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Following the first attempt to culture insect cells in vitro in 1915, almost 50 years passed before the methods for the establishment of continuous cell lines were successfully established. By 1980, the science of invertebrate cell culture had matured and many cell lines from different species were available for the study of insect and plant viruses. With the advent of the baculovirus-insect cell expression system a new exciting application for insect cells in biotechnology was realized. The need for new and superior insect cell lines for expression of recombinant proteins became important and research in insect cell culture gained renewed interest. In addition to the expression of recombinant proteins for basic research in cell and molecular biology, baculovirus biotechnology has been accepted by industry for the commercial production of reagents, therapeutics, and vaccines for use in agriculture and human health (32). This mini-review will examine; the early attempts to grow baculoviruses in cell culture, the development of widely used cell lines for protein expression, current directions for insect cell culture research, and commercial products that are in development or in the marketplace.
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The first attempt to grow insect tissues in vitro was attributed to Goldschmidt who in 1915 attempted to culture follicle cells of male gonads from pupae of the Cercropia moth (Samia cercropia) in the hemolymph of this species (12). Cells remained alive for a few days but he observed no mitosis in the culture. From this early and seminal observation, the science of insect cell culture was born. The implications and value of insect tissue cultures in the study of insect viruses were realized very early. In 1917, just two years after Goldschmidt's pioneering attempts to culture insect cells, Glaser (11) attempted to grow a polyhedral virus in cultures of insect hemocyte cells maintained in vitro without success.
No further attempts were documented until the classical paper published in 1935 by William Trager (49) who reported the first successful cultivation of a baculovirus in primary ovarian insect cell cultures from silkworm, Bombyx mori, larvae. Two media compositions were used, A and B. The composition of each was surprisingly very simple and only contained a sugar, maltose, 5 inorganic salts, and distilled water. Medium B differed from A in that it contained an egg albumin digest. Both media were supplemented with 10% non-heat inactivated silkworm hemolymph. Medium B provided the best growth of cells. Late instar larvae were used as the source of ovarian tissue and collection of the silkworm hemolymph. Using a hanging drop culture technique he was able to achieve very good ovarian cell growth for up to 3 weeks. He found that the monolayer cells could not be kept growing indefinitely but he was able to subculture them at least once. This was a remarkable achievement considering the state of the art and the noncomplex medium that he used. When he inoculated actively growing cell cultures with hemolymph taken from B. mori nucleopolyhedrovirus (BmNPV)-infected larvae, he was able to observe polyhedra formation within 24 hrs and in most of the cells within 48 hrs. Other interesting observations that Trager made included: 1) cell-free insect hemolymph was needed for optimum growth of the cells, 2) more and larger polyhedra are formed in active healthy cells than in less active, less healthy cells; 3) cell growth was inhibited by the virus, 4) the virus had multiplied (as measured by virus titration in larvae) through 8 passages of virus in cultured ovarian cells, and 5) the virus does not, with successive tissue culture passages, lose any of its characteristics properties. These remarkable early observations are similar to those recorded today by many researchers using optimum baculovirus and cell culture methods.
A landmark paper by Silver Wyatt in 1956 (54) was an important step in the evolution of improved methods for growing insect cells in vitro. Wyatt began her work in an attempt to corroborate Trager's work and to adapt her new techniques for routine use in the study of virus replication and titration. Instead, her study turned into an investigation of improved methods for the growth of insect tissue cultures. Wyatt attempted to culture B. mori ovarian cells in Trager's medium with 10% hemolymph and obtained poor cell growth. She also inoculated these cells with B. mori NPV and the infection was uneven with few infected cells. She attributed the poor infection levels to poor growth conditions for the cells and turned her attention to the growth of B. mori ovarian cells in a new medium formulation based in part on an analysis of the amino acids and sugar composition of insect hemolymph (53). Unlike Trager's medium that contained only 6 ingredients, Wyatt's new growth medium was composed of 34 ingredients including 5 inorganic salts, 3 sugars, 4 organic acids, and 22 amino acids. Ten percent heat-treated silkworm hemolymph was added to the final complete medium. With this formulation, Wyatt was able to obtained cells in culture "superior to any previously obtained" and was able to maintain the cells alive for up to 3 weeks. No subculturing nor baculovirus infection of these cultures was attempted.
