Alejandro Negrete

Economized large-scale production of high yield of rAAV for gene therapy applications exploiting baculovirus expression system.

The versatility of recombinant adeno‐associated vector (rAAV) as a gene delivery system is due to the vectors ability to transduce different cell types as well as dividing and non‐dividing cells. Large‐scale production of rAAV remains one of the major challenges for continued development of pre‐clinical and clinical studies, and for its potential commercialization. The baculovirus expression vectors (BEVS) and insect cells represent a potential method to produce rAAV economically at large scale. This technology uses three different BEVs (Bac‐Rep, Bac‐GFP, and Bac‐VP) each at a multiplicity of infection (MOI) of 3. We reported previously the production of rAAV at 40 L scale using a stirred‐tank bioreactor (STB). However, production in larger volumes is limited by the stability of the BEVs and amount of BEVs needed to achieve the target MOI of 3 per BEV. Here, the production parameters were optimized and the baculovirus stability was determined.

Evidence of Prior Exposure to Human Bocavirus as Determined by a Retrospective Serological Study of 404 Serum Samples from Adults in the United States

ABSTRACT Recently, molecular screening for pathogenic agents has identified a partial genome of a novel parvovirus, called human bocavirus (HBoV). The presence of this newly described parvovirus correlated with upper and lower respiratory tract infections in children. Lower respiratory tract infections are a leading cause of hospital admission in children, and the etiological agent has not been identified in up to 39% of these cases. Using baculovirus expression vectors (BEVs) and an insect cell system, we produced virus-like particles (VLPs) of HBoV. The engineered BEVs express the HBoV capsid proteins stoichiometrically from a single open reading frame. Three capsid proteins assemble into the VLP rather than two proteins predicted from the HBoV genome sequence. The denatured capsid proteins VP1, VP2, and VP3 resolve on silver-stained sodium dodecyl sulfate-polyacrylamide gels as three bands with apparent molecular masses of 72 kDa, 68 kDa, and 62 kDa, respectively. VP2 apparently initiates at a GCT codon (alanine) 273 nucleotides downstream from the VP1 start site and 114 nucleotides upstream from the VP3 initiation site. We characterized the stable capsids using physical, biochemical, and serological techniques. We found that the density of the VLP is 1.32 g/cm3 and is consistent with an icosahedral symmetry with approximately a 25-nm diameter. Rabbit antiserum against the capsid of HBoV, which did not cross-react with adeno-associated virus type 2, was used to develop enzyme-linked immunosorbent assays (ELISAs) for anti-HBoV antibodies in human serum. Using ELISA, we tested 404 human serum samples and established a range of antibody titers in a large U.S. adult population sample.

Strategies for manufacturing recombinant adeno-associated virus vectors for gene therapy applications exploiting baculovirus technology

The development of recombinant adeno-associated virus (rAAV) gene therapy applications is hampered by the inability to produce rAAV in sufficient quantities to support pre-clinical and clinical trials. Contrasting with adherent cell cultures, suspension cultures provide a straightforward means for expansion, however, transiently expressing the necessary, but cytotoxic virus proteins remains the challenge for rAAV production. Both the expansion and expression issues are resolved by using the baculovirus expression vector (bev) and insect cell culture system. This review addresses strategies for the production of rAAV exploiting baculovirus technology at different scales using different configurations of bioreactors as well as processing and product characterization issues. The yields obtained with these optimized processes exceed approximately 1 x 10(14) vector particles per liter of cell culture suitable for pre-clinical and clinical trials and possible commercialization.

ENPP1-Fc prevents mortality and vascular calcifications in rodent model of generalized arterial calcification of infancy.

Diseases of ectopic calcification of the vascular wall range from lethal orphan diseases such as generalized arterial calcification of infancy (GACI), to common diseases such as hardening of the arteries associated with aging and calciphylaxis of chronic kidney disease (CKD). GACI is a lethal orphan disease in which infants calcify the internal elastic lamina of their medium and large arteries and expire of cardiac failure as neonates, while calciphylaxis of CKD is a ubiquitous vascular calcification in patients with renal failure. Both disorders are characterized by vascular Mönckeburgs sclerosis accompanied by decreased concentrations of plasma inorganic pyrophosphate (PPi). Here we demonstrate that subcutaneous administration of an ENPP1-Fc fusion protein prevents the mortality, vascular calcifications and sequela of disease in animal models of GACI, and is accompanied by a complete clinical and biomarker response. Our findings have implications for the treatment of rare and common diseases of ectopic vascular calcification.

