ADA2 isoform of adenosine deaminase from pleural fluid

Adenosine deaminase isoenzyme 2 (ADA2) was isolated from human pleural fluid for the first time. Molecular and kinetic properties were characterized. It was shown that the inhibitors of adenosine deaminase isoenzyme 1 (ADA1), adenosine, and erithro-9-(2-hydroxy-3-nonyl)adenine (EHNA) derivatives are poor inhibitors of ADA2. Comparison of the interaction of ADA2 and ADA1 with adenosine and its derivative, 1-deazaadenosine, indicates that the isoenzymes have similar active centers. The absence of ADA2 inhibition by EHNA is evidence of a difference of these active centers in a close environment. The possible role of Zn2+ ions and the participation of acidic amino acids Glu and Asp in adenosine deamination catalyzed by ADA2 were shown.     

Molecular form of adenosine deaminase in severe combined immunodeficiency

The specific activity of adenosine deaminase was reduced to approximately 0.5% of normal in splenic tissue obtained from a patient with severe combined immunodeficiency. Sedimentation analysis of splenic homogenate from this patient revealed a major peak of adenosine deaminase activity which corresponded with respect to the sedimentation coefficient of one of three molecular species observed in control spleens but had markedly reduced activity. These findings suggest that the molecular heterogeneity of human adenosine deaminase is under the control of a single genetic locus and that the deficiency of adenosine deaminase activity in severe combined immunodeficiency is not due to a genetic deletion.     

Molecular forms of pigeon skeletal muscle AMP deaminase

Phosphocellulose chromatography of pigeon leg muscle extract revealed the existence of two well-separated forms of AMP deaminase. This was in contrast to the pigeon breast muscle extract, which yielded only one form. The two leg muscle enzyme isoforms manifested similar kinetic and regulatory properties. They were activated by very low concentration of potassium ions and demonstrated similar patterns of pH and effector dependence. At pH 6.5, as well as at other pH values tested. ADP and ATP slightly stimulated, whereas GTP and orthophosphate inhibited the two molecular forms of pigeons leg muscle enzyme. Surprisingly, the molecular form of AMP deaminase present in pigeon breast muscle was inhibited by ATP at all pH values tested. The kinetic and regulatory properties of the three molecular forms of pigeon skeletal muscle AMP deaminase examined do not resemble those which have been described for pigeon heart muscle enzyme.     

Purification of multiple forms of adenosine deaminase from rabbit intestine.

Two forms of adenosine deaminase (adenosine aminohydrolase, EC 3.5.4.4), differing in molecular size, have been purified and obtained in homogeneous form from rabbit intestine. The purification procedures involved extraction with acetate buffer, pH 5.5, precipitation and fractional reextraction with (NH4)2SO4, ion-exchange chromatography on DEAE-cellulose and gel filtration on Sephadex G-75 and Sephadex G-200. Gel filtrations analysis gave molecular weight estimates of 265 000 and 32 000 for the large and small deaminases respectively. The two enzymes forms had similar pH optima and pH stability ranges.     

Molecular forms of human heart muscle AMP deaminase.

Chromatography on phosphocellulose revealed the presence of two, kinetically different forms of human heart AMP deaminase. The main portion of the activity eluted from the column at about 1.1 M KCl, and the enzyme present in this eluate manifested a sigmoidal type of substrate saturation kinetics. The results from gel filtration indicate that human heart AMP deaminase is a tetrameric protein capable of aggregating in more complex active structures.     

Molecular recognition of adenosine deaminase: 15N NMR studies

The elucidation of the molecular recognition of adenosine deaminase (ADA), the interpretation of the catalytic mechanism, and the design of novel inhibitors are based mostly on data obtained for the crystalline state of the enzyme. To obtain evidence for molecular recognition of the physiologically relevant soluble enzyme, we studied its interactions with the in situ formed inhibitor, 6-OH-purine riboside (HDPR), by 1D-15N- and 2D-(1H-15N)- NMR using the labeled primary inhibitor [15N4]-PR. We synthesized both [15N4]-PR and an [15N4]-HDPR model, from relatively inexpensive 15N sources. The [15N4]-HDPR model was used to simulate H-bonding and possible Zn2+-coordination of HDPR with ADA. We also explored possible ionic interactions between PR and ADA by 15N-NMR monitored pH-titrations of [15N4]-PR. Finally, we investigated the [15N4]-PR-ADA 1:1 complex by 2D-(1H-15N) NMR. We found that HDPR recognition determinants in ADA do not include any ionic-interactions. HDPR N1 H is an H-bond acceptor, and not an H-bond donor. Despite the proximity of N7 to the Zn2+-ion, no coordination occurs; instead, N7 is an H-bond acceptor. We found an overall agreement between the crystallographic data for the crystallized ADA:HDPR complex and the 15N-NMR signals for the corresponding soluble complex. This finding justifies the use of ADA's crystallographic data for the design of novel inhibitors.     

