Haemozoin (β‐haematin) biomineralization occurs by self‐assembly near the lipid/water interface

Egan, Timothy J.; Chen, Jeff Yu-Jen; Villiers, Katherine A. de; Mabotha, Tebogo E; Naidoo, Kevin J.; Ncokazi, Kanyile K.; Langford, Steven J.; McNaughton, Donald; Pandiancherri, Shveta; Wood, Bayden Robert

doi:10.1016/j.febslet.2006.08.043

Cited by 127 publications

(202 citation statements)

References 32 publications

(62 reference statements)

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“…This means that the metal complex probably accumulates near water-lipid interface regions within the digestive vacuole of the parasite, rather than deeply inside the aqueous regions where CQ concentrates. This observation, together with the idea that lipids catalyze heme aggregation within plasmodium food vacuoles [47,48] and with the findings of Egan et al [36] that β-hematin spontaneously forms by rapid self-assembly near octanol-water or lipid-water interfaces can explain the enhanced antimalarial activity of complex 1 both in vitro and in vivo, when compared with CQ. Furthermore, the fact that the complex is active against CQ-resistant strains of P. falciparum may also be related to its greater lipophilicity, in line with previous reports indicating a lowered ability of the mutated transmembrane transporter PfCRT to promote the efflux of highly lipophilic drugs [40,51].…”

Section: Discussionmentioning

confidence: 57%

“…This is important in connection with the proposal that lipids catalyze heme aggregation, probably by increasing heme solubility in acidic environments [47]; neutral lipids that catalyze the formation of hemozoin in vitro have been shown to form lipid bodies associated with plasmodium food vacuoles [48]. Egan et al [36] recently demonstrated that under acidic physiologically realistic conditions β-hematin spontaneously forms by rapid selfassembly near octanol-water, pentanol-water, or lipid-water interfaces. Our partition data (Fig.…”

Section: Partition Coefficient Measurements As a Function Of Phmentioning

confidence: 99%

“…Inhibition of the heme aggregation at the interface of n-octanol-aqueous buffer mixtures was studied following a modification of the method described by Egan et al [36]. To establish a base line for the aggregation process, hemin was dissolved in 0.1 M NaOH solution to generate hematin and acetone was added until the acetone-to-water ratio was 4:6; the final solution contained 15 mg hematin per milliliter.…”

Section: Heme Aggregation Inhibition At An N-octanol-acidic Buffer Inmentioning

confidence: 99%

“…4b, when the inhibition assay was conducted in a 1:1 n-octanol-water mixture, a simple model of a waterlipid interface [49], following an adaptation of the procedure described by Egan et al [36] in which both the hematin and the drug are carefully introduced close to the interface, the overall process is much faster (30 min), and more importantly, the activity trend is reversed and complex 1 was significantly more efficient than CQDP (50% inhibition at drug-to-hemin concentration ratios of approximately 1.2 and 2.0, respectively). These results, together with the observation of Egan et al that β-hematin rapidly forms near octanol-water or lipid-water interfaces [36], led to the idea that a drug that concentrates near such interfaces at a pH value typical of the acidic food vacuole of Plasmodium parasites should be in a better position than the highly hydrophilic CQ to inhibit the process of heme aggregation, and this provides an explanation for the higher antimalarial activity of complex 1 compared with CQDP [28].…”

Section: Heme Aggregation Inhibition Activity Of Complex 1 In Acetatementioning

confidence: 99%

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The mechanism of antimalarial action of the ruthenium(II)–chloroquine complex [RuCl2(CQ)]2

et al. 2008

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The mechanism of antimalarial action of the ruthenium-chloroquine complex [RuCl 2 (CQ)] 2 (1), previously shown by us to be active in vitro against CQ-resistant strains of Plasmodium falciparum and in vivo against P. berghei, has been investigated. The complex is rapidly hydrolyzed in aqueous solution to [RuCl(OH 2 ) 3 (CQ)] 2 [Cl] 2 , which is probably the active species. This compound binds to hematin in solution and inhibits aggregation to β-hematin at pH ∼ 5 to a slightly lower extent than chloroquine diphosphate; more importantly, the heme aggregation inhibition activity of complex 1 is significantly higher than that of CQ when measured at the interface of noctanol-aqueous acetate buffer mixtures under acidic conditions modeling the food vacuole of the parasite. Partition coefficient measurements confirmed that complex 1 is considerably more lipophilic than CQ in n-octanol-water mixtures at pH ∼ 5. This suggests that the principal target of complex 1 is the heme aggregation process, which has recently been reported to be fast and spontaneous at or near water-lipid interfaces. The enhanced antimalarial activity of complex 1 is thus probably due to a higher effective concentration of the drug at or near the interface compared with that of CQ, which accumulates strongly in the aqueous regions of the vacuole under those conditions. Furthermore, the activity of complex 1 against CQ-resistant strains of P. falciparum is probably related to its greater lipophilicity, in line with previous reports indicating a lowered ability of the mutated transmembrane transporter PfCRT to promote the efflux of highly lipophilic drugs. The metal complex also interacts with DNA by intercalation, to a comparable extent and in a similar manner to uncomplexed CQ and therefore DNA binding does not appear to be an important part of the mechanism of antimalarial action in this case.

