Showing posts with label Porphyria Cutanea Tarda (PCT). Show all posts
Showing posts with label Porphyria Cutanea Tarda (PCT). Show all posts

Wednesday, April 18, 2012

Hepatitis C, porphyria cutanea tarda and liver iron: an update

Liver International
Early View (Online Version of Record published before inclusion in an issue)

Hepatitis C, porphyria cutanea tarda and liver iron: an update

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F. Ryan Caballes1,2, Hossein Sendi1, Herbert L. Bonkovsky1,2,3,*Article first published online: 17 APR 2012
DOI: 10.1111/j.1478-3231.2012.02794.x
© 2012 John Wiley & Sons A/S
Keywords:chloroquine; chronic hepatitis C; hepatitis C virus; hereditary emochromatosis; iron; oxidative stress; porphyria cutanea tarda; reactive oxygen species; therapeutic phlebotomy; uroporphyrinogen decarboxylase

Porphyria cutanea tarda (PCT) is the most common form of porphyria across the world. Unlike other forms of porphyria, which are inborn errors of metabolism, PCT is usually an acquired liver disease caused by exogenous factors, chief among which are excess alcohol intake, iron overload, chronic hepatitis C, oestrogen therapy and cigarette smoking. The pathogenesis of PCT is complex and varied, but hereditary or acquired factors that lead to hepatic iron loading and increased oxidative stress are of central importance. Iron loading is usually only mild or moderate in degree [less than that associated with full-blown haemochromatosis (HFE)] and is usually acquired and/or mutations in HFE. Among acquired factors are excessive alcohol intake and chronic hepatitis C infection, which, like mutations in HFE, decrease hepcidin production by hepatocytes. The decrease in hepcidin leads to increased iron absorption from the gut. In the liver, iron loading and increased oxidative stress leads to the formation of non-porphyrin inhibitor(s) of uroporphyrinogen decarboxylase and to oxidation of porphyrinogens to porphyrins. The treatment of choice of active PCT is iron reduction by phlebotomy and maintenance of a mildly iron-reduced state without anaemia. Low-dose antimalarials (cinchona alkaloids) are also useful as additional therapy or as alternative therapy for active PCT in those without haemochromatosis or chronic hepatitis C. In this review, we provide an update of PCT with special emphasis upon the important role often played by the hepatitis C virus.

Overview of porphyria cutanea tarda
Porphyria cutanea tarda (PCT) is the most common type of porphyria worldwide with an estimated prevalence in various countries ranging from 1:5000 to 1:70 000 [1, 2, 3, 4]. PCT is known by many other names, including symptomatic porphyria, idiosyncratic porphyria, chemical porphyria or acquired hepatic porphyria [5]. PCT typically presents as a chronic, gradually progressive cutaneous disorder, with vesicles, milia and bullae on the backs of the hands and forearms. Clinical features rarely develop unless there is at least 75% decrease in activity of hepatic uroporphyrinogen decarboxylase (UROD) [6, 7, 8]. The UROD is the fifth enzyme in the haem biosynthetic pathway. The UROD deficiency is usually acquired (75–80% of cases), but 20–25% of subjects with familial PCT have a genetic predisposition with partial (~50%) deficiency in UROD activity. Those with genetic predisposition need fewer other factors to decrease the activity further down to the threshold of ~75% in order for symptomatic disease to occur.

Nature of metabolic defect and pathogenesis of porphyria cutanea tarda
Porphyria cutanea tarda is a heterogeneous disease and has been classified into three subtypes (Table 1). Type I, accounting for 75–80%, is acquired PCT, in which deficiency of UROD is limited to hepatocytes. Type II, accounting for 20–25%, is hereditary, in which there is partial deficiency (~50%) of UROD in all tissues. Type III is a very rare form in which there exists an apparently genetic predisposition that leads to decreased UROD activity limited to hepatocytes [9, 10, 11]. It is thought that the genetic abnormality in type III PCT is in a still unidentified gene other than UROD. There is only one UROD gene in humans; it is located on chromosome 1P34, is around 10 kb in length and consists of 10 exons [12].

Table 1. Classification of porphyria cutanea tarda
Type Per cent of cases Nature of defect
  1. UROD, uroporphyrinogen decarboxylase.
I 75–80 Acquired defect leading to decreased activity  of hepatic UROD (<25% normal activity)
II 20–25 Hereditary partial defect in UROD activity  (~50% of normal) in all tissues. Other factors  also required to produce clinical features
III <1 Very rare. Apparently inherited defect in an as  yet unknown gene that leads to a secondary  critical decrease in hepatic UROD activity.

Several lines of evidence support the concept that, in PCT, there occurs in the liver the formation of an inhibitor of UROD, which is derived from uroporphyrinogen or hydroxymethylbilane, the tetrapyrrole precursor of uroporphyrinogen. Formation of the inhibitor, which more likely than not is an oxidation product, is increased by iron, a well-known oxidant, by activity of cytochrome P-4501A2, by alcohol excess and by oestrogen therapy (Fig. 1). Based on mass spectroscopic evidence obtained from studies in a murine model of PCT, it has been claimed that uroporphomethene is the inhibitor [13]. However, others have cast doubt upon the interpretation of the mass spectroscopic evidence [14]. Thus, the precise structure and nature of the UROD inhibitor remains unresolved.

