Lipid composition of Cunninghamella elegans cultivated on n-alkanes]

The ability to oxidize n-alkanes was studied with various species of fungi belonging to the Cunninghamella genus. These fungi are able to assimilate hydrocarbons and to accumulate up to 1.5 g/litre of biomass. The most active strain was Cunninghamella elegans (-) 1204. The amount of lipids formed, and their composition, depended on the length of the carbon chain of oxidized alkane. The content of fat in the cells increased with the length of the hydrocarbon chain. The following lipid fractions have been detected: phospholipids, monoglycerides, diglycerides, triglycerides, sterols, free fatty acids, sterol esters, and hydrocarbons. The qualitative composition of the fractions depended, to a considerable extent, on the n-alkane utilized. Investigation of the fatty-acid composition of intracellular lipids has shown that fatty acids with an even number of carbon atoms are formed from hydrocarbons with an even number of these atoms, while fatty acids both with an even and odd number of carbon atoms are synthesized from hydrocarbons with an odd number of these atoms. The relative content of the acids with the same number of carbon atoms as that of the alkane being utilized increased with the length of the carbon chain.     

The screening of microorganisms for hydroxylation activity: Hydroxylation of diamantanols

Summary 1-and/or 4-diamantanols are hydroxylated by various species of the genus Rhizopus giving rise to diamantandiols. The GLC method revealed both the species specificity of the organism and substrate specificity in the bioconversion. The effectivity of biotransformation by some species of the genus Rhizopus indicates that the procedure could be used for the preparation of some diamantandiols substituted on tertiary carbon atoms.     

The fatty acid composition of Haemophilus and Pasteurella multocida cells as a phylogenetic marker

When grown on meat-peptone agar with heated blood, different Haemophilus species (H. influenzae, H. parahaemolyticus, H. parasuis, H. pleuropneumoniae), including different H. influenzae serovars (a, b, c, d, e, f), and Pasteurella multocida have identical fatty acid composition, characterized by the prevalence of fatty acids with 16 carbon atoms, constituting about 70% and more of the total number of fatty acids, and a low level of fatty acids with 18 carbon atoms. P. multocida strains cultivated on meat-peptone agar with unheated blood have a greatly increased content of fatty acids with 18 carbon atoms, while the content of fatty acids with 16 carbon atoms is much lower. The identity of fatty acid composition under similar cultivation conditions, together with their similarity in other phenetic signs, is indicative of close phylogenic relationship between bacteria belonging to the genus Haemophilus and P. multocida.     

Taxonomic value of the property of fungi to assimilate hydrocarbons

A wide range of fungi were tested for their ability to assimilate a series of hydrocarbons, which includedn-paraffins, aromatic hydrocarbons and petroleum fractions.The property is not evenly distributed among the various fungal classes, but is to be found mainly in two orders, the Mucorales and the Moniliales. Within the latter order, the generaAspergillus andPenicillium are rich in hydrocarbon-assimilating strains. In other genera, the property of assimilating hydrocarbons is relatively rare.Hydrocarbon assimilation is not necessarily common to related species, nor proper to one species, but more the property of individual strains. Different strains belonging to the same species differ in metabolic activity when they are tested against a series of hydrocarbons. The property of assimilating hydrocarbons appears to lack taxonomic value. Species of the same genus show only a tendency to behave in a similar way, e.g.Penicillium strains usually assimilaten-decane and light gas oil whereasAspergillus strains seldom do so. Aspergillus species sporulate better on long chainn-paraffins. On some hydrocarbons, they develop particular pigments. n-Paraffins with at least ten carbon atoms support better growth than petroleum fractions. Individual strains are very sensitive to minor changes in hydrocarbon composition or structure. Only sparse delayed growth is observed on aromatic hydrocarbons.n-Heptane, petroleum ether, naphtha and kerosene are often toxic whereas aromatic hydrocarbons are usually non-toxic.     

Use of bacteria of the genus Azotobacter for biodegradation of oil-contaminated soils

The rate of self-purification of oil-contaminated soil increases after introduction of bacteria of the genus Azotobacter. The bacteria can assimilate oil hydrocarbons as the sole source of carbon and energy, both in the presence of fixed nitrogen and during nitrogen fixation. The species Azotobacter chroococcum activates growth of hydrocarbon-oxidizing bacteria present in Devoroil.     

