A carboxy-terminal fragment of protein mu 1/mu 1C is present in infectious subvirion particles of mammalian reoviruses and is proposed to have a role in penetration.

Penetration of a cell membrane as an early event in infection of cells by mammalian reoviruses appears to require a particular type of viral particle, the infectious subvirion particle (ISVP), which is generated from an intact virion by proteolytic cleavage of the outer capsid proteins sigma 3 and mu 1/mu 1C. Characterizations of the structural components and properties of ISVPs are thus relevant to attempts to understand the mechanism of penetration by reoviruses. In this study, a novel, approximately 13-kDa carboxy-terminal fragment (given the name phi) was found to be generated from protein mu 1/mu 1C during in vitro treatments of virions with trypsin or chymotrypsin to yield ISVPs. With trypsin treatment, both the carboxy-terminal fragment phi and the amino-terminal fragment mu 1 delta/delta were shown to be generated and to remain attached to ISVPs in stoichiometric quantities. Sites of protease cleavage were identified in the deduced amino acid sequence of mu 1 by determining the amino-terminal sequences of phi proteins: trypsin cleaves between arginine 584 and isoleucine 585, and chymotrypsin cleaves between tyrosine 581 and glycine 582. Findings in this study indicate that sequences in the phi portion of mu 1/mu 1C may participate in the unique functions attributed to ISVPs. Notably, the delta-phi cleavage junction was predicted to be flanked by a pair of long amphipathic alpha-helices. These amphipathic alpha-helices, together with the myristoyl group at the extreme amino terminus of mu 1/mu 1N, are proposed to interact directly with the lipid bilayer of a cell membrane during penetration by mammalian reoviruses.     

Structure,topology, and dynamics of myristoylated recoverin bound to phospholipid bilayers

Recoverin, a member of the EF-hand protein superfamily, serves as a calcium sensor in retinal rod cells. A myristoyl group covalently attached to the N-terminus of recoverin facilitates its binding to retinal disk membranes by a mechanism known as the Ca(2+)-myristoyl switch. Samples of (15)N-labeled Ca(2+)-bound myristoylated recoverin bind anisotropically to phospholipid membranes as judged by analysis of (15)N and (31)P chemical shifts observed in solid-state NMR spectra. On the basis of a (2)H NMR order parameter analysis performed on recoverin containing a fully deuterated myristoyl group, the N-terminal myristoyl group appears to be located within the lipid bilayer. Two-dimensional solid-state NMR ((1)H-(15)N PISEMA) spectra of uniformly and selectively (15)N-labeled recoverin show that the Ca(2+)-bound protein is positioned on the membrane surface such that its long molecular axis is oriented approximately 45 degrees with respect to the membrane normal. The N-terminal region of recoverin points toward the membrane surface, with close contacts formed by basic residues K5, K11, K22, K37, R43, and K84. This orientation of the membrane-bound protein allows an exposed hydrophobic crevice, near the membrane surface, to serve as a potential binding site for the target protein, rhodopsin kinase. Close agreement between experimental and calculated solid-state NMR spectra of recoverin suggests that membrane-bound recoverin retains the same overall three-dimensional structure that it has in solution. These results demonstrate that membrane binding by recoverin is achieved primarily by insertion of the myristoyl group inside the bilayer with apparently little rearrangement of the protein structure.     

Mammalian reoviruses contain a myristoylated structural protein.

The structural protein mu 1 of mammalian reoviruses was noted to have a potential N-myristoylation sequence at the amino terminus of its deduced amino acid sequence. Virions labeled with [3H]myristic acid were used to demonstrate that mu 1 is modified by an amide-linked myristoyl group. A myristoylated peptide having a relative molecular weight (Mr) of approximately 4,000 was also shown to be a structural component of virions and was concluded to represent the 4.2-kDa amino-terminal fragment of mu 1 which is generated by the same proteolytic cleavage that yields the carboxy-terminal fragment and major outer capsid protein mu 1C. The myristoylated 4,000-Mr peptide was found to be present in reovirus intermediate subviral particles but to be absent from cores, indicating that it is a component of the outer capsid. A distinct large myristoylated fragment of the intact mu 1 protein was also identified in intermediate subviral particles, but no myristoylated mu-region proteins were identified in cores, consistent with the location of mu 1 in the outer capsid. Similarities between amino-terminal regions of the reovirus mu 1 protein and the poliovirus capsid polyprotein were noted. By analogy with other viruses that contain N-myristoylated structural proteins (particularly picornaviruses), we suggest that the myristoyl group attached to mu 1 and its amino-terminal fragments has an essential role in the assembly and structure of the reovirus outer capsid and in the process of reovirus entry into cells.     