 Figure 1.

Figure 1.
Pathogenesis of porphyria cutanea tarda. The figure shows a summary of the normal pathway of haem biosynthesis, with emphasis on uroporphyrinogen decarboxylase (UROD) and its inhibition by an oxidation product thought to be derived from uroporphyrinogen. Formation of the inhibitor is thought also to require the action of CYP1A2. Several sites of action of iron are shown, including synergistic induction of ALA synthase 1, increases in oxidative stress [reactive oxygen species (ROS)], and induction of haem oxygenase 1. Alcohol and oestrogens also increase ROS and induce ALA Synthase 1. HCV infection increases ROS and decreases hepcidin production. The latter decrease is up-regulation of histone deacetylase [HDAC] and C/CBP homology protein [CHOP], which result in decreased binding of C/EBP to the hepcidin gene promoter region and thus decreased hepcidin production. Mutations in the HFE gene, (or more rarely, HJV and/or TfR2 genes) also lead to decreased hepcidin production. The decrease in hepcidin leads to increased absorption of iron from the small intestine, leading to additional hepatic iron overload and to amplification of the metabolic disarray.

UROD catalyses the step-wise decarboxylation of uroporphyrinogen to the corresponding coproporphyrinogen. Uroporphyrins (which contain 8–carboxylate groups) and hepta-carboxylated porphyrins accumulate in various organs as a consequence of impaired UROD activity and increased oxidative stress [2]. Porphyrins with many carboxylate residues are water soluble, whereas those with few [e.g. protoporphyrin with 2–carboxylate (–COOH) residues] are insoluble in water. Thus, those with higher numbers of –COOH residues, such as uro- and heptacarboxyl- porphyrins are excreted primarily in the urine; those with intermediate numbers of –COOH groups (e.g. coproporphyrins, with 4–COOH) are excreted in both urine and stool; whereas, protoporphyrin is secreted only into the bile and excreted only in the stool. Within cells, different water solubilities influence where various porphyrins accumulate. Owing to their hydrophilic nature, uro- and heptacarboxyl- porphyrins accumulate in the cytosol and lysosomes and are not associated with or dissolved in membranes to any appreciable extent. The ability of porphyrins to absorb light of 400–410 nm (the Soret band) [1, 15, 16, 17] is the key factor in producing the photocutaneous lesions observed on sun exposed areas in affected individuals. The delocalized Pi-electrons of aromatic porphyrins readily absorb energy of violet light and enter a higher energy state. This excited state then transfers its excess energy to molecular oxygen which in turn raises electrons of oxygen to a higher energy state (‘singlet oxygen’) [18]. The reactive oxygen species (ROS) give rise to the phototoxic damage characteristic of PCT [18], as well as further catalyzing the oxidation of porphyrinogens to porphyrins [8] (Fig. 1).

Major clinical, laboratory, histopathological features and risk factors of porphyria cutanea tarda
PCT clinically presents with blisters, vesicles and/or milia days to weeks after sun exposure [5, 8, 19] in areas likely to be exposed to the sun and to minor trauma, such as the dorsa of the hands and forearms. These lesions typically first arise and are worse in the summer and often take weeks or months to resolve. Chronic skin damage may result in scarring, changes in cutaneous pigmentation at the sites of blisters and milia (Fig. 2). Other skin manifestations may include a purplish heliotrope suffusion of periorbital areas [2], hypertrichosis, usually involving the lateral aspects of the face, chloracne, sclerodermatous changes, dystrophic calcification with ulceration, alopecia and onycholysis [8].

Figure 2.

Figure 2.
Typical cutaneous manifestations of PCT. Cutaneous lesions with bullae, vesicles and erosions on the dorsum of the hand.

As a result of marked excretions of porphyrins in the urine, patients with PCT may have urine that appears pink, red or brown, especially after exposure of the urine to air and light [2, 8]. Because the free porphyrins do not contain iron, urine tests for haem, haemoglobin or myoglobin are all negative. Thus, despite the pink-red colour of urine, routine urinalysis and blood counts are normal in most patients. Persons with active PCT are usually found to have mildly elevated serum aminotransferases and gamma-glutamyl transpeptidase [5]. The nonspecific findings of routine laboratory tests make it clear that special studies are needed to diagnose PCT. A useful initial test is direct fluorometric assay of plasma. In patients with symptomatic PCT, plasma porphyrins are elevated with maximal excitation and emission wavelengths at ~ 400 nm and ~ 620 nm respectively. When this fluorometric pattern is observed, tests for levels of porphyrins and porphyrin precursors in urine, and porphyrins in faeces are used to confirm the diagnosis. If PCT is present, elevated levels of uro- and heptacarboxyl- porphyrins are found in the urine along with elevated faecal isocoproporphyrin and plasma 8- and 7- carboxylporphyrins, with little or no elevation of erythrocyte porphyrin levels [9]. Urinary levels of delta-aminolevulinic acid (ALA) are normal or slightly increased (less than two times the upper limit of normal), and levels of urinary porphobilinogen are normal. The latter help to distinguish PCT from the acute or inducible hepatic porphyrias (hereditary coproporphyria, variegate porphyria), which may be present with cutaneous features indistinguishable from those of PCT. In addition, in variegate porphyria, the peak emission wavelength of plasma fluorescence is 626–628 nm, a finding of considerable diagnostic value.

