Evidence for HTR1A and LHPP as interacting genetic risk factors in major depression.

The HTR1A -1019C>G genotype was associated with major depression in the Utah population. Linkage analysis on Utah pedigrees with strong family histories of major depression including only cases with the HTR1A -1019G allele revealed a linkage peak on chromosome 10 (maximum HLOD=4.4). Sequencing of all known genes in the linkage region revealed disease-segregating single-nucleotide polymorphisms (SNPs) in LHPP. LHPP SNPs were also associated with major depression in both Utah and Ashkenazi populations. Consistent with the linkage evidence, LHPP associations depended on HTR1A genotype. Lhpp or a product of a collinear brain-specific transcript, therefore, may interact with Htr1a in the pathogenesis of major depression.

Selection of new HSF1 and HSF2 DNA-binding sites reveals difference in trimer cooperativity.

Multiple heat shock transcription factors (HSFs) have been discovered in several higher eukaryotes, raising questions about their respective functions in the cellular stress response. Previously, we had demonstrated that the two mouse HSFs (mHSF1 and mHSF2) interacted differently with the HSP70 heat shock element (HSE). To further address the issues of cooperativity and the interaction of multiple HSFs with the HSE, we selected new mHSF1 and mHSF2 DNA-binding sites through protein binding and PCR amplification. The selected sequences, isolated from a random population, were composed primarily of alternating inverted arrays of the pentameric consensus 5'-nGAAn-3', and the nucleotides flanking the core GAA motif were nonrandom. The average number of pentamers selected in each binding site was four to five for mHSF1 and two to three for mHSF2, suggesting differences in the potential for cooperative interactions between adjacent trimers. Our comparison of mHSF1 and mHSF2 binding to selected sequences further substantiated these differences in cooperativity as mHSF1, unlike mHSF2, was able to bind to extended HSE sequences, confirming previous observations on the HSP70 HSE. Certain selected sequences that exhibited preferential binding of mHSF1 or mHSF2 were mutagenized, and these studies demonstrated that the affinity of an HSE for a particular HSF and the extent of HSF interaction could be altered by single base substitutions. The domain of mHSF1 utilized for cooperative interactions was transferable, as chimeric mHSF1/mHSF2 proteins demonstrated that sequences within or adjacent to the mHSF1 DNA-binding domain were responsible. We have demonstrated that HSEs can have a greater affinity for a specific HSF and that in mice, mHSF1 utilizes a higher degree of cooperativity in DNA binding. This suggests two ways in which cells have developed to regulate the activity of closely related transcription factors: developing the ability to fully occupy the target binding site and alteration of the target site to favor interaction with a specific factor.

The carboxyl-terminal transactivation domain of heat shock factor 1 is negatively regulated and stress responsive.

We have characterized a stress-responsive transcriptional activation domain of mouse heat shock factor 1 (HSF1) by using chimeric GAL4-HSF1 fusion proteins. Fusion of the GAL4 DNA-binding domain to residues 124 to 503 of HSF1 results in a chimeric factor that binds DNA yet lacks any transcriptional activity. Transactivation is acquired upon exposure to heat shock or by deletion of a negative regulatory domain including part of the DNA-binding-domain-proximal leucine zippers. Analysis of a collection of GAL4-HSF1 deletion mutants revealed the minimal region for the constitutive transcriptional activator to map within the extreme carboxyl-terminal 108 amino acids, corresponding to a region rich in acidic and hydrophobic residues. Loss of residues 395 to 425 or 451 to 503, which are located at either end of this activation domain, severely diminished activity, indicating that the entire domain is required for transactivation. The minimal activation domain of HSF1 also confers enhanced transcriptional response to heat shock or cadmium treatment. These results demonstrate that the transcriptional activation domain of HSF1 is negatively regulated and that the signal for stress induction is mediated by interactions between the amino-terminal negative regulator and the carboxyl-terminal transcriptional activation domain.

Mouse heat shock transcription factors 1 and 2 prefer a trimeric binding site but interact differently with the HSP70 heat shock element.

