TITLE OF THE INVENTION
Thermal release of recombinant protein into culture media.
FIELD OF THE INVENTION
The invention relates to methods for the isolation of substantially pure polypeptides from recombinant micro¬ organisms.
BACKGROUND OF THE INVENTION
The use of bacteria to express foreign genes has' faced many practical and biological problems, including the instabi¬ lity of the polypeptide due to proteolysis, low levels of expression, and precipitation of the protein product. Precipitation is correlated to misfolding and lack of biologi¬ cal activity of the protein after purification. To solve these problems, a variety of techniques have been developed to enhance the expression of gene products by transformed hosts. These methods include the use of various promoters to allow the regulation of the level of expression, gene fusions to stabilize normally unstable proteins in the cell, and the use of signal peptides to translocate proteins out of the cyto¬ plasm to the periplasmic space. For example, Abrahamsen, L., et al . , European Patent Application Publication No. 0 225860,
published June 16, 1987, discloses methods for the isolation of expressed gene products having signal sequences from E. coli by induction of filamentous growth, where the expression of the desired gene product is dependent on the heat shock response. This response results in a quantitative leakage of periplasmic located proteins to the growth medium at tempera¬ tures of 30-42'C. Using these conditions, high expression and export of protein A was reported. However, this method is useful only for genes encoding signal sequences fused to protein A. Therefore, it is not widely applicable to all genes.
Proteins produced by host cells are normally trapped within the cells or secreted into the surrounding growth medium. In the former case, the cells must be ruptured to permit the desired protein to be isolated, whereas in the latter case, it can be separated from the growth media. Even in the case of secreted proteins, the preparation from which the protein is to be isolated is relatively complex, contain¬ ing a variety of other substances. Despite efficient separa¬ tion techniques, both the purity and the yield of the desired protein may be low. Lofdahl, S., et al ., PCT application, publication no. WO 84/03103, published 16 August 1984.
Lofdahl et al .. supra, have developed methods for selectively isolating a desired protein or polypeptide by constructing a recombinant vector containing a DNA sequence coding for the desired protein or polypeptide which is operatively linked to a DNA sequence coding for protein A. The expressed fusion protein is then selectively isolated by absorbing onto an IgG-supporting carrier, which binds protein A, followed by desorpt on of the fusion protein. The fusion protein is then cleaved at a unique cleavage site with a cleavage agent, which may include proteases, hydroxylamine, cyanogen bromide or formic acid, to give the purified protein.
Despite the above-described methods for isolating polypeptides produced by recombinant means, a need continues to exist for methods which allow the selective production of substantially pure polypeptides.
SUMMARY OF THE INVENTION
The invention relates to a method for the isolation of a substantially pure polypeptide expressed by a recombinant host comprising:
(a) cultivating on an aqueous nutrient medium, under recombinant protein producing conditions, a micro¬ organism transformed by a vector comprising a DNA sequence encoding said polypeptide, said vector further comprising expression signals which are recognized by said host and which direct the expression of said DNA sequence;
(b) heating said aqueous nutrient medium to 50- 100°C for a time not to exceed one hour to cause release of substantially pure polypeptide from the host; and
(c) recovering said substantially pure polypeptide from the aqueous nutrient medium.
Unexpectedly, it has been discovered that when a recom¬ binant host is heated to 50-100cC for a time not to exceed 1 hour, high levels of substantially pure polypeptide are released into the growth media. This method does not rely on filamentous growth of the host as taught by Abrahamsen et al . , supra, and in fact results in almost immediate and complete cell death at 70-80°C.
DESCRIPTION OF THE FIGURES
Figure 1 depicts a densitometric scan of a whole cell E
coli extract of protein G separated by polyacrylamide electro- phoresis.
Figure 2 depicts a densitometric scan of the supernatant separated by polyacrylamide electrophoresis after heating an aqueous nutrient medium containing E. coli transformed with a vector containing a gene encoding protein G to 80βC for 5 minutes. The major peak is protein G.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The invention is directed toward a method for the isolation of substantially pure polypeptide from a recombinant bacterial host by culturing the host under protein-producing conditions, heating the aqueous nutrient medium to 50-100"C for a time not to exceed 1 hour, and isolating the substan¬ tially pure polypeptide so produced. Although longer heating times and higher temperatures may be utilized, they are not preferred since degradation of the protein occurs under these harsher conditions.
Preferred bacterial hosts include Gram-negative organ¬ isms, in particular, E. coli, Erwin a sp. and Klebsiella sp. The most preferred host is E. coli.
Preferably, the aqueous nutrient medium is heated to 50- 100"C for about 5 minutes. Most preferably, the aqueous nutrient medium is heated to about 80°C for about 5 minutes. Under the most preferable conditions, substantially pure polypeptide is released into the culture media free from significant degradation. The method has the added advantage that endogenous proteases are inactivated by the high tempera¬ tures of the method, thus preventing proteolysis of the polypeptide.
