IE76136B1 - New use of linomide - Google Patents

Description

This invention relates to the use of N-phenyl-N-methyl-1,2hydro-4~hydroxy-l-methyl-2-oxo-quinoline-3-earboxamide or a pharmaceutically acceptable derivative thereof for the manufacture of a medicament having potential use for the treatment of retrovirus in5 fections5 specifically HIV infections, and of patients suffering from acquired immune deficiency syndrome (AIDS) and AIDS related complex (ARC).

Background Acquired immune deficiency syndrome (AIDS) has emerged as a mortal human disease of increasing global importance- As there is no effective therapy known for the treatment cf AIDS, new methods of therapy are urgently needed, and great efforts are being made to develop drugs and vaccines to combat AIDS.

The AIDS virus, first identified in 1983, has been described by several names. It is the third known T-lymphocyte virus (HTLV-III) and has the capacity to replicate within cells of the immune system and thereby lead to a profound destruction of T4 Tcells (or CD4 cells). See e.g. Gallo et al., Science 224, 500-503 (1984), and Popovic et al., Ibid., 497-500 (1984). This retrovirus has been known as lymphadenopathy-associated virus (LAV) or AIDS-related virus (ARV) and, most recently, as human immunodeficiency virus (HIV)» Two distinct AIDS viruses, HIV-1 and HIV-2, have been described. HIV-1 is the virus originally identified in 1983 by Montagnier and co-workers at the Pasteur Institute in Paris [Ann- Virol. Inst. Pasteur 135 E, 119-134 (1984)], while HIV-2 was more recently isolated by Montagnier and his coworkers in 1986 [Nature 326, 662 (1987)]. As used herein, HIV is meant to refer to these viruses in a generic sense.

Although the molecular biology of AIDS is beginning to be unraveled and defined, much more needs to be learned and understood about this disease. In the meantime, numerous approaches are being investigated in the search for potential anti-AIDS drugs and vaccines. i Development of an AIDS vaccine is hampered by lack of understanding of mechanisms of protective immunity against HIV, the magnitude of genetic variation of the virus, and the lack of effective animal models for HIV infection. See, e.g. Koff and Hoth, Science 241, 426-432 (1988).

The first drug to be approved by the US Food and Drug Administration (FDA) for treatment of AIDS was zidovudine, better known under its former name azidothymidine (AZT). Chemically, this drug is 3'-azido-3-deoxythymidine. This drug was originally selected as a potential weapon against AIDS because it was shown to inhibit replication of the virus in vitro. A serious drawback of AZT, however, is its toxic side-effects. In addition to AZT other antiviral agents such as Anasamycin, Ribovirin, Dideoxycytidine and Foscarnet have been developed. So far, however, these agents do not seem to be more advantageous than AZT. Also immunostimulating or irrcnunoadoptive treatments with IFNs or IL2, thymic hormones and factors, transfer factor, and treatments with so called immunostimulating drugs, e.g. isoprinosine, azimexon, tuftsin, bestatin, cimetidine, thymic transplants and HLA matched lymphocyte transfusions or siblings or identical twin bone marrow transplants have been tested but seem to have failed, as underlined in two recent reviews (Gottlieb MS et al, Immunotherapy of the acquired immune deficiency syndrome, In: Gal l in JI, Fauci AS, eds. Advances in hos defense mechanisms. New York: Raven Press, 1985;5:149-70, and Lotze MT. Treatment of immunologic disorders in AIDS. In De Vita VT, Heilman S, Rosenberg SA eds. AIDS etiology, diagnosis, treatment, and prevention. New York: Lippincott J8 company, 1985:235-63).

Summary of the invention According to the present invention it has now surprisingly been shown that N-phenyl-N-methyl-1,2-dihydro-4-hydroxv~l-metbyl2-oxo-quinoline-3-carboxamide has properties that might be useful for the treatment of retrovirus infections, such as HIV infections on mammals including humans, and of patients suffering from AIDS and ARC. N-phenyl-N-methyl-l,2-dihydro-4-hydroxy-l-methyl-2-oxoquinoline-3-carboxamide is also known under the name Linomide® and the generic name roquinimex. The invention also concerns the use of Linomide® or a pharmaceutically acceptable salt thereof such as the, Na or Ca salt for the manufacture of a drug for the treatment of retrovirus infections, especially HIV infections, and of patients suffering from AIDS and AIDS related complex. Linomide® was first described in the US patent 4,547,511 as an immunostimulating agent.

