A unique computational approach combined with in vitro telomerase activity reconstitution studies was used to identify 83 novel TRs from 10 animal kingdom phyla spanning 18 diverse classes from the most basal sponges to the late evolving vertebrates. This revealed that three structural domains, pseudoknot, a distal stem-loop moiety and box H/ACA, are conserved within TRs from basal groups to vertebrates, while group-specific elements emerge or disappear during animal TR evolution along different lineages.
Next the corn-smut fungus Ustilago maydis TR was identified using an RNA-immunoprecipitation and next-generation sequencing approach followed by computational identification of TRs from 19 additional class Ustilaginomycetes fungi, leveraging conserved gene synteny among TR genes. Phylogenetic comparative analysis, in vitro telomerase activity and TR mutagenesis studies reveal a secondary structure of TRs from higher fungi, which is also conserved with vertebrates and filamentous fungi, providing a crucial link in TR evolution within the opisthokonta super-kingdom.
Lastly, work by collabarotors from Texas A&M university and others identified the first bona fide TR from the model plant Arabidopsis thaliana. Computational analysis was performed to identify 85 novel AtTR orthologs from three major plant clades: angiosperms, gymnosperms and lycophytes, which facilitated phylogenetic comparative analysis to infer the first plant TR secondary structural model. This model was confirmed using site-specific mutagenesis and telomerase activity assays of in vitro reconstituted enzyme. The structures of plant TRs are conserved across land plants providing an evolutionary bridge that unites the disparate structures of previously characterized TRs from ciliates and vertebrates.
Telomeres are repetitive DNA sequences at linear chromosome termini, protecting chromosomes against end-to-end fusion and damage, providing chromosomal stability. Telomeres shorten with mitotic cellular division, but are maintained in cells with high proliferative capacity by telomerase. Loss-of-function mutations in telomere-maintenance genes are genetic risk factors for cirrhosis development in humans and murine models. Telomerase deficiency provokes accelerated telomere shortening and dysfunction, facilitating genomic instability and oncogenesis. Here we examined whether telomerase mutations and telomere shortening were associated with hepatocellular carcinoma (HCC) secondary to cirrhosis. Telomere length of peripheral blood leukocytes was measured by Southern blot and qPCR in 120 patients with HCC associated with cirrhosis and 261 healthy subjects. HCC patients were screened for telomerase gene variants (in TERT and TERC) by Sanger sequencing. Age-adjusted telomere length was comparable between HCC patients and healthy subjects by both Southern blot and qPCR. Four non-synonymous TERT heterozygous variants were identified in four unrelated patients, resulting in a significantly higher mutation carrier frequency (3.3%) in patients as compared to controls (p = 0.02). Three of the four variants (T726M, A1062T, and V1090M) were previously observed in patients with other telomere diseases (severe aplastic anemia, acute myeloid leukemia, and cirrhosis). A novel TERT variant, A243V, was identified in a 65-year-old male with advanced HCC and cirrhosis secondary to chronic hepatitis C virus (HCV) and alcohol ingestion, but direct assay measurements in vitro did not detect modulation of telomerase enzymatic activity or processivity. In summary, constitutional variants resulting in amino acid changes in the telomerase reverse transcriptase were found in a small proportion of patients with cirrhosis-associated HCC.