Hemoglobinopathies: slicing the Gordian knot of Plasmodium falciparum malaria pathogenesis.

Plasmodium falciparum malaria kills over 500,000 children every year and has been a scourge of humans for millennia. Owing to the co-evolution of humans and P. falciparum parasites, the human genome is imprinted with polymorphisms that not only confer innate resistance to falciparum malaria, but also cause hemoglobinopathies. These genetic traits--including hemoglobin S (HbS), hemoglobin C (HbC), and α-thalassemia--are the most common monogenic human disorders and can confer remarkable degrees of protection from severe, life-threatening falciparum malaria in African children: the risk is reduced 70% by homozygous HbC and 90% by heterozygous HbS (sickle-cell trait). Importantly, this protection is principally present for severe disease and largely absent for P. falciparum infection, suggesting that these hemoglobinopathies specifically neutralize the parasite's in vivo mechanisms of pathogenesis. These hemoglobin variants thus represent a "natural experiment" to identify the cellular and molecular mechanisms by which P. falciparum produces clinical morbidity, which remain partially obscured due to the complexity of interactions between this parasite and its human host. Multiple lines of evidence support a restriction of parasite growth by various hemoglobinopathies, and recent data suggest this phenomenon may result from host microRNA interference with parasite metabolism. Multiple hemoglobinopathies mitigate the pathogenic potential of parasites by interfering with the export of P. falciparum erythrocyte membrane protein 1 (PfEMP1) to the surface of the host red blood cell. Few studies have investigated their effects upon the activation of the innate and adaptive immune systems, although recent murine studies suggest a role for heme oxygenase-1 in protection. Ultimately, the identification of mechanisms of protection and pathogenesis can inform future therapeutics and preventive measures. Hemoglobinopathies slice the "Gordian knot" of host and parasite interactions to confer malaria protection, and offer a translational model to identify the most critical mechanisms of P. falciparum pathogenesis.

Introduction

In the 4th century BC, Alexander the Great conquered the known Western world [1]. Prior to his conquests in Asia, he encountered the Gordian knot, a complex knot of bark affixing a mythic ox-cart to a post in the town of Gordium. Alexander—a pupil of Aristotle—set his mind to untangling the knot, but, like others before him, could not find the ends (and thus the means) to do so. Faced with this intractable problem, Alexander sliced through the Gordian knot with a stroke of his sword and freed the cart. As one of history's greatest military commanders, Alexander subsequently assembled and ruled an empire stretching from the Eastern Mediterranean to the Himalayas while remaining undefeated in battle. These military conquests were presaged by his “Alexandrian solution” to the Gordian knot, demonstrating decisiveness and imagination in the face of a complex and seemingly unsolvable problem.

Malaria is an ancient disease that has persisted to our modern age, intractably killing over 500,000 children in sub-Saharan Africa each year [2]. While current interventions are succeeding in reducing its morbidity in some contexts [3]–[5], further improvements in our fundamental understanding of the pathogenesis of Plasmodium falciparum malaria are clearly needed to identify the molecular and cellular targets of next-generation therapeutics and preventive measures. The mechanisms of falciparum malaria pathogenesis remain obscure owing to the complex tangle of parasite virulence factors, host susceptibility traits, and innate and adaptive immune responses that modulate the development of distinct malaria syndromes [6], [7].

We propose that hemoglobinopathies slice the Gordian knot of falciparum malaria pathogenesis to protect children from the severe, life-threatening manifestations of the disease. Most strikingly, heterozygous hemoglobin S (HbAS, or sickle-cell trait) and homozygous hemoglobin C (HbCC, or hemoglobin C disease) reduce the risk of severe falciparum malaria in sub-Saharan African children by 90% and 70%, respectively [8]. These structural hemoglobin variants do not protect from P. falciparum infection [8], suggesting they interfere with the specific molecular mechanisms responsible for the morbidity of falciparum malaria. By isolating these pathogenic processes and solving the Gordian knot of malaria pathogenesis, hemoglobinopathies offer an attractive “natural experiment” to identify the molecular correlates of clinical morbidity. These correlates may be amenable to exploitation by future parasiticidal, adjunctive, or preventive therapies, thereby yielding targets for a new “Alexandrian solution” to the world's falciparum malaria problem.

Here we review the proposed mechanisms by which hemoglobinopathies (and fetal hemoglobin) protect against falciparum malaria.

