Darrell R. McCaslin

Allografts of the liver, which has a comparatively heavy leukocyte content compared with other vascularized organs, are accepted permanently across major histocompatibility complex barriers in many murine strain combinations without immunosuppressive therapy. It has been postulated that this inherent tolerogenicity of the liver may be a consequence of the migration and perpetuation within host lymphoid tissues of potentially tolerogenic donor-derived ("chimeric") leukocytes, in particular, the precursors of chimeric dendritic cells (DC). In this study, we have used granulocyte/macrophage colony-stimulating factor to induce the propagation of progenitors that give rise to DC (CD45+, CD11c+, 33D1+, nonlymphoid dendritic cell 145+, major histocompatibility complex class II+, B7-1+) in liquid cultures of murine bone marrow cells. Using this technique, together with immunocytochemical and molecular methods, we show that, in addition to cells expressing female host (C3H) phenotype (H-2Kk+; I-E+; Y chromosome-), a minor population of male donor (B10)-derived cells (H-2Kb+; I-A+; Y chromosome+) can also be grown in 10-d DC cultures from the bone marrow of liver allograft recipients 14 d after transplant. Highly purified nonlymphoid dendritic cell 145+ DC sorted from these bone marrow-derived cell cultures were shown to comprise approximately 1-10% cells of donor origin (Y chromosome+) by polymerase chain reaction analysis. In addition, sorted DC stimulated naive, recipient strain T lymphocytes in primary mixed leukocyte cultures. Evidence was also obtained for the growth of donor-derived cells from the spleen but not the thymus. In contrast, donor cells could not be propagated from the bone marrow or other lymphoid tissues of nonimmunosuppressed C3H mice rejecting cardiac allografts from the same donor strain (B10). These findings provide a basis for the establishment and perpetuation of cell chimerism after organ transplantation.

This paper describes the structural and biochemical characterization of talin, a protein localized to various cellular sites where bundles of actin filaments attach to the plasma membrane. By sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the protein has a molecular mass of 225,000 +/- 5,000 daltons. Hydrodynamic measurements at protein concentrations less than 0.72 mg/ml indicate a monomeric protein with a native molecular mass of 213,000 +/- 15,000 daltons. Sedimentation equilibrium experiments indicate self-association at protein concentrations of 0.72 mg/ml and higher. The data suggest that this self-association is a simple monomer:dimer equilibrium over the range of concentrations observed. At low protein concentrations where talin is a monomer, the Stokes radius and sedimentation coefficient vary with ionic strength. Under low ionic strength conditions (5-20 mM NaCl), talin has a Stokes radius of 6.5 nm and a sedimentation value of 9.4, suggesting an asymmetric globular molecule; whereas under high ionic strength conditions (200 mM NaCl), the Stokes radius increases to 7.7 nm and the sedimentation coefficient decreases to 8.8, suggesting a more elongated protein. This conformation change is confirmed by electron microscopy which reveals a more globular protein at low ionic strength which unfolds to become an elongated flexible molecule as the ionic strength is increased to physiological and higher levels. The amino acid composition of talin indicates a low level of aromatic residues, consistent with its relatively low extinction coefficient, talin has an isoelectric point between pH 6.7 and 6.8 based on isoelectric focusing. The detailed purification of talin is described.

Two-dimensional crystals of rhodopsin have been prepared from purified frog disk membranes by using the detergent Tween 80. The space group of the orthorhombic crystals is p22121; the unit cell dimensions are 47 X 151 A. Projection maps of negatively stained preparations have been calculated to a resolution of approximately 22 A. The rhodopsin molecules are associated as dimers that appear to be slightly sigmoidal and are 20-25 A in width and 70-80 A in length.

The effects of Staphylococcus aureus V8 protease (V8) on the multimeric structure of human von Willebrand factor (vWF) were studied to test and expand our model for the substructure of vWF. Electron microscopy of V8 digests of vWF revealed that the multimers were cleaved where the flexible rod (R) domains join the large elongated globular (G) domains. The resulting two major fragments, which were purified by affinity and hydrophobic interaction chromatography and by glycerol-gradient ultracentrifugation, are disulfide-linked homodimers of these domains (i.e. RR and GG) and are morphologically identical to the alternating RR and GG domains of intact vWF. The glycoprotein fragment GG (6.5 X 35 nm) has mass 343 kDa by sedimentation equilibrium and the amino-terminal sequence of intact plasma vWF. It contains the binding site for heparin within 300 residues of its amino terminus and a separate site for the platelet GPIb receptor responsible for platelet agglutination in the presence of ristocetin. With approximately 18% alpha-helix and approximately 15% beta-pleated sheet, fragment GG accounts for most of the ordered secondary structure present in whole vWF. The two thin flexible rod domains (1.8-2.0 X 30-34 nm) of fragment RR are joined at a small central nodule (approximately 5 nm diameter) and also have a small nodule at each free end. Fragment RR contains an extraordinarily high cystine content, lower than average amounts of other hydrophobic residues, and essentially no alpha-helix, as judged by circular dichroism. The amino-terminal sequence and amino acid composition of fragment RR corresponded to that of the COOH-terminal 685 residues of the intact vWF subunit (Titani, K., Kumar, S., Takio, K., Ericsson, L. H., Wade, R. D., Ashida, K., Walsh, K. A., Chopek, M. W., Sadler, J. E., and Fujikawa, K. (1986) Biochemistry 25, 3171-3184). This sequence analysis gives a mass of 180 kDa for glycosylated fragment RR, somewhat higher than the 130 kDa we obtained by sedimentation equilibrium. Our sequence analysis of a 110-kDa plasmic vWF peptide also permitted identification of a major plasmin cleavage site 705 residues from the COOH terminus and a half-cystine residue (1360) involved in maintaining the multimeric structure of plasmin-degraded vWF.(ABSTRACT TRUNCATED AT 400 WORDS)