Ambrosiozyma kamigamensis sp. nov. and A. neoplatypodis sp. nov., two new ascomycetous yeasts from ambrosia beetle galleries

Two new yeast species of the genus Ambrosiozyma are described on the basis of comparison of nucleotide sequences of large subunit of ribosomal DNA D1/D2 region. Ambrosiozyma kamigamensis and Ambrosiozyma neoplatypodis differ from Ambrosiozyma ambrosiae by 17 nucleotides (3.0%) and 16 nucleotides (2.8%), respectively, out of 565. The two species differ from each other by 13 nucleotides. Ambrosiozyma kamigamensis was isolated from galleries of the ambrosia beetle, Platypus quercivorus, in specimens of Quercus laurifolia and Castanopsis cuspidata located in the southern part of Kyoto, Japan. Ambrosiozyma neoplatypodis was isolated from similar material, but only in Q. laurifolia. Ambrosiozyma kamigamensis can be distinguished from the other Ambrosiozyma species by the inability to assimilate erythritol, whereas A. neoplatypodis can be distinguished by the ability to assimilate both L: -arabinose and nitrate. The type strains of A. kamigamensis and A. neoplatypodis are JCM 14990(T) (=CBS 10899(T)) and JCM 14992(T) (=CBS 10900(T)), respectively. This is the first report of new Ambrosiozyma species since the genus was proposed.     

The significance of hydrocarbon assimilation in yeast identification

A large number of yeasts were screened for the ability to assimilate hydrocarbons. Not only representatives of the genusCandida, but also species from other perfect and imperfect genera are able to usen-alkanes as sole carbon and energy source. The significance of this feature in yeast systematics is discussed. In general, all strains of a species share either the ability to assimilate hydrocarbons or the failure to do so. Exceptions are found in species regarded as heterogeneous, likeCandida sake, Candida diddensii andCandida zeylanoides. In cases where the usual criteria used in identification seem to be inadequate, the simple hydrocarbon assimilation test may be useful. Also in subgrouping the generaCandida andTorulopsis the test may be of value, because some perfect genera likeHansenula, Kluyveromyces andSaccharomyces lack hydrocarbon-assimilating representatives.     

Identification of a unicellular,non-pigmented alga that mediates growth inhibition in anuran tadpoles: a new species of the genus Prototheca (Chlorophyceae: Chlorococcales)

A non-pigmented, unicellular alga isolated from the faeces of British anuran tadpoles and which is associated with growth inhibition in these tadpoles, was described and identified using cytological, ultrastructural, nutrient assimilation and immunological studies. The alga possessed all the distinctive morphological features of the genus Prototheca, it grew weakly on Prototheca Isolation Medium (PIM), it required thiamine for continued growth and replication, and it could assimilate the five major substrates used to speciate the protothecans. All of these characteristics, together with previous nucleic acid hybridisation studies, indicated that the microorganism belonged to the genus Prototheca. There are currently five species recognised as valid (Pore, 1985 & 1986): Prototheca zopfii Kruger, 1884, P. wickerhamii Tubaki & Soneda, 1959, P. moriformis Kruger, 1884, P. stagnora Cooke, 1968 and P. ulmea Pore, 1986.The immunology showed that the new species was related to two of the protothecans, but overall it showed that the alga was antigenically distinct from the other protothecans tested in the immunoassay. This, together with its inability to grow strongly on PIM, its ability to assimilate a wide rage of carbon substrates and its ability to mediate growth inhibition in anuran tadpoles, indicated a new species of Prototheca. We therefore propose the name Prototheca richardsi sp. n.     

Microorganisms that break down alkyl sulfates

The following bacteria assimilating alkyl sulphates as a sole source of carbon and energy were isolated from various substrates: Pseudomonas, Achromobacter, Flavobacterium, Citrobacter, Enterobacter. The bacteria decomposed sodium dodecyl sulphate at a high rate, and some of them, industrial preparations of alkyl sulphates. The ability to assimilate alkyl sulphates was tested in 257 collection cultures belonging to different taxonomic groups. Alkyl sulphates were found to be decomposed by heterotrophous gram-negative rod-like bacteria belonging to different families and genera. The frequency of bacteria destroying alkyl sulphates at a high rate was found most often in the Pseudomonas genus.     