In active PCT, vesiculo-bullous lesions ‘festoon’ the dermal papillae whereby these dermal projections rise irregularly into the cavities of subepidermal fluid collections. There is also deposition of periodic acid-Schiff positive, diastase-resistant glycoproteins, various immunoglobulins and complement around both the dermo-epithelial junction and blood vessels. These lesions are not unique to PCT and are found in other porphyrias of the bullous type. Similarly, liver histopathology is mostly non specific and includes red fluorescence of unfixed hepatic tissue (which is seen in various types of porphyria), necrosis, inflammation, varying siderosis and steatosis [8, 20, 21] (Fig. 3). Haemosiderosis is usually mild to moderate but may be severe when accompanied by mutations that underlie hemochromatosis. Indeed, PCT shows a clear dose-response relationship in individuals carrying either C282Y or H63D gene mutations. In a meta-analysis done by Ellervik and colleagues, C282Y homozygotes were demonstrated to have the highest risk for PCT while H63D heterozygozity with wild type conferred the lowest risk [22]. Other features include needle-shaped hydrophilic cytoplasmic inclusions thought to be mainly composed of uro-and/or heptacarboxyl porphyrin crystals. These crystals have been localized to the areas of cytoplasm that contain ferritin granules further suggesting the role of iron in oxidation of porphyrinogens and subsequent crystallization of porphyrins

Figure 3.

Figure 3.
Hepatic histopathology in PCT. Fresh unfixed liver fluoresces a bright pin) [upper left, (unstained, 1×)] excess porphyrins. Typically, there is some degree of iron loading [upper right, (Prussian Blue stain, 10×)] and fatty change and inflammation [lower left, (H&E stain, 20×)]. The latter are often alcohol and/or chronic hepatitis C. Sometimes, cirrhosis and/or hepatocellular carcinoma develop [lower right, (H&E stain 10×)]. Photomicrographs kindly provided by JR Bloomer.

Iron enhances uroporphyrin overproduction in several ways (Fig. 1). First, iron increases ROS, which increase the rate at which uroporphyrinogen and heptacarboxylporphyrinogen are oxidized into their respective porphyrins [8]. Second, it decreases the activity of UROD by increasing formation of an inhibitor, probably derived from hydroxymethylbilane and/or uroporphyrinogen. Third, iron increases intracellular ALA levels providing more substrate for uroporphyrinogen and subsequent uroporphyrin synthesis.
Despite the importance of hepatic siderosis in PCT, iron by itself is insufficient to cause uroporphyrin overproduction in the absence of other predisposing factors [8, 15, 23, 24, 25]. Other known risk factors for PCT include UROD mutations [7], alcohol, smoking [25, 26], hepatotoxic aromatic hydrocarbons (e.g. hexachlorobenzene, 2,3,7,8-tetrachlorodibenzo-p-dioxin, and others), certain genetic variations in the genes for cytochrome P4501A2, and glutathione-S-transferase GSTM1 [27], hepatic tumours (benign, malignant, or metastatic) [15], dialysis, sarcoidosis, oestrogens and chronic infection with the hepatitis C or human immunodeficiency virus.

Overview of the hepatitis C virus and chronic hepatitis C
The HCV is a hepatotropic member of the flaviviridae family and is known to infect an estimated 170–200 million people worldwide [8, 28, 29]. HCV has six known major genotypes [1, 2, 3, 4, 5, 6] which may be further divided into 50 subtypes (1a, 1b, etc.). Certain genotypes are more prevalent in different parts of the globe. Genotype 1 is predominant in the USA, accounting for 70% of infections. Furthermore, 55% of these are subtype 1a whereas 40% are 1b; the remaining small proportion is caused by subtype 1a/1b co-infection. Most of the remaining 30% of infected individuals in the USA are because of HCV of genotypes 2 or 3, whereas genotypes 4–6 account for a small proportion [29]. In contrast, 80% of HCV infections in Europe are owing to subtype 1b. Other global variations include the predominance of genotype 2a in Japan, Taiwan and China; genotype 3 in Scotland and other parts of the UK [30]; genotype 4 in the Middle East and Northern and Central Africa; genotype 5 in South Africa and genotype 6 in South East Asia [29].

