Incorporation of light-harvesting complex I alpha and beta polypeptides into the intracytoplasmic membrane of Rhodobacter capsulatus

C-terminal cleavage of the LH1 α-polypeptide in the Sr2+-cultured Thermochromatium tepidum

The light-harvesting 1 reaction center (LH1-RC) complex in the thermophilic purple sulfur bacterium Thermochromatium (Tch.) tepidum binds Ca ions as cofactors, and Ca-binding is largely involved in its characteristic Q _y absorption at 915 nm and enhanced thermostability. Ca²⁺ can be biosynthetically replaced by Sr²⁺ in growing cultures of Tch. tepidum. However, the resulting Sr²⁺-substituted LH1-RC complexes in such cells do not display the absorption maximum and thermostability of those from Ca²⁺-grown cells, signaling that inherent structural differences exist in the LH1 complexes between the Ca²⁺- and Sr²⁺-cultured cells. In this study, we examined the effects of the biosynthetic Sr²⁺-substitution and limited proteolysis on the spectral properties and thermostability of the Tch. tepidum LH1-RC complex. Preferential truncation of two consecutive, positively charged Lys residues at the C-terminus of the LH1 α-polypeptide was observed for the Sr²⁺-cultured cells. A proportion of the truncated LH1 α-polypeptide increased during repeated subculturing in the Sr²⁺-substituted medium. This result suggests that the truncation is a biochemical adaptation to reduce the electrostatic interactions and/or steric repulsion at the C-terminus when Sr²⁺ substitutes for Ca²⁺ in the LH1 complex. Limited proteolysis of the native Ca²⁺-LH1 complex with lysyl protease revealed selective truncations at the Lys residues in both C- and N-terminal extensions of the α- and β-polypeptides. The spectral properties and thermostability of the partially digested native LH1-RC complexes were similar to those of the biosynthetically Sr²⁺-substituted LH1-RC complexes in their Ca²⁺-bound forms. Based on these findings, we propose that the C-terminal domain of the LH1 α-polypeptide plays important roles in retaining proper structure and function of the LH1-RC complex in Tch. tepidum.

The photosynthetic deficiency due to puhC gene deletion in Rhodobacter capsulatus suggests a PuhC protein-dependent process of RC/LH1/PufX complex reorganization

Optimal photosynthetic reaction centre (RC) and core antenna (LH1) levels in the purple bacterium Rhodobacter capsulatus require the puhC gene. Deletion of puhC had little effect on RC and LH1 assembly individually, but significantly inhibited the photosynthetic growth of RC+ LH1- strains, suggesting that maximal RC catalytic activity is PuhC-dependent. Consistent with post-assembly reorganization of the RC/LH1/PufX core complex by PuhC to include latecomer proteins, spatial separation of pufX from the RC/LH1 genes inhibited PufX accumulation and photosynthetic growth only in PuhC- strains. Photosynthetic activity improved to different degrees when PuhC homologues from three other species were expressed in PuhC- R. capsulatus, indicating that PuhC homologues function similarly but may interact inefficiently with a heterologous core complex. Anaerobic photosynthetic growth of PuhC- strains was affected by the duration of prior semiaerobic growth, and by two genes that modulate bacteriochlorophyll production: pufQ and puhE. These observations agree with a speculative model in which reorganization of the core complex is an important regenerative process, accelerated by PuhC.

Investigation of Rhodobacter capsulatus PufX interactions in the core complex of the photosynthetic apparatus

The photosynthetic apparatus of purple bacteria in the genus Rhodobacter includes a core complex consisting of the reaction centre (RC), light-harvesting complex 1 (LH1), and the PufX protein. PufX modulates LH1 structure and facilitates photosynthetic quinone/quinol exchange. We deleted RC/LH1 genes in pufX+ and pufX++ (merodiploid) strains of Rhodobacter capsulatus, which reduced PufX levels regardless of pufX gene copy number and location. Photosynthetic growth of RC-only strains and independent assembly kinetics of the RC and LH1 were unaffected by pufX merodiploidy, but the absorption spectra of strains expressing the RC plus either LH1 alpha or beta indicated that PufX may influence bacteriochlorophyll binding environments. Significant self-association of the PufX transmembrane segment was detected in a hybrid protein expression system, consistent with a role of PufX in core complex dimerization, as proposed for other Rhodobacter species. Our results indicate that in R. capsulatus PufX has the potential to be a central, homodimeric core complex component, and its cellular level is increased by interactions with the RC and LH1.

