EP1536825A1

EP1536825A1 - Interferon and immunoglobulin fc fragment hybrid

Info

Publication number: EP1536825A1
Application number: EP02753441A
Authority: EP
Inventors: Tse Wen Chang; Liming Yu
Original assignee: Tanox Inc
Current assignee: Genentech Inc
Priority date: 2002-08-07
Filing date: 2002-08-07
Publication date: 2005-06-08
Also published as: AU2002313730A1; CA2495480A1; EP1536825A4

Abstract

The present invention provides interferon-immunoglobulin Fc fusion proteins ('IFN-Fc hybrids') that are useful for removing or regressing tumors or delaying tumor development. The IFN-Fc hybrids preferably include peptide linkers between the IFN and the Fc fragment. These linkers are T cell inert sequences or any non-immunogenic sequence, preferably Gly-Ser repeat units. The preferred Fc fragment is a human immunoglobulin Fc fragment, preferably the η4 chain.

Description

LNTERFERON AND IMMUNOGLOBULIN FC FRAGMENT HYBRID

BACKGROUND OF THE INVENTION Field of the Invention

This invention relates to protein hybrids having an interferon protein covalently linked to an immunoglobulin Fc fragment, including hybrids having peptide linkers linking the interferon protein and immunoglobulin Fc fragment.

Description of the Prior Art

Interferons, including interferon-α ("IFNα") and interferon-β ('TFNβ"), were among the first cytokines to be produced by recombinant DNA technology. IFNα has been shown to have therapeutic value in conditions such as hairy cell leukemia and inflammatory and viral diseases, including hepatitis B. IFNβ has been approved for use in treatment of multiple sclerosis.

Most cytokines, including IFNα, have relatively short circulation half-lives because they are produced in vivo to act locally and transiently. To use IFNα as an effective systemic therapeutic, relatively large doses and frequent administrations are needed. Such frequent administrations are inconvenient and painful. Further, the toxic side effects associated with IFNα administration are so severe that some cancer patients cannot tolerate the treatment. These side effects are probably associated with administration of a high dosage.

To overcome these disadvantages, the molecule can be modified to increase its circulation half-life or the molecule's formulation can be modified to extend its release time. The dosage and administration frequency can then be reduced to increase the efficacy. Efforts have been made to create a recombinant IFNα-gelatin hybrid with an extended retention time (Tabata, Y. et al., Cancer Res. 51:5532-8, 1991). A lipid-based encapsulated IFNα formulation has also been tested in animals and achieved an extended release of the protein in the peritoneum (Bonetti, A. and Kim, S. Cancer Chemother Pharmacol. 33:258-261, 1993).

IgG and IgM immunoglobulins are among the most abundant proteins in the human blood. They circulate with half-lives ranging from several days to 21 days. IgG has been found to increase the half-lives of several ligand binding proteins (receptors) when used to form recombinant hybrids, including the soluble CD4 molecule, LHR, and the IFN-γ receptor (Mordenti J. et al, Nature, 337:525-31, 1989; Capon, D.J. and Lasky, L.A., U.S. Patent number 5,116,964; Kurschner, C. et al, J. Immunol. 149:4096-4100, 1992).

Various linkers have proven useful for producing protein hybrids. US Patent No. 5,723,125 issued to Chang, et al. on March 3, 1998 entitled "Hybrid with interferon-alpha and an immunoglobulin Fc linked through a non-immunogenic peptide" and US Patent No. 5,908,626 issued to Chang, et al. on June 1, 1999 entitled "Hybrid with interferon-.beta. and an immunoglobulin Fc joined by a peptide linker" disclose hybrid recombinant proteins consisting of human interferon and a human immunoglobulin Fc fragment joined by a peptide linker comprising the sequence Gly Gly Ser Gly Gly Ser Gly Gly Gly Gly Ser Gly Gly Gly Gly Ser.

Given the problems with the use of interferons to treat patients, there is a need for improved compositions and methods for administering interferons to patients while lengthening the in vivo half-life and decreasing the adverse side effects.

SUMMARY OF THE INVENTION

It is, therefore, an object of the invention to provide interferon hybrids that have a longer in vivo half-life than interferon.

