A bipartite system for the constitutive and inducible expression of high levels of foreign proteins in plants

We have developed combined transgene/virus vector systems for the expression of heterologous proteins in plants. The systems are based on the bipartite RNA plant virus, cowpea mosaic virus (CPMV), and involve the amplification of integrated copies of either full-length or deleted versions of RNA-2 carrying a foreign gene. In the case of plants transgenic for full-length versions of RNA-2 carrying the green fluorescent protein (GFP), amplification can be achieved by supplying RNA-1 either exogenously or by crossing. This allows either inducible or constitutive expression of the foreign gene and results in an infection that can be passaged to further plants. Replication of deleted versions of RNA-2 harbouring GFP requires the presence of both RNA-1 and a suppressor of gene silencing, a function which we show can be supplied by HcPro from potato virus Y. Replication of the deleted versions of RNA-2 can be achieved by supplying the suppressor and RNA-1 either exogenously or by crossing, showing that this system can also be used in an inducible and constitutive format. The use of deleted forms of RNA-2 has the advantage that no infectious virus is produced, providing an effective method of biocontainment. The CPMV-based systems have advantages over existing plant expression systems in terms of the expression levels obtainable and the simplicity and flexibility of use, and should be of great practical benefit in the development of plants as bioreactors.     

Use of virus vectors for the expression in plants of active full-length and single chain anti-coronavirus antibodies

To extend the potential of antibodies and their derivatives to provide passive protection against enteric infections when supplied orally in crude plant extracts, we have expressed both a small immune protein (SIP) and a full-length antibody in plants using two different plant virus vectors based on potato virus X (PVX) and cowpea mosaic virus (CPMV). The alphaSIP molecule consisted of a single chain antibody (scFv) specific for the porcine coronavirus, transmissible gastroenteritis virus (TGEV) linked to the alpha-CH3 domain from human IgA. To express the full-length IgA, the individual light and heavy chains from the TGEV-specific mAb 6A.C3 were inserted into separate PVX constructs and plants were co-infected with both constructs. Western blot analysis revealed the efficient expression of both the SIP and IgA molecules. Analysis of crude plant extracts revealed that both the plant-expressed alphaSIP and IgA molecules could bind to and neutralize TGEV in tissue culture, indicating that active molecules were produced. Oral administration of crude extracts from antibody-expressing plant tissue to 2-day-old piglets showed that both the alphaSIP and full-length IgA molecules can provide in vivo protection against TGEV.     

Generation of full-length cDNA recombinant vectors for the transient expression of human fibronectin in mammalian cell lines

In order to study the roles of the different alternatively spliced variants of human fibronectin (FN) as well as of its binding sites and structural domains in the processes of extracellular matrix assembly, cell adhesion, and cell migration, we constructed expression vectors coding for different human full-length FN polypeptides and deleted versions of these constructs. We expressed them transiently in mammalian cells by calcium phosphate transfection and microinjection techniques. While the deleted recombinants were expressed by both transfection and microinjection, the full-length recombinants could be only expressed by microinjection. Calcium phosphate transfection leads to the accumulation of recombinant FN in cytoplasmic vesicles of both matrix-forming and nonforming cells. On the contrary, microinjection leads to the accumulation of recombinant FN in cytoplasmic vesicles in cells that do not form a matrix, but to the rapid incorporation into the extracellular matrix of matrix-forming cells in addition to a cytoplasmic localization. Identical results were obtained when the FN signal and propeptides were replaced by those of E-cadherin.     

Rapid transient production in plants by replicating and non-replicating vectors yields high quality functional anti-HIV antibody

Background

The capacity of plants and plant cells to produce large amounts of recombinant protein has been well established. Due to advantages in terms of speed and yield, attention has recently turned towards the use of transient expression systems, including viral vectors, to produce proteins of pharmaceutical interest in plants. However, the effects of such high level expression from viral vectors and concomitant effects on host cells may affect the quality of the recombinant product.

