Mapping of host-parasite-microbiome interactions reveals metabolic determinants of tropism and tolerance in Chagas disease.

Chagas disease (CD) is a parasitic disease caused by Trypanosoma cruzi protozoa, presenting with cardiomyopathy, megaesophagus, and/or megacolon. To determine the mechanisms of gastrointestinal (GI) CD tissue tropism, we systematically characterized the spatial localization of infection-induced metabolic and microbiome alterations, in a mouse model of CD. Notably, the impact of the transition between acute and persistent infection differed between tissue sites, with sustained large-scale effects of infection in the esophagus and large intestine, providing a potential mechanism for the tropism of CD within the GI tract. Infection affected acylcarnitine metabolism; carnitine supplementation prevented acute-stage CD mortality without affecting parasite burden by mitigating infection-induced metabolic disturbances and reducing cardiac strain. Overall, results identified a previously-unknown mechanism of disease tolerance in CD, with potential for new therapeutic regimen development. More broadly, results highlight the potential of spatially resolved metabolomics to provide insight into disease pathogenesis and infectious disease drug development.

Further polymorphism of the MICA gene.

The MHC class I chain-related (MIC) gene family constitutes an interesting genetic group that is related to major histocompatibility complex (MHC) class I genes and is located within the MHC. The MIC gene products, MICA and MICB, have similar structures to HLA class I molecules. So far over 50 MICA alleles have been reported, which suggests that this genetic system is highly polymorphic. In order to investigate further the extent of MICA polymorphism we have studied exons 2-5 of the MICA gene in over 200 homozygous and heterozygous cell lines. Altogether we have identified 11 new MICA alleles and report 13 new nucleotide variations, one in exon 2, four in exon 3, four in exon 4, two in intron 1, one in intron 4 and one (a deletion) in exon 4. Eight of the 10 exonic variations are non-synonymous. The deletion in exon 4 leads to a frame-shift mutation and the introduction of a repeat of 12 leucine residues encoded by the microsatellite in exon 5. This study provides further evidence that the MICA gene is highly polymorphic. In contrast to MHC class I molecules, the polymorphic sites in MICA are predominantly within the alpha2 and alpha3 domains. The distribution of synonymous and non-synonymous substitutions suggests that there is selection for the polymorphic positions, which therefore define potential functional sites in the protein. We were also able to determine the association between MICA and HLA-B alleles in a number of homozygous cell lines bearing extended haplotypes.

HLA-B*8202 identified in a Caucasoid potential bone marrow donor.

Sequence analysis of HLA class I alleles has continued to reveal the true extent of polymorphism, particularly for B-locus alleles. This diversity can arise through reshuffling of polymorphic sequences generated by point mutation, resulting in interallelic recombination or intergenic recombination (1). Here we describe a new B-locus allele, B*8202, which is structurally most similar to B*8201, having only one nucleotide difference in exon 3 at nucleotide 557, resulting in an amino acid change of aspartic acid to glycine at residue 162. Glycine is the consensus amino acid for B-locus alleles, which suggests that B*8202 is older than B*8201 in evolutionary terms. B*8201 was found to be a hybrid of B*4501 and B*5602 that may have arisen through recombination events, explaining the serological patterns observed with these allotypes. The importance of high-resolution typing is emphasised here as routine typing suggested the presence of B*8201 and the new variant allele may have been missed had it not been typed further by sequence-based typing.