Terminal deletion mutants of myelin basic protein: new insights into self-association and phospholipid interactions

The 18.5kDa isoform of myelin basic protein (MBP) has strong and probably specific interactions with phosphoinositides that are of interest regarding this protein's function, and in effecting its two-dimensional crystallization for structural determination. We have designed and constructed truncation mutants of recombinant 18.5kDa murine myelin basic protein (rmMBP) lacking either the N- or C-terminal third, i.e. rmMBPDeltaN and rmMBPDeltaC, respectively. Both variants rmMBPDeltaC and rmMBPDeltaN generally had a reduced ability to aggregate lipid vesicles, compared to the whole protein, especially at lower protein/lipid ratios. Lipid vesicle cosedimentation showed that both truncated variants exhibited altered binding with phosphatidylinositol (PI). Incubation of these proteins under monolayers comprising PI and a nickel-chelating lipid yielded crystalline arrays of rmMBPDeltaC (but not rmMBPDeltaN) in the absence of high salt or osmolytes, which are required for crystallization of whole protein. This result suggests that the C-terminal segment of MBP is a significant source of conformational heterogeneity, and its removal will facilitate future planar or three-dimensional crystallization attempts. Incubation of rmMBPDeltaN and rmMBPDeltaC under monolayers comprising phosphatidylinositol-4-phosphate and a nickel-chelating lipid yielded tubular structures of opposite chirality, suggesting a synergistic effect of both termini of MBP in organizing myelin lipids.     

Analysis of the induction of the myelin basic protein binding to the plasma membrane phospholipid monolayer

Myelin basic protein(MBP) is an essential structure involved in the generation of central nervous system(CNS)myelin.Myelin shape has been described as liquid crystal structure of biological membrane.The interactions of MBP with monolayers of different lipid compositions are responsible for the multi-lamellar structure and stability of myelin.In this paper,we have designed MBP-incorporated model lipid monolayers and studied the phase behavior of MBP adsorbed on the plasma membrane at the air/water interface by thermodynamic method and atomic force microscopy(AFM).By analyzing the pressure–area(π–A) and pressure–time(π–T) isotherms,univariate linear regression equation was obtained.In addition,the elastic modulus,surface pressure increase,maximal insertion pressure,and synergy factor of monolayers were detected.These parameters can be used to modulate the monolayers binding of protein,and the results show that MBP has the strongest affinity for 1,2-dipalmitoyl-sn-glycero-3-phosphoserine(DPPS) monolayer,followed by DPPC/DPPS mixed and1,2-dipalmitoyl-sn-glycero-3-phospho-choline(DPPC) monolayers via electrostatic and hydrophobic interactions.AFM images of DPPS and DPPC/DPPS mixed monolayers in the presence of MBP(5 n M) show a phase separation texture at the surface pressure of 20 m N/m and the incorporation of MBP put into the DPPC monolayers has exerted a significant effect on the domain structure.MBP is not an integral membrane protein but,due to its positive charge,interacts with the lipid head groups and stabilizes the membranes.The interaction between MBP and phospholipid membrane to determine the nervous system of the disease has a good biophysical significance and medical value.     

Direct magnitude and phase imaging of myelin using ultrashort echo time (UTE) pulse sequences: A feasibility study

In this paper, we aimed to investigate the feasibility of direct visualization of myelin, including myelin lipid and myelin basic protein (MBP), using two-dimensional ultrashort echo time (2D UTE) sequences and utilize phase information as a contrast mechanism in phantoms and in volunteers. The standard UTE sequence was used to detect both myelin and long T2 signal. An adiabatic inversion recovery UTE (IR-UTE) sequence was used to selectively detect myelin by suppressing signal from long T2 water protons. Magnitude and phase imaging and T2* were investigated on myelin lipid and MBP in the forms of lyophilized powders as well as paste-like phantoms with the powder mixed with D₂O, and rubber phantoms as well as healthy volunteers. Contrast to noise ratio (CNR) between white and gray matter was measured. Both magnitude and phase images were generated for myelin and rubber phantoms as well white matter in vivo using the IR-UTE sequence. T2* values of ~ 300 μs were comparable for myelin paste phantoms and the short T2* component in white matter of the brain in vivo. Mean CNR between white and gray matter in IR-UTE imaging was increased from − 7.3 for the magnitude images to 57.4 for the phase images. The preliminary results suggest that the IR-UTE sequence allows simultaneous magnitude and phase imaging of myelin in vitro and in vivo.     