Methodology/Principal Findings

To assess the quality of antibodies transiently expressed to high levels in plants, we have expressed and characterised the human anti-HIV monoclonal antibody, 2G12, using both replicating and non-replicating systems based on deleted versions of Cowpea mosaic virus (CPMV) RNA-2. The highest yield (approximately 100 mg/kg wet weight leaf tissue) of affinity purified 2G12 was obtained when the non-replicating CPMV-HT system was used and the antibody was retained in the endoplasmic reticulum (ER). Glycan analysis by mass-spectrometry showed that the glycosylation pattern was determined exclusively by whether the antibody was retained in the ER and did not depend on whether a replicating or non-replicating system was used. Characterisation of the binding and neutralisation properties of all the purified 2G12 variants from plants showed that these were generally similar to those of the Chinese hamster ovary (CHO) cell-produced 2G12.

Conclusions

Overall, the results demonstrate that replicating and non-replicating CPMV-based vectors are able to direct the production of a recombinant IgG similar in activity to the CHO-produced control. Thus, a complex recombinant protein was produced with no apparent effect on its biochemical properties using either high-level expression or viral replication. The speed with which a recombinant pharmaceutical with excellent biochemical characteristics can be produced transiently in plants makes CPMV-based expression vectors an attractive option for biopharmaceutical development and production.     

植物抗逆蛋白（LEA3）22-氨基酸耐盐结构域在酵母细胞中的鉴定

大豆PM2蛋白属LEA3 （late embryogenesis abundant 3）蛋白。本文构建了编码PM2全长及含22-氨基酸结构域多肽（PM2、PM2A、PM2B和 PM2C）的酵母表达载体。转化酵母得到四种重组菌。SDS-PAGE电泳和ESI-MS/MS或MALDI-TOF/TOF质谱结果表明,重组菌可表达目标多肽。测定对照菌及重组菌在无胁迫、高盐（1.5 mol·L^-1 NaCl）和高渗透（2 mol·L^-1山梨糖）下的生长曲线。结果表明,在高盐胁迫下,四种重组菌胁迫后的恢复明显好于对照菌。多肽对高盐耐受能力的大小为:PM2C>PM2B≈PM2A≈PM2。证明大豆PM2蛋白的表达可提高酵母耐盐性,且22-氨基酸基序为PM2蛋白的耐盐结构域。结合前文在大肠杆菌中的结果,为“LEA蛋白可以类似机制参与原核和真核生物耐盐保护作用”的假说提供实验支持。然而,在高山梨糖胁迫下,对照菌和酵母重组菌的生长情况无明显差异。     

An unusual case of Waldenstr?m macroglobulinemia with half molecules of IgG in serum and urine

Immunochemical studies are described in an unusual case of Waldenstr?m's macroglobulinemia. Two monoclonal Igs (whole IgG1/kappa and IgG1/kappa half molecules) occurred in the serum in addition to the IgM monoclonal protein. Protein electrophoresis of the serum showed a monoclonal component in the gamma region, and the immunoelectrophoresis allowed detection of a monoclonal IgM/kappa and another abnormality represented by a double precipitin line in serum and urine, observed when antiserum anti IgG was used. The abnormal proteins were purified and further analyzed. The IgG-related proteins were whole four chains IgG monoclonal molecules, 1/2 IgG monoclonal molecules, composed of one heavy and one light chain, and residual polyclonal IgG. The half molecules were antigenically deficient with respect to normal IgG. The idiotypic analysis showed that the three monoclonal proteins shared idiotypic determinants. This patient had clinical and morphological findings of Waldenstr?m's macroglobulinemia and, as observed in other cases, the formation of half molecules was not associated with a distinct clinical syndrome.     

Electrophoretic properties of human IgG and its subclasses on sodium dodecyl-sulfate-polyacrylamide gel electrophoresis and immunoblots

Unreduced human immunoglobulin G (IgG) which was not aggregated showed anomalous apparent molecular masses on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). It migrated mainly as three distinct bands with apparent molecular masses from 190 to 240 kDa on gels containing 8% polyacrylamide, when denatured at 37 degrees C. Generation of this banding pattern has two reasons: (a) the pattern is a superposition of bands originating from the four IgG subclasses that differ in molecular masses and structures; and (b) the complexity of the band pattern is further increased, because IgG myeloma proteins of the IgG1 and IgG2 subclass migrated as doublets, while IgG3 and IgG4 formed primarily one band with slightly different apparent molecular masses. These properties were independent of the type of light chain in all myeloma proteins studied. Generation of doublets suggests heterogeneities of monoclonal proteins. The two separable protein populations from IgG1 differ in their susceptibility to reduction. Reduction at 37 degrees C cleaved the larger into heavy and light chain, while it generated heavy chain dimer and light chain from the smaller species. Hence, it is possible that monoclonal IgG1 are comprised of at least two subpopulations of molecules with different S-S bonds. Doublet formation of IgG2 remains unexplained, since both species were equally sensitive to reduction. Knowledge on the anomalous properties of IgG on SDS-PAGE is a prerequisite to run immunoblots from unreduced cellular antigens without confounding cell-associated IgG with cellular antigens.     

