Henryk Mach

Comparative Immunogenicity in Rhesus Monkeys of DNA Plasmid, Recombinant Vaccinia Virus, and Replication-Defective Adenovirus Vectors Expressing a Human Immunodeficiency Virus Type 1 gag Gene

ABSTRACT Cellular immune responses, particularly those associated with CD3+ CD8+ cytotoxic T lymphocytes (CTL), play a primary role in controlling viral infection, including persistent infection with human immunodeficiency virus type 1 (HIV-1). Accordingly, recent HIV-1 vaccine research efforts have focused on establishing the optimal means of eliciting such antiviral CTL immune responses. We evaluated several DNA vaccine formulations, a modified vaccinia virus Ankara vector, and a replication-defective adenovirus serotype 5 (Ad5) vector, each expressing the same codon-optimized HIV-1 gag gene for immunogenicity in rhesus monkeys. The DNA vaccines were formulated with and without one of two chemical adjuvants (aluminum phosphate and CRL1005). The Ad5-gag vector was the most effective in eliciting anti-Gag CTL. The vaccine produced both CD4+ and CD8+ T-cell responses, with the latter consistently being the dominant component. To determine the effect of existing antiadenovirus immunity on Ad5-gag-induced immune responses, monkeys were exposed to adenovirus subtype 5 that did not encode antigen prior to immunization with Ad5-gag. The resulting anti-Gag T-cell responses were attenuated but not abolished. Regimens that involved priming with different DNA vaccine formulations followed by boosting with the adenovirus vector were also compared. Of the formulations tested, the DNA-CRL1005 vaccine primed T-cell responses most effectively and provided the best overall immune responses after boosting with Ad5-gag. These results are suggestive of an immunization strategy for humans that are centered on use of the adenovirus vector and in which existing adenovirus immunity may be overcome by combined immunization with adjuvanted DNA and adenovirus vector boosting.

Degradative covalent reactions important to protein stability

Commonly observed chemical modifications that occur in proteins during their in vitro purification, storage, and handling are discussed. Covalent modifications described include deamidation and isoaspartate formation, cleavage of peptide bonds at aspartic acid residues, cystine destruction and thioldisulfide interchange, oxidation of cysteine and methionine residues, and the glycation and carbamylation of amino groups.

Vaccine-Induced Immunity in Baboons by Using DNA and Replication-Incompetent Adenovirus Type 5 Vectors Expressing a Human Immunodeficiency Virus Type 1 gag Gene

ABSTRACT The cellular immunogenicity of formulated plasmid DNA and replication-defective human adenovirus serotype 5 (Ad5) vaccine vectors expressing a codon-optimized human immunodeficiency virus type 1 gag gene was examined in baboons. The Ad5 vaccine was capable of inducing consistently strong, long-lived CD8+-biased T-cell responses and in vitro cytotoxic activities. The DNA vaccine-elicited immune responses were weaker than those elicited by the Ad5 vaccine and highly variable; formulation with chemical adjuvants led to moderate increases in the levels of Gag-specific T cells. Increasing the DNA-primed responses with booster doses of either Ad5 or modified vaccinia virus Ankara vaccines suggests a difference in the relative levels of cytotoxic and helper responses. The implications of these results are discussed.

Sucralfate and soluble sucrose octasulfate bind and stabilize acidic fibroblast growth factor

The actions of the anti-ulcer drug sucralfate have been proposed to be mediated through interaction with fibroblast growth factors (Folkman, J., Szabo, S., Strovroff, M., McNeil, P., Li, W. and Shing, Y. (1991) Ann. Surg. 214, 414-427). We show here that acidic fibroblast growth factor (aFGF; FGF-1) binds in vitro to both the soluble potassium salt and the insoluble aluminum salt of sucrose octasulfate, as demonstrated by a variety of biophysical techniques. Similar to the well-described interaction and stabilization of aFGF by heparin, soluble sucrose octasulfate (SOS) stabilizes aFGF against thermal, urea and acidic pH-induced unfolding as determined by a combination of circular dichroism, fluorescence spectroscopy and differential scanning calorimetry. In addition, SOS also enhances the mitogenic activity of aFGF and partially protects the proteins three cysteine residues from copper-catalyzed oxidation. SOS competes with heparin and suramin for the aFGF polyanion binding site as measured by both fluorescence and light scattering based competitive binding assays. Front-face fluorescence measurements show that the native, folded form of aFGF binds to the insoluble aluminum salt of sucrose octasulfate (sucralfate). Moreover, sucralfate stabilizes aFGF against thermal and acidic pH-induced unfolding to the same extent as observed with SOS. Thus, due to their high charge density, SOS and sucralfate bind and stabilize aFGF via interaction with the aFGF polyanion binding site.

