Structure-function analysis of human IL-6. Epitope mapping of neutralizing monoclonal antibodies with amino- and carboxyl-terminal deletion mutants.

To study the active site(s) of IL-6 we combined mutagenesis of IL-6 with epitope mapping of IL-6 specific mAb. In addition to amino-terminal deletion mutants we described previously, carboxyl-terminal deletion mutants were prepared. Functional analysis showed that deletion of only five carboxyl-terminal amino acids already reduced the bioactivity 1000-fold. A panel of mAb to IL-6 was subsequently analyzed by antibody competition experiments and binding to the amino- and carboxyl-terminal deletion mutants. On the basis of the competition experiments the six neutralizing mAb were divided in two groups (I and II). The binding pattern with the deletion mutants suggested that the region recognized by the four mAb in group I is composed of residues of amino- and carboxyl-terminus: binding of two mAb was abolished after deletion of amino acid Ala I-Ile26, of the third mAb after deletion of the four carboxyl-terminal amino acids whereas the fourth mAb did not bind to either mutant. Group II mAb retained binding to these mutants. Taken together these data suggest that in the native IL-6 molecule amino acid residues of amino and carboxyl terminus are in close proximity and that together they constitute an active site. Furthermore our data suggest that the part of the molecule recognized by group II antibodies is a second site involved in biologic activity.     

Dissecting the domain structure of the regulatory subunit of cAMP-dependent protein kinase I and elucidating the role of MgATP

A truncated regulatory subunit of cAMP-dependent protein kinase I was constructed which contained deletions at both the carboxyl terminus and at the amino terminus. The entire carboxyl-terminal cAMP-binding domain was deleted as well as the first 92 residues up to the hinge region. This monomeric truncated protein still forms a complex with the catalytic subunit, and activation of this complex is mediated by cAMP. The affinity of this mutant holoenzyme for cAMP and its activation by cAMP are nearly identical to holoenzyme formed with a regulatory subunit having only the carboxyl-terminal deletion and very similar to native holoenzyme. The off rate for cAMP from both mutant regulatory subunits, however, is monophasic and very fast relative to the biphasic off rate seen for the native regulatory subunit. The effects of NaCl, urea, and pH on cAMP binding are also very similar for the mutant and native holoenzymes. Like the native type I holoenzyme, both mutant holoenzymes bind ATP with a high affinity. The positive cooperativity seen for MgATP binding to the native holoenzyme, however, is abolished in the double deletion mutant. The Hill coefficient for ATP binding to this mutant holoenzyme is 1.0 in contrast to 1.6 for the native holoenzyme. The Kd (cAMP) is increased by approximately 1 order of magnitude for both mutant forms of the holoenzyme in the presence of MgATP. A similar shift is seen for the native holoenzyme. Further characterization of the MgATP-binding properties of the wild-type holoenzyme indicates that a binary complex containing catalytic subunit and MgATP is required, in particular, for reassociation with the cAMP-bound regulatory subunit. This binary complex is required for rapid dissociation of the bound cAMP and is probably responsible for the observed reduction in cAMP-binding affinity for the type I holoenzyme in the presence of MgATP.     

AMSH regulates calcium-sensing receptor signaling through direct interactions

Calcium-sensing receptor (CaR) activates intracellular pathways controlling calcium homeostasis. CaR carboxyl-terminal mutants associated with metabolic diseases suggest that unidentified proteins interact with the carboxyl-terminal region of this receptor. To address this possibility, we screened for CaR-interacting proteins using the carboxyl terminus of CaR (CaRDelta895-1075 deletion mutant). We identified AMSH, an ubiquitin isopeptidase, as a CaR-interacting partner. AMSH caused a decrease on the signaling properties of wild-type and mutant CaR. Our results indicate that AMSH, which has been recently characterized as a regulator of the endosomal sorting of epidermal growth factor receptor, represents a novel modulator of CaR signaling.     

Site-directed deletion mutants of a carboxyl-terminal region of human dihydrofolate reductase.