The puhE gene of Rhodobacter capsulatus is needed for optimal transition from aerobic to photosynthetic growth and encodes a putative negative modulator of bacteriochlorophyll production

A conserved orf of previously unknown function (herein designated as puhE) is located 3' of the reaction centre H (puhA) gene in purple photosynthetic bacteria, in the order puhABCE in Rhodobacter capsulatus. Disruptions of R. capsulatus puhE resulted in a long lag in the growth of photosynthetic cultures inoculated with cells grown under high aeration, and increased the level of the peripheral antenna, light-harvesting complex 2 (LH2). The amount of the photosynthetic reaction centre (RC) and its core antenna, light-harvesting complex 1 (LH1), was reduced; however, there was no decrease in expression of a lacZ reporter fused to the puf (RC and LH1) promoter, in RC assembly in the absence of LH1, or in LH1 assembly in the absence of the RC. In strains that lack LH2, disruption of puhE increased the in vivo absorption at 780 nm, which we attribute to excess bacteriochlorophyll a (BChl) pigment production. This effect was seen in the presence and absence of PufQ, a protein that stimulates BChl biosynthesis. Expression of puhE from a plasmid reduced A(780) production in puhE mutants. We suggest that PuhE modulates BChl biosynthesis independently of PufQ, and that the presence of excess BChl in PuhE(-)LH2(+) strains results in excess LH2 assembly and also interferes with the adaptation of cells during the transition from aerobic respiratory to anaerobic photosynthetic growth.

The PuhB protein of Rhodobacter capsulatus functions in photosynthetic reaction center assembly with a secondary effect on light-harvesting complex 1

The core of the photosynthetic apparatus of purple photosynthetic bacteria such as Rhodobacter capsulatus consists of a reaction center (RC) intimately associated with light-harvesting complex 1 (LH1) and the PufX polypeptide. The abundance of the RC and LH1 components was previously shown to depend on the product of the puhB gene (formerly known as orf214). We report here that disruption of puhB diminishes RC assembly, with an indirect effect on LH1 assembly, and reduces the amount of PufX. Under semiaerobic growth conditions, the core complex was present at a reduced level in puhB mutants. After transfer of semiaerobically grown cultures to photosynthetic (anaerobic illuminated) conditions, the RC/LH1 complex became only slightly more abundant, and the amount of PufX increased as cells began photosynthetic growth. We discovered that the photosynthetic growth of puhB disruption strains of R. capsulatus starts after a long lag period, which is due to physiological adaptation rather than secondary mutations. Using a hybrid protein expression system, we determined that the three predicted transmembrane segments of PuhB are capable of spanning a cell membrane and that the second transmembrane segment could mediate self-association of PuhB. We discuss the possible function of PuhB as a dimeric RC assembly factor.

The reaction center H subunit is not required for high levels of light-harvesting complex 1 in Rhodospirillum rubrum mutants

The gene (puhA) encoding the H subunit of the reaction center (RC) was deleted by site-directed interposon mutagenesis by using a kanamycin resistance cassette lacking transcriptional terminators to eliminate polar effects in both the wild-type strain Rhodospirillum rubrum S1 and the carotenoid-less strain R. rubrum G9. The puhA interposon mutants were incapable of photoheterotrophic growth but grew normally under aerobic chemoheterotrophic conditions. Absorption spectroscopy and sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the RCs were absent. In minimal medium and also in modified medium containing succinate and fructose, the light-harvesting 1 complex (LH1) levels of the S1-derived mutants were about 70 to 100% of the wild-type levels in the same media. The correct assembly of LH1 in the membrane and the pigment-pigment interaction were confirmed by near-infrared circular dichroism spectroscopy. LH1 formation was almost absent when the carotenoid-less G9-derived puhA mutants were grown in standard minimal medium, suggesting that carotenoids may stabilize LH1. In the fructose-containing medium, however, the LH1 levels of the G9 mutants were 70 to 100% of the parental strain levels. Electron micrographs of thin sections of R. rubrum revealed photosynthetic membranes in all mutants grown in succinate-fructose medium. These studies indicate that the H subunit of the RC is necessary neither for maximal formation of LH1 nor for photosynthetic membrane formation but is essential for functional RC assembly.