Structural insights into membrane targeting by the flagellar calcium-binding protein (FCaBP), a myristoylated and palmitoylated calcium sensor in Trypanosoma cruzi

The flagellar calcium-binding protein (FCaBP) of the protozoan Trypanosoma cruzi is targeted to the flagellar membrane where it regulates flagellar function and assembly. As a first step toward understanding the Ca(2+)-induced conformational changes important for membrane-targeting, we report here the x-ray crystal structure of FCaBP in the Ca(2+)-free state determined at 2.2A resolution. The first 17 residues from the N terminus appear unstructured and solvent-exposed. Residues implicated in membrane targeting (Lys-19, Lys-22, and Lys-25) are flanked by an exposed N-terminal helix (residues 26-37), forming a patch of positive charge on the protein surface that may interact electrostatically with flagellar membrane targets. The four EF-hands in FCaBP each adopt a "closed conformation" similar to that seen in Ca(2+)-free calmodulin. The overall fold of FCaBP is closest to that of grancalcin and other members of the penta EF-hand superfamily. Unlike the dimeric penta EF-hand proteins, FCaBP lacks a fifth EF-hand and is monomeric. The unstructured N-terminal region of FCaBP suggests that its covalently attached myristoyl group at the N terminus may be solvent-exposed, in contrast to the highly sequestered myristoyl group seen in recoverin and GCAP1. NMR analysis demonstrates that the myristoyl group attached to FCaBP is indeed solvent-exposed in both the Ca(2+)-free and Ca(2+)-bound states, and myristoylation has no effect on protein structure and folding stability. We propose that exposed acyl groups at the N terminus may anchor FCaBP to the flagellar membrane and that Ca(2+)-induced conformational changes may control its binding to membrane-bound protein targets.     

Stabilizing function for myristoyl group revealed by the crystal structure of a neuronal calcium sensor, guanylate cyclase-activating protein 1

Guanylate cyclase-activating proteins (GCAPs) are Ca(2+)-binding proteins myristoylated at the N terminus that regulate guanylate cyclases in photoreceptor cells and belong to the family of neuronal calcium sensors (NCS). Many NCS proteins display a recoverin-like "calcium-myristoyl switch" whereby the myristoyl group, buried inside the protein in the Ca(2+)-free state, becomes fully exposed upon Ca(2+) binding. Here we present a 2.0 A resolution crystal structure of myristoylated GCAP1 with Ca(2+) bound. The acyl group is buried inside Ca(2+)-bound GCAP1. This is in sharp contrast to Ca(2+)-bound recoverin, where the myristoyl group is solvent exposed. Furthermore, we provide direct evidence that the acyl group in GCAP1 remains buried in the Ca(2+)-free state and does not undergo switching. A pronounced kink in the C-terminal helix and the presence of the myristoyl group allow clustering of sequence elements crucial for GCAP1 activity.     

The bacteriophage Mu N gene encodes the 64-kDa virion protein which is injected with, and circularizes, infecting Mu DNA

Upon infection of Escherichia coli with bacteriophage Mu, a 64-kDa protein is injected into the host cell along with the phage DNA. This protein is involved in circularizing the infecting Mu DNA (Harshey, R. M., and Bukhari, A. I. (1983) J. Mol. Biol. 167, 427-441; Puspurs, A. H., Trun, N. J., and Reeve, J. N. (1983) EMBO J. 2, 345-352). Its possible role in the integration of infecting Mu DNA and in the infection process remains to be established. To identify the source of this protein we have prepared antiserum to the protein purified from viral particles. We have shown that the antiserum is specific for the Mu N gene product. The antiserum has been used to immunologically screen a Mu DNA library cloned into an expression vector. Four clones have been shown to produce a protein of 64 kDa that is specifically bound by the antiserum. The only Mu gene common to all four clones is the N gene, as demonstrated by physical and genetic mapping. We have also demonstrated by peptide mapping that the cloned N gene product is identical to the 64-kDa protein found complexed with the injected Mu DNA.     

