Expression and functional role of the Id HLH family in cultured astrocytes

The Id family of helix-loop-helix factors (Id1, Id2, and Id3) expressed in many types of cells has been reported to negatively regulate myoblast differentiation and is required for G1/S progression of arrested fibroblasts. Our previous studies have indicated that Id1, Id2, and Id3 mRNA expression appear in the subventricular zone of 1-day-old rat brains. At later ages, Id3 mRNA was only expressed in astrocytes. We now report that Id1 and Id3 mRNA expression increased in astrocytes during the first hour of serum stimulation. Subsequently, the Id1 and Id3 mRNA levels gradually declined to basal level as observed in cultures without serum stimulation. However, there was no significant difference in Id2 mRNA expression between serum-treated and control astrocyte cultures within 1 h of serum induction. In addition, a strong nuclear immunostaining for Id2 and Id3 proteins was observed 24 h after serum stimulation. This observation is consistent with our results that show an increase in Id2 and Id3 protein levels following 24 h serum induction. Furthermore, DNA synthesis in FCS-stimulated astrocytes was blocked by antisense oligonucleotides against Id3 mRNA. The addition of Id3 antisense oligonucleotides caused approximately 50% reduction in Id3 mRNA and protein levels when compared to that in sense-treated cultures. The results indicate that the inhibition of DNA synthesis in FCS-stimulated astrocytes is due to a decrease in Id3 levels by the antisense. These observations suggest that Id3 may play an important role in the regulation of astrocyte proliferation.     

Growth inhibition of human pancreatic cancer cell lines by anti-sense oligonucleotides specific to mutated K-ras genes

About 90% of human pancreatic cancers carry K-ras point mutation, which may play an important role in tumorigenesis. We investigated the inhibitory effects of anti-sense oligonucleotides targeting K-ras point mutation on the growth of cultured human pancreatic cancer cells. Eight human pancreatic cancer cell lines were screened for K-ras codon 12 point mutations by PCR-RFLP analysis and direct sequencing. Then, 3 cell lines with the major types of K-ras point mutation, i.e.,HuP-T1, HuP-T3 and PANC-1, and 1 without mutation, BxPC-3, were used for the experiments. Seventeen mer anti-sense oligonucleotides were designed, targeting the point mutation of K-ras codon 12, and transfected into the cells by the liposome-mediated method. Cell-growth activities were estimated by MTT assay. Levels of K-ras mRNA expression were determined using quantitative RT-PCR, and K-ras p21 protein synthesis was evaluated with Western blotting. Mutation-matched anti-sense oligonucleotides effectively inhibited the growth of these pancreatic cancer cell lines, except for BxPC-3, by suppressing K-ras mRNA expression and K-ras p21 protein synthesis. Moreover, mutation-matched anti-sense oligonucleotides showed stronger anti-proliferative effects than did mutation-mismatched ones. Our results suggest that anti-sense therapy specific to point mutations of K-ras mRNA is a practical approach to selective suppression of tumor growth, with little effect on normal cells.     

Id1, Id2, and Id3 gene expression in neural cells during development

Id1, Id2, and Id3 mRNA are expressed mainly in the proliferating ependymal cell zone of the mouse brain during embryogenesis. In this study, the expression pattern and cell phenotypes of the Id family mRNA were examined in postnatal and adult rat brain. The expression of Idl and Id3 mRNA in rat brain was observed in the cortex layer 1, corpus callosum, ventricular/subventricular zone (VZ/ SVZ), and the CA1-4 layers of the hippocampus at postnatal day 1 (P1) through P14, whereby it declined at 2 months. In general, the developmental pattern of Idl mRNA coincided with the pattern observed for Id3 mRNA. Similar to Id1 and Id3, Id2 mRNA was highly expressed in the corpus callosum, VZ/SVZ, and the hippocampus. Examination of Id2 mRNA revealed high levels in the cortex and caudate putamen at P1 through P14, whereas a decline was observed in its expression in the adult cortex. In P5 rat cerebellum, all Id mRNA examined were found in the internal granular cell layers; however, at this time point, only Id2 mRNA expression was detected in the differentiating zone of the external granular cell layers, preferentially localizing to adult Purkinje cells. Furthermore, only Id2 mRNA expression in brain was observed in NF+ neurons at P5. Examination of S100alpha+ and GFAP+ astrocytes, revealed the presence of all three mRNAs, whereas the expression of Id2 and Id3 mRNA was absent in 04+ immature oligodendrocytes. These data suggest that the spatial and temporal kinetic patterns during development, as well as cellular specificity, of the Id gene family may play a critical role in neural precursor cell proliferation and cell divergence.     

Aberrant expression of type I fibroblast growth factor receptor in human pancreatic adenocarcinomas

Acidic and basic fibroblast growth factors are mitogenic polypeptides that are overexpressed in pancreatic cancer. To determine whether fibroblast growth factors may exert direct effects on pancreatic cancer cells in vivo, we compared the expression of the high-affinity type I fibroblast growth factor receptor (FGFR-1) in human pancreatic tissues. In the normal pancreas, FGFR-1 immunostaining was seen mainly in acinar cells. In pancreatic cancers, FGFR-1 was abundant in ductal-like cancer cells which also exhibited many FGFR-1 mRNA in situ hybridization grains. Analysis by the polymerase chain reaction and RNase protection revealed that the 2-immunoglobulin-like and the 3-immunoglobulin-like forms of FGFR-1 were expressed in all tissue samples, and that the 2-immunoglobulin-like form was overexpressed in the cancer tissues by comparison with the normal tissues. These findings suggest that the 2-immunoglobulin-like form of FGFR-1 may contribute to aberrant autocrine and paracrine pathways in pancreatic cancer.     

CaSm: an Sm-like protein that contributes to the transformed state in cancer cells

A novel gene encoding a protein containing Sm motif-like domains was found to have elevated expression in pancreatic cancer and in several cancer-derived cell lines. CaSm (for Cancer-associated Sm-like) mRNA is up-regulated in 87.5% (seven of eight) of pancreatic tumor/normal pairs. Similarly, cell lines from cancers originating in liver, ovary, lung, and kidney show increased CaSm expression compared to their normal tissue cognates. CaSm encodes a 133-amino acid open reading frame that contains the two Sm motifs found in the common snRNP proteins, with the greatest homology to the Sm G protein (60% similarity). Two hypothetical proteins from Caenorhabditis elegans and Saccharomyces cerevisiae share even greater similarity (72.8 and 67.7%, respectively), suggesting a broad family of proteins containing Sm motifs. Antisense CaSm RNA is able to alter the transformed phenotype of pancreatic cancer cells by reducing their ability to form large colonies in soft agar when compared to untransfected cells. Therefore, CaSm expression appears to be necessary for maintenance of the transformed state.