Type II transmembrane domain hydrophobicity dictates the cotranslational dependence for inversion

Membrane insertion by the Sec61 translocon in the endoplasmic reticulum (ER) is highly dependent on hydrophobicity. This places stringent hydrophobicity requirements on transmembrane domains (TMDs) from single-spanning membrane proteins. On examining the single-spanning influenza A membrane proteins, we found that the strict hydrophobicity requirement applies to the N_out-C_in HA and M2 TMDs but not the N_in-C_out TMDs from the type II membrane protein neuraminidase (NA). To investigate this discrepancy, we analyzed NA TMDs of varying hydrophobicity, followed by increasing polypeptide lengths, in mammalian cells and ER microsomes. Our results show that the marginally hydrophobic NA TMDs (ΔG_app > 0 kcal/mol) require the cotranslational insertion process for facilitating their inversion during translocation and a positively charged N-terminal flanking residue and that NA inversion enhances its plasma membrane localization. Overall the cotranslational inversion of marginally hydrophobic NA TMDs initiates once ∼70 amino acids past the TMD are synthesized, and the efficiency reaches 50% by ∼100 amino acids, consistent with the positioning of this TMD class in type II human membrane proteins. Inversion of the M2 TMD, achieved by elongating its C-terminus, underscores the contribution of cotranslational synthesis to TMD inversion.     

Functional Analysis of a Class I Holin,P2 Y

Y is the putative holin gene of the paradigm coliphage P2 and encodes a 93-amino-acid protein. Y is predicted to be an integral membrane protein that adopts an N-out C-in membrane topology with 3 transmembrane domains (TMDs) and a highly charged C-terminal cytoplasmic tail. The same features are observed in the canonical class I lambda holin, the S105 protein of phage lambda, which controls lysis by forming holes in the plasma membrane at a programmed time. S105 has been the subject of intensive genetic, cellular, and biochemical analyses. Although Y is not related to S105 in its primary structure, its characterization might prove useful in discerning the essential traits for holin function. Here, we used physiological and genetic approaches to show that Y exhibits the essential holin functional criteria, namely, allele-specific delayed-onset lethality and sensitivity to the energization of the membrane. Taken together, these results suggest that class I holins share a set of unusual features that are needed for their remarkable ability to program the end of the phage infection cycle with precise timing. However, Y holin function requires the integrity of its short cytoplasmic C-terminal domain, unlike for S105. Finally, instead of encoding a second translational product of Y as an antiholin, as shown for lambda S107, the P2 lysis cassette encodes another predicted membrane protein, LysA, which is shown here to have a Y-specific antiholin character.     

Functional assembly of the λ S holin requires periplasmic localization of its N-terminus

Bacteriophage-λ-induced host-cell lysis requires two phage-encoded proteins, the S holin and the R transglycosylase. At a specific time during infection, the holin forms a lesion in the cytoplasmic membrane that permits access of the R protein to its substrate, the peptidoglycan. The λS gene represents the prototype of holin genes with a dual-start motif; they encode two proteins, a lysis effector and a lysis inhibitor. Although the two S proteins differ only by two amino acids (Met-1 and Lys-2) at the N-terminus, the longer product (S107) acts as an inhibitor of the lysis effector (S105). The functional difference between the proteins has been previously ascribed to the Lys-2 residue in S107. It was therefore of interest to determine the subcellular localization of the N-terminus of either S protein. To study the membrane topology of the S proteins, we used the topology probe TEM β-lactamase and an N-terminal tag derived from the Pseudomonas aeruginosa phage Pf3 coat protein. We show that both S proteins have a type III (N_out/C_in) topology. The results provide insight into the regulatory mechanism imposed by the dual-start motif and will be discussed in terms of a model for temporal regulation of the S-dependent “hole” in the membrane. Received: 28 January 1999 / Accepted: 23 April 1999     

The Murein Hydrolase of the Bacteriophage φ3626 Dual Lysis System Is Active against All Tested Clostridium perfringens Strains