Two mutations of phage mu transposase that affect strand transfer or interactions with B protein lie in distinct polypeptide domains.

Two mutations within the transposase (the A protein) gene of phage Mu with distinct effects on DNA transposition have been studied. The first mutation maps to the central domain (domain II) of A, a protein consisting of three major structural domains. The variant protein is normal in synapsis and cleavage of Mu ends but is temperature-sensitive in the strand transfer reaction, joining the Mu ends to target DNA. The second mutation is a deletion at the C terminus (within domain III); on the basis of genetic studies, the mutant protein is predicted to have lost the ability to interact with the Mu B protein. The B protein, in conjunction with A, promotes efficient intermolecular transposition, while inhibiting intramolecular transposition. We show that the purified mutant protein is proficient in intramolecular, but not intermolecular transposition in vitro. The interactions between A and B proteins have been followed by a proteolysis assay. The chymotrypsin sensitivity of the interdomainal Phe221-Ser222 peptide bond within the bidomainally organized B protein is exquisitely modulated by ATP, DNA and A protein. The sensitive or "open" state of this bond in native B protein becomes partially "open" upon binding of ATP by B, attains a "closed" or resistant configuration upon binding of DNA in presence of ATP, and is rendered "open" again upon addition of the A protein. In this test for the interaction of A protein with B protein-DNA complex, the domain II mutant behaves like wild-type A protein. However, the domain III mutant fails to restore chymotrypsin susceptibility of the Phe221-Ser222 bond.     

Reovirus mu1 structural rearrangements that mediate membrane penetration

Membrane penetration by nonenveloped reoviruses is mediated by the outer-capsid protein, mu1 (76 kDa). Previous evidence has suggested that an autolytic cleavage in mu1 allows the release of its N-terminally myristoylated peptide, mu1N (4 kDa), which probably then interacts with the target-cell membrane. A substantial rearrangement of the remaining portion of mu1, mu1C (72 kDa), must also have occurred for mu1N to be released, and some regions in mu1C may make additional contacts with the membrane. We describe here a particle-free system to study conformational rearrangements of mu1. We show that removal of the protector protein sigma3 is not sufficient to trigger rearrangement of free mu1 trimer and that free mu1 trimer undergoes conformational changes similar to those of particle-associated mu1 when induced by similar conditions. The mu1 rearrangements require separation of the mu1 trimer head domains but not the mu1N/C autocleavage. We have also obtained a relatively homogeneous form of the structurally rearranged mu1 (mu1*) in solution. It is an elongated monomer and retains substantial alpha-helix content. We have identified a protease-resistant approximately 23-kDa fragment of mu1*, which contains the largely alpha-helical regions designated domains I and II in the conformation of mu1 prior to rearrangement. We propose that the mu1 conformational changes preceding membrane penetration or disruption during cell entry involve (i) separation of the beta-barrel head domains in the mu1 trimer, (ii) autolytic cleavage at the mu1N/C junction, associated with partial unfolding of mu1C and release of mu1N, and (iii) refolding of the N-terminal helical domains of mu1C, with which mu1N was previously complexed, accompanied by dissociation of the mu1 trimer.     

