Arsenite uptake and metabolism by rat hepatocyte primary cultures in comparison with kidney- and hepatocyte-derived rat cell lines.

Biotransformation by methylation to monomethylarsonic acid (MMA) and dimethylarsinic acid (DMA) influences inorganic arsenical toxicity, which is often investigated in cultured cells. Arsenic (III) uptake and methylation was assessed in rat hepatocytes in primary culture and in three established rat cell lines (hepatoma-derived McA-RH 7777 cells and H4-II-EC-3 cells, and kidney epithelium-derived NRK-52E cells) to compare their use as model systems for arsenite metabolism. Incubation of all cell types with 0.27, 0.67, 1.33, 2.67, or 6.67 microM As(III) concentrations resulted in concentration-dependent arsenic uptake and biomethylation. Arsenic uptake by the NRK-52E cells was initially slower than that of the other cells, but by 8 h, total uptake was similar in all cell types. At the lowest arsenite concentration, the percentages of total arsenic methylated to MMA and DMA by the hepatocytes and the McA-RH 7777 cells were similar (67 and 66%); methylation by the H4-II-EC-3 cells was somewhat lower (52%), and methylation by the kidney-derived NRK-52E cells was much lower (15%). Total arsenic methylation was inhibited in the cell lines, but not in the hepatocytes, at the highest arsenite concentrations. In all cases, exposure to increased arsenite concentrations inhibited conversion of MMA to DMA much more than it affected the initial methylation step (inorganic arsenite to MMA). These results indicate that rat hepatocytes in primary culture and established rat hepatoma-derived cell lines are similar in their abilities to accumulate and methylate arsenic to MMA and DMA at environmentally relevant arsenic concentrations in the medium. They differed from the kidney epithelium-derived cells, which exhibited substantially lower biomethylation activity.

Morphometric and histopathologic analysis of lymphoid depletion in murine spleens following infection with Brucella abortus strains 2308 or RB51 or an htrA deletion mutant.

BALB/C mice were inoculated intraperitoneally with suspensions of Brucella abortus strains 2308 or RB51 or an htrA mutant. Spleens were examined on postinoculation day (PID) 2, 4, 7, 10, 15, 21, 30, and 60. Brucellae were cultured in high numbers from the spleens of mice infected with strains 2308 or htrA through PID 60; however, mice infected with strain RB51 cleared the infection between PID 30 and PID 60. Histopathologic changes in spleens from 2308-infected mice were characterized by marked accumulations of macrophages, which expanded marginal zones beginning as early as PID 7 and persisting through PID 60. Morphometric analysis showed a decrease in splenic white pulp in 2308-infected mice at PID 10, which correlated with the peak of bacterial infection. Although this decrease was significant (P < 0.05) when compared with values at the previous (PID 7) and the following (PID 15) time periods, it was not significantly different from white pulp values noted at PID 2 or PID 4 or the values for control spleens. Spleens from RB51-infected mice showed only mild to moderate accumulations of macrophages in marginal zone areas during the peak of RB51 infection (PID 7-10). Morphometric analysis of RB51-infected spleens showed a decrease in white pulp area, which coincided with peak bacterial numbers. However, this decrease was not significant (P > 0.05). Spleens from mice infected with the htrA mutant showed moderate to marked accumulations of macrophages in marginal zone areas, which persisted through PID 60. Multifocal necrosis in lymphoid follicles as early as PID 4 was seen in both htrA and 2308 infection. Morphometric analysis of htrA-infected spleens revealed no significant decrease in white pulp and no obvious correlation with bacterial numbers in the spleen. These results suggest that virulent B. abortus does not induce lymphoid depletion significantly below those values seen in noninfected mice; thus, the possible role of lymphoid depletion in the pathogenesis of brucellosis remains questionable.

Domain structure and conformation of histidine-proline-rich glycoprotein.