The Red Blood Cell and Plasmodium falciparum Parasites

The red blood cell (RBC) is critical for the propagation of malaria parasites (Figure 1A). After inoculation into a human by a mosquito and a brief, clinically silent incubation in the liver, P. falciparum parasites enter the erythrocytic stage of their life-cycle. It is during this time that parasites sequentially invade and egress from their host RBCs and cause the signs and symptoms of malaria. While developing within the RBC, the parasite traffics proteins to the RBC surface that mediate binding to extracellular host receptors and enable the parasite to sequester in the placenta, brain, and virtually every other organ. The attenuation of malaria by repeated, sub-lethal P. falciparum infections suggests a significant role for adaptive immunity, but the targets of this attenuating immune response remain largely obscure. Though this adaptive immunity can be protective, the development of maladaptive and dysregulated immune responses can also contribute to the pathogenesis of malaria.

Figure 1

General mechanisms by which hemoglobinopathies may attenuate the pathogenesis of falciparum malaria.

(A) Restriction of red blood cell (RBC) invasion or intraerythrocytic growth, thereby suppressing parasite densities in vivo; (B) interference with parasite-derived mediators of pathogenesis, including those involved in the binding of parasite-infected RBCs (iRBCs) to extracellular host receptors; (C) modulation of innate host defenses to favor protective, anti-inflammatory responses over those that drive pathogenic, pro-inflammatory responses; (D) enhancement of adaptive cell-mediated and humoral immune responses that clear iRBCs from the blood.

Variant RBCs are produced from some of the most common human genetic polymorphisms, and for over 60 years their widespread prevalence has been hypothesized to result from their evolutionary selection by severe, life-threatening falciparum malaria [9]. This natural selection is supported convincingly by clinical data for several common hemoglobin disorders (reviewed in [8]). Hemoglobin is the oxygen-carrying component and major protein of the RBC, and is normally formed as a tetramer of two α-globins and two β-globins which constitute adult hemoglobin A (HbA). The major hemoglobinopathies result from molecular lesions that either decrease the production of α- or β-globins (in α- and β-thalassemia, respectively) or encode single amino acid substitutions in β-globin (in HbS, HbC, and hemoglobin E [HbE]) (Table 1) [10]. The most severe hemoglobinopathies—HbSS homozygosity (sickle-cell disease) and the thalassemias major—are typically incompatible with life beyond early childhood without sophisticated medical care. Other hemoglobin traits such as HbAS, HbAC, HbCC, HbAE, HbEE, and the thalassemias minor are associated with essentially normal life-spans and far less directly attributable morbidity. Remarkably, these simple polymorphisms confer dramatic levels of protection from a complex disease: for HbAS, the substitution of glycine with valine at amino acid position 6 in only one of two β-globin chains reduces a child's risk of severe falciparum malaria by about 90% [8].

Table 1

The major hemoglobinopathies: epidemiology, molecular pathology, and clinical phenotype.

Hemoglobinopathy	Epidemiology	Genotype	Molecular Pathology	Clinical Phenotype
α-thalassemias
Trait
α+-thal trait	Global	Loss of one α-globin gene (αα/α-)		Asymptomatic; normal RBC size, quantity, and peripheral blood smear
α0-thal trait	Global	Loss of two α-globin genes (αα/–)		Mild anemia
Hemoglobin H (HbH) disease	Global	Loss of three α-globin genes (α-/–)	Accumulation of unpaired β-chains that form HbH and precipitate in RBCs	Chronic hemolytic anemia with hepatic, splenic, skeletal, and metabolic sequelae; transfusion support required in 2nd to 3rd decade of life
Hydrops fetalis/Hb Barts	Global	Loss of all four α-globin genes (–/–)	Accumulation of unpaired γ-chains in utero, forming Hb Bart's, which is unable to release oxygen	Incompatible with extra-uterine life
β-thalassemias
Minor/trait/heterozygosity	Global	Reduced expression of one β-globin gene		Typically asymptomatic; normal hematocrit, low mean corpuscular volume
Major	Global	Reduced expression of both β-globin genes	Accumulation of unpaired α-chains, leading to oxidant damage to RBCs and erythroid precursors	Profound anemia leading to transfusion dependence, complicated by iron overload
Hemoglobin S	Central, East, and West Africa; Arabian peninsula; South Asia	Glu→Val at position 6 of β-globin	Aggregation of deoxygenated HbS into polymers, leading to RBC deformation, hemolysis, and microcirculatory obstruction	Sickle-cell disease with frequent pain crises, transfusions, and acute chest syndrome when inherited as HbSS; asymptomatic when inherited as HbAS
Hemoglobin C	West Africa, centered on western Burkina Faso and northern Ghana	Glu→Lys at position 6 of β-globin	Formation of hexagonal HbC crystals	Mild hemolysis and anemia when inherited as HbCC; asymptomatic when inherited as HbAC
Hemoglobin E	Southeast Asia, centered on border of Thailand, Laos, and Cambodia	Glu→Lys at position 26 of β-globin	Mildly reduced expression of β-globin due to insertion of splice site and resulting mRNA degradation	Mild anemia, microcytosis, and hypochromia
Hemoglobin F a	>50% of hemoglobin at birth, largely absent by 6 months of age	Normal	Tetramer consisting of two α-chains and two γ-chains	Greater oxygen affinity within RBCs than adult hemoglobin A due to attenuated interactions with 2,3-bisphosphoglycerate

