Efficient immunization of rhesus macaques with an HCV candidate vaccine by heterologous priming-boosting with novel adenoviral vectors based on different serotypes.

Efficient vaccination against viral agents requires a strong T-cell-mediated immune response to clear viral-infected cells. Optimal vaccination can be achieved by administration of recombinant viral vectors encoding phatogen antigens. Adenoviral vectors have attracted considerable attention as potential viral vectors for genetic vaccination owing to their favorable safety profile and potent transduction efficiency following intramuscular injection. However, the neutralizing antibody response against adenoviral capsid proteins following adenoviral vectors injection limits the success of vaccination protocols based on multiple administrations of the same adenoviral serotype. In this work, we describe efficient immunization of rhesus macaques, the preferred model for preclinical assessment, with an HCV candidate vaccine by heterologous priming-boosting with adenoviral vectors based on different serotypes. The induced responses are broad and show significant cross-strain reactivity. Boosting can be delayed for over 2 years after priming, indicating that there is long-term maintenance of resting memory cells.

Characteristics of the adeno-associated virus preintegration site in human chromosome 19: open chromatin conformation and transcription-competent environment.

Adeno-associated virus (AAV) establishes latency in infected cells by integrating into the cellular genome, with a high preference for a unique region, called AAVS1, of the human chromosome 19. The AAV proteins Rep78 and -68 are postulated to initiate the site-specific integration process by binding to a Rep binding site (RBS) in AAVS1. We provide further evidence to corroborate this model by demonstrating that the AAVS1 RBS in human cell lines is located near a DNase I hypersensitive "open" chromatin region and therefore is potentially easily accessible to Rep proteins. This open conformation is maintained in transgenic rats which carry an AAVS1 3. 5-kb DNA fragment and are proficient for Rep-mediated site-specific integration. Interestingly, the core of the DNAse I hypersensitive site in AAVS1 corresponds to a sequence displaying transcriptional enhancer-like properties, suggesting that AAVS1 constitutes a transcription-competent environment. The implications of our findings for AAV physiology and gene therapy are discussed.

The receptor super-antagonist Sant7.

Interleukin-6 (IL-6) plays a central role in the pathogenesis of multiple myeloma, acting both as a growth and a survival factor for myeloma cells. IL-6 has been recently shown to possess three topologically distinct receptor binding sites: site 1 for binding to the subunit specific chain IL-6R alpha and sites 2 and 3 for the interaction with two separate subunits of the signalling chain gp130. We have generated a set of IL-6 receptor antagonists carrying substitutions that abolish interaction with gp130 at either site 2 alone (site 2 antagonist) or at both sites 2 and 3 (site 2+3 antagonist). In addition, substitutions were introduced at site 1 that increased affinity for IL-6R alpha. When tested as growth inhibitors on a representative set of IL-6-dependent human myeloma cell lines (XG-1, XG-2, XG-4 and XG-6), although site 2 antagonists were effective on 3 out of 4 of the cell lines, only the site 2+3 antagonist Sant7 showed full antagonism on the entire spectrum of cells tested. Moreover, IL-6 receptor antagonists were also pro-apoptotic factors for myeloma cells. Their capacity to induce cell death was directly related to the impairment of binding to gp130 and to their ability to fully block intracellular signalling. In fact, the most potent inducer of apoptosis was again Sant7, which also counteracted the protective autocrine effect excercised by the endogenously produced IL-6. On the basis of these results we propose the super-antagonist Sant7 as a possible candidate for the immunotherapy of multiple myeloma.

Human interleukin-6 receptor super-antagonists with high potency and wide spectrum on multiple myeloma cells.

Interleukin-6 (IL-6) is the major growth factor for myeloma cells and is believed to participate in the pathogenesis of chronic autoimmune diseases and postmenopausal osteoporosis. IL-6 has been recently shown to possess three topologically distinct receptor binding sites: site 1 for binding to the subunit specific chain IL-6R alpha and sites 2 and 3 for the interaction with two subunits of the signaling chain gp130. We have generated a set of IL-6 variants that behave as potent cytokine receptor super-antagonists carrying substitutions that abolish interaction with gp130 at either site 2 alone (site 2 antagonist) or at both sites 2 and 3 (site 2 + 3 antagonist). In addition, substitutions have been introduced in site 1 that lead to variable increases in binding for IL-6R alpha up to 70-fold. IL-6 super-antagonists inhibit wild-type cytokine activity with efficacy proportional to the increase in receptor binding on a variety of human call lines of different origin, and the most potent molecules display full antagonism at low molar excess to wild-type IL-6. When tested on a representative set of IL-6-dependent human myeloma cell lines, although site 2 super-antagonists were in general quite effective, only the site 2 + 3 antagonist Sant7 showed antagonism on the full spectrum of cells tested. In conclusion, IL-6 super-antagonists are a useful tool for the study of myeloma in vitro and might constitute, in particular Sant7, effective IL-6 blocking agents in vivo.

Monovalent phage display of human interleukin (hIL)-6: selection of superbinder variants from a complex molecular repertoire in the hIL-6 D-helix.

Phage display of proteins can be used to study ligand-receptor interaction and for the affinity-maturation of binding sites in polypeptide hormones and/or cytokines. We have expressed human interleukin-6 (hIL-6) on M13 phage in a monovalent fashion as a fusion protein with the phage coat protein, pIII. Phage-displayed hIL-6 is correctly folded, as judged by its ability to interact with conformation-specific anti-hIL-6 monoclonal antibodies (mAb) and with the hIL-6 receptor complex in vitro. We set up an experimental protocol for the efficient affinity selection of hIL-6 phage using the extracellular portion of the hIL-6 receptor alpha (hIL-6R alpha) fixed on a solid phase. This system was used to affinity-purify from a library of hIL-6 variants, in which four residues in the predicted D-helix of the cytokine were fully randomized, mutants binding hIL-6R alpha with higher efficiency than the wild type. When the best-binder variant Q175I/Q183A was combined with a previously identified superbinder S176R [Savino et al., Proc. Natl. Acad. Sci. 90 (1993) 4067-4071], a triple-substitution mutant Q175I/S176R/Q183A (hIL-6IRA) was obtained with a fivefold increased hIL-6R alpha binding and a 2.5-fold enhanced biological activity.