By the term "polypeptide" is intended protein G or protein G variants having the i munoglobulin binding proper-
ties of protein G, protein A or protein A variants having the immunoglobulin binding properties of protein A, and those polypeptides which may be produced in substantially pure form by the method of the invention, which include any peptide which does not irreversibly denature at 50-100cC and which can penetrate the cell wall during the heating procedure. Such proteins may include, but are not limited to, small proteins such as hormones, e.g., parathyroid hormone, growth hormone, ganadotropins (FSH, luteinizing hormone, chorionogonado- tropin), insulin, ACTH, prolactin, placenta! lactogen, melanocyte stimulating hormone, thyrotropin, calcitonin, enkephalin, angiotensin, and small cytokines.
In a preferred embodiment, the recombinant microorganism contains a vector containing the gene which encodes protein G. Vectors which contain the genes which encode protein G and protein G variants which have the immunoglobulin binding properties of protein G are described, for example, in International Application PCT/US87/00329, co-pending U.S. Application Serial No. 063,959, filed June 19, 1987, and co- pending U.S. Application Serial No. 209,236, filed June 20, 1988, the disclosures of which are incorporated by reference herein in their entirety. The vectors may incorporate promoters derived from, for example, bacteriophage, especially bacteriophage lambda, the E. coli tryptophan operon, the ______ coli lac operon, the E. coli J-glucuronidase locus, etc. Suitable recombinant hosts, disclosed in copending U.S. Application Serial No. 063,959, include E. coli GX7820, J . coli GX7823, E. coli GX8464, and E. coli GX8465. Most preferably, the production organism is the transformed host _____ coli GX1201 or E. coli GX6705, which contains the vector pGX5204 or a degenerate variant thereof.
By the method of this invention, high levels of substan¬ tially pure polypeptides can be obtained under conditions
where they may be easily isolated from the fermentation broth. By the term "substantially pure" is intended polypeptides which are substantially one major band by SDS-PAGE polyacryla- mide electrophoresis and which contain only minor amounts of other proteins which normally contaminate a whole cell lysate, as evidenced by the presence of other minor bands.
The recombinant cells may be cultivated under any physiologically compatible conditions of pH and temperature, in any suitable nutrient medium containing assimilable sources of carbon, nitrogen and essential minerals that support cell growth. Recombinant protein-producing cultivation conditions will vary according to the type of vector used to transform the host cells. For example, certain expression vectors comprise regulatory regions which require cell growth at certain temperatures, or addition of certain chemicals to the cell growth medium, to initiate the gene expression which results in the production of the recombinant polypeptide. Thus, the term recombinant "protein-producing conditions," as used herein, is not meant to be limited to any one set of cultivation conditions.
The expressed protein may be recovered from the fermenta¬ tion broth using any of the methods commonly known to those skilled in the art. As a first step, dead cells and insoluble debris are removed from the aqueous nutrient medium by filtration or centrifugation. Protein G or other recombinant protein may then be purified from the fermentation media using standard procedures such as absorption to immobilized immuno¬ globulin, as described by Sjoquist, U.S. Patent No. 3,850,798 (1974), ion exchange or gel chromatography, precipitation (e.g., with ammonium sulfate), dialysis, filtration or a combination of these methods.
The method of the invention is not limited to expression of polypeptides which have leader sequences. In addition, the
invention does not depend on induction of filamentous growth of E. coli as described by Abrahamsen et al .. European Patent Application 0225860. Cell death is complete upon heating at 70-80°C; thus, induction of filamentous growth at these temperatures is not possible. Moreover, since the fermenta¬ tion media is heated to 50-100°C in as little time as 5 minutes, there is little time for meaningful physiologically related morphological changes.
Although the inventors do not wish to be bound by any particular theory, it is hypothesized that the surprising level of purity of the expressed gene products, which results from heating at 50-100cC, is due to a dialysis-like effect. Such an effect might be expected if the heat treatment causes complete loss of membrane integrity. As the temperatures utilized in the practice of the invention likely cause the complete destruction of the cytoplasmic and outer cell membranes, the only remaining barrier to the release of the cell contents would be the peptidoglycan (PG) layer of the cell envelope. The protoplasmic contents are likely trapped within the PG barrier as a result of heat denaturation and coagulation. This theory is supported by the observation of condensed, granular cytoplasmic material by microscopic inspection after heat treatment. Soluble polypeptide, for example protein G, diffuses through the PG layer without significant impediment, by a dialysis-like mechanism. Thus, the polypeptides which may be recovered according to the invention, as listed above, are those which remain soluble and do not denaturate upon heating.
