Robert MacColl

Biliproteins and phycobilisomes from cyanobacteria and red algae at the extremes of habitat.

Abstract. This review considers the properties of biliproteins from cyanobacteria and red algae that grow in extreme habitats. Three situations are presented: cyanobacteria that grow at high temperatures; a red alga that grows in acidic conditions at high temperature; and an Antarctic red alga that grows in the cold in dim light conditions. In particular, the properties of their biliproteins are compared to those from organisms from more usual environments. C-phycocyanins from two cyanobacteria able to grow at high temperatures are found to differ in their stabilities when compared to C-phycocyanin from mesophilic algae. They differ in opposite ways, however. One is more stable to dissociation than the mesophilic protein, and the other is more easily dissociated at low temperatures. The thermophilic proteins resist thermal denaturation much better than the mesophilic proteins. The most thermophilic cyanobacterium has a C-phycocyanin with a unique blue-shifted absorption maximum which does not appear to be part of the adaptation of the cyanobacterium to high temperature. The C-phycocyanin from the high-temperature red alga is able to resist dissociation better than mesophilic C-phycocyanins. Electron micrographs show the phycobilisomes of these algae. The Antarctic alga grows under ice at some distance down the water column. Its R-phycoerythrin has a novel absorption spectrum that gives the alga an improved ability to harvest blue light. This may enhance its survival in its light-deprived habitat.

Hormone-induced conformational change of the purified soluble hormone binding domain of follitropin receptor complexed with single chain follitropin.

Human follicle-stimulating hormone receptor (hFSHR) belongs to family I of G protein-coupled receptors. FSHR extracellular domain (ECD) is predicted to have 8–9 αβ or leucine-rich repeat motif elements. The objective of this study was to identify elements of the FSHR ECD involved in ligand binding. Preincubation of recombinant hFSHR ECD with rabbit antisera raised against synthetic peptides of hFSHR ECD primary sequence abolished follitropin binding primarily in the region of amino acids 150–254. Accessibility of hFSHR ECD after hormone binding, captured by monoclonal antibodies against either ECD or FSH, was decreased for the region of amino acids 150–220 but additionally for amino acids 15–100. Thus, when hFSH bound first, accessibility of antibody binding was decreased to a much larger extent than if antibody was bound first. This suggestion of a conformational change upon binding was examined further. Circular dichroism spectra were recorded for purified single chain hFSH, hFSHR ECD, and hFSHR ECD-single chain hFSH complex. A spectral change indicated a small but consistent conformational change in the ECD·FSH complex after hormone binding. Taken together, these data demonstrate that FSH binding requires elements within the leucine-rich repeat motifs that form a central region of hFSHR ECD, and a conformational change occurs upon hormone binding.

The relationship of the quaternary structure of allophycocyanin to its spectrum

Abstract Allophycocyanin II in its trimer form (α3β3) at pH 7.0 has an absorption maximum at 652 nm. This band is selectively reduced in intensity at pH 7.0 when various salts are added. The loss of 652 nm absorption follows the order: NaClO4 ⪢ NaNO3 > NaBr > NaCl. When the NaClO4 concentration is in the range 0.6-1.0 m the 652-nm band is entirely lost, and sedimentation equilibrium and velocity studies suggest that the trimer is completely dissociated to monomers (αβ). Hydrophobic interactions appear to be important in maintaining the trimer. The monomer absorption maximum is at 616 nm. A series of experiments using these salts demonstrated at intermediate 652-nm intensities and the two extrema that an isobestic point at 626 nm is present which indicates an equilibrium between two species. Corresponding to the loss of 652 nm absorption is the disappearance of 661 nm fluorescence emission and the appearance of a new band at 642 nm. Removal of the NaClO4 by dialysis essentially restores the 652-nm absorption and 661-nm emission and the trimeric protein structure. The near ultraviolet region is only slightly perturbed during the loss of 652 nm absorption. In the absence of any additional salts these spectral changes also occur in pH 7.0 buffer at very low protein concentrations.

Protein aggregation in C-phycocyanin. Studies at very low concentrations with the photoelectric scanner of the ultracentrifuge

Solutions of C-phycocyanin of very low concentrations were examined by sedimentation-velocity studies in the Spinco model E ultracentrifuge equipped with a photoelectric scanning system and a monochromator. At sufficiently low concentrations complete disaggregation from the hexamer to the monomer was observed. The equilibrium constant of monomer to hexamer was estimated to be approx. 10(30). For studies of aggregation over the complete range of concentration, C-phycocyanins from Phormidium luridum and Lyngbya sp. were used. Sedimentation-velocity studies at high concentration with schlieren optics are reported for C-phycocyanins from Anabaena variabilis and Lyngbya sp. The pH-dependence of aggregation and the temperature-dependence of trimer-hexamer equilibrium for phycocyanins from these algae were found to be similar to those of other C-phycocyanins. The principal feature of the pH-dependence is the dominance of hexamers at the isoelectric point. Increasing temperature increased the amount of hexamer and decreased the amount of trimer.

Effect of salts on C-phycocyanin

Abstract The effect of a number of inorganic anions on the quaternary structure of C-phycocyanin has been investigated by fluorescence polarization. Dissociation to monomer occurred in the order: SCN− > ClO4− > NO3− > Br− > Cl−. These results suggest that hydrophobic interactions are important in the hexamer-monomer equilibrium of C-phycocyanin.

