Comparison of 7S nerve growth factor and nerve growth factor I from mouse submandibular glands

7S nerve growth factor (7S NGF) and nerve growth factor I (NGFI) are NGF-containing protein complexes isolated from mouse submandibular glands by different protocols, and reports suggest that the molecules differ chemically. In this study, we compared the molecular properties and subunit compositions of the two proteins. Purified 7S NGF and NGFI electrophoresed to identical positions on polyacrylamide gels in nondissociating buffers, with electrophoretic mobilities indistinguishable from that of unpurified NGF in salivary gland extracts. Ultraviolet absorption curves were identical, and sedimentation coefficients were similar (7.3 +/- 0.25 S for 7S NGF; 7.2 +/- 0.2 S for NGFI) as determined by sedimentation velocity analysis. By sedimentation equilibrium analysis, molecular weights of 135 000-140 000 were obtained for both complexes at protein concentrations in the centrifuge cell greater than 85 micrograms/mL; when protein concentrations within the centrifuge cell ranged from approximately 30 to 100 micrograms/mL at equilibrium, both complexes dissociated. Molecular weight values determined by gel filtration on Bio-Gel P300 and Sephadex G200 resins were similar for both proteins, and the values determined on Sephadex agreed with those obtained by ultracentrifugation. The subunit compositions of the complexes were also similar as determined by nonequilibrium isoelectric focusing, NGFI being composed of proteins that migrated to positions identical with those of the alpha, beta, and gamma subunits of 7S NGF. Furthermore, the stoichiometry of the subunits was similar in the two complexes as determined by radioimmunoassays to each of the subunits and by densitometric analysis of electrophoretic gels. Both methods showed that the complexes contain approximately 2 mol of the alpha and gamma subunits per mole of beta-NGF.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nerve growth factor-like immunoreactivities in rodent salivary glands and testis

Summary A series of polyclonal affinity-purified antibodies against mouse submandibular-gland nerve growth factor (NGF) are described. Using the submandibular gland of the male mouse and indirect immunofluorescence, the specificity and sensitivity of affinity-purified immunoglobulins and various other fractions from the immunized animals have been tested. It will be shown that affinity-purification schemes, including pre-purification of protein A-fractionated immunoglobulins to remove antibodies that bind to unrelated hydrophilic and hydrophobic proteins, significantly enhance the signal-to-noise ratio and specificity of the antibodies. The antibodies effectively detect NGF-like immunoreactivity in both fresh and fixed glandular tissue. Optimal fixation procedures are described. Fluorescence intensities are linearly correlated to log antibody concentration. By use of the best antibody fractions and optimal fixation protocols, the distribution of NGF-like immunoreactivity is described in eight different salivary glands (rat and mouse, male and female, submandibular and sublingual glands). In addition to the well-known large numbers of immunoreactive cells in the submandibular gland of the male mouse, immunoreactive cells were found in the sublingual gland of male mice and in the submandibular and sublingual glands of female mice. One antibody revealed a weak specific fluorescence also in the submandibular gland of the male mouse. In a survey of genital organs of male mice, one antibody revealed fluorescence in the germ cell line. We conclude that several polyclonal affinity-purified antibodies have been characterized that show a strong NGF-dependent binding to the secretory granules of tubular cells in the submandibular gland of male mice. These antibodies should make it possible to locate endogenous and perturbed NGF levels immunocytochemically, e.g., in the peripheral and central nervous system, where NGF concentrations may be several orders of magnitude lower than in the salivary glands.     

Subunit structure of high molecular weight mouse nerve growth factor

Studies from several laboratories have shown that mouse submandibular glands and mouse saliva contain nerve growth factor (NGF) as part of a high molecular weight oligomeric macromolecule composed of three different subunits, termed alpha, beta, and gamma. The beta-subunit is the nerve growth-promoting protein. The gamma-subunit is a serine protease class enzyme of highly restricted substrate specificity. The alpha-subunit has no known function. This high molecular weight form of nerve growth factor is also a Zn(II)-containing metalloprotein. In the present study, measurements of multiple physicochemical parameters have been used to deduce the subunit structure of high molecular weight NGF. Results demonstrate that it contains two alpha-, one beta- and one gamma-subunit together with one tightly bound Zn(II) ion per molecule.     