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Section: Discussionmentioning

confidence: 57%

Section: Partition Coefficient Measurements As a Function Of Phmentioning

confidence: 99%

Section: Heme Aggregation Inhibition At An N-octanol-acidic Buffer Inmentioning

confidence: 99%

Section: Heme Aggregation Inhibition Activity Of Complex 1 In Acetatementioning

confidence: 99%

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The mechanism of antimalarial action of the ruthenium(II)–chloroquine complex [RuCl2(CQ)]2

et al. 2008

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“…On the premise that hemozoin nucleation is induced via a surface layer of lipid glycerol groups that expose OH, CH 2 , and oxygen lonepairs, nucleation was predicted to occur via the {100} face, which exposes CO 2 H and C─H groups (5). Precipitation of micron-sized crystals of β-hematin from a myristoyl-glycerol solution/water interface was reported by Egan et al (6). The orientation of such crystals at the water surface was identified by grazing incidence X-ray diffraction, revealing crystals floating on their {100} faces, but not the presence of lipid layers (7).…”

mentioning

confidence: 99%

Aligned hemozoin crystals in curved clusters in malarial red blood cells revealed by nanoprobe X-ray Fe fluorescence and diffraction

Kapishnikov

Berthing

Hviid

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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The human malaria parasite Plasmodium falciparum detoxifies the heme byproduct of hemoglobin digestion in infected red blood cells by sequestration into submicron-sized hemozoin crystals. The crystal is composed of heme units interlinked to form cyclic dimers via reciprocal Fe─O (propionate) bonds. Templated hemozoin nucleation was envisaged to explain a classic observation by electron microscopy of a cluster of aligned hemozoin crystals within the parasite digestive vacuole. This dovetails with evidence that acylglycerol lipids are involved in hemozoin nucleation in vivo, and nucleation of β-hematin, the synthetic analogue of hemozoin, was consistently induced at an acylglycerol-water interface via their {100} crystal faces. In order to ascertain the nature of hemozoin nucleation in vivo, we probed the mutual orientations of hemozoin crystals in situ within RBCs using synchrotron-based X-ray nanoprobe Fe fluorescence and diffraction. The X-ray patterns indicated the presence of hemozoin clusters, each comprising several crystals aligned along their needle c axes and exposing {100} side faces to an approximately cylindrical surface, suggestive of nucleation via a common lipid layer. This experimental finding, and the associated nucleation model, are difficult to reconcile with recent reports of hemozoin formation within lipid droplets in the digestive vacuole. The diffraction results are verified by a study of the nucleation process using emerging tools of three-dimensional cellular microscopy, described in the companion paper.crystal nucleation | optical birefringence | X-ray diffraction | submicrofocus X-ray fluorescence | lipid-induced precipitation

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Hemozoin: A Paradigm for Biominerals in Disease

Carter

Hoang

Wright

2008

Wiley Encyclopedia of Chemical Biology

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Biomineralization is the formation of organic–inorganic composites by organisms. Originally evolved as a protective mechanism, this complex process has also become a recognized contributor to several disease states, which range from kidney stone disease (nephrolithiasis) to parasitic diseases like malaria. The characteristic three‐step process for the formation of biominerals is defined by the supramolecular preorganization of a nucleating template, the interfacial molecular recognition of crystal nuclei and the cellular processing of resultant aggregates. Hemozoin formed in the heme detoxification pathway used by the malarial parasite Plasmodium falciparum represents a paradigm for pathogenic biominerals. Current research indicates that a supramolecular lipid template organizes heme released previously during hemoglobin catabolism. Nucleation and growth of the heme aggregate serves to protect the parasite from the toxic effects of free heme. Given the mechanisms of biomineralization, it is not surprising to discover that century‐old antimalarial compounds function by disrupting key interactions between the heme substrate and template. Subsequently, the heme‐aggregate is released into the host vasculature and deposits in patients' brains, spleens, and livers where it disrupts host innate immune response. The underlying basis of this immunomodulating activity seems to result from hemozoin mediated lipid peroxidation. Understanding the relationships between hemozoin formation and its pathogenic activity with the host immune response represents a significant challenge to chemical biology.

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Haemozoin (β‐haematin) biomineralization occurs by self‐assembly near the lipid/water interface

Cited by 127 publications

References 32 publications

The mechanism of antimalarial action of the ruthenium(II)–chloroquine complex [RuCl2(CQ)]2

The mechanism of antimalarial action of the ruthenium(II)–chloroquine complex [RuCl2(CQ)]2

Aligned hemozoin crystals in curved clusters in malarial red blood cells revealed by nanoprobe X-ray Fe fluorescence and diffraction

Hemozoin: A Paradigm for Biominerals in Disease

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