Clostridium perfringens commonly occurs in food and feed, can produce an enterotoxin frequently implicated in food-borne disease, and has a substantial negative impact on the poultry industry. As a step towards new approaches for control of this organism, we investigated the cell wall lysis system of C. perfringens bacteriophage 3626, whose dual lysis gene cassette consists of a holin gene and an endolysin gene. Hol3626 has two membrane-spanning domains (MSDs) and is a group II holin. A positively charged beta turn between the two MSDs suggests that both the amino terminus and the carboxy terminus of Hol3626 might be located outside the cell membrane, a very unusual holin topology. Holin function was experimentally demonstrated by using the ability of the holin to complement a deletion of the heterologous phage λ S holin in λΔSthf. The endolysin gene ply3626 was cloned in Escherichia coli. However, protein synthesis occurred only when bacteria were supplemented with rare tRNA^Arg and tRNA^Ile genes. Formation of inclusion bodies could be avoided by drastically lowering the expression level. Amino-terminal modification by a six-histidine tag did not affect enzyme activity and enabled purification by metal chelate affinity chromatography. Ply3626 has an N-terminal amidase domain and a unique C-terminal portion, which might be responsible for the specific lytic range of the enzyme. All 48 tested strains of C. perfringens were sensitive to the murein hydrolase, whereas other clostridia and bacteria belonging to other genera were generally not affected. This highly specific activity towards C. perfringens might be useful for novel biocontrol measures in food, feed, and complex microbial communities.     

Dissection of De Novo Membrane Insertion Activities of Internal Transmembrane Segments of ATP-Binding-Cassette Transporters: Toward Understanding Topological Rules for Membrane Assembly of Polytopic Membrane Proteins

The membrane assembly of polytopic membrane proteins is a complicated process. Using Chinese hamster P-glycoprotein (Pgp) as a model protein, we investigated this process previously and found that Pgp expresses more than one topology. One of the variations occurs at the transmembrane (TM) domain including TM3 and TM4: TM4 inserts into membranes in an N_in-C_out rather than the predicted N_out-C_in orientation, and TM3 is in cytoplasm rather than the predicted N_in-C_out orientation in the membrane. It is possible that TM4 has a strong activity to initiate the N_in-C_out membrane insertion, leaving TM3 out of the membrane. Here, we tested this hypothesis by expressing TM3 and TM4 in isolated conditions. Our results show that TM3 of Pgp does not have de novo N_in-C_out membrane insertion activity whereas TM4 initiates the N_in-C_out membrane insertion regardless of the presence of TM3. In contrast, TM3 and TM4 of another polytopic membrane protein, cystic fibrosis transmembrane conductance regulator (CFTR), have a similar level of de novo N_in-C_out membrane insertion activity and TM4 of CFTR functions only as a stop-transfer sequence in the presence of TM3. Based on these findings, we propose that 1) the membrane insertion of TM3 and TM4 of Pgp does not follow the sequential model, which predicts that TM3 initiates N_in-C_out membrane insertion whereas TM4 stops the insertion event; and 2) “leaving one TM segment out of the membrane” may be an important folding mechanism for polytopic membrane proteins, and it is regulated by the N_in-C_out membrane insertion activities of the TM segments.     

The hydrophilic C-terminal part of the lambda S holin is non-essential for intermolecular interactions

Available evidence indicates that oligomerization of the bacteriophage lambda S holin leads to a non-specific lesion in the cytoplasmic membrane which permits transit of the phage encoded transglycosylase to the periplasm. In an attempt to locate an intermolecular interaction domain in S a chimeric protein comprising the N-terminal 32 aa of phage PhiX174 lysis protein E and the last 75 aa of lambda S has been constructed. We report that the EΦS fusion protein is stable, membrane bound, and inhibits S-mediated lysis in trans. C-terminal truncations of the EΦS fusion protein indicated that the hydrophilic C-terminal end of S (i.e. the last 15 aa) is non-essential for oligomerization.     

