CPG16, a novel protein serine/threonine kinase downstream of cAMP-dependent protein kinase.

Gene expression is necessary for the formation and consolidation of long term memory in both invertebrates and vertebrates. Here, we describe the expression and characterization of candidate plasticity gene 16 (cpg16), a protein serine/threonine kinase that was previously isolated from rat hippocampus as a plasticity-related gene. CPG16, when expressed in and purified from bacteria and COS7 cells, was only capable of autophosphorylation and phosphorylation of myelin basic protein but failed to phosphorylate many other peptides and proteins in in vitro phosphorylation assays. Recombinant CPG16, when overexpressed and purified from COS7 cells, had a relatively low level of autophosphorylation activity. This activity was significantly stimulated when cAMP-elevating agents (forskolin, 8-bromo-cAMP) were added to the cells but not by any other extracellular stimuli tested, e.g. serum, phorbol esters, and a calcium ionophore. Although the stimulation of CPG16 activity was inhibited by the cAMP-dependent protein kinase inhibitor H-89, it did not serve as a direct substrate for this kinase. This suggests that CPG16 may be activated by a cAMP-stimulated protein kinase cascade. Immunolocalization studies in COS7 and NIH-3T3 cells showed mostly cytoplasmic localization of CPG16 that turned partially nuclear upon stimulation with 8-bromo-cAMP. Moreover, overexpression of CPG16 seems to partially inhibit cAMP-stimulated activity of the transcription factor CREB (cAMP response element-binding protein), suggesting its involvement in the down-regulation of cAMP-induced transcription. Thus, CPG16 is a protein serine/threonine kinase that may be involved in a novel signaling pathway downstream of cAMP-dependent protein kinase.

Hippocampal plasticity involves extensive gene induction and multiple cellular mechanisms.

Long-term plasticity of the central nervous system (CNS) involves induction of a set of genes whose identity is incompletely characterized. To identify candidate plasticity-related genes (CPGs), we conducted an exhaustive screen for genes that undergo induction or downregulation in the hippocampus dentate gyrus (DG) following animal treatment with the potent glutamate analog, kainate. The screen yielded 362 upregulated CPGs and 41 downregulated transcripts (dCPGs). Of these, 66 CPGs and 5 dCPGs are known genes that encode for a variety of signal transduction proteins, transcription factors, and structural proteins. Seven novel CPGs predict the following putative functions: cpg2--a dystrophin-like cytoskeletal protein; cpg4--a heat-shock protein: cpg16--a protein kinase; cpg20--a transcription factor; cpg21--a dual-specificity MAP-kinase phosphatase; and cpg30 and cpg38--two new seven-transmembrane domain receptors. Experiments performed in vitro and with cultured hippocampal cells confirmed the ability of the cpg-21 product to inactivate the MAP-kinase. To test relevance to neural plasticity, 66 CPGs were tested for induction by stimuli producing long-term potentiation (LTP). Approximately one-fourth of the genes examined were upregulated by LTP. These results indicate that an extensive genetic response is induced in mammalian brain after glutamate receptor activation, and imply that a significant proportion of this activity is coinduced by LTP. Based on the identified CPGs, it is conceivable that multiple cellular mechanisms underlie long-term plasticity of the nervous system.

Neuritin: a gene induced by neural activity and neurotrophins that promotes neuritogenesis.

Neural activity and neurotrophins induce synaptic remodeling in part by altering gene expression. A cDNA encoding a glycosylphoshatidylinositol-anchored protein was identified by screening for hippocampal genes that are induced by neural activity. This molecule, named neuritin, is expressed in postmitotic-differentiating neurons of the developing nervous system and neuronal structures associated with plasticity in the adult. Neuritin message is induced by neuronal activity and by the activity-regulated neurotrophins BDNF and NT-3. Purified recombinant neuritin promotes neurite outgrowth and arborization in primary embryonic hippocampal and cortical cultures. These data implicate neuritin as a downstream effector of activity-induced neurite outgrowth.

NF-kappa B activates the HIV promoter in neurons.

Human immunodeficiency virus (HIV) infection of the brain leads to massive neuronal damage, resulting in the AIDS (acquired immunodeficiency syndrome) dementia complex (ADC). A recent study using transgenic mice indicates that neurons possess transcription factors capable of activating the HIV promoter. To identify these, we transfected two types of primary cultures of rat neurons with HIV promoter-reporter gene constructs. The two kappa B regulatory sites in the HIV long terminal repeat (LTR) are shown to be essential for strong promoter activity. Two proteins present in neurons, BETA and an NF-kappa B-like protein, can bind the kappa B sites. These proteins are shown to belong to distinct families of transcription factors. Mutation analysis and transfection of a dominant negative NF-kappa B mutant, indicate that the neuronal NF-kappa B-like activity mediates HIV promoter activation. cDNA cloning, biochemical and immunological analyses indicate that neuronal NF-kappa B is similar to NF-kappa B of other tissues. Transfections of primary neuron cultures with an HIV promoter-beta-galactosidase construct show that within these cultures, neurons are indeed the cells that highly activate the HIV promoter. Thus, analogous to the situation in T-lymphocytes and macrophages, NF-kappa B is an activator of HIV transcription in neurons.

