Phototrophic utilization of taurine by the purple nonsulfur bacteria Rhodopseudomonas palustris and Rhodobacter sphaeroides.

Taurine metabolism by two phototrophically grown purple nonsulfur bacteria enrichment isolates has been examined. Rhodopseudomonas palustris (strain Tau1) grows with taurine as a sole electron donor, sulfur and nitrogen source during photoautotrophic growth. Rhodobacter sphaeroides (strain Tau3) grows on the compound as sole electron donor, sulfur and nitrogen source, and partial carbon source, in the presence of CO(2) during photoheterotrophic growth.

Sulfoacetaldehyde bisulfite adduct is a substrate for enzymes presumed to act on sulfoacetaldehyde.

Sulfoacetaldehyde, an intermediate of interest to those studying microbial metabolism of sulfonates, is commonly synthesized as the bisulfite adduct. A published method presumed to convert this to the free aldehyde (and cited several times elsewhere in the literature) has been shown to be ineffective; this had not been realized by its users because the enzymes under study recognize the adduct as a substrate.

Sulfonates as terminal electron acceptors for growth of sulfite-reducing bacteria (Desulfitobacterium spp.) and sulfate-reducing bacteria: effects of inhibitors of sulfidogenesis.

This study demonstrates the ability of Desulfitobacterium spp. to utilize aliphatic sulfonates as terminal electron acceptors (TEA) for growth. Isethionate (2-hydroxyethanesulfonate) reduction by Desulfitobacterium hafniense resulted in acetate as well as sulfide accumulation in accordance with the expectation that the carbon portion of isethionate was oxidized to acetate and the sulfur was reduced to sulfide.

Sulfidogenesis from 2-aminoethanesulfonate (taurine) fermentation by a morphologically unusual sulfate-reducing bacterium, Desulforhopalus singaporensis sp. nov.

A pure culture of an obligately anaerobic marine bacterium was obtained from an anaerobic enrichment culture in which taurine (2-aminoethanesulfonate) was the sole source of carbon, energy, and nitrogen. Taurine fermentation resulted in acetate, ammonia, and sulfide as end products. Other sulfonates, including 2-hydroxyethanesulfonate (isethionate) and cysteate (alanine-3-sulfonate), were not fermented.

Acetate acts as a protonophore and differentially affects bead movement and cell migration of the gliding bacterium Cytophaga johnsonae (Flavobacterium johnsoniae).

Cells of Cytophaga johnsonae (now Flavobacterium johnsoniae) are able to translocate on solid surfaces but are unable to swim in liquid media. Organelles that may be involved in this gliding motility have not been detected, and the mechanism(s) responsible remains unknown. The movement of latex beads attached to the cell surface is considered by some to be a manifestation of the gliding machinery.

Taurine-sulfur assimilation and taurine-pyruvate aminotransferase activity in anaerobic bacteria.

We demonstrated the ability of strictly fermentative, as well as facultatively fermentative, bacteria to assimilate sulfonate sulfur for growth. Taurine (2-aminoethanesulfonate) can be utilized by Clostridium pasteurianum C1 but does not support fermentative growth of two Klebsiella spp. and two different Clostridium spp.

Sulfonates: novel electron acceptors in anaerobic respiration.

The enrichment and isolation in pure culture of a bacterium, identified as a strain of Desulfovibrio, able to release and reduce the sulfur of isethionate (2-hydroxyethanesulfonate) and other sulfonates to support anaerobic respiratory growth, is described. The sulfonate moiety was the source of sulfur that served as the terminal electron acceptor, while the carbon skeleton of isethionate functioned as an accessory electron donor for the reduction of sulfite. Cysteate (alanine-3-sulfonate) and sulfoacetaldehyde (acetaldehyde-2-sulfonate) could also be used for anaerobic respiration, but many other sulfonates could not.

Sulfonate-sulfur utilization involves a portion of the assimilatory sulfate reduction pathway in Escherichia coli.

Strains of Escherichia coli lacking serine transacetylase or a positive regulator (Cys B protein) of the assimilatory sulfate reduction (ASR) pathway were unable to assimilate sulfonate-S, while single mutants in O-acetyl-L-serine sulfhydrylase (either 'A' or 'B') were able to do so. Mutants unable to reduce sulfate to sulfite were nonetheless able to form and accumulate sulfide and then cysteine from sulfonates, while strains lacking sulfite reductase were not. Thus terminal portions of the ASR pathway are involved in reduction of sulfonate-S to that of cysteine.

Comparative aspects of utilization of sulfonate and other sulfur sources by Escherichia coli K12.

Selected biochemical features of sulfonate assimilation in Escherichia coli K-12 were studied in detail. Competition between sulfonate-sulfur and sulfur sources with different oxidation states, such as cysteine, sulfite and sulfate, was examined. The ability of the enzyme sulfite reductase to attack the C-S linkage of sulfonates was directly examined.

Sulfonate-sulfur assimilation by yeasts resembles that of bacteria.

Three sulfonates were tested for their ability to serve as nutrients for Hansenula wingei, Rhodotorula glutinis, Trigonopsis variabilis and Saccharomyces cerevisiae. Cysteate, taurine and isethionate, under aerobic conditions, could be utilized as sources of sulfur, although in some instances final cell yields were less than those obtained with an equimolar amount of sulfate-sulfur. Sulfonate assimilation by S.

Sulphonate utilization by enteric bacteria.

A variety of sulphonates were tested for their ability to serve as nutrients for Escherichia coli, Enterobacter aerogenes and Serratia marcescens. Cysteate, taurine and isethionate could not serve as sole sources of carbon and energy but, under aerobic conditions, could be utilized as sources of sulphur. Both sulphate and sulphonate supported equivalent cell yields, but the generation times varied with the sulphonate being metabolized.