Human interleukin 10 receptor 1/IgG1-Fc fusion proteins: immunoadhesins for human IL-10 with therapeutic potential

Interleukin 10 (IL-10) is produced by various types of human cancer, including malignant melanoma, and plays an important role in negative regulation of cell-mediated immune responses against tumors. We have developed chimeric molecules (immunoadhesins), combining the extracellular domain of human interleukin 10 receptor 1 (IL-10R1) with the Fc regions of human IgG1 heavy chain and investigated their capability of blocking the biological activities of human IL-10. Monomeric and dimeric immunoadhesins (IL-10R1/IgG1) constructs were tested for capturing human IL-10 and blocking its biological activities. Plasmid vectors that contained the IL-10 immunoadhesin constructs were directly transfected into human melanoma cell lines. Transfection of plasmid vectors into melanoma cell lines resulted in capturing of exogenously added as well as endogeneously produced IL-10. The supernatants obtained from an IL-10 non-producing melanoma cell line transfected with monomeric IL-10 immunoadhesin plasmids most efficiently captured exogenously added IL-10, compared to those obtained with the dimeric IL-10R1/IgG1 plasmid vector. Transfection of IL-10-producing melanoma cells with the monomeric IL-10 immunoadhesin plasmids totally captured endogenously produced IL-10 and enhanced T cell responses against allogeneic melanoma cells. Furthermore, purified monomeric IL-10 immunoadhesin protein showed IL-10 capturing efficacy compatible with that of IL-10-specific monoclonal antibodies. Collectively, these studies indicate that IL-10 immunoadhesins, especially in monomeric form, are potent inhibitors of biological activities of IL-10 and suggest that these molecules, alone or in conjunctions with other immunotherapeutic approaches, can be utilized for the immuno-targeting of IL-10 producing tumors. M. Terai and Y. Tamura contributed equally to this work. Yutaka Tamura and Eiko Otsuka are listed as inventors in the pending patent application for IL-10 Immunoadhesins (PCT/JP2004/013090).     

Fiber and penton base capsid modifications yield diminished adenovirus type 5 transduction and proinflammatory gene expression with retention of antigen-specific humoral immunity

Fiber and penton base capsid proteins of adenovirus type 5 (Ad5) mediate a well-characterized two-step entry pathway in permissive tissue culture cell lines. Fiber binds with high affinity to the cell surface coxsackievirus-and-adenovirus receptor (CAR), and penton base facilitates viral internalization by binding alphav integrins through an RGD motif. In vivo, the entry pathway is complicated by interactions of capsid proteins with additional cell surface molecules and blood factors. When administered systemically in mice, adenovirus vectors (Adv) localize primarily to hepatic tissue, resulting in efficient gene transduction and potent activation of the host antiviral immune response. The goal of the present study was to detarget Adv uptake through fiber and penton base capsid protein manipulations and determine how detargeted vectors influence transduction efficiency, inflammatory activation, and activation of the adaptive arm of the immune system. By manipulating fiber and the penton base, we have generated highly detargeted vectors (up to 1,200-fold reduction in transgene expression in vivo) with reduced macrophage stimulatory activity in vitro and in vivo. In spite of the diminished transduction and macrophage activation, the detargeted vectors induce strong neutralizing immunity as well as efficient antitransgene antibody. Three of the modified vectors produce antitransgene humoral immunity at levels that exceed or are equal to that seen with an unmodified Ad5-based vector. The fiber-pseudotyped and penton base constructs with RGD deleted have attributes that could be important enhancements in a number of vaccine applications.     