The human genome normally contains four copies of α-globin genes (in paired copies on chromosome 16: genotype αα/αα) and two copies of β-globin genes (on chromosome 11). Normal adult hemoglobin (HbAA) is a tetramer of two α-globin and two β-globin proteins.

Not technically a hemoglobinopathy but rather a normal hemoglobin variant of all newborns and infants.

The current understanding of falciparum malaria pathogenesis suggests four general hypotheses for investigating the nature of malaria protection by hemoglobinopathies (Figure 1): 1) restriction of RBC invasion or intraerythrocytic parasite growth, 2) interference with parasite-derived mediators of pathogenesis, 3) modulation of innate host responses, and 4) enhancement of the host's adaptive immune clearance of parasite-infected RBCs (iRBCs). While these mechanisms may be occurring simultaneously in vivo, we review the evidence for each of them separately.

Do Hemoglobinopathies Restrict P. falciparum Invasion of or Growth in RBCs?

Numerous investigations of the invasion and growth of P. falciparum in RBCs containing variant hemoglobins rapidly followed the development of in-vitro cultivation systems by Trager and Jensen, and Haynes et al. in 1976 (Table 2) [11], [12]. Reductions in RBC invasion have been reported for a variety of hemoglobinopathies including α-thalassemia trait [13], HbH disease [14], [15], HbEE [13], [15], HbAE [15], and the compound heterozygous β-thalassemia/HbE disorder [13], [15], [16]; reductions in the intraerythrocytic growth or maturation of parasites have been reported for HbH disease [14], [16], β-thalassemia minor [16], HbSS [17], [18], HbAS [17], HbCC [19]–[21], HbEE [22], HbAE [16], and HbF [23]–[26]. In addition to these positive findings, conflicting data have been reported from many of these investigations (see Table 2).

Table 2

Studies of P. falciparum invasion of and development in RBCs containing hemoglobin variants.

