Hexagonal Bilayer Structure Research Articles

Strong adsorbate-adsorbate interactions in the H 2O/Pd(110) system

The chemisorption of water on clean Pd(11O) and its coadsorption with CO 2 or O was studied using HREELS and TPD. On the clean surface HREELS spectra reveal two distinct arrangements below the onset of multilayer growth while there is only one TPD peak in this coverage range. We propose that at low coverages tetramers are formed whereas at intermediate coverages these tetramers coalesce into islands with the distorted hexagonal bilayer structure. The bilayer model for the saturated chemisorbed layer is carefully scrutinized and found to be in agreement with all the experimental results for Pd(110). Water coadsorption with CO 2 is dominated by a charge transfer from H 2O to CO 2 which is mediated by the metal surface. This leads to the formation of a bent CO 2 δ− species. The interaction between water and oxygen is a strong function of oxygen coverage. At low coverage a direct interaction leads either to the dissociation of water or to the formation of an O-H 2O complex. When the surface is covered with oxygen, the strength of the water surface bond is significantly reduced compared to the clean surface.

The calcium, copper and zinc content of some annelid extracellular haemoglobins.

The extracellular haemoglobins of Lumbricus and Tylorrhynchus contain 50 and 61 tightly bound calcium atoms per molecule, respectively. In addition, they contain one to four tightly bound copper and zinc atoms. Although the role of the latter is unknown, that of calcium is probably structural, assisting in the maintenance of the native hexagonal bilayer structure.

Scanning transmission electron microscopic examination of the hexagonal bilayer structures formed by the reassociation of three of the four subunits of the extracellular hemoglobin of Lumbricus terrestris.

A fraction obtained by gel filtration at neutral pH of the extracellular Hb of Lumbricus terrestris dissociated either at pH 9.8 or at pH 4.0, consisting of the three subunits D1 (31 kDa), D2 (37 kDa), and T (50 kDa), was found to produce two peaks when subjected to gel filtration on Superose 6 at pH 7. The first peak, which was eluted at a slightly greater volume than the native Hb, consisted of reassociated hexagonal bilayer structures when examined by scanning transmission electron microscopy. The dimensions of the two reassociated hexagonal bilayer structures were a vertex-to-vertex diameter of 25 nm and a height of 16 nm. The difference in size between the hexagonal bilayer structures and the native Hb is the contribution of subunit M, which consists of a single heme-containing chain I (16.75 kDa). Although the reassociated hexagonal bilayer structures have overall dimensions smaller than the 30 nm x 20 nm dimensions of the native Hb, the diameters of the central cavities are not substantially altered. Subtraction of the three-dimensional reconstructions of the reassociated hexagonal bilayer structures from those of the native Hb showed that subunit M was primarily localized at the periphery of Lumbricus Hb. The formation of hexagonal bilayer structures in the complete absence of subunit M provides additional support for the "bracelet" model of the quaternary structure of Lumbricus Hb proposed recently by us in which subunits D1 and D2 were assumed to act as linkers for complexes of subunits M and T or to form a "bracelet" decorated with 12 complexes of subunits M and T.

Bracelet protein: a quaternary structure proposed for the giant extracellular hemoglobin of Lumbricus terrestris.

The complete dissociation of the hexagonal bilayer structure of Lumbricus terrestris hemoglobin (3900 kDa) at neutral pH, in the presence of urea, guanidine hydrochloride, sodium perchlorate, potassium thiocyanate, sodium phosphotungstate, and sodium phosphomolybdate, followed by gel filtration at neutral pH on Sephacryl S-200 or Superose 6, produced two fragments, II (65 kDa) and III (17 kDa); NaDodSO4/polyacrylamide gel electrophoresis showed that peak II consisted of subunits D1 (31 kDa, chain V), D2 (37 kDa, chain VI), and T (50 kDa, disulfide-bonded trimer of chains II, III, and IV) and that peak II consisted of subunit M (16 kDa, chain I). When dissociation was incomplete, two additional peaks were present, peak Ia eluting at the same volume as the whole hemoglobin and peak Ib (200 kDa). Scanning transmission electron micrographs of peak Ia showed it to consist of whole molecules and of incomplete hexagonal bilayer structures, missing an apparent 1/12th. Peak Ib contained all four subunits but was usually deficient in subunits D1 and D2, was not always in equilibrium with the whole molecule, and could be dissociated further into II and III. The patterns of dissociation observed at neutral pH were very similar to those observed previously at alkaline pH and at acid pH and appear to be incompatible with the generally accepted multimeric model of Lumbricus hemoglobin subunit structure. A model is proposed in which it is postulated that the stoichiometries of some of the subunits need not be constant and that subunits D1 and D2 either form a "bracelet" decorated with complexes of T and M subunits or serve as "linkers" between the latter, to provide the appearance of a two-tiered hexagonal structure. Additional support for the proposed model comes from observations that the fragment II obtained subsequent to dissociation at pH 4, in sodium phosphotungstate, in sodium perchlorate, and in potassium thiocyanate was found to be in equilibrium with a hexagonal bilayer structure IaR(II), whose dimensions were approximately equal to 20% smaller than those of the native hemoglobin.

Preparation and characterization of monoclonal antibodies to the extracellular hemoglobin of Lumbricus terrestris

Murine monoclonal antibodies to the extracellular hemoglobin of Lumbricus terrestris were prepared by a modification of the method of Kohler and Milstein. 224 hybridomas were found to produce antibodies which bound to the hemoglobin; they were tested for binding to the four subunits of the hemoglobin: M (chain I, 16 kDa), D1 (chain V, 31 kDa), D2 (chain VI, 37 kDa) and T (50 kDa), a disulfide-bonded trimer of chains II, III and IV, each of about 17 kDa. 150 hybridomas bound to all four subunits and 40 hydridomas bound to various combinations of subunits. The remaining 34 hybridomas combined only with the hemoglobin. The twelve hybridomas obtained after subculturing and cloning were tested for their binding to the two fractions II and III, consisting of subunits D1 +D2 + T and M, respectively, obtained by dissociation at pH 9.5 and at pH 4.0 and to the reassociated whole molecules, obtained subsequent to return to neutral pH. Eight hybridomas which combined only with the hemoglobin also combined with all the reassociated molecules but not with any of the fractions: these monoclonal antibodies probably recognize conformation-dependent antigenic sites that are present only in the hexagonal bilayer structure characteristic of the native and reassociated hemoglobin molecules. Of the remaining four hybridomas, two bound to subunit T and two combined with subunits T and D2; they also combined with the reassociated molecules and with the fractions II. In addition, the hybridomas did not bind to the hemoglobins of Tubifex, Limnodrilus, Arenicola, Tylorrhynchus and Macrobdella or to the chlorocruorins of Myxicola and Eudistylia.