Definition of the interacting interfaces of Apobec3G and HIV-1 Vif using MAPPIT mutagenesis analysis.

The host restriction factor Apobec3G is a cytidine deaminase that incorporates into HIV-1 virions and interferes with viral replication. The HIV-1 accessory protein Vif subverts Apobec3G by targeting it for proteasomal degradation. We propose a model in which Apobec3G N-terminal domains symmetrically interact via a head-to-head interface containing residues 122 RLYYFW 127. To validate this model and to characterize the Apobec3G-Apobec3G and the Apobec3G-Vif interactions, the mammalian protein-protein interaction trap two-hybrid technique was used. Mutations in the head-to-head interface abrogate the Apobec3G-Apobec3G interaction. All mutations that inhibit Apobec3G-Apobec3G binding also inhibit the Apobec3G-Vif interaction, indicating that the head-to head interface plays an important role in the interaction with Vif. Only the D128K, P129A and T32Q mutations specifically affect the Apobec3G-Vif association. In our model, D128, P129 and T32 cluster at the edge of the head-to-head interface, possibly forming a Vif binding site composed of two Apobec3G molecules. We propose that Vif either binds at the Apobec3G head-to-head interface or associates with an RNA-stabilized Apobec3G oligomer.

MAPPIT (mammalian protein-protein interaction trap) analysis of early steps in toll-like receptor signalling.

The mammalian protein-protein interaction trap (MAPPIT) is a two-hybrid technique founded on type I cytokine signal transduction. Thereby, bait and prey proteins are linked to signalling deficient cytokine receptor chimeras. Interaction of bait and prey and ligand stimulation restores functional JAK (Janus kinase)-STAT (signal transducers and activators of transcription) signalling, which ultimately leads to the transcription of a reporter or marker gene under the control of the STAT3-responsive rPAP1 promoter. In the subsequent protocol, we describe the use of MAPPIT to study early events in Toll-like receptor (TLR) signalling. We here demonstrate a "signalling interaction cascade" from TLR4 to IRAK-1.

MAPPIT (MAmmalian Protein-Protein Interaction Trap) as a tool to study HIV reverse transcriptase dimerization in intact human cells.

The high mutation rate of Human Immunodeficiency Virus (HIV) leads to the rapid derivation of compound-resistant virus strains and thus necessitates the identification and development of compounds with alternative mode of actions. MAPPIT (MAmmalian Protein-Protein Interaction Trap) is a highly efficient tool to study protein-protein interactions in intact human cells and is applied to study the dimerization process of the HIV reverse transcriptase complex. Highly specific signals for the p66/p51 and p66/p66 interactions could readily be detected. Specificity was established further by introducing mutations in either subunit. Treatment with efavirenz resulted in an increased MAPPIT signal, with an EC50 value of 64nM for the p66/p51 interaction, and allowed detection of the p51/p51 homodimerization, confirming the context-dependent asymmetric contribution of both subunits. These results show that MAPPIT can be used as a novel screening tool for anti-HIV compounds in intact human cells.

Mammalian protein-protein interaction trap (MAPPIT) analysis of STAT5, CIS, and SOCS2 interactions with the growth hormone receptor.

Binding of GH to its receptor induces rapid phosphorylation of conserved tyrosine motifs that function as recruitment sites for downstream signaling molecules. Using mammalian protein-protein interaction trap (MAPPIT), a mammalian two-hybrid method, we mapped the binding sites in the GH receptor for signal transducer and activator of transcription 5 (STAT5) a and b and for the negative regulators of cytokine signaling cytokine-inducible Src-homology 2 (SH2)-containing protein (CIS) and suppressor of cytokine signaling 2 (SOCS2). Y534, Y566, and Y627 are the major recruitment sites for STAT5. A non-overlapping recruitment pattern is observed for SOCS2 and CIS with positions Y487 and Y595 as major binding sites, ruling out SOCS-mediated inhibition of STAT5 activation by competition for shared binding sites. More detailed analysis revealed that CIS binding to the Y595, but not to the Y487 motif, depends on both its SH2 domain and the C-terminal part of its SOCS box, with a critical role for the CIS Y253 residue. This functional divergence of the two CIS/SOCS2 recruitment sites is also observed upon substitution of the Y+1 residue by leucine, turning the Y487, but not the Y595 motif into a functional STAT5 recruitment site.

The C-terminus of CIS defines its interaction pattern.

