Preferential binding of radiolabeled poly-L-lysines to C6 and U87 MG glioblastomas compared with endothelial cells in vitro.

This report describes the preparation of polylysine-diethylene triamine pentaacetic acid (DTPA)-metal ion complexes and of iodinated polylysine derivatives and the preferential binding of these polymers to glioblastomas in culture. Synthetic polylysines (DP88 and DP299) were modified covalently either with the chelator DTPA or with 125I-Bolton Hunter reagent. The polylysine (DP88) was modified initially with fluorescein to permit fluorescence cytological studies and quantitative measurements of polylysine concentrations. The polylysines contained an average of one DTPA per 16 lysyl moieties. The polylysine-DTPA derivatives were then modified with a mixture of 153Gd and stable Gd. A copolymer (DP120) of lysine and tyrosine (4:1) was modified with 125I using chloramine T as catalyst. C6 (rat) and U87 MG (human) glioblastoma cells, in culture, bound six to seven times more polylysine-DTPA-Gd than endothelial cells from either aorta or brain. Each of the tumor cell types bound 10(8) molecules of the modified polylysine per cell when 2.5 x 10(5) cells were reacted with 50 micrograms or greater of the polylysine-DTPA-nuclide complex. The higher molecular weight polylysines delivered more radionuclide to the cells in culture. Although the tumor cells bound more [125I]polylysine and [125I]poly(lysine HBr,tyrosine) than they bound polylysyl-DTPA-Gd, the endothelial cells and the plastic culture dish also bound more of the iodinated polymers. The stoichiometry of polylysine bound per cell suggests that the sialic acid moieties on the cell surface are the primary binding sites for polylysine derivatives. Fluorescence microscopy studies revealed that the fluorescein polylysine (DP88) and the fluorescein polylysine-DTPA nuclide complex bound the tumor cells primarily at branch points along the neuritic processes, at the edge of the perikaryon and at the terminal regions of the outgrowth process. The polylysyl-DTPA-Gd can be used, with magnetic resonance imaging, to provide measurable contrast of the margin between C6 glioblastomas and normal brain in vivo in Wistar Furth rats.

Magnetic resonance imaging of rabbit brain after intracarotid injection of large multivesicular liposomes containing paramagnetic metals and DTPA.

A procedure has been developed for the preparation of large (10- to 80-microns-diameter) multivesicular liposomes that contain magnetic resonance contrast agent (DTPA and either manganese or gadolinium). Blue dextran was observed to induce the formation of the large liposomes with dioleoylphosphatidylcholine and cholesterol (1:1 molar ratio) and with dipalmitoylphosphatidylcholine and cholesterol (1:1 molar ratio). The formation of the large liposomes is dependent upon mixing the blue dextran with the lipid films at temperatures above the transition point of the lipids. Tracer amounts of 153Gd were added to the aqueous phase to permit quantitation of the recovery of encapsulated materials. Liposomes that were prepared using equimolar ratios of phospholipid and cholesterol were stable in serum for more than 12 h. The ultrastructure of the large multivesicular liposomes reveals the existence of individual vesicles (greater than 2 micron diameter) bound together by a multilamellar coating. When injected into the internal carotid artery of the rabbit, the large liposomes became entrapped in the vascular bed primarily in the frontal and occipital regions of brain. The resulting emboli may provide a means to deliver drugs to a specific site in brain, such as a tumor, if the vascular bed of the site can be cannulated precisely.

Antineurofilament antibody evaluation in neuropsychiatric systemic lupus erythematosus. Combination with anticardiolipin antibody assay and magnetic resonance imaging.

We used Western blot analysis to examine the occurrence and titer of antibody to cytoskeletal neurofilament protein antigens in patients with neuropsychiatric manifestations of systemic lupus erythematosus (SLE) and in controls. Twenty-two patients with neuropsychiatric SLE (NPSLE) had an increased incidence of antineurofilament antibody (ANFA) compared with 34 patients with SLE without neuropsychiatric symptoms, 78 patients with other disease processes, and 22 healthy controls. ANFA were found to be directed against the 205,000- and 160,000-dalton proteins of the neurofilament triplet. Patients with a diffuse NPSLE clinical presentation had the greatest frequency of serum ANFA (7 of 12, 58%) compared with all other groups examined. Magnetic resonance imaging and serum anticardiolipin antibody testing were also performed in selected patients with NPSLE. Patients with a focal clinical presentation of NPSLE, positive magnetic resonance imaging findings, and negative serum ANFA had significantly elevated levels of anticardiolipin antibody.

Magnetic resonance imaging of gadolinium-labeled monoclonal antibody polymers directed at human T lymphocytes implanted in canine brain.