Glucose uptake regulation in E. coli by the small RNA SgrS: comparative analysis of E. coli K-12 (JM109 and MG1655) and E. coli B (BL21).

BackgroundThe effect of high glucose concentration on the transcription levels of the small RNA SgrS and the messenger RNA ptsG, (encoding the glucose transporter IICBGlc), was studied in both E. coli K-12 (MG1655 and JM109) and E. coli B (BL21). It is known that the transcription level of sgrS increases when E. coli K-12 (MG1655 and JM109) is exposed to the non-metabolized glucose alpha methyl glucoside (αMG) or when the bacteria with a defective glycolysis pathway is grown in presence of glucose. The increased level of sRNA SgrS reduces the level of the ptsG mRNA and consequently lowers the level of the glucose transporter IICBGlc. The suggested trigger for this action is the accumulation of the corresponding phospho-sugars.ResultsIn the course of the described work, it was found that E. coli B (BL21) and E. coli K-12 (JM109 and MG1655) responded similarly to αMG: both strains increased SgrS transcription and reduced ptsG transcription. However, the two strains reacted differently to high glucose concentration (40 g/L). E. coli B (BL21) reacted by increasing sgrS transcription and reducing ptsG transcription while E. coli K-12 (JM109 and MG1655) did not respond to the high glucose concentration, and, therefore, transcription of sgrS was not detected and ptsG mRNA level was not affected.ConclusionsThe results suggest that E. coli B (BL21) tolerates high glucose concentration not only by its more efficient central carbon metabolism, but also by controlling the glucose transport into the cells regulated by the sRNA SgrS, which may suggest a way to control glucose consumption and increase its efficient utilization.

Reducing acetate excretion from E. coli K-12 by over-expressing the small RNA SgrS.

When exposed to the nonmetabolized glucose derivative alpha methyl glucoside (αMG), both Escherichia coli K-12 (JM109 and MG1655) and E. coli B (BL21) respond by reducing the concentration of the mRNA of the ptsG gene which is responsible for the biosynthesis of the glucose transporter EIICB(glu). This occurs through the over-expression of the noncoding small RNA SgrS, which interacts specifically with the mRNA of the ptsG gene and prevents its translation. However, when these bacteria are exposed to a glucose concentration of 40 g/L, over-expression of SgrS is observed only in E. coli B (BL21). Unlike E. coli K-12 (JM109 and MG1655), which are affected by high glucose concentration and produce higher levels of acetate, E. coli B (BL21) is not affected. Based on this information, it was assumed that over-expression of SgrS enables E. coli B (BL21) to reduce its acetate excretion by controlling the glucose transport. When SgrS was over-expressed in both E. coli K-12 strains from a multicopy plasmid, it was possible to reduce their acetate excretion levels to those seen in E. coli B. This observation opens a new approach towards controlling bacterial metabolism through the use of noncoding RNA.

Rad50 zinc hook is important for the Mre11 complex to bind chromosomal DNA double-stranded breaks and initiate various DNA damage responses.

Background: The Mre11 complex plays an important role in DNA DSB repair. Results: The Rad50 zinc hook domain is critical for the recruitment of the Mre11 complex to chromosomal DSBs. Conclusion: The Rad50 zinc hook domain is important for initiating DNA damage responses and mediating DSB repair. Significance: These studies help to understand how the Mre11 complex functions to repair DNA lesions and to maintain genome stability in mammalian cells. The Mre11-Rad50-Nbs1 (MRN) complex plays critical roles in checkpoint activation and double-stranded break (DSB) repair. The Rad50 zinc hook domain mediates zinc-dependent intercomplex associations of MRN, which is important for DNA tethering. Studies in yeast suggest that the Rad50 zinc hook domain is essential for MRN functions, but its role in mammalian cells is not clear. We demonstrated that the human Rad50 hook mutants are severely defective in various DNA damage responses including ATM (Ataxia telangiectasia mutated) activation, homologous recombination, sensitivity to IR, and activation of the ATR pathway. By using live cell imaging, we observed that the Rad50 hook mutants fail to be recruited to chromosomal DSBs, suggesting a novel mechanism underlying the severe defects observed for the Rad50 hook mutants. In vitro analysis showed that Zn2+ promotes wild type but not the hook mutant of MR to bind double-stranded DNA. In vivo, the Rad50 hook mutants are defective in being recruited to chromosomal DSBs in both H2AX-proficient and -deficient cells, suggesting that the Rad50 hook mutants are impaired in direct binding to chromosomal DSB ends. We propose that the Rad50 zinc hook domain is important for the initial binding of MRN to DSBs, leading to ATM activation to phosphorylate H2AX, which recruits more MRN to the DSB-flanking chromosomal regions. Our studies reveal a critical role for the Rad50 zinc hook domain in establishing and maintaining MRN recruitment to chromosomal DSBs and suggest an important mechanism of how the Rad50 zinc hook domain contributes to DNA repair and checkpoint activation.