The Discovery of a Novel R-phycoerythrin from an Antarctic Red Alga

A novel biliprotein, named R-phycoerythrin IV, has been discovered. It absorbs blue light better than any other known red algal biliprotein. The protein was found in Phyllophora antarctica, a benthic macroalga, which grows beneath the coastal waters of McMurdo Sound, Antarctica. Fluorescence emission and fluorescence excitation polarization spectroscopy demonstrated that R-phycoerythrin IV behaved as a typical R-phycoerythrin in the functioning of energy migration and has an emission maximum at 577 nm. The circular dichroism (CD) spectrum of the chromophores was compared with visible absorption spectrum, and both were deconvoluted. This process showed the energy states of various individual chromophores. The molecular weight of the protein suggested a α6β6γ polypeptide structure, and far UV CD studies revealed polypeptides with highly α-helical secondary structures. Dynamic light scattering indicated that the protein had a 5.54 nm radius, and its shape was nonspherical. R-phycoerythrin was also purified from a second benthic Antarctic red alga, Iridaea cordata. Its spectroscopic properties were similar to those of some R-phycoerythrins from nonpolar regions. The unique spectroscopic properties of R-phycocerythrin IV may help enable the alga to occupy its niche deeper in the water column than the red alga that has the typical R-phycoerythrin.

Spectroscopic study of the interaction of aluminum ions with human transferrin

Transferrin is the plasma protein responsible for transporting Fe3+ from the absorption to the utilization site. Interactions of apo- and holo-transferrin with Al3+ were studied by circular dichroism (CD), UV-visible, and fluorescence spectrometry. Binding of Al3+ to both metal-ion binding sites of apo-transferrin was confirmed by fluorescence studies. No interaction of Al3+ with holo-transferrin was observed, indicating that Al3+ cannot displace Fe3+ under the experimental conditions employed. An increase in tryptophan fluorescence (lambda max at 330 nm) by excitation at either 280 or 295 nm was observed after Al3+ interaction with apo-transferrin. There was no shift in wavelength of the fluorescence band of apo-transferrin after interaction with Al3+, but the intensity did increase. Since excitation at 295 nm is specific for tryptophan residues, tryptophan but not tyrosine must be responsible for the change in fluorescence intensity. Decreased fluorescence is the result of Fe3+ binding to apo-transferrin. The CD spectrum of apo-transferrin was slightly affected in the far UV by Al3+ binding, but a salient change was noted in the near UV at approximately 288 nm where tyrosine and tryptophan absorb. It is concluded that a small conformational change in the protein was induced by Al3+ binding to apo-transferrin.

The Chromophore and Polypeptide Composition of Aplysia Ink

The composition of the ink of the sea hare, Aplysia, was studied in regard to its tetrapyrrole and polypeptide content. The ink was separated into three pigment components by both thin-layer and gel filtration chromatography. These three pigments have distinctive visible absorption spectra, and--by comparison with known tetrapyrroles--we have demonstrated that they are derived from the three tetrapyrrole chromophores (bilins) found on the biliproteins of certain red algae, which constitute a portion of the Aplysia diet. The red component is phycourobilin; the purple is phycoerythrobilin; and the blue is phycocyanobilin. Sodium dodecyl sulfate gel electrophoresis experiments were also performed. The results of these experiments showed several polypeptides, and major bands at 78,000 and 61,000 molecular weight were noted. Biliproteins, at most, would be minor components of the ink.

ENERGY TRANSFER STUDIES ON CRYPTOMONAD BILIPROTEINS

Abstract. Fluorescence techniques of various types have been used to study the light‐gathering and energy transfer modes for various cryptomonad biliproteins (phycocyanin or phycoerythrins). Analysis of fluorescence polarization and absorption data demonstrates that each cryptomonad biliprotein is composed of at least two distinct types of absorbing chromophore, each attached to the protein through covalent linkages to different polypeptide chains. Examination of the fluorescence emission spectra as a function of excitation at several wavelengths demonstrates that only one of these absorbing chromo‐phores is responsible for the fluorescence. This behavior is consistent with a known phenomenon whereby photons are gathered by more than one chromophore and then after radiationless energy transfer are emitted by only one chromophore.

Picosecond fluorescence spectroscopy of the biliprotein phycocyanin 612: Direct evidence for fast energy transfer

Abstract Energy-transfer processes in phycocyanin 612, a light-harvesting biliprotein from the cryptomonad alga Hemilselmis virescens , have been studied by picosecond fluorescence spectroscopy. Fluorescence was excited with a 30 ps 532 nm laser pulse and detected with a streak camera. Two types of data were obtained. Profiles of intensity versus time using 10 nm band pass interference filters are summarized as follows: emission at wavelengths 650 nm) exhibits a 7 to 10 ps exponential rise time and a long exponential decay (1.0–1.4 ns). In the region from 600 to 640 nm, the time-resolved emission is more complicated; it consists of at least the sum of the shorter and longer wavelength components but additional components cannot be ruled out. The second type of data consists of spectra (intensity versus wavelength) taken at various times relative to the excitation pulse. These spectra qualitatively confirm the interference filter results. The kinetic results are interpreted in terms of Forster energy transfer between spectrally different chromophores within the biliprotein. Thus the emission of phycocyanin 612 provides a direct probe for studying the fast component of fluorescence during an energy transfer process.