A model for the gamma delta resolvase synaptic complex.

The serine recombinase gamma delta resolvase performs site-specific recombination in an elaborate synaptic complex containing 12 resolvase subunits and two 114-base pair res sites. Here we present an alternative structural model for the synaptic complex. Resolvase subunits in the complex contact their neighbors in equivalent ways, using three principal interactions, one of which is a newly proposed synaptic interaction. Evidence in support of this interaction is provided by mutations at the interface that either enable resolvase to synapse two copies of site I or inhibit synapsis of complete res sites. In our model, the two crossover sites are far apart, separated by the resolvase catalytic domains bound to them. Thus, recombination would require a substantial rearrangement of resolvase subunits or domains.

Architecture of the gamma delta resolvase synaptosome: oriented heterodimers identity interactions essential for synapsis and recombination.

Gammadelta resolvase catalyzes recombination within a complex nucleoprotein structure containing at least 12 resolvase subunits bound to two 114 bp res sites. The 2,3' interaction between resolvase dimers is essential for synapsis and recombination. Using oriented resolvase heterodimers, we have identified half sites of res that must be occupied by a 2,3'-proficient protomer. For synapsis, only four of the eight subunits bound to sites II and III, those at II-L and III-L, require a 2,3'-proficient interface. This 2,3' interaction, apparently between protomers bound to adjacent sites, may nucleate assembly of the core synaptic complex. For recombination, 2,3'-proficient subunits are also required at sites I-R and III-R, suggesting an important communication between the crossover site and the core of the synapse.

A formiminotransferase cyclodeaminase isoform is localized to the Golgi complex and can mediate interaction of trans-Golgi network-derived vesicles with microtubules.

A protein of 60 kDa (p60) has been identified using a quantitative in vitro vesicle-microtubule binding assay. Purified p60 induces co-sedimentation with microtubules of trans-Golgi network-derived vesicles isolated from polarized, perforated Madin-Darby canine kidney cells. Sequencing of the cDNA coding for this protein revealed that it is the chicken homologue of formiminotransferase cyclodeaminase (FTCD), a liver-specific enzyme involved in the histidine degradation pathway. Purified p60 from chicken liver has formiminotransferase activity, confirming that it is FTCD or an isoform of this enzyme. Isoforms of FTCD were identified in chicken hepatoma and HeLa cells, and immunolocalize to the region of the Golgi complex and vesicular structures in its vicinity. Furthermore, 58K, a previously identified microtubule-binding Golgi protein from rat liver (Bloom, G. S., and Brashear, T. A. (1989) J. Biol. Chem. 264, 16083-16092), is identical to FTCD. Both proteins co-purify with microtubules and co-localize with membranes of the Golgi complex. The capacity of FTCD to bind both to microtubules and Golgi-derived membranes may suggest that this protein, or one of its isoforms, might have in addition to its enzymatic activity, a second physiological function in mediating interaction of Golgi-derived membranes with microtubules.

Monofunctional domains of formiminotransferase-cyclodeaminase retain similar conformational stabilities outside the bifunctional octamer.

Each identical subunit of octameric formiminotransferase cyclodeaminase consists of a transferase and a deaminase domain connected by a short linker sequence. Both domains can be independently expressed in Escherichia coli as monofunctional dimers and show no indication of associating, suggesting that the linker mediates the only substantial interaction between the transferase and deaminase domains. To better understand the benefits arising from octamer formation, we have used equilibrium unfolding methods to examine the properties of the transferase and deaminase domains independently and within the octamer. Each isolated dimeric domain undergoes an apparent change in tertiary structure at low concentrations of urea (< 2 mol/l) which results in the concurrent loss of intrinsic fluorescence and catalytic activity. The full length octameric enzyme also undergoes inactivation and a loss of intrinsic fluorescence over this concentration range, without apparent change in secondary or quaternary structure. Between 2 and 2.5 M urea the isolated transferase and deaminase domains dissociate to monomers. However, only one of the subunit interfaces in the octamer is disrupted at this urea concentration and dissociation of the second interface occurs between 3.5 and 5 M urea. While each domain shows similar stability to denaturation within and outside of the octamer, one type of subunit interface achieves increased stability within the full length enzyme.

The two monofunctional domains of octameric formiminotransferase-cyclodeaminase exist as dimers.

Formiminotransferase-cyclodeaminase is a bifunctional enzyme arranged as a circular tetramer of dimers that exhibits the ability to efficiently channel polyglutamylated folate between catalytic sites. Through deletion mutagenesis we demonstrate that each subunit consists of an N-terminal transferase active domain and a C-terminal deaminase active domain separated by a linker sequence of minimally eight residues. The full-length enzyme and both isolated domains have been expressed as C-terminally histidine-tagged proteins. Both domains self-dimerize, providing direct evidence for the existence of two types of subunit interfaces. The results suggest that both the transferase and the deaminase activities are dependent on the formation of specific subunit interfaces. Because channeling is not observed between isolated domains, only the octamer appears able to directly transfer pentaglutamylated intermediate between active sites.

The nucleotide sequence of porcine formiminotransferase cyclodeaminase. Expression and purification from Escherichia coli.

We have isolated and characterized cDNA clones encoding the porcine liver octameric enzyme, 5-formiminotetrahydrofolate:L-glutamate N-formiminotransferase (EC 2.1.2.5)-formiminotetrahydrofolate cyclodeaminase (EC 4.3.1.4). The cDNA encodes a novel amino acid sequence of 541 residues which contains exact matches to two sequences derived by automated sequence analysis of CNBr cleavage fragments isolated from the porcine enzyme. The recombinant enzyme has been expressed as a soluble protein in Escherichia coli at levels 4-fold higher than those observed in liver, and is bifunctional, displaying both transferase and deaminase activities. With a calculated subunit molecular mass of 58,926 Da, it is similar in size to the enzyme isolated from porcine liver. Purification of the enzyme from E. coli involves chromatography on a novel polyglutamate column which might interact with the folylpolyglutamate binding site of the protein. The purified recombinant enzyme has a transferase specific activity of 39-41 units/mg/min.