DNA synthesis in the embryonic chick central nervous system

Summary DNA synthesis has been studied in chick embryos age between 2 and 10 days, using labelling with tritiated thymidine and stripping film autoradiography. The observations made earlier in the literature on a premitotic migration of the nuclei in the neural epithelium have been verified. In young stages (before day 7) peripherally migrated cells do not synthesize DNA, but after day 7 such a synthesis occurs. In spite of this, few mitoses are seen. The interpretation of these facts is discussed.The costs of this investigation were defrayed by grants from the Swedish Medical Research Council, the Medical Faculty of Lund, and the Royal Physiographic Society.     

Preparation of two neurotoxic esterases from the chick central nervous system

• 1.1. A standard procedure for lipid-extraction of lyophilized hen brain material is decribed.
• 2.2. Nine carboxylesterase isoenzymes (EC 3.1.1.1) are identified in lipid-extracted lyophilized material (LELM) using kinetic analysis of organophosphate inhibition. Total phenyl valerate (PV) hydrolysing carboxylesterase activity in LELM is 43.3U.g⁻¹
• 3.3. Two carboxylesterase isoenzymes of LELM are classified as neurotoxic esterases (NTE_A and NTEg_B).
• 4.4. Using n-octylglucoside 51% of the water-insoluble neurotoxic esterase activity from LELM are solubilized.
• 5.5. Six carboxylesterase isoenzymes including NTE_A (6.5 U-l⁻¹) and NTE_B (4.2 U-l⁻¹) are present in the solubilized preparation.
• 6.6. Throughout purification and separation steps carboxylesterase isoenzymes are identified by their rate constants for the reaction with organophosphorus inhibitors.

     

Glutaminase activity in the chick central nervous system during postnatal growth.

1. Glutaminase activity was evaluated in the chick cerebral hemispheres, optic lobes and cerebellum between the 1st and 30th day of postnatal growth. 2. Glutaminase activity is higher in the cerebral hemispheres than in the optic lobes and is lowest in the cerebellum. 3. It seems to be inversely related to the magnitude of the variations of glutamine concentration in the three areas. 4. No direct relation exists between enzyme activity and glutamate concentration in the three tissues.     

Glutamic acid decarboxylase in different areas of the developing chick central nervous system

The temporal course of the development of GAD activity in GABAergic neurons was studied in the chick retina, optic lobe and cerebellum. The developmental pattern of GAD activity was similar in the three areas studied, showing typical sigmoideal curves, which reached a maximal value at the 3^rd post-hatching day. Kinetic studies during development revealed that K_m remained unchanged while V_max increased 3-fold in the retina (48.99±0.84 nmol/hr/mg protein), almost 4-fold in the optic lobe (162.77±4.32 nmol/hr/mg protein) and 3.5 fold in the cerebellum (69.30±1.26 nmol/hr/mg protein). The developmental pattern of GAD activity in homogenates of the three areas studied from dark-reared and light-reared chicks with respect to normal light-dark cycle animals showed no significant differences. These results indicate that the increase in GAD activity during development are not due to a change in the affinity for its substrate but rather to changes in the concentration of the enzyme. The developmental pattern of GAD activity in the chick visual system was not affected by environmental conditions suggesting that the developmental profile is lightindependent.     

Extensive proliferation of oligodendrocyte precursors in the parenchyma of the embryonic chick central nervous system

The proliferation of oligodendrocyte lineage cells in the chick embryo central nervous system (CNS) was examined by double-immunolabeling with a lineage marker monoclonal antibody (mAb) O4 or mAb O1 and 5-bromo-3'-deoxyuridine (BrdU). In all regions examined, the first O4-positive (O4+) cells appeared in restricted regions of the ventricular zone (VZ), regarded as a site of oligodendrocyte origin. Within the O4+ focus, less than 20% of the O4+ cells incorporated BrdU. In contrast, O4+ cells in the parenchyma were mitotically active; for example, 40-50% of early O4+ cells were labeled with BrdU. Some of these were unipolar in shape, indicative of migratory precursor cells. The frequency of O4+/BrdU+ cell appearance decreased to less than 20% with further development. O1+ oligodendrocytes were largely mitotically inactive, with only approximately 5% of O1+ cells incorporating BrdU. These results clearly demonstrated that the VZ generates relatively few precursor cells and that these oligodendrocyte precursors actively generate their cohort in the parenchyma of the CNS.     

Identification of chick frizzled-10 expressed in the developing limb and the central nervous system

We have identified chick frizzled (Fz)-10, encoding a Wnt receptor, and examined the expression pattern during embryogenesis. Fz-10 is expressed in the region posterior to the Hensen's node at stage 6. Fz-10 expression is detected in the dorsal domain of the neural tube and the central nervous system of the developing embryo. In the developing limb, Fz-10 expression starts at stage 18 in the posterior-dorsal region of the distal mesenchyme, and gradually expands to the anterior-distal region. Fz-10 is also expressed in the feather bud and branchial arch. Implantation of Sonic hedgehog (Shh)-expressing cells into the anterior margin of the limb bud resulted in the induction of Fz-10 expression in anterior-dorsal mesenchyme.     