Substrate and inhibitor binding to dihydrofolate reductase (DHFR) primarily involves residues in the amino-terminal half of the enzyme; however, antibody binding studies performed in this laboratory suggested that the loop region located in the carboxyl terminus of human DHFR (hDHFR; residues 140-186) is involved in conformational changes that occur upon ligand binding and affect enzyme function (Ratnam, M., Tan, X., Prendergast, N.J., Smith, P.L. & Freisheim, J.H. (1988) Biochemistry 27, 4800-4804). To investigate this observation further, site-directed mutagenesis was used to construct deletion mutants of hDHFR missing 1 (del-1), 2 (del-2), 4 (del-4), and 6 (del-6) residues from loops in the carboxyl terminus of the enzyme. The del-1 mutant enzyme has a two-amino acid substitution in addition to the one-amino acid deletion. Deletion of only one amino acid resulted in a 35% decrease in the specific activity of the enzyme. The del-6 mutant enzyme was inactive. Surprisingly, the del-4 mutant enzyme retained a specific activity almost 33% that of the wild type. The specific activity of the del-2 mutant enzyme was slightly higher (38% wild-type activity) than that of the del-4 mutant. All three active deletion mutants were much less stable than the wild-type enzyme, and all three showed at least a 10-fold increase in Km values for both substrates. The del-1 and del-2 mutants exhibited a similar increase in KD values for both substrate and cofactor. The three active deletion mutants lost activity at concentrations of activating agents such as KCl, urea, and p-hydroxymercuribenzoate that continued to stimulate the wild-type enzyme. Antibody binding studies revealed conformational differences between the wild-type and mutant enzymes both in the absence and presence of bound folate. Thus, although the loops near the carboxyl terminus are far removed from the active site, small deletions of this region significantly affect DHFR function, indicating that the loop structure in mammalian DHFR plays an important functional role in its conformation and catalysis.     

Deletion of the carboxyl terminal of thioredoxin reductase C of <Emphasis Type="Italic">Arabidopsis</Emphasis> facilitates oligomerization

The hydrophobicity of NADPH-thioredoxin reductase C (AtNTRC) of Arabidopsis was determined at the carboxyl terminal based on a Kyte-Dolittle hydropathy plot. A carboxyl-terminal deletion mutant of AtNTRC was made in this study to determine whether such deletion could affect the structure and function of AtNTRC. The mutant protein with 14 amino acids deleted at the carboxyl terminus (designated as AtNTRCΔC14) was purified. It was found that AtNTRCΔC14 protein had higher hydrophobicity compared to AtNTRC. Such increase in hydrophobicity of AtNTRCΔC14 affected its native structure and functions. In addition, AtNTRCΔC14 had higher number of high oligomeric complexes compared to AtNTRC based on native-gel electrophoresis and size exclusion chromatography. Although the chaperone activity of AtNTRCΔC14 was enhanced, its NADPH-dependent reductase activity was lower compared to AtNTRC. Therefore, the hydrophobicity of the thioredoxin domain of AtNTRC is important for forming high molecular weight complexes and for maintaining functional balance between chaperone activity and thioredoxin reductase activity.     

Mutation of the two carboxyl-terminal tyrosines results in an insulin receptor with normal metabolic signaling but enhanced mitogenic signaling properties

Our previous studies have shown that the deletion of the insulin receptor carboxyl terminus impairs metabolic, but augments mitogenic, signaling (McClain, D. A., Maegawa, H., Levy, J., Huecksteadt, T., Dull, T. J., Lee, J., Ullrich, A., and Olefsky, J. M. (1988) J. Biol. Chem. 263, 8904-8911; Thies, R.S., Ulrich, A., and McClain, D. A. (1989) J. Biol. Chem. 264, 12820-12825). To explore further the regulatory role of the insulin receptor carboxyl terminus, a mutant insulin receptor was constructed in which the two tyrosines (Y1316 and Y1322) on the carboxyl terminus were replaced with phenylalanines. Rat 1 fibroblasts expressing high levels of this mutant receptor (Y/F2 cells) exhibited normal insulin binding and normal insulin internalization. The absence of the two tyrosines in the carboxyl terminus did not affect the phosphotransferase activity of the beta-subunit and insulin-stimulated glucose transport. However, the Y/F2 cells showed markedly enhanced sensitivity for insulin-stimulated DNA synthesis. Dose-response curves for both insulin-stimulated thymidine uptake and 5-bromo-2-deoxyuridine incorporation in the Y/F2 cell lines were shifted to the left (4-10-fold) compared with those observed in the cells expressing similar numbers of wild type receptors. Thus, the two tyrosines of the insulin receptor carboxyl terminus do not modulate the kinase function of the insulin receptor, although they are autophosphorylated in native receptors. Moreover, these tyrosines are not necessary for stimulation of glucose transport. On the other hand, these results suggest that the two carboxyl-terminal tyrosine residues exert an inhibitory effect on mitogenic signaling in native insulin receptors.     

