List of recombinant proteins

The following is a list of notable proteins that are produced from recombinant DNA, using biomolecular engineering.[1] In many cases, recombinant human proteins have replaced the original animal-derived version used in medicine. The prefix "rh" for "recombinant human" appears less and less in the literature. A much larger number of recombinant proteins is used in the research laboratory. These include both commercially available proteins (for example most of the enzymes used in the molecular biology laboratory), and those that are generated in the course specific research projects.

Human recombinants that largely replaced animal or harvested from human types

Medicinal applications

Research applications

  • Ribosomal proteins: For the studies of individual ribosomal proteins, the use of proteins that are produced and purified from recombinant sources[2][3][4][5] has largely replaced those that are obtained through isolation.[6][7] However, isolation is still required for the studies of the whole ribosome.[8][9]
  • Lysosomal proteins: Lysosomal proteins are difficult to produce recombinantly due to the number and type of post-translational modifications that they have (e.g. glycosylation). As a result, recombinant lysosomal proteins are usually produced in mammalian cells.[10] Plant cell culture was used to produce FDA-approved glycosilated lysosmal protein-drug, and additional drug candidates.[11] Recent studies have shown that it may be possible to produce recombinant lysosomal proteins with microorganisms such as Escherichia coli and Saccharomyces cerevisiae.[12] Recombinant lysosomal proteins are used for both research and medical applications, such as enzyme replacement therapy.[13]

Human recombinants with recombination as only source

Medicinal applications

Animal recombinants

Medicinal applications

Bacterial recombinants

Industrial applications

Viral recombinants

Medicinal applications

Plant recombinants

Research applications

Industrial applications

  • Laccases have found a wide range of application, from food additive and beverage processing to biomedical diagnosis, and as cross‐linking agents for furniture construction or in the production of biofuels.[30][36][37][38][39]
  • The tyrosinase‐induced polymerization of peptides offers facile access to artificial mussel foot protein analogues. Next generation universal glues can be envisioned that perform effectively even under rigorous seawater conditions and adapt to a broad range of difficult surfaces.[40]

See also

References

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