Characteristics of the purified nerve growth factor antibody

De novo synthesis of NGF subunits in S-180 mouse sarcoma cell line

It is an accepted hypothesis that the nerve growth factor protein (NGF) plays an important role in the development of vertebrate sympathetic and sensory ganglia and has effects on some central neurons. The best known NGF species is that isolated from mouse submaxillary gland, MSG-NGF. MSG-NGF can be isolated as a subunit containing protein, 7S-NGF, made up of three dissimilar subunits called alpha-, beta-, and gamma-NGF. Beta-NGF is the biologically active subunit and its synthesis in vivo and in vitro has been demonstrated. Less is known about the synthesis of the alpha- and gamma-NGF or the assembly of the subunits into the 7S complex. In order to develop a clonal model system for the study of NGF synthesis, processing and secretion, affinity chromatography techniques were applied to cell extracts of S180 mouse sarcoma, a cell line known to synthesize NGF. After incubating S180 cells in 35S-Methionine, cell extracts were exposed to antibody directed against alpha-NGF, gamma-NGF or beta-NGF covalently bound to Sepharose beads in order to elute and characterize the desired NGF subunits. Parallel experiments using immunoabsorbed [35S]Methionine-beta-NGF were carried out in the presence or absence of excess NGF, in order to demonstrate the specificity of this procedure. Affinity chromatography with a substrate analogue to arginine ester bound to Sepharose beads was also used to isolate de novo synthesized gamma-NGF.(ABSTRACT TRUNCATED AT 250 WORDS)

Retinal ganglion cell response to axotomy and nerve growth factor antiserum in the regenerating visual system of the newt (Notophthalmus viridescens): an ultrastructural morphometric analysis

One 3.0 mg dose of the nerve growth factor antiserum (anti-NGF) injected into the vitreous chamber of the eye at the time of optic nerve transection elicits significant changes in the normal newt (Notophthalmus viridescens) retinal ganglion cell body response to axotomy at 7 and 14 days postaxotomy (DPA). Light microscopic observations indicate that anti-NGF treatment significantly reduces the per cent of retinal ganglion cells demonstrating nuclear chromatin reactivity (ie., homogeneous to a more heterogeneous state) from 33.36 +/- 3.02 to 22.82 +/- 2.98%. In addition, the per cent of retinal ganglion cells demonstrating prominent nucleoli is dramatically decreased from 32.08 +/- 1.64 to 18.20 +/- 1.79% at 7 DPA. It is also important to note that the number of prominent nucleoli in the 7 DPA group is reduced to such an extent by anti-NGF treatment that the value is not significantly different from that of intact controls. Intact controls will routinely exhibit approximately half the number of prominent nucleoli that are normal for the untreated 7 DPA group. A definite dose-response relationship can be shown to exist between the per cent of nuclear reactive ganglion cells demonstrating prominent nucleoli and various anti-NGF concentrations at 14 DPA. There does not appear to be a dose-response relationship between various anti-NGF concentrations and the per cent of retinal ganglion cells demonstrating nuclear reactivity at 14 DPA. However, the degree of nuclear chromatin reactivity appears to be less at the higher anti-NGF concentrations (ie., greater than or equal to 3.0 mg/eye) at 14 DPA. Electron microscopic morphometric analysis reveals that anti-NGF treatment significantly reduces the cell perikaryal area at 7 and 14 DPA while the nuclear area remains unchanged. Therefore, there is a significant decrease in the cytoplasmic/nuclear ratios at both 7 and 14 DPA in response to anti-NGF treatment which appears more pronounced by 14 DPA. Anti-NGF treatment also significantly reduces the mitochondrial and nucleolar densities, as well as the nucleolar areas of cells at 7 and 14 DPA. There are no significant changes in Golgi field densities in response to anti-NGF treatment.