Prototheca filamenta: A fungus not an alga

The genusPrototheca is composed of colorless algae. Plastids, a characteristic feature of colorless algae, are absent fromP. filamenta cells. The growth pattern seen with light and scanning electron microscopes, and the ultrastructure observed with the transmission electron microscope suggest thatP. filamenta is a fungus. Consequently we recommend the removal ofP. filamenta from the genusPrototheca and subsequent investigation of this organism to determine its correct taxonomic placement among the fungi.     

Taxonomic and phylogenetic studies on a new taxon of budding, hyphal Proteobacteria, Hirschia baltica gen. nov., sp. nov

Four strains of budding, hyphal bacteria, which had very similar chemotaxonomic properties, were isolated from the Baltic Sea. The results of DNA-DNA hybridization experiments, indicated that three of the new isolates were closely related, while the fourth was only moderately related to the other three. Sequence signature and higher-order structural detail analyses of the 16S rRNA of strain IFAM 1418T (T = type strain) indicated that this isolate is related to the alpha subclass of the class Proteobacteria. Although our isolates resemble members of the genera Hyphomicrobium and Hyphomonas in morphology, assignment to either of these genera was excluded on the basis of their markedly lower DNA guanine-plus-cytosine contents. We propose that these organisms should be placed in a new genus, Hirschia baltica is the type species of this genus, and the type strain of H. baltica is strain IFAM 1418 (= DSM 5838).     

Three new anascosporic genera of the Saccharomycotina: Danielozyma gen. nov., Deakozyma gen. nov. and Middelhovenomyces gen. nov

Three new non-ascosporic, ascomycetous yeast genera are proposed based on their isolation from currently described species and genera. Phylogenetic placement of the genera was determined from analysis of nuclear gene sequences for D1/D2 large subunit rRNA, small subunit rRNA, translation elongation factor-1α and RNA polymerase II, subunits B1 and B2. The new taxa are: Deakozyma gen. nov., type species Deakozyma indianensis sp. nov. (type strain NRRL YB-1937, CBS 12903); Danielozyma gen. nov., type species Danielozyma ontarioensis comb. nov. (type strain NRRL YB-1246, CBS 8502); D. litseae comb. nov. (type strain NRRL YB-3246, CBS 8799); Middelhovenomyces gen. nov., type species Middelhovenomyces tepae comb. nov. (type strain NRRL Y-17670, CBS 5115) and M. petrohuensis comb. nov. (type strain NRRL Y-17663, CBS 8173).     

Prescottia equi gen. nov., comb. nov.: a new home for an old pathogen

The taxonomic status of Rhodococcus equi, originally isolated from foal specimens, has been the subject of discussion for a number of years. The chequered history of the taxon has prompted this polyphasic analysis of R. equi strains, close members of the genus Rhodococcus and representatives of other genera classified in the order Corynebacteriales, to establish the taxonomic position of this taxon. Thirty one R. equi strains, including the type strain, were examined for genotypic and numerical taxonomic properties. The resultant data are consistent with their classification in the order Corynebacteriales but the R. equi strains formed a distinct phyletic clade away from representatives of other members of the genus Rhodococcus in the 16S rRNA gene tree. Representatives of this clade shared their highest pairwise 16S rRNA gene sequence similarities with the type strain of Rhodococcus kunmingensis (95.2–98.1 %). However, the R. equi taxon was readily distinguished from R. kunmingensis and from the other members of the order Corynebacteriales using a combination of genotypic, chemotypic and phenotypic properties. On the basis of these data the R. equi strains are considered to represent a new genus. The name proposed for this taxon is Prescottia gen. nov., with Prescottia equi comb. nov. as the type species containing the type strain, C 7^T (= ATCC 25729^T = ATCC 6939^T = CCUG 892^T = CIP 54.72^T = DSM 20307^T = HAMBI 2061^T = NBRC 14956^T = JCM 1311^T = JCM 3209^T = LMG 18452^T = NBRC 101255^T = NCTC 1621^T = NRRL B-16538^T = VKM Ac-953^T).     

