Pharmacologic actions of 4-aminoquinoline compounds

Pharmacologic Actions of 4-Aminoquinoline Compounds

ALLEN H. MACKENZIE, M.D. Cleveland, Ohio

The pharmacokinetics, physiologic effects, and the metabolization of chloroquine and hydroxychloroquine are all similar. Their concentrations in plasma and tissue are directly related to dally dosing. The highest concentrations are found in melanin-containing tissues, particularly the choroid and ciliary body of the eye. The pharmacologic effects of 4-aminoquinoline compounds are reviewed in detail. It is likely that the rheumatologic effectiveness of these agents is primarily related to lysosomal actions. The drug-induced lysosomal abnormalities include diminished vesicle fusion, diminished exocytosis, and reversible “lysosomal storage disease.” It is likely that the retinal toxicity of these drugs is one manifestation of the altered lysosomal physiology involving the retinal pigmented epithelium. Tissue of retinal pigmented epithelium is similar to that of the bone-marrow-derived macrophage. Depression of extra-oculogram is an early sign of excessive dosage and can be used to measure potential toxicity during therapy with 4-aminoquinolines. Dosages ranging from 3.5 to 4.0 mg/kg per day for chloroquine and 6.0 to 6.5 mg/kg per day for hydroxychloroqulne are clinically safe. The beneficial effects of 4-aminoquinoline compounds in the management of rheumatoid arthritis, systemic lupus erythematosus (SLE), and other connective tissue diseases were discovered through serendipity [ 1,2]. While subsequent controlled studies have amply demonstrated the efficacy of these compounds in treating rheumatoid arthritis [3-111, and have established a level of efficacy for the management of SLE, use in juvenile rheumatoid arthritis [2,12] is investigational. They should only be used under approved protocols by experienced clinicians. METABOLISM

From the Department of Rheumatic and Immunologic Disease, Cleveland Clinic Foundation, Cleveland, Ohio. Requests for reprints should be addressed to Dr. Allen H. Mackenzie, Department of Rheumatic and Immunologic Disease, Cleveland Clinic Foundation, 9500 Euclid Avenue, Cleveland, Ohio 44106.

Currently, the two most used 4-aminoquinoline compounds are chloroquine phosphate, more popular in Europe [ 13,141, and hydroxychloroquine sulfate, more popular in the United States [ 15-l 7] _ These two agents are very similar antimalarials, differing only in a single hydroxyl group at the end of the side chain. Both are also similar in kinetics [ 181, actions [ 1,191, and metabolism [20,21]. I will therefore treat them alike; what I say of one, largely applies to the other. These basic amines have a heterocyclic planar rl-aminoquinoline nucleus at one end of the polar molecule and a lipophilic side chain on the other end [22], and their kinetics have been fairly well studied [ 181. They are rapidly and completely absorbed when given by mouth [21], and approximately 50 percent are transported by binding to serum proteins [23,24]. Their elimination proceeds in two stages. In the first stage there is rapid excretion with a half-time of

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PLAQuENILSYMPOS~UM--MACKENZIE

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INTESTINE

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and spleen; yet higher concentrations occur in kidney, bone marrow, lungs, and liver, while even higher concentrations are found in the adrenal glands and pituitary and the highest of all occur in melanin-containing tissues, particularly the choroid and ciliary body of the eye [20,28-301. Concentrations several hundred times those in the serum are found in liver, where an approximately 1 X 10e4 M concentration is found at therapeutic serum concentration (1 X lo+ M) [ 19,3 l-331. The therapeutic serum concentrations attainable in man at a clinically safe dosage of chloroquine (3.5 to 4.0 mg/kg per day) [34], produces serum levels of 0.6 to 0.9 pmol/L 119,311. For hydroxychloroquine, safe daily dosage (6 to 6.5 mg/kg per day) 1341 produces serum levels of 1.4 to 1.5 pmol/L [ 19,311. PHARMACOLOGIC

I...