Rotation and asymmetry of the mitotic spindle direct asymmetric cell division in the developing central nervous system

The asymmetric segregation of cell-fate determinants and the generation of daughter cells of different sizes rely on the correct orientation and position of the mitotic spindle. In the Drosophila embryo, the determinant Prospero is localized basally and is segregated equally to daughters of similar cell size during epidermal cell division. In contrast, during neuroblast division Prospero is segregated asymmetrically to the smaller daughter cell. This simple switch between symmetric and asymmetric segregation is achieved by changing the orientation of cell division: neural cells divide in a plane perpendicular to that of epidermoblast division. Here, by labelling mitotic spindles in living Drosophila embryos, we show that neuroblast spindles are initially formed in the same axis as epidermal cells, but rotate before cell division. We find that daughter cells of different sizes arise because the spindle itself becomes asymmetric at anaphase: apical microtubules elongate, basal microtubules shorten, and the midbody moves basally until it is positioned asymmetrically between the two spindle poles. This observation contradicts the widely held hypothesis that the cleavage furrow is always placed midway between the two centrosomes.     

Ontogenesis of histamine in the chick nervous system

Tissues from the central and peripheral nervous systems of the chick were analyzed for concentration of histamine (Hm) during development. Of the three CNS organs examined, cerebral hemispheres had the highest Hm content. Expressed on the bases of wet weight, protein, and DNA concentrations, sciatic nerve and the pineal gland had the highest levels of this biogenic amine of the five tissues investigated. The concentration of Hm was higher in the cerebellum, cerebral hemispheres, and thalamus of adult animals than in the 15 to 17-day-old embryos. The level of Hm rose markedly in the sciatic nerve and pineal gland after the 15th day of embryonic development. These data might indicate a possible involvement of Hm in controlling the course of maturation of certain organs in the nervous system.     

Expression of a medaka (Oryzias latipes) Bar homologue in the differentiating central nervous system and retina

Endoglin is an auxiliary receptor for the transforming growth factor-β family of cytokines and is required for angiogenesis and heart development. Endoglin expression during mouse embryogenesis was analysed by monitoring β-galactosidase expression from a lacZ reporter cassette inserted downstream of the endoglin promoter. Expression was first detected at 6.5 days post-coitum (dpc) in the amniotic fold and developing allantois. Between 7.5 and 8.5 dpc, endoglin was expressed in endothelial cells of the yolk sac, dorsal aorta and primitive heart tube, and from 9.5 to 13.5 dpc in endothelial cells throughout the developing vasculature. Interestingly, this pattern of endoglin expression is almost identical to that reported for Alk1.     

Cell-substratum adhesion in embryonic chick central nervous system is mediated by a 170,000-mol-wt neural-specific polypeptide

Embryonal chick neural retina cells release into the culture medium a complex of proteins and glycosaminoglycans, termed adherons, that promote cell to substratum adhesion. A monoclonal antibody (C1H3) blocks adheron-mediated cell to substratum adhesion and specifically binds to a 170,000-mol-wt protein present in retinal adherons (Cole, G.J., and L. Glaser, 1984, J. Biol. Chem., 259:4031-4034). The 170,000-mol-wt protein also can be identified in embryonic chick brain and peripheral nervous tissue. In the neural retina, C1H3 also binds to a second antigen with a molecular weight of 140,000 that is absent in the brain. Embryonic brain, therefore, provides a source for the immunopurification of the 170,000-mol-wt protein. Brain adherons also contain the 170,000-mol-wt protein, and cell to substratum adhesion mediated by these adherons is blocked by the C1H3 monoclonal antibody. The 170,000-mol-wt protein in the brain is therefore functionally identical to that in the retina. To demonstrate that adheron-mediated cell to substratum adhesion is caused by cell binding to the 170,000-mol-wt protein, we showed that (a) protease digestion, but not glycosaminoglycan hydrolase digestion of adherons, blocked their ability to bind cells to substratum; (b) the immunopurified 170,000-mol-wt protein blocks adheron-mediated cell to substratum adhesion; and (c) cells can bind to immunopurified 170,000-mol-wt protein bound to glass surfaces.     

Tetraspanins expressed in the embryonic chick nervous system

Proteins of the tetraspanin superfamily participate in the formation of plasma membrane signaling complexes; recent evidence implicates neuronal tetraspanins in axon growth and target recognition. We used a degenerate PCR screen to identify cDNAs encoding tetraspanins expressed in the embryonic spinal cord. Two cDNAs identified apparently represent chick homologues of NAG-2 (cnag) and CD9 (chCD9). A third clone encodes a novel tetraspanin (neurospanin). All three mRNAs are widely expressed but exhibit developmentally distinct patterns of expression in the nervous system. Both neurospanin and cnag exhibit high relative expression in nervous tissue, including brain, spinal cord and dorsal root ganglia (DRG).