Current animal models of bronchial asthma.

Human asthma is on the rise worldwide. The necessity to develop effective treatments against it requires an organized effort which covers every aspect of the disease from the pathological alterations via the genetic background to the use and development of active remedies. In these processes animal experiments have served an indispensable role. As asthma is not a natural disease in the animal kingdom the variety for artificially established animal models is quite wide. The possible selection ranges from the laboratory mouse to the horse, it includes ferret and sheep and even favorite pets such as cats and dogs. The large number of the models indicates that to some extent they might not be appropriate or it means that there is no generally accepted model of human asthma. Whatever the reason for this diversity animal models helped us to understand the detailed pathogenesis of some aspects of the disease, they helped us to develop compounds which are more active then previously used ones, and these models proved to us that human asthma is a unique, possibly species-specific disease the eradication of which requires a huge effort. This enormous task should include the collaboration of the clinical and basic research for the development of improved, advanced animal models, which in turn could strengthen our understanding about human asthma.

Preparation and biological effects of pure stereoisomeric novel soft anticholinergics.

A series of pure stereoisomeric soft glycopyrrolate analogues 3, 4 and 5 was synthesized using chiral intermediates and by careful separation of the stereoisomers formed during the last quaternization step of the synthesis. The stereochemistry of the products was elucidated using various 1D and 2D NMR techniques. Anticholinergic activity of the new compounds was determined by receptor binding studies and performing tests on isolated organs and by in vivo tests. Receptor binding revealed that in the higher alkyl ester series the (2R, 1'R, 3'R) and the (2R, 1'S, 3'S) isomers were the compounds showing the highest receptor affinity furthermore it demonstrated the confines of the length of the alkyl chain. In vitro isolated organ experiments correlated well with the receptor binding results, and in vivo investigations indicated the soft character of the compounds.

Anti-inflammatory effect and soft properties of etiprednol dicloacetate (BNP-166), a new, anti-asthmatic steroid.

In vitro and in vivo anti-inflammatory properties and soft characteristics of etiprednol dicloacetate (BNP-166) a new steroid, which has been developed for the treatment of asthma, were investigated in this study. The compound effectively decreased cytokine production in lipopolysaccharide stimulated lymphocytes and attenuated lectin-induced proliferation of blood mononuclear cells in tissue culture. In an animal model of allergen sensitized and challenged Brown Norway rats, using topical treatment, etiprednol dicloacetate substantially attenuated the extent of allergen induced bronchoalveolar fluid eosinophilia. At every examined parameter its pharmacological effects were comparable to those of budesonide. By means of in vitro biological and analytical methods the soft character of BNP-166 was also investigated. The anti-inflammatory effect of etiprednol dicloacetate in vitro was shown to be the function of the quantity of serum components, present in the assay. This loss of activity was most likely the result of the fast metabolism of etiprednol dicloacetate, which in the presence of sera could have been demonstrated by LC/MS/MS. Our data indicate that the significant local effect of the compound will very likely be accompanied with a drastically reduced systemic activity indicating an encouraging selectivity of the pharmacological action of etiprednol dicloacetate.

Prominent stress response of Purkinje cells in Creutzfeldt-Jakob disease.

To examine the role of stress-related 70-kDa heat shock proteins (Hsp-s) in Creutzfeldt-Jakob disease (CJD), we performed immunocytochemistry to detect Hsp-72 and Hsp-73, together with the abnormal (PrP(Sc)) and the presumed cellular form (PrP(C)) of the prion protein, and TUNEL method to measure cellular vulnerability in different brain regions in CJD and control cases. While Hsp-73 showed uniform distribution in all the examined samples, an increase in the number of Purkinje cells with prominent accumulation of Hsp-72 in the CJD group was observed. These neurons also showed intense PrP(C) staining, but TUNEL-positive nuclei were only detected in the granular (Hsp-72-negative) cell layer. Fewer cells of the inferior olivary nucleus were immunoreactive for Hsp-72 in CJD than in control cases, and regions showing severe spongiform change and gliosis exhibited fewer Hsp-72-immunoreactive neurons. Our results indicate that accumulation of the inducible Hsp-72 in certain cell types may be part of a cytoprotective mechanism, which includes preservation of proteins like PrP(C).