Hemoglobin, study	Reference	Parasite	Invasion	Development	Note
α+-thal trait (αα/α-)
Friedman, 1979	[24]	FCR-3	NR	Normal	Growth significantly attenuated by cultivation at 30% O2
Ifediba et al., 1985	[14]	NF-77	NR	Normal
Bunyaratvej et al., 1992	[13]	K1	Normal	NR
Udomsangpetch et al., 1993	[48]	TM267R	Normal	Reduced
α0-thal trait (αα/–)
Ifediba et al., 1985	[14]	NF-77	NR	Variably reduced
Luzzi et al., 1991	[105]	IT	NR	Normal
Bunyaratvej et al., 1992	[13]	K1	Reduced	NR
Wiiliams et al., 2002	[106]	A4U	Normal	Normal
HbH disease (α-/–)
Ifediba et al., 1985	[14]	NF-77	Reduced	Reduced
Brockelman et al., 1987	[16]	T9/94	NR	Reduced
Chotivanich et al., 2002	[15]	TM267R, TAB106, TAM169, TAB183	Reduced	NR
β-thalassemia minor
Friedman, 1979	[24]	FCR-3	NR	Normal	Growth significantly attenuated by cultivation at 30% O2
Brockelman et al., 1987	[16]	T9/94	NR	Reduced
Luzzi et al., 1991	[105]	IT	NR	Normal
Bunyaratvej et al., 1992	[13]	K1	Normal	NR
HbSS
Friedman, 1978	[29]	FCR-3	NR	Normal	Growth significantly attenuated by cultivating HbAS and HbSS iRBCs at low O2 tension
Pasvol et al., 1978	[17]	Parasite isolates	Increased	Reduced	Invasion and growth rates reduced in HbSS iRBCs at low O2 tension
Pasvol, 1980	[18]	Parasite isolates	Increased	Reduced	Growth attenuated in HbSS iRBCs at low O2 tension
LaMonte et al., 2012	[32]	3D7	NR	Reduced
HbAS
Friedman, 1978	[29]	FCR-3	NR	Normal	Growth significantly attenuated by cultivating HbAS iRBCs at low O2 tension
Pasvol et al., 1978	[17]	Parasite isolates	Normal	Reduced	Invasion and growth rates reduced in HbAS iRBCs at low O2 tension
Pasvol, 1980	[18]	Parasite isolates	Normal	Normal	Growth attenuated in HbAS iRBCs at low O2 tension
LaMonte et al., 2012	[32]	3D7	NR	Reduced
HbCC
Friedman et al., 1979	[19]	FCR-3	NR	Reduced
Olson & Nagel, 1986	[20]	FCR-3	Normal	Reduced	Lysis of HbCC iRBCs was restricted, preventing merozoite egress
Fairhurst et al., 2003	[21]	7G8, FCR-3, TM284, GB4, ITG, 3D7, Indochina, FCB	NR	Reduced
HbAC
Friedman et al., 1979	[19]	FCR-3	NR	Normal
Olson & Nagel, 1986	[20]	FCR-3	Normal	Normal
HbSC
Friedman et al., 1979	[19]	FCR-3	NR	Normal	Growth significantly attenuated by cultivating HbSC iRBCs at low O2 tension
Bunyaratvej et al., 1992	[13]	K1	Normal	NR
HbEE
Nagel et al., 1981	[22]	FCR-3	NR	Reduced
Santiyanont & Wilairat, 1981	[115]	FCR-1, FCM-1, K1	NR	Normal	No impact of high O2 tension
Bunyaratvej et al., 1992	[13]	K1	Reduced	NR
Chotivanich et al., 2002	[15]	TM267R, TAB106, TAM169, TAB183	Mildly reduced	NR
HbAE
Nagel et al., 1981	[22]	FCR-3	NR	Normal
Santiyanont & Wilairat, 1981	[115]	FCR-1, FCM-1, K1	NR	Normal	No impact of high O2 tension
Brockelman et al., 1987	[16]	T9/94	NR	Reduced
Bunyaratvej et al., 1992	[13]	K1	Normal	NR
Chotivanich et al., 2002	[15]	TM267R, TAB106, TAM169, TAB183	Reduced	NR
β-thalassemia/HbE
Brockelman et al., 1987	[16]	T9/94	Reduced	NR
Bunyaratvej et al., 1992	[13]	K1	Reduced	NR
Udomsangpetch et al., 1993	[48]	TM267R	Normal	Reduced
Chotivanich et al., 2002	[15]	TM267R, TAB106, TAM169, TAB183	Reduced	NR
HbF
Pasvol et al., 1976	[23]	Parasite isolates	Increased	Reduced	HbF RBCs derived from cord blood of a patient with HbAA genotype
Pasvol et al., 1977	[25]	Parasite isolates	Normal	Reduced	HbF RBCs derived from newborns with HbAA genotype and from donors with HPFH
Wilson et al., 1977	[26]	Parasite isolates	Normal	Reduced	HbF RBCs derived from newborns with HbAA genotype and from donors with HPFH
Friedman, 1979	[24]	FCR-3	NR	Reduced
Amaratunga et al., 2011	[51]	7G8, GB4, MC/R+, FVO, TM284	Normal	Normal	HbF RBCs derived from cord blood and from a donor with HPFH

Unless otherwise stated, assessments of RBC invasion and growth are relative to HbAA or non-thalassemic RBCs.

NR, not reported; HPFH, syndrome of hereditary persistence of fetal hemoglobin.

