H. Garrett Wada

Duration and magnitude of nerve growth factor signaling depend on the ratio of p75LNTR to TrkA.

The role of the low affinity neurotrophin receptor p75LNTR in neurotrophin signal transduction remains open. Recent reports show that this receptor generates intracellular signals independent of Trk activity, and others imply that it collaborates with Trk(s) to enhance cellular responses to low neurotrophin concentrations. We have used the Cytosensor microphysiometer as a direct marker of intracellular metabolic activity to address the physiologic role of p75LNTR in nerve growth factor (NGF) signal transduction. NGF treatment of PC12 or TrkA‐transfected Chinese hamster ovary (CHO) cells results in a rapid, transient increase in the extracellular acidification rate as measured by the Cytosensor; in both cell types, p75LNTR enhances this response. p75LNTR affects both the magnitude of and the duration of the extracellular acidification response to NGF. Moreover, it is not merely the presence of p75LNTR, but also the ratio of p75LNTR:TrkA which determines cellular responsiveness to NGF. In transiently transfected CHO cells, a 5:1 ratio of p75LNTR:trkA cDNAs produced the greatest change in NGF‐induced acid secretion. Pretreatment of PC12 cells with anti‐p75LNTR antibodies decreased the responsiveness to NGF. However, long‐term NGF exposure to PC12 cells in which p75LNTR expression was decreased to approximately 10% of wild‐type levels showed a longer duration of acid secretion compared to wild‐type PC12 cells. Together, these data suggest that p75LNTR may play a dual role in modulating NGF signal transduction by enhancing and extending cellular responses to short‐term ligand exposures while attenuating the metabolic response to long‐term ligand exposures. With regard to potential Trk‐independent p75LNTR signal transduction mechanisms, we detected no change in extracellular acidification response in 75LNTR‐transfected CHO cells, PCNA‐15 fibroblasts, or Schwann cells, all of which express large amounts of p75LNTR and no Trk. Thus, p75LNTR cannot produce any signal detected by microphysiometry in the absence of TrkA. J. Neurosci. Res. 51:442–453, 1998. © 1998 Wiley‐Liss, Inc.

Characterization of two different alkaline phosphatases in mouse teratoma: Partial purification, electrophoretic, and histochemical studies

Alkaline phosphatase (E.C.3.1.3.1.) has been used as a marker for embryonal carcinoma cells which constitute the multipotential stem cells of the mouse teratoma. Studies by other investigators based on kinetics of thermal inactivation and L-phenylalanine inhibition have shown that the alkaline phosphatase of the teratoma differs from the mouse intestinal and liver isozymes, but resembles the isozymes of kidney and placenta. Since functional characterization of nonpurified enzymes is not the most accurate means for distinguishing different molecular forms of an enzyme, we have partially purified the enzymes from the ascitic (embryoid body) and solid tumor forms of the OTT-6050 teratoma line, and utilized the technique of electrophoresis in polyacrylamide gels to compare the teratoma enzyme with isozymes from kidney and placenta. Covalent 32PO4-labeling of the alkaline phosphatases and polyacrylamide gel electrophoresis in sodium dodecylsulfate was also used to compare the subunit molecular weights of the enzymes. The results indicate that the mouse teratoma enzyme is distinct from the kidney and placental isozymes. Since histochemical studies have localized the enzyme to the stem cell population of the teratoma, the results imply that stem cell alkaline phosphatase is a distinct isozyme. The embryoid bodies contain a second alkaline phosphatase which may correspond to the placental isozyme. This enzyme may be attributed to the outer cell layer of embryoid bodies of the ascitic tumor, since this cell type histochemically demonstrates alkaline phosphatase activity.

The role of N-linked oligosaccharides of MHC class II antigens in T cell stimulation

A specific increase in T cell extracellular acidification rate has been demonstrated recently when complexes of purified MHC class II molecules and antigenic peptides interact with T cell receptors (TCRs) on cloned T cells. The present study shows that such measurements of an increase in extracellular acidification rate can be used to evaluate the functional role of various N-linked oligosaccharides of MHC class II antigens. Affinity-purified murine IAk and IAs were deglycosylated in the presence of aspargine-amidase enzyme and were characterized by SDS-polyacrylamide gel electrophoresis. The complete removal of all three N-linked oligosaccharides from the alpha/beta heterodimer was confirmed by four different lectin-linked Western blot analyses. Similar to the native heterodimer, both deglycosylated IAk and deglycosylated IAs were fully capable of binding synthetic antigenic peptides derived from myelin basic protein (MBP). When equivalent amount of glycosylated and deglycosylated class II-peptide complexes were exposed to restricted cloned T cells, identical increases in T cell extracellular acidification rates were observed. The specificity of such increases in extracellular acidification rate was demonstrated by exposing cloned T cells to irrelevant complexes of glycosylated and deglycosylated class II and antigenic peptides. These results show how measurement of extracellular acidification rate can be used to study structure-function correlations of ligand-receptor interactions, and support an earlier observation that N-linked oligosaccharides of murine MHC class II molecules are not involved in either antigenic peptide binding or T cell recognition.