Transcriptional response to GAA deficiency (Pompe disease) in infantile-onset patients.

Pompe disease is a genetic disorder resulting from a deficiency of lysosomal acid alpha-glucosidase (GAA) that manifests as a clinical spectrum with regard to symptom severity and rate of progression. In this study, we used microarrays to examine gene expression from the muscle of two cohorts of infantile-onset Pompe patients to identify transcriptional differences that may contribute to the disease phenotype. We found strong similarities among the gene expression profiles generated from biceps and quadriceps, and identified a number of signaling pathways altered in both cohorts. We also found that infantile-onset Pompe patient muscle had a gene expression pattern characteristic of immature or regenerating muscle, and exhibited many transcriptional markers of inflammation, despite having few overt signs of inflammatory infiltrate. Further, we identified genes exhibiting correlation between expression at baseline and response to therapy. This combined dataset can serve as a foundation for biological discovery and biomarker development to improve the treatment of Pompe disease.

Molecular characteristics of non-small cell lung cancer.

We used hierarchical clustering to examine gene expression profiles generated by serial analysis of gene expression (SAGE) in a total of nine normal lung epithelial cells and non-small cell lung cancers. Separation of normal and tumor, as well as histopathological subtypes, was evident by using the 3,921 most abundant transcript tags. This distinction remained when only 115 highly differentially expressed tags were used. Furthermore, these 115 transcript tags clustered into groups suggestive of the unique biological and pathological features of the different tissues examined. Adenocarcinomas were characterized by high-level expression of small airway-associated or immunologically related proteins, whereas squamous cell carcinomas overexpressed genes involved in cellular detoxification or antioxidation. The messages of two p53-regulated genes, p21(WAF1/CIP1) and 14-3-3final sigma, were consistently underexpressed in the adenocarcinomas, suggesting that the p53 pathway itself might be compromised in this cancer type. Gene expression patterns observed by SAGE were consistent with results obtained by quantitative real-time PCR or cDNA array analyses by using a total of 43 lung tumor and normal samples. Thus, although derived from only a few tissue libraries, gene expression profiles obtained by using SAGE most likely represent an unbiased yet distinctive molecular signature for the most common forms of human lung cancer.

Serial analysis of gene expression (SAGE) in Plasmodium falciparum: application of the technique to A-T rich genomes.

The advent of high-throughput methods for the analysis of global gene expression, together with the Malaria Genome Project open up new opportunities for furthering our understanding of the fundamental biology and virulence of the malaria parasite. Serial analysis of gene expression (SAGE) is particularly well suited for malarial systems, as the genomes of Plasmodium species remain to be fully annotated. By simultaneously and quantitatively analyzing mRNA transcript profiles from a given cell population, SAGE allows for the discovery of new genes. In this study, one reports the successful application of SAGE in Plasmodium falciparum, 3D7 strain parasites, from which a preliminary library of 6880 tags corresponding to 4146 different genes was generated. It was demonstrated that P. falciparum is amenable to this technique, despite the remarkably high A-T content of its genome. SAGE tags as short as 10 nucleotides were sufficient to uniquely identify parasite transcripts from both nuclear and mitochondrial genomes. Moreover, the skewed A-T content of parasite sequence did not preclude the use of enzymes that are crucial for generating representative SAGE libraries. Finally, a few modifications to DNA extraction and cloning steps of the SAGE protocol proved useful for circumventing specific problems presented by A-T rich genomes.

Combining serial analysis of gene expression and array technologies to identify genes differentially expressed in breast cancer.

Several methods have been used recently to determine gene expression profiles of cell populations. Here we demonstrate the strength of combining two approaches, serial analysis of gene expression (SAGE) and DNA arrays, to help elucidate pathways in breast cancer progression by finding genes consistently expressed at different levels in primary breast cancers, metastatic breast cancers, and normal mammary epithelial cells. SAGE profiles of 21PT and 21MT, two well-characterized breast tumor cell lines, were compared with SAGE profiles of normal breast epithelial cells to identify differentially expressed genes. A subset of these candidates was then placed on an array and screened with clinical breast tumor samples to find genes and expressed sequence tags that are consistently expressed at different levels in diseased and normal tissues. In addition to finding the predicted overexpression of known breast cancer markers HER-2/neu and MUC-1, the powerful coupling of SAGE and DNA arrays resulted in the identification of genes and potential pathways not implicated previously in breast cancer. Moreover, these techniques also generated information about the differences and similarities of expression profiles in primary and metastatic breast tumors. Thus, combining SAGE and custom array technology allowed for the rapid identification and validation of the clinical relevance of many genes potentially involved in breast cancer progression. These differentially expressed genes may be useful as tumor markers and prognostic indicators and may be suitable targets for various forms of therapeutic intervention.