Defects in gliding motility in mutants of Cytophaga johnsonae lacking a high-molecular-weight cell surface polysaccharide.

We previously observed (W. Godchaux, L. Gorski, and E.

Temporal sequence of the recovery of traits during phenotypic curing of a Cytophaga johnsonae motility mutant.

The lack of cell translocation and the resulting formation of nonspreading colonies of mutants of the gram-negative gliding bacterium Cytophaga johnsonae have been correlated with the loss of cell surface features of the organism. These cell surface traits include the ability to move polystyrene-latex beads over the cell surface and the ability to be infected by bacteriophages that infect the parent strain. In order to assess whether these traits reflect structures or functions that actually play a role in gliding, we studied a mutant (21A2I) selected for its inability to form spreading colonies; it is deficient in sulfonolipid, lacks bead movement ability, and is resistant to at least one bacteriophage.

Outer membrane polysaccharide deficiency in two nongliding mutants of Cytophaga johnsonae.

Phenol-extractable polysaccharides firmly associated with the outer membrane of the gliding bacterium Cytophaga johnsonae could be resolved by gel filtration in sodium dodecyl sulfate (SDS) or by SDS-polyacrylamide gel electrophoresis into a high-molecular-weight (H) fraction (excluded by Sephadex G-200) and a low-molecular-weight (L) fraction. Fraction L was rich in components typical of lipid A and the core region of lipopolysaccharide (P, 3-hydroxy fatty acids, and 2-keto-3-deoxyoctonate) and evidently was a lipopolysaccharide with a limited number of distal, repeating polysaccharide units, as judged by SDS-polyacrylamide gel electrophoresis. In relation to total carbohydrate, the H fraction was rich in amino sugar but poor in (possibly devoid of) the lipid A and core components.

Cysteine is not an obligatory intermediate in the biosynthesis of cysteate by Cytophaga johnsonae.

A cysteine auxotroph of Cytophaga johnsonae was able to incorporate sulfur from sulfate into cysteate, and thus into sulfonolipid, in the absence of cysteine synthesis. This indicates that cysteine is not an obligatory intermediate of the cysteate biosynthetic pathway even though cysteine sulfur can be utilized for cysteate synthesis.

Increase of ornithine amino lipid content in a sulfonolipid-deficient mutant of Cytophaga johnsonae.

The gram-negative gliding bacterium Cytophaga johnsonae contains not only large quantities of unusual sulfonolipids but also, as we report here, a second class of unusual lipids. These lipids were detected and quantified by two-dimensional thin-layer chromatography of lipids from cells grown in the presence of [14C]acetate and shown by chemical studies to be alpha-N-(3-fatty acyloxy fatty acyl)ornithines. Like the sulfonolipids, these ornithine lipids were localized in the outer membrane (whereas phosphatidylethanolamine was the predominant lipid of the inner membrane).

Cell wall and lipid composition of Isosphaera pallida, a budding eubacterium from hot springs.

Isosphaera pallida is an unusual gliding, budding eubacterium recently isolated from North American hot springs. Electron micrographs of ultrathin sections revealed a cell wall atypical of eubacteria: two electrondense layers separated by an electron-transparent layer, with no evident peptidoglycan layer. Growth was not inhibited by penicillin.

Isolation and characterization of nucleoprotein assembly intermediates of tobacco mosaic virus.

During assembly of tobacco mosaic virus from pure RNA and 20S capsid protein aggregates under conditions where protein is limiting, partially assembled intermediates of specific sizes accumulate; these were isolated on sucrose density gradients. The earliest intermediate found in substantial quantity sedimented at 56 S and was shown, by measurement of its buoyant density and of the length of the RNA segment protected by the capsid protein from nuclease digestion, to consist of RNA that is 13% encapsidated (corresponding to a rod length of about 39 nm); the next intermediate sediments at 78 S and is 18% encapsidated (corresponding to a rod length of about 54 nm). Studies of the distribution of intermediates at various input ratios of protein/RNA indicated that their accumulation results from decreases in the rate constants for protein binding that are local to specific points in the course of encapsidation.

Biosynthesis of a sulfonolipid in gliding bacteria.

Gliding bacteria of the genus Cytophaga synthesize sulfonolipids (1,2) that contain capnine (1-deoxy-15-methylhexadecasphinganine-1-sulfonic acid). Studies of the incorporation of radiolabeled compounds by C. johnsonae show that cysteate is utilized preferentially to both cystine and inorganic sulfate as a precursor of capnine sulfur and to both cystine and serine as a precursor of carbons 1 and 2 of capnine.

Sulfonolipids of gliding bacteria. Structure of the N-acylaminosulfonates.

Earlier (Godchaux, W., and Leadbetter, E. R.

Unusual sulfonolipids are characteristic of the Cytophaga-Flexibacter group.

Capnocytophaga spp. contain a group of unusual sulfonolipids, called capnoids (W. Godchaux III and E.

The relative proportions of lysosomal enzyme activities in bovine retinal pigment epithelium.

The lysosome fractions from bovine retina, liver and retinal pigment epithelium were isolated by subcellular fractionation and compared with regard to the relative proportions of several hydrolytic enzyme activities. It was found that the lysosome fraction of the retinal pigment epithelium is more than three times as active as the lysosome fractions from other tissues in degrading the rhodopsin of photoreceptor (rod) cell outer segments. This proteolytic activity is attributable to a cathepsin D-like proteinase, and the possible biochemical bases for its increased activity in the pigment epithelium are discussed, including interaction with phospholipase A.