Masanori Narahara

Sox6 overexpression causes cellular aggregation and the neuronal differentiation of P19 embryonic carcinoma cells in the absence of retinoic acid

The Sox6 gene is a member of the Sox gene family that encodes transcription factors. Previous studies have suggested that Sox6 plays an important role in the development of the central nervous system. Aggregation of embryonic carcinoma P19 cells with retinoic acid (RA) results in the development of neurons, glia and fibroblast‐like cells. In this report, we have shown that Sox6 mRNA increased rapidly in P19 cells during RA induction and then decreased during the differentiation of P19 into neuronal cells. To explore the possible roles of Sox6 during this process, stably Sox6‐overexpressing P19 cell lines (P19[Sox6]) were established. These P19[Sox6] had acquired both characteristics of the wild‐type P19 induced by RA. First, P19[Sox6] cells showed a marked cellular aggregation in the absence of RA. Second, P19[Sox6] could differentiate into microtubule‐associated protein 2 (MAP2)‐expressing neuronal cells in the absence of RA. Sox6 expression could cause the activation of endogenous genes including the neuronal transcription factor Mash‐1, the neuronal development‐related gene Wnt‐1, the neuron‐specific cell adhesion molecule N‐cadherin, and the neuron‐specific protein MAP2, resulting in neurogenesis. Moreover, E‐cadherin, a major cell adhesion molecule of wild‐type P19, was strongly induced by Sox6, resulting in cellular aggregation without RA. Thus Sox6 may play a critical role in cellular aggregation and neuronal differentiation of P19 cells.

Suppression of Sox6 in P19 cells leads to failure of neuronal differentiation by retinoic acid and induces retinoic acid-dependent apoptosis.

The Sox6 gene is a member of the Sox gene family, which encodes transcription factors, and previous studies have suggested that it plays an important role in the development of the central nervous system. Aggregation of embryonic carcinoma P19 cells with retinoic acid (RA) results in the development of neurons, glia, and fibroblast‐like cells. Sox6 mRNA increases rapidly in P19 cells during RA induction and then decreases during differentiation into neuronal cells. To investigate whether Sox6 expression is essential for neuronal differentiation, we established Sox6‐suppressed P19 (P19[anti‐Sox6]) cells by transfection of antisense‐Sox6 cDNA. Most of the P19[anti‐Sox6] cells showed no neurites and were not stained by the anti‐MAP 2 antibody, while the suppression of Sox6 expression nearly totally blocked neuronal differentiation in P19 cells. Further, Sox6 suppression caused RA‐dependent apoptosis by P19[anti‐Sox6] cells: RA‐treated P19[anti‐Sox6] cells showed chromatin condensation, DNA fragmentation, and an increase in caspase‐3‐like activity. Thus, Sox6 is considered essential for neuronal differentiation and may play an important role in the early stages of neuronal differentiation or apoptosis.

Expression of kininogen mRNAs and plasma kallikrein mRNA by cultured neurons, astrocytes and meningeal cells in the rat brain

Expression of kininogen mRNAs has been studied in cultures of three different types of cells in rat brain, including neurons and astrocytes from cerebral cortex and meningeal cells from the leptomeninges/choroid plexus. T-kininogen mRNA was expressed by meningeal cells, but not by neurons and astrocytes, and the expression in meningeal cells was enhanced by culture with prostaglandin E2 (PGE2) or dibutyryl cAMP (Bt2cAMP). Low-molecular-weight kininogen mRNA was not detected in these cultures of cells, even after treatment with PGE2. Although expression of high-molecular-weight kininogen mRNA was very low in these cultures of cells, PGE2 or Bt2cAMP markedly stimulated its expression in cultures of meningeal cells and slightly in neurons, but not in astrocytes. We also found that expression of plasma kallikrein mRNA was strong in cultures of meningeal cells and slight in astrocytes, but absent in neurons. These results suggest that cells in the leptomeninges/choroid plexus are major sources of kininogens in rat brain which may function as precursor proteins for kinins and/or potent cysteine proteinase inhibitors during cerebral inflammation.