Numerous candidate plasticity-related genes revealed by differential cDNA cloning.

Plasticity is a property of the nervous system that allows it to modify its response to an altered input. This capacity for change suggests that there are molecular mechanisms in neurons that can couple stimuli to long-term alterations in phenotype. Neuronal excitation elicits rapid transcriptional activation of several immediate-early genes, for example c-fos, c-jun and zif268. Many immediate-early genes encode transcription factors that control expression of downstream genes whose products are believed to bring about long-term plastic changes. Here we use a highly sensitive differential complementary DNA cloning procedure to identify genes that may participate in long-term plasticity. We cloned 52 cDNAs of genes induced by the glutamate analogue kainate in the hippocampus dentate gyrus. The number of these candidate plasticity-related genes (CPGs) is estimated to be 500-1,000. One of the cloned CPGs (16C8), encoding a protease inhibitor, is induced by a stimulus producing long-term potentiation and during dentate gyrus development; a second, cpg1, is dependent on activation of the NMDA (N-methyl-D-aspartate) receptor for induction and encodes a new small, dentate-gyrus-specific protein. Seventeen of the cloned CPGs encode known proteins, including six suggesting that strong neuronal activation leads to de novo synthesis of vesicular and other synaptic components.

Nuclear factor kappa B activates proenkephalin transcription in T lymphocytes.

Upon activation, T lymphocytes accumulate high levels of the neuropeptide enkephalin which correlate with high levels of proenkephalin mRNA in the cells. Here we investigated the transcriptional basis for these changes. The proenkephalin promoter contains a sequence GGGGACGTCCCC, named B2, which is similar to the kappa B sequence GGGGACTTTCC, the binding site of the transcription factor nuclear factor (NF)-kappa B. Activation of T lymphocytes induces an NF-kappa B-like binding activity to the B2 site, concomitant with activation of the proenkephalin promoter. Mutations at the B2 site abolish this transcriptional activation. The purified homodimer (two p50s) of the DNA-binding subunit of NF-kappa B binds the B2 site of proenkephalin relatively better than does the heterotetramer (two p65s plus two p50s) form of the factor. Thus, it appears that the T-cell-specific activation of the proenkephalin promoter is mediated by NF-kappa B. However, as NF-kappa B is ubiquitous and the transcriptional activation through the B2 site is T cell specific, yet another T-cell-specific factor which synergizes with NF-kappa B should be considered.

A brain-specific transcription activator.

We have identified a DNA binding protein, named BETA, that interacts with the same (B) transcriptional regulatory sequence as the known transcription factor NF-kappa B. BETA is found only in gray matter throughout the brain, and not in a variety of other rat tissues. Two binding sites for BETA are present adjacent to the promoter of the rat proenkephalin gene. Transfection of primary brain cultures that express BETA, with a reporter gene driven by the SV40 promoter linked to BETA DNA binding sites, results in transcriptional activation. We infer that BETA is a brain-specific transcription activator.

Elevated myc expression and c-myc amplification in spontaneously occurring B lymphoid cell lines.

Recently, a minor subpopulation of murine B lymphocytes, Ly-1+ B cells, has been distinguished by its unique ontogeny, tissue distribution, and prominence in certain autoimmune and neoplastic B cell diseases. We have previously described a simple murine spleen culture system that results in the spontaneous and exclusive outgrowth of long-term Ly-1+ B cell lines (B Ly-1 cells). Here, we report that the immortal growth property of B Ly-1 cells correlates with a 10-45-fold elevation of steady-state myc RNA and 2-10-fold amplification of the c-myc locus. While c-myc amplification has been observed in malignant cell lines derived from several tissues of origin, its occurrence in lymphoid cells has not been previously reported. The consistent c-myc amplification in B Ly-1 cells may reflect a unique state of this locus in the Ly-1+ B lymphocyte lineage, and contribute to the spontaneous immortalization of this B cell population in vitro, and its apparent predilection for malignant transformation in vivo.

A family of unusually spliced biologically active transcripts encoded by a Drosophila clock gene.

