Cytokines and neuronal differentiation

A diverse spectrum of complementary experimental investigations has demonstrated that two major cytokine superfamilies, the transforming growth factor-beta (TGF beta) and the hemopoietins, mediate an extensive range of developmental events in the nervous system that often rivals and frequently exceeds that of the classic neurotrophins. The exponential growth in the identification and physiological analysis of TGF beta subclasses of cytokines that transduce intracellular signals through intrinsic membrane serine/threonine kinase-associated receptor subunits has led to an increased understanding of their complex cellular actions in programming the temporospatial expression and maturation of anatomically distinct neuronal subpopulations. An analysis of the developmental parallels that exist between neural development and hematolymphopoiesis has fostered an expansion in the identification and classification of cellular actions of hematolymphopoietic cytokines that are also active during neural development. During the process of neural maturation, it has also become apparent that an extensive range of cell surface-associated and intracellular signalling molecules that are essential for hematopoietic and immunological development may also represent an important set of effector molecules that are active during neuronal differentiation. These recent advances in cell and molecular biology have allowed us to begin to construct an integrated model of the developmental signalling pathways and diverse cellular processes that are necessary for graded stages of neuronal maturation. These cumulative observations suggest that a dynamic hierarchy of epigenetic and genetic signals is essential for the growth, survival, and maturation of regional neuronal subpopulations that are derived from multipotent progenitor species within the central and peripheral nervous systems.     

Expression of zebrafish bHLH genes ngn1 and nrd defines distinct stages of neural differentiation

The phenotype of T cells in the central nervous system (CNS) in two models of chronic inflammation (experimental allergic encephalomyelitis and Corynebacterium parvum-induced inflammation) was compared to that of T cells in gut and chronically inflamed subcutaneous tissue and lung. CNS T cells display a similar phenotype in both inflammatory models, and are phenotypically unique compared to T cells from the other inflamed tissues. T cells from inflamed CNS are mainly CD4+ and are the only population examined that express a typical activated/memory phenotype: CD44high/LFA-1high/ICAM-1high/CD45RBlow. The CNS T cells are alpha4beta7-integrin(negative), but express alpha4-integrin and activated beta1 integrin, suggesting expression of the alpha4beta1-heterodimer in an activated state. In contrast, most T cells in gut express low levels of activated beta1 integrin. The CNS T cells lack expression of alpha6 and alphaE integrin chains and L-selectin. In inflamed CNS and inflamed subcutaneous tissue, approximately 50% of T cells express high affinity ligands for P-selectin while fewer than 10% express high affinity ligands for E-selectin. In summary, our data show that, independent of the inflammatory stimulus, T cells recruited into the inflamed CNS are phenotypically distinct from T cells in other inflamed tissues. This finding leads us to hypothesize the existence of a phenotypically distinct 'CNS-seeking' T lymphocyte population.     

TRAAK is a mammalian neuronal mechano-gated K+ channel

The novel structural class of mammalian channels with four transmembrane segments and two pore regions comprise background K+ channels (TWIK-1, TREK-1, TRAAK, TASK, and TASK-2) with unique physiological functions (1-6). Unlike its counterparts, TRAAK is only expressed in neuronal tissues, including brain, spinal cord, and retina (1). This report shows that TRAAK, which was known to be activated by arachidonic acid (3), is also opened by membrane stretch. Mechanical activation of TRAAK is induced by a convex curvature of the plasma membrane and can be mimicked by the amphipathic membrane crenator trinitrophenol. Cytoskeletal elements are negative tonic regulators of TRAAK. Membrane depolarization and membrane crenation synergize with stretch-induced channel opening. Finally, TRAAK is reversibly blocked by micromolar concentrations of gadolinium, a well known blocker of stretch-activated channels. Mechanical activation of TRAAK in the central nervous system may play an important role during growth cone motility and neurite elongation.     

Identification of Caenorhabditis elegans genes required for neuronal differentiation and migration

To understand the mechanisms that guide migrating cells, we have been studying the embryonic migrations of the C. elegans canal-associated neurons (CANs). Here, we describe two screens used to identify genes involved in CAN migration. First, we screened for mutants that died as clear larvae (Clr) or had withered tails (Wit), phenotypes displayed by animals lacking normal CAN function. Second, we screened directly for mutants with missing or misplaced CANs. We isolated and characterized 30 mutants that defined 14 genes necessary for CAN migration. We found that one of the genes, ceh-10, specifies CAN fate. ceh-10 had been defined molecularly as encoding a homeodomain protein expressed in the CANs. Mutations that reduce ceh-10 function result in Wit animals with CANs that are partially defective in their migrations. Mutations that eliminate ceh-10 function result in Clr animals with CANs that fail to migrate or express CEH-23, a CAN differentiation marker. Null mutants also fail to express CEH-10, suggesting that CEH-10 regulates its own expression. Finally, we found that ceh-10 is necessary for the differentiation of AIY and RMED, two additional cells that express CEH-10.     

Expression and regulation of neuronal apoptosis inhibitory protein during adipocyte differentiation

We have used the 3T3-L1 and 3T3-F442A preadipocyte cell lines to examine the expression and regulation of neuronal apoptosis inhibitory protein (NAIP) during adipocyte differentiation. When 3T3-L1 preadipocytes differentiated into adipocytes, they developed resistance to apoptosis induced by growth factor deprivation, as assessed by terminal deoxynucleotide transferase (TdT)-mediated dUTP nick end labeling. Protein expression of NAIP was markedly elevated in 3T3-L1 and 3T3-F442A adipocytes compared with that in their fibroblast-like precursors. NAIP was also present in rat white adipocytes. In 3T3-L1 cells, the increase in NAIP occurred by day 4 of the 8-day differentiation protocol, which includes exposure of confluent preadipocytes to insulin, dexamethasone, and isobutylmethylxanthine. Incubation of confluent 3T3-L1 preadipocytes with any of these components alone had no effect on NAIP expression. When 3T3-C2 cells, a control cell line that does not differentiate, were subjected to the differentiation protocol, the low NAIP levels remained unaltered. Addition of rapamycin, a p70 S6 kinase inhibitor that blocks adipocyte differentiation, to the 3T3-L1 differentiation medium prevented the rise in NAIP expression. These data demonstrate for the first time that NAIP is expressed in adipocyte cell lines and primary adipocytes. The differentiation-dependent augmentation of NAIP protein levels in 3T3-L1 adipocytes is closely correlated with the development of resistance to apoptosis induced by growth factor deprivation, suggesting a potential role for NAIP in these cells.     

Cellular and molecular changes during sex differentiation of embryonic mammalian gonads

Structural and molecular changes during sex differentiation and development of mammalian gonads from early embryonic phase until sexual maturity have been studied by morphologic and immunocytochemical methods in vivo and in experimental culture. The strategy has been to identify cellular macromolecules whose genes are differently expressed in the two sexes and to formulate a hypothetical regulatory chain of sex determination. This approach should provide new possibilities for finding the missing links between the final structural genes and the early regulatory genes, which are differentially expressed before and during gonadal differentiation. On the basis of accumulated structural and molecular evidence, the early epithelial differentiation from the precursor cells via cell aggregates to testicular cords or ovarian follicles is not sexually regulated. The biological consequences of sex determination in the differentiation of the genital organs include changes in the pattern formation of the gonadal epithelia and concomitant alterations in the synthesis and organization of the structural macromolecules.