MR Imaging Characteristics Associate with Tumor-Associated Macrophages in Glioblastoma and Provide an Improved Signature for Survival Prognostication.

BACKGROUND AND PURPOSE: In glioblastoma, tumor-associated macrophages have tumor-promoting properties. This study determined whether routine MR imaging features could predict molecular subtypes of glioblastoma that differ in the content of tumor-associated macrophages. MATERIALS AND METHODS: Seven internally derived MR imaging features were assessed in 180 patients, and 25 features from the Visually AcceSAble Rembrandt Images feature set were assessed in 164 patients. Glioblastomas were divided into subtypes based on the telomere maintenance mechanism: alternative lengthening of telomeres positive (ALT+) and negative (ALT-) and the content of tumor-associated macrophages (with [M+] or without [M-] a high content of macrophages). The 3 most frequent subtypes (ALT+/M-, ALT-/M+, and ALT-/M-) were correlated with MR imaging features and clinical parameters. The fourth group (ALT+/M+) did not have enough cases for correlation with MR imaging features. RESULTS: Tumors with a regular margin and those lacking a fungating margin, an expansive T1/FLAIR ratio, and reduced ependymal extension were more frequent in the subgroup of ALT+/M- (P < .05). Radiologic necrosis, lack of cystic component (by both criteria), and extensive peritumoral edema were more frequent in ALT-/M+ tumors (P < .05). Multivariate testing with a Cox regression analysis found the cystic imaging feature was additive to tumor subtype, and O6-methylguanine methyltransferase (MGMT) status to predict improved patient survival (P < .05). CONCLUSIONS: Glioblastomas with tumor-associated macrophages are associated with routine MR imaging features consistent with these tumors being more aggressive. Inclusion of cystic change with molecular subtypes and MGMT status provided a better estimate of survival.

Δ122p53, a mouse model of Δ133p53α, enhances the tumor-suppressor activities of an attenuated p53 mutant.

Growing evidence suggests the Δ133p53α isoform may function as an oncogene. It is overexpressed in many tumors, stimulates pathways involved in tumor progression, and inhibits some activities of wild-type p53, including transactivation and apoptosis. We hypothesized that Δ133p53α would have an even more profound effect on p53 variants with weaker tumor-suppressor capability. We tested this using a mouse model heterozygous for a Δ133p53α-like isoform (Δ122p53) and a p53 mutant with weak tumor-suppressor function (mΔpro). The Δ122p53/mΔpro mice showed a unique survival curve with a wide range of survival times (92-495 days) which was much greater than mΔpro/- mice (range 120-250 days) and mice heterozygous for the Δ122p53 and p53 null alleles (Δ122p53/-, range 78-150 days), suggesting Δ122p53 increased the tumor-suppressor activity of mΔpro. Moreover, some of the mice that survived longest only developed benign tumors. In vitro analyses to investigate why some Δ122p53/mΔpro mice were protected from aggressive tumors revealed that Δ122p53 stabilized mΔpro and prolonged the response to DNA damage. Similar effects of Δ122p53 and Δ133p53α were observed on wild-type of full-length p53, but these did not result in improved biological responses. The data suggest that Δ122p53 (and Δ133p53α) could offer some protection against tumors by enhancing the p53 response to stress.

Activation of p53 following ionizing radiation, but not other stressors, is dependent on the proline-rich domain (PRD).

The tumor suppressor protein, p53 is one of the most important cellular defences against malignant transformation. In response to cellular stressors p53 can induce apoptosis, cell cycle arrest or senescence as well as aid in DNA repair. Which p53 function is required for tumor suppression is unclear. The proline-rich domain (PRD) of p53 (residues 58-101) has been reported to be essential for the induction of apoptosis. To determine the importance of the PRD in tumor suppression in vivo we previously generated a mouse containing a 33-amino-acid deletion (residues 55-88) in p53 (mΔpro). We showed that mΔpro mice are protected from T-cell tumors but not late-onset B-cell tumors. Here, we characterize the functionality of the PRD and show that it is important for mediating the p53 response to DNA damage induced by γ-radiation, but not the p53-mediated responses to Ha-Ras expression or oxidative stress. We conclude that the PRD is important for receiving incoming activating signals. Failure of PRD mutants to respond to the activating signaling produced by DNA damage leads to impaired downstream signaling, accumulation of mutations, which potentially leads to late-onset tumors.

p53-mediated apoptosis prevents the accumulation of progenitor B cells and B-cell tumors.

We propose that the apoptotic function of p53 has an important role in B-cell homeostasis, which is important for the prevention of B-cell lymphomas. We created a mouse model (mDeltapro) that lacked residues 58-88 of the proline-rich domain of p53. mDeltapro is defective for apoptosis, but is able to arrest cell-cycle progression in hematopoietic tissues. mDeltapro develops late-onset B-cell lymphoma, but not the thymic T-cell tumors found in p53-null mice. Interestingly, mDeltapro lymphomas comprised incorrectly differentiated B cells. B-cell irregularities were also detected in mDeltapro before tumor onset, in which aged mice showed an increased population of inappropriately differentiated B cells in the bone marrow and spleen. We predict that by keeping B-cell populations in check, p53-dependent apoptosis prevents irregular B cells from eventuating in lymphomas.

Novel rare mutations and promoter haplotypes in ABCA1 contribute to low-HDL-C levels.

The ATP-binding cassette A1 (ABCA1) protein regulates plasma high-density lipoprotein (HDL) levels. Mutations in ABCA1 can cause HDL deficiency and increase the risk of premature coronary artery disease. Single nucleotide polymorphisms (SNPs) in ABCA1 are associated with variation in plasma HDL levels. We investigated the prevalence of mutations and common SNPs in ABCA1 in 154 low-HDL individuals and 102 high-HDL individuals. Mutations were identified in five of the low-HDL subjects, three having novel variants (I659V, R2004K, and A2028V) and two with a previously identified variant (R1068H). Analysis of four SNPs in the ABCA1 gene promoter (C-564T, G-407C, G-278C, and C-14T) identified the C-14T SNP and the TCCT haplotype to be over-represented in low-HDL individuals. The R1587K SNP was over-represented in low-HDL individuals, and the V825I and I883M SNPs over-represented in high-HDL individuals. We conclude that sequence variation in ABCA1 contributes significantly to variation in HDL levels.