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Apoprotein manufacturing and methods for protein purification

Engineering & Physical Sciences
Healthcare Portfolios
Life Sciences
Blood & Lymphatic Disease
Drug Screening & Discovery
College
College of Engineering (COE)
Researchers
Susin Pires, Ivan
Belcher, Donald
Palmer, Andre
Licensing Manager
Aanstoos, Megan
614-292-4946
aanstoos.1@osu.edu

T2018-237 Methods of purifying proteins that can be used in various applications such as drug delivery and detoxification of byproducts of hemolysis.

The Need

Novel protein and apoprotein purification strategies are valuable tools with a wide variety of medical and research applications. While there are existing techniques for protein and apoprotein purification, some of these have flaws such as the use of harsh denaturants, highly flammable solvents, low yields, cumbersome manufacturing processes, and high capital and operating expenses. Furthermore, they are not easily scalable, which inhibits their applications for expanded use. Therefore, effective, scalable, and safe methods for protein and apoprotein purification are needed.

The Portfolio

Dr. Andre Palmer and colleagues have developed a novel method for apoprotein manufacturing and several methods for protein purification, along with a novel, deliverable protein complex for use in various medical applications. These methods utilize various techniques to purify protein components, protein cocktails (i.e. protein mixtures), and complexes of interest. For example, some of the proteins purified include apohemoglobin (apoHb) and haptoglobin (Hp).

Separation of Small Hydrophobic Ligands from Proteins

With this invention, Dr. Palmer and colleagues have developed a method for separating small hydrophobic ligands from proteins, such as heme from hemoglobin (Hb) or metabolites and lipids from human serum albumin (HSA). This method allows for purification of apoproteins, such as apoHb and ligand-free HSA.

This novel technology does not require the use of specialized equipment, is relatively inexpensive, and easily scalable. Furthermore, this technology has the potential to be applied to any ligand-associated protein to produce the resultant apoprotein.

With a wide variety of medical applications, this method represents a breakthrough in the manufacturing of apoproteins. Large-scale manufacturing of apoproteins opens-up a new approach to facilitate small molecule drug transport in vivo. These proteins may be used for targeted drug delivery, bioimaging, and/or scavenging of toxic molecules during various disease states. Furthermore, these apoproteins could be used in various medical treatments, such as drug delivery for certain cancers. There are also other prospective applications for this technology: currently purified serum proteins may be made free of lipids and metabolites, thus improving their therapeutic index.

Isolation of Plasma Proteins and Plasma Protein Cocktails

Hp is a valuable plasma protein with various medical applications. Dr. Palmer and colleagues have refined a method to obtain isolated polymeric forms of Hp from plasma or plasma fractions with minimal contamination from other serum proteins or components. Hp can bind cell-free hemoglobin, which allows Hp to be used as a treatment for a variety of medical conditions characterized by states of hemolysis. Therefore, since Hp can target CD163+ macrophages and monocytes, Hp may be used for targeted drug delivery in combination with Hb and/or Hb-like molecules.

Furthermore, with the use of their method of separation, Dr. Palmer’s group is capable of isolating protein cocktails (i.e. protein mixtures) for enhanced treatment of states of hemolysis. One of these cocktails is capable of binding and detoxifying cell-free Hb, cell-free heme and free iron. During diseases states characterized by hemolysis, the rupture of red blood cells (RBCs) leads to the build-up of these toxic species in the circulation. Previous therapies have mainly focused on scavenging single toxic species (i.e. Hb, heme or iron). Yet, with the use of the protein scavenging cocktail, the treatment would detoxify the major toxic components of hemolysis (i.e. Hb, heme and iron).

The technology developed for isolation of Hp from plasma or plasma fractions can also be applied to purify other plasma proteins, concentrates and cocktails including Factor I, Factor VIII, Factor X, Von Willebrand factor, Fibrinogen, Fibronectin, Protein C, Ceruloplasmin, serum albumin, prothrombin, and immunoglobulins.

This method also provides an advancement in the field of protein purification. The main technique for purifying proteins is column chromatography. However, chromatography is an expensive technique with highly specialized equipment and specific separation conditions for each protein. Furthermore, in some types of chromatography, such as affinity chromatography, the process may require the use of harsh solvents to purify the target protein. With the use of their method, the process has the benefit of being easily scalable to accommodate the large volumes of plasma processed by the plasma protein industry. Therefore, this novel method represents a more effective, less expensive, and more easily scalable protein purification method versus column chromatography.

Selective Protein Purification

Specific proteins can be used in various medical and/or research applications. With this invention, Dr. Palmer and colleagues have developed a method for isolating specific target proteins from protein/particulate mixtures. The method uses a target protein binding molecule (TPBM) that allows for the purification of the desired protein. This process yields purified proteins, which can then be used in various medical applications.

This method is an improvement on current technology for several reasons. First, the use of specific TPBMs allows for the targeting and isolation of proteins specific to the researcher or manufacturer’s needs. Also, the method is inexpensive and less cumbersome compared to current technologies, promoting ease of use and wider applicability. This technology is versatile and can be used to purify a variety of proteins.

Therapeutic Uses of Protein Complexes

The researchers have created unique protein complexes that have a wide variety of medical applications. The products are synthetically made apoHb-Hp protein complexes. One medical application of this technology is for treatment of various states of hemolysis, where these complexes can be administered to detoxify both cell-free Hb, and cell-free heme. Moreover, this complex can be used as a drug carrier. For example, apoHb-Hp can target CD163+ macrophages and monocytes, thus potentially delivering chemotherapeutic drugs more effectively to these cells.

This technique is an improved method to treat hemolysis because it allows for the scavenging of both cell-free Hb and cell-free heme with a single molecule. There is a need for novel treatments to detoxify the byproducts of hemolysis. This technology therefore represents an advancement in the field that could provide more robust treatment for conditions such as hemolysis, and more efficacious drug delivery for conditions such as cancer.

Commercial Applications

  • Drug delivery
  • Detoxification of byproducts of hemolysis
  • Protein Purification
  • Apoprotein purification
  • Detoxification of blood transfusion
  • Additive to prolong the ex vivo storage lifetime of blood
  • Serum protein concentrates

Benefits/Advantages

  • Inexpensive
  • High yield
  • Scalable
  • More efficacious than current methods
  • Less cumbersome than available methods