For HbS-containing RBCs specifically, several reports have implicated enhanced sickling of iRBCs as a mechanism of malaria protection. Luzzatto et al. [27] and Roth et al. [28] separately reported increased sickling of HbAS iRBCs at low oxygen tension compared to HbAA iRBCs. Similarly, Friedman [29] described comparable parasite growth rates in HbAA, HbAS, and HbSS RBCs at high oxygen tension (18%), but sickling and destruction of parasites in HbAS and HbSS RBCs at lower oxygen tensions (1%–5%) that more closely mimic the micro-aerophilic environment of post-capillary venules in vivo. Conversely, exposure of iRBCs with either α- or β-thalassemia traits to high oxygen tensions restricted parasite growth, suggesting a reduced ability to tolerate oxidative stress [24].

A recent study proposes a novel mechanism of P. falciparum growth inhibition in HbS-containing RBCs. Both HbAS and HbSS RBCs manifest host microRNA (miRNA) profiles that are distinct from those of HbAA RBCs [30], [31]. Employing multiple independent approaches, LaMonte et al. [32] describe the translocation of several host RBC miRNAs into P. falciparum parasites, as well as the fusion of these human miRNAs with extant parasite mRNA transcripts to subsequently inhibit the translation of enzymes that are critical for parasite development. Specifically, the host miRNAs miR-451 and let-7i were significantly more abundant in HbAS and HbSS RBCs, and were associated with attenuated parasite growth in these cells. In addition, the inhibition of these two miRNAs by experimental transfection of RBCs with antisense oligonucleotides partially restored parasite growth. Downstream, miR-451 appears to fuse with transcripts of the regulatory subunit of the parasite's cAMP-dependent protein kinase (PKA-R) to reduce its translation, thereby upregulating activity of its substrate PKA and ultimately disrupting multiple parasite developmental pathways. Thus, the aberrant miRNA profile of HbS-containing RBCs may modulate the intraerythrocytic maturation of P. falciparum in a way that restricts parasite growth.

Do Hemoglobinopathies Interfere with Intrinsic Pathogenic Mechanisms of P. falciparum Malaria?

Two major pathogenic phenotypes of iRBCs have been described: those that mediate binding of iRBCs to endothelial receptors (“cytoadherence”) [33] and those that mediate binding of iRBCs to uninfected RBCs (“rosetting”) [34], [35]. Both adherence phenotypes are conferred by the expression of P. falciparum erythrocyte membrane protein 1 (PfEMP1) [36]–[38], a family of highly variant proteins that are concentrated in protuberant structures called “knobs” on the iRBC surface. Different PfEMP1 variants mediate the binding of iRBCs to microvascular endothelial cells (via CD36, ICAM-1, etc.) [39], placental syncytiotrophoblasts (via chondroitin sulfate A) [40], [41], and uninfected RBCs (via complement receptor 1, A and B blood group antigens, and heparin sulfate-like antigens) [42]–[44]. Other pathogenic mechanisms that may be associated with disease include the production of cytokines in response to P. falciparum glycosylphosphatidylinositol (PfGPI) [45] and parasite-derived uric acid [46], direct hemolysis due to parasite egress from RBCs, and PfEMP1-mediated suppression of inflammatory cytokines (discussed below) [47].

A series of investigations suggests that the weakening of cytoadherence interactions partially governs malaria protection by the hemoglobinopathies. Early studies by Udomsangpetch et al. [48] described impaired rosetting and binding to human umbilical-vein endothelial cells by α- and β-thalassemic iRBCs, although many of these RBCs contained additional hemoglobin mutations that may have influenced this phenotype. Additionally, impaired rosetting and cytoadherence were not clearly associated with reductions in the levels of surface antigens implicated in binding interactions. Similarly, Fairhurst et al. [21] found that the density of PfEMP1-laden knobs was markedly lower on the surface of HbAC and HbCC iRBCs (compared to HbAA iRBCs) despite comparable total iRBC levels of knob-associated histidine-rich protein (KAHRP), a major parasite-produced component of knobs. Further investigation of this phenomenon found that HbAC and HbCC markedly impaired the binding of iRBCs to human microvascular endothelial cells (HMVECs) under both static and physiologic flow conditions [49]. Subsequent investigations also found significant reductions in the binding of HbAS iRBCs [50], HbF-containing iRBCs [51], and α-thalassemic iRBCs [52] to HMVECs. Taken together, these reports support a common pathway for reducing the pathogenicity of parasites infecting hemoglobinopathic RBCs, whereby aberrant surface expression of PfEMP1 attenuates the binding of iRBCs to host cells within microvessels [53].