Production and secretion in CHO cells of the extracellular domain of AMOGβ2, a type-II membrane protein

A hybrid gene consisting of the sequences coding for the signal peptide and N terminus of a type-I membrane protein, the neural cell adhesion molecule (N-CAM), and the extracellular domain of the adhesion molecule on glia (AMOG/β2), a type-II membrane protein, was constructed. The sequence was inserted into a eukaryotic expression vector containing the human cytomegalovirus promoter and the glutamine synthetase selection marker, and used to transfect Chinese hamster ovary cells. The resulting stably transformed cell lines produced large amounts of soluble recombinant AMOG/β2 (reAMOG/β2), which was secreted into the culture medium as a heavily glycosylated 40-55-kDa protein. N-terminal sequence analysis revealed that the protein is not cleaved at the natural signal peptide cleavage site of N-CAM, but two amino acids (aa) further downstream. Treatment of reAMOG/β2 with N-glycosidase F (GlycoF) reduced the molecular mass to 27 kDa, corresponding to the calculated mass of the unglycosylated form. In contrast to AMOG/β2 isolated from mouse brain, which is sensitive to endoglycosidase H, the immuno affinity-purified re-protein is more resistant to this treatment, indicating that the sugars attached to reAMOG/β2 are mainly of the complex type. Our results demonstrate the feasibility of secreting the extracellular domain of a type-II membrane protein, which is usually inserted into the membrane with the C terminus facing the extracellular side.     

Putative autocleavage of reovirus mu1 protein in concert with outer-capsid disassembly and activation for membrane permeabilization

Capsid proteins of several different families of non-enveloped animal viruses with single-stranded RNA genomes undergo autocatalytic cleavage (autocleavage) as a maturation step in assembly. Similarly, the 76 kDa major outer-capsid protein mu1 of mammalian orthoreoviruses (reoviruses), which are non-enveloped and have double-stranded RNA genomes, undergoes putative autocleavage between residues 42 and 43, yielding N-terminal N-myristoylated fragment mu1N and C-terminal fragment mu1C. Cleavage at this site allows release of mu1N, which is thought to be critical for penetration of the host-cell membrane during cell entry. Most previous studies have suggested that cleavage at the mu1N/mu1C junction precedes addition to the outer capsid during virion assembly, such that only a small number of the mu1 subunits in mature virions remain uncleaved at that site (approximately 5%). In this study, we varied the conditions for disruption of virions before running the proteins on denaturing gels and in several circumstances recovered much higher levels of uncleaved mu1 (up to approximately 60%). Elements of the disruption conditions that allowed greater recovery of uncleaved protein were increased pH, absence of reducing agent, and decreased temperature. These same elements allowed comparably higher levels of the mu1delta protein, in which cleavage at the mu1N/delta junction has not occurred, to be recovered from particle uncoating intermediates in which mu1 had been previously cleaved by chymotrypsin in a distinct protease-sensitive region near residue 580. The capacity to recover higher levels of mu1delta following disruption of these particles for electrophoresis was lost, however, in concert with a series of structural changes that activate the particles for membrane permeabilization, suggesting that the putative autocleavage is itself one of these changes.     

Stimulation of the Mu DNA strand cleavage and intramolecular strand transfer reactions by the Mu B protein is independent of stable binding of the Mu B protein to DNA.

Interactions between the Mu A and Mu B proteins are important in the early steps of the in vitro transposition of a mini-Mu plasmid. We have examined these interactions by assaying Mu B stimulation of Mu A-mediated strand cleavage and strand transfer reactions. We have previously shown that in the presence of ATP the Mu B protein can stimulate the Mu A-directed cleavage reaction of mini-Mu plasmids carrying a terminal base pair mutation (Surette, M.G., Harkness, T., and Chaconas, G. (1991) J. Biol. Chem. 266, 3118-3124). Here we demonstrate that in the absence of a non-Mu DNA target molecule the Mu B protein stimulates intramolecular integration of a mini-Mu in an ATP-dependent fashion. Furthermore, modification of the Mu B protein with N-ethylmaleimide severely compromises the ability of B to form a stable complex with DNA; however, the modified protein stimulates the strand cleavage and intramolecular strand transfer reactions as efficiently as the untreated protein. These results indicate that the Mu B protein is capable of stimulating the Mu A protein through direct interaction in the absence of stable Mu B-DNA complex formation. Our results increase the spectrum of Mu B protein activities and uncouple the stimulatory properties of the Mu B protein from stable DNA binding but not the ATP cofactor requirement.     