Genes for the alpha and gamma subunits of mouse nerve growth factor are contiguous.

Here we describe the structure and linkage of genes encoding the alpha and gamma subunits of mouse nerve growth factor (NGF). These genes are members of the highly homologous glandular kallikrein multigene family. Together with the beta subunit, the alpha and gamma proteins constitute the high mol. wt. (7S) form of NGF isolated from mouse submandibular gland. The gamma subunit is an active serine protease and is thought to cleave pro-beta-NGF to generate the mature growth factor. The alpha subunit has no detectable proteolytic activity, but is essential for the stable formation of 7S NGF. Lack of enzyme activity of the alpha subunit can be attributed, at least in part, to the deletion of 15 nucleotides in a highly conserved coding region which is normally involved in the activation of serine proteases from their inactive zymogen form.     

Developmental changes of nerve growth factor levels in sympathetic ganglia and their target organs

The predominant source of nerve growth factor (NGF) used by mature sympathetic neurons originates in their target organs (Heumann, R., Korsching, S., Scott, J., and Thoenen, H. (1984), EMBO J. 3, 3183-3189; Korsching, S., and Thoenen, H. (1985), J. Neurosci. 5, 1058-1061). We have determined the NGF content of two sympathetically innervated mouse organs, submandibular gland and heart ventricle, and of sympathetic ganglia from mouse and rat between embryonic Day 12 (E12) and adulthood. NGF levels were measured by a two-site enzyme immunassay (Korsching, S., and Thoenen, H. (1983), Proc. Natl. Acad. Sci. USA 80, 3513-3516). In heart ventricle and submandibular gland, NGF first became detectable around the time of initial innervation by sympathetic neurons (E12 and E13, respectively) and increased respectively 14- and 7-fold in the following 2 days, to reach adult levels already at E14 for heart ventricle (1.4 +/- 0.2 ng NGF/g wet wt). NGF in the superior cervical ganglion (SCG) was first detected at the same time as in its target organ, the submandibular gland. NGF content in the SCG then increased 6-fold during the next 2 days and continued to increase until the end of the third postnatal week, when adult levels were reached. Although the levels of NGF in the adult mouse submandibular gland are sexually dimorphic and six orders of magnitude higher than those in other sympathetic target organs, no sex difference in the NGF content was found in either developing submandibular gland or SCG until the end of the third postnatal week. Moreover, the steep NGF increase observed in the male submandibular gland after postnatal Day 18 (250-fold within the following 3 days and up to the 55,000-fold in the next 7 days) was not reflected in a corresponding increase in the NGF content of the male SCG. These data indicate that, in accordance with earlier findings (see Levi-Montalcini, R., and Angeletti, P. U. (1968), Physiol. Rev. 48, 534-569), SCG neurons do not have access to the large amounts of NGF synthesized during and after adolescence in the mouse submandibular gland. Our results support the concept that initial fiber outgrowth of sympathetic neurons is neither dependent on NGF nor mediated by it. The time course of NGF levels in the SCG is consistent with the concept that sympathetic neurons are provided with NGF by means of retrograde axonal transport from the innervated organs already early in development.     

Differential localization of "brain-specific" S-100 and its subunits in rat salivary glands

In the rat, the S-100 antigens in the submandibular gland were found to be immunochemically identical with those in the brain (glial cells) when compared using crossed immunoelectrophoresis. Specific antibodies against the S-100a non-beta and against the S-100 beta subunit were prepared from antibodies against crude S-100 protein and from S-100 components (S-100a and b) by affinity chromatography. In the rat salivary glands a differential distribution of subunit immunoreactivity was clearly evidenced using indirect immunofluorescence. Certain intercalated duct cells of the submandibular gland as well as Schwann cells contained the S-100 beta subunit immunoreactivity exclusively, while other duct cells in parotid, submandibular, and sublingual glands contained S-100a non-beta subunit immunoreactivity. Both subunits were present in astrocytes and ependymal cells. The immunocytochemical localization of alpha and beta subunits is a promising technique for the classification of various types of S-100-containing cells.     