It is another object of the invention to provide interferon hybrids that can be administered less frequently that interferon.

It is a further object of the invention to provide interferon hybrids useful for removing or regressing tumors or delaying tumor development.

These and other objects are achieved using a protein hybrid comprising an interferon protein covalently linked at its C-terminal end to the N-terminal end of an immunoglobulin Fc fragment or a protein hybrid comprising an interferon protein covalently linked at its C- terminal end to the N-terminal end of a peptide linker that is covalently linked at its C- terminal end to the N-terminal end of an immunoglobulin Fc fragment. The preferred linker is an immunologically inert peptide consisting of Gly Ser repeat unit having from about 2 to about 40 amino acids. The linkers may also be T cell inert amino acid sequences or any non- immunogenic amino acid sequence. The hybrids of the present invention are useful for treating patients with tumors to remove tumors, regress tumors, or delay tumor development.

Other and further objects, features and advantages of the present invention will be readily apparent to those skilled in the art.

BRIEF DESCRIPTION OF THE SEQUENCE LISTING SEQ ID NO:l is the nucleotide and amino acid sequence of an JJFN-α-Fc hybrid. SEQ ED NO:2 is the amino acid sequence of an IFN-α-Fc hybrid shown in SEQ ID

NO:l.

SEQ ED NOS:3-9 are the amino acid sequences of the various length peptide linkers used to conjugate the N-terminal end(s) of a heavy chain γ4 Fc fragment to the C-terminal end of an IFN-β protein. SEQ ID NO: 10 is the amino acid sequence of a linker used to conjugate the N-terminal end of a heavy chain γl Fc fragment to the C-terminal end of an IFN-α protein as used in an assay as described below.

SEQ ID NO:l 1 is the amino acid sequence of a linker used to conjugate the N-terminal end of a heavy chain γ4 Fc fragment to the C-terminal end of an IFN-α protein which molecule was then used in an in vitro cytopathic effect assay as described below. BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 shows a virus cytopathic effect inhibition assay for various linkers in an IFN-β-Fc hybrid.

Fig. 2 shows a virus cytopathic effect inhibition assay for two different linkers in an IFN- α-Fc hybrid.

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides a protein hybrid comprising an interferon protein covalently linked at its C-terminal end to the N-terminal end of an immunoglobulin Fc fragment.

The interferon protein can be any Type I interferon including interferon-α, interferon- β, interferon-ω, interferon-δ, and interferon-τ or Type II interferon including interferon-γ. Preferably, the interferon protein in an interferon-α or interferon-β, most preferably an interferon-α2a or interferon-α2b.

The immunoglobulin Fc fragment can be a fragment from any class of immunoglobin including IgA, IgD, IgE, IgG, or IgM. Preferably, the Fc fragment is a human immunoglobulin Fc fragment, most preferably an IgG Fc fragment of the IgG4(γ4) subclass. The γ4 chain is preferred over the γl chain because the former demonstrates little or no antibody-dependant cell-mediated cytotoxicity (ADCC) or complement activating ability and is stable in human circulation.

The present invention also provides a protein hybrid homodimer comprising two interferon proteins covalently linked at their C-terminal end to each of the two N-terminal ends of an immunoglobulin Fc fragment, preferably a γ4 Fc fragment.

The present invention also provides a protein hybrid comprising an interferon protein covalently linked at its C-terminal end to the N-terminal end of a peptide linker that is covalently linked at its C-terminal end to the N-terminal end of an immunoglobulin Fc fragment. The interferon protein and Fc fragments are linked through a T cell immunologically inert peptide, preferably peptides with Gly Ser repeat units. Because these peptides are immunologically inactive, their insertion at the fusion point eliminates any neoantigenicity that may develop when directly joining of the interferon and Fc fragment.

The peptide linker is preferably an immunologically inert peptide consisting of Gly Ser repeat unit having from about 2 to about 40 amino acids. Typical amino acid sequences for the peptide linker are shown in SEQ ID NOS 3, 4, 5, 6, 7, 8, and 9. These linkers have the unique ability to connect interferons and Fc fragments without significantly adversely affecting the biological activity of the interferon. While all linker lengths function in the present invention, some linkers are somewhat more effective that others, i.e., linkers with 12 or more amino acids are somewhat more active than the shorter lengths. Preferably, the peptide linker has from 12 to 15 amino acids or from about 17 to 40 amino acids.