The adenovirus E3 14.5-kilodalton protein, which is required for down-regulation of the epidermal growth factor receptor and prevention of tumor necrosis factor cytolysis, is an integral membrane protein oriented with its C terminus in the cytoplasm.

We previously reported that the adenovirus type 5 E3 14.5-kilodalton protein (14.5K) forms a complex with E3 10.4K and that both proteins are required to down-regulate the epidermal growth factor receptor in adenovirus-infected human cells. Both proteins are also required to prevent cytolysis by tumor necrosis factor of most mouse cell lines infected by adenovirus mutants that lack E3 14.7K. The E3 14.5K amino acid sequence suggests that 14.5K is an integral membrane protein with an N-terminal signal sequence for membrane insertion. Here we show that 14.5K was found exclusively in cytoplasmic membrane fractions. Radiochemical sequencing of 14.5K indicated that the N-terminal signal sequence is cleaved predominantly between Cys-18 and Ser-19. With a mutant that does not express 10.4K, cleavage occurs predominantly between Phe-17 and Cys-18, indicating that the presence or absence of 10.4K affects the signal cleavage site. 14.5K was extracted into the detergent phase with Triton X-114, it remained associated with membranes after extraction with Na2CO3 at pH 11.5, and it was partially protected by membranes from proteinase K digestion; these observations indicate that 14.5K is an integral membrane protein. Proteinase K digestion followed by immunoprecipitation with antipeptide antisera directed against the N or C terminus of mature 14.5K indicated that 14.5K is oriented in the membrane with its N terminus in the lumen and its C terminus in the cytoplasm. Thus, 14.5K is a type I bitopic membrane protein. Previous studies indicated that 10.4K is also an integral membrane protein oriented with its C terminus in the cytoplasm. Altogether, these findings suggest that cytoplasmic membranes are the site of action when 10.4K and 14.5K down-regulate the epidermal growth factor receptor and prevent tumor necrosis factor cytolysis.     

Infectious rotavirus enters cells by direct cell membrane penetration, not by endocytosis.

Rotaviruses are icosahedral viruses with a segmented, double-stranded RNA genome. They are the major cause of severe infantile infectious diarrhea. Rotavirus growth in tissue culture is markedly enhanced by pretreatment of virus with trypsin. Trypsin activation is associated with cleavage of the viral hemagglutinin (viral protein 3 [VP3]; 88 kilodaltons) into two fragments (60 and 28 kilodaltons). The mechanism by which proteolytic cleavage leads to enhanced growth is unknown. Cleavage of VP3 does not alter viral binding to cell monolayers. In previous electron microscopic studies of infected cell cultures, it has been demonstrated that rotavirus particles enter cells by both endocytosis and direct cell membrane penetration. To determine whether trypsin treatment affected rotavirus internalization, we studied the kinetics of entry of infectious rhesus rotavirus (RRV) into MA104 cells. Trypsin-activated RRV was internalized with a half-time of 3 to 5 min, while nonactivated virus disappeared from the cell surface with a half-time of 30 to 50 min. In contrast to trypsin-activated RRV, loss of nonactivated RRV from the cell surface did not result in the appearance of infection, as measured by plaque formation. Endocytosis inhibitors (sodium azide, dinitrophenol) and lysosomotropic agents (ammonium chloride, chloroquine) had a limited effect on the entry of infectious virus into cells. Purified trypsin-activated RRV added to cell monolayers at pH 7.4 medicated 51Cr, [14C]choline, and [3H]inositol released from prelabeled MA104 cells. This release could be specifically blocked by neutralizing antibodies to VP3. These results suggest that MA104 cell infection follows the rapid entry of trypsin-activated RRV by direct cell membrane penetration. Cell membrane penetration of infectious RRV is initiated by trypsin cleavage of VP3. Neutralizing antibodies can inhibit this direct membrane penetration.     