Fate of intraocular chromaffin cell suspensions: role of initial nerve growth factor support

Summary Adrenal medullary tissue from adult rats was dissociated into cell suspensions and injected into the anterior chamber of the eye, where the cells were made to attach to the previously sympathectomized irides with the use of fibronectin. Short- and long-term survival of the chromaffin cells was examined in whole mounts of irides using Falck-Hillarp fluorescence histochemistry or indirect immunohistochemistry with antibodies against adrenaline and dopamine--hydroxylase (DBH). After 6 days in oculo all cells were immunoreactive for adrenaline; almost none displayed processes even if -nerve growth factor (NGF) was given at grafting. One month after weekly intraocular injections of NGF, many cells were surrounded by nerve fiber net-works and all cells were DBH-immunoreactive. Eight months postgrafting and 7 months after the last injection of NGF almost the entire iris was reinnervated and resembled a normal, sympathetically innervated iris. Both at 1 and 8 months, chromaffin cells, ganglion cells and transitional cell forms (chromaffin cells transforming towards ganglion-like cells) were found in irides from the NGF-treated eyes. The number of ganglion cells was remarkably increased with time by NGF, while the number of chromaffin cells decreased compared to controls. A single treatment with NGF at grafting had no marked effects as examined up to 3 months; at this time there was a certain outgrowth of nerve terminals, which, however, was not as pronounced as 1 month after repeated NGF injections. In conclusion, it is shown that some cells in a chromaffin cell suspension attach to the iris, transform to ganglion cells after an induction with exogenous NGF, and reinnervate the sympathically denervated iris. Such cells remain ganglion-like in character and continue to form processes even after cessation of exogenous NGF treatment.     

Nerve growth factor: biosynthetic products of the mouse salivary glands. Characterization of stable high molecular weight and 32,000-dalton nerve growth factors

Nerve growth factor (NGF) is a protein required for the growth and development of sensory and sympathetic neurons. The NGF is present in high concentrations in male mouse salivary glands, bovine seminal plasma, and snake venom. The physiological significance of NGF in these sources is not known: it might be a part of a high molecular weight (HMW) protein with possibly different biological function and be cleaved to the functional size by proteases. In an attempt to isolate a HMW protein containing as part of its structure the low molecular weight (LMW) NGF (2.5S), mouse salivary glands were homogenized in the presence of either 8 M urea or 6 M guanidine hydrochloride (Gdn X HCl) in order to denature proteases. This procedure revealed that the LMW NGF is a part of two HMW proteins that are biologically and immunologically homologous to the mouse 2.5S NGF. One of these HMW proteins (Mr 32,000 NGF) was purified and shown to be biologically active in the NGF bioassay. Furthermore, this Mr 32,000 NGF was cleaved by the gamma subunit of mouse HMW NGF to the 2.5S NGF. Evidence is also presented that there may be a HMW protein(s) with apparent molecular weights ranging from 94,000 to 200,000 and immunologically homologous to the three subunits (alpha, beta, gamma) of 7S NGF. This HMW NGF is biologically active in the NGF bioassay, and its activity is inhibited by antibody to the beta subunit. Furthermore, in contrast to mouse 7S NGF, this HMW NGF does not dissociate in either 8 M urea or 6 M Gdn X HCl.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunocytochemical localization of nerve growth factor in mouse salivary glands

Summary The submandibular glands of female mice and the sublingual and parotid glands of adult male and female mice have been examined by light microscopical immunocytochemistry for nerve growth factor (NGF). In female submandibular glands, staining for NGF was observed in granular convoluted tubule and striated duct cells. Sublingual glands of the mouse contained relatively few granular cells staining for NGF compared with submandibular glands. However, such granular cells appeared to be more numerous in male sublingual glands than in female glands. The remainder of the intralobular duct cells in both male and female sublingual glands exhibited apical subluminal staining for NGF as well as light basal plasmalemmal staining. Parotid glands in both male and female mice exhibited a similar pattern of staining for NGF in striated duct cells. However, the glands did not contain granular cells nor did they exhibit any pattern of staining which reflected a sexual dimorphism. Immunodot staining of salivary gland extracts confirmed the presence of immunoreactivity for NGF in all three of the major salivary glands.     