A Nanosecond Time-Resolved Fluorescence Study of Recombinant Human Myelin Basic Protein

Myelin basic protein (MBP) is a major component of myelin and plays a central role in the maintenance of its compact multilayered structure. Tryptophan fluorescence is sensitive to environmental factors such as polarity and rotational mobility and often reflects conformational changes in proteins. This work describes a detailed examination of the time-resolved emission properties of the single tryptophan of recombinant human myelin basic protein. Fluorescence decay curves were collected at two separate excitation wavelengths and at different wavelengths across the emission spectrum. The fitting parameters obtained with the aid of global analysis were combined with steady-state emission spectra collected from the same samples and are presented as decay-associated spectra (DAS) and time-resolved emission spectra (TRES). The effects of temperature and binding to anionic membranes on the decay of emission of MBP were investigated. The changes in fitted parameters and the appearance of DAS and TRES as a function of experimental conditions are interpreted in terms of variation in the local environment of the single tryptophan in MBP. The implications of the changes in local environment resulting from experimental treatments are discussed in the context of the overall conformation of MBP and are compared to structural and photophysical properties of MBP obtained from the central nervous system tissue of several species [P. Cavatorta, S. Giovanelli, A. Bobba, P. Riccio, and E. Quagliariello, Acta Neurol. (Napoli) 13, 162–169, (1991; P. Cavatorta, S. Giovanelli, A. Bobba, P. Riccio, A. G. Szabo, and E. Quagliarello, Biophys. J. 66, 1174–1179, 1994; P. Cavatorta, L. Masotti, A. G. Szabo, D. Juretic, P. Riccio, and E. Quagliariello, Cell Biophys. 13, 201–215, 1988].     

Fluorescence lifetime study of ECFP/EYFP labeled MBP in Förster resonance energy transfer

This paper studies the conformational change of the binding protein by a fluorescence lifetime method. As a model protein, maltose binding protein (MBP) where enhanced cyan protein (ECFP) and enhanced yellow fluorescent protein (EYFP) were genetically fused to act as a donor and an acceptor in Förster resonance energy transfer (FRET) was used. The ECFP and the EYFP were linked to the C-terminal and N-terminal regions of the MBP, respectively. In order to investigate the conformational change of the MBP, the lifetime of the ECFP, which acts as a donor in the ECFP:MBP:EYFP fusion protein, was analyzed during the FRET process. We observed that two lifetime components exist when the ECFP is linked to the MBP and that the lifetime of the ECFP is shortened when ECFP:MBP:EYFP protein undergoes a conformational change as a result of the maltose binding. In addition, we observed that the lifetime of the donor is gradually shorter in the ECFP:MBP:EYFP fusion protein as the maltose concentration increases. By a lifetime analysis and simulation study, we found that the participant rate of the ECFP:MBP:EYFP protein in FRET is the main cause of the donor lifetime shortening in relation to the increase of the maltose concentration.     

Caveolae and caveolin isoforms in rat peritoneal macrophages

Caveolea are special (highly hydrophobic) plasma membrane invaginations with a diameter of 50-100 nm. Their characteristic features are the flask- or omega-shape and the lack of basket-like coat composed of clathrin. Caveolin-an integral membrane protein-is the principal component of caveolae membranes in vivo. Multiple forms of caveolin have been identified: caveolin-1alpha, caveolin-1beta, caveolin-2 and caveolin-3. They differ in their specific properties and tissue distribution. In this paper we summarize the morphological and biochemical data providing strong evidence about the existence and function of caveolae in rat peritoneal macrophages. When studied electron microscopically, the surface of both resident and elicited macrophages exhibited omega- or flask-shaped plasma membrane invaginations. There was a significant difference, however, in the number of these profiles: whereas in resident cells only a small amount of them was found on the cell surface, in elicited cells they were abundantly present on the plasma membrane. Using an antibody against the VIP21/caveolin-1 isoform we showed that these plasma membrane pits were indeed caveolae. The number and the appearance of caveolae were found to be in close correlation with the functional activity of these phagocytotic cells, indicating that the formation of caveolae is a highly regulated process.Using Western blot analysis two different proteins ( approximately 29 and approximately 20 kDa)-both labelled with anti-caveolin antibodies-were identified in resident and elicited macrophages that have been isolated from rat peritoneal cavity. The approximately 20 kDa protein was labelled specifically only by anti-VIP21/caveolin-1, while the approximately 29 kDa protein was labelled by both anti-VIP21/caveolin-1 and anti-caveolin-2 antibodies. The presence of the approximately 29 kDa protein was highly characteristic of resident cells, and only a small amount of approximately 20 kDa protein was detected in these cells. Elicitation has resulted in a significant increase in the amount of approximately 20 kDa protein labeled only with anit-VIP21/caveolin-1. Our morphological (confocal and electron microscopical) studies have shown that in resident cells caveolin was present in the cytoplasm, in smaller vesicles and multivesicular bodies around the Golgi area. Only a very small amount of caveolae was found on the cell surface of these cells. In elicited macrophages, caveolae (labelled with anti-VIP21/caveolin-1 antibody) appeared in large numbers on the cell surface, but caveolin detected by anti-caveolin-2 was also found in small vesicles and multivesicular bodies. These data support the idea that the expression of the approximately 29 kDa (caveolin-related) protein is insufficient for caveolae formation in resident cells, it can function as a modified, macrophage-specific caveolin-2 isoform.Our results strongly suggest that caveolin-1 plays a crucial role in the formation of caveolae: it is the amount of caveolin-1 that regulates the appearance of caveolae on the plasma membrane.Studying the endocytotic processes of resident and elicited macrophages we have found that elicited macrophages bound and internalized significantly larger amounts of fluid phase marker (HRP) and immune complex (peroxidase-antiperoxidase-PAP) than resident cells. Serial section analysis, double labelled immunocytochemistry, and filipin treatment were used to demonstrate that caveolae can pinch off from the plasma membrane and can take part in endocytotic processes as alternative carriers in elicited macrophages.     

