Your search keyword '"Tracey, Mary K."' showing total 6 results

1. Scalable, methanol‐free manufacturing of the SARS‐CoV‐2 receptor‐binding domain in engineered Komagataella phaffii

Author

Dalvie, Neil C., primary, Biedermann, Andrew M., additional, Rodriguez‐Aponte, Sergio A., additional, Naranjo, Christopher A., additional, Rao, Harish D., additional, Rajurkar, Meghraj P., additional, Lothe, Rakesh R., additional, Shaligram, Umesh S., additional, Johnston, Ryan S., additional, Crowell, Laura E., additional, Castelino, Seraphin, additional, Tracey, Mary K., additional, Whittaker, Charles A., additional, and Love, J. Christopher, additional

Published

2021

2. Development of a platform process for the production and purification of single‐domain antibodies

Author

Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Crowell, Laura E, Goodwine, Chaz, Holt, Carla S, Rocha, Lucia, Vega, Celina, Rodriguez, Sergio A, Dalvie, Neil C, Tracey, Mary K, Puntel, Mariana, Wigdorovitz, Andrés, Parreño, Viviana, Love, Kerry R, Cramer, Steven M, Love, J Christopher, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Crowell, Laura E, Goodwine, Chaz, Holt, Carla S, Rocha, Lucia, Vega, Celina, Rodriguez, Sergio A, Dalvie, Neil C, Tracey, Mary K, Puntel, Mariana, Wigdorovitz, Andrés, Parreño, Viviana, Love, Kerry R, Cramer, Steven M, and Love, J Christopher

Abstract

Single-domain antibodies (sdAbs) offer the affinity and therapeutic value of conventional antibodies, with increased stability and solubility. Unlike conventional antibodies, however, sdAbs do not benefit from a platform manufacturing process. While successful production of a variety of sdAbs has been shown in numerous hosts, purification methods are often molecule specific or require affinity tags, which generally cannot be used in clinical manufacturing due to regulatory concerns. Here, we have developed a broadly applicable production and purification process for sdAbs in Komagataella phaffii (Pichia pastoris) and demonstrated the production of eight different sdAbs at a quality appropriate for nonclinical studies. We developed a two-step, integrated purification process without the use of affinity resins and showed that modification of a single process parameter, pH of the bridging buffer, was required for the successful purification of a variety of sdAbs. Further, we determined that this parameter can be predicted based only on the biophysical characteristics of the target molecule. Using these methods, we produced nonclinical quality sdAbs as few as 5 weeks after identifying the product sequence. Nonclinical studies of three different sdAbs showed that molecules produced using our platform process conferred protection against viral shedding of rotavirus or H1N1 influenza and were equivalent to similar molecules produced in Escherichia coli and purified using affinity tags.

Published

2021

3. Molecular engineering improves antigen quality and enables integrated manufacturing of a trivalent subunit vaccine candidate for rotavirus

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Dalvie, Neil C, Brady, Joseph R, Crowell, Laura E, Tracey, Mary K, Biedermann, Andrew M, Kaur, Kawaljit, Hickey, John M, Kristensen, D. L, Bonnyman, Alexandra D, Rodriguez-Aponte, Sergio A, Whittaker, Charles A, Bok, Marina, Vega, Celina, Mukhopadhyay, Tarit K, Joshi, Sangeeta B, Volkin, David B, Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Dalvie, Neil C, Brady, Joseph R, Crowell, Laura E, Tracey, Mary K, Biedermann, Andrew M, Kaur, Kawaljit, Hickey, John M, Kristensen, D. L, Bonnyman, Alexandra D, Rodriguez-Aponte, Sergio A, Whittaker, Charles A, Bok, Marina, Vega, Celina, Mukhopadhyay, Tarit K, Joshi, Sangeeta B, and Volkin, David B

Abstract

Background Vaccines comprising recombinant subunit proteins are well-suited to low-cost and high-volume production for global use. The design of manufacturing processes to produce subunit vaccines depends, however, on the inherent biophysical traits presented by an individual antigen of interest. New candidate antigens typically require developing custom processes for each one and may require unique steps to ensure sufficient yields without product-related variants. Results We describe a holistic approach for the molecular design of recombinant protein antigens—considering both their manufacturability and antigenicity—informed by bioinformatic analyses such as RNA-seq, ribosome profiling, and sequence-based prediction tools. We demonstrate this approach by engineering the product sequences of a trivalent non-replicating rotavirus vaccine (NRRV) candidate to improve titers and mitigate product variants caused by N-terminal truncation, hypermannosylation, and aggregation. The three engineered NRRV antigens retained their original antigenicity and immunogenicity, while their improved manufacturability enabled concomitant production and purification of all three serotypes in a single, end-to-end perfusion-based process using the biotechnical yeast Komagataella phaffii. Conclusions This study demonstrates that molecular engineering of subunit antigens using advanced genomic methods can facilitate their manufacturing in continuous production. Such capabilities have potential to lower the cost and volumetric requirements in manufacturing vaccines based on recombinant protein subunits.