The complete nucleotide sequence of an IFNα-Fc hybrid with no linker is shown in SEQ ID NO: 1 and the amino acid sequence is shown in SEQ ID NO:2. The linker, if present, is located between amino acid residue numbers 188 (Glu) and 189 (Glu). The sequences of a number of suitable linkers which were all shown to have about the same cytopathic effect in vitro, are shown in SEQ ID NOS 3, 4, 5, 6, 7, 8, and 9.

The preferred embodiment of the present invention is a protein hybrid comprising an interferon protein covalently linked at its C-terminal end to the N-terminal end of an immunoglobulin Fc fragment. However, the present invention also includes a protein hybrid comprising an immunoglobulin Fc fragment covalently linked at its C-terminal end to the N- terminal end of an interferon protein. Such proteins can be linked directly or through a peptide linker as described herein.

The present invention also provides a protein hybrid homodimer comprising two interferon proteins covalently linked at their C-terminal end to each of the two N-terminal ends of an immunoglobulin Fc fragment, preferably a γ4 Fc fragment, or a protein hybrid homodimer comprising two interferon proteins covalently linked at their C-terminal end to the N-terminal end of a peptide linker that is covalently linked at their C-terminal end to each of the two N-terminal ends of an immunoglobulin Fc fragment. The linkers can contain the same number of amino acids or a different number of amino acids.

If the Fc fragment selected is another chain, such as the μ chain, then, because the Fc fragments form pentamers with ten possible binding sites, the hybrid can comprise interferon and from 1 to 10 cytokines, including multiple interferons. Suitable cytokines that may function in the present invention include, but are not limited to, interleukins, Colony Stimulating Factor, and Tumor Necrosis Factor.

In another embodiment, an interferon protein is linked, directly or through a linker, to one of the two N-terminal ends of an immunoglobulin Fc fragment and another cytokine is linked, directly or through a linker, to the other of the two N-terminal ends of an immunoglobulin Fc fragment.

One significant advantage of the hybrids of the present invention over the native cytokine is that the hybrids have been shown to ablate tumors in an animal model. IFNα is approved for use in treating certain tumors and hepatitis B. The hybrids may be more effective than IFNα in treating infectious diseases and a broad range of tumors.

The IFNα cDNA can be obtained by reverse transcription and PCR using RNA extracted from cells that express IFNα and following the extraction with reverse transcription and expression in a standard expression system. There are several ways to express the recombinant protein in vitro, including in E. coli, baculovirus, yeast, mammalian cells or other expression systems. The prokaryotic system, E. coli, is not able to do post-translational modification, such as glycosylation. This could be a problem in these systems, and mammalian expression could be preferred for this reason, and because it offers other advantages in terms of simplifying purification.

There are several assay methods available for the measuring of the IFNα bioactivity, including an antiviral assay. The hybrids of the invention have a longer half-life in vivo than native IFNα based on in vitro experimental results. Even though the specific activity is lower, the hybrids are preferred to the native IFNα for clinical use. This is because, as a result of the longer half-life, the Cxt (the area under the concentration vs. time curve) is much greater based on in vitro results than for the native IFNα. This means that at the equivalent molar dosage of the native EFNα and the hybrid, the latter would provide a several hundred fold increased exposure to IFNα resulting in vastly increased efficacy at the same dosage and less frequent administration.

Immunoglobin Fc fragments useful in the present invention can be obtained by conventional methods well known to skilled artisans.

Peptide linkers useful in the present invention can be obtained by conventional methods well known to skilled artisans, including chemical synthesis and recombinant expression of the linker with the interferon and Fc fragment. The IFNα-Fc hybrids of the present invention have a much longer half-life in vivo than the native IFNα. Cytokines are generally small proteins with relatively short half-lives. They usually dissipate rapidly among various tissues, including at undesired sites. It is believed that small quantities of some cytokines can cross the blood-brain barrier and enter the central nervous system and cause severe neurological toxicity. The IFN-Fc hybrids of the present invention are especially suitable for treating tumors, including lymphomas and leukemias, because these products will have a long retention time in the vasculature and will not penetrate undesired sites.