A recent study supports this candidate mechanism of malaria protection. Cyrklaff et al. [54] investigated the protein-trafficking network of the iRBC and demonstrated that the parasite remodels the RBC's actin cytoskeleton to enable the export of parasite-derived proteins to knobs on the iRBC surface. In HbSC and HbCC iRBCs, this actin cytoskeleton is disrupted and the export of parasite proteins to surface knobs is relatively inhibited, possibly due to the inhibition of actin polymerization by hemichromes. These forms of oxidized, denatured hemoglobin are known to accumulate in HbS- and HbC-containing RBCs, thus providing a potential link between hemoglobin instability and abnormal PfEMP1/knob display. Further studies are needed to explore the impact of this phenomenon upon both in-vitro measures of parasite virulence—including PfEMP1 expression and iRBC binding to host cells—and in-vivo measures of malaria severity.

Do Hemoglobinopathies Impact the Innate Host Defense Responses to P. falciparum?

There is an emerging recognition of the impact of aberrant host responses in the pathogenesis of malaria, particularly severe falciparum malaria (reviewed in [55]–[57]). Studies of adjunctive interventions to modulate this response in humans have not yielded sustained successes [58], but experiments in murine models continue to demonstrate benefit [59], and new modalities remain under active investigation [58], [60], [61].

The innate host defense response encompasses myriad stereotypical pathways that are activated by microorganisms and orchestrated to mitigate insults while minimizing collateral toxicity (reviewed in [62]). Typically initiated by the recognition of pathogen-associated molecular patterns (PAMPs) by Toll-like receptors (TLRs) on leukocytes, these responses subsequently progress through: 1) a pro-inflammatory phase marked by release of cytokines, activation of endothelial cells, and recruitment of circulating and locally resident immune effector cells; 2) a counter-regulatory phase in which tissue-protective molecules such as erythropoietin [63], [64], heme oxygenase-1 (HO-1) [65], [66], and angiopoietin-1 [67] are deployed to limit inflammatory damage; and 3) a repair phase mediated by vascular- and tissue-specific stem cells [68], [69]. These phases result from host and pathogen factors that collectively balance these pro-inflammatory and counter-regulatory responses.

In falciparum malaria, these innate immune responses are potently initiated through the activation of TLRs on leukocytes by both PfGPI [70] and hemozoin (the product of heme polymerization) [71], [72], as well as by microvascular inflammation caused by PfEMP1-mediated binding of iRBCs to endothelium (see above) [73]. In murine models, the outcome of malaria is sensitive to experimental manipulation of multiple host innate response molecules, such as tumor necrosis factor (TNF), interferon-γ [74], and erythropoietin [75], suggesting their role in mediating differential infection outcome. In human studies, severe malaria has been associated with increased angiopoietin-2, decreased angiopoietin-1, and decreased endothelial nitric oxide levels [76]–[78], and the upregulation of counter-regulatory molecules including HO-1 and erythropoietin [78]–[80].

Few studies have investigated the impact of hemoglobinopathies on these responses, though recent murine and human studies have shed light on a possible role for HO-1. Normally, HO-1 catabolizes and thus mitigates the cytotoxicity of free heme, which is released by the degradation of the RBC's hemoglobin. Recent studies in murine models identified HO-1 as a protective counter-regulatory molecule in sepsis [81] and malaria [82], [83]. In addition, a recent study by Cunnington et al. has demonstrated that when HO-1 is upregulated in response to hemolysis during murine Plasmodium infection, resistance to non-typhoidal Salmonella disease is abrogated [84]. In combining mouse models of human cerebral malaria and of human sickle-cell trait, Ferreira et al. [85] demonstrated that mice carrying RBCs with human HbS were protected from cerebral malaria. Furthermore, they provided evidence that this protection is associated with chronically elevated production of HO-1 and with reduced production of inflammatory cerebral chemokines during infection. However, the interpretation that HO-1 activity may mediate HbS-associated protection from malaria in mice is complicated by elegant recent work on severe malaria in humans [86]. In Gambian children, the association of HO-1 levels with severe malaria was variable, and HO-1 promoter polymorphisms that confer higher constitutive levels of HO-1 were associated with increased risk of severe malaria. These findings, gathered mostly from patients with HbAA, suggest that HO-1 may be either protective or deleterious across a wide spectrum of levels in vivo.