In vitro reconstitution of the core and peripheral light-harvesting complexes of Rhodospirillum molischianum from separately isolated components

In most purple bacteria, the core light-harvesting complex (LH1) differs from the peripheral light-harvesting complex (LH2) in spectral properties and amino acid sequences. In Rhodospirillum (Rs. )molischianum, however, the LH2 closely resembles the LH1 of many species in amino acid sequence identity and in some spectral properties (e.g., circular dichroism and resonance Raman). Despite these similarities to LH1, the LH2 of Rs. molischianum displays an absorption spectrum similar to the LH2 complexes of other bacteria. Moreover, its crystal structure is very similar to the LH2 of Rhodopseudomonas (Rps.) acidophila. To better understand the basis of the biochemical and spectral differences between LH1 and LH2, we isolated the alpha and beta polypeptides of the LH2 complexes from an LH2-only strain of Rhodobacter (Rb.) sphaeroides as well as the alpha and beta polypeptides from both the LH1 and LH2 complexes from Rs. molischianum. We then examined their behavior in reconstitution assays with bacteriochlorophyll (Bchl). The Rb. sphaeroides LH2 alpha and beta polypeptides were inactive in reconstitution assays, whether alone, paired with each other, or paired in hybrid assays with the complementary LH1 polypeptides of Rs. rubrum, Rb. sphaeroides, Rb. capsulatus, or Rps. viridis. The LH1 beta polypeptide of Rs. molischianum behaved similarly to the LH1 beta polypeptides of Rs. rubrum, Rb. sphaeroides, Rb. capsulatus, and Rps. viridis, forming a subunit-type complex with or without an alpha polypeptide, and forming an LH1 complex when combined with a native LH1 alpha polypeptide. Interestingly, the LH2 beta polypeptide of Rs. molischianum, in the absence of other polypeptides, also formed a subunit-type complex as well as a further red-shifted complex whose spectrum resembled the 850 nm absorbance band of LH2. In the presence of the LH1 alpha polypeptide of Rs. rubrum or Rs. molischianum, it formed an LH1-type complex, but in the presence of the LH2 alpha polypeptide of Rs. molischianum it formed an LH2 complex. This is the first reported reconstitution of an LH2 complex using only isolated LH2 polypeptides and Bchl. It is also the first example of an LH2 beta polypeptide that can form an LH1 subunit-type complex and an LH1-type complex when paired with an LH1 alpha polypeptide.

Structure of the puf operon of the obligately aerobic, bacteriochlorophyll alpha-containing bacterium Roseobacter denitrificans OCh114 and its expression in a Rhodobacter capsulatus puf puc deletion mutant

Roseobacter denitrificans (Erythrobacter species strain OCh114) synthesizes bacteriochlorophyll a (BChl) and the photosynthetic apparatus only in the presence of oxygen and is unable to carry out primary photosynthetic reactions and to grow photosynthetically under anoxic conditions. The puf operon of R. denitrificans has the same five genes in the same order as in many photosynthetic bacteria, i.e., pufBALMC. PufC, the tetraheme subunit of the reaction center (RC), consists of 352 amino acids (Mr, 39,043); 20 and 34% of the total amino acids are identical to those of PufC of Chloroflexus aurantiacus and Rubrivivax gelatinosus, respectively. The N-terminal hydrophobic domain is probably responsible for anchoring the subunit in the membrane. Four heme-binding domains are homologous to those of PufC in several purple bacteria. Sequences similar to pufQ and pufX of Rhodobacter capsulatus were not detected on the chromosome of R. denitrificans. The puf operon of R. denitrificans was expressed in trans in Escherichia coli, and all gene products were synthesized. The Roseobacter puf operon was also expressed in R. capsulatus CK11, a puf puc double-deletion mutant. For the first time, an RC/light-harvesting complex I core complex was heterologously synthesized. The strongest expression of the R. denitrificans puf operon was observed under the control of the R. capsulatus puf promoter, in the presence of pufQ and pufX and in the absence of pufC. Charge recombination between the primary donor P+ and the primary ubiquinone Q(A)- was observed in the transconjugant, showing that the M and L subunits of the RC were correctly assembled. The transconjugants did not grow photosynthetically under anoxic conditions.