The complete primary structure of rabbit plasma histidine-proline-rich glycoprotein (HPRG), also known as histidine-rich glycoprotein, was determined by a combination of cDNA and peptide sequencing. Limited proteolysis with plasmin yielded three disulfide-linked fragments that were further purified. Reduction of the disulfide bonds with dithiothreitol under nondenaturing conditions releases the central, histidine-proline-rich domain, which contains 15 tandem repeats of the pentapeptide [H/P]-[H/P]PHG. The N-terminal fragment (295 amino acids), consisting of two cystatin-like modules, is bound to the proline-rich C-terminal fragment (105 amino acids) via a buried disulfide bond whose reduction requires prior denaturation. Far-UV circular dichroism spectra revealed beta-sheet with some alpha-helix, polyproline-II helix, and random coil in the secondary structure of the N-terminal, central, and C-terminal domains, respectively. The modular architecture of HPRG suggests that it may have several independent binding sites and that its biological role may be to bring two or more ligands together. The histidine-proline-rich domain, which contains 34 of the 53 histidine residues of HPRG, binds heparin and has an isoelectric point of 7.15 and a relatively high apparent pKa (7.0) of its histidine residues, and thus it probably mediates the interaction between HPRG and heparin, which is strikingly sensitive to pH in the range 7.0-7.4 [Peterson et al. (1987) J. Biol. Chem. 262, 7567-7574]. Solvent perturbation and second-derivative UV spectroscopy of HPRG revealed changes in the environment of tryptophan residues upon lowering the pH. This transition had a midpoint at pH 6.0 and required the disulfide bond bridging the histidine-proline-rich domain to the N/C fragment. The data are consistent with the mutual repulsion of protonated histidine residues in the histidine-proline-rich region causing a conformational change transmitted to the rest of the molecule via the disulfide bond.

Bacterial survival, lymph node changes, and immunologic responses of cattle vaccinated with standard and mutant strains of Brucella abortus.

Forty-eight cattle were used in 4 experiments; 6-week-old calves in experiments 1-3 (n = 24) and 10-month-old heifers in experiment 4 (n = 24). In experiments 1-3, 7 groups of 3 calves each were inoculated SC with 5 strains of Brucella abortus: virulent strain 2308 (2 groups), vaccine strain 19 (2 groups), and mutant strains RB51. 19 delta 31K, and 19 delta SOD. Sera and lymph node tissues were examined at 2-week intervals for evidence of infection. At postinoculation (PI) week 12, 2 calves in each group were given dexamethasone for 5 days. Calves were then euthanatized and lymphoid tissue, spleen, liver, and bone marrow were examined for evidence of B abortus. Calves given strain 2308 had large numbers of bacteria in their lymph nodes, marked granulomatous lymphadenitis in the deep cortex, and loss of lymphoid cells in superficial cortical areas. In addition, they had high serum antibody titers at PI week 16. Calves given strain 19, or genetic mutants derived from strain 19, cleared bacteria from lymph nodes more rapidly, had less lymphoid destruction, and developed antibody titers that did not persist for 16 weeks. The RB51 strain (rough) was cleared most rapidly from lymphoid tissues and induced serum antibody responses only to the core of the lipopolysaccharide molecule. Treatment of calves with dexamethasone did not cause B abortus to reappear in tissues of any calves, nor did serum antibody titers increase.(ABSTRACT TRUNCATED AT 250 WORDS)

Use of hemopexin domains and monoclonal antibodies to hemopexin to probe the molecular determinants of hemopexin-mediated heme transport.

Plasmin cleaves rabbit serum apohemopexin (Mr = 60,000) at a single site producing a heme-binding domain (I, Mr = 35,000) and a second domain (II, Mr = 25,000) (W. T. Morgan and A. Smith (1984) J. Biol. Chem. 259, 12001-12005). The absorbance spectra of heme-domain I are indicative of a bis-histidyl coordination complex with the central heme iron atom. Chemical modification of the 5 histidine residues of apo-domain I with diethylpyrocarbonate abolished heme binding, supporting this assignment. Upon binding heme, domain I migrates more rapidly in sucrose gradients, and, in sedimentation velocity experiments, the s value of domain I increases from 3.17 +/- 0.04 to 3.71 +/- 0.09, a notably large increase which indicates that the domain becomes much more compact. This conformational change which plays a pivotal role in hemopexin function requires the bis-histidyl coordination with heme iron and leads to a tighter association between domain I and domain II shown by the co-migration of heme-domain I and domain II in sucrose gradients. In turn, the association of heme-domain I with domain II increases the thermal stability of the heme-domain I chromophore. Results of binding studies using mouse hepatoma cells and isolated domains indicate that domain I not only binds heme but also plays a vital part in the hemopexin-receptor interaction. The change in conformation of domain I upon heme binding and the association between domains I and II induced by heme are both notable determinants of the strength of the hemopexin-receptor interaction, but an intact "hinge region" between the domains is not necessary for receptor binding. The importance of both domains in bringing about the transport function of hemopexin is confirmed by the ability of three (two specific for domain I and one for domain II) of seven monoclonal antibodies raised against hemopexin to inhibit the hemopexin-receptor interaction.

