A new glycoengineered insect cell line with an inducibly mammalianized protein N-glycosylation pathway.

The inability to produce recombinant glycoproteins with authentic N-glycans is a limitation of many heterologous protein expression systems. In the baculovirus-insect cell system, this limitation has been addressed by glycoengineering insect cell lines with mammalian genes encoding protein N-glycosylation functions ("glycogenes") under the transcriptional control of constitutive promoters. However, a potential problem with this approach is that the metabolic load imposed by the expression of multiple transgenes could adversely impact the growth and/or stability of glycoengineered insect cell lines. Thus, we created a new transgenic insect cell line (SfSWT-5) with an inducibly mammalianized protein N-glycosylation pathway. Expression of all six glycogenes was induced when uninfected SfSWT-5 cells were cultured in growth medium containing doxycycline. Higher levels of expression and induction were observed when SfSWT-5 cells were cultured with doxycycline and infected with a baculovirus. Interestingly, there were no major differences in the short-term growth properties of SfSWT-5 cells cultured with or without doxycycline. Furthermore, there were no major differences in the phenotypic stability of these cells after continuous culture for over 300 passages with or without doxycycline. Baculovirus-infected Sf9 and SfSWT-5 cells produced about the same amounts of a model recombinant glycoprotein, but only the latter sialylated this product and sialylation was more pronounced when the cells were treated with doxycycline. In summary, this is the first report of a lower eukaryotic system with an inducibly mammalianized protein N-glycosylation pathway and the first to examine how the presumed metabolic load imposed by multiple transgene expression impacts insect cell growth and stability.

Re-visiting the endogenous capacity for recombinant glycoprotein sialylation by baculovirus-infected Tn-4h and DpN1 cells.

It was previously reported that Tn-4h and DpN1 cells have the endogenous capacity to efficiently sialylate secreted alkaline phosphatase (SEAP) when infected with a baculovirus expression vector. In contrast, it has been found that lepidopteran insect cell lines that are more widely used as hosts for baculovirus vectors typically fail to sialylate SEAP and other recombinant glycoproteins. Thus, the N-glycan processing capabilities of Tn-4h and DpN1 cells are of potential interest to investigators using the baculovirus expression system for recombinant glycoprotein production. In this study, we experimentally re-assessed the ability of Tn-4h and DpN1 cells to sialylate SEAP with Sf9 and glyco-engineered Sf9 cells (SfSWT-1) as negative and positive controls, respectively. Our results showed that the SEAP purified from SfSWT-1 cells was strongly sialylated and initially indicated that the SEAP purified from Tn-4h cells was weakly sialylated. However, further analyses suggested that the SEAP produced by Tn-4h cells only appeared to be sialylated because it was contaminated with an electrophoretically indistinguishable sialoglycoprotein derived from fetal bovine serum. We subsequently expressed, purified, and analyzed a second recombinant glycoprotein (GST-SfManI) from all four cell lines and found that only the SfSWT-1 cells were able to detectably sialylate this product. Together, these results showed that neither Tn-4h nor DpN1 cells efficiently sialylated SEAP or GST-SfManI when infected by baculovirus expression vectors. Furthermore, they suggested that previous reports of efficient SEAP sialylation by Tn-4h and DpN1 cells probably reflect contamination with a sialylated, co-migrating glycoprotein, perhaps bovine fetuin, derived from the serum used in the insect cell growth medium.

Purification and characterization of a recombinant rat prohaptoglobin expressed in baculovirus-infected Sf9 insect cells.

To generate hemoglobin-free full-length haptoglobin the cDNA encoding rat haptoglobin alphabeta subunits was cloned into shuttle vector pVT-Bac-His and used to produce a recombinant baculovirus Autographa californica Nuclear Polyhedrosis Virus (AcNPV) as an expression vector, named HpAcNPV. Recombinant virus was used to infect Spodoptera frugiperda (Sf9) insect cells. The 50 kDa protein expressed was mostly secreted into the culture medium at relatively high titer (15 microg/mL) and was found to be rat prohaptoglobin having a vector-derived N-terminal extension of 37 amino acids, containing both a hexahistidine tag and an enterokinase recognition sequence. The protein was successfully purified by a three step procedure including nickel-linked agarose and DEAE-Sepharose chromatography steps. Hemoglobin was not detected in the purified preparations. Purified recombinant rat prohaptoglobin protein was also found to be glycosylated, and to be capable of forming a complex with rat hemoglobin in vitro.