Motion of carboxyl terminus of Galpha is restricted upon G protein activation. A solution NMR study using semisynthetic Galpha subunits

The carboxyl terminus of the G protein alpha subunit plays a key role in interactions with G protein-coupled receptors. Previous studies that have incorporated covalently attached probes have demonstrated that the carboxyl terminus undergoes conformational changes upon G protein activation. To examine the conformational changes that occur at the carboxyl terminus of Galpha subunits upon G protein activation in a more native system, we generated a semisynthetic Galpha subunit, site-specifically labeled in its carboxyl terminus with 13C amino acids. Using expressed protein ligation, 9-mer peptides were ligated to recombinant Galpha(i1) subunits lacking the corresponding carboxyl-terminal residues. In a receptor-G protein reconstitution assay, the truncated Galpha(i1) subunit could not be activated by receptor; whereas the semisynthetic protein demonstrated functionality that was comparable with recombinant Galpha(i1). To study the conformation of the carboxyl terminus of the semisynthetic G protein, we applied high resolution solution NMR to Galpha subunits containing 13C labels at the corresponding sites in Galpha(i1): Leu-348 (uniform), Gly-352 (alpha carbon), and Phe-354 (ring). In the GDP-bound state, the spectra of the ligated carboxyl terminus appeared similar to the spectra obtained for 13C-labeled free peptide. Upon titration with increasing concentrations of AlF4-, the 13C resonances demonstrated a marked loss of signal intensity in the semisynthetic Galpha subunit but not in free peptide subjected to the same conditions. Because AlF4- complexes with GDP to stabilize an activated state of the Galpha subunit, these results suggest that the Galpha carboxyl terminus is highly mobile in its GDP-bound state but adopts an ordered conformation upon activation by AlF4-.     

Role of the amino latch of staphylococcal alpha-hemolysin in pore formation: a co-operative interaction between the N terminus and position 217

Staphylococcal alpha-hemolysin (alphaHL) is a beta barrel pore-forming toxin that is secreted by the bacterium as a water-soluble monomeric protein. Upon binding to susceptible cells, alphaHL assembles via an inactive prepore to form a water-filled homoheptameric transmembrane pore. The N terminus of alphaHL, which in the crystal structure of the fully assembled pore forms a latch between adjacent subunits, has been thought to play a vital role in the prepore to pore conversion. For example, the deletion of two N-terminal residues produced a completely inactive protein that was arrested in assembly at the prepore stage. In the present study, we have re-examined assembly with a comprehensive set of truncation mutants. Surprisingly, we found that after truncation of up to 17 amino acids, the ability of alphaHL to form functional pores was diminished, but still substantial. We then discovered that the mutation Ser(217) --> Asn, which was present in our original set of truncations but not in the new ones, promotes complete inactivation upon truncation of the N terminus. Therefore, the N terminus of alphaHL cannot be critical for the prepore to pore transformation as previously thought. Residue 217 is involved in the assembly process and must interact indirectly with the distant N terminus during the last step in pore formation. In addition, we provide evidence that an intact N terminus prevents the premature oligomerization of alphaHL monomers in solution.     