Probing the Structure of the S105 Hole

For most phages, holins control the timing of host lysis. During the morphogenesis period of the infection cycle, canonical holins accumulate harmlessly in the cytoplasmic membrane until they suddenly trigger to form lethal lesions called holes. The holes can be visualized by cryo-electron microscopy and tomography as micrometer-scale interruptions in the membrane. To explore the fine structure of the holes formed by the lambda holin, S105, a cysteine-scanning accessibility study was performed. A collection of S105 alleles encoding holins with a single Cys residue in different positions was developed and characterized for lytic function. Based on the ability of 4-acetamido-4′-((iodoacetyl) amino) stilbene-2,2′-disulfonic acid, disodium salt (IASD), to modify these Cys residues, one face of transmembrane domain 1 (TMD1) and TMD3 was judged to face the lumen of the S105 hole. In both cases, the lumen-accessible face was found to correspond to the more hydrophilic face of the two TMDs. Judging by the efficiency of IASD modification, it was concluded that the bulk of the S105 protein molecules were involved in facing the lumen. These results are consistent with a model in which the perimeters of the S105 holes are lined by the holin molecules present at the time of lysis. Moreover, the findings that TMD1 and TMD3 face the lumen, coupled with previous results showing TMD2-TMD2 contacts in the S105 dimer, support a model in which membrane depolarization drives the transition of S105 from homotypic to heterotypic oligomeric interactions.     

The N-Terminal Transmembrane Domain of λ S Is Required for Holin but Not Antiholin Function

