The association between fructosamine-3 kinase 900C/G polymorphism, transferrin polymorphism and human herpesvirus-8 infection in diabetics living in South Kivu.

Prevalences of human herpesvirus-8 (HHV-8) infection and diabetes mellitus are very common in certain parts of Africa, containing iron-rich soils. We hypothesized that some genetic factors could have a link with susceptibility to HHV-8 infection. We focused on ferroportin Q248H mutation (rs11568350), transferrin (TF) polymorphism and fructosamine-3 kinase (FN3K) 900C/G polymorphism (rs1056534). The study population consisted of 210 type 2 diabetic adults and 125 healthy controls recruited in Bukavu (South Kivu). In the whole study population (diabetics+healthy controls), ferroportin Q248H mutation was detected in 47 subjects (14.0%) with 43 heterozygotes and 4 homozygotes. TF phenotype frequencies were 88.1% (CC), 10.4% (CD) and 1.5% (BC). Genotype frequencies of FN3K 900C/G polymorphism were respectively 9,3% (CC), 43.3% (GC) and 47.4% (GG). Prevalence of HHV8-infection in the study population was 77.3%. HHV-8 infection rate and HHV-8 IgG antibody titer were significantly higher in diabetics then in controls (p<0.0001). Significant differences were observed in HHV-8 infection rate and in HHV-8 IgG antibody titer according to FN3K rs1056534 (p<0.05 and p<0.05, respectively) and TF polymorphism (p<0.05 and p=0.005, respectively). No significant differences in HHV-8 infection rate and in HHV-8 IgG antibody titer were observed in the ferroportin Q248H mutation carriers (rs11568350) in comparison with ferroportin wild type. In a multiple regression analysis, FN3K rs1056534, TF polymorphism and presence of diabetes mellitus were predictors for HHV-8 infection. In contrast to these findings, ferroportin Q248H mutation (rs11568350) did not influence the susceptibility for an HHV-8 infection in sub-Saharan Africans.

Viral protease cleavage of inhibitor of kappaBalpha triggers host cell apoptosis.

Apoptosis is an innate immune response to viral infection that limits viral replication. However, the mechanisms by which cells detect viral infection and activate apoptosis are not completely understood. We now show that during Coxsackievirus infection, the viral protease 3C(pro) cleaves inhibitor of kappaBalpha (IkappaBalpha). A proteolytic fragment of IkappaBalpha then forms a stable complex with NF-kappaB, translocates to the nucleus, and inhibits NF-kappaB transactivation, increasing apoptosis and decreasing viral replication. In contrast, cells with reduced IkappaBalpha expression are more susceptible to viral infection, with less apoptosis and more viral replication. IkappaBalpha thus acts as a sensor of viral infection. Cleavage of host proteins by pathogen proteases is a novel mechanism by which the host recognizes and responds to viral infection.