The role of the carboxyl terminus in ClC chloride channel function

The human muscle chloride channel ClC-1 has a 398-amino acid carboxyl-terminal domain that resides in the cytoplasm and contains two CBS (cystathionine-beta-synthase) domains. To examine the role of this region, we studied various carboxyl-terminal truncations by heterologous expression in mammalian cells, whole-cell patch clamp recording, and confocal imaging. Channel constructs lacking parts of the distal CBS domain, CBS2, did not produce functional channels, whereas deletion of CBS1 was tolerated. ClC channels are dimeric proteins with two ion conduction pathways (protopores). In heterodimeric channels consisting of one wild type subunit and one subunit in which the carboxyl terminus was completely deleted, only the wild type protopore was functional, indicating that the carboxyl terminus supports the function of the protopore. All carboxyl-terminal-truncated mutant channels fused to yellow fluorescent protein were translated and the majority inserted into the plasma membrane as revealed by confocal microscopy. Fusion proteins of cyan fluorescent protein linked to various fragments of the carboxyl terminus formed soluble proteins that could be redistributed to the surface membrane through binding to certain truncated channel subunits. Stable binding only occurs between carboxyl-terminal fragments of a single subunit, not between carboxyl termini of different subunits and not between carboxyl-terminal and transmembrane domains. However, an interaction with transmembrane domains can modify the binding properties of particular carboxyl-terminal proteins. Our results demonstrate that the carboxyl terminus of ClC-1 is not necessary for intracellular trafficking but is critical for channel function. Carboxyl termini fold independently and modify individual protopores of the double-barreled channel.     

Ras complements the carboxyl terminus of v-Abl protein in lymphoid transformation.

Abelson murine leukemia virus (Ab-MLV) mutants expressing v-Abl proteins lacking the carboxyl terminus are compromised in the ability to transform lymphoid but not NIH 3T3 cells. This feature correlates with the presence of low levels of phosphotyrosine in lymphoid cells infected with carboxyl-terminal truncation mutants. In contrast, high levels of phosphotyrosine are observed in NIH 3T3 cells infected with wild-type and mutant Ab-MLV. Two downstream targets affected in lymphoid transformants are the GTPase-activating protein and GTPase-activating protein-associated protein p62, molecules which are heavily tyrosine phosphorylated in lymphoid cells transformed by wild-type Ab-MLV but not carboxyl-terminal truncation mutants of Ab-MLV. This difference suggested that signaling mediated via the Ras pathway may be compromised in lymphoid cells expressing the carboxyl-terminal truncation mutants. Consistent with this idea, expression of v-Ha-ras complemented these mutants in primary bone marrow transformation assays and increased transformation frequencies obtained with the Ab-MLV mutants 8- to 20-fold. These data suggest that a biologically important link exists between the carboxyl terminus of v-Abl protein and the Ras pathway. Signals transmitted via this connection may enhance those mediated via other regions of the v-Abl protein and facilitate transformation of primary, nonimmortalized cells such as pre-B lymphocytes.     

Critical and distinct roles of amino- and carboxyl-terminal sequences in regulation of the biological activity of the Chp atypical Rho GTPase

Chp (Cdc42 homologous protein) shares significant sequence and functional identity with the human Cdc42 small GTPase, and like Cdc42, promotes formation of filopodia and activates the p21-activated kinase serine/threonine kinase. However, unlike Cdc42, Chp contains unique amino- and carboxyl-terminal extensions. Here we determined whether Chp, like Cdc42, can promote growth transformation and evaluated the role of the amino- and carboxyl-terminal sequences in Chp function. Surprisingly, we found that a GTPase-deficient mutant of Chp exhibited low transforming activity but that deletion of the amino terminus of Chp greatly enhanced its transforming activity. Thus, the amino terminus may serve as a negative regulator of Chp function. The carboxyl terminus of Cdc42 contains a CAAX (where C is cysteine, A is aliphatic amino acid, X is terminal amino acid) tetrapeptide sequence that signals for the posttranslational modification critical for Cdc42 membrane association and biological function. Although Chp lacks aCAAXmotif, we found that Chp showed carboxyl terminus-dependent localization to the plasma membrane and to endosomes. Furthermore, an intact carboxyl terminus was required for Chp transforming activity. However, treatment with inhibitors of protein palmitoylation, but not prenylation, caused Chp to mislocalize to the cytoplasm. Thus, Chp depends on palmitoylation, rather than isoprenylation, for membrane association and function. In summary, Chp is implicated in cell transformation, and the unique amino and carboxyl termini of Chp represent atypical mechanisms of regulation of Rho GTPase function.     