The hybrids of the present invention are therefore useful for treating patients with tumors to remove tumors, regress tumors, or delay tumor development. The hybrids are administered in amounts effective to treat the patient with tumors. The determination of the dosage is within the skill of the art based upon the patient size, tumor size, tumor type, and similar parameters.

The IFN-Fc hybrids can be administered in a pharmaceutical formulation including suitable excipients and additives. The dosage for human use can be readily determined by extrapolation from animal data, with compensation for differences in size, and routine experimentation in clinical trials.

The invention will now be described with reference to examples and experimental results, although it will be understood that these examples are included merely for purposes of illustration and are not intended to limit the scope of the invention unless otherwise specifically indicated..

Example 1 IFNα-Fc Hybrid Demonstrates a Large Increase in Half-Life over the Native IFNα

The disclosures of U.S. Patent No. 5,723,125, incorporated by reference, describes making an IFNα-Fc(γl) hybrid with a linker having the sequence: Gly Gly Ser Gly Gly Ser

(SEQ ID NO: 10). The specific activity of this hybrid was 7.7 x 10⁸ units/μmole in an in vitro assay in Daudi cells, compared with 15.4 x 10⁸ units/μmole for the unmodified interferon-α in the same assay. In a later cytopathic effect inhibition assay, the hybrid showed an antiviral specific activity of 2.2 x 10⁸ IU/μmole, which is lower than the 3.8 x 10⁹ IU/μmole of the unmodified interferon-α. In attempting to increase the specific activity of the hybrid, the linker was extended, to increase the flexibility and decrease steric hindrance. A linker having the sequence: Gly Gly Ser Gly Gly Ser Gly Gly Gly Gly Ser Gly Gly Gly Gly Ser (SEQ ID

NO: 11) was used. Another difference in the new hybrid was that the Fc portion was γ4 Fc, rather than γlFc. The results of a virus cytopathic effect inhibition assay, in vitro, showed that the new hybrid had an antiviral specific activity of 1.1 -2.2x10⁹ IU/μmole, a 5-10 fold increase over the old one. Nevertheless, it is still 2-3 fold less than that of the unmodified interferon-α, which had a specific activity of 3.8 x 10⁹ IU/μmole in this same assay. However, in an in vivo pharmacokinetic study in primates, the serum half-life of the claimed new hybrid was about 40 fold longer than the unmodified interferon. Also, the clearance half-life after subcutaneous (s.c.) administration of the hybrid was almost 120 fold longer. The hybrid, when administered s.c, was also well absorbed. The large increase in the AUC (area under curve) for the new hybrid means that it likely would be more efficacious than native interferon-α, notwithstanding its lower specific activity.

Experiments described below were then conducted to determine the effect of using linkers of different lengths on cytopathic activity.

Example 2 Study of the Effect of Various Linkers on IFN-Fc Cytopathic Activity

Comparison of IFN-α(16)Fc and IFN-α- Ala-Fc

The effect of peptide linkers was tested by comparing IFN-α(16)Fc and IFNα-Ala-Fc. IFN-α(16)Fc contains IFNα linked to the hinge region of the human IgG4 Fc fragment through the sixteen amino acid peptide linker shown in SEQ ID NO: 11, an amino acid sequence as follows: GlyGlySerGlyGlySerGlyGlyGlyGlySerGlyGlyGlyGlySer. The IFN-α- Ala-Fc construct contains IFN-α linked to the hinge region of the human IgGl Fc with one amino acid (Ala) between the two domains. DNA fragments encoding IFN-α(16)Fc and IFN- α-Ala-Fc were inserted, respectively, at the polycloning site of the pcDNA3 expression plasmid. Purified plasmid DNA was then used to transfect NS0 cells by electroporation. Stably-transformed cell lines were selected in the presence of G418. Cell lines expressing these linker variants were then grown in spinner culture flasks. Spent culture supernatant was collected and purified proteins were prepared using the protein A affinity column. Purified proteins were used in the same virus cytopathic effect inhibition assays as described in Example 1. Both IFN-α- Ala-Fc and IFN-α(16)Fc were shown to have equivalent activities (Figure 1).

