Three different actin filament assemblies occur in every hair cell: each contains a specific actin crosslinking protein

The apex of hair cells of the chicken auditory organ contains three different kinds of assemblies of actin filaments in close spatial proximity. These are (a) paracrystals of actin filaments with identical polarity in stereocilia, (b) a dense gellike meshwork of actin filaments forming the cuticular plate, and (c) a bundle of parallel actin filaments with mixed polarities that constitute the circumferential filament belt attached to the cytoplasmic aspect of the zonula adhaerens (ZA). Each different supramolecular assembly of actin filaments contains a specific actin filament cross-linking protein which is unique to that particular assembly. Thus fimbrin appears to be responsible for paracrystallin packing of actin filaments in stereocillia; an isoform of spectrin resides in the cuticular plate where it forms the whisker-like crossbridges, and alpha actinin is the actin crosslinking protein of the circumferential ZA bundle. Tropomyosin, which stabilizes actin filaments, is present in all the actin filament assemblies except for the stereocilia. Another striking finding was that myosin appears to be absent from the ZA ring and cuticular plate of hair cells although present in the ZA ring of supporting cells. The abundance of myosin in the ZA ring of the surrounding supporting cells means that it may be important in forming a supporting tensile cellular framework in which the hair cells are inserted.     

Assembly and disulfide rearrangement of recombinant surfactant protein A in vitro

The surfactant-associated protein, protein A, produced by transgenic Chinese hamster ovary cells exhibits a heterogeneous population of structures. Electron microscopy reveals lollipop-shaped monomers consisting of a collagenous triple helix and a globular domain as well as oligomers in which two, three or more protomers are connected by their collagenous stalks. Each protomer consists of three alpha-chains (36 kDa) but under non-reducing conditions few free alpha-chains are observed by SDS/PAGE. Instead gamma-components (three chains), gamma 2 (six chains) and higher components are observed which are derived from intra- and inter-protomer disulfide cross-linking. Complete reduction at low temperature dissociates the oligomers, but preserves the intact structure of monomers as demonstrated by electron microscopy and trypsin digestion. Circular dichroism revealed an unfolding of the collagen triple helices of fully reduced protein A at 26 degrees C and of the unreduced protein A around 41.5 degrees C. Reoxidation of the fully reduced protein A re-established mainly the disulfide bonds within the triple helix but not between monomers. Very few higher assembly forms were reformed even at high protein A concentrations. Cellular in vivo systems must possess an efficient assembly mechanism which cannot be simulated by an in vitro system.     

In vitro assembly of gap junctions.

Gap junction structures were assembled in vitro from octyl-beta-D-glucopyranoside-solubilized components of lens fiber cell membranes. Individual pore structures (connexons), short double-membrane structures, and other amorphous material were evident in the solubilized mixture. Following the removal of the detergent by dialysis, these connexons associated to form single- and double-layered, two-dimensional hexagonal arrays (unit cell size a = b = 8.5 nm). The formation of larger arrays was dependent on the lipid-to-protein ratio and the presence of Mg2+ ions. Crystallographic analysis of electron micrographs revealed that lens junctional connexons consisted of six subunits surrounding a stain-filled channel. Upon further detergent treatment, in vitro assembled gap junctions were insoluble and formed three-dimensional stacks while other components were solubilized. SDS-PAGE and mass data from scanning transmission electron microscopy strongly suggest that a 38-kDa polypeptide, which is a processed form of the lens specific gap junction protein MP70, is a major component of the arrays. The in vitro assembly of gap junctions opens new avenues for the structural analysis of gap junctions and for the study of the intermolecular interactions of connexons during junctional assembly.     

Murein-metabolizing enzymes from Escherichia coli: existence of a second lytic transglycosylase.

In addition to the soluble lytic transglycosylase, a murein-metabolizing enzyme with a molecular mass of 70 kDa (Slt70), Escherichia coli possesses a second lytic transglycosylase, which has been described as a membrane-bound lytic transglycosylase (Mlt; 35 kDa; EC 3.2.1.-). The mlt gene, which supposedly encodes Mlt, was cloned, and the complete nucleotide sequence was determined. The open reading frame, identified on a 1.7-kb SalI-PstI fragment, codes for a protein of 323 amino acids (M(r) = 37,410). Two transmembrane helices and one membrane-associated helix were predicted in the N-terminal half of the protein. Lysine and arginine residues represent up to 15% of the amino acids, resulting in a calculated isoelectric point of 10.0. The deduced primary structure did not show significant sequence similarity to Slt70 from E. coli. High-level expression of the presumed mlt gene was not paralleled by an increase in murein hydrolase activity. To clarify the identity of the second transglycosylase, we purified an enzyme with the specificity of a transglycosylase from an E. coli slt deletion strain. The completely soluble transglycosylase, with a molecular mass of approximately 35 kDa, was designated Slt35. Its determined 26 N-terminal amino acids showed similarity to a segment in the middle of the Slt70 primary structure. Polyclonal anti-Mlt antibodies, which had been used for the isolation of the mlt gene, were found to cross-react with Mlt as well as with Slt35, suggesting that the previously described Mlt preparation was contaminated with Slt35. We conclude that the second transglycosylase of E. coli is not a membrane-bound protein but rather is a soluble protein.     