The virus is transmitted mainly by the parenteral route and to a lesser extent by vertical and sexual transmission. Acute HCV infection may begin insidiously or present abruptly. It has a limited course that usually lasts 1 or 2 months. Acute infection is rarely detected because the majority of patients are asymptomatic. Indeed, only 10–20% of patients develop jaundice, with a greater proportion presenting with nonspecific symptoms (e.g. anorexia, fatigue, nausea and tiredness). Of those acutely infected by HCV, 60–85% develop chronic infection and approximately 70% of these develop chronic liver disease, 10–20% of which progress to cirrhosis [31]. Indeed, chronic hepatitis C (CHC) has become the single most common indication for orthotopic liver transplantation in the western world. Thus, cirrhosis caused by CHC accounts for 40–50% of patients listed for transplant [32].

Although the majority of patients with CHC have elevated serum aminotransferases, about a third of those infected have persistently normal levels despite a high viral load and continued hepatic injury. Patients with chronic infection frequently complain of fatigue. Other nonspecific symptoms such as myalgias, arthralgias, paresthesias, pruritus and sicca syndrome are also frequent complaints.

Epidemiology/association of porphyria cutanea tarda with hepatitis C virus
In most studies, there is a strong association between HCV infection and PCT (Table 2) [20, 33, 34, 35]. Furthermore, it has been observed that HCV-infected individuals develop PCT at an earlier age than do uninfected persons with PCT [24, 25]. Although the presence of any single risk factor is likely not sufficient to cause PCT, HCV is thought to be a strong trigger for the development of deranged porphyrin metabolism in those with other known predisposition [1, 3, 16, 20, 35, 36]. O'Reilly et al. reported only minimal elevations of urinary porphyrins in 59 subjects infected with HCV but with few or no concomitant susceptibilities. Subjects found to have mildly elevated porphyrins were on a variety of medications that may have influenced porphyrin metabolism, and none had overt PCT [36]. Nomura et al. confirmed these results and also found HCV and HIV co-infection to be significantly associated with elevated serum porphyrins [3]. In addition, Jalil et al. analysed records of 143 patients with well documented PCT. They found that most subjects with clinically manifest PCT had three or more known susceptibility factors [17] (Table 2).

Factors that underlie the association of hepatitis C virus and porphyria cutanea tarda
Although CHC is among factors known to increase risk of PCT, it is not clear if the virus, per se, plays a role in the development and pathogenesis of PCT, or whether this association is mainly caused by iron overload and/or increased oxidative stress, which often occur in the context of CHC. It has been known for many years that (i) most patients with PCT have some degree of iron overload; (ii) iron removal ameliorates porphyrin overproduction and clinical features and (iii) administration of iron produces relapse of PCT [26]. Serum iron indices and iron content of the liver are often elevated in patients with CHC [20, 37]. The precise molecular mechanisms by which iron may influence HCV-induced liver disease are not fully understood. Among several proposed mechanisms are iron-induced immunological modifications and iron effects on signal transduction and HCV proliferation [38]. Elevated hepatic iron and increased serum iron indices also have been associated with PCT (Table 2) [39], and iron is known to exert several actions that increase oxidation of porphyrinogens and lead to inhibition of UROD (Fig. 1). Therefore, iron can be considered as a common factor for the development and progression of both CHC- and PCT- induced liver diseases. Based on these facts, it can be anticipated that patients with iron overload like those with hereditary hemochromatosis (HH) have a higher risk for the development and progression of both CHC- and PCT- induced liver diseases. Indeed, significantly increased frequencies of both C282Y and H63D mutations of HFE in PCT patients have been reported from studies in Northern Europe and the USA [26, 40, 41]. The preponderance of the evidence suggests that patients with CHC who are heterozygous for H63D or C282Y mutations are at a higher risk of severe hepatocellular injury and fibrosis [42]. Therefore, even in patients harbouring HFE mutations that cause milder defects in iron homeostasis, it is possible that the presence of HFE mutations leads to the inactivation of UROD through interaction with other factors like HCV infection, which change iron homeostasis in the liver.

Transgenic mice expressing an HCV polyprotein and fed a high-iron diet were found to have not only higher degrees of hepatic steatosis, lipid peroxidation and mitochondrial injury, but also a higher risk of development of hepatocellular carcinoma (HCC), compared to mice fed a normal diet [43]. Using human hepatoma cells, expressing an HCV subgenomic replicon, Fillebeen et al. [44] showed that HCV replication altered the expression of several genes related to iron metabolism. Alteration of these genes, in turn, can contribute to development of PCT in the context of HCV infection.

Recently, Nishina et al. have shown that HCV increases ROS, which leads to increase hepatic expression of CCAAT/enhancer binding protein homologous protein (CHOP) [45] via an increase in histone deacetylase activity [46]. The CHOP is a nuclear protein that inhibits C/EBPα via the binding of their carboxy terminal domains. Thus, the CHOP-C/EBPα heterodimer renders the C/EBPα monomer unavailable to bind its DNA enhancer elements that lead to hepcidin production.