Morphology and phylogeny reveal a novel hydnoid taxon from India: Mycorrhaphoides stalpersii gen. and sp. nov

Mycorrhaphoides gen. nov. and Mycorrhaphoides stalpersii sp. nov. are described and defined based on morphological details and phylogenetic inference of a hydnoid macrofungus collected in Acharya Jagadish Chandra Bose Indian Botanic Garden, Howrah (India). It is characterized by stipitate basidiomata with duplex context in stipe, presence of multi‐clamped septa, and smooth and hyaline cystidia.     

A new nitrogen-fixing bacterium: Derxia gummosa nov. gen. nov. spec.

Summary A vigorously nitrogen-fixing bacterium was isolated from a West Bengal soil. Cells from young cultures on nitrogen-deficient agar medium appear as rods measuring approx. 3–6x1.0–1.2 ., with rounded ends and homogeneous cytoplasm. Older cells contain big refractile bodies representing vacuoles and fat deposits and show a wide variation in shape. Short motile cells with a single polar flagellum arise in liquid medium with combined (ammonia) nitrogen. The Gram reation is negative and endospores are not formed.The organism is aerobic but catalase-negative. It grows rather feebly in sugar-free protein media, but in nitrogen-deficient media it produces ah heavy and extremely tenacious growth, of a characteristic uneven appearance on agar and changing from white to dark red-brown. Glucose, fructose, ethanol, glycerol, mannitol and sorbitol are the best sources of carbon. Acid but no gas is formed from several carbohydrates. Nitrogen fixation is slow but may amount to 20–25 mg. per gram glucose or mannitol supplied. Molybdenum stimulates nitrogen fixation strongly and cannot be replaced by vanadium.Various forms of combined nitrogen, especially glutamic acid, are assimilated more readily than free nitrogen. Growth can be initiated within aPh-interval from approx. 5 to 9; growing cultures may be acidified to Ph 4.5 or less.The organism is morphologically, culturally and serologically different from Azotobacter and Beijerinckia and is regarded as representing a new genus.     

Macrochaete gen. nov. (Nostocales,Cyanobacteria), a taxon morphologically and molecularly distinct from Calothrix

Historically, the genus Calothrix included all noncolonial, tapered, heterocytous filaments within the cyanobacteria. However, recent molecular phylogenies show that “Calothrix” defined in this sense represents five distinct clades. The type species of Calothrix is marine, with solitary basal heterocytes, no akinetes, and distal ends tapering abruptly into short hairs. We examined the morphology and phylogeny of 45 tapering cyanobacteria in the Rivulariaceae, including freshwater and marine representatives of both Calothrix (35 strains) and its sister taxon Rivularia (10 strains). The marine Calothrix fall into two lineages, but we lack the generitype and so cannot identify the clade corresponding to the type species. The freshwater and soil Calothrix fall into the C. parietina clade and are characterized by having a basal heterocyte, no akinetes, and gradual tapering—but not into a long hyaline hair. Macrochaete gen. nov. is a freshwater taxon sister to the Calothrix lineages but clearly separated from Rivularia. The species in this genus differ morphologically from Calothrix by their ability to produce two heteromorphic basal heterocytes and specific secondary structures of the 16S–23S ITS. An additional feature present in most species is the presence of a distal, long hyaline hair, but this character has incomplete penetrance due to its expression only under specific environmental conditions (low phosphate), and in one species appears to be lost. We recognize three species: M. psychrophila (type species) from cold environments (high mountains, Antarctica), M. santannae from wet walls of subtropical South America, and M. lichenoides, a phycobiont of lichens from Europe.     