Following Wyatt's work, it was generally accepted by most researchers that new media containing all the factors necessary for growth still needed to be developed. However, before this was accomplished, a major breakthrough-the establishment of the first insect cell line-was reported by Shangyin Gaw and associates in 1959 (10). They reported the continuous culture of a B. mori cell line using the simple medium composition developed by Trager in 1935. They used Trager's solution B (see above) supplemented with 10% non-heat inactivated hemolymph and were able to grow ovarian cells and maintain them for at least 22 passages. They also reported that the cells were susceptible to BmNPV and polyhedra formation occurred after 48 postinfection. After submission of their paper for publication, they subcultured the cells through passage 24 before losing the cultures to a bacterial contamination (T.U. Zia, personal communication).
A major step in the evolution of an improved insect cell culture medium was reported by Grace (16). Grace composed a medium that was essentially the same as Wyatt's medium with the following changes: 1) ten members of the vitamin B complex were added; 2) The ionic ratios of the Na/ K and Ca/Mg were altered to values found in the blood of Saturnid moths; 3) The osmotic pressure was changed from an equivalent of 0.72%NaCl to an equivalent of 0.99% NaCl; and the pH was changed from 6.35 to 6.5. Five percent of heat-treated hemolymph was added to the medium. With these changes, Grace was able to establish lines from ovarian tissue of Antheraea eucalypti(16), larval tissues of the mosquito Aedes aegypti (15) and ovarian tissue of B. mori (14). In subsequent studies, Grace also reported that BmNPV was able to infect A. eucalypti cell clones (17) to varying degrees.
The research by Grace which resulted in numerous publications reporting new established cell lines from moths and mosquitoes coupled with his description of Graces insect cell culture growth medium, a medium that is still widely used today, opened the floodgates for the development of many other insect cell lines in laboratories around the world. For his many early contributions Tom Grace is considered by many as the pioneer who was most responsible for providing the leadership and scientific breakthroughs that led to a new era in insect cell culture. It is estimated that 350 to 400 cell lines were established between 1960 and 1990 and for years many of these established lines were important research tools to study the pathology of insect viruses and insect transmitted viruses of animals and man.
Another significant scientific contribution that greatly synergized the interest in insect cell culture research was the development of the baculovirusinsect cell expression system (43, 47). The baculovirus-insect cell expression system is now considered a highly effective, proven, and robust technology for the expression of thousands of recombinant proteins for use in cell and molecular biology research with both insect and mammalian cells (32). Commercial production of recombinant proteins is a growing industry and several companies are using this expression system for the commercial development of immuno-therapeutics, animal vaccines and human vaccines.
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The Autographa californica multiple nucleopolyhedrovirus (AcMNPV) is the most widely used virus vector for protein expression (32). T86 virus AcMNPV has a broad in vitro host range and numerous established cell lines have been evaluated for their growth characteristics, baculovirus susceptibility, and ability to express high levels of recombinant proteins (4, 24, 46). Although the versatile cell line Tn368, developed by Fred Hink in 1970 (24), was initially widely used for basic studies with AcMNPV, three other cell lines became the dominant lines that are currently used for protein expression around the world by academia and industry. These are the Spodoptera frugiperda line, SF21 (and its clonal isolate, SF9), and the Trichoplusia ni line, BTI TN5B1-4, commercially known as the High Five cells.
The SF21 cell line was established by James E. Vaughn at the USDA Insect Pathology Laboratory in Beltsville, Maryland, in 1970. SF21 cells were developed from ovarian tissue of S. frugiperda pupae (13) and at passage 22 it was reported to be susceptible to S. frugiperda NPV. The cell line designated IPLB-SF-21 was established in hemolymph-supplemented medium (13) and was shown to be highly susceptible to AcMNPV. A detailed description of the establishment of this line was published in 1977 (51) and a strain of the IPLB-SF-21 line was adapted to a hemolymph-free medium by Gardiner and Stockdale in England (9). This strain which was designated IPLB-SF-21AE was later used by the Vaughn lab for virus studies and is the origin of the highly popular SF21 cells that are currently used today (J. L. Vaughn, personal communication). In 1983 the SF9 cells were cloned from the parent line IPLB-SF21AE (ATCC No. CRL-1711). The SF9 clone and SF21 cells are similar in their characteristics with the following properties: They are 1) robust cells and easy to culture in monolayer or suspension, 2) highly susceptible to AcMNPV, 3) able to grow rapidly to high cell densities and produce high budded virus (BV) titers, and 4) readily adaptable to serum-free medium and scaleup culture. Recently, a new cell line was established from the SF9 cells by selection in serum-free medium supplemented with human insulin. This new line, which is reported to be genetically and morphologically distinct from the parent SF9 cells, is known commercially as expressSF+ (Protein Sciences Corp., Meriden, Ct).