To understand the function of multiple heat shock transcription factors in higher eukaryotes, we have characterized the interaction of recombinant mouse heat shock transcription factors 1 and 2 (mHSF1 and mHSF2) with their binding site, the heat shock element (HSE). For our analysis, we utilized the human HSP70 HSE, which consists of three perfect 5'-nGAAn-3' sites (1, 3, and 4) and two imperfect sites (2 and 5) arranged as tandem inverted repeats. Recombinant mHSF1 and mHSF2, which exist as trimers in solution, both bound specifically to this HSE and stimulated transcription of a human HSP70-CAT construct in vitro. Footprinting analyses revealed differential binding of mHSF1 and mHSF2 to the HSP70 HSE. Specifically, mHSF1 bound all five pentameric sites, whereas mHSF2 failed to interact with the first site of the HSE but bound to sites 2 to 5. Missing-nucleoside analysis demonstrated that the third and fourth nGAAn sites were essential for mHSF1 and mHSF2 binding. The binding of the initial mHSF1 trimer to the HSE exhibited preference for sites 3, 4, and 5, and then binding of a second trimer occurred at sites 1 and 2. These results suggest that HSF may recognize its binding site through the dyad symmetry of sites 3 and 4 but requires an adjacent site for stable interaction. Our data demonstrate that mHSF1 and mHSF2 bind specifically to the HSE through major groove interactions. Methidiumpropyl-EDTA footprinting revealed structural differences in the first and third repeats of the HSE, suggesting that the DNA is distorted in this region. The possibility that the HSE region is naturally distorted may assist in understanding how a trimer of HSF can bind to what is essentially an inverted repeat binding site.

Blocking Chk1 expression induces apoptosis and abrogates the G2 checkpoint mechanism.

Checkpoint kinase 1 (Chk1) is a checkpoint gene that is activated after DNA damage. It phosphorylates and inactivates the Cdc2 activating phosphatase Cdc25C. This in turn inactivates Cdc2, which leads to G2/M arrest. We report that blocking Chk1 expression by antisense or ribozymes in mammalian cells induces apoptosis and interferes with the G2/M arrest induced by adriamycin. The Chk1 inhibitor UCN-01 also blocks the G2 arrest after DNA damage and renders cells more susceptible to adriamycin. These results indicate that Chk1 is an essential gene for the checkpoint mechanism during normal cell proliferation as well as in the DNA damage response.

Down-regulation of survivin by antisense oligonucleotides increases apoptosis, inhibits cytokinesis and anchorage-independent growth.

Survivin, a member of the inhibitor of apoptosis protein (IAP) family, is detected in most common human cancers but not in adjacent normal cells. Previous studies suggest that survivin associates with the mitotic spindle and directly inhibits caspase activity. To further investigate the function of survivin, we used a survivin antisense (AS) oligonucleotide to downregulate survivin expression in normal and cancer cells. We found that inhibition of survivin expression increased apoptosis and polyploidy while decreasing colony formation in soft agar. Immunohistochemistry showed that cells without survivin can initiate the cleavage furrow and contractile ring, but cannot complete cytokinesis, thus resulting in multinucleated cells. These findings indicate that survivin plays important roles in a late stage of cytokinesis, as well as in apoptosis.

The transcriptional regulation of heat shock genes: a plethora of heat shock factors and regulatory conditions.

The inducible regulation of heat shock gene transcription is mediated by a family of heat shock factors (HSF) that respond to diverse forms of physiological and environmental stress including elevated temperature, amino acid analogs, heavy metals, oxidative stress, anti-inflammatory drugs, arachidonic acid, and a number of pathophysiological disease states. The vertebrate genome encodes a family of HSFs which are expressed ubiquitously, yet the DNA binding properties of each factor are negatively regulated and activated in response to specific conditions. This chapter will discuss the regulation of the HSF multi-gene family and the role of these transcriptional activators in the inducible expression of genes encoding heat shock proteins and molecular chaperones.

Distribution and functional characterization of human Nav1.3 splice variants.

