A bioprocessing strategy that allows for the selection of Cr(VI)-reducing bacteria from soils

Anaerobic bacteria that reduce hexavalent chromium [Cr(VI)] to trivalent [Cr(III)] are common in soils and were used to develop a bioprocess employing a selection strategy. Indigenous Cr(VI)-reducers were enriched from Cr(VI)-contaminated soil under anaerobic conditions. The mixed culture was then tested for Cr(VI)-reducing activity in a chemostat, followed by transfer to a 1-L packed-bed bioreactor operated at 30°C for additional study. The support material used in the reactor consisted of 6-mm porcelain saddles. Cr(VI) concentrations in the liquid ranged from 140–750 mg L⁻¹. Cr(VI)-reducing bacteria were the dominant population with Cr(VI)-reduction rates of approximately 0.71 mg g⁻¹ dry cells h⁻¹ achieved at Cr(VI) concentrations of 750 mg L⁻¹. These results indicate a potential for selecting and maintaining indigenous Cr(VI)-reducers in a bioreactor for Cr(VI)-remediation of groundwater or soil wash effluents. Received 09 January 1996/ Accepted in revised form 15 November 1996     

Etioplast differentiation in arabidopsis: both PORA and PORB restore the prolamellar body and photoactive protochlorophyllide-F655 to the cop1 photomorphogenic mutant.

The etioplast plastid type of dark-grown angiosperms is defined by the accumulation of the chlorophyll (Chl) precursor protochlorophyllide (Pchlide) and the presence of the paracrystalline prolamellar body (PLB) membrane. Both features correlate with the presence of NADPH:Pchlide oxidoreductase (POR), a light-dependent enzyme that reduces photoactive Pchlide-F655 to chlorophyllide and plays a key role in chloroplast differentiation during greening. Two differentially expressed and regulated POR enzymes, PORA and PORB, have recently been discovered in angiosperms. To investigate the hypothesis that etioplast differentiation requires PORA, we have constitutively overexpressed PORA and PORB in the Arabidopsis wild type and in the constitutive photomorphogenic cop1-18 (previously det340) mutant, which is deficient in the PLB and Pchlide-F655. In both genetic backgrounds, POR overexpression increased PLB size, the ratio of Pchlide-F655 to nonphotoactive Pchl[ide]-F632, and the amount of Pchlide-F655. Dramatically, restoration of either PORA or PORB to the cop1 mutant led to the formation of etioplasts containing an extensive PLB and large amounts of photoactive Pchlide-F655.     

Organ-specific expression of highly divergent thionin variants that are distinct from the seed-specific crambin in the crucifer Crambe abyssinica

Most thionins of higher plants are toxic to various bacteria, fungi, and animal and plant cells. The only known exception is the seed-specific thionin, crambin, of the crucifer Crambe abyssinica. Crambin has no net charge, is very hydrophobic and exhibits no toxicity. In the present work, the organization of the crambin precursor polypeptide was deduced from cDNA sequences. The precursor shows a domain structure similar to that of the preproprotein of other thionins, which contains a signal peptide, a thionin domain and a C-terminal amino acid extension. Unlike the thionin precursors studied thus far, both the thionin domain and the C-terminal amino acid extension of the crambin precursor have no net charge and are hydrophobic, thus facilitating their interaction, by analogy to that proposed for the corresponding domains of other thionin precursors that have positive and negative charges. The existence of a large number of novel and highly variable thionin variants in Crambe abyssinica has been deduced from cDNA sequences that were amplified by the polymerase chain reaction (PCR) from RNA of seeds, leaves and cotyledons. While the deduced amino acid sequences of the thionin domains of most of these thionin precursor molecules are highly divergent, the two other domains are conserved. Most of the predicted thionin variants are positively charged. The presence of positively charged residues in the thionin domains consistently correlates with the presence of a negatively charged residue in the C-terminal amino acid extension of the various thionin precursors. The different thionin variants are encoded by distinct sets of genes and are expressed in an organ-specific manner.     

Chlorophyll Synthesis in a Deetiolated (det340) Mutant of Arabidopsis without NADPH-Protochlorophyllide (PChlide) Oxidoreductase (POR) A and Photoactive PChlide-F655

Chlorophyll (Chl) synthesis in Arabidopsis is controlled by two light-dependent NADPH-protochlorophyllide (PChlide) oxidoreductases (PORs), one (POR A) that is active transiently in etiolated seedlings at the beginning of illumination and another (POR B) that also operates in green plants. The function of these two enzymes during the light-induced greening of dark-grown seedlings has been studied in the wild type and a deetiolated (det340) mutant of Arabidopsis. One of the consequences of the det mutation is that POR A is constitutively down-regulated, and therefore, synthesis of the POR A enzyme is shut off. When grown in the dark, the det340 mutant lacks POR A and the photoactive PChlide-F655 species but maintains the second PChlide reductase, POR B. Previously, photoactive PChlide-F655 has often been considered to be the only PChlide form that leads to Chl formation. Despite its deficiency in POR A and photoactive PChlide-F655, the det340 mutant is able to green when placed in the light. Chl accumulation, however, proceeds abnormally. At the beginning of illumination, seedlings of det340 mutants are extremely susceptible to photooxidative damage and accumulate Chl only at extremely low light intensities. They form core complexes of photosystems I and II but are almost completely devoid of light-harvesting structures. The results of this study demonstrate that in addition to the route of Chl synthesis that has been studied extensively in illuminated dark-grown wild-type plants, a second branch of Chl synthesis exists that is driven by POR B and does not require POR A.     