The scientific experimentation with Linomide® has shown that Linomide® has multiple immunological activities. It has thus been found that Linomide® increases the proliferative response to T and B cell mitogens [Larsson, E.L., Joiki, A.L. and Stalhandske, T.: Mechanism of action of the new immunomodulator LS 2616, Int. J. Immunopharmacol. 9:425, 1987], enhances antibody production [Carlsten, H., Tarkowski, A., and Nilsson, L-A: The effect of immunomodulating treatment on cutaneous delayed hypersensitivity in MRL (Ipr/lpr) mice, APMIS 97:728, 1989] and augments NK cell activity [Kalland, T., Aim, G., and Stalhandske, T.: Augmentation of mouse natural killer cell activity by LS 2616, a new immunomodulator, J. Immunol. 134:3956, 1985], [Kalland, T.: Regulation of NK progenitors: Studies with a novel immunmodulator with distinct effects at the precursor level, J. Immunol. 144:4472-6, 1990,].

In view of the fact that Linomide® has been shown to stimulate the T lymphocytes and increase the production of IL-2 it could not be expected that Linomide® should show effect on retrovirus infections as attempts to treat HIV Infected patients with the T cell growth hormone IL-2 accelerated the disease. No doubt, it can be said that stimulation of T lymphocytes in patients with HlV-infections may be a two-edged sword. T helper cells are pivotal in the generation of an immune response, but also the reservoir for the replicating HIV-virus. Also, in view of the fact that the previous experiments with immunostimulating agents have not been successful it is interesting to see the promising results of Linomide®.

Linomide® has the following structural formula: Linomide® may be used as such or as a salt of pharmaceutically acceptable cation. Furthermore,, Linomide® can be used in combination with other anti-AIDS agents.

A conceivable Linomide® dosage range in the treatment of AIDS would be from about 0.1 to about 100 mg a day or possibly higher depending upon the specific condition to be treated, the age and weight of the specific patient, and the specific patient's response to the medication. The exact individual dosage, as well as the daily dosage, will be determined according to standard medical principles under the direction of a physician.

Formulations that could be used according to the present invention are disclosed in US patent No. 4,547,511 col. 11.

As stated above Linomide® is a potent stimulator of T lymphocytes and augments the production of IL-2. The immunpharmacological profile, however, is dominated by a profound increase in natural killer (NK) cell activity with less effects on T cell activity in vivo [Kalland, T.: Effects of the immunomodulator LS 2516 on growth and metastasis of the murine B16-F10 melanoma, Cancer Res. 46:3018, 1986]. In particular, the frequency of CD4 expressing cells is not increased during treatment of mice with Linomide® (Example 2). This finding in combination with promising results on retrovirus infected monkeys makes Linomide® potentially useful in treatment of retrovirus including HIV-infections, AIDS and ARC in spite of potential hazards related fo the T ceil stimulating properties of Linomide®.

The invention is further illustrated by the following examples.

Example 1 Effect of Linomide® on NK activity 7. CYTOTOXICITY Treatment 100:1* 50:1* 25:1* Control 18±4 12±2 8±2 Linomide® 29+5 20+4 14+4 * Effector cell: Target cell ratio Linomide® (ISO mg/kg/day) was given in the drinking water for four days and spleen NK activity against YAC-1 cells determined by a conventional 51Cr-release assay as described [Kalland, T., Aim, G.s and Stalhandske, T.: Augmentation of mouse natural killer cell activity by LS 2616, a new immunomodulator, J. Immunol. 134:3956, 19853- The result from one experiment with 3 C57B1/6 mice per treatment group is shown and demonstrate that Linomide® significantly enhances NK activity.

Example 2 Effect of treatment with Linomide® on spleen T lymphocyte subpopulations: % Fluorescent cells Treatment Thy 1.2 CD4 CDS Control 44±4 31±2 11±2 Linomide 42+5 28+2 10+3 C57B1/6 mice were given Linomide® (160 mg/kg/day) in the drinking water for 4 days. Control animals were given ordinary drinking water. Spleen cells were prepared as described [Kalland, T.s Aim, G., and Stalhandske, T.: Augmentation of mouse natural killer cell activity by LS 2616, a new immunomodulator, J. Immunol. 134:3956, 19853 and examined for the expression of cell surface markers by direct immunofluorescence. The following FITC-labeled monoclonal antibodies were used: HO-134 (Thy 1.2), GK 1.5 (CD4) and 19.178c (CDS) [for reference to antibodies see Kalland, T.: Regulation of NK progenitors: Studies with a novel immunmodulator with distinct effects at the precursor level, J. Immunol. 144:4472-6, 1990]. The number of positive cells was determined by counting 400 cells in an epifluoroscence equipped Leitz microscope. Values represent mean ± SD of three mice. The data suggest that Linomide® do not significantly altier the distribution of T lymphocyte subpopulations.

