Sequence and deletion analysis of the recombination enhancement gene (ref) of bacteriophage P1: evidence for promoter-operator and attenuator-antiterminator control.

The ref gene of bacteriophage P1 stimulates recombination between two defective lacZ genes in the Escherichia coli chromosome (lac x lac recombination) and certain other RecA-dependent recombination processes. We determined the DNA sequence of the 5' portion of the ref gene and tested various regions for functionality by inserting DNA fragments lacking increasing amounts of 5' sequence into plasmid and lambda phage vectors and measuring the ability of the constructs to stimulate lac x lac recombination. The region found essential for Ref activity in the absence of external heterologous promoters encodes two presumptive promoters, pref-1 and pref-2, whose -10 regions fall in a nearly perfect 13-base-pair (bp) tandem repeat. The -10 region of the putative pref-1 is part of a phage P1 c1 repressor recognition sequence. The first two ATG codons in the ref reading frame are, respectively, 90 and 216 bp downstream from the putative promoter-operator region. Deletion analysis indicated that translation can initiate at either ATG (although neither is associated with a canonical ribosome-binding sequence) and that the 42 amino acids in between are not indispensable for Ref stimulation of lac x lac recombination. However, the shorter reading frame appears to encode a less active polypeptide. The 91-bp leader region between the putative promoter-operator and the first ATG contains 30 codons in frame with the ref structural sequence, but its frame can be shifted without affecting Ref activity. The leader region ends with an apparent rho-independent termination sequence (attenuator). Deletion of 18 bp of early leader sequence drastically reduced Ref activity, even when ref was driven by a heterologous promoter (plac). An 8-bp internal deletion in the putative attenuator sequence relieved this requirement for the early leader sequence. This latter observation, along with nucleotide complementarity between portions of the early leader and attenuator sequences, are consistent with preemption of attenuation by the early leader.     

The c1 repressor of bacteriophage P1 operator-repressor interaction of wild-type and mutant repressor proteins.

The c1 repressor gene of bacteriophage P1 and the temperature-sensitive mutants P1c1.100 and P1c1.162 was cloned into an expression vector and the repressor proteins were overproduced. A rapid purification procedure was required for the isolation of the thermolabile repressor proteins. Identification of the highly purified protein of an apparent molecular weight of 33,000 as the product of the c1 gene was verified by (i) the coincidence of partial amino acid sequences determined experimentally to that deduced from the c1 DNA sequence, and (ii) the temperature-sensitive binding to the operator DNA of the thermolabile repressor proteins. Analysis of the products of c1-c1.100 recombinant DNAs relates the thermolability to an unknown alteration in the C-terminal half of the c1.100 repressor. Binding to the operator DNA of c1 repressor is sensitive to N-ethylmaleimide. Since the only three cysteine residues are located in the C-terminal half of the repressor it is suggested that this part of the molecule is important for the binding to the operator DNA. This assumption is supported by the findings that a 14-kDa C-terminal repressor fragment obtained by cyanogen bromide cleavage retains DNA binding properties.     

On the role of IS1 in the formation of hybrids between the bacteriophage P1 and the R plasmid NR1

Summary The genomes of bacteriophage P1 derivatives carrying drug resistance genes derived from an R plasmid NR1 were analysed by restriction cleavage and be DNA-DNA hybridization. Two representatives of a class of oversized P1CmSmSu phages were identified as P1 carrying the entire r-determinant of NR1 together with its two flanking, directly repeated IS1. In one case the r-determinant insertion is carried at the site of the residential IS1 of P1, in the other case it is transposed into another region of the P1 genome. Models postulate that the first type resulted from reciprocal recombination within IS1 elements and that the formation of the second type of P1-R hybrid depended both on IS1 mediated transposition and reciprocal recombination. Plaque forming P1Cm or P1CmSm phages are explained as IS1 mediated deletion derivatives of P1CmSmSu, although an alternative model postulates that sometimes P1Cm phages might result from two consecutive transposition events of only one IS1 without involving reciprocal recombination. Secondary P1 derivatives carrying only one IS1 at the site of the original r-determinant or of Cm insertions into P1 must have been produced by reciprocal recombination between the two IS1 flanking the insertions. An implication from this study, that any genetic material carried adjacent to an IS1 element may undergo passive transposition, is discussed.     