Amphirosellinia gen. nov. and a new species of Entoleuca

The new genus Amphirosellinia is erected to include five xylariaceous fungi with erumpent or immersed perithecioid stromata. Amphirosellinia fushanensis, A. nigrospora and A. tennesseensis are newly described, whereas A. evansii and A. quercina are new combinations. Synnematous, geniculosporium-like anamorphs are known for A. fushanensis, A. nigrospora, A. tennesseensis and A. evansii; the anamorph of the latter species was produced on natural substratum, whereas those of the former three species were produced in culture. Dichotomous keys are presented for the Amphirosellinia species and for some genera that might be confused with Amphirosellinia. Entoleuca ellisii also is described as new. It readily can be separated from the known species in the genus by its smaller ascospore size range and short ascospore germ slit.     

Methanothrix soehngenii gen. nov. sp. nov., a new acetotrophic non-hydrogen-oxidizing methane bacterium

A new genus of methanogenic bacteria is described, which was isolated from a mesophilic sewage digester. It is most probably the filamentous bacterium, earlier referred to asMethanobacterium soehngenii, fat rod or acetate organism. The single non-motile, non-sporeforming cells are rod-shaped (0.8×2 m) and are normally combined end to end in long filaments, surrounded by a sheath-like structure. The filaments form characteristic bundles.Methanothrix soehngenii decarboxylates acetate, yielding methane and carbon dioxide. Other methanogenic substrates (H₂–CO₂, formate, methanol, methylamines) are not used for growth or methane formation. Formate is split into hydrogen and carbon dioxide. The temperature optimum for growth and methane formation is 37°C and the optimal pH range is 7.4–7.8. Sulfide and ammonia serve as sulfur and nitrogen source respectively. Oxygen completely inhibits growth and methane formation, but the bacteria do not loose their viability when exposed to high oxygen concentrations. 100 mg/l vancomycin showed no inhibition of growth and methanogenesis. No growth and methane formation was observed in the presence of: 2-bromoethanesulfonic acid, viologen dyes, chloroform, and KCN. The bacterium has a growth yield on acetate of 1.1–1.4 g biomass per mol acetate. The apparent K _S of the acetate conversion system to methane and carbon dioxide is 0.7 mmol/l. The DNA base composition is 51.9 mol% guanine plus cytosine. The nameMethanothrix is proposed for this new genus of filamentous methane bacterium. The type species,Methanothrix soehngenii sp. nov., is named in honor of N. L. Söhngen.     

Thermohydrogenium kirishiense gen. nov. and sp. nov., a new anaerobic thermophilic bacterium

Six strains of a new anaerobic thermophilic non-sporeforming bacterium were isolated in pure culture from industrial yeast biomass. Cells were rod-shaped (0.4–0.8×1.0–11.0 m), non-motile. They stained gram-negative, but outer membrane was not present. The growth occurred between 45–75 °C, the optimal temperature is 65°. Optimal pH value was 7.0–7.4. The bacterium utilized for growth several sugars, starch and yeast extract. The best source of nitrogen was peptone. The main fermentation products of glucose were ethanol, acetate, H₂ and CO₂. As minor products isopropanol, butanol, butyrate and lactate were found. Glucose was metabolized via the Embden-Meyerhoff pathway. Cytochromes and quinones were not found. DNA-base composition was 33.2–34.0 mol%. The DNA-DNA hybridization and 5S rRNA nucleotide sequences showed distantly related of isolated stains to phenotypical similar bacteria. It was proposed to consider the isolated bacterium as Thermohydrogenium kirishiense gen. nov. and sp. nov.     

Barbatosphaeria gen. et comb. nov., a new genus for Calosphaeria barbirostris

The new genus Barbatosphaeria is described for a perithecial ascomycete known as Calosphaeria barbirostris occurring on decayed wood of deciduous trees under the periderm. The fungus produces nonstromatic perithecia with hyaline, 1-septate ascospores formed in unitunicate, nonamyloid asci. Anamorphs produced in vitro belong to Sporothrix and Ramichloridium with holoblastic-denticulate conidiogenesis; conidiophores of the two types were formed in succession during the development of the colony. Phylogenetic analyses of nuLSU rDNA sequences indicate that this fungus is distinct from morphologically similar Lentomitella, tentatively placed in the Trichosphaeriales. It groups with freshwater Aquaticola and Cataractispora and terrestrial Cryptadelphia in maximum parsimony analysis; the same grouping but without Cryptadelphia was inferred from Bayesian analysis. Cultivation, morphology and phylogenetic studies of the nuLSU rDNA support the erection of a new genus for C. barbirostris.     