Use of Bacteria of the Genus Azotobacter for Bioremediation of Oil-Contaminated Soils

The rate of self-purification of oil-contaminated soil increases after introduction of bacteria of the genus Azotobacter. The bacteria can assimilate oil hydrocarbons as the sole source of carbon and energy, both in the presence of fixed nitrogen and during nitrogen fixation. The species Azotobacter chroococcum activates growth of hydrocarbon-oxidizing bacteria present in Devoroil.     

<Emphasis Type="Italic">Rhodotorula taiwanensis</Emphasis> sp. nov., a novel yeast species from a plant in Taiwan

A novel anamorphic yeast strain, A1-01^T, belonging to the genus Rhodotorula was isolated from a plant in Taiwan and analysed morphologically, physiologically and phylogenetically. Neither ballistoconidia nor sexual reproduction was observed. Sequence analysis of the 26S rRNA gene and the ITS region indicate that Rhodosporidium sphaerocarpum is the most closely related species, with 14 and 24 nucleotide substitutions, respectively. The novel species differed physiologically from R. sphaerocarpum in its ability to assimilate ethylamine and cadaverine, its inability to assimilate ethanol and nitrite. From these comparative analyses, the following novel yeast species is proposed: Rhodotorula taiwanensis sp. nov. with the type strain of A1-01^T (BCRC 23118^T = CBS 11729^T).     

<Emphasis Type="Italic">Candida patagonica</Emphasis> sp. nov., a new species of yeast from cellar surfaces

A novel anamorphic yeast species belonging to the genus Candida has been isolated from cellar surfaces in North Patagonia. Morphological and physiological observation and phylogenetic analysis were performed. Pseudomycelium was plentifully produced. No sexual reproduction was observed. From sequence analysis of the 26S rDNA D1/D2 region, Candida bituminiphila and Zygoascus hellenicus were the closest species with 40 and 79 bp substitutions, respectively. C. bituminiphila differed physiologically from the novel species in its ability to assimilate sucrose and erythritol, in not fermenting any sugars, in growing without some vitamin compounds, and in growing at 40°C. All these data support the hypothesis that the new yeast, named Candida patagonica, is a novel species related to C. bituminiphila. The type strain is UNCOMA 159.5 (= CECT 12029 = CBS 10443).     

Complete genome sequence of Desulfarculus baarsii type strain (2st14)

Desulfarculus baarsii (Widdel 1981) Kuever et al. 2006 is the type and only species of the genus Desulfarculus, which represents the family Desulfarculaceae and the order Desulfarculales. This species is a mesophilic sulfate-reducing bacterium with the capability to oxidize acetate and fatty acids of up to 18 carbon atoms completely to CO(2). The acetyl-CoA/CODH (Wood-Ljungdahl) pathway is used by this species for the complete oxidation of carbon sources and autotrophic growth on formate. The type strain 2st14(T) was isolated from a ditch sediment collected near the University of Konstanz, Germany. This is the first completed genome sequence of a member of the order Desulfarculales. The 3,655,731 bp long single replicon genome with its 3,303 protein-coding and 52 RNA genes is a part of the Genomic Encyclopedia of Bacteria and Archaea project.     

Trichosporon mycotoxinivorans sp. nov., a new yeast species useful in biological detoxification of various mycotoxins

A yeast strain isolated from the hindgut of the lower termite Mastotermes darwiniensis (Mastotermitidae) was found to represent a new member of the genus Trichosporon. Trichosporon mycotoxinivorans is closely related to T. loubieri on the basis of the phylogenetic trees based on the D1/D2 region of 26S rDNA, an approx. 600 bp fragment of the 18S rDNA and both ITS regions. However, the two species differ at nine positions in the D1/D2 region of 26S rDNA. The IGS1 region of T. mycotoxinivorans is 401 bp long. T. mycotoxinivorans is distinguished from T. loubieri by its ability to assimilate inulin and galactitol, and its inability to grow at 40 °C. The name of this newly isolated strain refers to an important characteristics of T. mycotoxinivorans to detoxify mycotoxins such as ochratoxin A and zearalenone. Therefore this strain can be used for the deactivation of the respective mycotoxins in animal feeds.     

