The use of alkaline-phosphatase conjugated second antibody for the enhancement of immunoprecipitation techniques on cellulose acetate membranes

Joachim Kohn (1912–1987) and the Origin of Cellulose Acetate Electrophoresis

The year 2006 marks the 50th anniversary of the discovery of cellulose acetate (CA) electrophoresis by Joachim Kohn, a pathologist at Queen Mary’s Hospital in Roehampton, London. During a career in pathology that began in 1950 and spanned 37 years, Kohn published more than 50 papers in clinical laboratory medicine. He was the first to report the use of CA microbiology filters as solid supports for zone electrophoresis and the separation of hemoglobin phenotypes on CA membranes. Kohn also invented a new electrophoresis chamber and an 8-position stamp applicator especially for use with CA membranes. Beginning in 1957, Kohn pioneered the development of CA techniques for immunoelectrophoresis, counter immunoelectrophoresis, radial immunodiffusion, protein blotting, and immunofixation. He also designed a transport dressing for burn patients and was the first person to describe the use of an enzyme-based dipstick for measuring fingerstick blood glucose concentrations. This short review highlights Kohn’s discovery of CA electrophoresis and his contributions to the development of this procedure.

Of matrices and men

Matrices used in modern electrokinetic techniques are surveyed. They are essentially three: cellulose acetate, agarose and polyacrylamide gels. The use of cellulose acetate is confined mostly to analyses in clinical chemistry labs. The properties of agarose are discussed, in particular its capacity of forming large-pore structures via supercoiling, i.e. formation of suprafibers with average radii of approximately 20-25 nm. Several modified agaroses are reviewed, in particular the SeaPlaque, SeaPrep, NuSieve, NuFix, Seakem and Isogel brands and a composite agarose-polyacrylamide matrix, quite popular in the seventies for DNA and RNA separations. The field of polyacrylamide gels seems to be bursting, with the large number of crosslinkers described, imparting special properties to such matrices. The properties of new, modified acrylamide monomers, little known in the field of electrophoresis, are evaluated; in particular: trisacryl gels, hydroxyalkyl methacrylate gels and acryloylmorpholine-bisacrylylpiperazine gels, the latter formed by amphiphilic monomers, highly resistant to alkaline hydrolysis. The properties and formulas of a host of acidic and basic acrylamido derivatives (11 of them) used as buffers and titrants for isoelectric focusing in immobilized pH gradients are reviewed here for the first time. The review culminates with a glimpse at a new generation of amphiphatic matrices, such as HydroLink and 'shielded hydrophobic phase' gels, which appear to be the latest developments in the fields of electrophoresis and chromatography, respectively.

Purification and characterization of intestinal alkaline phosphatase from harp seal

1. Alkaline phosphatase (EC 3.1.3.1.) from harp seal (Phagophilus groenlandicus) has been purified by concanavalin A-Sepharose chromatography to homogeneity with a specific activity of 1200-1500 units/mg of protein. 2. The mol. wt of the enzyme and its subunits were estimated as 260,000 and 70,000, respectively. By chromatofocusing the isoelectric point of this enzyme is 5.5. 3. With p-nitrophenylphosphate, pH-optimum and KM for the enzyme are 9.8 and 0.9 mM, respectively. 4. The enzyme was strongly inhibited by Sn4+, Fe3+ and Zn2+, whereas Mg2+ and Mn2+ were effective activators of the enzyme. Seal alkaline phosphatase was slightly inhibited by high concentrations of Ca2+ and Cr3+. 5. The enzyme activity reached a maximum at 55-60 degrees C. It was shown that the heat stability of seal and calf intestinal alkaline phosphatases were equal at 37 and 56 degrees C.

Instantaneous roll-blot from cellulose acetate after electrophoresis. A versatile tool for monoclonal antibody characterization

An instantaneous blotting method from cellulose acetate to nitrocellulose was developed using a high pressure roll apparatus. This method was applied to the early characterization of monoclonal antibody specificity and to monoclonal immunoglobulin typing in mouse hybridoma supernatants, human sera or unconcentrated urines. Immunoglobulins were then revealed using, successively, anti-isotype specific monoclonal or polyclonal antibodies, avidin-biotinylated peroxidase complexes and cobalt-enhanced diaminobenzidine substrate.

Human monoclonal antibodies to thyroid antigens derived by hybridization of lymphocytes from a diabetic patient

Human monoclonal antibodies to human endocrine cells have been obtained following the generation of immunoglobulin-secreting interspecies lymphocyte hybridomas. Peripheral blood lymphocytes from an adult patient presenting with acute onset, Type I, diabetes mellitus were fused in vitro with mouse myeloma cells of the NS1 cell line. Initial selection of resulting hybridomas was made by their ability to proliferate in HAT medium. Those hybridomas secreting human immunoglobulins were identified by radioimmunoassay and, thereafter, cloned at frequent intervals to ensure continued antibody production. Human monoclonal antibodies selected in this manner are being employed to identify those epitopes which are common antigenic targets during initial stages of autoimmune-mediated diabetes mellitus and associated multiple endocrinopathies. Of these antibodies, one (HML 3.22) recognizes an epitope present on the human TSH receptor and a second (HML 3.21) identifies a component of thyroglobulin. The potential value of human monoclonal antibodies as probes for analyzing autoimmune-mediated endocrine diseases is discussed.

Bence Jones protein detection: a rapid immunoblotting technique for routine use on unconcentrated urine

A new immunoblotting method is described for the detection of Bence Jones proteinuria by the routine laboratory. Unconcentrated urine specimens are subjected to electrophoresis on agarose gels. Separated proteins are transferred to a nitrocellulose membrane and the immunoglobulins located and identified by horseradish-peroxidase double-antibody staining. The new method has been compared with that used routinely, and an improved rate of detection of both Bence Jones protein and intact urinary monoclonal immunoglobulin has been obtained. Among urine specimens received for routine testing for Bence Jones protein from 83 patients, 64 monoclonal components were found by the new technique compared with 45 by the method used routinely. Other advantages of the new procedure include: no need to concentrate urine specimens before electrophoresis; unlike immunofixation, the proteins may be detected successfully over a wide concentration range without using several specimen or antibody dilutions; and interpretation is easier.