Despite the paucity of investigations of hemoglobinopathies and innate host defenses, a separate line of investigations of nitric oxide (NO) and severe malaria highlights the importance of interactions between iRBC and endothelium in the pathogenesis of severe malaria. As noted above, severe falciparum malaria is associated with low NO bioavailability [87], [88], and a polymorphism in the nitric oxide synthase 2 (NOS2) promoter—which increases NO production and is prevalent in Kenyan and Tanzanian children—was associated with substantial protection from severe malaria [89]. Data support diverse roles for NO in mediating parasite death [90] and in acquiring immune memory [91]. NO also manifests anti-inflammatory activity by reducing the expression of host receptors used by iRBCs to bind microvascular endothelial cells [92]. Indeed, the addition of NO to an in-vitro model of endothelial binding downregulated the endothelial expression of ICAM-1 and VCAM-1, and attenuated the cytoadherence of iRBCs under flow conditions [93]. Thus, both hemoglobinopathies and increased NO production are associated with protection from severe malaria in vivo, and both are also associated with reduced binding of iRBCs to endothelium in vitro. These findings suggest that similar molecular phenomena—the disruption of iRBC–endothelium interactions—may also occur in vivo.

Do Hemoglobinopathies Enhance the Adaptive Immune Response to P. falciparum?

Evidence from field studies supports an association between several hemoglobinopathies, adaptive immunity, and protection from malaria [94], [95], though investigations of these relationships are complicated by the absence of reliable correlates of immune protection.

A central role for antibodies in malaria immunity is suggested by the ability of polyclonal IgG from malaria-immune adults to clear parasitemias in children with malaria [96]. Several field studies have investigated differences in antigen seroreactivity in children with hemoglobinopathies. Cross-sectional studies of children with hemoglobinopathies in Nigeria [97], the Gambia [98], Cameroon [99], Gabon [100], [101], and Burkina Faso [102] have yielded inconsistent results, with some demonstrating higher seroreactivity to specific or variant surface P. falciparum antigens of heterologous parasites in HbAS children, and others reporting no differences. These findings were explored by measuring seroreactivity to a panel of 491 P. falciparum proteins in Malian children before and after a well-defined malaria transmission season [103]; though IgG responses to antigens were enhanced after the transmission season, there were no qualitative or quantitative differences in antigen recognition between HbAA, HbAS, and HbAC children. Given the methodological strengths of this study and the broad spectrum of antigens investigated, it seems clear that these hemoglobinopathies do not generally enhance the acquisition of antibodies to P. falciparum antigens. It remains to be fully investigated whether they enhance IgG recognition of specific variants of PfEMP1 or other surface antigens that are known to play a role in malaria immunity.

Antibody-mediated phagocytosis of iRBCs is believed to be an important effector mechanism in protection from malaria. Investigations with normal RBCs have demonstrated that monocytes preferentially phagocytose iRBCs compared to uninfected RBCs, and that this preference is potentiated by the binding of IgG to iRBCs [104]. Additionally, polyclonal IgG from hyper-immune sera binds more avidly to both α-thalassemic iRBCs [105], [106] and β-thalassemic iRBCs [105] compared to non-thalassemic iRBCs, suggesting that this mechanism may preferentially clear iRBCs harboring hemoglobin variants. Indeed, Ayi et al. [107] demonstrated that ring-parasitized HbAS, β-thalassemic, and HbH RBCs had higher levels of membrane-bound hemichromes, C3c fragments, and aggregated band 3 proteins, and were phagocytosed more readily than ring-parasitized HbAA RBCs. While these data suggest that hemoglobinopathies functionally enhance the clearance of iRBCs, the precise mechanism of this enhancement remains obscure, evidence for this role in parasite clearance by other hemoglobinopathies is lacking, and the correlation between this mechanism and protection from clinical disease has not been specifically investigated.

Multiple lines of evidence support the hypothesis that P. falciparum parasites interfere with the acquisition of immunologic memory responses that contribute to subsequent control of parasitemia (reviewed in [108]). Several mechanisms are supported by murine and human studies, including the depletion by circulating parasites of dendritic cells [109], parasite-specific CD4+ T cells [110], [111], and memory B cells [112] by either soluble factors [111] or interactions between iRBCs and antigen-presenting cells [113]. It is unknown whether hemoglobinopathies impact the efficiency or magnitude of the cellular and molecular mechanisms that suppress immune memory directed at P. falciparum parasites.