The following examples are provided to illustrate the invention, and are not to be construed as limiting the invention in any manner.
EXAMPLE 1 Preparation of Substantially Pure Protein G
Recombinant E. coli containing a vector which encodes a protein G variant having the immunoglobulin binding properties of protein G (GX8465, see U.S. Application Serial No. 063,959, filed June 19, 1987, incorporated by reference herein) was cultivated in an aqueous nutrient medium (see Table 1) at 32βC, 800 rpm, 1 vvm, pH 7.2 ± 0.1 (titrants: 10% NaOH, 2M H3PO4). After cultivation at 32°C for 6-12 hours, expression of recombinant protein G was induced by raising the broth temperature to 42βC for 1 hr. After 1 hr at 42°C, the broth temperature was reduced to 39βC and maintained at that temperature for 3 hours. As shown in Figure 1, separation of a whole cell extract by SDS-PAGE electrophoresis followed by densitometric scanning of the gel shows that the extract is substantially contaminated by other proteins. The broth was then heated to 80βC and maintained at that temperature for one hour. Samples were removed periodically for analysis by gel electrophoresis (SDS-PAGE). Both cell pellets and cell free media were analyzed at 0, 15, 30 and 60 minutes after heating to 80βC.
Before heating, the pellet contained substantially impure protein G. At this time, no protein G was detected in the fermentation media. At time = 0 (when the temperature reached 80°C), a considerable band of substantially pure protein G was found in the cell-free medium. The corresponding cell pellet showed reduced levels of protein G. At time = 15, only a trace of protein G remained within the pellet. After 30 minutes, no protein G was detectable in the pellet. In contrast, after heating for 15 minutes at 80°C, substantially pure protein G was observed in the supernatant. The relative purity of the protein G in the supernatant did not substan-
tially decline after continued heating at 80°C for one hour. However, some chemical alteration, as evidenced by a fuzziness of the protein G band, was observed after 30 in. at 80°C.
Thus, heating at 80°C results in the release of substan¬ tially all of the protein G into the supernatant and retention of other proteins within the cells.
TABLE 1 Fermentation Media Composition
Ingredients Concentration
Acid digest casein 30 g/1
* Glucose 30 g/1 K2HP04 5 g/1 (NH4)2S04 3 g/1 MgS04.7H20 0.25 g/1 CaCl2.2H20 0.1 g/1 M44 salts (100 X) 10 ml/1
* Biotin 0.1 mg/1
* Nicotinamide 1.0 mg/1
* Ampicillin 100 mg/1 Distilled H 0 dilute to 1360 ml SAG 4130 0.25 ml/1
* = post autoclaving additions
EXAMPLE 2 Release of Protein G at 70°C
The experiment in Example 1 was repeated using a 70°C heat treatment instead of an 80°C heat treatment to induce release of protein G. At this temperature, the release of protein G into the broth does not appear to be complete.
Although substantially pure, the protein G appears to degrade after extended heating at 70°C as evidenced by fuzzy bands on the polyacrylamide electrophoresis gel.
EXAMPLE 3 Release of Protein G at 80βC for 5 Minutes
Example 1 was repeated, except that the holding period at 80βC was reduced to about 5 minutes. This brief exposure resulted in essentially quantitative release of substantially pure protein G as observed by SDS PAGE electrophoresis (Figure 2). In addition, the apparent degradation of protein G due to prolonged heating (as evidenced by the widening of the protein G band on the gel) was greatly reduced.
EXAMPLE 4 Preparation of Substantially Pure Protein A
Recombinant E. coli containing a vector which encodes Protein A, strain NRRL 15910 (U.S. Patent No. 4,691,009) was cultivated in an aqueous medium (see Table 2) at 37°C, 800 rpm, 100 min., pH 7.2 ± 0.1 (titrants: 10% NH40H, 2 M H3P0 ). After growth leveled off, the broth was heated to 80βC for 5 min, then cooled to 30βC. SDS-PAGE analysis of the distribu¬ tion of recombinant Protein A demonstrated that prior to heating, the Protein A was present in the cells and very little was detectable in the supernatant. After heating to 80°C, substantially all of the Protein A was released from the cells was present in the broth supernatant in substantially pure form. Thus, heat inactivation at 80βC results in the release of substantially all of the Protein A into the super¬ natant and the retention of other proteins within the cells in a manner analogous to Protein G.
TABLE 2 Fermentation Media Composition
Ingredients
Tryptone
Yeast extract
K2HP04
(NH4)2S04
MgS04.7H20
CaCl2.2H20
M-44 salts (100 X)
Having now fully described this invention, it will be understood by those of skill in the art that the same can be performed within a wide and equivalent range of conditions, formulations and other parameters without affecting the scope of the invention or any embodiment thereof.