A satellite RNA of arabis mosaic nepovirus and its pathological impact

Three RNA species were encapsidated in arabis mosaic nepovirus from lilac (ArMV-L): the two genomic RNAs, RNA-1 and -2, and an RNA-3, Mr. 0.4 × 10⁶. The genomic RNAs from ArMV-L separated by gel electrophoresis from RNA-3 were infectious and, during ten passages of this isolate (ArMV-SF) RNA-3 was not produced; only RNA-1 and RNA-2. When inoculated with the genomic species of ArMV-L, or with those of other ArMV isolates, RNA-3 replicated but did not do so in the absence of RNA-1 and RNA-2. The RNA-3 did not share extensive regions of nucleotide sequences with the genomic RNAs but, like them, was polyadenylated and was linked to a protein (VPg) which did not seem essential for replication. When the pathogenicity of ArMV-L and ArMV-SF was compared in 42 plant species/cultivars representing 36 genera and 14 families, the following differences were observed: in three species of legume, disease progressed more rapidly when RNA-3 was present but in species from five families, the presence of RNA-3 was correlated with symptom amelioration. When RNA-3 was present, the amounts of ELISA detected antigen were not consistently different in tip leaves of Nicotiana megalosiphon, Chenopodium amaranticolor, C. quinoa or Pisum sativum from those in leaves where RNA-3 was absent.     

Activity-dependent heteromerization of the hyperpolarization-activated, cyclic-nucleotide gated (HCN) channels: role of N-linked glycosylation

Formation of heteromeric complexes of ion channels via co-assembly of different subunit isoforms provides an important mechanism for enhanced channel diversity. We have previously demonstrated co-association of the hyperpolarization activated cyclic-nucleotide gated (HCN1/HCN2) channel isoforms that was regulated by network (seizure) activity in developing hippocampus. However, the mechanisms that underlie this augmented expression of heteromeric complexes have remained unknown. Glycosylation of the HCN channels has been implicated in the stabilization and membrane expression of heteromeric HCN1/HCN2 constructs in heterologous systems. Therefore, we used in vivo and in vitro systems to test the hypothesis that activity modifies HCN1/HCN2 heteromerization in neurons by modulating the glycosylation state of the channel molecules. Seizure-like activity (SA) increased HCN1/HCN2 heteromerization in hippocampus in vivo as well as in hippocampal organotypic slice cultures. This activity increased the abundance of glycosylated HCN1 but not HCN2-channel molecules. In addition, glycosylated HCN1 channels were preferentially co-immunoprecipitated with the HCN2 isoforms. Provoking SA in vitro in the presence of the N-linked glycosylation blocker tunicamycin abrogated the activity-dependent increase of HCN1/HCN2 heteromerization. Thus, hippocampal HCN1 molecules have a significantly higher probability of being glycosylated after SA, and this might promote a stable heteromerization with HCN2.     

Arginine kinase isoforms in the closest protozoan relative of metazoans

The genome of the choanoflagellate Monosiga brevicollis contains at least three genes for the phosphoryl transfer enzyme, arginine kinase (AK; EC 2.7.3.3). Bioinformatic analyses of the deduced amino acid sequences of the proteins coded for by two of these genes showed that one of these AKs is cytoplasmic (denoted AK1) while the other appears to have an N-terminal mitochondrial targeting peptide (denoted AK2). Cloning and expression of the cDNA for AK1 yielded considerable soluble AK activity. Three AK2 constructs were expressed - one corresponding to the full length protein and two corresponding to truncated versions in which the signal peptide had been deleted. Expression of the former construct yielded minimal soluble activity. In contrast, significant AK activity was found in both truncated constructs confirming the importance of removal of the targeting peptide for proper folding and catalytic activity. Both AK1 and AK2 are functional oligomers unlike typical AKs which are monomeric. A phylogenetic analysis showed that these choanoflagellate AKs group more closely with a supercluster consisting of cytoplasmic and mitochondrial CKs and invertebrate AKs that evolved secondarily from a CK-like ancestor. Reaction-diffusion constraints in choanoflagellates are likely mitigated by the presence of AK isoforms which facilitate energy transport in these highly polarized cells.     

Contributions of the brome mosaic virus RNA-3 3'-nontranslated region to replication and translation.