Serial analysis of gene expression in non-small cell lung cancer.

We used the serial analysis of gene expression (SAGE) method to systematically analyze transcripts present in non-small cell lung cancer. Over 226,000 SAGE tags were sequence analyzed from two independent primary lung cancers and two normal human bronchial/tracheal epithelial cell cultures. A total of 226,000 SAGE tags were sequence identified, representing 43,254 unique transcripts. Comparison of the tags present in the tumor with those identified in the normal tissue revealed 175 transcript tags that were overrepresented in the normal tissue and 142 tags that were overexpressed in the tumor by 10-fold or more. Northern hybridization was performed on 15 of the most abundantly expressed tags identified in the tumors. These tags were derived from either a known gene or a matched expressed sequence tag clone. The transcripts for 3 of the 15 genes, PGP 9.5, B-myb, and human mutT, were abundantly expressed in primary lung cancers (10 of 18, 15 of 18, and 6 of 12 tumors, respectively). In contrast, the presence of PGP9.5 and B-myb was much less frequent in primary tumors derived from other tissue origins. These results suggest that at least a portion of the transcripts identified by SAGE are frequently associated with lung cancer, and that their overexpression may contribute to lung tumorigenesis. The identification and further characterization of genes generated by SAGE should provide potential new targets for the diagnosis, prognosis, and therapy of lung cancer.

SAGE transcript profiles for p53-dependent growth regulation.

Serial analysis of gene expression (SAGE) allows for a quantitative, representative, and comprehensive profile of gene expression. We have utilized SAGE technology to contrast the differential gene expression profile in rat embryo fibroblast cells producing temperature-sensitive p53 tumor suppressor protein at permissive or non-permissive temperatures. Analysis of approximately 15,000 genes revealed that the expression of 14 genes (P < 0.001, > or = 0.03% abundance) was dependent on functional p53 protein, whereas the expression of three genes was significantly higher in cells producing non-functional p53 protein. Those genes whose expression was increased by functional p53 include RAS, U6 snRNA, cyclin G, EGR-1, and several novel genes. The expression of actin, tubulin, and HSP70 genes was elevated at the non-permissive temperature for p53 function. Interestingly, the expression of several genes was dependent on a non-temperature-sensitive mutant p53 suggesting altered transcription profiles dependent on specific p53 mutant proteins. These results demonstrate the utility of SAGE for rapidly and reproducibly evaluating global transcriptional responses within different cell populations.

Repression of the HSV-1 latency-associated transcript (LAT) promoter by the early growth response (EGR) proteins: involvement of a binding site immediately downstream of the TATA box.

During herpes simplex virus (HSV) latency, in neurons of the nervous system, a single family of viral transcripts (the Latency-Associated Transcripts or LATs) are synthesized. Within the LAT promoter region, we have identified a consensus sequence for the EGR proteins in an unusual position immediately downstream of the TATA box. The early growth response (EGR) proteins are rapidly induced in cells by stimuli which also induce HSV to reactivate from latency. In order to determine if EGR proteins play any role in control of LAT transcription, we have analyzed the interactions between EGR proteins and the LAT promoter. Gel retardation and DNase I protection assays demonstrated that EGR1 zinc finger protein bound specifically to the LAT promoter region EGR consensus sequence. To determine if EGR proteins could modulate transcription through the LAT promoter, cotransfection assays were performed using chloramphenicol acetyltransferase (CAT) reporter constructs driven by either the wild-type LAT promoter or a LAT promoter with a mutated EGR binding site. Contransfection of the wild-type LAT promoter construct with EGR expression plasmids resulted in inhibition of the basal level of CAT activity with EGR-2 but not EGR-1 or 3. However, normal levels of CAT activity were observed in cotransfections using the mutant LAT promoter CAT construct suggesting that repression was mediated by the binding of EGR-2 proteins to the LAT promoter. Furthermore, data from combination binding assays using EGR1 and TATA binding protein (TBP) in vitro support the hypothesis that binding of EGR proteins to the LAT promoter prevents binding of TBP and thus suppresses transcription. These results may provide a link between stress responses in neurons of the CNS which activate the EGR family of proteins and HSV reactivation from latency due to the same stress response.