Effect of subchronic bimoclomol treatment on vascular responsiveness and heat shock protein production in spontaneously hypertensive rats.

This study was designed to investigate the effects of subchronic bimoclomol treatment on endothelial function and expression of 72 kD heat shock protein (HSP-72) in spontaneously hypertensive rats. Endothelial function was tested by monitoring vascular responses to acetylcholine in isolated aortic ring preparations. Polymerase chain reaction was applied to determine HSP-72 mRNA content in the tissue samples. Significant age-dependent declines in relaxation to acetylcholine and vascular HSP-72 mRNA levels were observed in the spontaneously hypertensive animals. Both changes were prevented by subchronic application of bimoclomol suggesting that preservation of endothelial function might be related to sustained levels of HSP-72.

Bacterially expressed human Fc gamma RIIb is soluble and functionally active after in vitro refolding.

A recombinant soluble form of the human Fc gamma receptor was produced by engineering a cDNA construct containing the extracellular part of the mature protein. After expression in bacteria as inclusion body, the polypeptide was highly purified and was refolded in vitro with a method that was developed for the renaturation of immunoglobulin fragments. With this method oxidation of the disulfide bridges within the domains of the protein is done in the presence of an artificial 'chaperone' which protects the polypeptide molecules from unwanted protein protein interactions thereby inhibiting the incorrect oxidation of the SH-groups. and misfolding of the protein. The refolded recombinant soluble Fc gamma RIIb showed several characteristics of the native receptor: (i) it was recognized by a series of monoclonal antibodies specific for, and in most cases produced against the native cell-surface receptor: (ii) it is bound to its ligand (the Fc-region of different immunoglobulins) under very diverse conditions: and (iii) it is competed strongly and specifically with the native cell surface receptor for both ligand and antibody binding in experiments with distinct read-outs; (iv) monoclonal antibodies produced against the recombinant protein specifically recognized Fc gamma RIIb on different cells. From these data it was concluded that the recombinant soluble Fc-receptor was in a native, functionally active form, and its function was not affected by the lack of glycosylation.

Ultrastructural localization of Hsp-72 examined with a new polyclonal antibody raised against the truncated variable domain of the heat shock protein.

In spite of the intensive search for the determination of the continuously widening physiological and pathological roles of different stress proteins, their ultrastructural localization at the electron microscopic (EM) level has hardly been examined. As it becomes increasingly evident that the function and physiological effectiveness of stress proteins are highly dependent on their spatial location and their associations with diverse regulator proteins, the demand for morphological studies which can identify their detailed distribution within the cells is evident. The reason for the practical lack of studies carried out at the EM level, lies in the shortage of reagents with suitable specificity and avidity necessary for this type of examination. To create such a reagent, a polyclonal antibody was raised using a recombinant truncated form of the inducible Hsp-72 protein. The antibody was extensively characterized, using different immunochemical methods to determine and verify its specificity, and then it was tried in ultrastructural examinations. Using the new antibody, it was possible to analyze the intracellular distribution of Hsp-72 with the immunogold technique. The localization of Hsp-72 was demonstrated directly at the ultrastructural level in the cytoplasm (especially at the cisterns of the RER), in the nucleus (mainly around the heterochromatic regions) and at both sides of the nuclear envelope close to the membrane pores. Apart from these localizations, Hsp-72 was found in several membrane bordered intracellular structures, which mainly belong to the endosomal-lysosomal system. We provide the first morphological verification of the appearance of Hsp-72 on the surface of the cells. Also novel is the indication, that the stress protein may recycle from the cell surface using a common route which includes coated pits and the endosomal system.

Targeting of influenza epitopes to murine CR1/CR2 using single-chain antibodies.