Nerve growth factor-induced increase in [3H]thymidine incorporation into pancreas of young rats and its partial blockade by propranolol or partial sialoadenectomy

Administration of nerve growth factor (NGF) twice daily for 2 days to rats 11 days at the time of the initial injection resulted in a 6.6-fold increase in [3H]thymidine levels of pancreas, when comparison was made to levels of untreated controls. Isoproterenol (ISO), a beta-adrenergic agonist known to produce marked increase in [3H]thymidine incorporation into DNA of salivary glands, caused increases in levels of [3H]thymidine in pancreas that were similar in magnitude to those induced by NGF. The combined administration of ISO and NGF did not cause any increase above those observed with either agent alone. Administration of propranolol (3 mg/kg body wt) prior to administration of ISO prevented the usual ISO-induced increase in DNA synthesis, but propranolol in either a 3- or 9-mg/kg body wt dose, caused only a 50% inhibition of NGF-induced thymidine incorporation. In the absence of the submandibular-sublingual glands, the ISO failed to induce the usual high levels of thymidine incorporation, whereas NGF induced the same high levels observed in rats with submandibular glands intact. NGF did not alter the distribution of beta 1- and beta 2-adrenoceptors in the pancreas but did increase norepinephrine when the initial administration was at age 5 days, but not when it was given at age 10 days. Since NGF increased DNA synthesis in the absence of submandibular-sublingual glands, whereas ISO did not, this suggests that ISO requires NGF to induce beta 1-activation and subsequent synthesis and that NGF is a direct activator.     

An immunohistochemical study performed with monoclonal and polyclonal antibodies to mouse epidermal growth factor

We developed two monoclonal antibodies, E5 and F5, which react with mouse epidermal growth factor (mEGF) and urogastrone. These antibodies and a rabbit antiserum to mEGF were used for immunohistochemical analysis of staining reactions in rodent and human tissues. Our results do not confirm the published reports of EGF-like immunoreactivity in Brunner's glands, human submandibular glands, human kidney tissue, or rodent brain sections.     

Molecular cloning of bovine and chick nerve growth factor (NGF): delineation of conserved and unconserved domains and their relationship to the biological activity and antigenicity of NGF.

Previous experiments with purified mouse and bovine nerve growth factor (NGF) have shown that the biological activities of these two NGFs are identical, whereas the immunological cross-reactivity of antibodies produced against the two NGF molecules is very limited. This observation, together with the fact that antibodies to mouse NGF do not affect the development of sympathetic and sensory neurons in chick embryos, suggests that the domain of the NGF molecules responsible for the biological action has been highly conserved during evolution, whereas other domains determining the immunological properties were under less rigorous evolutionary constraint. The nucleotide sequences of bovine and chick NGF were determined from a cDNA clone prepared from mRNA of bovine seminal vesicles and from cloned chick genomic DNA, and the amino acid sequences deduced therefrom were compared with the available sequences of mouse and human NGF. All six cysteine residues were conserved in agreement with the previous finding that the biological activity of NGF is conformation-dependent requiring intact disulfide bridges. Amino acid changes are mainly confined to hydrophilic regions expected to be potential antigenic determinants, thus providing an explanation for the poor immunological cross-reactivities between the different NGFs. One single hydrophilic region is conserved in all NGFs and this region could be involved in the biological activity. The carboxy termini of bovine and chick NGF differ from that of mouse NGF, the changes in the amino acid sequences suggest that chick and bovine NGF are probably not processed by the gamma-subunit and that no 7S complex can be formed as in the mouse submandibular gland.     