Two different murine monoclonal anti-human T cell antibodies, that were coupled to gadolinium (Gd), bind specifically to human T lymphocyte cells implanted in canine brain. This binding was at a concentration of Gd sufficient to detect the implanted cells and to distinguish them from the surrounding brain tissue with magnetic resonance imaging (MRI) at a field strength of 1.5 Tesla. These Gd-labeled immunoglobulin preparations did not bind bovine T cells at a concentration sufficient to be detected on MRI. A protein solution containing the immunoglobulins (100 micrograms), gelatin (2 mg), and bovine serum albumin (2.5 mg) was reacted with the dianhydride of diethylenetriaminepentaacetic acid (DTPA); the DTPA serves as a metal chelator and as a protein crosslinking agent. The DTPA-protein complex was reacted with Gd chloride. There were approximately 10 DTPA residues per protein molecule in the modified protein mixture. Isolated human or bovine monocytes (approximately 12 million cells) were implanted in the brains of anesthetized dogs in a volume of 40 microliters. The blood-brain barrier was then disrupted by the intra-arterial injection of hyperosmotic mannitol, and the Gd-labeled antibodies were injected through a catheter placed at the branch of the internal and external carotid arteries. The brains were imaged 48 to 72 hours later. The MRI scans revealed a markedly decreased T1 relaxation time with a high signal intensity (TE = 25 msec, TR = 200 msec) related to the human T cell implants. There was no evidence of decreased T1 at the site of the bovine T cells. Neither control murine gamma globulin coupled to Gd-DTPA nor anti-human T cell antibodies uncoupled to Gd modified the MRI contrast of the human T cells in the brain.

The electronic spectra of porphyrin-like cobalt-tetracarboxy-phthalocyanines as modified by polylysine and polyglycols.

The effect of poly-L-lysine and polyglycols on the electronic spectral properties of cobalt-tetracarboxy-phthalocyanine, compound (I), was studied in order to determine the effect of the polymers on the molecular stacking properties of compound (I). In the present study we have coupled, both covalently and electrostatically, the poly-L-lysine to compound (I). The electrostatic interaction with the polylysine resulted in a bathochromic shift of absorbance by compound (I) from 680 to 695 nm, and the generation of shoulders in the 590 and 580 nm region. The bathochromic shift indicates that the polylysine either misaligns the units of compound (I) in the molecular stack or alters the angular relationship of the planar compound (I) molecules. The covalent linkage with the polylysine resulted in stabilization of the monomeric form of compound (I) with no hypochromism in the 680 nm region. The reaction of the polyglycols, dextran and DEAE dextran with compound (I) prior to the addition of the polylysine, stabilized the polymeric stacked form of compound (I) in the presence of the polylysine. Ammonium ion and ethanolamine resulted in the appearance of peaks in the 730-760 nm region; a trihydroxy containing primary amine and monomeric lysine generated no such peak at wavelengths above 700 nm. The polyglycol binding capacity of compound (I) facilitated the separation of the unbound compound (I) from the polymeric complexes.

Anti-neurofilament antibodies in the sera of patients with small cell carcinoma of the lung and with visual paraneoplastic syndrome.

The sera of patients with small cell carcinoma of the lung (SCCL) and an associated visual paraneoplastic syndrome (VPNS) have high titer immunoglobulins that react with retinal ganglion cells and with cloned lines of the SCCL. The immunoglobulins in the sera of two patients with SCCL and VPNS reacted with at least one common antigen shared by neural cells and cloned lines of the SCCL. The molecular weights of the predominant neural and tumor antigens were 205,000, 145,000, 65,000, and 20,000-24,000 as determined by Western blots. Three of the antigens from neural tissue copurify and comigrate electrophoretically with neurofilament proteins. Polyclonal antibodies prepared against authentic neurofilament proteins react with antigens having molecular weights identical to those of proteins that react with immunoglobulins from the SCCL-VPNS patients. Polyclonal antibodies that were prepared against isolated retinal ganglion cells and that were shown previously to cause the immunoablation of the ganglion cells in vivo reacted most intensely with the Mr 205,000 antigen and weakly with the Mr 145,000 and Mr 70,000 antigens. Treatment of the Western blots with alkaline phosphatase from Escherichia coli did not affect the immunoreactivity between the immunoglobulins and the purified neurofilament proteins. It is proposed that the immunoglobulins in the sera of patients with SCCL-VPNS may be involved etiologically in the development of the VPNS.

Properties of N-acetylhistamine deacetylase in mammalian brain.

Properties of N-acetylhistamine deacetylase in rat brain were studied, utilizing a sensitive coupled radioenzymatic assay. The Km for N-acetylhistamine for this deacetylase was 660 microM and its Vmax was 330 pmol/h/mg protein. N-Acetylhistamine deacetylase activity increased 80% in the presence of 1 mM Mn2+. The Km of Mn2+ was 40 microM. The enzyme is primarily a soluble enzyme with a relatively uniform regional distribution, unlike the distribution for histamine and histidine decarboxylase. Neonatal activity of this enzyme in rat brain is higher than in adult brain. alpha-Fluoromethylhistidine does not affect the activity of N-acetylhistamine, indicating that deacetylation probably does not play a regulatory role in the synthesis of brain histamine.