Scientific Abstract: Diabetic kidney disease (DKD) is the leading cause of end-stage renal disease. While DKD injury factors are extensively studied, protective factors remain poorly defined and present a critical knowledge gap. Recently we and others described the existence of potential protective and healing mechanisms in DKD. These concepts warrant further investigation and have the potential to greatly improve outcomes. Papers from our and other laboratories confirm that after multiple passages cultured skin fibroblasts (SF) behaviors differ between patients with versus without DKD. Consistent with protective mechanisms, our earlier gene expression studies showed that individuals protected from DKD had some SF behaviors that differ both from patients with DKD and from normal controls, suggesting the protected group had unique cellular behaviors associated with very slow development of DKD lesions. Our recent gene expression studies (hi-seq) in SF grown in high glucose (HG) uncovered that pathways related to DNA replication and repair, protein repair, and cell cycle were markedly overexpressed in patients with type 1 diabetes (T1D) without DKD as compared to T1D patients with DKD and non-diabetic controls. These pathways were also differently expressed in SF of monozygotic twins discordant for T1D. Thus, upregulation of these pathways is posited as protective of DKD and epigenetically regulated. Hyperglycemia induces DNA damage, thus activating DNA repair pathways [primarily the base excision repair (BER) pathway] in order to restore DNA integrity and prevent cellular dysfunction. Indeed, the BER pathway was markedly up-regulated in T1D patients without DKD (p=5.14e-5) as compared to patients with DKD and controls. Our preliminary data indicate that BER pathway is also upregulated in proximal tubular epithelial cells (PTEC). We will test whether these pathway differences are associated with functional differences in SF and PTEC cultured from research skin and kidney biopsies in T1D volunteers.
Our Specific Aims are to determine 1) changes in BER protein levels, DNA damage and repair capacity in SF in response to in vitro HG and their relationship to DKD risk, 2) changes in BER protein levels, DNA damage, repair capacity and response to a therapeutic agent in PTEC cultured in HG and their relationship to DKD risk, 3) urinary levels of DNA damage products in relation to DKD risk, and 4) epigenetic mechanisms associated with gene expression in key differentially expressed BER pathway genes. We hypothesize that, although both T1D patients with and without DKD may have increased BER pathway activity compared to controls, this activity will be much greater in the patients protected from DKD, and that our robust SF findings will be recapitulated in PTEC. Given the depth of our basic science strengths in the relevant areas, the unique research materials, the innovative technical capabilities of our superb investigative team, and our proven collaboration track, we are extremely well positioned for the successful completion of these studies. If our hypotheses are borne out, this work will open new research avenues aimed at DKD prevention.
Strong data indicate that hyperglycemia induces oxidative DNA damage which is linked to chronic complications of diabetes, including diabetic kidney disease, the leading cause of end-stage renal disease in the U.S. DNA damage due to oxidative injury is primarily repaired by the base excision repair (BER) pathway, and we recently described that the BER pathway was upregulated in cultured skin fibroblasts of patients with type 1 diabetes without versus with DN or non-diabetic controls. This proposal will define the functional consequences of BER upregulation as well as the mechanisms associated with protection and recovery from hyperglycemia-induced cellular injury in two independent model systems and has the potential to lead to novel preventative and therapeutic strategies.