A significant contribution in the development of new cell lines for the production of high levels of recombinant proteins, was the establishment of the T. ni cell line, BTI-Tn5B1-4 (19). The Tn5B1-4 cells are a clonal isolate of a parental line Tn5B1 which was established from T. ni eggs in 1986 for studies of the replication of a T. ni granulovirus and NPV (18). The clonal isolate, Tn5B1-4 normally grows in monolayer culture and has the following characteristics. They are: 1) highly susceptible to AcMNPV, 2) adaptable to grow in suspension, 3) able to grow to moderate cell densities and produce moderate BV titers, 4) readily adaptable to serum-free media and scaleup procedures, and 5) able to produce very high levels of many recombinant proteins. The ability of these cells to outperform SF21 and SF9 cells in their expression of most but not all recombinant proteins (4) has led to the acceptance of Tn5B1-4 cells as a widely used line for gene expression. This cell line is available for research purposes under the trade name "High Five" cells (Invitrogen Inc, Carlsbad, Ca). Recently, two novel, clonal cell lines (Tn-H5CL-B and Tn-H5CL-F) were isolated from the High Five cells at passage 90 (34). Both H5CL-B and H5CL-F cells showed higher levels of B-galactosidase production and expressed two-fold more secretory alkaline phosphatase when compared to High Five cells. The clonal lines also exhibited higher resistance to nutrient stress. Both the parental cells and the novel clones produced 2.5-fold more wild type AcMNPV occlusion bodies than SF9 cells. The clonal lines have a population doubling time similar to the High Five cells, grow as attached monolayers and can be adapted to serum-free medium.
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Numerous small to midsize startup biotechnologycompanies in North America and the Europe are currently using the baculovirus-insect cell technology to produce custom recombinant proteins for research and commercial applications. Furthermore, since this system is an accepted technology for the production of viral antigens with vaccine potential, several companies are now in the developmental testing stage with therapeutic or vaccine products for animal or human purposes. An excellent review by van Oers (50) summarizes the potential use of the baculovirus-cell system for animal and human vaccines. Currently, there are two animal vaccines that are on the market and several immuno-therapeutic and human vaccines are being developed and produced in SF21, SF9, expressSF+, or High Five cells (Table 1 and 2). In Europe, two commercial subunit vaccines for classical swine fever are produced in S. frugiperda cells by Intervet, Leiden, The Nether lands (50). Several human vaccines that are being produced in S. frugiperda cells and are in mid to late phase clinical trials are:1) Provenge, an immuno-therapeutic vaccine for prostate cancer developed by Dendreon Inc, Seattle, WA., 2) Flublok, a vaccine for human influenza virus developed by Protein Sciences Inc., Meriden, CT., and 3) Chimigen vaccines for chronic hepatitis B and C developed by Virex Medical Corp., Calgary, Canada.
Table 1. Commercial products in development using Spodoptera frugiperda cells
Table 2. Commercial products in development using Trichoplusia ni “High five cells”
Commercial products in development using T. ni High Five cells include: 1) FavId (idiotype/KLH) an immuno-therapeutic vaccine for B-cell non-Hodg kin's lymphoma developed by Favrille Inc, San Diego, CA. and 2) Cervarix, a vaccine for cervical cancer developed jointly by Medimmune, Gaithersburg, Md and GlaxoSmithKline, Rixensart, Belgium. Cervarix may be the first insect cell produced vaccine to be commercialized for human use. GlaxoSmithKline filed for regulatory approval in Europe in March 2006 and expect approval by early 2007. They intend to filefor regulatory approval in the United States by April, 2007. A new vaccine produced in insect cells would be a major advancement for women's health since it is estimated that approximately 250 000 women worldwide die each year of cervical cancer. The commercial availability and probable success of vaccines for animal or human use in the near future will provide even greater impetus for the application of the baculovirus-insect cell technology in research and medicine.