Forty-five years of developmental biology of photosynthetic bacteria

Developmental biology and cell differentiation of photosynthetic prokaryotes are less noticed fields than the showpieces of eukaryotes, e.g. Drosophila melanogaster. The large metabolic versatility of the facultative purple bacteria and their great capability to adapt to different ecological conditions, however, aroused the inquisitiveness to investigate the process of cell differentiation and to use these bacteria as model system to study structure, function and biosynthesis of the photosynthetic apparatus. The great progress in research in this field paved the way to study principal mechanisms of cellular organization and differentiation in these bacteria. In this article, the history of the research on membrane structure and development of anoxygenic photosynthetic prokaryotes during the last 45 years is described. A personal account of how I entered the field through research on the phototaxis of cyanobacteria is given. Intracytoplasmic membranes (ICM) were detected by electron microscopy in cyanobacteria and in purple non-sulfur bacteria. The formation of ICM by invagination of the cytoplasmic membrane in purple bacteria was observed for the first time. Investigations on the effect of changes in oxygen tension and light intensity on the formation of pigments and intracytoplasmic membranes followed. The isolation, purification, and analysis of light-harvesting complexes and of pigment-binding proteins was the next step of our research. Lipopolysaccharides and peptidoglycans were detected and analyzed in the outer membrane of photosynthetic bacteria. Functional membrane differentiation includes variations in the rates of photophosphorylation and electron transport. Molecular genetic approaches have initiated the investigation of transcriptional regulation and the analysis of correlation between pigment and protein synthesis. Molecular analysis of assembly of light-harvesting complexes and membrane differentiation are the present aspects of our research. Cell differentiation has been considered under evolutionary view.

Import and assembly of the α and β-polypeptides of the light-harvesting complex I (B870) in the membrane system of Rhodobacter capsulatus investigated in an in vitro translation system

Transcripts of the genes pufBA, pufB or pufA from Rhodobacter capsulatus were translated in a cell-free system of R. capsulatus. The incorporation of the nascent polypeptides LHIα and β in various types of membranes and the assembly of the light-harvesting (LH) complex I (B870) were investigated. The highest rate of stable incorporation of LHIα and β into the membrane was observed with membranes from the wild type strain grown under chemotrophic conditions. Addition of membranes from cells defective in biosynthesis of pigment-binding proteins resulted in a less efficient or less stable incorporation of LHIαβ. The single polypeptides LHIα or β were synthesized and inserted into the membrane but were extractable to a higher percentage by 6 M urea than the pairwise inserted LHI polypeptides.If the ribosomes and the S135 extract were depleted of DnaK the rate of synthesis of both polypeptides, LHIα and β, was strongly reduced. Removal of GroEL from the cell-free system did not impair the synthesis and membrane association of both proteins, but affected the stable insertion. A high percentage of the LHIαβ polypeptides became extractable by 6 M urea if the cell-free system was depleted of GroEL. Addition of GroEL to the cell-free system restored the capacity of stable insertion of both proteins into the membrane. GroEL interacted with LHIα and β before membrane targeting as shown by immunological means.A protein fraction, which can be removed from the membrane with a low-salt buffer, supported the effective and stable incorporation of LHIαβ into the membrane. It is concluded that the assembly of the LHI complex in the membrane system of R. capsulatus is a multistep process guided and supported by polypeptides located in the cytoplasm and in the membrane. In the cell-free in vitro system not only the correct insertion of the LHI polypeptides but also an assembly with bacteriochlorophyll was observed. BChl was synthesized from δ-amino levulinate in the cell free system.

Spectral alterations in Rhodobacter capsulatus mutants with site-directed changes in the bacteriochlorophyll-binding site of the B880 light-harvesting complex

Site-directed mutagenesis has suggested that conserved histidine and alanine residues in the alpha-subunit of the B880 (LHI) antenna complex of Rhodobacter capsulatus (alpha His32 and alpha Ala28) form part of the bacteriochlorophyll binding site (Bylina, E.J., Robles, S.J. and Youvan, D.C. (1988) Isr. J. Chem. 28, 73-78). Spectroscopic characterization of chromatophores from alpha Ala28 mutants at 77 K revealed: (i) red shifts in B880 absorption and emission maxima of approximately 6 and 10 nm, respectively, with a serine exchange; (ii) red shifts of 3 nm with a glycine exchange; (iii) and no significant shifts with a cysteine exchange, despite a reduction of approximately 50% in B880 level. The strains with the serine and glycine exchanges showed characteristic fluorescence polarization increases over the red-edge of the B880 band, suggesting that the absorption red shifts arose from altered pigment-protein interactions rather than from increased oligomerization states that would be expected to show markedly diminished and red shifted rises in polarization (Westerhuis, W.H.J., Farchaus, J.W. and Niederman, R.A. (1993) Photochem. Photobiol. 58, 460-463). Excitation spectra of strains with alpha His32 to glutamine and alpha Ala28 to histidine exchanges, thought to be depleted in B880, revealed low levels of a 'pseudo-B880' complex with blue-shifted maxima and fluorescence polarization rises; when excited directly into this component, the former strain showed an emission spectrum similar to that of B880. An essentially wild-type electrochromic carotenoid response was observed only in the B880-containing mutants, since membranes isolated from the B880-depleted strains exhibited an increased permeability to ions.