The focus of the present study is the molecular and functional characterization of four splice variants of the human Nav1.3 alpha subunit. These subtypes arise due to the use of alternative splice donor sites of exon 12, which encodes a region of the alpha subunit that resides in the intracellular loop between domains I and II. This region contains several important phosphorylation sites that modulate Na+ channel kinetics in related sodium channels, i.e. Nav1.2. While three of the four Nav1.3 isoforms, 12v1, 12v3 and 12v4 have been previously identified in human, 12v2 has only been reported in rat. Herein, we evaluate the distribution of these splice variants in human tissues and the functional characterization of each of these subtypes. We demonstrate by reverse transcriptase-polymerase chain reaction (RT-PCR) that each subtype is expressed in the spinal cord, thalamus, amygdala, cerebellum, adult and fetal whole brain and heart. To investigate the functional properties of these different splice variants, each alpha subunit isoform was cloned by RT-PCR from human fetal brain and expressed in Xenopus oocytes. Each isoform exhibited functional voltage-dependent Na+ channels with similar sensitivities to tetrodotoxin (TTX) and comparable current amplitudes. Subtle shifts in the V 1/2 of activation and inactivation (2-3 mV) were observed among the four isoforms, although the functional significance of these differences remains unclear. This study has demonstrated that all four human splice variants of the Nav1.3 channel alpha subunit are widely expressed and generate functional TTX-sensitive Na+ channels that likely modulate cellular excitability.

Interaction of topoisomerase 1 with the transcribed region of the Drosophila HSP 70 heat shock gene.

Topoisomerase I cleavage sites have been mapped in vivo on the Hsp70 heat shock gene of Drosophila melanogaster cells using the drug camptothecin. Topoisomerase I cleavage was only observed when the Hsp70 gene was transcriptionally active. Site-specific single-strand DNA cleavage by topoisomerase I was confined to the transcribed region of the Hsp70 gene and occurred on both the transcribed and nontranscribed DNA strands. A number of the single-strand breaks on the complementary DNA strands occurred in close proximity giving rise to double-stranded DNA breaks. Inhibition of heat-induced Hsp70 transcription by either Actinomycin D (Act D) or 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) inhibited topoisomerase I cleavage except at the 5' and to a lesser extent the 3' end of the gene. Camptothecin (100 microM) inhibited transcription of the Hsp70 gene greater than 95%. These results suggest that topoisomerase I is intimately associated with and has an integral part in Hsp70 gene transcription.

Analysis of topoisomerase I and II cleavage sites on the Drosophila actin and Hsp70 heat shock genes.

We have compared topoisomerase I and II cleavage sites on the actin 5C and 57A genes and the hsp70 genes in Drosophila Kc cells using the inhibitors camptothecin (topoisomerase I specific) and VM-26 (topoisomerase II specific) to assess the role of these enzymes in transcriptional regulation. Topoisomerase I cleavage sites were localized to the transcribed regions of the actin 5C and hsp70 genes and were present only when these genes were active. The actin 57A gene, shown previously to be inactive in Kc cells, had no detectable topoisomerase I cleavage sites. In contrast to topoisomerase I, topoisomerase II cleavage sites could be detected on transcriptionally active and inactive actin and hsp70 DNA sequences. Topoisomerase II cleavage sites on the inactive hsp70 gene were primarily localized to the very 5' end of the transcribed region of the gene. However, upon heat-induced activation of hsp70 transcription, topoisomerase II cleavage rapidly shifted from the 5' to the 3' end of the gene. Then, during the shutdown of hsp70 expression, there was a gradual reappearance of topoisomerase II cleavage at the 5' end of the gene that temporally correlated with the repression of hsp70 transcription. There was a similar preferential association of topoisomerase II with the 5' ends of transcriptionally repressed actin 5C and 57A genes. These results demonstrate that there are marked differences in how topoisomerases I and II interact with transcriptionally active and inactive regions of chromatin. In addition, we have identified an unusual type of topoisomerase II binding site that is preferentially associated with the 5' ends of inactive hsp70 and actin genes, suggesting that this enzyme may facilitate changes in chromatin structure that are associated with repression of gene transcription.

Analysis of topoisomerase II-mediated DNA cleavage in the 5'-region of the Drosophila hsp70 gene. Identification of a novel half-site DNA substrate for topoisomerase II cleavage.