Disulfide bond assignment and identification of regions required for functional activity of oncostatin M

Oncostatin M is a polypeptide cytokine having unique structure and diverse biological activities, including the ability to inhibit growth of certain cultured tumor cells. Here we have determined the disulfide bonding pattern of recombinant oncostatin M and have used site-directed mutagenesis to identify regions of this molecule necessary for receptor binding and growth inhibitory activities. Two intramolecular disulfide bonds, C6-C127 and C49-C167, were identified in recombinant oncostatin M. Analysis of mutations at each of the five cysteines in oncostatin M indicated that mutants C49S and C167S were inactive (less than 1/10 wild type activity) in growth inhibitory assays and radioreceptor assays. Carboxyl-terminal deletion mutations terminating at S185 and beyond were active, but further shortening abolished activity in both assays. Two deletion mutants proximal to C49 (delta 22-36 and delta 44-47) and insertion mutant GAG77 also were inactive. One deletion mutant, delta 87-90, had significantly (approximately 3-fold) increased activities in both growth inhibitory assays and radioreceptor assays. A potential amphiphilic domain was identified beginning at C167 and extending toward the carboxyl terminus. Two mutants having altered hydrophobic residues within this domain (F176G and F184G) were inactive, suggesting that these residues are required for proper conformation of the receptor binding site. Taken together, these results indicate that biological activity of oncostatin M requires discontinuous regions of the molecule, including residues near the essential disulfide bond, C49-C167, and within a putative amphiphilic helix at the carboxyl terminus. Oncostatin M thus belongs to a growing family of cytokines whose interactions with their respective receptors are mediated in part by known or predicted carboxyl-terminal amphiphilic helices.     

The carboxyl-terminal region of the geranylgeranyl diphosphate synthase is indispensable for the stabilization of the region involved in substrate binding and catalysis

Rat geranylgeranyl diphosphate synthase (GGPS) and its deletion mutants from the carboxyl terminus were analysed using Escherichia coli harbouring pACYC-crtIB, which contains crtI and crtB encoding the carotenoid biosynthetic enzymes. Mutants (delta-4, -8, -12 and -16) produced lycopene-derived red colour, but mutants (delta-17, -18, -19, -20, -23, -57 and -70) did not. The histidine-tagged mutants (delta-4, -8, -12 and -16) were overexpressed in E. coli BL21 (DE3) and purified in a stable form by nickel affinity chromatography except for one mutant (delta-16). The farnesyl-transferring activities of wild-type GGPS, delta-4, -8 and -12 mutants were relatively in a ratio of 1.0, 0.84, 0.26 and 0.0015. Each Km value of the four recombinants were estimated to be 0.71, 2.0 2.8 and 55 microM for farnesyl diphosphate and to be 2.9, 5.1, 56 and >100 microM for isopentenyl diphosphate, respectively. Allylic substrate specificities of these recombinants were estimated by quantitative analysis of the products, revealing that delta-8 and -12 mutants lack the ability to accept dimethylallyl and geranyl diphosphates compared to wild-type GGPS and delta-4 mutant. These results suggest that the KMFTEENE residing on the carboxyl-terminal sequence of GGPS stabilizes the active region involved in the substrate binding and catalysis.     

Role of the carboxyl-terminal region of arrestin in binding to phosphorylated rhodopsin.

The structural and functional properties of arrestin were studied by subjecting the protein to limited proteolysis. Limited proteolysis by trypsin cleaves arrestin (48 kDa), producing 20-25-kDa fragments. Prior to this stage of proteolysis, trypsin produced 46.6-, 45.4-, and 42-kDa fragments. Structural analysis of the proteolytic fragments demonstrated major cleavage at the carboxyl terminus, indicating that the carboxyl terminus is highly exposed. We found that forms of arrestin truncated at their carboxyl terminus maintained their functional properties and bound to phosphorylated rhodopsin. Native arrestin binds only to photoexcited phosphorylated rhodopsin, whereas the truncated arrestin binds to phosphorylated rhodopsin independent of its exposure to light. The truncated forms of arrestin were separated from native arrestin by a chromatographic procedure and subsequently characterized in functional studies. The binding of the truncated forms of arrestin to phosphorylated photoexcited rhodopsin is more tight than the binding of native arrestin as determined by a direct binding assay and the phosphodiesterase assay. We suggest that the acidic carboxyl-terminal region of arrestin may act as a regulator for light-dependent binding to phosphorylated rhodopsin.     

