Karen E. DeBell

Phospholipase C-mediated hydrolysis of PIP2 releases ERM proteins from lymphocyte membrane.

Mechanisms controlling the disassembly of ezrin/radixin/moesin (ERM) proteins, which link the cytoskeleton to the plasma membrane, are incompletely understood. In lymphocytes, chemokine (e.g., SDF-1) stimulation inactivates ERM proteins, causing their release from the plasma membrane and dephosphorylation. SDF-1–mediated inactivation of ERM proteins is blocked by phospholipase C (PLC) inhibitors. Conversely, reduction of phosphatidylinositol 4,5-bisphosphate (PIP2) levels by activation of PLC, expression of active PLC mutants, or acute targeting of phosphoinositide 5-phosphatase to the plasma membrane promotes release and dephosphorylation of moesin and ezrin. Although expression of phosphomimetic moesin (T558D) or ezrin (T567D) mutants enhances membrane association, activation of PLC still relocalizes them to the cytosol. Similarly, in vitro binding of ERM proteins to the cytoplasmic tail of CD44 is also dependent on PIP2. These results demonstrate a new role of PLCs in rapid cytoskeletal remodeling and an additional key role of PIP2 in ERM protein biology, namely hydrolysis-mediated ERM inactivation.

Membrane Raft-Dependent Regulation of Phospholipase Cγ-1 Activation in T Lymphocytes

ABSTRACT Numerous signaling molecules associate with lipid rafts, either constitutively or after engagement of surface receptors. One such molecule, phospholipase Cγ-1 (PLCγ1), translocates from the cytosol to lipid rafts during T-cell receptor (TCR) signaling. To investigate the role played by lipid rafts in the activation of this molecule in T cells, an influenza virus hemagglutinin A (HA)-tagged PLCγ1 was ectopically expressed in Jurkat T cells and targeted to these microdomains by the addition of a dual-acylation signal. Raft-targeted PLCγ1 was constitutively tyrosine phosphorylated and induced constitutive NF-AT-dependent transcription and interleukin-2 secretion in Jurkat cells. Tyrosine phosphorylation of raft-targeted PLCγ1 did not require Zap-70 or the interaction with the adapters Lat and Slp-76, molecules that are necessary for TCR signaling. In contrast, the Src family kinase Lck was required. Coexpression in HEK 293T cells of PLCγ1-HA with Lck or the Tec family kinase Rlk resulted in preferential phosphorylation of raft-targeted PLCγ1 over wild-type PLCγ1. These data show that localization of PLCγ1 in lipid rafts is sufficient for its activation and demonstrate a role for lipid rafts as microdomains that dynamically segregate and integrate PLCγ1 with other signaling components.

Cbl-mediated Regulation of T Cell Receptor-induced AP1 Activation IMPLICATIONS FOR ACTIVATION VIA THE Ras SIGNALING PATHWAY

The functional role of Cbl in regulating T cell receptor (TCR)-mediated signal transduction pathways is unknown. This study uses Cbl overexpression in conjunction with a Ras-sensitive AP1 reporter construct to examine its role in regulating TCR-mediated activation of the Ras pathway. Cbl overexpression in Jurkat T cells inhibited AP1 activity after TCR ligation. However, AP1 induction by 4β-phorbol 12-myristate 13-acetate, which up-regulates Ras activity in a protein kinase C-dependent, TCR/tyrosine kinase-independent manner, was not affected by Cbl overexpression. Cbl overexpression also did not affect AP1 induction by an activated Ras protein or a membrane-bound form of the guanine nucleotide exchange factor Sos. In addition, activation of the mitogen-activated protein kinase Erk2 was decreased by Cbl overexpression. Therefore, Cbl regulates events that are required for full TCR-mediated Ras activation, and data are presented to support a model whereby Cbl regulates events required for Ras activation via its association with Grb2.

Functional Independence and Interdependence of the Src Homology Domains of Phospholipase C-γ1 in B-Cell Receptor Signal Transduction

ABSTRACT B-cell receptor (BCR)-induced activation of phospholipase C-γ1 (PLCγ1) and PLCγ2 is crucial for B-cell function. While several signaling molecules have been implicated in PLCγ activation, the mechanism coupling PLCγ to the BCR remains undefined. The role of PLCγ1 SH2 and SH3 domains at different steps of BCR-induced PLCγ1 activation was examined by reconstitution in a PLCγ-negative B-cell line. PLCγ1 membrane translocation required a functional SH2 N-terminal [SH2(N)] domain, was decreased by mutation of the SH3 domain, but was unaffected by mutation of the SH2(C) domain. Tyrosine phosphorylation did not require the SH2(C) or SH3 domains but depended exclusively on a functional SH2(N) domain, which mediated the association of PLCγ1 with the adapter protein, BLNK. Forcing PLCγ1 to the membrane via a myristoylation signal did not bypass the SH2(N) domain requirement for phosphorylation, indicating that the phosphorylation mediated by this domain is not due to membrane anchoring alone. Mutation of the SH2(N) or the SH2(C) domain abrogated BCR-stimulated phosphoinositide hydrolysis and signaling events, while mutation of the SH3 domain partially decreased signaling. PLCγ1 SH domains, therefore, have interrelated but distinct roles in BCR-induced PLCγ1 activation.