Induction of cell growth regulatory genes by p53.

Transcriptionally regulated growth-response genes play a pivotal role in the determination of the fate of a cell. p53 is known to transcriptionally regulate genes important in regulating cell growth potential. Using differential reverse transcription-PCR analysis of rat embryo fibroblast cells containing a temperature-sensitive p53 allele, we were able to isolate several transcripts up-regulated specifically in cells harboring functional p53 protein. Two of these genes, SM20 and microsomal epoxide hydrolase (mEH), are previously described genes. Two previously uncharacterized cDNAs, cell growth regulatory (CGR) genes CGR11 and CGR19, were isolated. The predicted amino acid sequence of these novel proteins contain known motifs; EF-hand domains (CGR11) and a ring-finger domain (CGR19), suggestive of function. CGR11 and CGR19 appear to be primary response genes expressed to moderate levels in functional p53 cells. Both CGR11 and CGR19 are able to inhibit the growth of several cell lines.

Novel replication inhibitory function of the developmental regulator/transcription repressor protein WT1 encoded by the Wilms' tumor gene.

The tumor suppressor/developmental regulator protein WT1 encoded by the Wilms' tumor gene is a zinc finger-containing transcription factor which binds to the G+C-rich motif 5'-GCGGGGGCG-3' and represses transcription. Alternatively spliced variants of WT1 (termed+KTS) having an insertion in the zinc finger region are defective for binding to and hence for repression of transcription from promoters containing this motif. Due to the known interactions of two other tumor suppressor proteins with the simian virus 40 (SV40) oncoprotein large tumor antigen (TAg) [which in one case (p53) results in inhibition of the replication initiation activity of TAg], and because of the presence of G+C-rich sequences in the SV40 origin region, we tested the effect of WT1 on TAg- and SV40 origin-dependent DNA replication. WT1 and its alternatively spliced variants were found to be potent inhibitors of replication. Inhibition of replication by WT1 required portions of the N-terminal transcription repression domain and the C-terminal DNA binding domain, while other WT1 sequences needed for transcriptional regulation were dispensable. WT1 neither inhibited the synthesis of TAg nor formed a stable complex with it. Studies of the requirement of cis-active origin sequences in vivo and protein-DNA interactions in vitro indicated that WT1 and its alternatively spliced variants might inhibit replication by their novel binding to the GC box promoter motifs of the SV40 21 bp repeat replication-auxiliary sequence.

DNA recognition by splicing variants of the Wilms' tumor suppressor, WT1.

The Wilms' tumor suppressor, WT1, is a zinc finger transcriptional regulator which exists as multiple forms owing to alternative mRNA splicing. The most abundant splicing variants contain a nine-nucleotide insertion encoding lysine, threonine, and serine (KTS) in the H-C link region between the third and fourth WT1 zinc fingers which disrupts binding to a previously defined WT1-EGR1 binding site. We have identified WT1[+KTS] binding sites in the insulin-like growth factor II gene and show that WT1[+KTS] represses transcription from the insulin-like growth factor II P3 promoter. The highest affinity WT1[+KTS] DNA binding sites included nucleotide contacts involving all four WT1 zinc fingers. We also found that different subsets of three WT1 zinc fingers could bind to distinct DNA recognition elements. A tumor-associated, WT1 finger 3 deletion mutant was shown to bind to juxtaposed nucleotide triplets for the remaining zinc fingers 1, 2, and 4. The characterization of novel WT1 DNA recognition elements adds a new level of complexity to the potential gene regulatory activity of WT1. The results also present the possibility that altered DNA recognition by the dominant WT1 zinc finger 3 deletion mutant may contribute to tumorigenesis.

RNA editing in the Wilms' tumor susceptibility gene, WT1.

Rat kidney WT1 cDNAs contain either a thymidine or a cytosine residue at position 839. Genomic WT1 DNA contains only T839. To explain these results, we propose the WT1 transcript undergoes RNA editing in which U839 is converted to C, resulting in the replacement of leucine 280 in WT1 by proline. RNA editing at the same nucleotide was observed in WT1 cDNAs from human testis. In functional assays, the WT1-leucine280 polypeptide repressed the EGR-1 promoter in in vitro assays approximately 30% more efficiently than WT1-proline. Edited WT1-C839 mRNA was barely detectable in neonatal kidney, whereas adult rat kidneys contained both U839 and C839-WT1 mRNA, suggesting a role for the two protein isoforms in growth and differentiation.