In vivo magnetic resonance imaging of the blue crab, Callinectes sapidus: effect of cadmium accumulation in tissues on proton relaxation properties.

Nuclear magnetic resonance imaging (MRI) has been used to visualize the internal anatomy of a living blue crab. The resolution obtained in these studies was sufficient to distinguish individual organs by the differences in their proton densities and proton relaxation properties. T1 (spin-lattice relaxation time)-weighted imaging revealed the lipid-rich nature of the hepatopancreas and gonadal tissue. To evaluate the effect of metal-induced stress on the different organs, crabs were exposed to elevated levels of cadmium in their diet, which resulted in increased concentrations of both cadmium and copper in the hepatopancreas. The spin-spin relaxation time, T2, of mobile protons in the metal-exposed tissue was significantly greater than T2 in the control tissues. These measurements suggest that the excess copper in the exposed tissues was diamagnetic [Cu(I)], since the presence of paramagnetic copper [Cu(II)] would result in a decrease of observed T2 values. We hypothesize that the increased T2 value is a reflection of increased free water in the hepatopancreas. These studies show that magnetic resonance imaging is an important nondestructive tool for the study of morphological and physiological changes that occur in marine invertebrates in response to anthropogenic and natural stresses.     

Ubiquitous soluble Mg(2+)-ATPase complex. A structural study.

We have performed a detailed structural analysis of the soluble Mg(2+)-ATPase complex purified from Xenopus laevis ovary, which is an abundant and ubiquitous homo-oligomeric protein complex located in the nucleus and in the cytoplasm, belonging to a novel multigene-family of putative Mg(2+)-ATPases. Enzyme activity staining after non-denaturing polyacrylamide gel electrophoresis revealed that Mg(2+)-ATPase activity of the native protein is dependent on oligomerization and could not be detected in dissociated subunits. For the native protein a sedimentation coefficient of 15.3 S and a corresponding relative molecular mass of 612,000 was determined by analytical ultracentrifugation and a relative molecular mass of 590,000 was estimated from scanning transmission electron microscopy, supporting our previous conclusion that the oligomer comprises six 97,000 Mr subunits. Conventional electron microscopy of negatively stained specimens revealed the Mg(2+)-ATPase complex to be a hexagonal molecule in its favoured "end-on" projection and a double-banded molecule in its "side-on" projection (approx. 12 nm diameter; approx. 9 nm height). In addition, dimerized complexes could be observed in negatively stained specimens, yielding pronounced hexameric images and four-banded images in their end-on and side-on orientations, respectively (approx. 12 nm diameter; approx. 18.5 nm height). Two-dimensional (2D = mono-molecular) crystals have been produced from the dimerized complexes by the negative staining carbon film technique. Hexagonal crystals with a p6 plane group symmetry were obtained from molecules in their end-on orientation and longitudinal arrays with a p2 symmetry from complexes in their side-on orientation. A low-resolution molecular model of the native protein, derived from averages of these two 2D crystals, is presented. From our results we propose oligomerization as an inherent structural principle of organization for this whole newly defined Mg(2+)-ATPase multigene-family, that includes such seemingly diverse functionally defined proteins as mammalian and yeast "vesicle fusion" and "peroxisome assembly" proteins and the product of the yeast cell cycle gene CDC48.     

Functional properties of ficoll and their influence on anther culture responses of wheat

The effects of ficoll in liquid culture media have been contradictory in previous reports. The objective of this study was to determine the functional properties of ficoll in potato 4 (P4) liquid induction medium and their influence on anther culture responses of wheat. Ficoll addition significantly (p0.01) reduced callus production from the anthers of spring wheat cv. Pavon 76. The reduction was directly related to the concentration of ficoll added within the range of 50 to 200 g l^-1 medium. Although the addition of ficoll significantly (p0.01) increased the percentage of regenerable calli and the ratio of green vs. albino plants, the final yield of green plants per 100 anthers was significantly lower. Consistent results also were obtained with four other spring wheat genotypes (Chris, Butte 86, WA 6916, and Edwall). Ficoll concentration affected the density, viscosity, and osmolality of the liquid media. The higher medium density caused by ficoll addition increased the percentage of floating calli, as well as the percentage of regenerable calli and the ratio of green vs. albino plants. However, the increased medium viscosity by ficoll addition significantly (p0.01) reduced callus production. Ficoll addition also increased medium osmolality, which affected callus production by interacting with the sugar concentration of the induction media. Using response functions, the estimated maltose concentration for maximum callus production was 105 g l^-1 for the standard P4 media, compared with 68 g l^-1 for the ficoll-containing P4 media. These results clearly demonstrate that ficoll addition to the liquid P4 induction medium containing high sucrose concentration (90 g l^-1) is deleterious to the maximum production of green plants from wheat anther culture.