Malignancy-associated serosanguinous pleural effusions

Cytologic preparations of 786 pleural effusions from 495 patients were reviewed, including 312 specimens from 172 cancer patients. Approximately 50% of the paraneoplastic effusions were sanguinous. Thoracic cancer was histologically confirmed in 145 patients, 64% of whom had cytologically positive pleural effusions; 71% of these specimens were also macroscopically bloody. Regardless of any histologic evidence of neoplastic invasion of the pleura, the presence of blood in the majority of the effusions was related most often to acute inflammatory reactions with vascular dilatation and proliferation within serosal tissues or the underlying pulmonary parenchyma.     

Localization of adenosine deaminase and adenosine deaminase complexing protein in rabbit brain

Adenosine deaminase and adenosine deaminase complexing protein have been localized in rabbit brain. Brains fixed in paraformaldehyde or in Clarke's solution were blocked coronally. Blocks from brains fixed in paraformaldehyde were either frozen in liquid nitrogen or embedded in paraffin. Tissue fixed in Clarke's solution was embedded in paraffin. Sections from each block were stained by the peroxidase-antiperoxidase method for adenosine deaminase or complexing protein using affinity-purified goat antibodies. Adenosine deaminase and complexing protein did not co-localize. Adenosine deaminase was detected in oligodendroglia and in endothelial cells lining blood vessels, whereas complexing protein was concentrated in neurons. The subcellular location and appearance of the peroxidase reaction product associated with individual cells was also quite distinctive. The cell bodies of adenosine deaminase-positive oligodendroglia were filled with intense deposits of peroxidase reaction product. In contrast to oligodendroglia, the reaction product associated with most neurons stained for complexing protein was concentrated in granular-appearing cytoplasmic deposits. In some instances, these deposits were clustered about the nuclear membrane. Staining of neurons in the granular layer of cerebellum was an exception. Granule cells were lightly outlined by peroxidase reaction product. Cerebellar islands, also referred to as glomeruli, were stained an intense uniform brown. These results raise the possibility that oligodendroglia and blood vessel endothelia, through the action of adenosine deaminase, might play a role in controlling the concentration of extracellular adenosine in brain. They do not, however, support the suggestion that complexing protein aids in adenosine metabolism by positioning adenosine deaminase on the plasma membrane.     

Fluorescence microscopy of mycobacteria in pleural effusions

The diagnostic advantage of fluorescence microscopy (FM) of Papanicolaou-stained cytological specimens obtained by bronchoscopy has been described previously. This study was designed to evaluate the method's diagnostic benefit in cytological preparations of pleural effusions in cases of active pulmonary tuberculosis. In contrast to bronchial material there is no advantage in cytological evaluation of pleural effusions by FM.     

Curschmann's spirals in pleural and peritoneal effusions

Curschmann's spirals were found in smears and cell block preparations of five spontaneously occurring pleural and peritoneal fluids. The spirals were similar to those seen in the respiratory tract, although generally much smaller. In three of the five cases, the fluids also contained mucus-secreting adenocarcinoma cells; it is postulated that the spirals formed from mucus secreted by these cells. In the other two cases, there was evidence of serosal inflammation; it is suggested that the spirals in these cases developed from submesothelial connective tissue mucosubstances that entered the serosal cavity through a mesothelium of increased permeability due to the inflammation. No simple explanation can be accepted as to the exact mode of spiral formation, which is presumed to be a complex physical and biochemical phenomenon.     

Natural killer cells in carcinomatous pleural effusions

Summary Effector cells in carcinomatous pleural effusions of patients with primary or secondary lung cancer were examined for natural killer (NK) activity against K562 cells in a 4-h chromium release assay, and for mitogenic responses and lymphocyte subpopulation constitutions. NK activity of lymphocyte-rich mononuclear cells isolated from carcinomatous pleural effusions by centrifugation on a discontinuous gradient of Ficoll-Hypaque was markedly low in seven of 40 patients studied, and absent in the other 33 cases. NK activity of peripheral blood mononuclear cells from the patients was lower than that of cells from normal donors, but always higher than that of effusion cells from the same patients. NK cells in the peripheral blood and in pleural effusions had some characteristics in common, in that they lacked a capacity to bind sheep erythrocytes, were nonadherent to Sephadex G-10 beads and nylon wool, and belonged to large granular lymphocytes. On the other hand, nonmalignant effusions of patients with congestive heart failure had significant NK activity. The effector cells in the effusions included a higher frequency of T cells than those in the peripheral blood of the same patients. Proliferative responses to phytohemagglutinin and concanavalin A of effusion cells were comparable to those of normal blood cells and were higher than those of blood cells from the same patients. The reason for low NK activity and high mitogenic response in carcinomatous pleural effusions is as yet undefined.