A structure-function study of the C2 domain of cytosolic phospholipase A2. Identification of essential calcium ligands and hydrophobic membrane binding residues

The C2 domain of cytosolic phospholipase A2 (cPLA2) is involved in the Ca2+-dependent membrane binding of this protein. To identify protein residues in the C2 domain of cPLA2 essential for its Ca2+ and membrane binding, we selectively mutated Ca2+ ligands and putative membrane-binding residues of cPLA2 and measured the effects of mutations on its enzyme activity, membrane binding affinity, and monolayer penetration. The mutations of five Ca2+ ligands (D40N, D43N, N65A, D93N, N95A) show differential effects on the membrane binding and activation of cPLA2, indicating that two calcium ions bound to the C2 domain have differential roles. The mutations of hydrophobic residues (F35A, M38A, L39A, Y96A, Y97A, M98A) in the calcium binding loops show that the membrane binding of cPLA2 is largely driven by hydrophobic interactions resulting from the penetration of these residues into the hydrophobic core of the membrane. Leu39 and Val97 are fully inserted into the membrane, whereas Phe35 and Tyr96 are partially inserted. Finally, the mutations of four cationic residues in a beta-strand (R57E/K58E/R59E/R61E) have modest and negligible effects on the binding of cPLA2 to zwitterionic and anionic membranes, respectively, indicating that they are not directly involved in membrane binding. In conjunction with our previous study on the C2 domain of protein kinase C-alpha (Medkova, M., and Cho, W. (1998) J. Biol. Chem. 273, 17544-17552), these results demonstrate that C2 domains are not only a membrane docking unit but also a module that triggers membrane penetration of protein and that individual Ca2+ ions bound to the calcium binding loops play differential roles in the membrane binding and activation of their parent proteins.     

Phorbol ester translocation of protein kinase C in guinea-pig synaptosomes and the potentiation of calcium-dependent glutamate release

The distribution of protein kinase C activity and specific phorbol ester binding sites between soluble and particulate fractions of isolated guinea-pig cerebral cortical synaptosomes is examined following preincubation with phorbol esters. Half-maximal decrease in cytosolic activity requires 10 nM 4 beta-phorbol myristoyl acetate. Specific [3H]phorbol dibutyrate binding sites are translocated from cytoplasmic to particulate fractions in parallel with protein kinase C activity. Depolarization of the plasma membrane by 30 mM KCl does not cause translocation of protein kinase C. 1 microM 4 beta-phorbol myristoyl acetate and 1 microM 4 beta-phorbol didecanoate (but not 1 microM 4 alpha-phorbol didecanoate) enhance the release of glutamate from synaptosomes partially depolarized by 10 mM KCl; however, 4 beta-phorbol myristoyl acetate is ineffective at 20 nM. 1 microM 4 beta-phorbol myristoyl acetate slightly increases the cytosolic free Ca2+ concentration of polarized synaptosomes, but not that following partial depolarization. 4 beta-Phorbol myristoyl acetate causes a concentration-dependent increase in the Ca2+-dependent glutamate release induced by sub-optimal ionomycin concentrations, but is without effect on the release induced by maximal ionomycin. It is concluded that phorbol esters stereospecifically enhance the Ca2+-sensitivity of glutamate release, but that higher concentrations may be required than for protein kinase C translocation in the same preparation. Instead the enhancement may be related to the rapid inactivation of protein kinase C which occurs with phorbol esters.     

Detailed mechanisms of the inactivation of factor VIIIa by activated protein C in the presence of its cofactors, protein S and factor V

Factor VIIIa is inactivated by a combination of two mechanisms. Activation of factor VIII by thrombin results in a heterotrimeric factor VIIIa that spontaneously inactivates due to dissociation of the A2 subunit. Additionally, factor VIIIa is cleaved by the anticoagulant serine protease, activated protein C, at two cleavage sites, Arg(336) in the A1 subunit and Arg(562) in the A2 subunit. We previously characterized an engineered variant of factor VIII which contains a disulfide bond between the A2 and the A3 subunits that prevents the spontaneous dissociation of the A2 subunit following thrombin activation. Thus, in the absence of activated protein C, this variant has stable activity following activation by thrombin. To isolate the effects of the individual activated protein C cleavage sites on factor VIIIa, we engineered mutations of the activated protein C cleavage sites into the disulfide bond-cross-linked factor VIII variant. Arg(336) cleavage is 6-fold faster than Arg(562) cleavage, and the Arg(336) cleavage does not fully inactivate factor VIIIa when A2 subunit dissociation is blocked. Protein S enhances both cleavage rates but enhances Arg(562) cleavage more than Arg(336) cleavage. Factor V also enhances both cleavage rates when protein S is present. Factor V enhances Arg(562) cleavage more than Arg(336) cleavage as well. As a result, in the presence of both activated protein C cofactors, Arg(336) cleavage is only twice as fast as Arg(562) cleavage. Therefore, both cleavages contribute significantly to factor VIIIa inactivation.     