Use of hollow fiber tangential flow filtration for the recovery and concentration of HIV virus-like particles produced in insect cells

Attenuated viruses, inactivated viruses and virus like particles (VLPs) are known to be efficient vaccines partially due to their particulate structure. A potential HIV vaccine candidate engineered as a VLP (HIV gag-VLP) and produced in insect cells is currently under preclinical trials demanding large amounts. Due to their extreme fragility and sensitivity to shear forces the recovery and concentration of these extracellular enveloped particles of approximately 120 nm in size is challenging. The current bench scale gradient ultracentrifugation and precipitation methods have been found unsuitable for larger scale processes. In this study a two-step tangential flow filtration (TFF) process using hollow fibers was developed for the clarification and concentration of HIV gag-VLPs. The first step is microfiltration for cell removal and the second step is ultrafiltration for concentrating the HIV gag-VLPs. The chosen parameters for the microfiltration step were hollow fiber membranes of 0.45 μm cut off 5000 s(-1) shear force and a flux of 10 LMH. The chosen parameters for the ultrafiltration step were a 500 kDa cut off membrane, 6000 s(-1) shear force and a trans-membrane pressure (TMP) of 1.25 bar. The utilization of these parameters provided with concentrated HIV-gag VLPs from 2L of starting cell suspension within 6h of processing time. These downstream processing conditions are extremely valuable for the further large-scale purification process development for HIV gag-VLPs and other particulate bioproducts.

Analyzing metabolic variations in different bacterial strains, historical perspectives and current trends - example E. coli

The analysis of metabolic differences in bacterial strains is a useful tool for the development of strains with desired growth and production properties. Several methods are available for the evaluation and understanding of the differences: Biochemical methods to measure metabolites concentration and enzyme activity, mathematical methods to analyze metabolic fluxes through the various pathways, proteomic methods to identify expressed proteins, and genomic methods to detect and measure gene expression. A combination of the various methods is required to obtain a comprehensive understanding of metabolic activities. The genomic methods provide substantial amount information on global gene expression but do not always reflect the actual activity of the individual components. The review focuses on the different methodologies and their use, as well as historical overview of the evaluation of the differences between Escherichia coli K and E. coli B.

Large-Scale Production of Recombinant Adeno-Associated Viral Vectors

Current and future demands of viral vectors for the development of successful pre-clinical and clinical studies in human gene therapy and possible commercialization of gene therapy products require well-established large-scale production processes. One of the most promising vectors for human gene therapy is recombinant adeno-associated virus vectors (rAAVs). Some of the attractive features of rAAV are broad tissue tropism, low immunogenicity, ability to transduce both mitotic and post-mitotic cells, and long-term gene expression in non-dividing cells. Recently, we developed a novel technology for the production of these vectors exploiting baculovirus expression vectors (BEV: ) in insect cell cultures. Initially developed in small, shake flask format, this process has been successfully scaled to larger volumes. In an effort to standardize rAAV production in stirred tank bioreactors, we characterized the culture conditions to derive a set of parameters correlated with high rAAV yields. Measuring capacitance and dielectric spectroscopy with a permittivity probe enabled us to determine optimal times of infection and harvest. Consistent yields of rAAV, 2 x 10(13) DNase-resistant vector genomes (vg) [1 x 10(12) transducing units (tu)] per liter of cell culture were obtained in bioreactors with working volumes ranging from 10 to 40 l. This represents significant progress toward establishing a robust large-scale process at industry level.