DETECTION OF BIKUNIN MRNA IN LIMITED PORTIONS OF RAT BRAIN

Tissue distribution of bikunin mRNA, which encodes a Kunitz-type serine protease inhibitor of the inter-alpha-inhibitor family (IalphaI), was studied in rats and mice by the reverse-transcripsion polymerase chain reaction (RT-PCR). We found that the liver as well as other tissues, such as the kidney, testis and adrenal gland, expressed bikunin mRNA. Although signals of bikunin mRNA were faint in the whole brain of rats and mice, distinct signals were found in limited portions of rat brain, such as the hippocampus, cerebral cortex and pituitary, but undetectable in cerebellum, medulla oblongata, hypothalamus, striatum, midbrain and choroid plexus. In three distinct types of cells, such as neurons, astrocytes and meningeal cells, in primary cultures isolated from the cerebral cortex and meninges of 1-day-old newborn rats, only neurons positively expressed bikunin mRNA. These results suggest that, in addition to peripheral tissues, neurons in the hippocampus and cerebral cortex produce bikunin, suggesting a potential role of bikunin/IalphaI family in these brain regions.

Presence of β-citryl-L-glutamic acid in the lens : its possible role in the differentiation of lens epithelial cells into fiber cells

The beta-CG concentration in the chicken brain was high during embryonic development and decreased rapidly to a lower level close to hatching, while the concentration in the eyeball which was also high during the embryonic life retained a fairly high level after hatching. The distribution of beta-CG in the bovine eye was determined. About 95% of total beta-CG content in the whole eye was localized in the lens. However, the distribution of beta-CG in the eye varied depending on species. beta-CG was exclusively localized in the lens in the eyes of fish and mammals, but distributed in both lens and retina in frogs. The molecule was localized in the retina rather than the lens in the chicken eye, although the concentrations was extremely low compared to those in the mammalian, amphibian and fish eyes. It was found that beta-CG is present ubiquitously in the lens or retina in various species. The distribution of beta-CG in the bovine lens was determined in the three cortex regions and nucleus. beta-CG was present at the highest concentration in the equatorial cortex, at a moderate concentration in the posterior and anterior cortex, and at the lowest concentration in the nucleus. Similar distribution patterns were also found in the rabbit and rat lens. When embryonic chick lens epithelial cells were cultured in the presence of fetal calf serum, the cells elongated, differentiated into fiber cells and formed lentoid bodies. The cells of lentoid bodies were stained strongly by the anti-beta-CG antibody, while cells around the structures were not. In addition, the beta-CG content in the lenses from the galactose cataractous rat decreased to about 20-30% of that in the normal lens. These findings suggest that beta-CG may play a role in the differentiation of epithelial cells into fiber cells.

Purification and properties of ß-citryl-l-glutamate-hydrolysing enzyme from rat testis particulate

beta-Citryl-L-glutamate-hydrolysing enzyme (beta-CGHE) was purified from rat testis particulate fraction 13,000-fold, at a yield of 7%. The enzyme was purified by ammonium sulfate fractionation, hydroxyapatite, chelating Sepharose, beta-CG-Sepharose affinity chromatography and Sephacryl S-300 gel filtration. The purified enzyme usually migrated as two periodic acid Schiffs-stained bands on native polyacrylamide gel-electrophoresis (PAGE) with molecular weights of 350 and 420 kDa. Both bands hydrolyzed beta-citryl-L-glutamate (beta-CG) to citrate and glutamate. The 420 kDa band was changed by digestion with N-glycosidase F, into a 350 kDa band on native PAGE. The purified enzyme was composed of 90, 100, 115 and 130 kDa subunits on SDS-PAGE under non-reduced conditions. The purified enzyme was pharmacologically similar to the beta-CGHE activity partially purified from rat testis. This enzyme required manganese ions for full activity and it was strongly inhibited by nucleotides such as ATP or GTP and phosphate ions. beta-CGHE was also potently inhibited by an excitatory amino acid agonist, L-quisqualate, but not by another agonists, N-methyl-D-aspartate and kinate. It had high substrate specificity for beta-CG. The antibodies against the purified enzyme reacted mainly to the 115 kDa band on the SDS-PAGE and precipitated the enzyme activity from the crude and purified enzyme solution.