Intramolecular Regulation of Phospholipase C-γ1 by Its C-Terminal Src Homology 2 Domain

ABSTRACT Phosphoinositide-specific phospholipase C-γ1 (PLC-γ1) is a key enzyme that governs cellular functions such as gene transcription, secretion, proliferation, motility, and development. Here, we show that PLC-γ1 is regulated via a novel autoinhibitory mechanism involving its carboxy-terminal Src homology (SH2C) domain. Mutation of the SH2C domain tyrosine binding site led to constitutive PLC-γ1 activation. The amino-terminal split pleckstrin homology (sPHN) domain was found to regulate the accessibility of the SH2C domain. PLC-γ1 constructs with mutations in tyrosine 509 and phenylalanine 510 in the sPHN domain no longer required an intact amino-terminal Src homology (SH2N) domain or phosphorylation of tyrosine 775 or 783 for activation. These data are consistent with a model in which the SH2C domain is blocked by an intramolecular interaction(s) that is released upon cellular activation by occupancy of the SH2N domain.

Differential effects of Cbl and 70Z/3 Cbl on T cell receptor-induced phospholipase Cγ-1 activity

We demonstrate that the differential effects Cbl and oncogenic 70Z/3 Cbl have on Ca2+/Ras‐sensitive NF‐AT reporters is partially due to their opposing ability to regulate phospholipase Cγ1 (PLCγ1) activation as demonstrated by analysis of the activation of an NF‐AT reporter construct and PLCγ1‐mediated inositol phospholipid (PI) hydrolysis. Cbl over‐expression resulted in reduced T cell receptor‐induced PI hydrolysis, in the absence of any effect on PLCγ1 tyrosine phosphorylation. In contrast, expression of 70Z/3 Cbl led to an increase in basal and OKT3‐induced PLCγ1 phosphorylation and PI hydrolysis. These data indicate that Cbl and 70Z/3 Cbl differentially regulate PLCγ1 phosphorylation and activation. The implications of these data on the mechanism of Cbl‐mediated signaling regulation are discussed.

A dynamic constitutive and inducible binding of c-Cbl by PLCγ1 SH3 and SH2 domains (negatively) regulates antigen receptor-induced PLCγ1 activation in lymphocytes

We investigated the structural requirements for c-Cbl-mediated inhibition of Ag receptor-induced PLCgamma1 activation. Analysis of site-specific c-Cbl mutants indicated that tyrosine phosphorylation of c-Cbl was required for down-regulation of the PLCgamma1/Ca2+ pathway. Coprecipitation experiments indicated that c-Cbl and PLCgamma1 constitutively interact through a PLCgamma1 SH3 domain-dependent mechanism and that c-Cbl and PLCgamma1 can inducibly interact through the SH2(C) domain of PLCgamma1. Additional data indicate that the SH3 domain of PLCgamma1 binds to both canonical and noncanonical SH3 domain-binding sites in the proline-rich region of c-Cbl. Overexpression of c-Cbl in a PLCgamma-deficient B cell line, P10-14, stably reconstituted with wild-type PLCgamma1 led to a significant decrease in B cell receptor-induced NF-AT-dependent transcription, a PLCgamma- and Ca(2+)-dependent event. In contrast, c-Cbl overexpression in P10-14 cells reconstituted with a PLCgamma1 SH3 domain mutant had little effect on receptor-induced NF-AT activation. These data suggest that c-Cbl-mediated regulation of PLCgamma1 requires an interaction between c-Cbl and PLCgamma1 that is primarily mediated by the SH3 domain of PLCgamma1. The interaction of c-Cbl with PLCgamma1 may negatively effect events required for PLCgamma1 activation.

70Z/3 Cbl induces PLC gamma 1 activation in T lymphocytes via an alternate Lat- and Slp-76-independent signaling mechanism

The oncoprotein 70Z/3 Cbl signals in an autonomous fashion or through blockade of endogenous c-Cbl, a negative regulator of signaling. The mechanism of 70Z/3 Cbl-induced signaling was investigated by comparing the molecular requirements for 70Z/3 Cbl- and TCR-induced phospholipase Cγ1 (PLCγ1) activation. 70Z/3 Cbl-induced PLCγ1 tyrosine phosphorylation required, in addition to the PLCγ1 N-terminal SH2 domain, the C-terminal SH2 and SH3 domains that were dispensable for TCR-induced phosphorylation. Deletion of the leucine zipper of 70Z/3 Cbl did not eliminate 70Z/3 Cbl-induced PLCγ1 phosphorylation, suggesting that blockage of c-Cbl via dimerization with 70Z/3 Cbl cannot fully explain 70Z/3 Cbl activating characteristics. The complete elimination of PLCγ1 phosphorylation required deleting the SH3 domain-binding region of 70Z/3 Cbl, consistent with 70Z/3 Cbl binding the PLCγ1 SH3 domain. 70Z/3 Cbl-induced PLCγ1 phosphorylation required Zap-70, as for the TCR, and the tyrosine kinase binding domain of 70Z/3 Cbl, which binds Zap-70, but did not require PLCγ1 binding to Lat, a crucial interaction in TCR-induced PLCγ1 phosphorylation. Furthermore, 70Z/3 Cbl-induced activation of NFAT, a PLCγ1/Ca2+-dependent transcriptional event, required Zap-70, but was independent of Slp-76, an adapter required for TCR-induced NFAT activation. These results suggest that 70Z/3 Cbl and PLCγ1 form a TCR-, Lat- and Slp-76-independent complex that leads to PLCγ1 phosphorylation and activation.

Phospholipase C–mediated hydrolysis of PIP2 releases ERM proteins from lymphocyte membrane

1. 1. Hao, 2. et al . 2009. J. Cell Biol. doi:10.1083/jcb.200807047. [OpenUrl][1][Abstract/FREE Full Text][2] [1]: {openurl}?query=rft_id%253Dinfo%253Adoi%252F10.1083%252Fjcb.200807047%26rft_id%253Dinfo%253Apmid%252F19204146%26rft.genre%253Darticle%26rft_val_fmt%253Dinfo%