The λ S gene encodes a holin, S105, and an antiholin, S107, which differs by its Met-Lys N-terminal extension. The model for the lysis-defective character of S107 stipulates that the additional N-terminal basic residue keeps S107 from assuming the topology of S105, which is N-out, C-in, with three transmembrane domains (TMDs). Here we show that the N terminus of S105 retains its fMet residue but that the N terminus of S107 is fully deformylated. This supports the model that in S105, TMD1 inserts into the membrane very rapidly but that in S107, it is retained in the cytoplasm. Further, it reveals that, compared to S105, S107 has two extra positively charged moieties, Lys2 and the free N-terminal amino group, to hinder its penetration into an energized membrane. Moreover, an allele, S105_ΔTMD1, with TMD1 deleted, was found to be defective in lysis, insensitive to membrane depolarization, and dominant to the wild-type allele, indicating that the lysis-defective, antiholin character of S107 is due to the absence of TMD1 from the bilayer rather than to its ectopic localization at the inner face of the cytoplasmic membrane. Finally, the antiholin function of the deletion protein was compromised by the substitution of early-lysis missense mutations in either the deletion protein or parental S105 but restored when both S105_ΔTMD1 and holin carried the substitution.In general, holins control the length of the infection cycle of double-stranded DNA phages (37). During late gene expression, the holin protein accumulates harmlessly in the bilayer until suddenly and spontaneously triggering the formation of holes in the membrane at an allele-specific time (13, 15). Holin genes are extremely diverse, but most can be grouped into two main classes based on the number of predicted transmembrane domains (TMDs): class I, with three TMDs and a predicted N-out, C-in topology, and class II, with two TMDs and a predicted N-in, C-in topology (38). Holin genes and function are subject to several levels of regulation, among which a particularly striking feature is the common occurrence of two potential translational starts, or dual-start motifs (5, 37), separated by only a few codons. Dual-start motifs are found in many holins of both of the two major classes; in nearly every case, the two starts are separated by at least one basic residue. The first dual-start motif to be characterized was that of λ S, the prototype class I holin gene (Fig. 1A and B). Translation initiation events occur at codons 1 and 3, giving rise to two products, S107 and S105, each named because of the length of its amino acid sequence; in the wild-type (wt) allele, two RNA structures define the ratio of initiations at the two start codons, resulting in an S105/S107 ratio of ∼2:1.Open in a separate windowFIG. 1.Gene, topology, and sequence of λ S. (A, top) The λ lysis cassette, including genes S, R, Rz, and Rz1, is shown, along with its promoter p_R′, and Q, encoding the late gene activator. The 5′ end of the class I holin gene S has two start codons, Met1, the start for S107, and Met3, the start for S105, and two RNA structures that regulate initiations at these codons. The S105 and S107 alleles have Leu (CUG) codons in place of the Met3 and Met1 codons, respectively. (B) Primary structure of S proteins. Missense changes relevant to the text are shown. Starts for S107 and S105 are indicated by asterisks. The three TMDs are boxed (13), and the extent of the ΔTMD1 deletion is indicated. (C) Model for the membrane topology of S105, S107, and S105_ΔTMD1. Topology and boundary residues for TMD1, -2, and -3 are based on Graschopf and Blasi (11) and Gründling et al. (13), respectively.Although they differ only by the Met-Lys N-terminal extension of S107, the two proteins have opposing functions; S105 is the holin and S107 the antiholin. The antiholin function is reflected by four principal features: first, when the Met3 start is inactivated, the mutant allele, designated S107 (Fig. ​(Fig.1A),1A), is lysis defective (26); second, the S107 protein binds and inhibits S105 specifically (3, 16); third, when S107 is produced in stoichiometric excess over S105, lysis is blocked for several times the length of the normal infection cycle (3, 4, 7, 16); and fourth, S107 antiholin function, i.e., inhibition of S105 hole formation, can be instantly subverted by collapsing the proton motive force, most easily done by addition of energy poisons to the medium (3). The predicted N-out, C-in topology and the requirement for the energized membrane led to a model in which S107 is initially inserted in the membrane with only two TMDs, with TMD1 being blocked from insertion by the presence of the positively charged residue, Lys2, whereas S105 has three TMDs (Fig. ​(Fig.1C)1C) (39). From this perspective, S105-S107 complexes, which are approximately twice as numerous as the S105 homodimers, are defective in triggering hole formation. An appealing feature of this model is that when an S105-mediated hole formation event does occur in a cell, the resultant collapse of the membrane potential allows insertion of TMD1 of S107 into the membrane, instantly tripling the amount of active holin by making the previously inactive pool of S105-S107 complexes functional (38).Some genetic and physiological evidence for the topology of the λ S proteins has been obtained using gene fusions. First, a fusion of the S gene at codon 105 with lacZ generates a functional, membrane-inserted β-galactosidase chimera, indicating, as expected, the cytoplasmic disposition of the highly charged C terminus of the S protein (40). Second, Graschopf and Bläsi (12) demonstrated that S-mediated hole formation could be obtained with constructs where a secretory signal sequence was fused to the N termini of both S105 and S107. Lysis required the cleavage of the signal sequence by leader peptidase, and export of the signal-S107 form was slower than for the signal-S105 form. However, evidence for the topology of native forms of S has not been available. Moreover, no basis for the inhibitory character of S107 has been established. In the simplest view, the antiholin function could be due to the absence of TMD1 from the bilayer or the ectopic localization of TMD1 in the cytoplasm, or both. Here, we report studies directed at dissecting the precise role of topology in S107 function and correlating antiholin activity with its ability to heterodimerize with S105. The results are discussed in terms of a general model for the formation of the holin lesion and the role of dynamic membrane topology in its temporal regulation.     

