Protein separations, factors involved

Membranes offer a format for interaction of an analyte with a stationary phase alternative to the familiar column. For certain kinds of separations, particularly preparative separations involving strong adsorption, the membrane format is extremely useful. A 5 x 4 mm hollow-fiber membrane layered with the protein bovine serum albumin was used for the chiral separation of the amino acid tryptophan, with a separation factor of up to 6.6.62 Diethey-laminoethyl-derivatized membrane disks were used for high-speed ion exchange separations of oligonucleotides.63 Sulfonated membranes were used for peptide separations, and reversed-phase separations of peptides, steroids, and aromatic hydrocarbons were accomplished on C18-derivatized membranes. 

The proteomic analysis of the brain has certain limitations that are related either to the sample and/or analytical approach. In the analysis of the brain, many factors may be involved, such as differences among individuals, differences in age and sex, possible other diseases, treatment with medicines, as well as technical factors, disease-unrelated factors, such as postmortem time, improper treatment of the samples, etc., all of which can affect a clear discrimination between healthy and diseased states of interest. The technical limitations involve inefficient detection of low-abundance gene products, hydrophobic proteins (they do not enter the IPG strips), and acidic, basic, high-, and low-molecular mass proteins. All these protein classes are underrepresented in 2-D gels (Lubec et al., 2003 Fountoulakis, 2004). A combination of proteomics methods with protein separation, enriching techniques, and alternative methodologies for detection will improve the detection of additional differences between AD and control brains. Such differences may be essential in the discovery of early disease markers and therapeutic approaches. 

An unexpected finding in the RNA Pol I field was the realization that yeast do not have factors that resemble the two essential vertebrate RNA Pol I auxiliary factors, UBF and SL1. Indeed, many attempts to clone yeast RNA Pol I factors by homology screening did not yield any results. Moreover, analysis of the yeast genomic sequence does not show any protein with obvious similarity to UBF or SL1. This was unexpected, as the RNA Pol II and Pol III machineries are rather conserved between vertebrates and yeast. Consequently, the identification of yeast factors involved in RNA Pol I transcription has evolved separately from the... 

Immunoaffinity chromatography utilizes the high specificity of antigen—antibody interactions to achieve a separation. The procedure typically involves the binding, to a soHd phase, of a mouse monoclonal antibody which reacts either directly with the protein to be purified or with a closely associated protein which itself binds the product protein. The former approach has been appHed in the preparation of Factor VIII (43) and Factor IX (61) concentrates. The latter method has been used in the preparation of Factor VIII (42) by immobilization of a monoclonal antibody to von WiHebrand factor [109319-16-6] (62), a protein to which Factor VIII binds noncovalenfly. Further purification is necessary downstream of the immunoaffinity step to remove... 

Over thirty different elements have been determined in medical and biological materials by atomic absorption spectroscopy. The popularity of the technique is due to a number of factors, including sensitivity, selectivity, and ease of sample preparation. With biological fluids, often no preparation at all is required. The techniques employed usually involve simple dilution of the sample with water or with an appropriate reagent to eliminate interference. Alternatively, the element to be determined is separated by solvent extraction. Either an untreated sample, a protein free filtrate, or an ashed sample is extracted. 

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