The results which were obtained with Linomide® and are presented in Examples 1 and 2 show that Linomide® is of potential use in the treatment of HIV-infections.

Example 3 The following experiments with SIV virus support the above in vitro results.

Backoround_of the te£t_model_ Since the HIV-viruses do not infect the most commonly used experimental animals such as rats and mice, alternative models have to be utilized to examine the effect of potential drugs in vivo.

Two principally different approaches can be taken. Scid mice have successfully been reconstituted with human haematopoietic cells and found to be able to carry HIV-virus infected lymphocytes (Namikawa, R,, Kaneshima, H., Lieberman, M., Weissman, I.L., McCune, J.M.: Infection of the SCID-hu mouse by HIV-l. Science 242:1684-6, 1988) . However, the relevance of this model is somewhat questionable, in particular for the investigation of drugs not directly interfering with virus replication but merely acting on host cells. Various species of monkeys have been tested as vehicles for different HIV or SIV viruses. SIV infection of cynomolgus monkeys results in an infection with many similarities to that of AIDS in the human (Putkonen, P., Warstedt, K.. Thorstensson, R., Benthin, R-, Albert, J., Lundgren, B-, Oberg. B-, Norby, E„, Biberfeld, G., Experimental infection of cynomolgus monkeys (Macaca Fascicularis) with simian immunodeficiency virus (SIVsm). J.AIDS Res. 2:359-365, 1989) . Virus can be isolated from lymphoid cells and lymph nodes at particular stages of infection, and antibodies to SIV is readily detectable. Moreover, a profound decrease in the absolute and relative number of CD4+ T cells is a consistently observed. The animals develop clinical disease characterized by enlarged lymph nodes, opportunistic infections, weight loss and wasting syndrome. This model is probably one of the most relevant for in vivo testing of vaccines and drugs designed to treat HIV-infections in humans.

Materials and methods Animals Nine cynomolgus monkeys (Macaca Fascicularis) were used in this study. The mean body mass was 2600 g and the range was 2260 to 2030 g. The monkeys were housed in single cages in a biosafety level three facility» Before use. the animals were controlled for clinical health by physical examination and were confirmed to be free of SIV antibodies by ELISA [Putkonen, P„, Warstedt, K., Thorstensson, R.s Benthin. R., Albert, J., Lundgren, B-, Oberg, B., Norrby, E-, Biberfeld, G.: Experimental infection of cynomolgus monkeys (Macaca Fascicularis) with simian immunodeficiency virus (SIVsm), J. AIDS 1989:2, 359-365]. The absence of pre-existing retrovirus was further investigated by cocultivating monkey PBMC (=peripheral blood mononuclear cells) with human PHA-stimulated PBMC and testing of culture supernatants for reverse transcriptase activity.

Viru£ source As in previous studies [Putkonen, P., Warstedt, K., Thorstensson, R., Benthin, R.s Albert, J., Lundgren, B., Oberg, B., Norrby, E., Biberfeld, G.: Experimental infection of cynomolgus monkeys (Macaca Fascicularis) with simian immunodeficiency virus (SIVsm), J. AIDS 1989:2, 359-365] we used a SIV strain isolated from a naturally infected sooty mangabey monkey (SIVsm). A stock of this virus was previously titred in vivo in monkeys.

Exge r i mental _de s κι n Intraperitoneal treatment with Linomide® or NaCl started four days before challenge with live virus and subsequently every day (not during weekends) subcutaneosly during the time of followup. The follow-up is 75 days after live virus challenge.

Monkeys LI-3 were treated with a low dose Linomide® 0.3 mg/kg bw x 2 Monkeys L4-6 were treated with a high dose Linomide® 3 mg/kg bw x 2 Monkeys L7-9 were given sodium chloride x 2 All monkeys were challenged with 10-100 animal ID50 of live SIVsm. Animals were sacrificed when they became moribund.