Single-chain variable fragment (scFv) antibodies are genetically engineered molecules comprising the variable regions responsible for specific binding. scFv that recognize certain surface molecules on professional antigen presenting cells could therefore be suitable for targeting Ag to these cells. We have produced an scFv that recognizes murine complement receptors 1 and 2 (CR1/CR2) and genetically fused it with different numbers of influenza hemagglutinin peptides which contain both B and T cell epitopes. The CR1/CR2 specific hybridoma 7G6 was used for RT-PCR to obtain the variable regions, which were then combined to create an scFv fragment. The influenza hemagglutinin intersubunit peptide HA317-41 (IP) was engineered to the N terminus of the scFv in one, two or three copies. The so obtained IP(1-3)7G6scFv still bound the complement receptors; the peptides in the construct were recognized by the peptide specific monoclonal IP2-11-1 on Western blots and ELISAs. The CR1/CR2 positive B lymphomas A20 and 2PK3 presented the peptide to an I-Ed restricted IP specific T cell hybridoma more efficiently when incubated with the IP(1)7G6 constructs as compared to the free peptide. The results suggest that scFv could work as targeting devices in subunit vaccines.

Insulin-regulated mitochondrial gene expression is associated with glucose flux in human skeletal muscle.

To identify abnormally expressed genes contributing to muscle insulin resistance in type 2 diabetes, we screened the mRNA populations from normal and diabetic human skeletal muscle using cDNA differential display and isolated abnormally expressed cDNA clones of mitochondrial-encoded NADH dehydrogenase 1 (ND1), cytochrome oxidase 1, tRNA(leu), and displacement loop. We then measured mRNA expression of these mitochondrial genes using a relative quantitative polymerase chain reaction method in biopsies taken before and after an insulin clamp in 12 monozygotic twin pairs discordant for type 2 diabetes and 12 matched control subjects and in muscle biopsies taken after an insulin clamp from 13 subjects with type 2 diabetes, 15 subjects with impaired glucose tolerance, and 14 subjects with normal glucose tolerance. Insulin infusion increased mRNA expression of ND1 from 1.02 +/- 0.04 to 2.55 +/- 0.30 relative units (P < 0.001) and of cytochrome oxidase 1 from 0.80 +/- 0.01 to 1.24 +/- 0.10 relative units (P < 0.001). The ND1 response to insulin correlated with glucose uptake (r = 0.46, P = 0.002). Although the rate of insulin-mediated glucose uptake was decreased in the diabetic versus the nondiabetic twins (5.2 +/- 0.7 vs. 8.5 +/- 0.8 mg x kg(-1) fat-free mass x min(-1), P < 0.01), insulin-stimulated ND1 expression was not significantly different between them (2.4 +/- 0.5 vs. 2.7 +/- 0.5 relative units). Neither was there any significant intrapair correlation of ND1 expression between the monozygotic twins (r = -0.15, NS). We conclude that insulin upregulates mitochondrial-encoded gene expression in skeletal muscle. Given the positive correlation between ND1 expression and glucose uptake and the lack of intrapair correlation between monozygotic twins, mitochondrial gene expression may represent an adaptation to intracellular glucose flux rather than an inherited trait.

A hemagglutinin-based multipeptide construct elicits enhanced protective immune response in mice against influenza A virus infection.

Multipeptide constructs, comprising adjacent sequences of the 317-341 intersubunit region of immature influenza A hemagglutinin (H1N1), were designed and the functional properties of these branched peptides were compared to that of the corresponding linear peptides. In vivo studies revealed that the immunogenicity of the peptides was dependent on the presence of the hydrophobic fusion peptide (comprised in FP3), encompassing the N-terminal 1-13 sequence of the HA2 subunit. Antibody and T cell recognition, however, was directed against the 317-329 HA1 sequence, comprised in the P4 peptide. Multiple copies of P4, covalently linked by branched lysine residues, significantly enhanced the efficiency of antibody binding and the capacity of peptides to elicit B- and T-cell responses. A fraction of peptide induced antibodies reacted with immature or with proteolitically cleaved hemagglutinin (HA) molecules pretreated at low pH. Immunization with a multipeptide construct, (P4)4-FP3, not only resulted in elevated antibody and T cell responses but conferred enhanced protection against lethal A/PR/8/34 (H1N1) infection as compared to its subunit peptides. The beneficial functional properties of this artificial peptide antigen may be acquired by multiple properties including: (i) stabilized peptide conformation which promotes strong, polyvalent binding to both antibodies and MHC class II molecules; (ii) appropriate P4 conformation for antibody recognition stabilized by the covalently coupled fusion peptide, resulting in the production of virus cross reactive antibodies which inhibit the fusion activity of the virus; (iii) activation of peptide specific B cells which potentiate antigen presentation and peptide specific T cell responses; and (iv) generation of helper T cells which secrete lymphokines active in the resolution of infection.