___

Fbure 1.

Diagram of the kinetics, distribution, therapeutic tissue concentration levels, anddisposition of hydroxychloroquine in man 1331.

about three days. The second stage has a more prolonged half-time of about 18 days. Clinical half-life, on the other hand, is 50 to 52 hours for each agent, rising to a higher value at very high serum concentrations [ 181 (Figure 1). About 50 percent of the administered dose has been identifiably recovered [21]. Thus, of the identifiable 4-aminoquinoline compounds excreted, 50 to 60 percent is in the urine, while 8 to 10 percent of chloroquine and up to 15 to 24 percent of hydroxychloroquine is fecally excreted [ 251. Hydroxychloroquine is reportedly conjugated with glucuronide and excreted in the bile [ 20,211. Unknown amounts of 4-aminoquinoline compounds are deposited into dermal cells and appendages, and sloughed off by the skin [ 261. The remainder is thought to be metabolically biotransformed to molecules not readily perceived as being derived from 4-aminoquinoline compounds [ 201. The 4-aminoquinoline compounds attain plasma concentrations that are directly related to the magnitude of the daily dosage [ 231 in a clear-cut, dose-response relationship (Figure 2). At a given serum concentration, the drug is distributed throughout various body tissues, depending upon tissue affinity for the compound [ 271. Fat, bone, tendon, and brain contain relatively small amounts of 4-aminoquinolines [ 201. Lowest tissue concentrations are found in skeletal muscle, skin, and sclera; the next higher concentrations are found in heart

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EFFECTS

Although a broad spectrum of biologic actions of 4aminoquinolines is demonstrable in vitro. or in animals at higher concentrations, these effects are not clinically valuable because they require dosage levels that are too toxic to permit prolonged therapy. Thus, the actions of antimalarial drugs at the above-mentioned.concentrations are the only effects safely attainable in vivo [ 11. The spectrum of pharmacologic actions that pertain in rheumatology probably span the concentration range from 10m7 M to 10m4 M in tissues, but never higher than about 1.5 X 10m6 M in serum. In this concentration range, three principal groups of effects are observable: 1. The 4-aminoquinolines form a complex with ferriprotoporphyrin IX, an intermediary product of hemoglobin digestion by malarial parasites (plasmodia) (351. This complex is so toxic that ions are lost from the parasite cells, osmotic lysis occurs, and malaria is inhibited or cured. Plasmodia resistant to the chloroquine action digest little hemoglobin. Such resistant plasmodia appear no more susceptible to chloroquine than are the cells of the host. 2. Chloroquine influences the behavior of lysosomes, interfering with the vesicle fusion process in a cell [36,37]. Lysosomes increase in number, increase in volume, decrease in density, and develop lamellar membrane structures called myeloid (or myelin) bodies [38-411. Such myelin bodies are thought to be phospholipid configurations [37,41] in phagocytic or autophagic vacuoles. Treated cells are unable to proceed at normal rates with orderly pinocytosis 1421, exoplasmosis, and phagolysosomal fusion [43], with the result that large quantities of cellular membrane are sequestered within the cell in the increased number of lysosomal vesicles. These vesicles contain or consist of plasma membrane phospholipids 1411, with attached cell receptors [ 421. This population of vesicles normally

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10-5M

500 mg/d

(13 3mg/Kg/d)

10e6M

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(4 mg/Kg/d)

/

10e7M 500mghk

Figure 2. A family of curves showing the time course to attainment of plateau concentrations of chloroquine in plasma, and the dependence of plateau plasma concentration on daily dosage rate. While these curves describe the dynamics of chloroquine, hydroxychioroquine behaves in much the same way [d-6,25,26].

