in the genus Euglena. Euglena mutabilis differed from other Euglena species in a mirror‐inverted arrangement of 12 from 15 identified clusters, making it very likely that the emergence at the base of the genus Euglena, which has been considered a long branch artifact, is truly a probable position. This was corroborated by many similarities in gene arrangement and orientation with Strombomonas and Monomorphina, rendering the genome organization of E. mutabilis in certain clusters as plesiomorphic feature. By RNA analysis exact exon–intron boundaries and the type of the 77 introns identified were mostly determined unambiguously. A detailed intron study of psbC pointed at two important issues: First, the number of introns varied even between species, and no trend from few to many introns could be observed. Second, mat1 was localized in Eutreptiales exclusively in intron 1, and mat2 was not identified. With the emergence of Euglenaceae in most species, a new intron containing mat2 inserted in front of the previous intron 1 and thereby became intron 2 with mat1.     

Morphological and Molecular Characterisation of Notosolenus urceolatus Larsen and Patterson 1990, a Member of an Understudied Deep‐branching Euglenid Group (Petalomonads)

Petalomonads are particularly important for understanding the early evolution of euglenids, but are arguably the least studied major group within this taxon. We have established a culture of the biflagellate petalomonad Notosolenus urceolatus, and conducted electron microscopy observations and molecular phylogenetic analysis. Notosolenus urceolatus has eight pellicular strips bordered by grooves and underlain by close‐set microtubules. There are ventral and dorsal Golgi bodies. Mitochondria apparently contain fibrous inclusions, as in Petalomonas cantuscygni. A previously undocumented type of large, globular extrusome is present instead of the tubular extrusomes characteristic of Euglenozoa. The feeding apparatus lacks rods and vanes, and is partly supported by an “MTR”. The flagella have complex transition zones that are extremely elongated but unswollen. Only the emergent portion of the anterior flagellum has an organised paraxonemal rod, and also has very fine mastigonemes. The basal bodies are offset and lack connecting fibres. 18S rRNA gene phylogenies show that N. urceolatus is closely related to Petalomonas sphagnophila and P. cantuscygni, not Notosolenus ostium, confirming that current generic assignments based on the number of emergent flagella are phylogenetically unreliable, and making it difficult to infer whether features shared by N. urceolatus and P. cantuscygni (for example) are general for petalomonads.