Desulfurella acetivorans gen. nov. and sp. nov. —a new thermophilic sulfur-reducing eubacterium

A new type of thermophilic cyanobacterial mat, rich in elemental sulfur and containing large numbers of sulfur-reducing bacteria able to utilize different growth substrates at 55° C, was found in the Uzon caldere (Kamchatka). One of the largest groups among these organisms were acetate-oxidizing sulfur-reducing bacteria, numbering 10⁶ cells · cm^–3 of mat. The pure culture of a sulfur-reducing eubacterium growing on acetate was isolated. Cells of the new isolate are Gram-negative short rods, often in pairs, motile, with a single polar flagellum. The optimal temperature for growth is 52 to 57° C, with no growth observed at 42 or 73° C. The pH optimum is 6.8 to 7.0. The new isolate is demonstrated to be a true dissimilatory sulfur reducer: it is an obligate anaerobe, it is unable to ferment organic substrates and it can use no electron acceptors other than elemental sulfur. Acetate is the only energy and carbon source, and H₂S and CO₂ are growth products. No cytochromes were detected. The G+C content of DNA is rather low, only 31.4 mol%. Thus, morphological and physiological features of the new isolate are quite close to those of Desulfuromonas. But on the grounds of a significant difference in the G+C content of DNA, the absence of cytochromes and because of its thermophilic nature, a new genus Desulfurella is proposed with the type species Desulfurella acetivorans.     

A new genus, Helgoeca gen. nov., for a nudiform choanoflagellate

A new genus, Helgoeca gen. nov., has been designated to accommodate a nudiform loricate choanoflagellate (American Type Culture Collection strain ATCC 50073) that was incorrectly attributed to the tectiform genus Acanthoecopsis (=Acanthocorbis). The first indication that this species might be nudiform came from a four-gene phylogeny of the choanoflagellates which recovered ATCC 50073 within a strongly supported monophyletic clade comprising two other nudiform taxa. Fortunately an isolate of the species in question was available from the ATCC and when observed in rapidly growing culture it was immediately apparent that this species divided with the production of 'naked' motile cells; a typically nudiform character. The beaker-shaped lorica of this species consists of an outer layer of approximately 11 longitudinal costae, which terminate anteriorly as spines, and an equal or larger number of helical costae, with a left-handed conformation, each of which terminates anteriorly adjacent to the base of a spine. The pattern of costae in this species is indistinguishable from that of Acanthocorbis nana Thomsen and for this reason A. nana has been transferred to the new genus Helgoeca gen. nov., as the type species.     

Aplanochytrium kerguelensis gen. nov. spec. nov., a new phycomycete from subantarctic marine waters

Summary A new monocentric marine fungus,Aplanochytrium kerguelensis gen. nov. spec. nov., was recovered from water samples taken in the vicinity of the Kerguelen Islands in the South Indian Ocean during a cruise of the research vessel USNS Eltanin.Aplanochytrium is very similar toThraustochytrium Sparrow (1936) in having a chytrid-like thallus and in being able to utilize pine pollen as a substrate to which it establishes contact by well-developed rhizoids. At maturity, however, only aplanospores are formed, as inDermocystidium sensu Goldstein and Moriber (1966).     

A new genus of theActinoplanaceae: Dactylosporangium,gen. nov.

