Donald E. Paglia

Bio: Donald E. Paglia is an academic researcher from University of California, Los Angeles. The author has contributed to research in topics: Hemolytic anemia & Pyruvate kinase. The author has an hindex of 22, co-authored 57 publications receiving 11899 citations. Previous affiliations of Donald E. Paglia include University of New Mexico & Albert Einstein College of Medicine.

Hereditary Hemolytic Anemia with Human Erythrocyte Pyrimidine 5′-Nucleotidase Deficiency

Abstract: A severe deficiency of a red cell pyrimidine 5'-nucleotidase was found to be associated with hereditary hemolytic anemia in four members of three kindreds. The syndrome was characterized by marked increases above normal in red cell basophilic stippling, total nucleotides, and GSH and by a fairly severe deficiency of ribosephosphate pyrophosphokinase (EC 2.7.6.1.). Patient erythrocytes uniquely contained large amounts of pyrimidine 5'-ribonucleotides. In earlier studies, these were erroneously considered to be adenosine phosphates, since all previous investigations of the nucleotides of human red cells and reticulocytes have shown 97% or more to contain adenine. Total nucleotides in patient cells were present in amounts 3-6 times greater than normal, and approximately 80% contained pyrimidine. The ultraviolet spectral curves of deproteinized red cell extracts exhibited a shift in maximum absorbance from the usual 256-257 nm to approximately 266-270 nm, and absorbance at 250, 270, 280, and 290 nm, expressed as a ratio of that at 260 nm, differed greatly from normal. The spectral characteristics of extracts provide the basis of a readily performed screening procedure, which does not require enzyme assay. The nucleotidase activity in deficient red cells assayed less than 14%, and usually less than 10%, of normal and much less in terms of reticulocyte-rich blood, where it was consistently found to be increased. The enzyme has a pH optimum of 7.5-8.0, is inhibited by EDTA, and does not utilize purine 5'-ribonucleotides or beta-glycerophosphate as substrates. While comparatively few family members have been available thus far for study, initial data are compatible with an autosomal, recessive mode of transmission of the deficiency. The pyrimidine 5'-ribonucleotides are presumably derived from RNA degradation and, not being diffusible, accumulate when the enzyme catalyzing their dephosphorylation is deficient. It is postulated that the prominent basophilic stippling results from retarded ribosomal RNA degradation secondary to accumulation of degradation products, namely pyrimidine 5'-ribonucleotides. Ribosephosphate pyrophosphokinase deficiency is considered to be an epiphenomenon. The mechanism responsible for increased red cell GSH is unknown.

Hereditary hemolytic anemia with hexokinase deficiency. Role of hexokinase in erythrocyte aging.

Abstract: IT is now clear that hereditary hemolytic anemias not associated with hemoglobinopathy or with the thalassemia syndromes are frequently due to inherited deficiencies in one or another of the enzymes upon which the erythrocyte is dependent to meet its energy needs. The non-nucleated, relatively metabolically impoverished adult human red cell has limited resources and places major dependence upon energy derived from the conversion of glucose to lactate – chiefly via the anaerobic Embden–Meyerhof pathway, but to a lesser but still important extent by way of the oxidative hexose monophosphate shunt. In the former diphosphopyridine nucleotide (NAD) is cycled to its . . .

[44] Glutathione peroxidase

Abstract: Publisher Summary This chapter presents a procedure for the preparation of glutathione peroxidase, which is regarded as a major protective system against endogenously and exogenously induced lipid peroxidation. Two types of methods are used for determining the activity of glutathione peroxidase. One involves a direct measurement of unconsumed glutathione (GSH) at fixed time periods by polarographic GSH analysis' (Method 1), or by the dithionitrobenzoic acid method (Method 2). The second approach takes advantage of the capability of glutathione reductase, with nicotinamide adenine dinucleotide phosphate (NADPH), to regenerate GSH from oxidized GSH. The decrease in NADPH is continuously measured spectrophotometrically, while the GSH concentration in the enzymatic cycle remains essentially constant (Method 3). A convenient source for the preparation of glutathione peroxidase is bovine blood including the following steps: hemolysate; organic solvent precipitation; phosphate precipitation; absorption to phenyl-sepharose; and washing on diethylaminoethyl (DEAE)–sephadex, S-300 sephacryl, and hydroxylapatite column.

Two’s company, three’s a crowd: can H2S be the third endogenous gaseous transmitter?

Abstract: Bearing the public image of a deadly "gas of rotten eggs," hydrogen sulfide (H2S) can be generated in many types of mammalian cells. Functionally, H2S has been implicated in the induction of hippocampal long-term potentiation, brain development, and blood pressure regulation. By acting specifically on KATP channels, H2S can hyperpolarize cell membranes, relax smooth muscle cells, or decrease neuronal excitability. The endogenous metabolism and physiological functions of H2S position this gas well in the novel family of endogenous gaseous transmitters, termed "gasotransmitters." It is hypothesized that H2S is the third endogenous signaling gasotransmitter, besides nitric oxide and carbon monoxide. This positioning of H2S will open an exciting field-H2S physiology-encompassing realization of the interaction of H2S and other gasotransmitters, sulfurating modification of proteins, and the functional role of H2S in multiple systems. It may shed light on the pathogenesis of many diseases related to the abnormal metabolism of H2S.

The Glutathione Status of Cells

Abstract: Publisher Summary Glutathione (GSH) is the most important nonprotein thiol in living systems and is of widespread occurrence in the intracellular milieu of animals, plants, and microorganisms GSH was isolated and named by the English biochemist Frederick Gowland Hopkins This chapter discusses GSH status, the biologically relevant chemistry of GSH, the forms in which GSH can be present within the cell, along with the GSH content of cells and the methods for analysis of this substance GSH-related biochemical reactions and the biological roles of GSH are discussed in the chapter The use of perturbations in GSH status as a means for investigating GSH-related phenomena and an analysis of the consequences of perturbation are presented A short summary of genetic lesions related to GSH is also included Like chemically induced perturbations in GSH status, genetic lesions provide valuable insights into the role of GSH in normal functions and processes in cells The chapter concludes with some brief comments about the future of the relationship of GSH status to cellular processes

Review on in vivo and in vitro methods evaluation of antioxidant activity.

Abstract: A good number of abstracts and research articles (in total 74) published, so far, for evaluating antioxidant activity of various samples of research interest were gone through where 407 methods were come across, which were repeated from 29 different methods. These were classified as in vitro and in vivo methods. And those are described and discussed below in this review article. In the later part of this review article, frequency of in vitro as well as in vivo methods is analyzed with a bar diagram. Solvents are important for extracting antioxidants from natural sources. Frequency of solvents used for extraction is also portrayed and the results are discussed in this article. As per this review there are 19 in vitro methods and 10 in vivo methods that are being used for the evaluation of antioxidant activity of the sample of interest. DPPH method was found to be used mostly for the in vitro antioxidant activity evaluation purpose while LPO was found as mostly used in vivo antioxidant assay. Ethanol was with the highest frequency as solvent for extraction purpose.