Creating directed double-strand breaks with the Ref protein: a novel RecA-dependent nuclease from bacteriophage P1

The bacteriophage P1-encoded Ref protein enhances RecA-dependent recombination in vivo by an unknown mechanism. We demonstrate that Ref is a new type of enzyme; that is, a RecA-dependent nuclease. Ref binds to ss- and dsDNA but does not cleave any DNA substrate until RecA protein and ATP are added to form RecA nucleoprotein filaments. Ref cleaves only where RecA protein is bound. RecA functions as a co-nuclease in the Ref/RecA system. Ref nuclease activity can be limited to the targeted strands of short RecA-containing D-loops. The result is a uniquely programmable endonuclease activity, producing targeted double-strand breaks at any chosen DNA sequence in an oligonucleotide-directed fashion. We present evidence indicating that cleavage occurs in the RecA filament groove. The structure of the Ref protein has been determined to 1.4 Å resolution. The core structure, consisting of residues 77–186, consists of a central 2-stranded β-hairpin that is sandwiched between several α-helical and extended loop elements. The N-terminal 76 amino acid residues are disordered; this flexible region is required for optimal activity. The overall structure of Ref, including several putative active site histidine residues, defines a new subclass of HNH-family nucleases. We propose that enhancement of recombination by Ref reflects the introduction of directed, recombinogenic double-strand breaks.     

Transposition of a tetracycline-resistance determinant (Tn1523) and cointegration events mediated by the pIP231 plasmid in Escherichia coli

A 10.8-kb transposable DNA sequence conferring resistance to tetracycline resides on the IncY Escherichia coli plasmid pIP231. This sequence, designated Tn1523, was shown to insert into different sites of the replicons of the IncY prophage P1Cm c1.100 and the IncI1 plasmid pIP112. This process is not dependent on the host recombination system recA. Genetic results indicate that Tn1523 transposition involves the formation of a cointegrate intermediate, either between pIP231 and P1Cm c1.100, or between pIP231 and pIP112. These intermediates were found to be resolved into donor and recipient plasmids, each harboring a copy of the Tn1523 transposon. A stable structure formed by fusion of the pIP231 plasmid with the pIP112 plasmid was also observed. This event occurs in the absence of the bacterial recA gene product and seems to involve a site-specific reciprocal recombination between "IS-like" elements.     

Ref(2)P, the Drosophila melanogaster homologue of mammalian p62, is required for the formation of protein aggregates in adult brain

P62 has been proposed to mark ubiquitinated protein bodies for autophagic degradation. We report that the Drosophila melanogaster p62 orthologue, Ref(2)P, is a regulator of protein aggregation in the adult brain. We demonstrate that Ref(2)P localizes to age-induced protein aggregates as well as to aggregates caused by reduced autophagic or proteasomal activity. A similar localization to protein aggregates is also observed in D. melanogaster models of human neurodegenerative diseases. Although atg8a autophagy mutant flies show accumulation of ubiquitin- and Ref(2)P-positive protein aggregates, this is abrogated in atg8a/ref(2)P double mutants. Both the multimerization and ubiquitin binding domains of Ref(2)P are required for aggregate formation in vivo. Our findings reveal a major role for Ref(2)P in the formation of ubiquitin-positive protein aggregates both under physiological conditions and when normal protein turnover is inhibited.     

The bof gene of bacteriophage P1: DNA sequence and evidence for roles in regulation of phage c1 and ref genes.

The C1 repressor of bacteriophage P1 acts via 14 or more distinct operators. This repressor represses its own synthesis as well as the synthesis of other gene products. Previously, mutation of an auxiliary regulatory gene, bof, has been shown to increase expression of some C1-regulated P1 genes (e.g., ref) but to decrease expression of others (e.g., ban). In this study the bof gene was isolated on the basis of its ability to depress stimulation of Escherichia coli chromosomal recombination by the P1 ref gene, if and only if a source of C1 was present. C1 alone, but not Bof alone, was partially effective. The bofDNA sequence encodes an 82-codon reading frame that begins with a TTG codon and includes the sites of the bof-1(Am) mutation and a bof::Tn5 null mutation. Expression of ref::lacZ and cl::lacZ fusion genes was partially repressed in trans by a P1 bof-1 prophage or by plasmid-encoded C1 alone, which was in agreement with effects on Ref-stimulated recombination and with previous indirect evidence for c1 autoregulation. Repression of both fusion genes by plasmid-encoded C1 plus Bof or by a P1 bof+ prophage was more complete. When the C1 source also included a 0.7-kilobase region upstream from C1 which encodes the coi gene, repression of both c1::lacZ and ref::lacZ by C1 alone or by C1 plus Bof was much less effective, as if Coi interfered with C1 repressor function.     