Constructs for IFNβ-Fc Linker Variants

A number of different constructs of interferon-β linked to an Fc ("IFNβ-Fc") were made, to determine the effect of linker length on the activity of the IFNβ-Fc hybrid. The amino acid sequences of these constructs are listed in the following Table 1. Table 1 Translated Amino Acid Sequences of Various IFNβ-Fc.

Expression of IFNβ-Fc Linker Variants

DNA sequences containing different IFNβ-Fc linker variants were inserted, respectively, at the polycloning site of the pcDNA3 expression plasmid. Purified DNA was then used to transfect NSO cells by electroporation. Stably-transformed cell lines were initially selected in the presence of G418. Cell lines expressing these linker variants were then grown in the absence of G418. Spent culture supernatant was collected and filtered through a 0.22 μm membrane. The concentration of IFNβ-Fc was estimated by PCFIA using purified EFNβ-Fc protein as the standard. Concentrations of culture supernatant were estimated to be 5.4, 22.5, 15.9, 5.7, 10.2, 5.5, and 4.5 μg/ml for the IFNβ-Fc variants containing peptide linkers of 2, 8, 12, 18, 23, 30 and 40 amino acids, respectively. These supernatants were used in the following in vitro cytopathic effect experiments. In vitro Cytopathic Effect Assays using the IFNβ-Fc Variants.

In 96-well plates, human lung carcinoma A549 cells were plated at lOOμl/well containing 5x10⁴ cells using DMEM containing 5% FBS. Plates were incubated at 37°C for 24 hrs in the 5% CO₂ incubator. Culture supernatants containing the IFNβ-Fc linker variants were diluted. These solutions were then used to make 2-fold serial dilutions in a 96-well plate using DMEM containing 5% FBS. One hundred μl of the diluted samples were added to each well and the plates were incubated at 37°C for an additional 24 hours in the incubator. Culture supernatant was removed and encephalomyocarditis (EMC) virus was added at 100 μl/well (the virus is diluted 1:200 in D15 containing 5% FBS from virus stock). The plates were then incubated at 37°C for 48hrs in the 5% CO₂ incubator. Culture supernatant was removed and the wells were washed 2 times with PBS. Cells were then fixed with paraformaldehyde; and stained with the giemsa dye, then left for 5 minutes at room temperature. Thereafter, the plates were rinsed gently with tap water several times. Methanol was added to each well and the wells were read at 630nm using the Dynatech MR5000

ELISA reader.

The results of several experiments with IFNβ-Fc hybrids, as shown in Figure 2, and the results for the two different IFNα-Fc hybrids shown in Example 2, show that the cytopathic effect did not change significantly no matter which linker was used. Further in vivo experiments on one of the IFNα-(16)Fc hybrids were conducted as described below.

Example 3 Animal Tumor Model.

Tumor Initiation in Mice

Female CB17/scid mice (Charles River Laboratories; seven and half weeks old) were inoculated subcutaneously (s.c.) with Daudi Burkitt lymphoma cells at the lower right flarik at a total volume of 100 μl. There were four different cell densities tested in five animals in each group (Table 2). The injection site was monitored one day after inoculation and then daily three weeks after inoculation.

Palpable tumors were measured by caliper. Tumor volume was determined and calculated using the formula, V=4 xyz/3, where 2x, 2y and 2z are the three perpendicular diameters of the tumor and the average of two measurements.

For inoculation, cells were grown in vitro in D15 media with 10% fetal calf serum inlOO ml spinners to a density of 0.6X106/ml with 94% viability. Cells were harvested by centrifugation at 300g for 10 minutes, washed twice in cold PBS, and resuspended to the desired density in PBS. Cell counting and Tryptan Blue staining confirmed the cell density and viability.

Table 2 Cell Density and Route of Inoculation Cell Density No. of Animals Route of Administration

PBS 5 s.c.

0.5X10⁶/100ul PBS 5 s.c.

2.5X10⁶/100ul PBS 5 s.c.

1.25X10⁷/100ul PBS 5 s.c.