A single-chain bispecific Fv2 molecule produced in mammalian cells redirects lysis by activated CTL.

Single-chain Fv (sFv) molecules consist of the two variable domains of an antibody (Ab) connected by a polypeptide spacer and contain the binding activities of their parental antibodies (Abs). In this paper we have attached the C-terminus of 2C11-sFv (anti-mouse CD3 epsilon-chain) to the N-terminus of OKT9-sFv (anti-human transferrin receptor [TfR]) through a 23 amino acid inter-sFv linker consisting primarily of CH1 region residues from 2C11, to form a single-chain bispecific Fv2 [bs(sFv)2] molecule. The bs(sFv)2 was expressed in COS-7 cells, and was secreted at the same rate as the two parental sFvs. The secreted protein had both anti-CD3 and anti-TfR binding activities. Essentially all of the secreted bs(sFv)2 molecules bound TfR and the binding affinity of the bs(sFv)2 was comparable to that of OKT9 sFv and Fab. Thus, the attachment of the inter-sFv linker to the N-terminus of OKT9-sFv did not impair its binding function. The bs(sFv)2 retained both binding specificities after long-term storage at 4 degrees C or overnight incubation at 37 degrees C. It redirected activated mouse CTL to specifically lyse human TfR+ target cells at low (ng/ml) concentrations and was much more active than a chemically cross-linked heteroconjugate prepared from the same parental mAbs. Because bs(sFv)2 molecules secreted by mammalian cells are homogeneous proteins containing two binding sites in a single polypeptide chain, they hold great promise as an easily obtainable, economic source of a bispecific molecule suitable for in vivo use.

Correct disulfide pairing and efficient refolding of detergent-solubilized single-chain Fv proteins from bacterial inclusion bodies.

In vitro folding of denatured proteins has remained an inefficient and empirical process that has limited the use of bacterially expressed recombinant proteins. In this paper we show that in vitro folding of recombinant single-chain Fv (sFv) proteins is markedly facilitated when disulfide bonds are formed in detergent solution. sFv proteins from three different antibodies were expressed as bacterial cytoplasmic inclusion bodies and solubilized in the weak ionic detergent, sodium lauroylsarcosine (SLS). Upon oxidation in air in the presence of metal ion catalysts, all three sFvs quantitatively formed intrachain disulfide bonds which ran as a single band in SDS-polyacrylamide gel electrophoresis under non-reducing conditions. By contrast, oxidation from 6 M urea gave large amounts of disulfide linked aggregates, and three closely spaced bands of monomeric protein. Detergent was removed from the oxidized sFvs by addition of 6 M urea and absorption with an ion exchange resin. After dialysis and gel filtration in non-denaturing solution, moderate to high yields of monomeric sFv were obtained, depending upon the sFv. All three sFvs gave single bands on isoelectric focussing and SDS-PAGE gels and had similar or identical binding specificities and affinities as the parental Fabs, implying that the final products contained correctly paired disulfide bonds. The correct disulfide pairing suggests that the disulfide loops within the detergent-solubilized sFvs adopt a native-like structure.

Alternative triggering molecules and single chain bispecific antibodies.

Although T cell receptors and Fc receptors are the best known cytotoxic triggering molecules, a number of adhesion molecules recently have been identified as alternative triggering molecules. We discuss how CD44, an adhesion molecule found on all leukocytes and many other cell types, becomes a triggering molecule on NK cells following stimulation with IL-2. We also describe a genetically engineered single chain bispecific antibody, produced in mammalian cells and in bacteria, that is capable of redirecting lysis in the nanogram per milliliter range.

Redirection of cellular cytotoxicity. A two-step approach using recombinant single-chain Fv molecules.

In this article the authors discuss an indirect system for redirecting cellular cytotoxicity, which utilizes a "universal" bispecific antibody to redirect T-cells to kill cells targeted with single-chain Fv (sFv) fusion proteins that carry a peptide tag recognized by the bispecific antibody. This approach has a number of theoretical advantages in the immunotherapy of cancer.

Retargeting of CTL by an efficiently refolded bispecific single-chain Fv dimer produced in bacteria.

