The solution structure of Rhodobacter sphaeroides LH1beta reveals two helical domains separated by a more flexible region: structural consequences for the LH1 complex.

Here, the solution structure of the Rhodobacter sphaeroides core light-harvesting complex beta polypeptide solubilised in chloroform:methanol is presented. The structure, determined by homonuclear NMR spectroscopy and distance geometry, comprises two alpha helical regions (residue -34 to -15 and -11 to +6, using the numbering system in which the conserved histidine residue is numbered zero) joined by a more flexible four amino acid residue linker. The C-terminal helix forms the membrane spanning region in the intact LH1 complex, whilst the N-terminal helix must lie in the lipid head groups or in the cytoplasm, and form the basis of interaction with the alpha polypeptide. The structure of a mutant beta polypeptide W(+9)F was also determined. This mutant, which is deficient in a hydrogen bond donor to the bacteriochlorophyll, showed an identical structure to the wild-type, implying that observed differences in interaction with other LH1 polypeptides must arise from cofactor binding. Using these structures we propose a modification to existing models of the intact LH1 complex by replacing the continuous helix of the beta polypeptide with two helices, one of which lies at an acute angle to the membrane plane. We suggest that a key difference between LH1 and LH2 is that the beta subunit is more bent in LH1. This modification puts the N terminus of LH1beta close to the reaction centre H subunit, and provides a rationale for the different ring sizes of LH1 and LH2 complexes.

Reconstitution of the B873 light-harvesting complex of Rhodospirillum rubrum from the separately isolated alpha- and beta-polypeptides and bacteriochlorophyll a.

The light-harvesting complex of Rhodospirillum rubrum was reversibly dissociated into its component parts: bacteriochlorophyll and two 6-kilodalton polypeptides. The dissociation of the complex by n-octyl beta-D-glucopyranoside was accompanied by a shift of the absorbance maximum from 873 to 820 nm (a stable intermediate form) and finally to 777 nm. In the latter state, bacteriochlorophyll was shown to be free from the protein. Complexes absorbing at 820 and 873 nm could be re-formed from the fully dissociated state with over 80% yield by dilution of the detergent. Absorbance and circular dichroism properties of the re-formed B820 complex were essentially identical with those of B820 formed from chromatophores. Phospholipids and higher concentrations of complex were required to obtain the in vivo circular dichroism spectrum for reassociated B873. Reconstitution of the light-harvesting complexes from separately isolated alpha- and beta-polypeptides and bacteriochlorophyll was also demonstrated. Absorbance and circular dichroism spectra of these complexes were identical with those of complexes formed by the reassociation of the dissociated complex. Bacteriochlorophyll and the beta-polypeptide alone formed a complex that had an absorbance at 820 nm, but an 873-nm complex could not be formed without addition of the alpha-polypeptide. The alpha-polypeptide alone with bacteriochlorophyll did not form any red-shifted complex. In preliminary structure-function studies, some analogues of bacteriochlorophyll were also tested for reconstitution.

Probing protein structural requirements for formation of the core light-harvesting complex of photosynthetic bacteria using hybrid reconstitution methodology.

The α- and ß-polypeptides of LH1 isolated from four different photosynthetic bacteria (Rhodospirillum rubrum, Rhodobacter sphaeroides, Rhodobacter capsulatus and Rhodopseudomonas viridis) were used for homologous and hybrid reconstitution experiments with bacteriochlorophyll a. Formation of B820-type subunit complexes and LH1-type complexes were evaluated. The ß-polypeptides of R. rubrum, Rb. sphaeroides and Rb. capsulatus behaved similarly and formed B820-type subunit complexes in the absence of an α-polypeptide. The α- and ß-polypeptides were both required to form a LH1-type complex with each of these three homologous systems. In hybrid experiments where the ß-polypeptides were tested for reconstitution with α-polypeptides other than their homologous partners, half of the twelve possible combinations resulted in formation of both B820- and LH1-type complexes. Three of the combinations that did not result in formation of a LH1-type complex involved the ß-polypeptide of R. rubrum. It is suggested that these latter results can be explained by charge repulsion between the Lys at position-17 (assigning the conserved His located nearest to the C-terminus as position 0) in the ß-polypeptide of R. rubrum and each of the heterologous α-polypeptides tested, all of which have an Arg at this location. Conclusions that can be derived from these experimental results include: (1) the experimental data support the idea that a central core region of approximately 40 amino acids exists in each of the polypeptides, which contains sufficient information to allow formation of both the B820- and LH1-type complexes and (2) a specific portion of the N-terminal hydrophilic region of each polypeptide was found in which ion pairs between oppositely charged groups on the α- and ß-polypeptides seem to stabilize complex formation.

Probing the structure of the core light-harvesting complex (LH1) of Rhodopseudomonas viridis by dissociation and reconstitution methodology.