Human tumor xenografts became detectable in thel.25X10⁷ group at the site of injection four weeks after inoculation. One week later, the tumor take rate reached 80% and was maintained at this level throughout the entire pilot study period. It took about three weeks (2.5-3.5 wks) for a palpable tumor to grow up to 10-15% of the animal's body weight.

In the 2.5X10⁶ and 0.5X10⁶ groups, the take rate reached 60% by the end of the nine and half weeks. The tumors did not kill the mice and there was no sign of metastases.

Thus, it is concluded that a subcutaneous inoculation of 1.25X10⁷ Daudi Burkitt lymphoma cells will yield about 80% tumor takes in about four weeks.

In vivo Antiproliferation Study Experiment with Daily Dosing

Thirty-two mice inoculated with 12.5X10⁶ Daudi Burkitt lymphoma cells were randomly assigned to one of four treatment groups as shown in Table 3. Roferon A (IFN-α- 2a, Hoffmann La Roche, Nutley, NT) and IFN-α(16)-2a-Fc (having the linker shown in SEQ ID NO: 11) treatment began the day after tumor inoculation. All the animals were dosed daily subcutaneously over the scruff and the treatment continued for eight consecutive weeks. During the treatment period, animals were monitored every 3-4 days for tumor development, and tumor size was measured as above. After the treatment period, weekly observations were continued for additional six months for animals that were tumor free by the time when treatment stopped.

Blood was collected retro-orbitally 24 hours post the last dosing day, one, two and four weeks after termination of the treatment for IFN-α-2a-Fc and one, two and three weeks after termination of Roferon A treatment. Serum Interferon level was determined by ELISA.

Table 3 Dose, Route and Schedule

Group Dose Route of Schedule Administration

Control Diluent s.c. daily

Roferon A lX10⁶IU/100μl s.c. daily

IFN-α-Fc lX10⁶IU/100μl s.c. daily

IFN-α-Fc lX10⁵IU/100μl s.c. daily

Effect of IFN-α on Tumor Take Rate and Tumor Progression Tumor development in different treatment groups is shown in Table 4. In control animals, the first tumor was detected 24 days after inoculation and within 6 days thereafter 7/8 (87.5%) of the animals had developed tumors. The average time of tumor detection was 25.1+ 2.3 days (The mouse that developed a tumor at day 75 was not included.). In Roferon A treated animals, the first tumor became detectable 32 days after the inoculation. After another two weeks, 87.5% had developed tumors. The average tumor detection time was 39.6+4.7 days (t>t ₀._{05 (}i₂₎, PO.05). Roferon A delayed tumor development for about two weeks. IFN-α-2a-Fc treatment at both doses completely prevented the Daudi lymphoma from developing throughout the entire dosing period. At the lower dose, two mice developed detectable tumors at 2 and 19 days after cessation of the treatment. While all mice in 1x10 IU/day group and the remaining six mice in 1X10⁵ IU/daily still remained tumor free six months post treatment. (Table 4). This experiment was repeated once with similar results, as shown in Table 4.

Table 4

Tumor Development in CB17/scid Mice (Exp.l .)

Date of Date of Tumor Development

Mouse I.D. Inoculation Tumor Detection Time (days) Mean+S.D.

C* 116 5/27/98 6/20/98 24

117 5/27/98 6/20/98 24

125 5/27/98 6/20/98 24

134 5/27/98 6/20/98 24

114 5/27/98 6/20/98 24

101 5/27/98 6/22/98 26

119 5/27/98 6/26/98 30 25.1+_2.3

R* 133 5/27/98 6/28/98 32

104 5/27/98 7/1/98 35

103 5/27/98 7/6/98 40

115 5/27/98 7/6/98 40

110 5/27/98 7/7/98 41

113 5/27/98 7/9/98 43

128 5/27/98 7/12/98 48 39.6± 4.7

*C indicates a control

*R indicates that Roferon A was administered at 1X10^{6 Iϋ d y}

Effect of IFN-α on tumor growth rate Once the tumor grew to about 1% of the mouse's body weight, tumor growth rate in control and Roferon A treated animals were very close. In control animals, average tumor volume increased 10 times in two weeks, while Roferon A treated mice showed a 9-fold increase. Table 5 Tumor Take Rate in Different Treatments

