Distribution of Ankyrin Isoforms and Their Proteolysis After Ischemia and Reperfusion in Rat Brain

Abstract: The distribution of brain-type ankyrin (ankyrin_B, 212 kDa) and erythrocyte-type ankyrin (ankyrin_R, 239 kDa) was investigated in the subcellular fractions of rat forebrain (P1, 1,000 g pellet; P2, 15,000 g pellet; P3, 100,000 g pellet; S, 100,000 g supernatant) by immunoblotting using specific antibodies. The P2 fraction contained ∼40% of the 212- and 163-kDa isoforms of ankyrin_B and the 239-kDa isoform of ankyrin_R. Further subfractionation of the P2 by Percoll gradient centrifugation followed by separation of myelin showed association of the three ankyrin isoforms with the synaptosome-rich fraction but not with the myelin-rich fraction. The plasma membrane-rich P3 fraction contained a concentration of ankyrin isoforms similar to that in the P2 fraction. In vitro proteolysis of ankyrin in the P2 fraction with calpain showed that the 212-kDa ankyrin_B was more susceptible to calpain than was ankyrin_R. In the two-vessel occlusion model, ischemia for 30 min generated the 160-kDa fragment of ankyrin_R, and reperfusion for 60 min after 30 min of ischemia remarkably increased the 160-kDa fragment. The reperfusion also significantly decreased the 212-kDa isoform of ankyrin_B. Both ischemia-reperfusion and in vitro proteolysis with calpain generated the 160-kDa fragment of ankyrin_R, suggesting the involvement of calpain.     

GPI1 stabilizes an enzyme essential in the first step of glycosylphosphatidylinositol biosynthesis.

Attachment of glycosylphosphatidylinositol (GPI) is essential for the surface expression of many proteins. Biosynthesis of glycosylphosphatidylinositol is initiated by the transfer of N-acetylglucosamine from UDP-N-acetylglucosamine to phosphatidylinositol. In mammalian cells, this reaction is mediated by a complex of PIG-A, PIG-H, PIG-C, and GPI1. This complexity may be relevant for regulation and for usage of a particular phosphatidylinositol. However, the functions of the respective components have been unclear. Here we cloned the mouse GPI1 gene and disrupted it in F9 embryonal carcinoma cells. Disruption of the GPI1 gene caused a severe but not complete defect in the generation of glycosylphosphatidylinositol-anchored proteins, indicating some residual biosynthetic activity. A complex of PIG-A, PIG-H, and PIG-C decreased to a nearly undetectable level, whereas a complex of PIG-A and PIG-H was easily detected. A lack of GPI1 also caused partial decreases of PIG-C and PIG-H. Therefore, GPI1 stabilizes the enzyme by tying up PIG-C with a complex of PIG-A and PIG-H.     

Prospectively Isolated Cancer-Associated CD10+ Fibroblasts Have Stronger Interactions with CD133+ Colon Cancer Cells than with CD133? Cancer Cells

Although CD133 has been reported to be a promising colon cancer stem cell marker, the biological functions of CD133⁺ colon cancer cells remain controversial. In the present study, we investigated the biological differences between CD133⁺ and CD133⁻ colon cancer cells, with a particular focus on their interactions with cancer-associated fibroblasts, especially CD10⁺ fibroblasts. We used 19 primary colon cancer tissues, 30 primary cultures of fibroblasts derived from colon cancer tissues and 6 colon cancer cell lines. We isolated CD133⁺ and CD133⁻ subpopulations from the colon cancer tissues and cultured cells. In vitro analyses revealed that the two populations showed similar biological behaviors in their proliferation and chemosensitivity. In vivo analyses revealed that CD133⁺ cells showed significantly greater tumor growth than CD133⁻ cells (P = 0.007). Moreover, in cocultures with primary fibroblasts derived from colon cancer tissues, CD133⁺ cells exhibited significantly more invasive behaviors than CD133⁻ cells (P<0.001), especially in cocultures with CD10⁺ fibroblasts (P<0.0001). Further in vivo analyses revealed that CD10⁺ fibroblasts enhanced the tumor growth of CD133⁺ cells significantly more than CD10⁻ fibroblasts (P<0.05). These data demonstrate that the in vitro invasive properties and in vivo tumor growth of CD133⁺ colon cancer cells are enhanced in the presence of specific cancer-associated fibroblasts, CD10⁺ fibroblasts, suggesting that the interactions between these specific cell populations have important roles in cancer progression. Therefore, these specific interactions may be promising targets for new colon cancer therapies.     

Oxidative degradation of thymine with O2 promoted by L-ascorbic acid and Cu(II) ion

Oxidation of thymine with O2 was promoted by copper(I) ion generated from reaction of L-ascorbic acid (AA) with copper (II) ion. The main oxidation products were thymine glycol (TG) and N-formyl-N'-pyruvylurea (FPU). At higher concentration of O2, formation of FPU was favored, while TG was dominant at higher Cu(II) ion and lower O2 concentrations. Reaction mechanism involving hydroxy thyminyl radical was proposed.     

A second Warburg-like effect in cancer metabolism: The metabolic shift of glutamine-derived nitrogen

Carbon and nitrogen are essential elements for life. Glucose as a carbon source and glutamine as a nitrogen source are important nutrients for cell proliferation. About 100 years ago, it was discovered that cancer cells that have acquired unlimited proliferative capacity and undergone malignant evolution in their host manifest a cancer-specific remodeling of glucose metabolism (the Warburg effect). Only recently, however, was it shown that the metabolism of glutamine-derived nitrogen is substantially shifted from glutaminolysis to nucleotide biosynthesis during malignant progression of cancer—which might be referred to as a “second” Warburg effect. In this review, address the mechanism and relevance of this metabolic shift of glutamine-derived nitrogen in human cancer. We also examine the clinical potential of anticancer therapies that modulate the metabolic pathways of glutamine-derived nitrogen. This shift may be as important as the shift in carbon metabolism, which has long been known as the Warburg effect.     

The possible existence of a heat-stable alkaline proteinase (HAP) in rat skeletal muscle

1. A unique caseinolytic activity was found in the crude extract from chicken and rat skeletal muscle. Hardly any activity was detected at physiological assay temperatures at pH 8.0 but did well at around 60 degrees C. 2. The activity partially purified from rat skeletal muscle showed optimum pH at around 8.0 at 60 degrees C. It hardly hydrolyzed casein below 50 degrees C, but in the presence of 5 M urea it showed relatively high activity at 30 degrees C. The activity was completely stable at 50 degrees C for 1 hr. 3. The activity seems to be contained in a high mol. wt (450,000) protein from the elution volume and is due to cysteine proteinase from the effect of inhibitors. 4. The above properties agreed with those of the heat-stable alkaline proteinase (HAP) of fish purified homogeneously by electrophoresis. This seems to suggest that HAP may also exist in rat skeletal muscle.