Virus 15£ΊδΛΪ°£ £η£ £?£δ1 δηί£9,θ£ detection Virus isolations were performed as previously described [Putkonen, P., Warstedt, K., Thorstensson, R., Benthin, R„, Albert, J. , Lundgren, 8„, Oberg, B., Norrby, E., Biberfeld, G.: Experimental infection of cynomolgus monkeys (Macaca Fascicularis with simian immunodeficiency virus (SIVsm), J. AIDS 1989:2, 359ί365] with one important improvement. The culture supernatants were screened by a sensitive HIV-2/SIV antigen assay [Thorstensson, R., Walther, L., Putkonen, P-, Albert, J., Biberfeld, G: A capture immunoassay for detection of HIV-2/SIV antigen, J. AIDS in press]. Presence of viral antigen in serum was demonstrated as previously described [Thorstensson, R., Walther, L., Putkonen, P., Albert, 3., Biberfeld, G: A capture immunoassay for detection of HIV-2/SIV antigen, J. AIDS in press].

Sero1ogica1 _a ssays Not tested so far.

Lymphocyte_surface_markers_ T-lymphocyte subsets in peripheral blood were determined by immunofluorescence as previously described [Putkonen, P., Warstedt, K. , Thorstensson, R-, Benthin, R., Albert, J., Lundgren, B., Oberg, B., Norrby, E., Biberfeld, G.: Experimental infection of cynomolgus monkeys (Macaca Fascicularis with simian immunodeficiency virus (SIVsm), J. AIDS 1989:2, 359-365]. Peripheral blood samples were incubated with FITC-conjugated anti-CD4 (0KT4, Ortho) and anti-CD8 (Leu2, Becton Dickinson). The samples were analyzed in a Spectrum III flow cytometer (Ortho Diagnostics).

Results All nine monkeys became infected as determined by virus isolation (Table 1). Virus was isolated from all animals on day 14, and 62. Presence of viral antigen in serum was demonstrated 14 days after challenge in all nine monkeys.

Monkeys L4, L6 and L9 were sacrificed 70-82 days after challenge because of severe weight loss and rapid decrease of CD4+ cells (AIDS-like disease). Currently, monkey L7 also is in a bad clinical condition.

Enlargement of peripheral lymph nodes were observed in monkeys L3 and L/.

Monkeys Ll-3 have remained clinically healthy.

Weight curves, CD4 count, 7.CD+ cells and CD4/8 ratio are shown in Figures 1-4.

The body weight of the animals is shown in figure 1. Only a slight weight reduction is seen in monkeys Ll-3 treated with 0.6 mg/kg/day Linomide®. In contrast, one monkey in each of the control group (L9) and one in the high dose Linomide® group showed a dramatic reduction in body weight.

The absolute number and percentage of CD4+ T lymphocytes in peripheral blood was followed with regular intervals during the experiment. The number of CD4+ lymphocytes was severly reduced in the control group at day 75 (0.33xl09/l, 28% of start value) but only slightly reduced in the low dose Linomide® treated group (0.92xl09/l. 70% of start value)(Figure 2). Similarly, the percent age of CD4+ cells in peripheral blood was reduced in control monkeys, but essentially unaltered in monkeys treated with low dose Linomide® (Figure 3). The high dose Linomide® treatment did not significantly alter the number or frequency of CD4 cells in infected monkeys. In a qualitative virus isolation assay, virus could be isolated from all monkeys 14 days after challenge and viral antigens was demonstrated up to 62, the latest time included for this test (Table 1).

The half life of Linomide® differs markedly between species. It is two hours in mice, six hours in cynomolgus monkeys, 24 hours in rats and about 48 hours in humans. The lower dose of Linomide® in the present investigation (0.3 mg/kg x2daily) was based on extrapolations of data on half-life and optimal immunomodulatory activity in mice, rats and humans. Although the dose-response curve of Linomide® in common with many other biological response modifiers have been shown to be bell-shaped, a. supra optimal dose (3 mg/kg x2 daily) was also included to examine possible direct effects of Linomide® on viral replication.

Claims (8)

1. The use of Linomide® or a pharmaceutically acceptable salt thereof for the manufacture of a medicament for the treatment of retrovirus infections.

2. The use according to claim 1 for the treatment of HiV-infections.

3. The use according to claim 1 for the treatment of AIDS and AIDS related complex.

4. The use according to any of the preceding claims characterized in that Linomide® is used in combination with one or more other anti-AIDS agents. 5. The use according to any one of the claims 2-4 for increasing the T4 cell number.

5. The use according to any of the preceding claims wherein the medicament is for oral administration.

6. 7. Tha use according to any one of the claims 1-5 wherein the medicament is for parenteral administration.

7.

8. Use according to claim 1 , substantially as hereinbefore described and exemplified.