The T4 RI antiholin has an N-terminal signal anchor release domain that targets it for degradation by DegP

Lysis inhibition (LIN) of T4-infected cells was one of the foundational experimental systems for modern molecular genetics. In LIN, secondary infection of T4-infected cells results in a dramatically protracted infection cycle in which intracellular phage and endolysin accumulation can continue for hours. At the molecular level, this is due to the inhibition of the holin, T, by the antiholin, RI. RI is only 97 residues and contains an N-terminal hydrophobic domain and a C-terminal hydrophilic domain; expression of the latter domain fused to a secretory signal sequence is sufficient to impose LIN, due to its specific interaction with the periplasmic domain of the T holin. Here we show that the N-terminal sequence comprises a signal anchor release (SAR) domain, which causes the secretion of RI in a membrane-tethered form and then its subsequent release into the periplasm, without proteolytic processing. Moreover, the SAR domain confers both functional lability and DegP-mediated proteolytic instability on the released form of RI, although LIN is not affected in a degP host. These results are discussed in terms of a model for the activation of RI in the establishment of the LIN state.     

An ancient player unmasked: T4 rI encodes a t-specific antiholin

Phage T4 effects lysis by its holin T and its endolysin E. Lysis is inhibited (LIN) if the infected cell is subjected to secondary infections by T4 phage particles. The T4 rI gene is required for LIN in all hosts tested. Here, we show that a cloned rI gene can impose a T-specific LIN on T-mediated lysis in the context of the phage lambda infective cycle, in the absence of other T4 genes and without secondary infection by T4. Moreover, it is shown that the T holin accumulates in the membrane during LIN, forming SDS-resistant oligomers. We show by cross-linking experiments that a T-RI heterodimer is formed during LIN, demonstrating that RI belongs to the functional class of antiholins, such as the S107 protein of lambda, which heterodimerizes with its cognate holin, S105. Finally, we show that the addition of Ni(2+) ions to the medium can block lysis by a T protein hexahistidine-tagged at its C-terminus, suggesting that liganding of the periplasmic domain is sufficient to impose lysis inhibition. The results are discussed in terms of a model in which the LIN-inducing signal of the secondary infecting phage influences a conformational equilibrium assumed by RI in the periplasm.     

Functional analysis of the holin-like proteins of mycobacteriophage Ms6

The mycobacteriophage Ms6 is a temperate double-stranded DNA (dsDNA) bacteriophage which, in addition to the predicted endolysin (LysA)-holin (Gp4) lysis system, encodes three additional proteins within its lysis module: Gp1, LysB, and Gp5. Ms6 Gp4 was previously described as a class II holin-like protein. By analysis of the amino acid sequence of Gp4, an N-terminal signal-arrest-release (SAR) domain was identified, followed by a typical transmembrane domain (TMD), features which have previously been observed for pinholins. A second putative holin gene (gp5) encoding a protein with a predicted single TMD at the N-terminal region was identified at the end of the Ms6 lytic operon. Neither the putative class II holin nor the single TMD polypeptide could trigger lysis in pairwise combinations with the endolysin LysA in Escherichia coli. One-step growth curves and single-burst-size experiments of different Ms6 derivatives with deletions in different regions of the lysis operon demonstrated that the gene products of gp4 and gp5, although nonessential for phage viability, appear to play a role in controlling the timing of lysis: an Ms6 mutant with a deletion of gp4 (Ms6(Δgp4)) caused slightly accelerated lysis, whereas an Ms6(Δgp5) deletion mutant delayed lysis, which is consistent with holin function. Additionally, cross-linking experiments showed that Ms6 Gp4 and Gp5 oligomerize and that both proteins interact. Our results suggest that in Ms6 infection, the correct and programmed timing of lysis is achieved by the combined action of Gp4 and Gp5.     

CD39 reveals novel insights into the role of transmembrane domains in protein processing, apical targeting and activity