Interaction of hemopexin with Sn-protoporphyrin IX, an inhibitor of heme oxygenase. Role for hemopexin in hepatic uptake of Sn-protoporphyrin IX and induction of mRNA for heme oxygenase.

Sn-protoporphyrin IX (SnPP), an inhibitor of heme oxygenase and a potential therapeutic agent for neonatal hyperbilirubinemia, is bound tightly by hemopexin. The apparent dissociation constant (Kd) at pH 7.4 is 0.25 +/- 0.15 microM, but estimation of the Kd for the SnPP-hemopexin complex is hampered by the fact that at physiological pH SnPP exists as monomers and dimers, both of which are bound by hemopexin. SnPP is readily displaced from hemopexin by heme (Kd less than 1 pM). The hemopexin-SnPP interaction, like that of heme-hemopexin, is dependent on the histidine residues of hemopexin. However, as expected from the differences in the coordination chemistries of tin and iron, the stability of the histidyl-metalloporphyrin complex is lower for SnPP-hemopexin than for mesoheme-hemopexin. Nevertheless, when SnPP binds to hemopexin, certain of the ligand-induced changes in the conformation of hemopexin which increase the affinity of the protein for its receptor are produced. Binding of SnPP produces the conformational change in hemopexin which protects the hinge region of hemopexin from proteolysis, but SnPP does not produce the characteristic increase in the ellipticity of hemopexin at 231 nm that heme does. Competition experiments confirmed that human serum albumin (apparent Kd = 4 +/- 2 microM) has a significantly lower affinity for SnPP than does hemopexin. Appreciable amounts of SnPP (up to 35% in adults and 20% in neonates) would be bound by hemopexin in the circulation, and the remainder of SnPP would be associated with albumin due to the latter's high concentration in serum. Essentially no non-protein-bound SnPP is present. Importantly, SnPP-hemopexin binds to the hemopexin receptor on mouse hepatoma cells with an affinity comparable to that of heme-hemopexin and treatment of the hepatoma cells with SnPP-hemopexin causes a rapid increase in the steady state level of heme oxygenase messenger RNA. These results show that hemopexin participates in the transport of SnPP to heme oxygenase and in its regulation by SnPP.

Importance of ligand-induced conformational changes in hemopexin for receptor-mediated heme transport.

Hemopexin alters conformation upon binding heme as shown by circular dichroism (CD), but hemopexin binds the heme analog, iron-meso-tetra-(4-sulfonatophenyl)-porphine (FeTPPS), without undergoing concomitant changes in its CD spectrum. Moreover, FeTPPS, unlike heme, does not increase the compactness of the heme-binding domain (I) of hemopexin shown by an increased sedimentation rate in sucrose gradients. On the other hand, like heme, FeTPPS forms a bishistidyl coordination complex with hemopexin and upon binding protects hemopexin from cleavage by plasmin. Competitive inhibition and saturation studies demonstrate that FeTPPS-hemopexin binds to the hemopexin receptor on mouse hepatoma cells but with a lower affinity (Kd 125 nM) more characteristic of apo-hemopexin than heme-hemopexin (Kd 65 nM). This provides evidence that conformational changes produced in hemopexin upon binding heme, but not upon binding FeTPPS, are important for increasing the affinity of hemopexin for its receptor. The amount of cell-associated radiolabel from 55FeTPPS-hemopexin increases linearly for up to 90 min but at a rate only about a third of that of the mesoheme-complex. As expected from the recycling of hemopexin, more iron-tetrapyrrole than protein is associated with the Hepa cells, but the ratio of 55Fe-ligand to 125I-hemopexin is only 2:1 for FeTPPS-hemopexin compared to 4:1 for mesoheme complexes. [55Fe]Mesoheme was associated at 5 min with lower density fractions containing plasma membranes and at 30 min with fractions containing higher density intracellular compartments. In contrast, 55FeTPPS was found associated with plasma membrane fractions at both times and was not transported into the cell. Although FeTPPS-hemopexin binds to the receptor, subsequent events of heme transport are impaired. The results indicate that upon binding heme at least three types of conformational changes occur in hemopexin which have important roles in receptor recognition and that the nature of the ligand influences subsequent heme transport.