Sequences upstream of the 3'-terminal tRNA-like structure of brome mosaic virus RNAs have been predicted to fold into several stem-loop and pseudoknot structures. To elucidate the functional role of this upstream region, a series of deletions was made in cDNA clones of RNA-3, a genomic component not required for replication. These deletion mutants were transcribed in vitro and cotransfected with RNA-1 and RNA-2 into barley protoplasts. Deletion of single stem-loop structures gave progeny retaining near-wild-type accumulation levels. Constructions representing deletion of two or three stem-loops substantially lowered the accumulation of progeny RNA-3 relative to wild-type levels. RNA-3 mutants bearing deletions of longer sequences or of the entire region (delta PsKs RNA-3) replicated poorly, yielding no detectable RNA-3 or RNA-4 progeny. Levels of RNA-1 and RNA-2, in the presence of a mutant RNA-3, were found to increase relative to the accumulation observed in a complete wild-type transfection. The stability of delta PsKs RNA-3 in protoplasts was somewhat lower than that of wild-type RNA during the first 3 h postinoculation. Little difference in translatability in vitro of wild-type and RNA-3 constructs bearing deletions within the stem-loop region was observed, and Western immunoblot analysis of viral coat protein produced in transfected protoplasts showed that protein accumulation paralleled the amount of RNA-4 message produced from the various sequences evaluated. These results indicate that the RNA-3 pseudoknot region plays a minor role in translational control but contributes substantially to the overall replication of the brome mosaic virus genome.     

Purification and characterization of human H-ras proteins expressed in Escherichia coli.

The full-length normal and T24 mutant human H-ras proteins and two truncated derivatives of the T24 mutant were expressed efficiently in Escherichia coli. The proteins accumulated to 1 to 5% of total cellular protein, and each was specifically recognized by anti-ras monoclonal antibodies. The two full-length proteins as well as a carboxyl-terminal truncated derivative (deleted for 23 amino acid residues) were soluble upon cell lysis and were purified to 90% homogeneity without the use of denaturants. In contrast, an amino-terminal truncated ras derivative (deleted for 22 amino acid residues) required treatment with urea for its solubilization. The guanine nucleotide binding activity of these four proteins was assessed by a combination of ligand binding on proteins blots, immunoprecipitation, and standard filter binding procedures. The full-length proteins showed similar binding kinetics and a stoichiometry approaching 1 mol of GTP bound per mol of protein. The showed similar binding kinetics and a stoichiometry approaching 1 mol of GTP bound per mol of protein. The carboxyl-terminal truncated protein also bound GTP, but to a reduced extent, whereas the amino-terminal truncated protein did not have binding activity. Apparently, the carboxyl-terminal domain of ras, although important for transforming function, does not play a critical role in GTP binding.     

戊型肝炎病毒DNA免疫的研究

利用PCR方法获得1 163 bp的戊型肝炎（Hepatitis E Virus,HEV）开放读码框架(Open Reading Frame,ORF)ORF2之3’大片段和369bp ORF3的完整片段,分别克隆到真核表达载体pcDNA3中,构建两种含有HEV主要抗原表位的质粒DNApcE2和pcE3,分别或混合免疫Swiss小鼠三次（0时,第2周,第4周）,观察其在小鼠体内诱发的体液免疫应答。ELISA检测结果表明,pcE2和pcE3在小鼠体内均可诱导出一定水平的HEVIgG抗体,且在第三次免疫接种两周后,100%的小鼠抗体阳转。与两种质粒单独免疫相比,两者同时注射的抗体水平较高。本研究为HEVDNA疫苗的研究打下一定基础。     

Segmental flexibility and complement fixation of genetically engineered chimeric human, rabbit and mouse antibodies.

We generated a family of chimeric immunoglobulin G (IgG) molecules having identical antigen-combining sites for the dansyl (DNS) hapten, in conjunction with nine heavy chain constant (CH) regions. This family of antibody molecules allows comparison of CH dependent properties independent of possible variable region contributions to IgG function. The segmental flexibility and complement fixation activity were measured of six genetically engineered molecules (the four human IgG isotypes, mouse IgG3 and rabbit IgG) and the remaining three mouse IgG isotypes, (IgG1, IgG2a and IgG2b), isolated previously by somatic cell genetic techniques. These properties of antibody molecules each correlate with the length of the immunoglobulin hinge region which separate the first and second CH (CH1 and CH2) domains. These results attribute a structural basis for two critical properties of antibody molecules.