Cargo proteins of the biosynthetic secretory pathway are folded in the endoplasmic reticulum (ER) and proceed to the trans Golgi network for sorting and targeting to the apical or basolateral sides of the membrane, where they exert their function. These processes depend on diverse protein domains. Here, we used CD39 (NTPdase1), a modulator of thrombosis and inflammation, which contains an extracellular and two transmembrane domains (TMDs), as a model protein to address comprehensively the role of native TMDs in folding, polarized transport and biological activity. In MDCK cells, CD39 exits Golgi dynamin-dependently and is targeted to the apical side of the membrane. Although the N-terminal TMD possesses an apical targeting signal, the N- and C-terminal TMDs are not required for apical targeting of CD39. Folding and transport to the plasma membrane relies only on the C-terminal TMD, while the N-terminal one is redundant. Nevertheless, both N- and C-terminal anchoring as well as genuine TMDs are critical for optimal enzymatic activity and activation by cholesterol. We conclude therefore that TMDs are not just mechanical linkers between proteins and membranes but are also able to control folding and sorting, as well as biological activity via sensing components of lipid bilayers.     

The murein hydrolase of the bacteriophage phi3626 dual lysis system is active against all tested Clostridium perfringens strains

Clostridium perfringens commonly occurs in food and feed, can produce an enterotoxin frequently implicated in food-borne disease, and has a substantial negative impact on the poultry industry. As a step towards new approaches for control of this organism, we investigated the cell wall lysis system of C. perfringens bacteriophage phi3626, whose dual lysis gene cassette consists of a holin gene and an endolysin gene. Hol3626 has two membrane-spanning domains (MSDs) and is a group II holin. A positively charged beta turn between the two MSDs suggests that both the amino terminus and the carboxy terminus of Hol3626 might be located outside the cell membrane, a very unusual holin topology. Holin function was experimentally demonstrated by using the ability of the holin to complement a deletion of the heterologous phage lambda S holin in lambdadeltaSthf. The endolysin gene ply3626 was cloned in Escherichia coli. However, protein synthesis occurred only when bacteria were supplemented with rare tRNA(Arg) and tRNA(Ile) genes. Formation of inclusion bodies could be avoided by drastically lowering the expression level. Amino-terminal modification by a six-histidine tag did not affect enzyme activity and enabled purification by metal chelate affinity chromatography. Ply3626 has an N-terminal amidase domain and a unique C-terminal portion, which might be responsible for the specific lytic range of the enzyme. All 48 tested strains of C. perfringens were sensitive to the murein hydrolase, whereas other clostridia and bacteria belonging to other genera were generally not affected. This highly specific activity towards C. perfringens might be useful for novel biocontrol measures in food, feed, and complex microbial communities.     

Outward Rectification of Voltage-Gated K+ Channels Evolved at Least Twice in Life History

Voltage-gated potassium (K⁺) channels are present in all living systems. Despite high structural similarities in the transmembrane domains (TMD), this K⁺ channel type segregates into at least two main functional categories—hyperpolarization-activated, inward-rectifying (K_in) and depolarization-activated, outward-rectifying (K_out) channels. Voltage-gated K⁺ channels sense the membrane voltage via a voltage-sensing domain that is connected to the conduction pathway of the channel. It has been shown that the voltage-sensing mechanism is the same in K_in and K_out channels, but its performance results in opposite pore conformations. It is not known how the different coupling of voltage-sensor and pore is implemented. Here, we studied sequence and structural data of voltage-gated K⁺ channels from animals and plants with emphasis on the property of opposite rectification. We identified structural hotspots that alone allow already the distinction between K_in and K_out channels. Among them is a loop between TMD S5 and the pore that is very short in animal K_out, longer in plant and animal K_in and the longest in plant K_out channels. In combination with further structural and phylogenetic analyses this finding suggests that outward-rectification evolved twice and independently in the animal and plant kingdom.     

