Federation proceedings最新文献

The enzyme-linked immunosorbent assay (ELISA) has been investigated for its ability to quantitate hydrophobic proteins like cytochromes b5 and P-450 at the subnanogram level. Issues encountered that have broad significance not only for ELISA, but for other qualitative and quantitative immunoassays as well, include the effects of detergent, the discriminatory capacity of ELISA, and the method for determining an assay's selectivity.

Endothelial cells (EC) isolated from bovine brain microvessels produce a continuous monolayer when grown in primary culture. The EC are joined together by tight junctions and contain few pinocytotic vesicles. Horseradish peroxidase (HRP) is unable to penetrate this in vitro barrier system. Exposure of the cells to 1.6 M arabinose produces a reversible separation of the tight junctions with penetration of HRP across the monolayer in a pattern similar to that observed in animals after infusion of hyperosmotic solutions into the carotid artery. The behavior of brain microvascular cells in culture suggest that they retain properties important to the formation of the blood-brain barrier.

Within minutes of occlusion of a major coronary artery the polymorphonuclear leukocytes (PMNs) are activated whereby they adhere to the vascular endothelium and migrate through the endothelial layer. Interactions with the endothelium can promote increased vascular resistance, diminished collateral flow, capillary blockade, and predisposition to vasospasm, as well as enhanced vascular permeability. On subsequent reperfusion entrapped leukocytes contribute to the no-reflow phenomenon, while more leukocytes gain access to the previously ischemic region. The leukocytes infiltrate the myocardium where they exacerbate the process of tissue injury and the development of arrhythmias. The release of leukocyte-derived mediators including arachidonic acid (AA) metabolites and oxygen-derived free radicals probably underlies these activities of the leukocytes. PMNs contain active lipoxygenase enzymes capable of metabolizing AA to products that are not normally found in the myocardium, and can dominate the metabolic profile of that tissue, leading to changes in myocardial integrity and function. Inhibitors of the lipoxygenase enzymes suppress the accumulation of leukocytes into the ischemic myocardium and reduce infarct size. However, because the drugs prevent cell invasion it cannot be inferred that a lipoxygenase metabolite per se is deleterious to the ischemic heart, inasmuch as any leukocyte-dependent mechanism of injury will be attenuated whether it is mediated by eicosanoids or by any other leukocyte-derived product. Additional studies with specific inhibitors/antagonists are required to determine the biochemical mechanisms underlying the different aspects of leukocyte-mediated myocardial injury.

The determination of primary structures by amino acid and nucleotide sequencing for the C3b-and/or C4b-binding proteins H, C4BP, CR1, B, and C2 has revealed the presence of a common structural element. This element is approximately 60 amino acids long and is repeated in a tandem fashion, commencing at the amino-terminal end of each molecule. Two other complement components, C1r and C1s, have two of these repeating units in the carboxy-terminal region of their noncatalytic A chains. Three noncomplement proteins, beta 2-glycoprotein I (beta 2I), the interleukin 2 receptor (IL 2 receptor), and the b chain of factor XIII, have 4, 2 and 10 of these repeating units, respectively. These proteins obviously belong to the above family, although there is no evidence that they interact with C3b and/or C4b. Human haptoglobin and rat leukocyte common antigen also contain two and three repeating units, respectively, which have more limited homology with the repetitive regions in this family. All available data indicate that multiple gene duplications and exon shuffling have been important features in the divergence of this family of proteins with the 60-amino-acid repeat.