Hepcidin, a 25-amino acid cysteine-rich peptide, is the key regulator of iron absorption and metabolism in humans, which induces internalization and degradation of ferroportin, and this in turn leads to the reduction of iron exported from cells. Therefore, over-expression of hepcidin in mice and humans leads to iron deficiency, whereas its deficiency leads to iron overload. In HCV-infected individuals [as with FL-N/35 transgenic mice with the full length HCV polyprotein [45]], compared to controls, hepcidin expression levels are low relative to the iron content of hepatocytes [47, 48]. Interestingly, in a recent study, Ajioka et al. showed that hepatic hepcidin expression in patients with PCT was significantly reduced, regardless of HFE genotype, when compared with patients with HH but without PCT with comparable iron overload [49]. Therefore, they suggested that the hepatic siderosis associated with PCT likely results from dysregulated hepcidin. Taken together, it appears that HCV leads to down-regulation of hepcidin, and this can lead to iron overload, which in turn facilitates development of PCT by inhibiting UROD activity (Fig. 1).

In addition to CHC, there are also reports that show concurrence of other viral infection like HBV, HIV and HHV6 with PCT [26, 50]. These associations suggest that viral infection, per se, may play a role in reducing the activity of UROD. Additional studies investigating alteration of UROD activity in HCV-infected cell lines may help to unravel the mechanism of this association.

As mentioned above, besides HCV infection and HFE mutations, several environmental factors have been shown to precipitate overt clinical PCT, including alcohol abuse, tobacco use and use of oral oestrogens (Table 2) [17]. Alcohol may cause liver damage, ranging from reversible steatosis to alcoholic cirrhosis. Alcohol also exacerbates the hepatopathy of CHC. Alcohol, oestrogens, iron and CHC all produce increased oxidative stress in liver cells. Besides, it is also anticipated that there might be common molecular pathways for triggering both PCT, and its predisposing factors. In mice, cytochrome P4501A2 (Cyp1A2) plays a major role in the development of uroporphyria. Unlike mice with normal Cyp1A2, knockout mice deficient in Cyp1A2 do not develop uroporphyria following exposure to halogenated polyaromatic hydrocarbons [51]. As mentioned above, in a recent study, it was found that genetic variations in human CYP1A2(*1F) and GST(M1) alleles are associated with susceptibility to PCT [27]. The GSTM1 is particularly important in the deactivation of reactive intermediates of polycyclic aromatic hydrocarbons.

Management of porphyria cutanea tarda [Table 3]
As in other types of cutaneous porphyria, avoidance of sun exposure and/or strong light of 400–410 nm wavelength (Soret band) is the most effective way to prevent the cutaneous manifestations of PCT. Avoidance of sun exposure involves the use of protective clothing (Solumbra®; and opaque sunscreens that contain zinc or titanium oxide. In addition, preventing or controlling various predisposing factors should be a routine part of management.

Click To Enlarge Table 3

Definitive therapy aimed at the pathogenic mechanism of PCT includes iron reduction, and antimalarials that remove porphyrins from the liver and other tissues. Among these, phlebotomy is the treatment of choice and has generally been shown to be cheap, safe and effective. Although moderate hepatic iron overload is common in PCT, presence of hepatic siderosis in PCT is not a prerequisite for successful treatment with venesection [52, 53]. It is recommended that a unit (450–500 ml) of blood be removed either once a week or every other week [54] until the serum ferritin (SF) is <25 ng/ml [13, 55, 56, 57, 58]. Clinical remission is usually evident after removal of 2–4 L of blood [59]. Indeed, with the regimen recommended above, cutaneous manifestations gradually improve with resolution of bullae in 2–3 months, improvement of cutaneous fragility in 6–9 months, and complete biochemical remission in 13 months [59, 60]. Care should be taken to prevent pre-phlebotomy haemoglobin from falling below 11 g/dl. Pre-existent anaemia, severe serum protein deficiency, e.g. cirrhosis and bleeding disorders, are unusual relative contraindications to phlebotomy.

Diets somewhat restricted in iron, liver and red meats (the latter are rich in haem) are also recommended because with iron reduction there is a compensatory increase of iron absorption from the GI tract. This compensatory mechanism is attributed to the reduction of serum hepcidin post-iron reduction. Reduced hepcidin in turn, increases ferroportin expression and function, which ultimately results in enhanced intestinal iron absorption [61, 62]. Haem iron is particularly well absorbed, so that a modest restriction of haem intake is good general dietary advice, except for those with iron deficiency.

If phlebotomy is contraindicated, low-dose chloroquine (125 mg every other day) is usually the next best choice. Indeed, although relapse of PCT following chloroquine treatment occurs earlier than after iron reduction, it has been found to be cheap and effective, and to achieve remission at a similar rate as venesection [60]. Chloroquine binds 8 and 7–carboxylate porphyrins, which accumulate in lysosomes, and forms water soluble complexes with them that lead to tissue mobilization and increased urinary excretion [25, 59]. After initiation of chloroquine treatment, initial elevations of serum aminotransferases and porphyrins sometimes occur. These elevations are generally mild and usually normalize within 2 months [59, 60]. At least 3 months of treatment, however, are needed before clinical remission is seen. Similar to phlebotomy-monotherapy, complete biochemical remission usually is not achieved until at least 1 year of chloroquine treatment [59]. Another antimalarial agent, hydroxychloroquine (200 mg twice weekly), has also been shown to be an effective treatment for PCT; however, it is less preferred because remission is shorter than with chloroquine [60]. In severe cases, or when the most rapid therapeutic response is sought, phlebotomy and antimalarials may be used together and may result in faster remission than does either treatment alone (although this has not been shown in prospective randomized trials).