Formation of an antiparallel, intermolecular coiled coil is associated with in vivo dimerization of osmosensor and osmoprotectant transporter ProP in Escherichia coli.

Membrane transporter ProP from Escherichia coli senses extracellular osmolality and responds by mediating the uptake of osmoprotectants such as glycine betaine when osmolality is high. Earlier EPR and NMR studies showed that a peptide replica of the cytoplasmic ProP carboxyl terminus (residues D468-R497) forms a homodimeric, antiparallel, alpha-helical coiled coil in vitro stabilized by electrostatic interactions involving R488. Amino acid replacement R488I disrupted coiled-coil formation by the ProP peptide, elevated the osmolality at which ProP became active, and rendered the osmolality response of ProP transient. In the present study, either E480 or K473 was replaced with cysteine (Cys) in ProP, a Cys-less, fully functional, histidine-tagged ProP variant, to use Cys-specific cross-linking approaches to determine if antiparallel coiled-coil formation and dimerization of the intact protein occur in vivo. The Cys at positions 480 would be closer in an antiparallel dimer than those at positions 473. These replacements did not disrupt coiled-coil formation by the ProP peptide. Partial homodimerization of variant ProP-E480C could be demonstrated in vivo and in membrane preparations via Cys-specific cross-linking with dithiobis(maleimidoethane) or by Cys oxidation to cystine by copper phenanthroline. In contrast, these reagents did not cross-link ProP with Cys at position 133 or 241. Cross-linking of ProP with Cys at position 473 was limited and occurred only if ProP was overexpressed, consistent with an antiparallel orientation of the coiled coil in the intact protein in vivo. Although replacement E480C did not alter transporter activity, replacement K473C reduced the extent and elevated the threshold for osmotic activation. K473 may play a role in ProP structure and function that is not reflected in altered coiled-coil formation by the corresponding peptide. Substitution R488I affected the activities of ProP-(His)(6), ProP-E480C, and ProP-K473C as it affected the activity of ProP. Surprisingly, it did not eliminate cross-linking of Cys at position 480, and it elevated cross-linking at position 473, even when ProP was expressed at physiological levels. This suggested that the R488I substitution may have changed the relative orientation of the C-termini within the dimeric protein from antiparallel to parallel, resulting in only transient osmotic activation. These results suggest that ProP is in monomer-dimer equilibrium in vivo. Dimerization may be mediated by C-terminal coiled-coil formation and/or by interactions between other structural domains, which in turn facilitate C-terminal coiled-coil formation. Antiparallel coiled-coil formation is required for activation of ProP at low osmolality.

A structural model for the osmosensor, transporter, and osmoregulator ProP of Escherichia coli.

Transporter ProP of Escherichia coli, a member of the major facilitator superfamily (MFS), acts as an osmosensor and an osmoregulator in cells and after purification and reconstitution in proteoliposomes. H(+)-osmoprotectant symport via ProP is activated when medium osmolality is elevated with membrane impermeant osmolytes. The three-dimensional structure of ProP was modeled with the crystal structure of MFS member GlpT as a template. This GlpT structure represents the inward (or cytoplasm)-facing conformation predicted by the alternating access model for transport. LacZ-PhoA fusion analysis and site-directed fluorescence labeling substantiated the membrane topology and orientation predicted by this model and most hydropathy analyses. The model predicts the presence of a proton pathway within the N-terminal six-helix bundle of ProP (as opposed to the corresponding pathway found within the C-terminal helix bundle of its paralogue, LacY). Replacement of residues within the N-terminal helix bundle impaired the osmotic activation of ProP, providing the first indication that residues outside the C-terminal domain are involved in osmosensing. Some residues that were accessible from the periplasmic side, as predicted by the structural model, were more susceptible to covalent labeling in permeabilized membrane fractions than in intact bacteria. These residues may be accessible from the cytoplasmic side in structures not represented by our current model, or their limited exposure in vivo may reflect constraints on transporter structure that are related to its osmosensory mechanism.