A subunit complex was formed from the core light-harvesting complex (LH1) of bacteriochlorophyll(BChl)-b-containing Rhodopseudomonas viridis. The addition of octyl glucoside to a carotenoid-depleted Rps. viridis membrane preparation resulted in a subunit complex absorbing at 895 nm, which could be quantitatively dissociated to free BChl b and then reassociated to the subunit. When carotenoid was added back, the subunit could be reassociated to LH1 with a 25% yield. Additionally, the Rps. viridis α- and ß-polypeptides were isolated, purified, and then reconstituted with BChl b. They formed a subunit absorbing near 895 nm, similar to the subunit formed by titration of the carotenoid depleted membrane, but did not form an LH1-type complex at 1015 nm. The same results were obtained with the ß-polypeptide alone and BChl b. Isolated polypeptides were also tested for their interaction with BChl a. They formed subunit and LH1-type complexes similar to those formed using polypeptides isolated from BChl-a-containing bacteria but displayed 6-10 nm smaller red shifts in their long-wavelength absorption maxima. Thus, the larger red shift of BChl-b-containing Rps. viridis is not attributable solely to the protein structure. The ß-polypeptide of Rps. viridis differed from the other ß-polypeptides tested in that it could form an LH1-type complex with BChl a in the absence of the α- and γ-polypeptides. It apparently contains the necessary information required to assemble into an LH1-type complex. When the γ-polypeptide was tested in reconstitution with BChl a and BChl b with the α- and ß-polypeptides, it had no effect; its role remains undetermined.

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.

Reconstitution of core light-harvesting complexes of photosynthetic bacteria using chemically synthesized polypeptides. 1. Minimal requirements for subunit formation.

Described are the chemical synthesis, isolation and characterization of each of three polypeptides whose amino acid sequences reproduce portions of the amino acid sequence of the beta-polypeptides of the core light-harvesting complex (LH1) of Rhodobacter sphaeroides or Rhodospirillum rubrum. The native beta-polypeptides of LH1 of these organisms contain 48 and 54 amino acids, respectively. The smallest synthetic polypeptide had an amino acid sequence identical to that of the last 16 amino acids of the beta-polypeptide of Rb. sphaeroides (sph beta 16) but failed to form either a subunit- or LH1-type complex under reconstitution conditions. Also, this polypeptide, lengthened on the N terminus by adding the sequence Lys-Ile-Ser-Lys to enhance solubility, failed to form a subunit- or LH1-type complex. In contrast, polypeptides containing either the 31 amino acids at the C terminus of the beta-polypeptide of Rb. sphaeroides (sph beta 31) or the equivalent 31 amino acids of the beta-polypeptide of Rs. rubrum (rr beta 31) were fully competent in forming a subunit-type complex and exhibited association constants for complex formation comparable to or exceeding those of the native beta-polypeptides. The absorption and CD spectra of these subunit-type complexes were nearly identical to those of subunit complexes formed with native beta-polypeptides. It may be concluded that all structural features required to make the subunit complex are present in the well-defined, chemically synthesized polypeptides. Neither polypeptide appeared to interact with the native alpha-polypeptides to form a LH1-type complex. However, sph beta 31 formed a LH1-type complex absorbing at 849 nm without an alpha-polypeptide. Although chemical syntheses of polypeptides of this size are common, the purification of membrane-spanning segments is much more challenging because the polypeptides lack solubility in water. The chemical syntheses reported here represent the first such syntheses of membrane-spanning polypeptides which display native activity upon reconstitution.

Reconstitution of core light-harvesting complexes of photosynthetic bacteria using chemically synthesized polypeptides. 2. Determination of structural features that stabilize complex formation and their implications for the structure of the subunit complex.

Chemically synthesized polypeptides have been utilized with a reconstitution assay to determine the role of specific amino acid side chains in stabilizing the core light-harvesting complex (LH1) of photosynthetic bacteria and its subunit complex. In the preceding paper [Meadows, K. A., Parkes-Loach, P. S., Kehoe, J. W., and Loach, P. A. (1998) Biochemistry 37, 3411-3417], it was demonstrated that 31-residue polypeptides (compared to 48 and 54 amino acids in the native polypeptides) having the same sequence as the core region of the beta-polypeptide of Rhodobacter sphaeroides (sph beta 31) or Rhodospirillum rubrum (rr beta 31) could form subunit-type complexes. However, neither polypeptide interacted with the native alpha-polypeptides to form a native LH1 complex. In this paper, it is demonstrated that larger segments of the native Rb. sphaeroides beta-polypeptide possess native behavior in LH1 formation. Polypeptides were synthesized that were six (sph beta 37) and ten amino acids (sph beta 41) longer than sph beta 31. Although sph beta 37 exhibited behavior nearly identical to that of sph beta 31, sph beta 41 behaved more like the native polypeptide. In the case of rr beta 31, a polypeptide with four additional amino acids toward the C terminus was synthesized (rr beta 35). Because LH1-forming behavior was not recovered with this longer polypeptide, one or more of the three remaining amino acids at the C-terminal end of the native beta-polypeptide seem to play an important role in LH1 stabilization in Rs. rubrum. Three analogues of the core region of the Rb. sphaeroides beta-polypeptide were synthesized, in each of which one highly conserved amino acid was changed. Evidence was obtained that the penultimate amino acid, a Trp residue, is especially important for subunit formation. When it was changed to Phe, the lambda Max of the subunit shifted from 823 to 811 nm and the association constant decreased about 500-fold. Changing each of two other amino acids had smaller effects on subunit formation. Changing Trp to Phe at the location six amino acid residues toward the C terminus from the His coordinated to Bchl resulted in an approximately 10-fold decrease in the association constant for subunit formation but did not affect the formation of a LH1-type complex compared to sph beta 31. Finally, changing Arg to Leu at the location seven amino acid residues toward the C terminus from the His coordinated to Bchl decreased the association constant for subunit formation by about 30-fold. In this case, no LH1-type complex could be formed. On the basis of these results, in comparison with the crystal structure of the LH2 beta-polypeptide of Rhodospirillum molischianum, two possible structures for the subunit complex are suggested.