Group Treatment Tumor Take Rate (%) (N=8)

Control Diluent 100 (8/8)

Roferon A ιxιo⁶ru/ιooui 87.5 (7/8)

IFN α-2a-Fc ιxιo⁶ ιu/ιooui 0

IFN α-2a-Fc ιxιo⁵ ιu/ιooui 25.0 (2/8)

Quantization of Serum EFN-α Level Serum concentration of IFN-α and IFN-α-2a-Fc was determined by ELISA procedures. In Roferon A treated mice, IFN-α -2a was undetectable 24 hours after the last dose. In IFN-α-2a-Fc treated mice, serum IFN-α-2a-Fc concentration was 3.5 ug/ml for thelxlO⁶ IU/day group and 0.7 ug/ml for the lxlO⁵ IU/day group 22 days after termination of the treatment (Table 6). There was a decrease in serum concentration between 1 and 22 days after the end of the treatment. The data indicate that IFN-α-2a-Fc has a half-life of about one week in mice after being administered subcutaneously 1X10⁶ IU/day or 1X10⁵ IU/day for 8 weeks.

Table 6 Serum IFN-α-2a Level (μg/ml)

Treatment Days Post Treatment Termination

1 22

IFN-α-2a-Fc lX10° IU 25.370+6.885 12.080+3.477 3.477+0.525

IFN-α-2a-Fc 1X10⁵ IU 2.766+1.138 1.549+0.536 0.691+0.141 Roferon A Undetectable Undetectable Undetectable

Experiment with an Increased-Dosing-Interval In this experiment, Roferon A 1X10⁶ IU was given every 3 days and 1X10⁶ IU IFN- α-2a-Fc was dosed every three days and weekly. The results are shown in Table 7. Roferon A 1X10 IU for 3 days failed to show any protection against tumor formation as compared to the control animals in tumor volume and average time for tumor development, while 1X10⁶ IU IFN-α-Fc administered every three days and weekly effectively inhibited the tumor formation during the eight week treatment period. This inhibition extended to seven weeks after the treatment period. Table 7 Tumor Development in animals with an increased dosing intervals

Treatment Tumor Take Rate (%) Average Time for Tumor

Development (N=8) (days)

Control 100 (8/8) 21.1+1.1

Roferon A 10⁶ IU/ 3 days 100 (8/8) 22.0+1.9

IFN-FC 10⁶ IU/ 3 days N/A N/A

ΓFN-FC 10⁶ IU/ weekly N/A N/A

Preliminary study with established Daudi Burkitt Lymphomas Two mice with well established 5-week-old Daudi Burkitt lymphomas were treated with IFN-α-Fc atlO⁶ IU/daily. After ten days, complete regression was observed in both of the animals (Table 8). Two other mice with established 6.5-week-old Daudi lymphomas were treated with 10⁶ IU Roferon A every three days for eight weeks. In the latter mice, tumor volume decreased rapidly, declining from 2.7 cm³ and 4.6 cm³ to 0.3 cm³, a reduction of 89% to 94% in the first two weeks. Complete regression was not achieved.

Table 8 Tumor Regression in Control Mice

Mouse ID. Date Tumor Volume (cm )

416 ] [ 1/20/98 0.195 (7 mm X7.6 mm)

L 1/24/98 0.161 (6.4 mm X7.6 mm)

L 1/25/98 palpable

L 1/26/98 palpable

11/27/98 complete regression

453 1 11/20/98 0.858 (10 mm X 16 mm)

11/24/98 0.393 (6.4 mm X 7.6 mm, 7.6 mm X7.6mm)

11/25/98 palpable

11/26/98 palpable

[ 1/27/98 palpable

[ 1/28/98 barely palpable

[ 1/29/98 complete regression

Summary and Conclusions

A murine human tumor xenograft model has been established by inoculating subcutaneously female CB17/scid mice (six and half weeks old) with 1.25X10⁷ Daudi Burkitt lymphoma cells in the lower right flank at a total volume of 100 μl.