Analysis of transposable elements inserted in the genomes of bacteriophages Mu and P1.

We have examined the genomes of the temperate bacteriophages Mu and P1 and some of their insertion mutants for hybridization with the prokaryotic transposable elements IS1 and IS2. We used the DNA blotting-hybridization technique in which denatured DNA fragments are transferred to nitrocellulose paper directly from agarose gels and hybridized to 32P-labeled probe DNA. The 800 base pair insertion in an X mutant of Mu was found to hybridize with IS1. The chloramphenicol resistance transposon, Tn9, in Mu X cam mutants was found to be located at or close to the sites of IS1 insertion in X mutants; Tn9 also hybridized with IS1. The restriction endonuclease BalI cleaved IS1 once; it cleaved Tn9 in all Mu X cam mutants twice to release a fragment of about 1700 base pairs. These results support the conclusion that Tn9 contains one copy of IS1 at each end. In the P1cam isolate, from which Tn9 was transposed to Mu, BalI made a third cut in Tn9 giving rise to fragments of about 850 base pairs. The data further suggested that Tn9 is present in tandem copies in the P1cam isolate we examined. P1 itself was found to harbor IS1. The two P1 strains tested had a common fragment containing IS1; one strain had an additional copy of IS1. The IS1 element common to the P1 strains was shown to be the site of the Tn9 insertion in the P1cam isolate examined. No hybridization between IS2 and any of the Mu and P1 strains could be detected.     

IS1 insertion generates duplication of a nine base pair sequence at its target site.

Three independent integrations of the E. coli insertion sequence, IS1, into the gal operon have been analyzed. DNA sequences of portions of the wild-type galT gene which act as the target sites for these insertions, as well as the corresponding gal/IS1 junctions, are reported. Two features are particularly noteworthy. First, similar sequences appearing in inverted orientation consitute the ends of IS1: 18 of the terminal 23 base pairs at each end are identical. Second, in all three insertions, a 9 base pair segment found once in the wild-type sequence at the site of insertion is duplicated and appears in the same orientation at each end of the inserted element. The sequence of this 9 base pair repeat is different for each insertion analyzed. No homology between the inverted repeat sequences at the ends of IS1 and the sequences of the target sites is observed. Models for the mechanism of IS1 insertion are proposed.     

Enhancement of Escherichia Coli Plasmid and Chromosomal Recombination by the Ref Function of Bacteriophage P1

The Ref activity of phage P1 enhances recombination between two defective lacZ genes in the Escherichia coli chromosome (lac- x lac- recombination). Plasmid recombination, both lac- x lac- and tet- x tet-, was measured by transformation of recA strains, and was also assayed by measurement of beta-galactosidase. The intracellular presence of recombinant plasmids was verified directly by Southern blotting. Ref stimulated recombination of plasmids in rec+ and rec(BCD) cells by 3-6-fold, and also the low level plasmid recombination in recF cells. RecA-independent plasmid recombination, either very low level (recA cells) or high level (recB recC sbcA recA cells), was not stimulated. Ref stimulated both intramolecular and intermolecular plasmid recombination. Both normal and Ref-stimulated lac- x lac- chromosomal recombination, expected to be mostly RecBC-dependent in wild-type bacteria, were affected very little by a recF mutation. We have previously reported Ref stimulation of lac- x lac- recombination in recBC sbcB bacteria, a process known to be RecF-dependent. Chromosomal recombination processes thought to involve activated recombination substrates, e.g., Hfr conjugation, P1 transduction, were not elevated by Ref activity. We hypothesize that Ref acts by unknown mechanisms to activate plasmid and chromosomal DNA for RecA-mediated recombination, and that the structures formed are substrates for both RecF-dependent (plasmid, chromosomal) and Rec(BCD)-dependent (chromosomal) recombination pathways.     

Amplification of drug resistance genes flanked by inversely repeated IS1 elements: involvement of IS1-promoted DNA rearrangements before amplification.