Complete genome sequence of the gliding, heparinolytic Pedobacter saltans type strain (113)

Pedobacter saltans Steyn et al. 1998 is one of currently 32 species in the genus Pedobacter within the family Sphingobacteriaceae. The species is of interest for its isolated location in the tree of life. Like other members of the genus P. saltans is heparinolytic. Cells of P. saltans show a peculiar gliding, dancing motility and can be distinguished from other Pedobacter strains by their ability to utilize glycerol and the inability to assimilate D-cellobiose. The genome presented here is only the second completed genome sequence of a type strain from a member of the family Sphingobacteriaceae to be published. The 4,635,236 bp long genome with its 3,854 protein-coding and 67 RNA genes consists of one chromosome, and is a part of the Genomic Encyclopedia of Bacteria and Archaea project.     

Yeast species utilizing uric acid,adenine,n-alkylamines or diamines as sole source of carbon and energy

Yeast strains utilizing uric acid, adenine, monoamines or diamines as sole source of carbon and energy were isolated from several soil samples by the enrichment culture method. The most common species wasTrichosporon cutaneum. Strains ofCandida catenulata, C. famata, C. parapsilosis, C. rugosa, Cryptococcus laurentii, Stephanoascus ciferrii andTr. adeninovorans were also isolated. All strains utilizing uric acid as sole carbon source utilized some primaryn-alkyl-l-amines hydroxyamines or diamines as well. The ascomycetous yeast strains showing these characteristics all belonged to species known to assimilate hydrocarbons. Type strains of hydrocarbon-positive yeast species which were not found in the enrichment cultures generally assimilated putrescine, some type strains also butylamine or pentylamine, but none assimilated uric acid. Methanol-positive species were not isolated. Type strains of methanol-positive and of hydrocarbon-negative species did not assimilate uric acid, butylamine or putrescine. Assimilation of putrescine as sole source of carbon and energy may be a valuable diagnostic criterion in yeast taxonomy.     

Sectoriality and physiological organisation in herbaceous plants: an overview

The physiological organisation of plants is considered in relation to the carbon economy of plant parts. Although assimilate is partitioned according to the relative strength of sinks, in many species there is also a very close relationship between partitioning and shoot phyllotaxy, giving rise to sectorial patterns of allocation whereby only certain sinks are supported by any source leaf. Essentially these sinks are in the same orthostichy as the source leaf. This constraint of the vascular architecture on assimilate distribution to developing sinks such as leaves, flowers and fruits is not always absolute, as following the loss of their principal source leaves these sinks can in many cases be supplied with assimilate by other leaves via new inter-orthostichy pathways. The supply of assimilate to major sinks such as developing fruits becomes more and more localised with time so that a fruit in an axillary position becomes largely supported by its subtending leaf; the reproductive node—a metamer-can thus be regarded as a relatively autonomous unit of the plant (an IPU). Similary, once established after a developmental phase of assimilate import, tiller ramets and branches in unitary plants tend to become physiologically autonomous modules. However, the functional autonomy of tillers is reversed following defoliation or shading as they are then sustained by the import of assimilate, subject to its availability, from unaffected tillers. Consequently the plant becomes physiologically integrated by the flow of assimilate from one part to another. The mainly autonomous ramets of many stoloniferous and rhizomatous species display a similar pattern of physiological integration in response to source manipulation, but in some species the ramets appear to maintain their independent functioning as a normal feature of the carbon allocation within the clone. In other clonal species, as the clone develops and becomes more structurally complex, vascular constraints start to restrict the movement of resources, and the clone becomes composed of a number of semi-autonomous IPUs. In unitary plants branches appear to remain very physiologically isolated in terms of their carbon economy once they become established, irrespective of a range of source-sink manipulations.These different patterns of physiological integration and organisation are discussed in relation to different strategies of assimilate utilisation and conservation.