(I 2mg/Kg/d (0 6mg/Kg/d

0

eqwalent) equwalent)

2

I MONTHS

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recycles intact units of membrane rapidly from the surface of the cell into pinocytic and phagosomal vesicles, to the endoplasmic reticulum and golgi, thence back to the cell surface. Primary lysosomes possess a membrane composition similar to that of the plasma membrane [44]. The entire cell surface membrane of a working phagocyte of the macrophage type is recycled approximately every five minutes [42]. A number of specific absorptive endocytosis systems are thought to require this membrane with its receptors in order to operate efficiently. Sequestration of so much plasma membrane in the stabilized vesicles depletes the cell surface of receptors for all manner of molecules, because these receptor sites are imbedded into the phospholipid plasma membrane [42,43]. The depletion of cell surface receptors probably diminishes the rate or efficiency with which a cell responds to its environment. This has been well proven to be true for acid hydrolases [42] of several types, but probably applies also to other receptors, for example, those for phytohemagglutinin. Phytohemagglutinin responsiveness is diminished in chloroquine-treated cells [45,46]. Thymidine uptake has been shown to be diminished. However, the 4-aminoquinoline compounds do not affect receptor affinity [42]. Depletion of cell surface receptors caused by reversible inhibition of membrane recycling appears to be the mechanism, rather than blockade of receptors [43]. Complex functions, such as phagocytosis [47] and chemotaxis [48], are probably dependent on these receptors. Although these effects are completely reversible [42], cellular efficiency is greatly diminished [36]. The growth of cells is inhibited, and a significant amount of cell death will occur at concentrations in excess of therapeutic levels [46]. The mechanism by which the 4-aminoquinoline drugs inhibit vesicle fusion is not yet clear. Some data suggest a chloroquine/clathrin interaction in which the latter is solubilized [49]. Clathrin is a structural protein, coating vesicle walls, which is probably involved in vesicle fusion [44,50,51]. The properties of clathrin are

altered by lysosomotropic amines, elevated pH, and other factors [49]. 3. In the presence of chloroquine or hydroxychloroquine, the digestive efficiency of phagolysosomes is diminished [38,52,53]. Studies have shown delayed digestion during cellular autophagy in the presence of 4-aminoquinoline drugs for several differing constituents: (1) some cellular proteins, (2) mucopolysaccharides, (3) hormones, and (4) phospholipids [53]. The controlled autophagy necessary to the early stages of derepression in a transforming lymphocyte [46,52] or in a cell preparing to undergo mitosis is delayed. The basic amine molecules become concentrated in the lysosomes. The drug passively diffuses into the cell in a lipophilic basic unprotonated state, but once it enters the acid milieu of a lysosome (pH about 4.0), the 4aminoquinoline compound becomes progressively protonated [49]. Protonation renders the side chain more lipophobic, and hence traps the drug within the lysosome. The entry into the cell is by passive diffusion, not requiring energy, but the trapping mechanism depends upon the proton pump in the wall of the lysosome, which does require energy. The pH of a chloroquinetreated lysosome rises from about 4.0 or 4.5 to approximately 6.0 pH units [54]. It is not certain how hydroxychloroquine and chloroquine interfere with lysosomal digestion. Since the pH rises within the lysosome, it conceivably could rise enough to exceed the optimal range for acid hydrolases to perform their digestive functions. In addition, the dissociation of the lysosomal hydrolases from their mannosyl recognition marker “receptor” does not take place with normal speed in the presence of chloroquine [42]. This inhibits the discharge of contained enzymes into a phagosome or to the cell surface. There seems to be a real likelihood that such important cellular activities as feeding, secreting, excreting, synthesis, mitosis, immune transformation, and autophagy [55] depend upon a functional lysosomal system. Thus, the sequestration of receptors within the altered lysosomes could depress immune