Tn2653 contains one copy of the tet gene and two copies of the cat gene derived from plasmid pBR325 and is flanked by inverted repeats of IS1. Transposed onto the P1-15 prophage, it confers a chloramphenicol resistance phenotype to the Escherichia coli host. Because the prophage is perpetuated as a plasmid at about one copy per host chromosome, the host cell is still tetracycline sensitive even though P1-15 is carrying one copy of the tet gene. We isolated P1-15::Tn2653 mutants conferring a tetracycline resistance phenotype, in which the whole transposon and variable flanking P1-15 DNA segments were amplified. Amplification was most probably preceded by IS1-mediated DNA rearrangements which led to long direct repeats containing Tn2653 sequences and P1-15 DNA. Subsequent recombination events between these direct repeats led to amplification of a segment containing the tetracycline resistance gene in tandem arrays.     

Coupled and Independent Contributions of Residues in IS6 and IIS6 to Activation Gating of CaV1.2

Voltage dependence and kinetics of Ca_V1.2 activation are affected by structural changes in pore-lining S6 segments of the α₁-subunit. Significant effects are induced by either proline or threonine substitutions in the lower third of segment IIS6 (“bundle crossing region”), where S6 segments are likely to seal the channel in the closed conformation (Hohaus, A., Beyl, S., Kudrnac, M., Berjukow, S., Timin, E. N., Marksteiner, R., Maw, M. A., and Hering, S. (2005) J. Biol. Chem. 280, 38471–38477). Here we report that S435P in IS6 results in a large shift of the activation curve (-25.9 ± 1.2 mV) and slower current kinetics. Threonine substitutions at positions Leu-429 and Leu-434 induced a similar kinetic phenotype with shifted activation curves (L429T by -6.6 ± 1.2 and L434T by -12.1 ± 1.7 mV). Inactivation curves of all mutants were shifted to comparable extents as the activation curves. Interdependence of IS6 and IIS6 mutations was analyzed by means of mutant cycle analysis. Double mutations in segments IS6 and IIS6 induce either additive (L429T/I781T, -34.1 ± 1.4 mV; L434T/I781T, -40.4 ± 1.3 mV; L429T/L779T, -12.6 ± 1.3 mV; and L434T/L779T, -22.4 ± 1.3 mV) or nonadditive shifts of the activation curves along the voltage axis (S435P/I781T, -33.8 ± 1.4 mV). Mutant cycle analysis revealed energetic coupling between residues Ser-435 and Ile-781, whereas other paired mutations in segments IS6 and IIS6 had independent effects on activation gating.Ca²⁺ current through Ca_V1.2 channels initiates muscle contraction, release of hormones and neurotransmitters, and affects physiological processes such as vision, hearing, and gene expression (1). Their pore-forming α₁-subunit is composed of four homologous domains formed by six transmembrane segments (S1–S6) (2). The signal of the voltage-sensing machinery, consisting of multiple charged amino acids (located in segments S4 and adjacent structures of each domain), is transmitted to the pore region (3). Conformational changes in pore lining S6 and adjacent segments finally lead to pore openings (activation) and closures (inactivation).Our understanding of how Ca_V1.2 channels open and close is largely based on extrapolations of structural information from potassium channels. The crystal structures of the closed conformation of two bacterial potassium channels (KcsA and MlotiK) (4, 5) show a gate located at the intracellular channel mouth formed by tightly packed S6 helices. The crystal structure of the open conformation of Kv1.2 (6, 7) revealed a bent S6 with the highly conserved PXP motif apparently acting as a hinge (see 8). The activation mechanism proposed for MthK channels involves helix bending at a highly conserved glycine at position 83 (see Ref. 9, “glycine gating hinge” hypothesis).Compared with potassium channels, the pore of Ca_V is asymmetric, and none of the four S6 segments has a putative helix-bending PXP motif. Furthermore, the conserved glycine (corresponding to position 83 in MthK, see Ref. 10) is only present in segments IS6 and IIS6 (for review see Ref. 11). We have shown that substituting proline for this glycine in IIS6 of Ca_V1.2 does not significantly affect gating (12).Zhen et al. (13) investigated the pore lining S6 segments of Ca_V2.1 using the substituted cysteine accessibility method. The accessibility of cysteines was changed by opening and closing the channel, consistent with the gate being on the intracellular side. The general picture of a channel gate close to the inner channel mouth of Ca_V1.2 was recently supported by pharmacological studies (14).Substitution of hydrophilic residues in the lower third of segment IIS6 of Ca_V1.2 (LAIA motif, 779–784, see Ref. 12) induces pronounced changes in channel gating as follows: a shift in the voltage dependence of activation accompanied by a slowing of the activation kinetics near the footstep of the m_∞(V) curve and a slowing of deactivation at all potentials. Interestingly, these changes in channel gating resemble the effects of proline substitution of Gly-219 in the bacterial sodium channel from Bacillus halodurans (“Gly-219 gating hinge,” see Ref. 15).The strongest shifts of the activation curve reported so far were observed for proline substitutions (12). As prolines in an α-helix cause a rigid kink with an angle of about 26° (16), we hypothesized that these mutants were causing a kink in helix IIS6 similar to a bend that would normally occur flexibly during the activation process (12).Here we extend our previous study by systematically substituting residues in segment IS6 of Ca_V1.2 by proline or the small and polar threonine. Several functional IS6 mutants with shifted activation and inactivation characteristics were identified (S435P, L429T, and L434T), and the interdependence of IS6 and IIS6 mutations was analyzed. Mutant cycle analysis revealed both mutually independent and energetically coupled contributions of IS6 and IIS6 residues on activation gating.     