Previous in vivo studies have identified a prominent 4'-demethylepipodophyllotoxin-9-(4,6-O-thionylidine-beta-D-g lucopyranoside) (VM-26)-induced double-stranded topoisomerase II cleavage site at approximately +80 relative to the start of Drosophila hsp70 transcription (Kroeger, P. E., and Rowe, T. C. (1992) Biochemistry 31, 2492-2502). Topoisomerase II binding at this site correlated with the repression of hsp70 transcription suggesting that this protein-DNA interaction was important in the regulation of hsp70 gene expression. In this paper, we investigated the interaction of purified Drosophila topoisomerase II with a 271-base pair DNA fragment containing the +80 region of the hsp70 gene using the topoisomerase II-specific inhibitor VM-26. VM-26-induced topoisomerase II cleavage of the hsp70 DNA resulted in a major 4-base staggered double-stranded break at +84. In the absence of ATP the +84 site was the only significant VM-26-induced cleavage site. Addition of ATP to the reaction resulted in a stimulation of topoisomerase cleavage throughout the 271-base pair DNA fragment. Deletion analyses determined that approximately 15 to 25 bp of flanking sequence were required for efficient cleavage at most topoisomerase II sites within the hsp70 DNA. However, in the case of the +84 site, topoisomerase cleavage still occurred even when this site was split in half by the restriction enzyme PstI. Topoisomerase II cleavage of both "half-site" DNA molecules occurred at the correct positions on the 4-base single-stranded DNA overhangs generated by PstI. Cleavage was reversible indicating that topoisomerase II could reseal the single-stranded DNA break formed in each half-site substrate. Denaturation of the half-site molecules abolished topoisomerase II cleavage suggesting that cleavage required the duplex region adjacent to the single-stranded cleavage site. Identification of this unusual half-site substrate provides additional evidence that double-stranded cleavage of DNA by topoisomerase II occurs via two sequential single-stranded breaks.

Topological linkage of circular DNA molecules promoted by Ustilago rec 1 protein and topoisomerase.

We studied the formation of linked circular DNA molecules promoted by the combined action of rec 1 protein and type I topoisomerase of Ustilago maydis. When ATP was added as cofactor to reactions containing rec 1 protein, pairs of homologous circular DNA molecules became linked after addition of topoisomerase. Closed circular duplex molecules could be joined at homologous sites with circular single-stranded molecules or with other circular duplex molecules, provided that homologous single-stranded DNA fragments or RNA polymerase and nucleoside triphosphates were also added. Complexes formed were topologically linked through regions of heteroduplex DNA. When the analog adenylyl-imidodiphosphate was substituted for ATP, nonhomologous pairs of circular DNA molecules became linked.

In vivo occupancy of histone gene proximal promoter elements reflects gene copy number-dependent titratable transactivation factors and cross-species compatibility of regulatory sequences.

To assess systematically the structural and functional aspects of histone gene transcription within a chromosomal context, we stably integrated an extensive set of human histone H4 gene constructs into mouse C127 cells. Levels of expression were determined by S1 nuclease protection assays for multiple mouse monoclonal cell lines containing these human H4 genes. For each cell line, we quantitated the number of integrated human H4 genes by Southern blot analysis. The results indicate that the expression of the human H4 gene is in part copy number dependent at low gene dosages. However, the level of expression varies among different cell lines containing similar numbers of copies of the same H4 gene construct. This result suggests that position-dependent chromosomal integration effects contribute to H4 gene transcription, consistent with the roles of long-range gene organization and nuclear architecture in gene regulation. At high copy number, the level of human H4 gene expression per copy decreased, and endogenous mouse H4 mRNA levels were also reduced. Furthermore, in vivo occupancy at the human H4 gene immediate 5' regulatory elements, as defined by genomic fingerprinting, showed copy number-dependent protein/DNA interactions. Hence, human and mouse H4 genes compete for titratable transcription factors in a cellular environment. Taken together, these results indicate cross-species compatibility and suggest limited representation in vivo of the factors involved in regulating histone H4 gene transcription.

cDNA cloning and characterization of human Delta5-desaturase involved in the biosynthesis of arachidonic acid.

Two human expressed sequence tag (EST) cDNA sequences with identity with Delta(5)- and Delta(6)-desaturases from a filamentous fungus, Mortierella alpina, were identified from the LifeSeq(R) database of Incyte Pharmaceuticals, Inc. (Palo Alto, CA, U.S.A.). An oligonucleotide complementary to the 3' EST cDNA sequences was used to screen human liver cDNA using rapid amplification of cDNA ends (RACE)-PCR. The amplified DNA fragment had 98% identity with a putative open reading frame (ORF) predicted from a human genomic sequence, and encoded 444 amino acids. Expression of this ORF in mouse fibroblast cells demonstrated that the encoded protein was a Delta(5)-desaturase, as determined by the conversion of dihomo-gamma-linolenic acid (C(20:3,n-6)) into arachidonic acid (C(20:4,n-6)). The human Delta(5)-desaturase contained a predicted N-terminal cytochrome b(5)-like domain, as well as three histidine-rich domains. A tissue expression profile revealed that this gene is highly expressed in fetal liver, fetal brain, adult brain and adrenal gland. A search of the existing databases led to localization of this ORF within a 14 kb interval flanked by the flap endonuclease-1 (FEN1) and vitelliform macular dystrophy (Best's disease; VMD2) loci of chromosome 11q12.