A single-chain bispecific Fv dimer (bs(sFv)2) having specificity for mouse CD3 epsilon chain and human transferrin receptor was produced in bacterial inclusion bodies. To overcome difficulties associated with in vitro protein folding, we used a novel renaturation approach to obtain active bs(sFv)2. The protein was dissolved in the weak ionic detergent sodium lauroylsarcosine, and disulfides were formed by oxidation in air. After oxidation, the bs(sFv)2 exhibited very little covalent aggregation and migrated as a single species in nonreducing SDS-PAGE, suggesting that disulfides were correctly paired. The detergent was removed using an ion exchange resin and the protein fractionated by size exclusion chromatography. The recovered 65-kDa protein was monomeric in non-denaturing solvent, homogeneous by SDS-PAGE, and comprised 15 to 20% of material applied to the gel filtration column. This protein bound specifically to both mouse CD3 epsilon chain and human transferrin receptor with affinities indistinguishable from those of the parental Fabs or single-chain Fvs. The bs(sFv)2 specifically redirected mouse cytotoxic T cells to lyse target cells expressing human transferrin receptor at picomolar concentrations. Bacterially produced and detergent oxidized bs(sFv)2 molecules may therefore provide the abundant amounts of homogeneous active material required to redirect cytotoxic cells against tumors and other unwanted cells in animal models and in patients.

Construction of a functional disulfide-stabilized TCR Fv indicates that antibody and TCR Fv frameworks are very similar in structure.

Disulfide-stabilized Fvs (dsFv) are recombinant Fv fragments of antibodies in which the inherently unstable VH-VL heterodimer is stabilized by an interchain disulfide bond engineered between structurally conserved framework positions. We now design and produce a disulfide-stabilized Fv of a T cell receptor. It is composed of V alpha and V beta variable domains of the 2B4 TCR stabilized by a disulfide bond between framework residues of the TCR Fv at a site corresponding to that used for disulfide stabilization of antibody Fvs. For ease of production and detection, the TCRdsFv was fused to a truncated form of Pseudomonas exotoxin (PE38). The TCR(dsFv) retains its native conformation and is much more stable than a TCR scFv. Moreover, it is functional in biological assays. Because successful disulfide stabilization of the TCR Fv by the positions used for antibody Fv stabilization would not occur unless the mutated residues in TCR Fv are at positions closely similar to those in antibody Fvs, most likely within less than 1.5 A, these results provide very strong experimental evidence for the structural similarity between immunoglobulin and TCR antigen-binding variable domains.

T cell recognition of the posttranslationally cleaved intersubunit region of influenza virus hemagglutinin.

The influenza virus hemagglutinin is synthesized as a single polypeptide chain, but upon maturation it will posttranslationally be modified by a host cell related trypsin-like enzyme. The enzymatic cleavage attacks the so-called intersubunit region of the molecule giving rise to covalently linked HA1 and HA2 subunits. An I-Ed-restricted T cell epitope was identified in the highly conserved intact intersubunit region of the influenza virus hemagglutinin. T cell recognition of a 25-mer synthetic peptide comprising the intact intersubunit region does not require further processing and the elimination of the intervening Arg residue coupling the fusion peptide to the C-terminal segment of HA1 does not abolish the T cell activating capacity. The fine specificity pattern of a T cell hybridoma similar to that of the polyclonal T cell response demonstrates that a single T cell receptor is able to recognize peptides of different sizes representing not only the uncleaved but also the cleaved form of this hemagglutinin region. Based on specificity studies the epitope was localized to the C-terminal 11 amino acids of the HA1 subunit. The cross-reactivity of peptide-primed T cells with influenza virus infected antigen-presenting cells shows that fragments comprising the identified epitope of the intersubunit region can be generated as a result of natural processing of the hemagglutinin molecule. As antigen-presenting cells are lacking the enzyme which is responsible for the posttranslational modification of newly synthesized hemagglutinin molecules, the role of immature viral proteins in immune recognition is discussed.

The influence of branched polypeptide carriers on the immunogenicity of predicted epitopes of HSV-1 glycoprotein D.

