Gene-environment interaction between MBL2 genotype and smoking, and the risk of gram-positive bacteraemia.

Mannose-binding lectin (MBL) insufficiency caused by point mutations in the MBL2 gene has been associated with increased susceptibility to bacteraemic infections. We here investigated the effect of MBL2 polymorphisms on the susceptibility and clinical course of bacteraemia. The study cohort comprised 145 patients with bacteraemia and 400 controls. In the case of patients with bacteraemia, laboratory findings and clinical data were registered on admission and during six consecutive days. MBL2 structural polymorphisms at codons 52 (CGT-->TGT; designated D or O), 54 (GGC-->GAC; B or O) and 57 (GGA-->GAA; C or O) in exon 1 of the MBL2 gene and promoter region polymorphisms at position -221 (G-->C, designated Y or X alleles) were determined. No difference in MBL2 genotype frequencies between the bacteraemic patients and controls was detected, and MBL2 genotype had no independent effect on mortality, nor disease severity. However, smoking proved a significant risk factor for Gram-positive (Staphylococcus aureus, Streptococcus pneumoniae or beta-haemolytic streptococci) bacteraemia in patients carrying the variant O allele (53% current smokers in Gram-positive bacteraemia patients compared with only 21% in controls, odds ratios 4.2, 95% confidence intervals 2.0-9.0; P < 0.001), while it did not have an effect in those homozygous for the A allele. The same effect was not detected in Escherichia coli bacteraemia. In conclusion, MBL2 genotypes representing MBL insufficiency were not associated with the overall risk of bacteraemia or disease severity, but smoking in carriers of the structural variant O allele may have a deleterious effect increasing the risk of Gram-positive bacteraemia.

Mannose-binding lectin 2 (MBL2) gene polymorphism in asthma and atopy among adults.

Mannose-binding lectin (MBL) insufficiency due to polymorphisms in the MBL2 gene causes an opsonization defect, which has been connected to infections and atopy. We investigated the significance of MBL2 genotypes with regard to persistent asthma and atopy among adults. The genotypes were determined in 243 adults with persistent asthma and 400 controls. Atopy was determined by skin-prick test. As a result, the carriage of -221 base pairs (bp) promoter region variant allele X (nucleotide change G-->C; alleles Y-->X, respectively) causing low MBL expression proved to be a significant risk factor for asthma in non-atopic males [odds ratio (OR) = 2.52, 95% confidence interval (CI) = 1.23-5.15; P = 0.01]. Furthermore, the X-allele carriage was associated with the decrease in lung function (forced expiratory volume at 1 s, FEV(1)) during follow-up in the patients with asthma (P = 0.033), the effect being strongest for non-atopic asthmatics (P = 0.042). The MBL2 genotype had no clear effect on the occurrence of atopy in adults. In conclusion, our results abrogate the previously suggested predisposing effect of MBL insufficiency on atopy at least in adults. However, as MBL is a complement component participating in immune defence against microbes, and as in the pathogenesis of non-atopic asthma infectious agents are probably involved, the gene-environment interactions between MBL and infections should be assessed further with regard to asthma.

Mutations at the mitochondrial DNA polymerase (POLG) locus associated with male infertility.

Human mitochondrial DNA polymerase, encoded by POLG, contains a polyglutamine tract encoded by a CAG microsatellite repeat. Analysis of POLG genotypes in different populations identified an association between absence of the common, ten-repeat allele and male infertility typified by a range of sperm quality defects but excluding azoospermia.

Novel coding-region polymorphisms in mitochondrial seryl-tRNA synthetase (SARSM) and mitoribosomal protein S12 (RPMS12) genes in DFNA4 autosomal dominant deafness families.

Two genes for components of the mitochondrial translational apparatus, mitochondrial seryl-tRNA synthetase (SARSM) and mitoribosomal protein S12 (RPMS12) lie adjacent to one another on human chromosome 19, within the critical interval for the autosomal dominant deafness locus DFNA4. Both genes are plausible candidates for DFNA4, based on the fact that deafness mutations in mtDNA have been mapped both to tRNA-ser(UCN) and to the accuracy domain of the small subunit rRNA. We have sequenced the coding regions, proximal promoters, 5' and 3' UTR and splice junctional regions of both genes in two families with DFNA4-linked deafness and in controls. Novel polymorphisms 84425C>T, 83907A>G, 79485T>G, 79406C>T, 71755A>C and 68686C>G (numbered as in GenBank AC011455) were found in one or both families, but none is a plausible disease-causing mutation. Although regulatory mutations affecting either gene could still be involved in the phenotype, structural gene mutations affecting SARSM or RPMS12 can be excluded from consideration as the cause of DFNA4-linked deafness, at least in the families identified thus far.

Human mtDNA sublimons resemble rearranged mitochondrial genoms found in pathological states.

Sublimons, originally identified in plant mitochondria, are defined as rearranged mtDNA molecules present at very low levels. We have analysed the primary structures of sublimons found in human cells and tissues and estimated their abundance. Each tissue of a given individual contains a wide range of different sublimons and the most abundant species differ between tissues in a substantially systematic manner. Sublimons are undetectable in rho(0) cells, indicating that they are bona fide derivatives of mtDNA. They are most prominent in post-mitotic tissue subject to oxidative stress. Rearrangement break-points, often defined by short direct repeats, are scattered, but hotspot regions are clearly identifiable, notably near the end of the D-loop. The region between the replication origins is therefore frequently eliminated. One other hotspot region is located adjacent to a known site of protein binding, suggesting that recombination may be facilitated by protein-protein interactions. For a given primary rearrangement, both deleted and partially duplicated species can be detected. Although each sublimon is typically present at a low level, at most a few copies per cell, sublimon abundance in a given tissue can vary over three orders of magnitude between healthy individuals. Collectively, therefore, they can represent a non-negligible fraction of total mtDNA. Their structures are very similar to those of the rearranged molecules found in pathological states, such as adPEO and MNGIE; therefore, we propose that, as in plants, human mtDNA sublimons represent a pool of variant molecules that can become amplified under pathological conditions, thus contributing to cellular dysfunction.