Structure and Function of the Bacterial bc 1 Complex: Domain Movement, Subunit Interactions, and Emerging Rationale Engineering Attempts

The ubiquinol: cytochrome c oxidoreductase, or the bc ₁ complex, is a key component ofboth respiratory and photosynthetic electron transfer and contributes to the formation of anelectrochemical gradient necessary for ATP synthesis. Numerous bacteria harbor a bc ₁ complexcomprised of three redox-active subunits, which bear two b-type hemes, one c-type heme, andone [2Fe–2S] cluster as prosthetic groups. Photosynthetic bacteria like Rhodobacter speciesprovide powerful models for studying the function and structure of this enzyme and are beingwidely used. In recent years, extensive use of spontaneous and site-directed mutants and theirrevertants, new inhibitors, discovery of natural variants of this enzyme in various species, andengineering of novel bc ₁ complexes in species amenable to genetic manipulations have providedus with a wealth of information on the mechanism of function, nature of subunit interactions,and assembly of this important enzyme. The recent resolution of the structure of variousmitochondrial bc ₁ complexes in different crystallographic forms has consolidated previousfindings, added atomic-scale precision to our knowledge, and raised new issues, such as thepossible movement of the Rieske Fe–S protein subunit during Q_o site catalysis. Here, studiesperformed during the last few years using bacterial bc ₁ complexes are reviewed briefly andongoing investigations and future challenges of this exciting field are mentioned.     

Mutation of the Chlamydomonas reinhardtii analogue of residue M210 of the Rhodobacter sphaeroides reaction center slows primary electron transfer in Photosystem II

Primary charge separation within Photosystem II (PS II) is much slower (time constant 21 ps) than the equivalent step in the related reaction center (RC) found in purple bacteria ( 3 ps). In the case of the bacterial RC, replacement of a specific tyrosine residue within the M subunit (at position 210 in Rhodobacter sphaeroides), by a leucine residue slows down charge separation to 20 ps. Significantly the analogous residue in PS II, within the D2 polypeptide, is a leucine not a tyrosine (at position D2-205, Chlamydomonas reinhardtii numbering). Consequently, it has been postulated [Hastings et al. (1992) Biochemistry 31: 7638–7647] that the rate of electron transfer could be increased in PS II by replacing this leucine residue with tyrosine. We have tested this hypothesis by constructing the D2-Leu205Tyr mutant in the green alga, Chlamydomonas reinhardtii, through transformation of the chloroplast genome. Primary charge separation was examined in isolated PS II RCs by time-resolved optical spectroscopy and was found to occur with a time constant of 40 ps. We conclude that mutation of D2-Leu205 to Tyr does not increase the rate of charge separation in PS II. The slower kinetics of primary charge separation in wild type PS II are probably not due to a specific difference in primary structure compared with the bacterial RC but rather a consequence of the P680 singlet excited state being a shallower trap for excitation energy within the reaction center.     

Peroxisomal Disorders: Clinical,Biochemical, and Molecular Aspects

Peroxisomes are subcellular organelles catalyzing a number of indispensable functions in cellular metabolism. The importance of peroxisomes in man is stressed by the existence of an expanding group of genetic diseases in which there is an impairment in one or more peroxisomal functions. Much has been learned in recent years about these functions and many of the enzymes involved have been characterized, purified and their cDNAs cloned. This has allowed resolution of the enzymatic and molecular basis of many of the single peroxisomal enzyme deficiencies. Similarly, the molecular basis of the peroxisome biogenesis disorders is also being resolved rapidly thanks to the successful use of CHO as well as yeast mutants. In this paper we will provide an overview of the peroxisomal disorders with particular emphasis on their clinical, biochemical and molecular characteristics.     

Molecular systematics of Clerodendrum (Lamiaceae): ITS sequences and total evidence

Thirty-three species of Clerodendrum s.l. and five outgroup genera were included in a sequence analysis of internal transcribed spacers of the nuclear ribosomal DNA. The results of the cladistic analysis were compared to and combined with cpDNA restriction site data from a previous study. All molecular data identified four major clades within Clerodendrum s.l. and showed the genus to be polyphyletic. Clerodendrum s.s., minus Konocalyx and Cyclonema, is monophyletic and the genus should be restricted to this group. Cyclonema and Konocalyx form a clade distinct from Clerodendrum s.s., which has been recognized as Rotheca Raf.     

Re-examination of ultrastructures of the stellate chloroplast organization in brown algae: Structure and development of pyrenoids