The reason for recommending low-dose chloroquine or hydroxychloroquine therapy in PCT is that, if full usual doses are used for initial therapy, a symptomatic acute hepatitis, with fever, right upper quadrant abdominal pain, and marked increases in serum aminotransferase levels often ensue, owing to a too rapid removal of accumulated porphyrins from hepatic stores with hepatocyte necrosis.

Iron chelation with deferoxamine has also been described as an alternative treatment for PCT in those who are intolerant of therapeutic phlebotomy [25, 62]. Subcutaneous infusions of deferoxamine (40–50 mg/kg BW) five nights a week for 8–10 h in 16 patients were able to normalize urinary porphyrin excretion. Once normalized, infusions were reduced to 5–10 days per month or every other month [25]. Although not as convenient or cheap as therapeutic phlebotomy, deferoxamine is able to remove the toxic highly reactive, loosely bound iron implicated in the pathogenesis of PCT. Furthermore, it may reduce the compensatory increase of intestinal iron absorption often seen in remission induced by the greater degree of iron reduction achieved by phlebotomies. Oral iron chelators (deferasirox, deferiprone) are also available in some countries. They, too, may be effective and relatively safe for therapy of PCT, especially in those with elevated SFs and increased total body iron stores. However, to the best of our knowledge, prospective randomized controlled trials of their use in PCT have not been performed.

Patients with end-stage renal disease undergoing dialysis, who typically are anaemic at baseline, may benefit from iron mobilization via a combination of erythropoietin and smaller volume phlebotomies. Dialyzers with ultra-permeable membranes and plasmapheresis may also be employed. Renal transplantation has been curative in refractory cases of PCT associated with chronic renal failure [62].

Treatment of chronic hepatitis C in the context of porphyria cutanea tarda
The principles of treatment described above can also generally be used for PCT in the setting of CHC. Although chloroquine effectively reduces uroporphyrin levels, it does not address the loosely bound hepatic iron thought to be of importance in PCT pathogenesis. Owing to the fact that patients with homozygous C282Y mutations of HFE (a risk factor for PCT) also failed to respond to chloroquine treatment, most investigators prefer phlebotomy in patients with both HFE gene mutations and CHC [63]. Although treatment of PCT alone with iron chelators is possible, such therapy is far more expensive and involved and thus phlebotomy is preferred. Furthermore, there is paucity of data regarding use of iron chelators in those with CHC and PCT [25].

It has been reported that interferon alpha (IFN) therapy improved the levels of serum aminotransferases and urinary porphyrins and resolved skin lesions along with decreasing HCV-RNA levels in patients with concurrent CHC and PCT [64, 65]. On the other hand, there are also a few reports of de novo occurrence of PCT during IFN plus ribavirin therapy for CHC [23].

In one small study reported only in abstract form, Rossini et al. [66] randomized 20 patients with both PCT and CHC into two cohorts. Group 1 received phlebotomy prior to dual therapy with pegylated interferon and ribavirin whereas group 2 received dual therapy without pretreatment venesection. The investigators measured levels of HCV-RNA in serum before and after iron depletion in group 1 and found no significant difference, in keeping with earlier results of others [67, 68]. No comparisons between the viral levels of the two groups were reported in the abstract. Mainly based on the results in their group 1, the investigators concluded that iron depletion did not seem to improve the rate of response to anti-HCV treatment in these patients. In addition to providing little data on group 2 (especially in comparison to group 1), the study was small in size and thus, lacks statistical power. Furthermore, while group 1 subjects were all infected with HCV of genotype 1b, there were two patients with genotype 2a in group 2. It is well known that genotype 2 HCV is more responsive to interferon-based therapy. Thus, the two rather small groups were not comparable, rendering interpretation of results problematical.

Treatment of PCT by iron reduction is successful even in patients with CHC. Because iron overload is found in most cases of PCT [8, 13, 21], and iron is a recognized factor that influence severity and course of chronic viral hepatitis [6, 61], reduction of iron stores by venesection can lead to improvement of both conditions. Furthermore, the fact that patients with CHC and PCT respond poorly to interferon (IFN) [69] and that phlebotomy enhances sustained virological response (SVR) of patients who received IFN monotherapy [70], suggest that venesection preceding combination antiviral therapy may be ideal. Therefore, it is usually wise to treat the PCT with therapeutic phlebotomies first and then deal with the treatment for CHC with peg-IFN and ribavirin or, now, with triple therapy (peg-IFN + ribavirin + HCV protease inhibitor, either boceprevir or telaprevir). Iron reduction prior to combination antiviral therapy not only helps to reduce possible deleterious effects of iron on UROD, and hence improves symptoms of PCT, but also facilitates decreasing of HCV-RNA levels, and impedes the synergistic effect of iron and HCV in the progression of liver disease. It is not yet known whether the newer triple (or, in future) quadruple –drug regimens for CHC will prove effective also as therapy for PCT with CHC. These issues will require future study.