The Wilms' tumor suppressor gene WT1 is negatively autoregulated.

The Wilms' tumor suppressor gene WT1 encodes a zinc-finger DNA-binding protein that functions as a transcriptional repressor. WT1 is expressed in a dramatic spatial and temporal pattern during kidney development and is thought to be critical during mesenchymal-epithelial conversion. The WT1 protein bound multiple sites in the WT1 promoter and functioned as a powerful transcriptional repressor of its gene in vivo (> 50-fold). The WT1 protein carrying an NH2-terminal 17-amino acid insertion and a 3-amino acid insertion (KTS) between zinc fingers 3 and 4, arising from the most abundant of four alternatively spliced transcripts, was the most powerful repressor. Of importance, a subset of WT1-binding sites differs from the Egr-1 consensus sequence, which has been shown to bind one splice variant of the WT1 protein (WT1(-KTS)). We characterized two of these sites and show that they bind both -KTS and +KTS forms of the WT1 zinc-finger protein and can confer repression on a heterologous promoter construct. Our data demonstrate that WT1, in addition to its known effects on insulin-like growth factor II, platelet-derived growth factor A, and Pax-2 transcription, is a powerful repressor of its own gene. These observations emphasize its critical role as a transcriptional regulatory protein during normal kidney development.

A structure-function analysis of transcriptional repression mediated by the WT1, Wilms' tumor suppressor protein.

The chromosome 11p13 Wilms' tumor locus (wt1) encodes a zinc finger-containing transcription factor (WT1). WT1 binds to the consensus sequence (5'-GCGGGGGCG-3') and represses transcription when bound to this site in vivo. The mechanism of repression is not yet defined. To investigate the mechanisms of transcriptional repression and map the domains of WT1 responsible, we constructed hybrid proteins between the yeast GAL4 1-147 DNA binding domain and WT1. Fusion of a 298 amino acid glutamine-proline-rich N-terminal segment of WT1 to the GAL4 DNA binding domain created a potent transcriptional repressor. The use of N- and C-terminal truncations of this segment demonstrated that as few as 96 amino acids were required for active repression by GAL4-WT1 hybrid proteins in NIH3T3 fibroblasts. However, the truncated GAL4-WT1 fusion proteins functioned poorly as repressors in embryonic kidney-derived 293 cells, suggesting cell type-specific requirements for transcriptional repression. Site-directed mutagenesis of the WT1 repression domain revealed that deletion of homopolymeric proline and glycine regions, as well as single amino acid changes, partially inactivated the repression function. Single repressor binding sites placed upstream of the transcription start site conferred WT1-mediated repression to a heterologous promoter, whereas multiple sites resulted in additive (non-synergistic) increases in transcriptional repression. Significant repression of transcription was observed when binding sites were placed 760 base pairs upstream or 1000 base pairs downstream relative to the site of transcription initiation. We conclude that the transcriptional repression function of WT1 is contained in the N-terminal, non-DNA binding domain of the protein and that repression can be functionally transferred to a heterologous DNA binding domain.

Molecular analysis of the PHO81 gene of Saccharomyces cerevisiae.

The PHO81 gene product is a positive regulatory factor required for the synthesis of the phosphate repressible acid phosphatase (encoded by the PHO5 gene) in Saccharomyces cerevisiae. Genetic analysis has suggested that PHO81 may be the signal acceptor molecule; however, the biochemical function of the PHO81 gene product is not known. We have cloned the PHO81 gene and sequenced the promoter. A PHO81-LacZ fusion was shown to be a valid reporter since its expression is regulated by the level of inorganic phosphate and is controlled by the same regulatory factors that regulate PHO5 expression. To elucidate the mechanism by which PHO81 functions, we have isolated and cloned dominant mutations in the PHO81 gene which confer constitutive synthesis of acid phosphatase. We have demonstrated that overexpression of the negative regulatory factor, PHO80, but not the negative regulatory factor PHO85, partially blocks the constitutive acid phosphatase synthesis in a strain containing a dominant constitutive allele of PHO81. This suggests that PHO81 may function by interacting with PHO80 or that these molecules compete for the same target.

The Wilms' tumor gene product, WT1, represses transcription of the platelet-derived growth factor A-chain gene.