Roferon A 1x10 IU/day treatment delayed the Daudi B cell lymphoma development by two weeks (t>t o.os ₍i₂ P<0.05). IFN-α-2a-Fc 1X10⁶ IU/day completely inhibited the tumor formation throughout the entire dosing period and this inhibition has been extended to six months after termination of the treatment. Partial to full inhibition was also shown in the 1X10⁵ IU /day IFN-α-2a-Fc treated mice.

Roferon A lxlO⁶ IU/ 3 days treatment failed to show any protection against the tumor development whereas Daudi Burkitt lymphoma has been completely inhibited by either IFN- α-Fc at lxl 0⁶ IU/3 days or the IFN-α-2a-Fc lxl 0⁶ IU/ weekly, and inhibition continued for at least seven weeks after cessation of the treatment.

Preliminary data demonstrated that established, 5-week-old Daudi Burkitt lymphomas are completely regressed when treated with EFN-α-2a-Fc 10⁶ IU/daily for ten days. A 90% reduction of tumor volume in 2 weeks is also achieved in Daudi Burkitt lymphomas which were treated with 10⁶ IU Roferon A/every 3 days for seven weeks before the IFN-α-2a-Fc treatment started.

IFN-α-2a-Fc has a half-life of about one week, when administered subcutaneously 1X10⁶ IU/day or 1X10⁵ IU/day for eight weeks.

It should be understood that the terms and expressions used herein are exemplary only and not limiting, and that the scope of the invention is defined only in the claims which follow, and includes all equivalents of the subject matter of those claims.

Claims

What is Claimed is:

1. A protein hybrid comprising an interferon protein covalently linked to an immunoglobulin Fc fragment.

2. The protein hybrid of claim 1 comprising an interferon protein covalently linked at its C- terminal end to the N-terminal end of an immunoglobulin Fc fragment.

3. The protein hybrid of claims 1 or 2 further comprising a peptide linker between the interferon protein and the immunoglobulin Fc fragment wherein the interferon protein is covalently linked at its C-terminal end to the N-terminal end of the peptide linker and the peptide linker is covalently linked at its C-terminal end to the N-terminal end of the immunoglobulin Fc fragment.

4. The protein hybrid of claim 3 wherein the linker comprises Gly Ser repeat units.

5. The protein hybrid of claim 4 wherein the Gly Ser repeat units comprise from 2 to 40 amino acids.

6. The protein hybrid of claim 4 wherein the Gly Ser repeat units comprise from 12 to 15 amino acids.

7. The protein hybrid of claim 4 wherein the Gly Ser repeat units comprise from 17 to 40 amino acids.

8. The protein hybrid of claim 3 wherein the linker comprises a T cell inert amino acid sequence or a non-immunogenic amino acid sequence.

9. The protem hybrid of claims 1, 2, or 3 wherein the interferon protein is selected from the group consisting of interferon-α and interferon-β.

10. The protein hybrid of claims 1, 2, or 3 wherein the interferon protein is interferon-α.

11. The protein hybrid of claim 9 wherein the interferon protein is selected from the group consisting of interferon-α2a or interferon-α2b.

12. The protein hybrid of claims 1, 2, or 3 wherein the Fc fragment is an IgG Fc fragment.

13. The protein hybrid of claims 1, 2, or 3 wherein the Fc fragment is an IgG γ4 chain Fc fragment.

14. The protein hybrid of claims 1, 2, or 3 further comprising another cytokine covalently linked at its C-terminal end to the N-terminal end of the other chain of the immunoglobulin Fc fragment, thereby forming a homodimer.

15. The protein hybrid of claim 14 wherein the cytokine is an interferon.

16. A protein hybrid comprising an interferon protein covalently linked at its C-terminal end to the N-terminal end of a peptide linker that is covalently linked at its C-terminal end to

19 the N-terminal end of an immunoglobulin Fc fragment, wherein the peptide linker comprises Gly Ser repeat units of having 2 to 15 and 17 to 40 amino acids.

17. A method of treating patients with tumors to remove tumors, regress tumors, or delay tumor development, comprising administering the protein hybrid of any of claims 1 to 16 to the patient in amounts effective to remove tumors, regress tumors, or delay tumor development.

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