Differences in treatment status within the patient population may have effects on the resulting tissues used to obtain genomic DNA and thus the results of the LOH studies. LOH in Wilms tumors appears to occur in large sections on the short arm of chromosome 7, as seen in patients W-733 and W-8188 (Figure 2). This is concordant with previous studies [4, 10, 33, 34]. Notably, two patients (W-8194 and W-8197) showed examples of just one instance of LOH each. Due to distances between
LOH markers for patient W-8194 (approximately 100 kb), and a lack of informative SNPs in SOSTDC1, it is unclear whether this region of LOH extends beyond the SOSTDC1 locus. Patient W-8197 showed IWR-1 purchase one instance of LOH in the direct sequence. As no other informative SNPs were found within the direct sequence, this may represent either LOH affecting SOSTDC1 or a point mutation. It is noteworthy that tumor size, stage, histology, and treatment status varied among these patients. We observed LOH affecting the SOSTDC1 locus at a frequency of 5/36 (14%) in adult RCC. In contrast to the observations within the Wilms tumors, the regions of LOH in adult RCC tumors were noncontiguous, as SNPs showing LOH were broken up by heterozygous alleles.
Due to the high incidence of aneuploidy in these tumors, this phenomenon may be partially explained by chromosomal copy number variation. Indeed, multiple studies referenced in the Database of Genomic Variants show variations in copy number that affect parts of the 2 Mb region; including the area around SOSTDC1 [35, 36]. We have previously reported downregulation of both the message (90% of check details patients) and protein encoded by SOSTDC1 in RCC-clear cell tumors
[16]. To determine whether or not these observations could be attributed to LOH, we performed immunohistochemistry on the patient samples that had displayed LOH at SOSTDC1. We found that SOSTDC1 protein levels were comparable between samples that displayed LOH and those that did not (Figure 3), indicating that the instances of LOH observed in our patient samples were not associated with a detectable decrease in SOSTDC1 protein expression. Considering previous observations that SOSTDC1 negatively regulates Wnt-induced Interleukin-3 receptor signaling in renal cells, we also tested whether SOSTDC1 LOH corresponded to increased Wnt signaling in patient samples. To this end, selleck chemical immunohistochemical analyses were undertaken to compare SOSTDC1-relevant signaling between samples with and without LOH. This staining showed that LOH status did not consistently alter the levels or localization of β-catenin, a marker of Wnt pathway activation (Figure 3). The observations that LOH at SOSTDC1 did not decrease SOSTDC1 protein expression or increase Wnt-induced signaling suggest that LOH may not be the key regulator of SOSTDC1 protein expression in pediatric and adult renal tumors.