cGMP inhibition of Na+/H+ antiporter 3 (NHE3) requires PDZ domain adapter NHERF2, a broad specificity protein kinase G-anchoring protein

Electroneutral NaCl absorption mediated by Na+/H+ exchanger 3 (NHE3) is important in intestinal and renal functions related to water/Na+ homeostasis. cGMP inhibits NHE3 in intact epithelia. However, unexpectedly it failed to inhibit NHE3 stably transfected in PS120 cells, even upon co-expression of cGMP-dependent protein kinase type II (cGKII). Additional co-expression of NHERF2, the tandem PDZ domain adapter protein involved in cAMP inhibition of NHE3, restored cGMP as well as cAMP inhibition, whereas NHERF1 solely restored cAMP inhibition. In vitro conditions were identified in which NHERF2 but not NHERF1 bound cGKII. The NHERF2 PDZ2 C terminus, which binds NHE3, also bound cGKII. A non-myristoylated mutant of cGKII did not support cGMP inhibition of NHE3. Although cGKI also bound NHERF2 in vitro, it did not evoke inhibition of NHE3 unless a myristoylation site was added. These results show that NHERF2, acting as a novel protein kinase G-anchoring protein, is required for cGMP inhibition of NHE3 and that cGKII must be bound both to the plasma membrane by its myristoyl anchor and to NHERF2 to inhibit NHE3.     

Myristoylation of the RING finger Z protein is essential for arenavirus budding

The arenavirus small RING finger Z protein is the main driving force of arenavirus budding. The primary structure of Z is devoid of hydrophobic transmembrane domains, but both lymphocytic choriomeningitis virus (LCMV) and Lassa fever virus Z proteins accumulate near the inner surface of the plasma membrane and are strongly membrane associated. All known arenavirus Z proteins contain a glycine (G) at position 2, which is a potential acceptor site for a myristoyl moiety. Metabolic labeling showed incorporation of [(3)H]myristic acid by wild-type Z protein but not by the G2A mutant. The mutation G2A eliminated Z-mediated budding. Likewise, treatment with the myristoylation inhibitor 2-hydroxymyristic acid inhibited Z-mediated budding, eliminated formation of virus-like particles, and caused a dramatic reduction in virus production in LCMV-infected cells. Budding activity was restored in G2A mutant Z proteins by the addition of the myristoylation domain of the tyrosine protein kinase Src to their N termini. These findings indicate N-terminal myristoylation of Z plays a key role in arenavirus budding.     

Membrane geometry and protein functions

This review is devoted to systematization and analysis of the data on the effect of membrane geometry on different processes in living cells. In some cases, membrane curvature is the determinant in regulation of enzyme activity and in protein-lipid interactions. This fact has been demonstrated by the example of regulation of activity of some important enzymes, such as phospholipase A₂, protein kinase C, phosphatidyl serine decarboxylase 2, cytochrome P450, phosphatidyl inositol 3-kinase, CTP:phosphocholine cytidyltransferase, diglycosyl diacylglycerol synthetase, and G protein ArfGAP1 hydrolyzing GTP in the Arf-GTP complex. The effect of membrane geometry and bilayer curvature stress on penetration of cytotoxic and Trojan peptides into a cell, formation of pores at penetration of viruses into a cell, folding of membrane proteins, and release of cytochrome c from mitochondria during apoptosis have been considered as well. The conclusion has been made that membrane geometry and the resultant curvature stress energy are critical parameters in many vitally important cell processes, including regulation of some key enzymes.