Summary Two aerobic mesophilic species of a new genus belonging to the familyActinoplanaceae are described under the nameDactylosporangium (D. aurantiacum strainD/748 type species andD. thailandensis strainD/449). The new genus is characterized by the production of finger shaped sporangia emerging directly from the vegetative mycelium.The motile sporangiospores, three to four in number are arranged in a single straight row inside the sporangium.The genusActinoplanes of the familyActinoplanaceae was described in 1950 byCouch and is characterized by the bacteria-like, flagellated spores formed in sporangia. Other members of the familyActinoplanaceae have been studied byKarling (1954),Rothwell (1957) andCross et al. (1963) in the United States, byGaertner (1955) in Germany, byVan Brummelen andWent (1957) in Holland, byNonomura andOhara (1960) in Japan, byTaig et al. (1962),Tsyganov et al. (1963), andKoniev et al. (1965) in Russia. Except for the organisms studied byKarling and byRothwell, which undoubtedly belonged to theActinoplanes but were not studied in pure culture, the organisms studied by most of the other authors belonged to the genusStreptosporangium.Three new genera having motile spores were described more recently:Ampullariella andSpirillospora described byCouch (1963, 1964), andPlanomonospora byThiemann et al. (1967b).     

Yokenella regensburgei gen. nov., sp. nov.: a new genus and species in the family Enterobacteriaceae

The name Yokenella gen. nov. is proposed for a group of organisms in the family Enterobacteriaceae isolated from clinical sources and insects. Yokenella is a gram-negative, oxidase-negative, fermentative, motile rod possessing the characteristics of the family Enterobacteriaceae and the guanine plus cytosine contents of the DNA range from 58.0 to 59.3 mol%. Biochemical characteristics of this group and DNA hybridization studies indicate that the 11 strains studied here comprise a separate species which should be best placed in a new genus. This single DNA hybridization group is named Yokenella regensburgei sp. nov. The type strain of Y. regensburgei is NIH 725-83 (JCM 2403).     

Elainella gen. nov.: a new tropical cyanobacterium characterized using a complex genomic approach

Cyanobacteria represent an ancient, monophyletic lineage of bacteria with the ability to undertake oxygenic photosynthesis. Although they possess a relatively high degree of morphological variability compared with other prokaryotes and there is a wealth of molecular data, there are still significant gaps in our knowledge of cyanobacterial diversity, especially in tropical areas. Here, we present a novel, filamentous, tropical cyanobacterium, which could be classified as Pseudophormidium based on morphological criteria. A total evidence investigation employing ecological, morphological and genomic data, indicated that our strains form a new and ancient evolutionary lineage among cyanobacteria unrelated to Pseudophormidium. Based on this polyphasic assessment, our strains represent a novel, monospecific genus: Elainella. This new genus represents an example of phenotypic convergence, which seems to be a prevalent macroevolutionary pattern in cyanobacteria, a likely cause of the frequently cited polyphyly within a majority of genera.     

Wangella harbinensis gen. nov., sp. nov., a new member of the family Micromonosporaceae

A novel endophytic actinomycete, designated strain NEAU-J3^T, was isolated from soybean root (Glycine max (L.) Merr) and characterized using a polyphasic approach. Phylogenetic analysis based on 16S rRNA gene sequences suggested that strain NEAU-J3^T fell within the family Micromonosporaceae. The strain was observed to form an extensively branched substrate mycelium, which carried non-motile oval spores with a smooth surface. The cell walls of strain NEAU-J3^T were determined to contain meso-diaminopimelic acid and galactose, ribose and glucose were detected as whole-cell sugars. The major menaquinones were determined to be MK-9(H₄) and MK-9(H₆). The phospholipids detected were phosphatidylcholine and phosphatidylethanolamine. The major cellular fatty acids were determined to be C_16:0, C_18:1 ω9c, C_18:0, C_17:0, C_17:1 ω7c, anteiso-C_17:0, C_16:1 ω7c and C_15:0. The DNA G + C content was 62.5 mol%. On the basis of the morphological and chemotaxonomic characteristics, phylogenetic analysis and characteristic patterns of 16S rRNA gene signature nucleotides, strain NEAU-J3^T is considered to represent a novel species of a new genus within the family Micromonosporaceae, for which the name Wangella harbinensis gen. nov., sp. nov. is proposed. The type strain of Wangella harbinensis is strain NEAU-J3^T (=CGMCC 4.7039^T = DSM 45747^T).