Some taxa of brown algae have a so‐called ‘stellate’ chloroplast arrangement composed of multiple chloroplasts arranged in a stellate configuration, or else a single chloroplast with radiating lobes. The fine structures of chloroplasts and pyrenoids have been studied, but the details of their membrane configurations as well as pyrenoid ontogeny have not been well understood. The ultrastructure of the single stellate chloroplast in Splachnidium rugosum and Scytothamnus australis were re‐examined in the present study, as well as the stellate arrangement of chloroplasts in Asteronema ferruginea and Asterocladon interjectum, using freeze‐substitution fixation. It was confirmed that the chloroplast envelope invaginated into the pyrenoid in Splachnidium rugosum, Scytothamnus australis and Asteronema ferruginea, but chloroplast endoplasmic reticulum (CER) remained on the surface of the chloroplast. The space between the invaginated chloroplast envelope and CER was filled with electron‐dense material. In Asteronema ferruginea, CER surrounding each pyrenoid was closely appressed to the neighboring CER over the pyrenoids, so that the chloroplasts formed a stellate configuration; however, in the apical cells chloroplasts formed two or more loose groups, or were completely dispersed. The pyrenoids of Asterocladon interjectum did not have any invagination of the chloroplast envelope, but a unique membranous sac surrounded the pyrenoid complex and occasionally other organelles (e.g. mitochondria). Immunolocalization of β‐1,3‐glucans showed that the membranous sac in Asterocladon interjectum did not contain photosynthetic products such as chrysolaminaran. Observations in the dividing cells of Splachnidium rugosum and Scytothamnus australis indicated that the pyrenoid in the center of the chloroplast enlarged and divided into two before or during chloroplast division.     

Patterns of chloroplast diversity among western European Dactylorhiza species (Orchidaceae)

In Europe, the genus Dactylorhiza comprises a bewildering variety of forms that are difficult to sort into discrete species. Most Dactylorhiza species are diploid or tetraploid and contrasting hypotheses have been proposed to explain the complex variation within this group. Using PCR-RFLP analysis in eight putative species, we could identify four highly differentiated chloroplast DNA lineages. The first lineage (clade A) included the unique haplotype found in D. sambucina. Clade B grouped four haplotypes belonging mostly to D. incarnata. Clades C and D included 27 haplotypes detected in diploid D. fuchsii and in all tetraploid species investigated. Eighty percent of the chloroplast variation were consistent with currently accepted species boundaries. The imperfect agreement between chloroplast variation and species boundaries may be ascribed to incomplete lineage sorting and/or reticulation. Our cpDNA results provide strong evidence that the allotetrapolyploids have been formed through asymmetric hybridization with a member of the D. fuchsii / maculata group as the maternal parent.     

Photosynthesis research: advances through molecular biology – the beginnings, 1975–1980s and on...

Restriction endonuclease recognition sites and genes for rRNAs were first mapped on chloroplast chromosomes in 1975–1976. This marked the beginning of the application of molecular biology tools to photosynthesis research. In the first phase, knowledge about proteins involved in photosynthesis was used to identify plastid and nuclear genes encoding these proteins on cloned segments of DNA. Soon afterwards the DNA sequences of the cloned genes revealed the full primary sequences of the proteins. Knowledge of the primary amino acid sequences provided deeper understanding of the functioning of the protein and interactions among proteins of the photosynthetic apparatus. Later, as chloroplast DNA sequencing proceeded, genes were discovered that encoded proteins that had not been known to be part of the photosynthetic apparatus. This more complete knowledge of the composition of reaction centers and of the primary amino acid sequences of individual proteins comprising the reaction centers opened the way to determining the three-dimensional structures of reaction centers. At present, the availability of cloned genes, knowledge of the gene sequences and systems developed to genetically manipulate photosynthetic organisms is permitting experimental inquiries to be made into crucial details of the photosynthetic process. This revised version was published online in August 2006 with corrections to the Cover Date.     

DCL is a plant-specific protein required for plastid ribosomal RNA processing and embryo development

The defective chloroplast and leaf-mutable (dcl-m) mutation of tomato blocks chloroplast differentiation in leaf mesophyll cells and a signaling system that appears to be required for morphogenesis of palisade cells during leaf growth. To dissect the function of DCL, mutants with stable dcl alleles (dcl-s) were generated and examined for their phenotype. DCL/dcl-s plant produce dcl-s/dcl-s seeds with embryos arrested at the globular stage of development. The levels of several chloroplast- and nuclear-encoded proteins are strongly reduced in dcl-m mutant leaf sectors without significant changes in their corresponding mRNAs. The 4.5S rRNA fails to be processed efficiently, however, suggesting that DCL has a direct or indirect function in rRNA processing or correct ribosome assembly. Accordingly, chloroplasts in dcl-m sectors are impaired in polysome assembly, which can explain the reduced accumulation of chloroplast-encoded proteins. These results suggest that DCL is required for chloroplast rRNA processing, and emphasize the importance of plastid function during embryogenesis.     

Biotransformation of eudesmanes by Tessaria absinthioides cell suspension cultures

Tessaria absinthioides callus and cell suspension cultures were established. The most appropriate plant growth regulator combination and culture conditions for cell growth and secondary metabolites were obtained on MS basal media supplemented with 20.0 M IBA/ 18.0 M BA at 22°C and using a photoperiod of 16 h light / 8 h dark. Meanwhile, submerged cultures were initiated by inocula of 5 and 10% (v/ v) and shaken at 120 rpm. The analysis of the presence of the sesquiterpenes in submerged cultures showed that only the eremophilane tessaric acid was accumulated once stationary phase was reached. When ilicic acid was added, only tessaric acid was recovered from biotransformation procedure. However, since no eudesmanes were detected, it is more likely that ilicic acid is not converted to further oxidised eudesmanes. But its disappearance, together with the increase in tessaric acid accumulation, showed that it has been metabolised into the above-mentioned eremophilane. The eudesmanic acid 3-oxo--costic acid was obtained by bioconversion of the precursor -costic acid by cell suspension cultures, together with 3,5-dihydroxycostic and 3,5-dihydroxycostic acids.