Highlights d scRNA-seq analyses highlight conserved myeloid subsets in human and murine CRC d Two distinct TAM subsets show inflammatory and angiogenic signatures, respectively d Two distinct TAM subsets show differential sensitivity to CSF1R blockade d Anti-CD40 activates specific cDC1s and expands Th1-like and CD8 + memory T cells
Wilms' tumor (WT) has been considered a prototype for arrested cellular differentiation in cancer, but previous studies have relied on selected markers. We have now performed an unbiased survey of gene expression in WTs using oligonucleotide microarrays. Statistical criteria identified 357 genes as differentially expressed between WTs and fetal kidneys. This set contained 124 matches to genes on a microarray used by Stuart and colleagues (Stuart RO, Bush KT, Nigam SK: Changes in global gene expression patterns during development and maturation of the rat kidney. Proc Natl Acad Sci USA 2001, 98:5649-5654) to establish genes with stage-specific expression in the developing rat kidney. Mapping between the two data sets showed that WTs systematically overexpressed genes corresponding to the earliest stage of metanephric development, and underexpressed genes corresponding to later stages. Automated clustering identified a smaller group of 27 genes that were highly expressed in WTs compared to fetal kidney and heterologous tumor and normal tissues. This signature set was enriched in genes encoding transcription factors. Four of these, PAX2, EYA1, HBF2, and HOXA11, are essential for cell survival and proliferation in early metanephric development, whereas others, including SIX1, MOX1, and SALL2, are predicted to act at this stage. SIX1 and SALL2 proteins were expressed in the condensing mesenchyme in normal human fetal kidneys, but were absent (SIX1) or reduced (SALL2) in cells at other developmental stages. These data imply that the blastema in WTs has progressed to the committed stage in the mesenchymal-epithelial transition, where it is partially arrested in differentiation. The WT-signature set also contained the Wnt receptor FZD7, the tumor antigen PRAME, the imprinted gene NNAT and the metastasis-associated transcription factor E1AF.
Wnts are secreted signaling proteins able to control diverse biological processes such as cell differentiation and proliferation. Many Wnts act through a canonical, beta-catenin signaling pathway. Here, we report that Wnt receptors and transcriptional effectors are expressed in primary human endothelial cells and that Wnt/beta-catenin signaling promotes angiogenesis. Human umbilical vein and microvascular endothelial cells express Wnt receptors, Frizzled-4, -5, -6, and beta-catenin-associated transcription factors, Tcf-1, -3, -4 and Lef-1. In endothelial cells, ectopic expression of Wnt-1 stabilized cytosolic beta-catenin, demonstrating activation of the Wnt/beta-catenin canonical signaling pathway. Expression of Wnt-1 or a stabilized and active form of beta-catenin, beta-cateninS37A, promoted endothelial cell proliferation. Proliferation induced by Wnt/beta-catenin signaling was optimal in the presence of bFGF. beta-cateninS37A expression in endothelial cells promoted survival after growth factor deprivation. Using matrigel assays, Wnt-1 or beta-cateninS37A expression promoted the formation of capillary-like networks. To help define the effectors of Wnt angiogenic function, microarray analysis was used to compare endothelial cells expressing Wnt-1 to control cells. Interleukin-8, a known angiogenic factor, was identified as a transcriptional target of Wnt/beta-catenin signaling in endothelial cells. Expression of either Wnt-1 or beta-cateninS37A induced Interleukin-8 transcripts and secreted protein. We thus conclude that Wnt/beta-catenin signaling promotes angiogenesis possibly via the induction of known angiogenic regulators such as Interleukin-8.
The Ipl (Tssc3) gene lies in an extended imprinted region of distal mouse chromosome 7, which also contains the Igf2 gene. Expression of Ipl is highest in placenta and yolk sac, where its mRNA is derived almost entirely from the maternal allele. Ipl encodes a small cytoplasmic protein with a pleckstrin-homology (PH) domain. We constructed two lines of mice with germ-line deletions of this gene (Ipl neo and Ipl loxP ) and another line deleted for the similar but nonimprinted gene Tih1. All three lines were viable. There was consistent overgrowth of the Ipl-null placentas, with expansion of the spongiotrophoblast. These larger placentas did not confer a fetal growth advantage; fetal size was normal in Ipl nulls with the Ipl neo allele and was decreased slightly in nulls with the Ipl loxP allele. When bred into an Igf2 mutant background, the Ipl deletion partially rescued the placental but not fetal growth deficiency. Neither fetal nor placental growth was affected by deletion of Tih1. These results show a nonredundant function for Ipl in restraining placental growth. The data further indicate that Ipl can act, at least in part, independently of insulin-like growth factor-2 signaling. Thus, genomic imprinting regulates multiple pathways to control placental size. The Ipl gene, also known as Tssc3, lies on distal chromosome 7 of the mouse and human chromosome 11p15.5 (1, 2). This region contains multiple imprinted genes clustered in 1 Mb of DNA. Two of these, p57 Kip2 (Cdkn1c) and Igf2, control fetal and placental growth in mice (3-7) and humans (8). Similar to these genes, Ipl is highly expressed in the extraembryonic tissues (1), but in contrast to these genes, Ipl is expressed only weakly in the embryo proper (1, 9). Ipl encodes a cytoplasmic protein with a pleckstrin-homology (PH) domain (9), thus by analogy with other PH-domain proteins it may modulate cell signaling, intracellular trafficking, or other processes that depend on phosphatidylinositol lipid second messengers. Ipl has two close relatives: TDAG51 and Tih1. Of these genes, Tih1 is most similar to Ipl (9). Tih1 is located in a nonimprinted region of mouse chromosome 1, and it is expressed biallelically (9). To determine the function of Ipl and to accumulate data relevant to the biological rationale for imprinting, we created mice with germ-line deletions of Ipl and Tih1. Materials and MethodsGene Deletions, Genotyping, and Gene Expression. To make the Ipl neo targeting vector, a 5-kb 5Ј genomic NotI restriction fragment and a 6-kb 3Ј EcoRI͞XbaI fragment flanking Ipl were ligated upstream and downstream of Pgk-Neo in pPNT1, yielding pPNT-Ipl. To make the Ipl loxP targeting vector, the Pgk-Neo cassette of pPNT-⌬Ipl was replaced by that from pLNL, which includes flanking loxP sites. To verify homologous recombination, we used genomic PCR products upstream and downstream of the 5Ј and 3Ј cassettes. Recombination of the loxP sites was induced by crossing to HSP-Cre transgenic mice (10). The Ipl deletions (encompassing nucleotides 77,444-78,990 of GenBank a...
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