Venesection prior to ribavirin (RBV)-based therapy may prove challenging because of the frequent development of hemolytic anaemia associated with RBV therapy. Thus optimal timing of when to stop phlebotomy prior to initiating RBV-based regimen is unknown [25]. Owing to paucity of data, some authors suggest that the haemoglobin levels be between 12 and 14 g/dl prior to starting RBV-based therapy after appropriate phlebotomy [25].

Treatment of hepatitis C virus-infected patients without porphyria cutanea tarda with Phlebotomy
Iron reduction may improve the severity of CHC and increase the likelihood of response of CHC to antiviral therapy. Prior to the advent of combination therapy with pegylated IFN and ribavirin, multiple clinical trials demonstrated improved clinical response in CHC patients treated with phlebotomy and IFN monotherapy compared to IFN monotherapy alone [71]. Desai et al. [70] conducted a meta-analysis of these randomized controlled trials and reported highly significant improvements in virological response rates (P < 0.001) from phlebotomy and IFN therapy compared to IFN alone.
Some investigators have reported that phlebotomy with dual therapy (ribavirin and interferon) does not improve viral response [66, 72, 73]. However, in a recent prospective, randomized controlled trial on the effect of phlebotomy in well-matched subjects with CHC undergoing combination therapy with peg-IFN and ribavirin, 6 of 10 (60%) of subjects who underwent phlebotomies vs only two of eight (25%) of subjects who did not undergo phlebotomies achieved an SVR [74].

Distante and colleagues [75] treated a total of 256 patients with CHC from 30 different hospitals with dual therapy for 6 months and found that, prior to treatment, non-responders (n = 127) compared to sustained responders (n = 129) had significantly higher median SF values (130 μg/L vs 75 μg/L, P = 0.001). In this study, sustained responders were defined as having negative HCV-RNA at 6 months after the end of 26 weeks of dual therapy. The study showed the following results: (i) only 10% of patients with SF ≥ 500 μg/L responded to dual therapy; (ii) patients with transferrin saturation ≥50% had lower sustained response rates; and (iii) there was an inverse correlation between SF values and sustained response rate by multivariate analysis.

Although SF was not found to be a reliable predictor of hepatic siderosis by some investigators [12], raised SF clearly is a predictor of non-response in patients with CHC [75]. Regardless of whether SF is a marker of hepatic siderosis or not, lowering SF via phlebotomy may be an alternative or adjunctive method of increasing SVR even in those without PCT. In an attempt to clarify the effects of dual therapy on iron status, Ferrara et al. conducted a prospective observational study in previously untreated subjects with CHC [76]. They found that, although SF prior to treatment had good specificity in predicting stainable iron in the liver (89%), its sensitivity in detecting iron overload was low (25%). Furthermore, they found that SVR is more likely to occur in subjects with lower baseline SF, who experienced a greater rise in SF levels during treatment than did those who did not achieve SVR. More specifically, they found an inverse correlation between serum iron, transferrin saturation, and SF with the degree of haemolysis up until week 4 of treatment. Indeed, they noted that a 2.5-fold increase in SF at week 12 was associated with increased SVR rates. Their results suggest that SF levels after 4 weeks of dual therapy are more reflective of other phenomena than siderosis caused by ribavirin-induced haemolysis alone. Perhaps, a greater rise in SF during antiviral therapy is a marker of greater biological responsiveness to therapy, similar to other changes in laboratory variables, previously shown to be associated with responsiveness to therapy [77]. Thus, although limited in sensitivity, SF at baseline provides a cheap and effective method to estimate siderosis if phlebotomy is planned prior to treatment, as well as prediction of likelihood of response to therapy.

A retrospective study by Rulyak et al. [73], concluded that pretreatment hepatic iron concentration (HIC) is not a predictor of response to combination IFN and RBV therapy. Similarly, although Pianko et al. [72] confirmed the possible beneficial effects of lower HIC in IFN monotherapy, they found the mean HIC in both sustained responders and non-responders to RBV-based dual therapy was not significantly different. As pointed out by Desai and colleagues [13], however, the mean HICs for subjects described in these studies were only 523 μg/g and <700 μg/g dry weight respectively. The fact that previous studies showed that HIC of at least 1100 μg/g separates responders from non-responders to IFN-based therapy may account for these discordant results.