Proteins of the SOCS (suppressors of cytokine signalling) family are characterized by a conserved modular structure with pre-SH2 (Src homology 2), SH2 and SOCS-box domains. Several members, including CIS (cytokine-inducible SH2 protein), SOCS1 and SOCS3, are induced rapidly upon cytokine receptor activation and function in a negative-feedback loop, attenuating signalling at the receptor level. We used a recently developed mammalian two-hybrid system [MAPPIT (mammalian protein-protein interaction trap)] to analyse SOCS protein-interaction patterns in intact cells, allowing direct comparison with biological function. We find that, besides the SH2 domain, the C-terminal part of the CIS SOCS-box is required for functional interaction with the cytokine receptor motifs examined, but not with the N-terminal death domain of the TLR (Toll-like receptor) adaptor MyD88. Mutagenesis revealed that one single tyrosine residue at position 253 is a critical binding determinant. In contrast, substrate binding by the highly related SOCS2 protein, and also by SOCS1 and SOCS3, does not require their SOCS-box.

Review: Negative regulation of leptin receptor signalling.

Leptin was discovered as an adipostat, regulating body weight by balancing food intake and energy expenditure. Recently, leptin emerged as a pleiotropic cytokine. It plays a substantial role in a wide spectrum of other functions including immune regulation, bone formation and fertility. Leptin signalling is under tight control. Aberrations of this stringent control system may be implicated in a variety of pathologies. Here, we review the various mechanisms that control cellular leptin receptor signalling.

Pleiotropy of leptin receptor signalling is defined by distinct roles of the intracellular tyrosines.

The leptin receptor (LEPR) is a class I cytokine receptor signalling via both the janus kinase/signal transducer and activator of transcription (JAK/STAT) and the MAP kinase pathways. In addition, leptin has been shown previously to activate AMP-activated kinase (AMPK) in skeletal muscle. To enable a detailed analysis of leptin signalling in pancreatic beta cells, LEPR point mutants with single or combined exchanges of the three intracellular tyrosines were expressed in HIT-T15 insulinoma cells. Western blots with activation state-specific antibodies recognizing specific signalling molecules revealed that the wild-type receptor activated STAT1, STAT3, STAT5 and ERK1/2 but failed to alter the phosphorylation of AMPK. Each of the three intracellular tyrosine residues in LEPR exhibited different signalling capacities: Tyr985 was necessary and sufficient for leptin-induced activation of ERK1/2; Tyr1077 induced tyrosyl phosphorylation of STAT5; and Tyr1138 was capable of activating STAT1, STAT3 and STAT5. Consistent results were obtained in reporter gene assays with STAT3 or STAT5-responsive promoter constructs, respectively. Furthermore, the sequence motifs surrounding the three tyrosine residues are conserved in LEPR from mammals, birds and in a LEPR-like cytokine receptor from pufferfish. Mutational analysis of the box3 motif around Tyr1138 identified Met1139 and Gln1141 as important determinants that define specificity towards the different STAT factors. These data indicate that all three conserved tyrosines are involved in LEPR function and define the pleiotropy of signal transduction via STAT1/3, STAT5 or ERK kinases. Activation and inhibition of AMPK appears to require additional components of the signalling pathways that are not present in beta cells.

The ins and outs of leptin receptor activation.

The adipocyte-derived hormone leptin signals the status of body energy stores by activating its receptor in hypothalamic nuclei. In contrast to the initial expectations, leptin treatment of human obesity was largely unsuccessful. One explanation for this is the marked leptin resistance, which likely operates in part at the receptor level. The leptin receptor is a member of the class I cytokine receptor family, which uses the Janus kinase/signal transducer and activator of transcription pathway as a major signaling route. In this review, we focus on the molecular mechanisms underlying leptin receptor activation. Different modes of leptin-induced clustering of the ectodomains and the subsequent signaling events will be discussed.

Comparison of leptin- and interleukin-6-regulated expression of the rPAP gene family: evidence for differential co-regulatory signals.

The pancreatitis-associated protein (PAP)/regenerating protein (REG) family represents a complex group of small secretory proteins, which can function as acute phase reactants, lectins, antiapoptotic factors or growth factors for pancreatic beta-cells and neural cells. Transcriptional induction of rPAP/Reg genes was studied here in PC12 cells made responsive to leptin. Northern-blots showed quantitative differences in induction of four major family members by leptin and IL-6. Surprisingly, induction by leptin was strongly enhanced upon forskolin co-treatment whereas induction by IL-6 was counteracted. Functional studies involving progressive rPAP I promoter deletions showed, in the case of leptin, a clear correlation with predicted cis-regulatory elements. Leptin-induced stimulation was dependent on STAT3, since over-expression of dominant-negative STAT3, but not of dominant-negative STAT1, completely blocked transcriptional activation. In case of IL-6, an enhancer element outside the cloned promoter fragment is required for full stimulation. The effects of forskolin in a leptin and IL-6 context could not be explained at the promoter level, but rather events occurring upstream in the signalling cascade must be postulated to explain the differential co-regulatory effects.