Determining the helical tilt angle and dynamic properties of the transmembrane domains of pinholin S2168 using mechanical alignment EPR spectroscopy

The lytic cycle of bacteriophage φ21 for the infected E. coli is initiated by pinholin S²¹, which determines the timing of host cell lysis through the function of pinholin (S²¹68) and antipinholin (S²¹71). The activity of pinholin or antipinholin directly depends on the function of two transmembrane domains (TMDs) within the membrane. For active pinholin, TMD1 externalizes and lies on the surface while TMD2 remains incorporated inside the membrane forming the lining of the small pinhole. In this study, spin labeled pinholin TMDs were incorporated separately into mechanically aligned POPC (1-palmitoyl-2-oleoyl-glycero-3-phosphocholine) lipid bilayers and investigated with electron paramagnetic resonance (EPR) spectroscopy to determine the topology of both TMD1 and TMD2 with respect to the lipid bilayer; the TOAC (2,2,6,6-tetramethyl-N-oxyl-4-amino-4-carboxylic acid) spin label was used here because it attaches to the backbone of a peptide and is very rigid. TMD2 was found to be nearly colinear with the bilayer normal (n) with a helical tilt angle of 16 ± 4° while TMD1 lies on or near the surface with a helical tilt angle of 84 ± 4°. The order parameters (~0.6 for both TMDs) obtained from our alignment study were reasonable, which indicates the samples incorporated inside the membrane were well aligned with respect to the magnetic field (B₀). The data obtained from this study supports previous findings on pinholin: TMD1 partially externalizes from the lipid bilayer and interacts with the membrane surface, whereas TMD2 remains buried in the lipid bilayer in the active conformation of pinholin S²¹68. In this study, the helical tilt angle of TMD1 was measured for the first time. For TMD2 our experimental data corroborates the findings of the previously reported helical tilt angle by the Ulrich group.     

Analysis of membrane topology of the human reduced folate carrier protein by hemagglutinin epitope insertion and scanning glycosylation insertion mutagenesis

The human reduced folate carrier (RFC) is the major membrane transport system for both reduced folates and chemotherapeutic antifolate drugs, such as methotrexate (MTX). Although the RFC protein has been subjected to intensive study in order to identify critical structural and functional determinants of transport, it is impossible to assess the significance of these studies without characterizing the essential domain structure and membrane topology. The primary amino acid sequence from the cloned cDNAs predicts that the human RFC protein has 12 transmembrane domains (TMDs) with a large cytosolic loop between TMDs 6 and 7, and cytosolic-facing N- and C-termini. To establish the RFC membrane topology, a hemagglutinin (HA) epitope was inserted into the individual predicted intracellular and extracellular loops. HA insertions into putative TMD interconnecting loops 3/4, 6/7, 7/8, and 8/9, and the N- and C-termini all preserved MTX transport activity upon expression in transport-impaired K562 cells. Immunofluorescence detection with HA-specific antibody under both permeabilized and non-permeabilized conditions confirmed extracellular orientations for loops 3/4 and 7/8, and cytosolic orientations for loops 6/7 and 8/9, and the N- and C-termini. Insertion of a consensus N-glycosylation site [NX(S/T)] into putative loops 5/6, 8/9, and 9/10 of deglycosylated RFC-Gln⁵⁸ had minimal effects on MTX transport. Analysis of glycosylation status on Western blots suggested an extracellular orientation for loop 5/6, and intracellular orientations for loops 8/9 and 9/10. Our findings strongly support the predicted topology model for TMDs 1-8 and the C-terminus of human RFC. However, our results raise the possibility of an alternative membrane topology for TMDs 9-12.     

Pinholin S21 mutations induce structural topology and conformational changes

The bacteriophage infection cycle is terminated at a predefined time to release the progeny virions via a robust lytic system composed of holin, endolysin, and spanin proteins. Holin is the timekeeper of this process. Pinholin S²¹ is a prototype holin of phage Φ21, which determines the timing of host cell lysis through the coordinated efforts of pinholin and antipinholin. However, mutations in pinholin and antipinholin play a significant role in modulating the timing of lysis depending on adverse or favorable growth conditions. Earlier studies have shown that single point mutations of pinholin S²¹ alter the cell lysis timing, a proxy for pinholin function as lysis is also dependent on other lytic proteins. In this study, continuous wave electron paramagnetic resonance (CW-EPR) power saturation and double electron-electron resonance (DEER) spectroscopic techniques were used to directly probe the effects of mutations on the structure and conformational changes of pinholin S²¹ that correlate with pinholin function. DEER and CW-EPR power saturation data clearly demonstrate that increased hydrophilicity induced by residue mutations accelerate the externalization of antipinholin transmembrane domain 1 (TMD1), while increased hydrophobicity prevents the externalization of TMD1. This altered hydrophobicity is potentially accelerating or delaying the activation of pinholin S²¹. It was also found that mutations can influence intra- or intermolecular interactions in this system, which contribute to the activation of pinholin and modulate the cell lysis timing. This could be a novel approach to analyze the mutational effects on other holin systems, as well as any other membrane protein in which mutation directly leads to structural and conformational changes.     