Cloning of a human cDNA encoding a novel enzyme involved in the elongation of long-chain polyunsaturated fatty acids.

The Saccharomyces cerevisiae protein ELO2p is involved in the elongation of saturated and monounsaturated fatty acids. Among several sequences with limited identity with the S. cerevisiae ELO2 gene, a consensus cDNA sequence was identified from the LifeSeq(R) database of Incyte Pharmaceuticals, Inc. Human liver cDNA was amplified by PCR using oligonucleotides complementary to the 5' and 3' ends of the putative human cDNA sequence. The resulting full-length sequence, termed HELO1, consisted of 897 bp, which encoded 299 amino acids. However, in contrast with the ELO2 gene, expression of this open reading frame in S. cerevisiae demonstrated that the encoded protein was involved in the elongation of long-chain polyunsaturated fatty acids, as determined by the conversion of gamma-linolenic acid (C(18:3, n-6)) into dihomo-gamma-linolenic acid (C(20:3, n-6)), arachidonic acid (C(20:4, n-6)) into adrenic acid (C(22:4, n-6)), stearidonic acid (C(18:4, n-3)) into eicosatetraenoic acid (C(20:4, n-3)), eicosapentaenoic acid (C(20:5, n-3)) into omega3-docosapentaenoic acid (C(22:5, n-3)) and alpha-linolenic acid (C(18:3, n-3)) into omega3-eicosatrienoic acid (C(20:3, n-3)). The predicted amino acid sequence of the open reading frame had only 29% identity with the yeast ELO2 sequence, contained a single histidine-rich domain and had six transmembrane-spanning regions, as suggested by hydropathy analysis. The tissue expression profile revealed that the HELO1 gene is highly expressed in the adrenal gland and testis. Furthermore, the HELO1 gene is located on chromosome 6, best known for encoding the major histocompatibility complex, which is essential to the human immune response.

Topoisomerase II activity involved in cleaving DNA into topological domains is altered in a multiple drug-resistant Chinese hamster ovary cell line.

Drug resistance to inhibitors of DNA topoisomerase II can result from qualitative or quantitative alterations in the target enzyme, topoisomerase II, or from perturbations in drug transport that may or may not involve P-glycoprotein. In the present study, a drug-resistant Chinese hamster ovary cell line, SMR16, was selected in the presence of an epipodophyllotoxin (VP-16) and was found to be cross-resistant to all classes of topoisomerase II inhibitors (3-35-fold). The 3-fold level of resistance of these cells to vincristine is likely due to diminished uptake of this drug, and this is not mediated by overexpression of P-glycoprotein. No alteration in transport of VP-16 was observed. Immunoblotting with several polyclonal anti-topoisomerase II antibodies demonstrated that the resistant cells contain approximately two-thirds of the parental enzyme amount. The topoisomerase II catalytic activity present in 0.35 M NaCl nuclear extracts paralleled this decrease. VP-16- and 4'-(9-acridinylamino)methanesulfon-m-anisidide-induced DNA damage, mediated by topoisomerase II, was found to be decreased 10-12-fold in both intact SMR16 cells and nuclei isolated from these cells, when measured by alkaline filter elution. However, the VP-16-induced DNA cleavage activity present in 0.35 M NaCl nuclear extracts of the resistant cells was attenuated only 2-fold, relative to wild-type cells. Homogeneous preparations of the enzyme obtained from resistant cells demonstrated the same cleavage and catalytic activity as purified wild-type topoisomerase II. Analysis by pulse-field gel electrophoresis of the DNA isolated from VM-26- and 4'-(9-acridinylamino)methanesulfon-m-anisidide-treated sensitive and resistant cells demonstrated significantly less conversion of SMR16 chromosomal DNA into 50-150-kilobase DNA fragments. Chinese hamster ovary SMR16 cells are apparently resistant to topoisomerase II poisons because the topoisomerase II that defines the DNA topological domains is either decreased in amount or insensitive to drug action.