During acute myocardial ischemia, granulocytes accumulate and obstruct the microcirculation. Granulocytes remain plugged in individual myocardial capillaries on reperfusion and are the major cause of the no-reflow phenomenon. During 3 h of ischemia, the granulocyte content of myocardium measured by 111In labeling increases from 1.0 X 10(6) to 1.5 X 10(6) cells/g, and after 5 min of reperfusion increases to 2.4 X 10(6) cells/g. The effects of granulocytes during 1 h of acute ischemia were determined by comparing agranulocytic to whole blood perfusion. With whole blood collateral flow decreased, water content increased (edema), ventricular fibrillation was common, and 27% of capillaries had no-reflow, whereas in the absence of granulocytes, collateral flow increased, there was no edema, arrhythmias were rare, and the no-reflow phenomenon was completely prevented. It is unfortunate that the inflammatory signals triggered by ischemia remain active on acute reperfusion, limit tissue salvage, and perhaps cause reperfusion injury. Several activating stimuli for granulocytes are known, but what inhibits them? Adenosine is known to inhibit superoxide radical formation by granulocytes, and 5-amino-4-imidazole carboxamide-riboside (AICA-riboside) augments adenosine release from energy-deprived cells. In dogs subjected to 1 h of ischemia, AICA-riboside pretreatment augmented adenosine release by nearly 10-fold, which was accompanied by a significant increase in collateral blood flow and decreased arrhythmias. We propose a new hypothesis: adenosine acts as a natural antiinflammatory autacoid during transient injury linking the ability to catabolize ATP (an indicator of viability) to granulocyte inhibition, thus preventing premature activation of the inflammatory response to cell death. Granulocytes are active participants in acute myocardial ischemia and means to prevent their activation, remove them from the reperfusate, or inhibit them will be necessary for optimum reperfusion salvage.

Reperfusion of ischemic myocardium is recognized as potentially beneficial because mortality is directly related to infarct size, and the latter is related to the severity and duration of ischemia. However, reperfusion is associated with extension of the injury that is additive to that produced by ischemia alone. The phenomenon of reperfusion injury is caused in large part by oxygen-derived free radicals from both extracellular and intracellular sources. The loci of oxygen-free radical formation include: myocardial sources (mitochondria), vascular endothelial sources (xanthine oxidase and other oxidases), or the inflammatory cellular infiltrate (neutrophils). Experimental studies have shown that free radical scavengers and agents that prevent free radical production can reduce myocardial infarct size in dogs subjected to temporary regional ischemia followed by reperfusion. Superoxide dismutase and catalase, which catalyze the breakdown of superoxide anion and hydrogen peroxide, respectively, limit experimental myocardial infarct size. The free radical scavenging agent N-(2-mercaptopropionyl)glycine (MPG) is reported to be effective in limiting infarct size. The ischemic-reperfused myocardium derives significant protection when experimental animals are pretreated with the xanthine oxidase inhibitor allopurinol. Neutrophils also serve as a significant source of oxygen-derived free radicals at the site of tissue injury. A number of agents have been shown to directly inhibit neutrophil-derived oxygen free radical formation and neutrophil accumulation within the reperfused myocardium. These agents include ibuprofen, nafazatrom, BW755C, prostacyclin, and iloprost. Thus, free radical scavengers and agents that prevent free radical formation can provide significant protection to the ischemic-reperfused myocardium.

The fourth component of complement in humans is coded for by two closely linked loci, i.e., C4A and C4B, that have been positioned within the class III region of the human major histocompatibility complex along with the genes for C2, Bf, and steroid 21-OH. Both C4 loci are highly polymorphic and certain alleles, particularly the nulls, are associated with susceptibility to autoimmune disease. About one-half of the null alleles are due to a large deletion that includes both a C4 and flanking 21-OH gene. Despite the near identity of the products of the two loci, the proteins differ dramatically in their efficiency of covalent binding to antigen. The amino acid substitutions responsible for the functional differences have been identified and they are clustered relatively near the covalent binding site within the C4d region of the alpha chain. These observations support the hypothesis that the susceptibility to autoimmune disease is related to the structural variation of the C4 protein.

Many important questions remain to be answered about the mechanism that mediates coupled Na,K,Cl cotransport. We still do not know what the ATP requirement involves. Is ATP the direct energy source? Such an energy source does not seem to be necessary, inasmuch as the net free energy in the combined transmembrane chemical gradients of Na, K, and Cl is quite sufficient to maintain the observed high Cl(i). Could a protein kinase-mediated mechanism be responsible for the ATP requirement? How does reducing Cl(i) stimulate the transporter? What are the kinetic relationships for the co-ions at the outward- and inward-facing transport sites? Are they symmetrical? Can the squid axon regulate its cell volume? If so, is the Na,K,Cl transporter directly involved? Thus, the squid axon remains a fruitful preparation to study a transport mechanism similar to that found in a variety of cells. Its large size confers unique experimental advantages that should help us in our quest to understand this widely distributed transport mechanism.