An Integrated Hypothesis

In this review, we have artificially partitioned the evidence for diverse mechanisms of protection, but pathogenic pathways overlap substantially, and it is similarly likely that protective mechanisms in vivo also involve multiple pathways. As noted above, field evidence indicates that hemoglobinopathies do not impair parasite infection but instead attenuate malaria; this pattern suggests that protection from malaria syndromes is not mediated against the pre-erythrocytic stages of the P. falciparum life-cycle, and that hemoglobinopathies may influence the transition from parasite infection to disease.

Embroidering the positive and negative evidence summarized above suggests a model of malaria protection in which hemoglobinopathies impair the parasite's trafficking of PfEMP1 and other knob proteins to the iRBC surface [21], possibly due to the association of hemoglobinopathies with elevated hemichrome levels [49], [54]. Abnormal PfEMP1/knob display weakens the molecular interactions involved in the cytoadherence [49] and rosetting [48], [49] of iRBCs in microvessels. The attenuation of these host–parasite interactions not only mitigates microvascular obstruction and ischemia, but also impairs the activation of endothelial cells and limits the elaboration of inflammatory mediators including TNF [114]. Additionally, given the role of PfEMP1 in downregulating the release of pro-inflammatory cytokines like IL-12 [113] and IFN-γ [47] from PBMCs, abnormal PfEMP1/knob display may inhibit the parasite's ability to blunt both innate and adaptive immune responses. Finally, this attenuation of host-cell injury, coupled with mechanisms of parasite growth restriction in hemoglobinopathic iRBCs, may be involved in prolonging the asymptomatic phase of parasitemia. This delay in developing symptoms (and thus delay in seeking antimalarial treatment) may offer a greater amount of time for erythrocytic-stage antigens and markers of RBC senescence to be exposed to the immune system, thereby enhancing both the acquisition and maintenance of the adaptive and memory immune responses that ultimately protect individuals from developing the deadliest complications of P. falciparum infection. This model is based upon currently available data largely obtained from in-vitro experimental and in-vivo animal model studies, and most commonly for HbAS and α-thalassemia. Clearly, many opportunities exist to interrogate these phenomena in translational studies involving human populations that carry diverse hemoglobinopathies (Box 1).

Do microRNAs impact the maturation of parasites in HbC, HbE, α-thalassemic, or HbF RBCs? Is their profile or impact in HbAS RBCs modified by the presence of α-globin deletions?

Does microRNA manipulation of HbS-containing iRBCs impact their ability to cytoadhere to human microvascular endothelial cells or rosette with uninfected RBCs?

How does the presence of α-thalassemia modify the effects of HbS, HbC, or HbE on parasite growth, maturation, microvascular adhesion, or endothelial cell activation?

Do hemoglobinopathies quantitatively or qualitatively restrict the expression of specific variants of PfEMP1?

Does reduced binding to human endothelial cells in vitro correlate with reductions in markers of endothelial activation in vivo?

How do other malaria-protective polymorphisms, such as type O blood group antigen and glucose-6-phosphate dehydrogenase (G6PD) deficiency, interact with co-inherited hemoglobinopathies in mitigating pathogenesis?

How do hemoglobinopathies impact the resting endogenous levels of angiopoietin-1, angiopoietin-2, and heme oxygenase-1?

Do hemoglobinopathies augment cell-mediated immunity to P. falciparum antigens?

Do hemoglobinopathies quantitatively or qualitatively enhance the acquisition of antibodies to specific variants or domains of PfEMP1?

Do hemoglobinopathies impair the mechanisms by which the iRBC and the parasite interfere with the acquisition of immune memory?

Conclusions

In the spirit of Alexander, we propose that hemoglobinopathies may be nature's “Alexandrian solution” to the problem of understanding fundamental aspects of falciparum malaria. This bold slice through the Gordian knot of malaria pathogenesis represents a unique opportunity to isolate and identify the molecular correlates of falciparum malaria pathogenesis in humans in vivo, and to translate these findings into future interventions to prevent, treat, and eliminate this ancient and intractable scourge.