Localization of domains within the Drosophila Ref(2)P protein involved in the intracellular control of sigma rhabdovirus multiplication.

The ref(2)P gene of Drosophila melanogaster interferes with sigma rhabdovirus multiplication. This gene is highly variable, and the different alleles are considered permissive or restrictive according to their effects on virus replication. In all cases, the mechanisms involve intracellular interactions between the sigma virus and Ref(2)P proteins. We showed that the N-terminal domain of the Ref(2)P protein was required for its activity in vivo. The protein was inactive in the null p(od)2 mutant when its first 82 amino acids were deleted. The p delta n gene was constructed so that the first 91 amino acids coded for by the restrictive alleles could be expressed in vivo. It was active in a transformed line. This sequence was sufficient to impart a restrictive phenotype to an adult D. melanogaster fly after it was injected with the virus. However, the truncated protein expressed by p delta n did not have an effect on the hereditary transmission of the sigma virus to the offspring of the infected flies, even though it contained the restriction site. The native Ref(2)P protein has been previously shown to have conformation-dependent epitopes common with some of those of the viral N protein. We demonstrated the following. (i) These epitopes were found in a domain of the Ref(2)P protein distinct from the site involved in restriction. (ii) They were modified in the N protein of the haP7 sigma virus mutant selected as being adapted to the restrictive alleles of the ref(2)P gene; only one mutation in the N gene, leading to an amino acid substitution, distinguished the haP7 mutant from the original virus. (iii) The virus strains partially or totally adapted to the effects of the full restrictive protein expressed by pp were always found to multiply to a lesser extent in the presence of the protein expressed by p delta n. These data suggest that two distinct domains of the Ref(2)P protein are involved in the control of sigma virus multiplication.     

Rhodobacter capsulatus mutants lacking the Rieske FeS protein form a stable cytochrome bc1 subcomplex with an intact quinone reduction site.

The ubiquinol-cytochrome c oxidoreductase (or bc1 complex) of Rhodobacter capsulatus consists of three subunits: cytochrome b, cytochrome c1, and the Rieske iron-sulfur protein, encoded by the fbcF, fbcB, and fbcC genes, respectively. In the preceding paper [Davidson, E., Ohnishi, T., Atta-Asafo-Adjei, E., & Daldal, F. (1992) Biochemistry (preceding paper in this issue)], we have observed that the apoproteins for cytochromes b and c1 are fully present in the intracytoplasmic membrane of R. capsulatus mutants containing low amounts of, or no, Rieske apoprotein. Here we present evidence that the redox midpoint potentials of cytochromes b and c1, as well as their ability to bind antimycin and stabilize a semiquinone at the Qi site, are unaffected by the absence of the Rieske subunit. This is the first report describing a mutant containing a stable bc1 subcomplex with an intact Qi site in the chromatophore membranes, and provides further evidence that a functional quinone reduction site can be formed in the absence of a quinol oxidation (Qo) site. Additional mutants carrying fbc deletions expressing the remaining subunits of the cytochrome bc1 complex were constructed to investigate the relationship among these subunits for their stability in vivo. Western blot analysis of these mutants indicated that cytochromes b and c1 protect each other against degradation, suggesting that they form a two-protein subcomplex in the absence of the Rieske protein subunit.     

