Amino acid sequences of two ferredoxins from Phytolacca esculenta. Gene duplication and speciation

Amino acid sequences of heterotrophic and photosynthetic ferredoxins from the tomato plant (Lycopersicon esculentum Mill.)

Several forms (isoproteins) of ferredoxin in roots, leaves, and green and red pericarps in tomato plants (Lycopersicon esculentum Mill.) were earlier identified on the basis of N-terminal amino acid sequence and chromatographic behavior (Green et al. 1991). In the present study, a large scale preparation made possible determination of the full length amino acid sequence of the two ferredoxins from leaves. The ferredoxins characteristic of fruit and root were sequenced from the amino terminus to the 30th residue or beyond. The leaf ferredoxins were confirmed to be expressed in pericarp of both green and red fruit. The ferredoxins characteristic of fruit and root appeared to be restricted to those tissue. The results extend earlier findings in demonstrating that ferredoxin occurs in the major organs of the tomato plant where it appears to function irrespective of photosynthetic competence.

Genetics and molecular biology of methanotrophs

Over the last 20 years or so, the obligate methane-oxidizing bacteria (methanotrophs) have attracted considerable interest. As they grow on a relatively cheap and abundant carbon source, they appeared ideal organisms for the production of bulk chemicals, single-cell protein and for use in biotransformations. More recently their cooxidation properties have been investigated for bioremediation, including the removal of chlorinated compounds such as trichloroethylene from polluted groundwaters. These studies have resulted in a great deal of information on the physiology and biochemistry of methanotrophs but sadly the molecular biology and genetic studies of these organisms have lagged behind. This has been in part due to the obligate nature of the methanotrophs and the refractory nature of such organisms to conventional genetic analysis. However, the more recent availability of broad-host range plasmids coupled with improvements in molecular biology methods have allowed the development of molecular genetic techniques for methanotrophs. The purpose of this review is to summarize what is known about the genetics and molecular biology of methanotrophs and how this information can be used to complement previous and current biochemical studies on the unique property of these bacteria, i.e. the ability to oxidize methane to methanol. Recent developments in molecular ecology techniques that may be applied to these apparently ubiquitous organism are also considered.

The methane monooxygenase gene cluster of Methylosinus trichosporium: cloning and sequencing of the mmoC gene

Methane monooxygenase (MMO) is the enzyme responsible for the conversion of methane to methanol in methanotrophic bacteria. The soluble MMO enzyme complex from Methylosinus trichosporium also oxidizes a wide range of aliphatic and aromatic compounds in a number of potentially useful biotransformations. In this study we have used heterologous DNA probes from the type X methanotroph Methylococcus capsulatus (Bath) to isolate mmo genes from the type II methanotroph M. trichosporium. We report here that the gene encoding the reductase component, Protein C of MMO, lies adjacent to the genes encoding the other components of soluble MMO in M. trichosporium but is separated by an open reading frame of unknown function, orfY. The complete nucleotide sequence of these genes is presented. Sequence analysis of mmoC indicates that the N-terminus of Protein C has significant homology with 2Fe2S ferredoxins from a wide range of organisms.

Examination of protein sequence homologies: V. New perspectives on evolution between bacterial and chloroplast-type ferredoxins inferred from sequence evidence

Sequence homologies among 34 chloroplast-type ferredoxins were examined using a computer program that quantitatively evaluates the extent of sequence similarity as a correlation coefficient. The resultant alignment contains six gaps representing insertions or deletions of some residues, all of which are located such that they precisely preserve the domains of structural fragments as determined by crystallographic data on Spirulina platensis ferredoxin. In the search for any total correlation between the chloroplast-type and 27 bacterial ferredoxins, 1891 comparison matrices prepared for possible combinations indicated that the bacterial basal sequence of 55 residues has been conserved evolutionarily in the chloroplast-type sequences corresponding to residue positions 36-90 of Spirulina platensis ferredoxin. In addition, the bacterial "connector sequence" region was found to be conserved. These findings strongly suggest that the bacterial and chloroplast-type ferredoxins descended from a common ancestor, and branched off after the bacterial gene duplication, whereas the chloroplast-type ferredoxins originally were generated by duplicating the already duplicated bacterial gene, i.e., by "double-duplication."

The complete amino acid sequence of Nitrobacter agilis cytochrome c-550

The amino acid sequence of cytochrome c-550 from the chemoautotroph, Nitrobacter agilis, was completed by using solid-phase sequencing and conventional procedures. The cytochrome was composed of 109 amino acid residues and its molecular weight was calculated to be 12375 including haem c. The cytochrome was homologous to eukaryotic cytochromes c and some photosynthetic bacterial cytochromes c2. In particular, its primary structure was very similar to that of Rhodopseudomonas viridis cytochrome c2. Some of its properties were compared with those of other cytochromes c on the basis of the primary structure.

Purification of multiple pea ferredoxins by chromatography at high ionic strength on unsubstituted Sepharose 4B

At high concentrations of ammonium sulfate (3--4 M) pea ferredoxin (which is soluble under these conditions) can be adsorbed to Sepharose 4B, either by column chromatography or by batchwise treatment. A reverse (3 M to 1 M) ammonium sulfate gradient results in the elution of three peaks of ferredoxin. The spectral ratio A420/A280 of 0.47--0.54 indicates that each peak of ferredoxin is highly purified by this single step. A further gel filtration removes residual high molecular weight contaminants from the ferredoxin. The spectrum of the purified pea ferredoxin is typical of other plant ferredoxins in having absorbance peaks at 276 nm, 330 nm, 422 nm and 465 nm. Other chromatographic matrices are capable of adsorbing ferredoxin. Sepharose and Sephacryl wee the best adsorbents while Sephadex and cellulose adsorbed ferredoxin less tenaciously. The polyacrylamide-based resins Biogel P-4 and P-200 did not adsorb ferredoxin at high ionic strength.