High Throughput Formulation Screening for Global Aggregation Behaviors of Three Monoclonal Antibodies

Global aggregation behaviors of three distinct monoclonal antibodies were characterized by high throughput, multiassay analysis. First, extensive screening of formulations was performed using both incubation at elevated temperature and differential thermal scanning. In incubation studies, formulation conditions representing native favored, native favored but with particulate formation, unfolding with slow aggregation, and fast aggregation with or without phase separation were mapped across a wide range of pH and ionic strength. The sample types or aggregation kinetic scenarios were classified based on fluorescence spectroscopy, light scattering, and micron particle count. Furthermore, apparent melting point was determined for each formulation condition by differential thermal scanning. The global aggregation behaviors and their apparent melting points together highlight the common underlying aggregation pathways and kinetics for the three antibodies. Overall, incorporating multistage aggregation mechanisms in multivariate data analysis provides valuable insights to what and how high throughput techniques can be implemented. Understanding global aggregation behaviors is a key element toward development of rational screening approach.

The Use of Flow Cytometry for the Detection of Subvisible Particles in Therapeutic Protein Formulations

The amount, identity, and size distribution of particles in parenteral therapeutic protein formulations are of immense interest due to potential safety and efficacy-related implications. In this communication, we describe the use of a flow cytometer equipped with forward- and side-scattering as well as fluorescence detectors, to determine the number of subvisible particles in monoclonal antibody formulations. The method appears to detect particles of size 1 μ and larger, requiring relatively small sample volumes to estimate subvisible particle counts. Additionally, it facilitates differentiation of proteinaceous particles after staining with a fluorescent hydrophobic dye. The method is expected to be particularly well suited for pharmaceutical development, because it provides increased throughput due to the use of a 96-well autosampler.

Ultraviolet Spectroscopy as a Tool in Therapeutic Protein Development

Ubiquitous ultraviolet absorption spectroscopy, despite the availability of more sophisticated techniques, remains an indispensable tool that can give an initial insight into the concentration and aggregation state of protein samples. The high degree of reproducibility afforded by diode-array spectrophotometers, combined with their powerful vendor-supplied algorithms, presents an opportunity for improving the accuracy and throughput for their use in pharmaceutical development. In this review, factors important to optimal utilization of the technique, as applied to the development of monoclonal antibodies, are discussed, and specific methodologies are described. In particular, techniques to probe the intrinsic structural properties of proteins, and their behavior under a wide variety of conditions, through the application of second-derivative spectroscopy combined with advanced computational treatments are presented. The information contained in this review is specifically directed to practitioners of the technique in contemporary research and development settings.

Examination of phenylalanine microenvironments in proteins by second-derivative absorption spectroscopy

We have employed near ultraviolet derivative absorption spectroscopy to study the microenvironments of phenylalanine residues in proteins. The use of second-derivative uv spectra in the 250- to 270-nm range effectively suppresses spectral contributions from tryptophan and tyrosine residues. Fitting a polynomial to the numerically calculated second-derivative spectrum allows precise determination of the position of the negative derivative peak near 258 nm. This position is shown to be correlated with the polarity of the microenvironments of phenylalanine residues. This approach allows monitoring of changes in the state of phenylalanine side chains during folding/unfolding of the proteins. In addition, this method permits perturbation of protein samples with ethylene glycol to be used to establish the relative degree of solvent exposure of protein phenylalanine.

Addressing new analytical challenges in protein formulation development

As the share of therapeutic proteins in the arsenal of modern medicine continue increasing, relatively little progress has been made in the development of analytical methods that would address specific needs encountered during the development of these new drugs. Consequently, the researchers resort to adaptation of existing instrumentation to meet the demands of rigorous bioprocess and formulation development. In this report, we present a number of such adaptations as well as new instruments that allow efficient and precise measurement of critical parameters throughout the development stage. The techniques include use of atomic force microscopy to visualize proteinacious sub-visible particles, use of extrinsic fluorescent dyes to visualize protein aggregates, particle tracking analysis, determination of the concentration of monoclonal antibodies by the analysis of second-derivative UV spectra, flow cytometry for the determination of subvisible particle counts, high-throughput fluorescence spectroscopy to study phase separation phenomena, an adaptation of a high-pressure liquid chromatography (HPLC) system for the measurement of solution viscosity and a variable-speed streamlined analytical ultracentrifugation method. An ex vivo model for understanding the factors that affect bioavailability after subcutaneous injections is also described. Most of these approaches allow not only a more precise insight into the nature of the formulated proteins, but also offer increased throughput while minimizing sample requirements.

Degradative Covalent Reactions Important to Protein Stability

Commonly observed chemical modifications that occur in proteins during their in vitro purification, storage, and handling are discussed. Covalent modifications described include deamidation and isoaspartate formation, cleavage of peptide bonds at aspartic acid residues, cystine destruction and thioldisulfide interchange, oxidation of cysteine and methionine residues, and the glycation and carbamylation of amino groups.