Complementary DNA cloning of the transcripts of the Drosophila clock gene period reveals three distinct transcripts. These result from unusual splicing pathways, one involving a CG 3' splice site and one resulting in the use of two different reading frames in one exon, and they predict three separate proteins. Two of the cloned cDNAs can restore clock function to mutant arrhythmic flies.

Molecular mapping of point mutations in the period gene that stop or speed up biological clocks in Drosophila melanogaster.

The pero1 and the pers mutations in Drosophila melanogaster, which seem to eliminate or speed up, respectively, the clocks underlying biological rhythmicity, were mapped to single nucleotides. Chimeric DNA fragments consisting of well-defined wild-type plus mutant DNA subsegments were constructed, introduced into flies by germ-line transformation, and assayed for biological activity. These experiments localized both pero1 and pers to a 1.7-kilobase DNA fragment that is mostly coding DNA. Sequencing of this subsegment from each mutant showed that pero1 is completely accounted for by a nonsense mutation in the third coding exon of a 4.5-kilobase RNA transcribed from this locus. The pers mutation is also a single nucleotide substitution, in the fourth coding exon, which results in a serine-to-asparagine substitution in the per gene protein product. The functional significance of these changes is discussed with reference to the phenotypes of the two mutations.

B-Ly1 cells: immortal Ly-1+ B lymphocyte cell lines spontaneously arising in murine splenic cultures.

We have surveyed the molecular and functional properties of B-Ly1 cells, spontaneously occurring Ly-1+ cell tissue cultures lines established from murine spleen. Several features are surprising when compared to the conventional understanding of B cell physiology: In contrast to the major B cell subpopulation, these cells establish stable in vitro lines in the absence of nominal growth factors. This outgrowth is consistently accompanied by c-myc amplification and deregulation, and resistance to the effects of an autoregulatory IgM species which normally curtails the growth of B cells. These properties may be relevant to the disproportionate occurrence of Ly-1+ B cell malignancies in vivo. B-Ly1 cell lines consistently delete immunoglobulin constant region genes, and uniformly express lambda light chains, a rare murine isotype. These features may be causally related, and may reflect a novel recombinational activity (see this volume). Immunoglobulin expression can be modulated by conventional stimuli. However, the response is transient, and includes production of mature heavy chain isotypes ("class switching") without apparent switch deletion. Moreover, unstimulated B-Ly1 cells show transcriptional activity throughout the heavy chain locus, and a novel hypermutation activity affecting the immunoglobulin variable region. The mechanisms underlying this surprising pattern of immunoglobulin expression are unknown. However, one wonders whether this expression pattern, if common to Ly-1+ B cell in vivo, might provide modes to escape idiotypic or isotypic immunoregulation. If so, this may be relevant to the prevalence of autoantibody production by this subpopulation. Thus, we are hopeful that some of these unique properties, if confirmed in the Ly-1+ B cells in vivo, will provide more definitive markers for this subpopulation, and disclose mechanisms accounting for their distinctive physiology and pathophysiology.

Probing of the coupling site of the beta-adrenergic receptor. Competition between different forms of the guanyl nucleotide binding protein for interaction with the receptor.

The interaction of the beta-adrenergic receptor (R) with different forms of the regulatory protein (G) was studied. For this purpose, the reconstituted system formed from separate soluble preparations of R and G was employed (Citri, Y., and Schramm, M. (1980) Nature (Lond.) 287, 297-300). Soluble preparations of the native nonactive G, to which GDP is bound (GGDP), and the persistently active G, to which guanyl-5'-yl-imidophosphate (Gpp(NH)p) is bound GGPP(MH)P), were prepared. Reconstituted systems made of GGDP, GGPP(NH)P, and R were used to test whether each of the two forms of G can affect the other's interaction with R. GGPP(NH)P was found to compete with GGDP for the interaction with R. However, GGDP was unable to interfere with the interaction of R with GGPP(NH)P. Similar experiments were carried out with another persistently active G (GGTP gamma S). In sharp contrast to GGPP(NH)P, GGTP gamma S was found incapable of competing with GGDP for R. The above experiments suggest that GGDP and GGPP(NH)P interact with the same coupling site on R. However, the degree of recognition of G by R depends strongly on the guanyl nucleotide which is bound to G. The relative order of recognition being GGPP(NH)P greater than GGDP greater than GGTP gamma S approximately 0. These findings may also explain the known irreversible effects of GTP gamma S in the adenylate cyclase system.

Resolution, reconstitution and kinetics of the primary action of a hormone receptor.

The beta-adrenergic receptor (R) and the GTP binding protein (G) with which the receptor interacts were obtained in separate soluble fractions. Their recombination produced a hormone responsive system. In the presence of hormone the encounter of R with G in the reconstituted membrane occurs much faster than the subsequent R-induced activation of G.