Detection of nerve growth factor and its mRNA by separate and combined immunohistochemistry andin situ hybridization in mouse salivary glands

Summary Intense labelling of secretory cells in the male mouse submandibular gland was observed afterin situ hybridization using mouse nerve growth factor (NGF) cDNA probes. Under the same conditions, sparse less intensely labelled cells were also found in the sublingual gland. Hybridization to a chicken NGF cDNA probe gave weak labelling on the glands in accordance with a weak cross-hybridization between mouse NGF mRNA and chicken NGF cDNA probes, whereas no labelling was seen using pUC9 DNA as a hybridization probe. A combination ofin situ hybridization and immunohistochemistry was also carried out on the same sections of submandibular gland. A good correlation was seen between actively synthesizing and intensely immunoreactive cells in the gland. The technique described here allows the detection of individual cells synthesizing relatively low levels of NGF. The combination ofin situ hybridization and immunocytochemistry on the same section should be particularly useful in cases where NGF is transported away from its site of synthesis.     

Effects of selective denervation and nerve growth factor on activity-mediated growth of rat parotid gland.

A dietary change from all liquid to solid food is followed by an average increase of 200% in [3H]thymidine uptake into the parotid gland of rat. However, removal of either the parasympathetic (Px) or the sympathetic (Sx) innervation to the parotid gland prior to the dietary change resulted in a partial inhibition of the increase; values for the parasympathectomized gland were 51% of those of the innervated gland, and values of the sympathectomized parotid gland were 42% of those of the innervated gland. Removal of both autonomic nerves caused a complete inhibition. Initiation of nerve growth factor (NGF) injection (1 microgram/kg body wt, two times daily for the 2 days of chow refeeding) at the time of chow refeeding had no effect on completely or partially denervated glands, and thymidine values for the denervated parotid gland of rats given NGF did not differ statistically from those of rats not given NGF. With parasympathectomy, sympathectomy, and complete denervation, weight of parotid gland was decreased from that of innervated glands, and administration of NGF had no effect on the denervation-induced decreases. The data show that both branches of the innervation to parotid gland must be intact to ensure a maximal increase in thymidine uptake with the dietary change from liquid to solid food. The level of the enzyme, beta 1-4 galactosyltransferase, involved in proliferation, also depended on the presence of intact nerves. Enzyme activity of innervated parotid gland showed an average increase of 200% with chow refeeding of rats previously on liquid diet, but with Px, the average increase was 51% of that of the innervated parotid, and with Sx, it was 41%. NGF administration did not cause any change in levels of this enzyme in any Px or PxSx parotid gland and only a small change in Sx parotid; it did increase levels of this enzyme in parotid of rats without submandibular-sublingual glands.     

Biological and biochemical properties of nerve growth factor synthesized by mouse S-180 cells in culture

Nerve Growth Factor (NGF), a protein involved in the maintenance and differentiation of sensory and sympathetic neuronal cells [1], is synthesized by several different types of cells in culture [2-7]. In this paper, the biochemical and biological properties of NGF synthesized by a mouse S-180 sarcoma cell line were examined. These cells do not appear to produce the 7S-NGF molecule, a form of NGF found in high concentrations in the mouse submandibular gland [8]. The 7S-NGF is comprised of three distinct protein subunits named beta-NGF, alpha and gamma [9]. Although the S-180 cells do not produce 7S-NGF, the cells do synthesize one of the component subunits of 7S-NGF, the beta-NGF subunit. Biological, electrophoretic, immunological and molecular weight criteria were used to establish that the beta-NGF synthesized by the S-180 cells is very similar to the submandibular gland beta-NGF. The S-180 beta-NGF was bound to an unidentified binding component(s) which is not immunologically similar to either the alpha- or gamma-subunit. The functional significance of this interaction is not known.     

Beta 1 subunits of sodium channels. Studies with subunit-specific antibodies

The purified Na+ channel from rat brain consists of alpha (260 kDa), beta 1 (36 kDa), and beta 2 (33 kDa) subunits. Pure beta 1 subunits were prepared from purified rat brain Na+ channels which had been adsorbed to hydroxylapatite resin and used to prepare specific anti-beta 1 subunit antiserum. Antibodies purified from this antiserum by antigen affinity chromatography immunoprecipitate 125I-labeled, purified beta 1 subunits and purified Na+ channels (measured as high affinity [3H] saxitoxin binding sites) and recognize beta 1 subunits on immunoblots of solubilized rat brain membranes. The affinity-purified anti-beta 1 antibodies recognize beta 1 subunits in rat spinal cord, heart, skeletal muscle, and sciatic nerve, but do not detect immunoreactive beta 1 subunits in eel electroplax or eel brain. The developmental time course of expression of immunoreactive beta 1 subunits in rat forebrain was measured by immunoprecipitation followed by immunoblotting with affinity-purified anti-beta 1 antibodies. The amount of immunoreactive beta 1 subunits increased steadily to adult levels during the first 21 days of postnatal development.     