Published

2021

4. Development of a platform process for the production and purification of single‐domain antibodies

Author

Crowell, Laura E., primary, Goodwine, Chaz, additional, Holt, Carla S., additional, Rocha, Lucia, additional, Vega, Celina, additional, Rodriguez, Sergio A., additional, Dalvie, Neil C., additional, Tracey, Mary K., additional, Puntel, Mariana, additional, Wigdorovitz, Andrés, additional, Parreño, Viviana, additional, Love, Kerry R., additional, Cramer, Steven M., additional, and Love, J. Christopher, additional

Published

2021

5. Scalable, methanol‐free manufacturing of the SARS‐CoV‐2 receptor‐binding domain in engineered Komagataella phaffii.

Author

Dalvie, Neil C., Biedermann, Andrew M., Rodriguez‐Aponte, Sergio A., Naranjo, Christopher A., Rao, Harish D., Rajurkar, Meghraj P., Lothe, Rakesh R., Shaligram, Umesh S., Johnston, Ryan S., Crowell, Laura E., Castelino, Seraphin, Tracey, Mary K., Whittaker, Charles A., and Love, J. Christopher

Abstract

Prevention of COVID‐19 on a global scale will require the continued development of high‐volume, low‐cost platforms for the manufacturing of vaccines to supply ongoing demand. Vaccine candidates based on recombinant protein subunits remain important because they can be manufactured at low costs in existing large‐scale production facilities that use microbial hosts like Komagataella phaffii (Pichia pastoris). Here, we report an improved and scalable manufacturing approach for the SARS‐CoV‐2 spike protein receptor‐binding domain (RBD); this protein is a key antigen for several reported vaccine candidates. We genetically engineered a manufacturing strain of K. phaffii to obviate the requirement for methanol induction of the recombinant gene. Methanol‐free production improved the secreted titer of the RBD protein by >5X by alleviating protein folding stress. Removal of methanol from the production process enabled to scale up to a 1200 L pre‐existing production facility. This engineered strain is now used to produce an RBD‐based vaccine antigen that is currently in clinical trials and could be used to produce other variants of RBD as needed for future vaccines. [ABSTRACT FROM AUTHOR]

Published

2022

6. Adaptation of Aglycosylated Monoclonal Antibodies for Improved Production in Komagataella phaffii.

Author

Yang Y, Dalvie NC, Brady JR, Naranjo CA, Lorgeree T, Rodriguez-Aponte SA, Johnston RS, Tracey MK, Elenberger CM, Lee E, Tié M, Love KR, and Love JC

Subjects

Animals, CHO Cells, Glycosylation, Humans, Recombinant Proteins biosynthesis, Recombinant Proteins genetics, Recombinant Proteins chemistry, Immunoglobulin G biosynthesis, Antibodies, Monoclonal biosynthesis, Saccharomycetales metabolism, Cricetulus

Abstract

Monoclonal antibodies (mAbs) are a major class of biopharmaceuticals manufactured by well-established processes using Chinese Hamster Ovary (CHO) cells. Next-generation biomanufacturing using alternative hosts like Komagataella phaffii could improve the accessibility of these medicines, address broad societal goals for sustainability, and offer financial advantages for accelerated development of new products. Antibodies produced by K. phaffii, however, may manifest unique molecular quality attributes, like host-dependent, product-related variants, that could raise potential concerns for clinical use. We demonstrate here conservative modifications to the amino acid sequence of aglycosylated antibodies based on the human IgG1 isotype that minimize product-related variations when secreted by K. phaffii. A combination of 2-3 changes of amino acids reduced variations across six different aglycosylated versions of commercial mAbs. Expression of a modified sequence of NIST mAb in both K. phaffii and CHO cells showed comparable biophysical properties and molecular variations. These results suggest a path toward the production of high-quality mAbs that could be expressed interchangeably by either yeast or mammalian cells. Improving molecular designs of proteins to enable a range of manufacturing strategies for well-characterized biopharmaceuticals could accelerate global accessibility and innovations., (© 2024 The Author(s). Biotechnology and Bioengineering published by Wiley Periodicals LLC.)

Published

2025