Detection of alpha-helical coiled-coil dimer formation by spin-labeled synthetic peptides: a model parallel coiled-coil peptide and the antiparallel coiled coil formed by a replica of the ProP C-terminus.

Electron paramagnetic resonance spectroscopy was used to determine relative peptide orientation within homodimeric, alpha-helical coiled-coil structures. Introduction of cysteine (Cys) residues into peptides/proteins for spin labeling allows detection of their oligomerization from exchange broadening or dipolar interactions between residues within 25 A of each other. Two synthetic peptides containing Cys substitutions were used: a 35-residue model peptide and the 30-residue ProP peptide. The model peptide is known to form a stable, parallel homodimeric coiled coil, which is partially destabilized by Cys substitutions at heptad a and d positions (peptides C30a and C33d). The ProP peptide, a 30-residue synthetic peptide, corresponds to residues 468-497 of osmoregulatory transporter ProP from Escherichia coli. It forms a relatively unstable, homodimeric coiled coil that is predicted to be antiparallel in orientation. Cys was introduced in heptad g positions of the ProP peptide, near the N-terminus (K473C, creating peptide C473g) or closer to the center of the sequence (E480C, creating peptide C480g). In contrast to the destabilizing effect of Cys substitution at the core heptad a or d positions of model peptides C30a and C33d, circular dichroism spectroscopy showed that Cys substitutions at the heptad g positions of the ProP peptide had little or no effect on coiled-coil stability. Thermal denaturation analysis showed that spin labeling increased the stability of the coiled coil for all peptides. Strong exchange broadening was detected for both C30a and C33d, in agreement with a parallel structure. EPR spectra of C480g had a large hyperfine splitting of about 90 G, indicative of strong dipole-dipole interactions and a distance between spin-labeled residues of less than 9 A. Spin-spin interactions were much weaker for C473g. These results supported the hypothesis that the ProP peptide primarily formed an antiparallel coiled coil, since formation of a parallel dimer should result in similar spin-spin interactions for the spin-labeled Cys at both sites.

Creation of a fully functional cysteine-less variant of osmosensor and proton-osmoprotectant symporter ProP from Escherichia coli and its application to assess the transporter's membrane orientation.

Transporter ProP of Escherichia coli is an osmosensor and an osmoprotectant transporter. Previous results suggest that medium osmolality determines the proportions of ProP in active and inactive conformations. A cysteine-less (Cys-less) variant was created and characterized as a basis for structural and functional analyses based on site-directed Cys substitution and chemical labeling of ProP. Parameters describing the osmosensory and osmoprotectant transport activities of Cys-less ProP-(His)(6) variants were examined, including the threshold for osmotic activation and the absolute transporter activity at high osmolality (in both cells and proteoliposomes), the dependence of K(M) and V(max) for proline uptake on osmolality, and the rate constant for transporter activation in response to an osmotic upshift (in cells only). Variant ProP-(His)(6)-C112A-C133A-C264V-C367A (designated ProP) retained similar activities to ProP-(His)(6) in both cells and proteoliposomes. The bulky Val residue was favored over Ala or Ser at position 264, whereas Val strongly impaired function when placed at position 367, highlighting the importance of residues at those positions for osmosensing. In the ProP* background, variants with a single Cys residue at positions 112, 133, 241, 264, 293, or 367 retained full function. The native Cys at positions 112, 133, 264, and 367, predicted to be within transmembrane segments of ProP, were poorly reactive with membrane-impermeant thiol reagents. The reactivities of Cys at positions 241 and 293 were consistent with exposure of those residues on the cytoplasmic and periplasmic surfaces of the cytoplasmic membrane, respectively. These observations are consistent with the topology and orientation of ProP predicted by hydropathy analysis.