Kallikrein localization in rodent salivary glands and kidney with the immunoglobulin-enzyme bridge technique.

Kallikrein has been localized in rodent kidney and salivary glands by means of an immunoglobulin-enzyme bridge technique. In sections of kidney, anti-kallikrein antibodies bound to the apical region of certain distal tubule segments in the cortex, to reabsorption droplets of proximal convoluted tubules, and to certain duct segments in the papilla. In salivary glands of both male and female rats and mice, and apical rim of most striated duct cells of submandibular, parotid and sublingual glands and granular tubules of submandibular glands exhibited immunoreactivity. Granular intercalated duct cells in female submandibular glands also displayed immunostaining for kallikrein. Phenylephrine administration resulted in loss of immunoreactive granules from the granular convoluted tubule cells of male mouse submandibular gland. This response was paralleled by a biochemically demonstrable decrease in kallikrein-like tosylarginine methyl ester (TAME) esterase activity.     

Immunocytochemical localization and concentrations of the α and γ subunits of 7S-nerve growth factor in the submandibular gland of the mouse

Summary For unexplained reasons, nerve growth factor (NGF) exists in very high concentrations in the submandibular gland of the mouse. The NGF in the gland, called 7S-NGF, is a non-covalent complex of three protein subunits, named -, - and -NGF. All the known biological activity resides in the -NGF subunit, and previous studies have shown that -NGF is present in much greater concentrations in the male submandibular gland than in the female gland. The higher concentration in the male is due to the fact that -NGF is synthesized in the granular tubule cells of the submandibular gland. These cells are much more numerous in the male gland.In contrast to -NGF, neither the concentrations of and subunits nor their cellular localization in the mouse submandibular gland have been established. In this study, radioimmunoassays specific for . and subunits determined that both are present in much higher concentrations in the male gland. Immunocytochemical work localized both subunits in the granular tubule cell in the male and female submandibular gland. This indicates that all the components of 7S-NGF exist in a single cell type in the gland and suggests that 7S-NGF can be formed within this cell and secreted as a complex into the saliva.     

Expression of the alpha subunit of 7S nerve growth factor in the mouse submandibular gland

-NGF is an inactive serine protease that is associated in the mouse submandibular gland with a closely related serine protease, -NGF, and the neurotrophic factor, -NGF. The heterogeneity of purified -NGF has been examined by DEAE-cellulose chromatography and SDS polyacrylamide gel electrophoresis. A possible explanation for the observed heterogeneity is presented. Antibodies have been prepared against -NGF and purified by affinity chromatography so that they do not cross-react with -NGF. This antibody preparation recognizes two very similar proteins in male mouse submandibular gland RNA-directed cell-free translation mixtures. The expression of only one of these forms is regulated by testosterone. Oligonucleotide probes specific for each of the three NGF subunits have been prepared and used for Northern blot analysis of RNA from the mouse submandibular gland. The three subunits were found to be coordinately expressed and each were 30-fold more abundant in male than in female glands.Abbreviations used NGF nerve growth factor - -, -, and -NGF -, -, and -subunits of mouse 7S NGF - PBS phosphate buffered saline - DTT dithiothreitol - PPO 2,5-Diphenyloxazole - DMSO dimethylsulfoxide - HEPES N-2-Hydroxyethylpiperazine-N-2-ethanesulfonic acid - SSC 0.15M NaCl, 15 mM sodium citrate Supported by USPHS research grant NS19964. This paper is respectfully dedicated to Profs. Eric M. Shooter and Silvio Varon in recognition of their many contributions to our understanding of the structure and function of nerve growth factor.