Translocation of precytochrome c2 into intracytoplasmic membrane vesicles of Rhodobacter capsulatus requires a peripheral membrane protein

Rhodobacter capsulatus is a member of the group of alpha-purple bacteria which are closely related to the ancestral endosymbiont that gave rise to mitochondria. It has therefore been hypothesized that the molecular mechanisms governing protein export in alpha-purple bacteria have been conserved during the evolution of mitochondria. To enable analysis of protein export in alpha-purple bacteria we describe here the development of a homologous cell-free synthesis/export system consisting entirely of components of R. capsulatus. Translocation of precytochrome c2 into intracytoplasmic membrane vesicles of this organism was found to require the proton-motive force and proceed at a significantly higher efficiency when membranes were present during protein synthesis. Furthermore, we show that, in this cell-free system, translocation depends on a preparation of peripheral membrane proteins which do not possess detectable SecA- and SecB-like activities.

The distribution of charged amino acids in mitochondrial inner-membrane proteins suggests different modes of membrane integration for nuclearly and mitochondrially encoded proteins

We have analyzed the amino acid distribution in seven nuclearly encoded and five mitochondrially encoded inner membrane proteins with experimentally well characterized topologies. The mitochondrially encoded proteins conform to the 'positive inside' rule, i.e. they have many more positively charged residues in their non-translocated as compared to translocated domains. However, most of the nuclearly encoded proteins do not show such a bias but instead have a surprisingly skewed distribution of Glu residues with an almost ten times higher frequency in the intermembrane space than in the matrix domains. These findings suggest that some, but possibly not all, nuclearly encoded inner membrane proteins may insert into the membrane by a mechanism that does not depend on the distribution of positively charged amino acids.

Characterization of LHI- and LHI+ Rhodobacter capsulatus pufA mutants

The NH2 termini of light-harvesting complex I (LHI) polypeptides alpha and beta of Rhodobacter capsulatus are thought to be involved in the assembly of the LHI complex. For a more detailed study of the role of the NH2-terminal segment of the LHI alpha protein in insertion into the intracytoplasmic membrane (ICM) of R. capsulatus, amino acids 6 to 8, 9 to 11, 12 and 13, or 14 and 15 of the LHI alpha protein were deleted. Additionally, the hydrophobic stretch of the amino acids 7 to 11 was lengthened by insertion of hydrophobic or hydrophilic amino acids. All mutations abolished the ability of the mutant strains to form a functional LHI antenna complex. All changes introduced into the LHI alpha protein strongly reduced the stability of its LHI beta partner protein in the ICM. The effects on the mutated protein itself, however, were different. Deletion of amino acids 6 to 8, 9 to 11, or 14 and 15 drastically reduced the amount of the LHI alpha protein inserted into the membrane or prevented its insertion. Deletion of amino acids 12 and 13 and lengthening of the stretch of amino acids 7 to 11 reduced the half-life of the mutated LHI alpha protein in the ICM in comparison with the wild-type LHI alpha protein. Under the selective pressure of low light, revertants which regained a functional LHI antenna complex were identified only for the mutant strain deleted of amino acids 9 to 11 of the LHI alpha polypeptide [U43 (pTPR15)]. The restoration of the LHI+ phenotype was due to an in-frame duplication of 9 bp in the pufA gene directly upstream of the site of deletion present in strain U43(pTPR15). The duplicated nucleotides code for the amino acids Lys, Ile, and Trp. Membranes purified from the revertants were different from that of the reaction center-positive LHI+ LHII- control strain U43(pTX35) in doubling of the carotenoid content and increase of the size of the photosynthetic unit. By separating the reaction center and LHI complexes of the revertants by native preparative gel electrophoresis, we confirmed that the higher amount of carotenoids was associated with the LHI proteins.