Evidence for an early evolutionary emergence of γ-type carbonic anhydrases as components of mitochondrial respiratory complex I

Background  

The complexity of mitochondrial complex I (CI; NADH:ubiquinone oxidoreductase) has increased considerably relative to the homologous complex in bacteria. Comparative analyses of CI composition in animals, fungi and land plants/green algae suggest that novel components of mitochondrial CI include a set of 18 proteins common to all eukaryotes and a variable number of lineage-specific subunits. In plants and green algae, several purportedly plant-specific proteins homologous to γ-type carbonic anhydrases (γCA) have been identified as components of CI. However, relatively little is known about CI composition in the unicellular protists, the characterizations of which are essential to our understanding of CI evolution.     

Single- and double-stranded RNA measurements by flow cytometry in solid neoplasms

We investigated the ability of single- and double-stranded RNA measurements to discriminate between neoplastic and non-neoplastic solid tissues. Sixty-one solid nonhematopoietic neoplasms, 10 reactive non-neoplastic lesions, and 26 normal tissue samples were the test materials. Single-stranded ribonucleic acid (s-RNA) levels and double-stranded ribonucleic acid (ds-RNA) excess in these specimens were defined in relationship to normal human lymphocytes. The mean s-RNA index in normal, reactive, benign, and diploid and aneuploid malignant tissue samples was 0.90, 1.54, 1.9, 1.2, and 2.2, respectively. For ds-RNA, the mean excess level for normal, reactive, benign, and diploid and aneuploid malignant specimens was 8.5%, 18.5%, 51.0%, 36.0%, and 41.3%, respectively. No statistical differences in s-RNA level were found between non-neoplastic and neoplastic tissue samples. A significant difference in ds-RNA excess was found between non-neoplastic and benign, and diploid and aneuploid malignant neoplastic tissue (P less than 0.001). The specificity of s-RNA level and ds-RNA excess was 94.4% and 100%, and the sensitivity was 29.5% and 67.2%, respectively. Notably, ds-RNA determinations identified 70.0% of the diploid neoplastic samples, in contrast to 20% by s-RNA. Our preliminary data suggest that ds-RNA may be a useful parameter and may complement DNA ploidy in identification of solid neoplasms, especially if the yield of intact cells is improved.