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responsiveness by depletion of appropriate receptors. Add to this the delayed vesicle fusion and inhibited phagosomal digestion, and the outcome is considerable reversible interference in cell work. 4. The 4-aminoquinoline compounds are bound to numerous tissue constituents such as nucleoproteins [ 561, melanins [ 281, porphyrins [35,57], and the like. This begins to be significant at about 1 X 10m6 M serum concentration and becomes much more intense at higher concentrations. The effect on nucleoprotein alters the physical properties of DNA and RNA, thus delaying excision and repair and diminishing the efficiency of polymerases [ 58-611. Effects attainable at still higher concentrations do not appear to be therapeutically significant. In summary, it appears likely that the rheumatologic effectiveness of the 4-aminoquinoline drugs is related primarily to the lysosomal actions. These take place at concentrations safely attainable in the plasma of patients during therapy. ABNORMAL

LYSOSOMAL

FUNCTIONS

Three 4-aminoquinoline-induced abnormalities of lysosomal function are known to occur: 1. Chloroquine diminishes vesicle fusion, perhaps by modifying clathrin [49]. This sequesters large quantities of plasma membrane in the lysosomes, thus trapping as much as 50 percent of receptors within, away from the cell surface [42]. This would appear to alter the cell’s responsiveness, not only to many ordinary stimuli, but probably also to immune stimuli. 2. Exocytosis of cell products is diminished by the same inhibition of vesicle fusion. Salmeron and Lipsky [62] have found lnterleukin 1 concentration to be greatly diminished in vitro when using very low concentrations of chloroquine. Conceivably, lnterleukin 1 is secreted via exocytosis of transport vesicles, via carrier-receptors, or via both. Cells rich in lysosomes appear particularly susceptible to these effects of the 4-aminoquinoline compounds. Polymorphonuclear leucocytes, macrophages, synovial macrophages, and retinal pigmented epithelium macrophages are all altered in morphology and in biologic responses by 4aminoquinolines in therapeutic concentrations. 3. Lie and Schofield [38] have drawn the analogy of resemblance to a “lysosomal storage disease” during therapy with chloroquine. Storage results when diges-

tive processes cannot proceed to completion, so that residual matter is left in lysosomes/phagosomes unable to be exocytosed. RETINAL

PIGMENTED

EPITHELIUM

Elner et al [63] have put forth evidence that the retinal pigmented epithelium is a tissue very similar in its structure and responses to bone marrow-derived macrophages. The cells of retinal pigmented epithelium possess microvilli and numerous ruffles under electron microscopy, and they demonstrate phagocytosis, glass adherence, and the ability to phagocytose erythrocytes coated with antibodies. It is the duty of the retinal pigmented epithelium to scavenge, to phagocytose, and intracellularly to digest the aged photoreceptor membrane discs in its phagolysosomes. Photoreceptor discs are shed diurnally from the tip of the rod and cone cells under the influence of light. Potts [29] has demonstrated dose-related depression of retinal pigmented epithelium metabolism, which is reversible up to very high drug concentration levels. The photoreceptor lesion appears to be largely secondary to retinal pigmented epithelium depression during 4-aminoquinoline therapy, and it too has been reversible up to the point of extensive cell death, which correlates with excessive daily doses. The biologic current generated in the retinal pigmented epithelium is measured as the extra-oculogram. Depression of the extra-oculogram is an early sign of excessive 4-aminoquinoline dosage, and has been used to monitor eyes during therapy [ 141. It is reasonable to suspect that a dosage-dependent, pharmacologicinduced lysosomal storage disease of the retinal pigmented epithelium might cause retinal dystrophy from inefficient elimination of photoreceptor cell debris. It is also reasonable to suspect that a threshold level of this phenomenon can be defined in terms of dosage or concentration, above which toxicity develops but below which therapy may be conducted in relative safety [34,64,65]. Since the retinal lesion is the only medically significant toxicity of antimalarial drugs [66], all other adverse effects being reversible, studies were undertaken to attempt to define a therapeutically safe zone, and the threshold of toxicity. These will be discussed in my paper, “Dose Refinements in Long-Term Therapy of Rheumatoid Arthritis with Antimalarial%” appearing elsewhere in this symposium issue.

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