Mohammad Zafrullah

A genetic analysis of HIV-1 from Punjab, India reveals the presence of multiple variants.

ObjectiveTo determine the extent of HIV-1 genetic variation in Indian patients. Design: To avoid any bias in selecting viral variants, HIV-1 DNA was amplified directly from the peripheral blood mononuclear cells of patients and sequenced. Genetic similarity between Indian sequences and other geographic isolates was analysed by phylogenetic analysis algorithms. MethodsA fragment encompassing the C2/V3-V5 regions of HIV-1 gp120 was amplified from the lymphocyte DNA of 12 Indian patients. Multiple clones from each patient were sequenced. Nucleotide sequences encompassing about 650 base pairs were aligned for the Indian and other geographically distinct isolates. Inter-isolate relationships were analysed by means of distance, parsimony and neighbour-joining algorithms. ResultsNucleotide sequence comparisons showed low interpatient variation. Amino-acid comparisons revealed a high degree of homology between Indian sequences in this study and those studied earlier. On distance and parsimony trees, most of the Indian sequences clustered together as subtype C. However, sequences from three patients also showed significant homologies and phylogenetic clustering outside of subtype C. ConclusionsThe predominant strain of HIV-1 in India belongs to subtype C and little interpatient nucleotide sequence divergence in the majority of cases suggests recent spread of HIV-1 in this region. This study also presents the first evidence for non-C subtypes in the Indian population with two epidemiologically linked samples remaining unclassified for any existing env subtype. The presence of variant subtypes in Indian patients sheds light on the transmission routes of HIV-1 to India and emphasizes the need to include these sequences in vaccine development strategies.

Reevaluation of a North India isolate of hepatitis E virus based on the full-length genomic sequence obtained following long RT-PCR

The genomic cloning and sequence of hepatitis E virus (HEV) from an epidemic in North India is reported. We describe here a simple method wherein the viral RNA was reverse transcribed and then amplified in a single step using an extra long polymerase chain reaction procedure. The full genome nucleotide sequence of this HEV isolate (called Yam-67) was made up of 7191 nucleotides, excepting the poly(A) tail and had three open reading frames: ORF1 coding for 1693 amino acids (aa), ORF2 coding for 659 aa and ORF3 coding for 122 aa. This North Indian isolate of HEV showed close sequence homology to other HEV isolates from India and Asia, but was distant from the Chinese genotype 4, Japanese, Mexican and US isolates. There is no indication from sequence analysis that this may be an atypical strain of HEV, as reported earlier.

A C-terminal hydrophobic region is required for homo-oligomerization of the hepatitis E virus capsid (ORF2) protein

Hepatitis E virus (HEV) is the causative agent of hepatitis E, an acute form of viral hepatitis. The open reading frame 2 (ORF2) of HEV encodes the viral capsid protein, which can self-oligomerize into virus-like particles. To understand the domains within this protein important for capsid biogenesis, we have carried out in vitro analyses of association and folding patterns of wild type and mutant ORF2 proteins. When expressed in vitro or in transfected cells, the ORF2 protein assembled as dimers, trimers and higher order forms. While N-terminal deletions up to 111 amino acids had no effect, the deletion of amino acids 585–610 led to reduced homo-oligomerization. This deletion also resulted in aberrant folding of the protein, as determined by its sensitivity to trypsin. This study suggests that a C-terminal hydrophobic region encompassing amino acids 585–610 of the ORF2 protein might be critical for capsid biogenesis.