Participation of the lytic replicon in bacteriophage P1 plasmid maintenance.

P1 bacteriophage carries at least two replicons: a plasmid replicon and a viral lytic replicon. Since the isolated plasmid replicon can maintain itself stably at the low copy number characteristic of intact P1 prophage, it has been assumed that this replicon is responsible for driving prophage replication. We provide evidence that when replication from the plasmid replicon is prevented, prophage replication continues, albeit at a reduced rate. The residual plasmid replication is due to incomplete repression of the lytic replicon by the c1 immunity repressor. Incomplete repression was particularly evident in lysogens of the thermoinducible P1 c1.100 prophage, whose replication at 32 degrees C remained almost unaffected when use of the plasmid replicon was prevented. Moreover, the average plasmid copy number of P1 in a P1 c1.100 lysogen was elevated with respect to the copy number of P1 c1+. The capacity of the lytic replicon to act as an auxiliary in plasmid maintenance may contribute to the extraordinary stability of P1 plasmid prophage.     

Identification of key structural determinants of the IntI1 integron integrase that influence attC x attI1 recombination efficiency

The integron platform codes for an integrase (IntI) from the tyrosine family of recombinases that mediates recombination between a proximal double-strand recombination site, attI and a single-strand target recombination site, attC. The attI site is only recognized by its cognate integrase, while the various tested attCs sites are recombined by several different IntI integrases. We have developed a genetic system to enrich and select mutants of IntI1 that provide a higher yield of recombination in order to identify key protein structural elements important for attC × attI1 recombination. We isolated mutants with higher activity on wild type and mutant attC sites. Interestingly, three out of four characterized IntI1 mutants selected on different substrates are mutants of the conserved aspartic acid in position 161. The IntI1 model we made based on the VchIntIA 3D structure suggests that substitution at this position, which plays a central role in multimer assembly, can increase or decrease the stability of the complex and accordingly influence the rate of attI × attC recombination versus attC × attC. These results suggest that there is a balance between the specificity of the protein and the protein/protein interactions in the recombination synapse.     

The effect of mutations in the Xis-binding sites on site-specific recombination in coliphage HK022

Excisionase (Xis) is an accessory protein that is required for the excision of the related prophages lambda and HK022. Xis binds to two tandemly arranged binding sites (X1 and X2) on the P arm of the recombination sites attP and attR. Gel-retardation analyses and site-specific recombination assays were conducted on derivatives bearing site-directed mutations in the X1 and X2 sites of phage HK022. The results confirm the cooperative binding of Xis to its sites, showing that binding to X1 stimulates further binding to X2. The results also show that mutants affected in a single site are inactive in excision, whereas mutants affected in both sites, which show a complete absence of Xis binding, display significant excision activity. This restored activity is attributed to the interaction of Xis with Integrase, the protein that catalyzes the site-specific recombination reaction.     

Transition of galactosyltransferase 1 from trans-Golgi cisterna to the trans-Golgi network is signal mediated

The Golgi apparatus (GA) is the organelle where complex glycan formation takes place. In addition, it is a major sorting site for proteins destined for various subcellular compartments or for secretion. Here we investigate beta1,4-galactosyltransferase 1 (galT) and alpha2,6-sialyltransferase 1 (siaT), two trans-Golgi glycosyltransferases, with respect to their different pathways in monensin-treated cells. Upon addition of monensin galT dissociates from siaT and the GA and accumulates in swollen vesicles derived from the trans-Golgi network (TGN), as shown by colocalization with TGN46, a specific TGN marker. We analyzed various chimeric constructs of galT and siaT by confocal fluorescence microscopy and time-lapse videomicroscopy as well as Optiprep density gradient fractionation. We show that the first 13 amino acids of the cytoplasmic tail of galT are necessary for its localization to swollen vesicles induced by monensin. We also show that the monensin sensitivity resulting from the cytoplasmic tail can be conferred to siaT, which leads to the rapid accumulation of the galT-siaT chimera in swollen vesicles upon monensin treatment. On the basis of these data, we suggest that cycling between the trans-Golgi cisterna and the trans-Golgi network of galT is signal mediated.