Hepatitis C virus is classified into the gender Hepacivirus of the Flaviviridae family. It is a spherical virus of approximately 50 nm of diameter. It has a glycoproteic enfold that contains lipids and a positive chain genome of 9600 nucleotides of length that codifies a precursor of large-sized lipoproteins, segmented simultaneously with the processes of cotraslation and postraslation to produce particular structural and nonstructural proteins. The coding genes order is 5’-C-E1-E2-p7-NS2-NS3-NS4A-NS4B-NS5A-NS5B-3’. The C gen, consisted of 190 amino acids, is the basic subunit of the nucleocapsid protein. A characteristic of the E gen is the presence of a hypervariable region that codifies two envelop glycoproteins (E1 and E2), involved in the union to cellular receptors and the entrance of the virus to the host cell. N2 and N3 genes codify two proteases that are involved in the processing of the nonstructural region, while NS4A gen acts as a cofactor for the activity of a NS3 serin-protease enzyme. NS5 derive two phosphorylated products (whose function is unknown), NS5B contains the RNA dependent-RNA polymerase domain, essential for the viral replication. This RNA virus is characterized for a high genomic heterogeneity degree as a consequence of RNA polymerase to correct replication mistakes.

In the study entitled Biliverdin Inhibits Hepatitis C Virus Nonstructural 3/4A Protease Activity: Mechanism for the Antiviral effects of Heme Oxygenase? published in the December issue of the Hepatology by Zhu et al., it is reported that biliverdin has a strong inhibitory activity against recombinant and endogenous NS3/4A protease.1 Several studies have shown that HCV infection is associated with an oxidative injury, and for this reason modulation of host cells antioxidant activity has been suggested as a potential therapeutic target for HCV infection.2 Dionisio et al. found that the two main players in the oxidative stress caused by HCV are the hepatitis C core protein and non structural protein NS5A.3

Heme oxygenase (HMOX) is the enzyme which degrades heme and produces carbon monoxide, biliverdin and iron. Biliverdin is then converted into bilirubin by biliverdin reductase, HMOX is upregulated not only by heme, but also by oxidative stress stimuli, and its overexpression constitutes a protective cellular response against oxidative stress.4

HMOX has anti-inflammatory and antiapoptotic activities both in vivo and in vitro, and the induction of this enzyme has been found to have a protective role in ischemic acute renal failure,5 cerebral ischemia,6 organ transplantation7 and apoptotic damage.8 Interestingly, HMOX has been found to have important antiviral effects against hepatitis B virus (HBV). Protzer and colleagues reported that the induction of HMOX by cobalt-protoporphyrin-IX treatment significantly reduced the levels of HBV core protein.9 In regards to human immunodeficiency virus (HIV), McPhee et al. found that biliverdin and bilirubin inhibited recombinant HIV-1 protease in vitro and also HIV-2 and simian immunodeficiency virus proteases10. Other pyrrolic pigments, such as stercobilin, urobilin, biliverdin dimethyl ester and xanthobilirubic acid, also showed similar inhibitory activity at low concentrations.10 There is accumulating body of evidence that bile pigments have other multiple and in general anti-inflammatory properties. They exert anti-complement action, block leukocyte adhesion and activation, monocyte migration or inhibic adhesion molecule signalling. 11 In 2008, Zhu et al. evaluated the effect of HMOX on HCV replication and found that overexpression of HMOX decreased HCV DNA replication in full length and nonstructural replicons, without affecting DNA synthesis and cellular growth. 2 More recently they observed that biliverdin, and in to a lesser extent its metabolite, bilirubin, have antiviral activity in the human hepatoma cell line (Huh5-15) and Huh7.5 cells harboring full length (Huh7.5FL) Con1 replicons. Biliverdin showed antiviral activity in concentrations as low as 20 μM (1.17 mg/dL); by contrast, bilirubin-IX-α and other mixed isomers showed antiviral activity at concentrations of 200 μM (11.7 mg/dL) or higher. Qin found that deconjugated bile pigments inhibit serine-activated pancreatic proteases such as chymotrypsin and trypsin, which led the group to investigate the effects of biliverdin and other tetrapyrrolic derivates on the activity of HCV NS 3/4A. 12 When Zhu et al. measured the activity of the protease and compared the inhibitory activity of the biliverdin with that of a known competitive inhibitor of the NS3/4A (AnaSpec #25346) they observed that biliverdin activity was similar to that of the inhibitor. Although still unsettled, the mechanism of biliverdin inhibition on proteases might be related to the helical porphyrinlike conformation of this pyrrolic derivative affecting also lipophilicity of this pigment.

It remains to be elucidated what is the biological relevance of the findings that biliverdin and other tetrapyrrolic pigments inhibit the activity of NS3/4A as well as NS5B. Serum concentrations of heme are much lower 13,14 than those used by Zhu et al.1, and serum levels of biliverdin are practically undetectable. 15 It also should be noted that in a clinical study on US population no correlation was found between HMOX1 promoter sequence variations modulating enzymatic activity and HCV infection outcomes. 16 These results are in line with our own results (LV, unpublished data) demonstrating no prognostic role in genetic variations of both HMOX1 and bilirubin UDP-glucuronosyl transferase (UGT1A1) genes on HCV clinical status. Although the gap between in vitro and in vivo data still remains rather large, the demonstration of inhibitory effects of tetrapyrrolic pigments on HCV proteases may unlock a wide range of possibilities to create new potential therapies for HCV infection.