Probing the bacteriochlorophyll binding site by reconstitution of the light-harvesting complex of Rhodospirillum rubrum with bacteriochlorophyll a analogues.

Structural features of bacteriochlorophyll (BChl) a that are required for binding to the light-harvesting proteins of Rhodospirillum rubrum were determined by testing for reconstitution of the B873 or B820 (structural subunit of B873) light-harvesting complexes with BChl a analogues. The results indicate that the binding site is very specific; of the analogues tested, only derivatives of BChl a with ethyl, phytyl, and geranylgeranyl esterifying alcohols and BChl b (phytyl) successfully reconstituted to form B820- and B873-type complexes. BChl analogues lacking magnesium, the C-3 acetyl group, or the C-13(2) carbomethoxy group did not reconstitute to form B820 or B873. Also unreactive were 13(2)-hydroxyBChl a and 3-acetylchlorophyll a. Competition experiments showed that several of these nonreconstituting analogues significantly slowed BChl a binding to form B820 and blocked BChl a-B873 formation, indicating that the analogues may competitively bind to the protein even though they do not form red-shifted complexes. With the R. rubrum polypeptides, BChl b formed complexes that were further red-shifted than those of BChl a; however, the energies of the red shifts, binding behavior, and circular dichroism (CD) spectra were similar. B873 complexes reconstituted with the geranylgeranyl BChl a derivative, which contains the native esterifying alcohol for R. rubrum, showed in-vivo-like CD features, but the phytyl and ethyl B873 complexes showed inverted CD features in the near infrared. The B820 complex with the ethyl derivative was about 30-fold less stable than the two longer esterifying alcohol derivatives, but all formed stable B873 complexes.

Spectroscopic characterization of the light-harvesting complex of Rhodospirillum rubrum and its structural subunit.

The spectroscopic properties of the light-harvesting complex of Rhodospirillum rubrum, B873, and a detergent-isolated subunit form, B820, are presented. Absorption and circular dichroism spectra suggest excitonically interacting bacteriochlorophyll alpha (BChl alpha) molecules give B820 its unique spectroscopic properties. Resonance Raman results indicate that BCHl alpha is 5-coordinate in both B820 and B873 but that the interactions with the BChl C2 acetyl in B820 and B873 are different. The reactivity of BChl alpha in B820 in light and oxygen, or NaBH4, suggests that it is exposed to detergent and the aqueous environment. Excited-state lifetimes of the completely dissociated 777-nm-absorbing form [1.98 ns in 4.5% octyl glucoside (OG)], the intermediate subunit B820 (0.72 ns in 0.8% OG), and the in vivo like reassociated B873 (0.39 ns in 0.3% OG) were measured by single-photon counting. The fluorescence decays were exponential when emission was detected at wavelengths longer than 864 nm. An in vivo like B873 complex, as judged by its spectroscopic properties, can be formed from B820 without the presence of a reaction center.

Isolation and characterization of a subunit form of the light-harvesting complex of Rhodospirillum rubrum.

A new method is described for the isolation of subunits of the light-harvesting complex from Rhodospirillum rubrum (wild type and the G-9 mutant) in yields that approach 100%. The procedure involved treating membrane vesicles with ethylenediaminetetraacetic acid-Triton X-100 to remove components other than the light-harvesting complex and reaction center. In the preparation from wild-type cells, a benzene extraction was then employed to remove carotenoid and ubiquinone. The next step involved a careful addition of the detergent n-octyl beta-D-glucopyranoside, which resulted in a quantitative shift of the long-wavelength absorbance maximum from 873 to 820 nm. This latter complex was then separated from reaction centers by gel filtration on Sephadex G-100. The pigment-protein complex, now absorbing at 820 nm, contained two polypeptides of about 6-kilodalton molecular mass (referred to as alpha and beta) in a 1:1 ratio and two molecules of bacteriochlorophyll (BChl) for each alpha beta pair. This complex is much smaller in size than the original complex absorbing at 873 nm but probably is an associated form such as alpha 2 beta 2 X 4BChl or alpha 3 beta 3 X 6BChl. The 820-nm form could be completely shifted back to a form once again having a longer wavelength lambda max near 873 nm by decreasing the octyl glucoside concentration. Thus, the complex absorbing at 820 nm appears to be a subunit form of the original 873-nm complex.