Delineation of the IGF-II C domain elements involved in binding and activation of the IR-A, IR-B and IGF-IR.

OBJECTIVE: Human insulin-like growth factor-I and -II (IGF-I and -II) ligands share a high degree of sequence and structural homology. Despite their similarities, IGF-I and IGF-II exhibit differential receptor binding and activation characteristics. The C domains of IGF-I and IGF-II are the primary determinants of binding specificity to the insulin-like growth factor I receptor (IGF-IR), insulin receptor exon 11- (IR-A) and exon 11+ (IR-B) isoforms. DESIGN: Three IGF-II analogues were generated in order to delineate the C domain residues that confer the differential receptor binding affinity and activation properties of the IGFs. Chimeric IGF-II analogues IGF-IICI(N) and IGF-IICI(C) contained partial IGF-I C domain substitutions (IGF-I residues underlined) GYGSSSRRSR and SRVSRRAPQT, respectively. RESULTS: The IGF-IICI(N) analogue bound the IR-A and IGF-IR with high affinity but bound the IR-B with a relatively lower affinity than IGF-II, suggesting a negative interaction between the exon-11 encoded peptide in the IR-B and the C-domain. The ability of IGF-IICI(N) to activate receptors and elicit cell viability responses was generally proportional to its relative receptor binding affinity but appeared to act as a partial agonist equivalent to IGF-I when binding and activating the IGF-IR. In contrast, IGF-IICI(C) bound IGF-IR with high affinity but elicited lower receptor activation and cell viability responses. Analogue IGF-IICI(S) contained a truncated IGF-I C domain (GSSSRRAT) and generally displayed a relatively poor ability to bind, activate and elicit viability responses via each receptor. CONCLUSIONS: Together, the IGF analogues demonstrate that both flanks of the IGF-II C domain play important roles in the greater ability of IGF-II to bind and activate IR receptors than IGF-I.

Serum concentrations of brain-derived neurotrophic factor (BDNF) are decreased in colorectal cancer patients.

OBJECTIVE: To determine the usefulness of brain-derived neurotrophic factor (BDNF) as a diagnostic biomarker for colorectal cancer (CRC). MATERIALS AND METHODS: ELISA immunoassay was used to examine BDNF concentrations in the sera of two different retrospective cohorts consisting of CRC patients and age/gender matched controls. Cohort 1 consisted of 99 controls and 97 CRC patients, whereas cohort 2 consisted of 47 controls and 91 CRC patients. RESULTS: In cohort 1, the median concentration of BDNF was significantly (p< 0.0001) lower in CRC patient samples (18.8 ng/mL, range 4.0-56.5 ng/mL) than control samples (23.4 ng/mL, range 3.0-43.1 ng/mL). This finding was validated in an independent patient cohort (CRC patients: 23.0 ng/mL, range 6.0-45.9 ng/mL; control patients: 32.3 ng/mL, range 14.2-62.4 ng/mL). BDNF concentrations did not differ significantly between Dukes' staging in the patient cohort, however patients with Stages A, B, C and D (p< 0.01 for each stage) tumours had significantly reduced BDNF levels compared to healthy controls. Receiver operating characteristic analysis was performed to determine the ability of BDNF to discriminate between healthy controls and those with CRC. At 95% specificity, BDNF concentrations distinguished CRC patients with 25% and 18% sensitivity, respectively, in cohorts 1 and 2 (cohort 1: AUC=0.79, 95% CI 0.70-0.87; cohort 2: AUC =0.69, 95% CI 0.61-0.76). CONCLUSION: The serum levels of BDNF were significantly lower in colorectal cancer patients when compared to a control population, and this did not differ between different Dukes' stages.

Silencing of the insulin receptor isoform A favors formation of type 1 insulin-like growth factor receptor (IGF-IR) homodimers and enhances ligand-induced IGF-IR activation and viability of human colon carcinoma cells.

Insulin receptor (IR) overexpression is common in cancers, with expression of the A isoform (IR-A, exon 11-) predominating over the B isoform. The IR-A signals a proliferative, antiapoptotic response to IGF-II, which itself can be secreted by tumors to establish an autocrine proliferative loop. Therefore, IGF-II signaling via the IR-A could mediate resistance to type 1 IGF receptor (IGF-IR) inhibitory drugs that are currently in development. This study addressed the role of the IR-A, using a small interfering RNA-based approach in SW480 human colon adenocarcinoma cells that coexpress the IGF-IR. Clonogenic survival was inhibited by depletion of the IGF-IR but not the IR-A, and dual receptor depletion had no greater effect than IGF-IR knockdown alone, suggesting that the IR-A could not compensate for IGF-IR loss. IGF-IR knockdown also resulted in a decrease in viability, whereas IR-A depletion resulted in increased viability. Consistent with this, upon IR-A depletion, we found a concomitant enhancement of IGF-IR activation by IGF-I and IGF-II, reduced formation of IGF-IR:IR-A hybrid receptors and increased IGF-IR homodimer formation. Together, these results suggest that IGF bioactivity is mediated more effectively by the IGF-IR than by the IR-A or receptor hybrids and that signaling via the IGF-IR is dominant to the IR-A in colon cancer cells that express both receptors.