A novel folding intermediate state for apolipoprotein A-I: role of the amino and carboxy termini

Intramolecular interactions between the amino and carboxy termini of apolipoprotein A-I (apoAI) are believed to stabilize the helix bundle conformation of the protein. During lipid assembly the protein undergoes conformational changes that result in an exposure of the carboxy terminus and its insertion into the lipid phase. To determine the role of the two termini in the energetics of unfolding, we studied the guanidine-hydrochloride-induced unfolding and refolding of apoAI as well as its N-terminal deletion (del[1-43]), C-terminal deletion (del[186-243]), and the double deletion containing only the central residues 44-185. Thermodynamic analysis of the equilibrium unfolding measured by fluorescence spectroscopy revealed the presence of an intermediate unfolded state (I(equil)) in addition to the native (N) and unfolded states. Refolding kinetics of apoAI, measured by stopped-flow circular dichroism, revealed two kinetic intermediates, I(burst) and I(recovery). Computer modeling suggested that the first resembles the partially unfolded protein, whereas the second overlaps with the native state of the protein. The free energy changes for the N --> I(equil) transition of the N-terminal and double deletions were lower then that of the full-length form, whereas that for the C-terminal deletion was higher. Our findings suggest that the N-terminus of apoAI stabilizes the native state of the protein by increasing the Eyring energy barrier for the N --> I(equil) unfolding transition; whereas the carboxyl terminus destabilizes that state.     

Activation of wild type p53 function by its mortalin-binding, cytoplasmically localizing carboxyl terminus peptides

The Hsp70 family member mortalin (mot-2/mthsp70/GRP75) binds to a carboxyl terminus region of the tumor suppressor protein p53. By in vivo co-immunoprecipitation of mot-2 with p53 and its deletion mutants, we earlier mapped the mot-2-binding site of p53 to its carboxyl terminus 312-352 amino acid residues. In the present study we attempted to disrupt mot-2-p53 interactions by overexpression of short p53 carboxyl-terminal peptides. We report that p53 carboxyl-terminal peptides (amino acid residues 312-390, 312-352, 323-390, and 323-352) localize in the cytoplasm, whereas 312-322, 337-390, 337-352, and 352-390 locate mostly in the nucleus. Most interestingly, the cytoplasmically localizing p53 peptides harboring the residues 323-337 activated the endogenous p53 function by displacing it from p53-mortalin complexes and relocating it to the nucleus. Such activation of p53 function was sufficient to cause growth arrest of human osteosarcoma and breast carcinoma cells.     

A Two-step Mechanism for the Folding of Actin by the Yeast Cytosolic Chaperonin

Actin requires the chaperonin containing TCP1 (CCT), a hexadecameric ATPase essential for cell viability in eukaryotes, to fold to its native state. Following binding of unfolded actin to CCT, the cavity of the chaperone closes and actin is folded and released in an ATP-dependent folding cycle. In yeast, CCT forms a ternary complex with the phosducin-like protein PLP2p to fold actin, and together they can return nascent or chemically denatured actin to its native state in a pure in vitro folding assay. The complexity of the CCT-actin system makes the study of the actin folding mechanism technically challenging. We have established a novel spectroscopic assay through selectively labeling the C terminus of yeast actin with acrylodan and observe significant changes in the acrylodan fluorescence emission spectrum as actin is chemically unfolded and then refolded by the chaperonin. The variation in the polarity of the environment surrounding the fluorescent probe during the unfolding/folding processes has allowed us to monitor actin as it folds on CCT. The rate of actin folding at a range of temperatures and ATP concentrations has been determined for both wild type CCT and a mutant CCT, CCT4anc2, defective in folding actin in vivo. Binding of the non-hydrolysable ATP analog adenosine 5′-(β,γ-imino)triphosphate to the ternary complex leads to 3-fold faster release of actin from CCT following addition of ATP, suggesting a two-step folding process with a conformational change occurring upon closure of the cavity and a subsequent final folding step involving packing of the C terminus to the native-like state.     

Immunological approaches to the transmembrane topology and conformational changes of the carboxyl-terminal regulatory domain of yeast plasma membrane H(+)-ATPase.