The Wilms' tumor locus on chromosome 11p13 contains a tumor suppressor gene, wt1, which encodes a DNA binding protein (WT1) with four zinc fingers and a glutamine-proline-rich N terminus and which functions as a repressor of transcription. The platelet-derived growth factor (PDGF) A-chain gene encodes a potent growth factor, which is expressed in high levels in a number of tumor cell lines. We initiated a search for WT1 target genes and now report that WT1 strikingly represses transcription of the PDGF A-chain gene in transient transfection assays and that the WT1 protein interacts directly with a highly G+C-rich region of the PDGF A-chain promoter in gel mobility shift assays. The results suggest that WT1 may function to repress expression of the PDGF A-chain gene and that loss of this or related repressor activities may contribute to the abnormal growth of Wilms' tumors.

Human platelet-derived growth factor A chain is transcriptionally repressed by the Wilms tumor suppressor WT1.

Wilms tumor, an embryonic kidney malignancy, accounts for approximately 6% of all pediatric neoplasms. A gene implicated in the genesis of this tumor, the Wilms tumor suppressor gene (WT1), encodes a zinc-finger DNA-binding protein (WT1) that functions as a transcriptional repressor. In certain Wilms tumors, the platelet-derived growth factor A chain (PDGF-A) is overexpressed; it has therefore been suggested that it may play an autocrine role in development of these neoplasms. Since the PDGF-A promoter contains putative binding sites for WT1, we explored the role of WT1 in regulating A-chain expression. The major PDGF-A promoter activity was localized in transient transfection assays to a region spanning from -643 to + 8 relative to the transcription start site. WT1 bound to several sites in this region of the promoter, as demonstrated by gel-shift analysis and DNase I footprinting, and functioned as a powerful repressor of PDGF-A transcription in vivo. Maximal repression (> 50-fold) of the PDGF-A promoter was dependent on the presence of multiple WT1 binding sites in transient transfection assays. Our observations suggest a mechanism for normal downregulation of a growth factor gene and of an autocrine growth process of import in kidney development and other biological systems.

Repression of the insulin-like growth factor II gene by the Wilms tumor suppressor WT1.

The Wilms tumor suppressor gene wt1 encodes a zinc finger DNA binding protein, WT1, that functions as a transcriptional repressor. The fetal mitogen insulin-like growth factor II (IGF-II) is overexpressed in Wilms tumors and may have autocrine effects in tumor progression. The major fetal IGF-II promoter was defined in transient transfection assays as a region spanning from nucleotides -295 to +135, relative to the transcription start site. WT1 bound to multiple sites in this region and functioned as a potent repressor of IGF-II transcription in vivo. Maximal repression was dependent on the presence of WT1 binding sites on each side of the transcriptional initiation site. These findings provide a molecular basis for overexpression of IGF-II in Wilms tumors and suggest that WT1 negatively regulates blastemal cell proliferation by limiting the production of a fetal growth factor in the developing vertebrate kidney.

Characterization of the zinc finger protein encoded by the WT1 Wilms' tumor locus.

We analysed the biochemical properties of the transcription factor encoded by the putative tumor-suppressor gene present at the WT1 Wilms' tumor locus. A gene containing the full-length amino acid coding sequence of human wt1 was reconstructed from synthetic oligonucleotides and cloned into expression vectors for in vitro and in vivo protein synthesis. Polyclonal rabbit antibodies specific for the WT1 protein were raised to an Escherichia coli-produced 91 amino acid N-terminal segment and to a 136 amino acid C-terminal segment, which contains the zinc finger domain. WT1 produced by in vitro translation migrated as a 52 kDa protein on sodium dodecylsulfate-polyacrylamide gels and bound to the EGR consensus sequence in gel-retardation assays. Expression of the wt1 gene via transient transfection in COS-1 cells revealed a 52 kDa protein which was immunoprecipitated by both the N-terminal- and C-terminal-specific antisera. Immunofluorescence studies of wt1-transfected COS-1 cells revealed that the WT1 protein was localized to the nucleus. Metabolic labeling with [32P]orthophosphate failed to reveal significant phosphorylation of the WT1 protein in COS-1 cells. Two immunoreactive WT polypeptides of 52 and 54 kDa were observed in murine embryonic stem cells and COS-1 kidney cells and may represent previously identified splicing variants of WT1. These antisera should be useful in characterizing the structure and function of the WT1 protein in human Wilms' tumor specimens.