Organ-specific expression of highly divergent thionin variants that are distinct from the seed-specific crambin in the crucifer Crambe abyssinica

Most thionins of higher plants are toxic to various bacteria, fungi, and animal and plant cells. The only known exception is the seed-specific thionin, crambin, of the crucifer Crambe abyssinica. Crambin has no net charge, is very hydrophobic and exhibits no toxicity. In the present work, the organization of the crambin precursor polypeptide was deduced from cDNA sequences. The precursor shows a domain structure similar to that of the preproprotein of other thionins, which contains a signal peptide, a thionin domain and a C-terminal amino acid extension. Unlike the thionin precursors studied thus far, both the thionin domain and the C-terminal amino acid extension of the crambin precursor have no net charge and are hydrophobic, thus facilitating their interaction, by analogy to that proposed for the corresponding domains of other thionin precursors that have positive and negative charges. The existence of a large number of novel and highly variable thionin variants in Crambe abyssinica has been deduced from cDNA sequences that were amplified by the polymerase chain reaction (PCR) from RNA of seeds, leaves and cotyledons. While the deduced amino acid sequences of the thionin domains of most of these thionin precursor molecules are highly divergent, the two other domains are conserved. Most of the predicted thionin variants are positively charged. The presence of positively charged residues in the thionin domains consistently correlates with the presence of a negatively charged residue in the C-terminal amino acid extension of the various thionin precursors. The different thionin variants are encoded by distinct sets of genes and are expressed in an organ-specific manner.     

Chlorophyll synthesis in green leaves and isolated chloroplasts of barley (Hordeum vulgare)

The photoreduction of protochlorophyllide was studied in leaves and isolated chloroplasts of barley. Leaves of plants which had been preilluminated for varying lengths of time were incubated with [¹⁴C]-δ- aminolevulinic acid for 2 h in the dark. The subsequent photoreduction of [¹⁴C]-protochlorophyllide was analyzed by high performance liquid chromatography of pigments extracted from illuminated leaves and plastids. The plastids used in this study were isolated in the dark from leaves at the end of the 2 h labelling period. Three major results were obtained:

• 1

  The extent of protochlorophyllide reduction in vivo was rapidly reduced as a function of the preillumination period. In 24 h preilluminated plants only a small fraction of the radioactively labelled protochlorophyllide was reduced during the subsequent light period.
• 2

  The amount of NADPH-protochlorophyllide oxidoreductase (EC 1.6.99.-) present in plastids of fully-green plants was drastically reduced relative to levels in plastids of dark-grown plants as estimated by the methods of immunoblotting of plastid proteins and immunogold labelling of ultrathin sections of the leaf tissue.
• 3

  In etiolated plants light seemed to affect the reduction of protochlorophyllide directly through the excitation of protochlorophyllide. In fully green plants, however, light also affected chlorophyll formation indirectly by the supply of NADPH via photosynthetic electron transport.

     

Degradation and resynthesis of adenine nucleotides in adult rat heart myocytes

The degradation and short-term resynthesis of adenine nucleotides have been examined in a preparation of isolated rat heart myocytes. These myocyte preparations are essentially free of vascular and endothelial cells, contain levels of adenine nucleotides quite comparable to those of intact heart tissue, and retain these components remarkably well for up to 2 h of aerobic incubation in the presence of 1 mM Ca2+. When the cells are rapidly and synchronously de-energized by addition of uncoupler, an inhibitor of respiration and iodoacetate, cellular ATP is degraded almost quantitatively to AMP. The AMP is then converted to either intracellular adenosine, which accumulates to high concentrations before release to the cell exterior, or to IMP. The relative contribution of these two pathways depends on the metabolic state of the cells just prior to de-energization, with IMP production favored when respiring cells are de-energized and adenosine formation predominant when glycolyzing myocytes are subjected to this treatment. Cells de-energized by anaerobiosis in the absence of glucose lose ATP and adenine nucleotides with the production of IMP and adenosine. Upon reoxygenation, these cells restore a high adenylate energy charge and about 60% of control levels of GTP. There is a net resynthesis of 5-7 nmol of adenine nucleotides.mg-1 protein with a corresponding decline in IMP. Added [14C]adenosine labels the adenine nucleotide pool, but little net resynthesis of adenine nucleotides via adenosine kinase can be detected. It therefore appears that a rapid regeneration of adenine nucleotides can occur via the enzymes of the purine nucleotide cycle in heart myocytes and is limited by the size of the IMP pool retained.     

Protein bodies in ray cells of Populus x canadensis Moench ‘robusta’

Light- and electron-microscopical investigations revealed distinct intravacuolar protein aggregates of 0.3–0.8 m in diameter in ray cells of poplar during the dormant season. In semi-thin sections, these bodies showed positive protein staining and enzymatic digestibility with pepsin, indicating their proteinaceous nature. Morphometric measurements showed such protein bodies in 7–13% of the area of the ray-cell lumen. This amount corresponded with the protein content of the wood determined biochemically, e.g. 2.0–5.0 g·mg^-1 dry weight. Polyacrylamide gel electrophoresis of the total protein fraction extracted from wood showed prominent polypeptide species with an apparent molecular weight of 30–32 kilodaltons. The results indicate considerable protein storage in ray cells, especially in the form of protein-storage vacuoles.Abbreviation DW dry weight