Molecular genetic experiments have suggested that the carboxyl terminus of the Saccharomyces cerevisiae plasma membrane H(+)-ATPase is an inhibitory domain involved in the "in vivo" regulation of the enzyme by glucose metabolism. An antibody prepared against a fusion protein including the last 59 amino acids of the ATPase sequence has been affinity purified to yield a preparation which requires the 18 carboxyl-terminal amino acids for recognition. Antibody binding experiments show that the carboxyl-terminal domain of the ATPase can be selectively exposed by concentrations of the detergent Tween-20 which do not break down the permeability barrier of the plasma membrane to the antibody. Both enzyme-linked immunosorbent assay and immunofluorescence analysis demonstrate that the accessibility of the carboxyl-terminal domain in isolated plasma membranes depends on the physiological state of the cell being increased by glucose metabolism. Immunofluorescence analysis of isolated plasma membrane vesicles, using a dual labeling protocol with concanavalin A and antibody to reveal the orientation of individual vesicles, and colloidal gold immunoelectron microscopy of ultrathin cryosections of whole yeast cells separately demonstrate that the ATPase carboxyl terminus is located in the cytoplasmic compartment. The application of a mutant deleted of the epitope(s) recognized by the affinity purified carboxyl-terminal antibody eliminates the possibility of artifacts arising from nonspecific antibody binding. The accessibility properties and cytoplasmic location of the carboxyl-terminal domain appear to be consistent with its role as a negative regulator of the ATPase.     

Stimulation of p53 DNA binding by c-Abl requires the p53 C terminus and tetramerization

The carboxyl terminus of p53 is a target of a variety of signals for regulation of p53 DNA binding. Growth suppressor c-Abl interacts with p53 in response to DNA damage and overexpression of c-Abl leads to G(1) growth arrest in a p53-dependent manner. Here, we show that c-Abl binds directly to the carboxyl-terminal regulatory domain of p53 and that this interaction requires tetramerization of p53. Importantly, we demonstrate that c-Abl stimulates the DNA-binding activity of wild-type p53 but not of a carboxyl-terminally truncated p53 (p53Delta363C). A deletion mutant of c-Abl that does not bind to p53 is also incapable of activating p53 DNA binding. These data suggest that the binding to the p53 carboxyl terminus is necessary for c-Abl stimulation. To investigate the mechanism for this activation, we have also shown that c-Abl stabilizes the p53-DNA complex. These results led us to hypothesize that the interaction of c-Abl with the C terminus of p53 may stabilize the p53 tetrameric conformation, resulting in a more stable p53-DNA complex. Interestingly, the stimulation of p53 DNA-binding by c-Abl does not require its tyrosine kinase activity, indicating a kinase-independent function for c-Abl. Together, these results suggest a detailed mechanism by which c-Abl activates p53 DNA-binding via the carboxyl-terminal regulatory domain and tetramerization.     

Phosphorylation of the avian retrovirus integration protein and proteolytic processing of its carboxyl terminus.

The integration protein (IN) of the Prague A strain of Rous sarcoma virus (RSV) was analyzed by high-resolution sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three polypeptides of similar proportions and molecular mass (32 kDa) were immunoprecipitated by an antiserum directed against the first 10 amino acids of the amino terminus of IN. However, the faster-migrating nonphosphorylated polypeptide was not immunoprecipitated by two different polyclonal antisera directed against the last 11 amino acids of the carboxyl terminus of IN. These results suggest that the faster-migrating species was proteolytically processed at its carboxyl terminus. RSV IN is phosphorylated on an S residue located five amino acids from its carboxyl terminus. Two different missense mutations at this S residue resulted in the isolation of slow-growing viable mutants whose phenotypes were stable. Each mutation at residue 282 eliminated both major phosphorylated-Ser-containing tryptic peptides observed with wild-type IN. An S----F mutation resulted in the conversion of all IN polypeptides to one species that was not precipitable by carboxyl-terminal antisera, suggesting that this amino acid transition promoted proteolysis at the carboxyl terminus. An S----D mutation resulted in the recovery of one major (greater than 95%) slower-migrating polypeptide that was immunoprecipitated by carboxyl-terminal antisera, suggesting that this negatively charged D residue (similar to phosphorylated Ser) inhibited proteolysis. Modification of the S residue at amino acid 262 to R had no apparent effect on the proteolytic processing or phosphorylation of IN.