In the previously discussed study by Ferrara and colleagues, the presence of iron in the mesenchymal cells (Kupffer cells and endothelial cells of the portal tract) and not the total iron score correlated with SVR. This finding agrees well with the analysis done by Bonkovsky et al. 3 years earlier when they reported that stainable iron in endothelial cells or in portal triads predicted a lower likelihood of SVR in those who underwent dual therapy [61, 78]. The distribution of iron among cell types in the liver is thus likely to be more important than HIC. However, in absence of selective iron removal techniques, pretreatment phlebotomy is the least expensive and most effective method to decrease HIC and iron in mesenchymal cells. In subjects with CHC and PCT (and most other conditions associated with iron loading) therapeutic phlebotomies will mobilize iron from storage sites throughout the body. Furthermore, when combined with an iron deficient diet, the concern posed by Ferrara and colleagues in regard to how the down-regulation of hepcidin may affect the targeted iron pool can be reasonably addressed. Of course, larger, adequately powered prospective studies are needed to confirm these tentative conclusions.

It is nonetheless clear that higher baseline levels of SF and/or HICs have been associated with more severe and advanced CHC and with decreased likelihood of responding to interferon [61, 67] or even dual therapy [76]. These observations understandably led to studies on effects of iron reduction in CHC without concomitant PCT. Iron reduction by therapeutic phlebotomy did not lead to any significant change in HCV-RNA levels in sera, but it did lead to improvements in serum ALT levels [79], to improvements in hepatic histopathology [68] and to decreases in histological progression and risk of development of HCC [80]. Indeed, iron reduction and low iron diets continue to be used, especially in Japan and China, as safe and inexpensive therapy for CHC among those who have not responded to, or have not tolerated, IFN-based antiviral therapy [81] (H Hayashi, L-Y Zheng, personal communication). Iron reduction is also used by some clinicians in the USA and Europe, [82] for similar indications (H Bonkovsky, unpublished; T Desai, S Shedlofsky, personal communication) although we acknowledge that this approach is not used in most centres. In several small studies, iron reduction before and during IFN therapy has been shown to improve CVR, EOTR and SVR, and a meta-analysis established significant benefit of such therapy [70].

Recently, investigators from Japan and Italy concluded that patients with CHC are more sensitive to iron hepatotoxicity than patients with HH and recommended venesection to reduce activity of liver disease in both conditions [83]. Others in Japan concluded that iron reduction by venesection was superior to dietary iron reduction in CHC [81].

Furthermore, other benefits of phlebotomy in CHC patients without PCT include known improvement of serum aminotransferase levels [8, 37, 70, 84], improvement of fibrosis [70], and decreased risk of HCC [25, 70]. In light of the above data, it is not unreasonable to recommend pretreatment phlebotomy in CHC patients without PCT, who have not responded to or have been intolerant of or unable to afford antiviral double or triple therapy, especially if they are found to have HICs >1100 μg/g dry liver or >1+ stainable iron [85], and if siderosis is primarily mesenchymal. However, additional larger prospective clinical trials are needed to better assess whether or not there is a role for iron reduction in management of some patients with chronic hepatitis C. Furthermore, with the several new stat-C small molecule drugs with potent activity against the HCV virus now under development, perhaps, in the not too distant future, rates of cure and tolerability of therapy will both improve further, and the numbers of subjects for whom iron reduction may be considered will decrease. Nevertheless, especially in less developed countries or in those without the means to afford expensive new multiple drug regimens, the inexpensive and safe measures of iron reduction and low iron diets may retain a useful place in the therapeutic armamentarium.

Summary and conclusions
An important aetiological association between CHC and PCT is well-established. Both CHC and PCT are also associated with hepatic iron overload and with increased oxidative stress. Other factors associated with PCT, such as excess alcohol and oestrogen therapy, also increase oxidative stress in hepatocytes (Fig. 1). The importance of iron is further emphasized by the fact that iron reduction regularly and reliably leads to amelioration of PCT, whether associated with CHC or not. In addition, studies, especially from the Far East, indicate that iron reduction that is sustained for several years leads to improvement of the histopathological severity of CHC, to reduced risk of histopathological progression, and to reduced risk of development of HCC. Thus, we recommend iron reduction as initial therapy of PCT and of CHC with PCT. In addition, iron reduction and maintenance of an iron-reduced state are reasonable therapeutic alternatives for those who do not respond to, who do not tolerate, or cannot afford, dual or triple antiviral therapy of CHC.

Supported by a grant (DK R01 38825) and contracts (U01 DK065201, U01 DK065176) from NIH (NIDDK) and by funds provided by the American Porphyria Foundation and the Carolinas HealthCare Foundation. We thank Melanie McDermid and Kay Snider for assistance with typing and preparation of the manuscript.

Conflicts of Interest: During the past 3 years, Dr. Bonkovsky has served as an advisor to and has received research support from Clinuvel, Inc and Novartis, Inc. He has been an adviser to Boehringer-Ingelheim, Gmbh and Lundbeck A/S. He has received research support from Vertex, Inc. Dr Bonkovsky is a member of the Scientific Advisory Board of the American Porphyria Foundation and is Chair of the Scientific Advisory Board of the Iron Disorders Institute. He is a member of the Board of Directors of the Iron Disorders Institute. Dr Bonkovsky is site PI at Carolinas Medical Center for the US Porphyria Consortium, a part of the Rare Diseases Clinical Research Network, supported by the NIH office of Rare Diseases and the NIDDK.

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