Physical and functional interactions of the cytomegalovirus US6 glycoprotein with the transporter associated with antigen processing

The endoplasmic reticulum-resident human cytomegalovirus glycoprotein US6 (gpUS6) inhibits peptide translocation by the transporter associated with antigen processing (TAP) to prevent loading of major histocompatibility complex class I molecules and antigen presentation to CD8+ T cells. TAP is formed by two subunits, TAP1 and TAP2, each containing one multispanning transmembrane domain (TMD) and a cytosolic nucleotide binding domain. Here we reported that the blockade of TAP by gpUS6 is species-restricted, i.e. gpUS6 inhibits human TAP but not rat TAP. Co-expression of human and rat subunits of TAP demonstrates independent binding of gpUS6 to human TAP1 and TAP2, whereas gpUS6 does not bind to rat TAP subunits. gpUS6 associates with preformed TAP1/2 heterodimers but not with unassembled TAP subunits. To locate domains of TAP required for gpUS6 binding and function, we took advantage of reciprocal human/rat intrachain TAP chimeras. Each TAP subunit forms two contact sites within its TMD interacting with gpUS6. The dominant gpUS6-binding site on TAP2 maps to an N-terminal loop, whereas inhibition of peptide transport is mediated by a C-terminal loop of the TMD. For TAP1, two gpUS6 binding domains are formed by loops of the C-terminal TMD. The domain required for TAP inactivation is built by a distal loop of the C-terminal TMD, indicating a topology of TAP1 comprising 10 endoplasmic reticulum transmembrane segments. By forming multimeric complexes, gpUS6 reaches the distant target domains to arrest peptide transport. The data revealed a nonanalogous multipolar bridging of the TAP TMDs by gpUS6.     

Protein determinants of phage T4 lysis inhibition

Genetic studies have established that lysis inhibition in bacteriophage T4 infections occurs when the RI antiholin inhibits the lethal hole-forming function of the T holin. The T-holin is composed of a single N-terminal transmembrane domain and a ~20 kDa periplasmic domain. It accumulates harmlessly throughout the bacteriophage infection cycle until suddenly causing permeabilization of the inner membrane, thereby initiating lysis. The RI antiholin has a SAR domain that directs its secretion to the periplasm, where it can either be inactivated and degraded or be activated as a specific inhibitor of T. Previously, it was shown that the interaction of the soluble domains of these two proteins within the periplasm was necessary for lysis inhibition. We have purified and characterized the periplasmic domains of both T and RI. Both proteins were purified in a modified host that allows disulfide bond formation in the cytoplasm, due to the functional requirement of conserved disulfide bonds. Analytical centrifugation and circular dichroism spectroscopy showed that RI was monomeric and exhibited ~80% alpha-helical content. In contrast, T exhibited a propensity to oligomerize and precipitate at high concentrations. Incubation of RI with T inhibits this aggregation and results in a complex of equimolar T and RI content. Although gel filtration analysis indicated a complex mass of 45 kDa, intermediate between the predicted 30 kDa heterodimer and 60 kDa heterotetramer, sedimentation velocity analysis indicated that the predominant species is the former. These results suggest that RI binding to T is necessary and sufficient for lysis inhibition.