Random mutagenesis MAPPIT analysis identifies binding sites for Vif and Gag in both cytidine deaminase domains of Apobec3G.

The mammalian two-hybrid system MAPPIT allows the detection of protein-protein interactions in intact human cells. We developed a random mutagenesis screening strategy based on MAPPIT to detect mutations that disrupt the interaction of one protein with multiple protein interactors simultaneously. The strategy was used to detect residues of the human cytidine deaminase Apobec3G that are important for its homodimerization and its interaction with the HIV-1 Gag and Vif proteins. The strategy is able to identify the previously described head-to-head homodimerization interface in the N-terminal domain of Apobec3G. Our analysis further detects two new potential interaction surfaces in the N-and C-terminal domain of Apobec3G for interaction with Vif and Gag or for Apobec3G dimerization.

The many faces of the SOCS box.

The suppressors of cytokine signalling (SOCS) box is a structural domain found at the C-terminus of over 70 human proteins. It is usually coupled to a protein interaction module such as an SH2 domain in case of SOCS proteins, a family of modulators of cytokine signaling. The SOCS box participates in the formation of E3 ligase complexes, marking activated cytokine receptor complexes for proteasomal degradation. A similar mechanism was recently uncovered for controlling SOCS activity itself, since SOCS2 was found to enhance the turnover of other SOCS proteins. The SOCS box can also add unique features to individual SOCS proteins: it can function as an adaptor domain as was demonstrated for SOCS3, or as a modulator of substrate binding in case of CIS. In this review we discuss these multiple roles of the SOCS box, which emerges as a versatile module controlling cytokine signaling via multiple mechanisms.

A complex interaction pattern of CIS and SOCS2 with the leptin receptor.

Hypothalamic leptin receptor signalling plays a central role in weight regulation by controlling fat storage and energy expenditure. In addition, leptin also has direct effects on peripheral cell types involved in regulation of diverse body functions including immune response, bone formation and reproduction. Previous studies have demonstrated the important role of SOCS3 (suppressor of cytokine signalling 3) in leptin physiology. Here, we show that CIS (cytokine-inducible SH2 protein) and SOCS2 can also interact with the leptin receptor. Using MAPPIT (mammalian protein-protein interaction trap), a cytokine receptor-based two-hybrid method operating in intact cells, we show specific binding of CIS with the conserved Y985 and Y1077 motifs in the cytosolic domain of the leptin receptor. SOCS2 only interacts with the Y1077 motif, but with higher binding affinity and can interfere with CIS and STAT5a prey recruitment at this site. Furthermore, although SOCS2 does not associate with Y985 of the leptin receptor, we find that SOCS2 can block interaction of CIS with this position. This unexpected interference can be explained by the direct binding of SOCS2 on the CIS SOCS box, whereby elongin B/C recruitment is crucial to suppress CIS activity.

Functional cross-modulation between SOCS proteins can stimulate cytokine signaling.

SOCS (suppressors of cytokine signaling) proteins are negative regulators of cytokine signaling that function primarily at the receptor level. Remarkably, in vitro and in vivo observations revealed both inhibitory and stimulatory effects of SOCS2 on growth hormone signaling, suggesting an additional regulatory level. In this study, we examined the possibility of direct cross-modulation between SOCS proteins and found that SOCS2 could interfere with the inhibitory actions of other SOCS proteins in growth hormone, interferon, and leptin signaling. This SOCS2 effect was SOCS box-dependent, required recruitment of the elongin BC complex, and coincided with degradation of target SOCS proteins. Detailed mammalian protein-protein interaction trap (MAPPIT) analysis indicated that SOCS2 can interact with all members of the SOCS family. SOCS2 may thus function as a molecular bridge between a ubiquitin-protein isopeptide ligase complex and SOCS proteins, targeting them for proteasomal turnover. We furthermore extended these observations to SOCS6 and SOCS7. Our findings point to a unique regulatory role for SOCS2, SOCS6, and SOCS7 within the SOCS family and provide an explanation for the unexpected phenotypes observed in SOCS2 and SOCS6 transgenic mice.