To investigate the role of synthetic polypeptide carriers in inducing an epitope-specific immune response relevant for vaccine design, peptides comprising two distinct regions of herpes simplex virus type I glycoprotein D (1-23 and 273-284) have been conjugated to the branched polypeptides with polylysine backbone, poly[L-Lys-(DL-Alam)] (AK), or poly[L-Lys-(Leui-DL-Alam)] (LAK) and to keyhole limpet haemocyanin (KLH). The magnitude, fine specificity and isotype distribution of the conjugate-, peptide-and carrier-specific antibody responses were characterized in immunized BALB/c and CBA mice. Conjugates containing the polypeptide carrier AK were the most effective in inducing HSV gD-peptide-specific antibody responses while KLH peptide conjugates resulted in conjugate-specific antibody responses without measurable peptide specificity. The efficacy of AK-peptide conjugates was verified by the dominant appearance of peptide-specific antibodies belonging to functionally efficient IgG isotopes, accompanied by low levels of carrier specific antibody responses. Preimmunization of BALB/or CBA mice with AK conjugates comprising the 1-23 or 276-284 HSV peptides resulted in prolonged survival of animals infected with a lethal dose of infectious HSV-1. The potency of these conjugates in eliciting a protective immune response shows a close correlation with the relative levels of conjugate-induced virus-specific antibodies and the neutralizing activity of sera as measured in preimmunized survivors.

Mammalian expression and secretion of functional single-chain Fv molecules.

Single-chain Fv (sFv) proteins are genetically engineered molecules that consist of the two variable domains of an antibody connected by a polypeptide linker; they contain the antigen binding function of the parental protein in a single 30-kDa polypeptide chain. sFvs are usually produced in bacteria where they are insoluble and therefore require extensive refolding in vitro. In this report we followed the processing of three antibody sFvs (145-2C11 directed against murine CD3 epsilon chain, OKT9 against the human transferrin receptor, and U7.6 against dinitrophenyl groups) by transfected mammalian (COS-7) cells to determine whether the mammalian protein folding machinery can produce and secrete active sFv with high efficiency. The sFvs contained an immunoglobulin light chain leader sequence, which directed them to the endoplasmic reticulum and allowed secretion into the medium. We found that the sFvs were secreted at different rates, with the rate-limiting step of secretion being their exit from the endoplasmic reticulum. We increased the secretion rate of one of the sFvs by introducing an asparagine-linked glycosylation site in FR1 of the heavy chain, and by using tunicamycin (an inhibitor of glycosylation) we found that glycosylated antibody sFvs were secreted faster than their nonglycosylated counterparts. All secreted sFvs specifically bound their antigens; where tested, at least 90% of the secreted sFv was functional. Therefore, mammalian cells can effectively fold and secrete sFv antibody and can provide a convenient system for testing and producing sFv proteins.

The intersubunit region of the influenza virus haemagglutinin is recognized by antibodies during infection.

The influenza virus haemagglutinin has an important role in the infectious cycle of the virus and carries multiple B and T cell epitopes. It is synthesized as a single polypeptide chain but viral infectivity depends on its post-translational enzymatic cleavage. The cleavage site of a trypsin-like enzyme responsible for this modification is found in the most conserved intersubunit region of the molecule. In this study the role of this region in antibody recognition was investigated. Synthetic peptides comprising the intact and cleaved forms of the intersubunit segment were used to examine the specificity of virus- or peptide-induced antibodies. The immune response elicited by viral infection resulted in the appearance of antibodies capable of neutralizing the virus without interfering with its binding to the receptor. A monoclonal antibody (MoAb) of such functional properties was shown to recognize the intact intersubunit region both in the uncleaved haemagglutinin molecule and in a 25-mer synthetic peptide comprising the intact intersubunit region. Specificity and functional studies revealed the conformation-dependent recognition of the C-terminal segment of the haemagglutinin 1 subunit by this MoAb. The binding of the antibody was shown to inhibit the trypsin-mediated cleavage of the haemagglutinin molecule and the membrane fusion event. The enzymatic cleavage of the haemagglutinin was demonstrated to abolish antibody recognition of the infective virus suggesting an escape mechanism mediated by the functional destruction of this highly conserved region. The synthetic peptide corresponding to the intact intersubunit region is characterized by an ordered structure and is able to elicit an antibody response in BALB/c mice while its subfragments are nonimmunogenic. Furthermore, this peptide elicited a protective immune response demonstrated by in vivo experiments.