Positive effects and mechanism of ultrasound on chitin preparation from shrimp shells by co-fermentation

The objective of this study is to explore the effect and mechanism of ultrasound on chitin extraction from shrimp shells powder (SSP) by the co-fermentation of Bacillus subtilis and Acetobacter pasteurianus. After pre-treating the SSP with high-intensity ultrasound (HIU) at 800 W, the protease activity in the fermentation solution reached 96.9 U/mL on day 3, which was significantly higher than for SSP that had not been pre-treated with ultrasound (81.8 U/mL). The fermentation time of the chitin extraction process was 5.0 d without ultrasound pre-treatment, while it was shortened to 4.5 d when using ultrasound at 800 W to treat SSP. However, there were no obvious differences when we applied ultrasound at low power (200 W, 400 W). Furthermore, chitin purified from shrimp shells pre-treated with HIU at 800 W exhibited lower molecular weight (11.2 kDa), higher chitin purity (89.8%), and a higher degree of deacetylation (21.1%) compared to SSP with no ultrasound pre-treatment (13.5 kDa, 86.6%, 18.5%). Results indicate that HIU peels off the protein/CaCO₃ matrix that covers the SSP surface. About 9.1% of protein and 4.7% of Ca²⁺ were released from SSP pre-treated with HIU at 800 W. These figures were both higher than with no ultrasound pre-treatment (4.5%, 3.2%). Additionally, the amount of soluble protein extracted from SSP through HIU at 800 W was 50% higher than for the control sample. SDS-PAGE analysis indicated that the soluble protein was degraded to the micromolecule. It also revealed that HIU (600, 800 W) induced the secondary and tertiary structure destruction of protein extracted from SSP. In conclusion, HIU-induced degradation and structural damage of protein enhances the protein/CaCO₃ matrix to be peeled off from SSP. Also, in the co-fermentation process, an increase of protease activity further accelerates deproteinization.     

ESI-MS and MALLS analysis of quaternary structure of molluscan hemocyanins

The understanding of the function of macromolecular complexes is mainly related to a precise knowledge of their structure. Recently, the development of suitable mass spectrometric techniques (electrospray ionization (ESI) and matrix-assisted laser desorption/ionization (MALDI)) and multi-angle laser light scattering has enabled mass determination of native complexes and of their subunits. By these techniques, the structure and association/dissociation behavior of huge molecules of molluscan Octopus vulgaris, Sepia officinalis and Rapana venosa have been characterized. Molecular masses of the native and dissociated molecule of cephalopodan Hcs O. vulgaris (3545 and 359.3?kDa, respectively) and S. officinalis (4134 and 443.8?kDa, respectively) revealed that only one type subunit organizes their molecules, while the presence of two isoforms with different masses (422.8 and 400.0?kDa) has been determined for gastropodan R. venosa Hc, aggregated into didecamers. The difference of their structural subunits was also established after limited proteolysis with TPCK-trypsin. Eight functional units (FUs) with masses of?~?50?kDa were isolated from both subunits of RvH and isoform of Sepia officinalis, while seven FUs were purified from OvH. Further characterization of proteins by ESI-mass spectrometry (MS) and MALDI-MS, methods gave insights into post-translational modifications such as glycosylation. Glycosylation of O. vulgaris and S. officinalis Hcs was suggested based on the differences (11.6 and 40.0?kDa, respectively) between the masses measured by ESI-MS and those calculated by their gene sequences.     

Maltose Binding Protein Is Partially Structured in Its Molten Globule State

Seven double cysteine mutants of maltose binding protein (MBP) were generated with one each in the active cleft at position 298 and the second cysteine distributed over both domains of the protein. These cysteines were spin labeled and distances between the labels in biradical pairs determined by pulsed double electron–electron resonance (DEER) measurements. The values were compared with theoretical predictions of distances between the labels in biradicals constructed by molecular modeling from the crystal structure of MBP without maltose and were found to be in excellent agreement. MBP is in a molten globule state at pH 3.3 and is known to still bind its substrate maltose. The nitroxide spin label was sufficiently stable under these conditions. In preliminary experiments, DEER measurements were carried out with one of the mutants yielding a broad distance distribution as was to be expected if there is no explicit tertiary structure and the individual helices pointing into all possible directions.