Renal phenotype of young and old telomerase-deficient mice.

Telomere shortening in the kidney explains the impaired regenerative capacity, but may not drive the ageing phenotype itself. We investigated kidneys from young and old Terc(+/+) and Terc(-/-) mice of early (G1) and late (G4, G5) generations. Functional parameters declined and age-related morphological changes increased in late generation Terc(-/-) mice and with further age.

Association of single nucleotide polymorphisms on chromosome 9p21.3 with cardiovascular death in kidney transplant recipients.

Background: Recipient death is a leading cause for renal allograft loss. Cardiovascular mortality is the most important cause of death among this patient group. Single nucleotide polymorphisms (SNPs) in a noncoding region close to the CDKN2a/b senescence genes have been associated with higher cardiovascular morbidity and mortality in nontransplant populations.

Telomere shortening reduces regenerative capacity after acute kidney injury.

Telomeres of most somatic cells progressively shorten, compromising the regenerative capacity of human tissues during aging and chronic diseases and after acute injury. Whether telomere shortening reduces renal regeneration after acute injury is unknown. Here, renal ischemia-reperfusion injury led to greater impairment of renal function and increased acute and chronic histopathologic damage in fourth-generation telomerase-deficient mice compared with both wild-type and first-generation telomerase-deficient mice.