Production and structural characterization of amino terminally histidine tagged human oncostatin M in E. coli.

Oncostatin M is a cytokine that acts as a growth regulator on a wide variety of cells and has diverse biological activities including acute phase protein induction, LDL receptor up-regulation and cell-specific gene expression. In order to gather information about the Onc M structure, we established a protocol for large scale production and single step purification of this functional cytokine from bacterial cells. The cDNA of human Onc M was cloned by RT-PCR from total RNA of PMA induced U937 cells. After the addition of a six histidine tag at the N-terminus, the coding region of mature Onc M was cloned in the pT7.7 expression vector. Histidine tagged Onc M was overexpressed in bacterial cells and purified to homogeneity in one step on a metal chelating column. We found that recombinant 6xHis-OncM remains fully active in a growth inhibition assay. Structural characterization of the purified protein was performed by electrospray mass spectrometry, automated Edman degradation and peptide mapping by high-pressure liquid chromatography/fast-atom-bombardment mass spectrometry. Thermal and pH stability dependence of Onc M was assessed by circular dichroism spectroscopy; the helical content is about 50%, in agreement with the four helix bundle fold postulated for cytokines that bind haematopoietic receptors of type I.

Oncostatin M binds directly to gp130 and behaves as interleukin-6 antagonist on a cell line expressing gp130 but lacking functional oncostatin M receptors.

Oncostatin M (OM) and interleukin 6 (IL-6) are functionally related cytokines, which trigger similar biological responses because they share gp130 as a common signal transducing transmembrane receptor. While IL-6 recruits gp130 only upon binding to its specific receptor subunit (IL-6R alpha), reconstitution and cross-linking experiments on cell membranes suggest that OM can directly interact with gp130 and that this interaction is necessary but not sufficient to stimulate cells. However, the issue of the direct binding between gp130 and OM, in the absence of any additional membrane component, remained essentially unclarified. In this paper we show that, uniquely among the family of cytokines that transduce through gp130, OM directly binds in vitro with a 10(-8) M affinity sgp130, a soluble form of gp130. Moreover, titration of sgp130 with OM inhibits the formation of a ternary complex comprising IL-6, sIL-6R alpha, and sgp130. These in vitro properties of OM are consistent with the additional finding that on human hepatoma Hep3B cells, which express gp130 but not functional OM receptors, OM does not mimic IL-6 activity, but rather behaves, at high doses, as an IL-6 antagonist.

Generation of interleukin-6 receptor antagonists by molecular-modeling guided mutagenesis of residues important for gp130 activation.

Interleukin-6 (IL-6) drives the sequential assembly of a receptor complex formed by the IL-6 receptor (IL-6R alpha) and the signal transducing subunit, gp130. A model of human IL-6 (hIL-6) was constructed by homology using the structure of bovine granulocyte colony stimulating factor. The modeled cytokine was predicted to interact sequentially with the cytokine binding domains of IL-6R alpha and gp130 bridging them in a way similar to that of the interaction between growth hormone and its homodimeric receptor. Several residues on helices A and C which were predicted as contact points between IL-6 and gp130 and therefore essential for IL-6 signal transduction, were subjected to site-directed mutagenesis individually or in combined form. Interestingly, while single amino acid changes never produced major alterations in IL-6 bioactivity, a subset of double mutants of Y31 and G35 showed a considerable reduction of biological activity and were selectively impaired from associating with gp130 in binding assays in vitro, while they maintained wild-type affinity towards hIL-6-R alpha. More importantly, we demonstrated the antagonistic effect of mutant Y31D/G35F versus wild-type IL-6.

The uvp1 gene of plasmid pR cooperates with mucAB genes in the DNA repair process.

We show that a DNA fragment that contains the uvp1 gene of the plasmid pR directs the synthesis in Escherichia coli minicells of a protein of apparent molecular weight 20 kDa. Inspection of the nucleotide sequence of the region reveals an open reading frame that has the capacity to encode a protein of 198 amino acids. The uvp1 gene product has been found, in two different systems, to enhance the recombinational activity of E. coli cells. We have also observed a striking similarity to resolvase and invertase proteins. The significance of this finding for the function of the uvp1 gene product requires further investigation. We conclude that the uvp1 gene encodes a 20 kDa protein which appears to be responsible for enhancement of both UV survival and recombinational activity in E. coli.

Cellular response to DNA damage is enhanced by the pR plasmid in mouse cells and in Escherichia coli.

The pR plasmid, which enhances the survival of Escherichia coli C600 exposed to UV light by induction of the SOS regulatory mechanism, showed the same effect when it transformed mouse LTA cells (tk-, aprt-). With Tn5 insertion mutagenesis which inactivates UV functions in the pR plasmid, we recognized two different regions of the plasmid, uvp1 and uvp2. These pR UVR- mutants exhibited the same effect in LTA transformed cells, demonstrating that resistance to UV light, carried by the pR plasmid, was really due to the expression of these two regions, which were also in the mouse cells. Statistical analysis showed that the expression of the uvp1 and uvp2 regions significantly increased (P less than 0.01) the survival upon exposure to UV light in mouse cells and bacteria. These results might suggest the presence of an inducible repair response to DNA damage in mouse LTA cells.