Long-term environmental exposure to metals (Cu, Cd, Pb, Zn) activates the immune cell stress response in the common European sea star (Asterias rubens)

The common sea star Asterias rubens represents a key-species of the North-Eastern Atlantic macro benthic community. The cells of their immune system, known as coelomocytes, are the first line of defence against environmental hazards. Here, we report the results of investigations on the immune cells response of sea stars exposed to marine environmental pollution for long periods. We show that levels of the heat shock cognate protein 70 (HSC70) in coelomocytes from A. rubens, which were collected during a field study in the Sǿrfjord (North Sea, SW coast of Norway) along a contamination gradient, are directly associated with the long-term accumulation of Cd, Cu heavy metals exclusively in the tegument. Conversely, Pb and Zn accumulation in the tegument did not relate to HSC70 levels and none of the metals were found accumulated in the pyloric coeca. In addition the coelomocytes from A. rubens, collected in high and low metal impacted stations were examined by a proteomic approach using two-dimensional electrophoresis (2DE). By comparison of the proteomic maps, we observed that 31 protein spots differed in their relative abundance, indicating a gene expression response to the metal mixture exposure. All together, our results confirm that the echinoderm immune cells are a suitable model for the assessment of long-term exposure to environmental pollution, moreover that the increased level of HSC70 can be considered a signal of an acquired tolerance within a large spectrum of protein profile changes occurring in response to metal contamination.

[Fibers glass induced cytotoxicity and genotoxicity]

Man-made vitrous fibers, have been widely used as a substitute for asbestos, as an insulation material. However the fibrous morphology of MMVFs raises concern about potential health hazard. The aim of our study was to assess cytotoxic and genotoxic effects induced on a human alveolar cell line A549 by exposure to glass wool fibers (GW). Cells were exposed for 72 h to 5, 50, 100 microg/ml of glass wool, after incubation the cell viability was determined by a MTT reduction assay. The genotoxic effect was studies by Comet test. An undamaged cell appeared as a nucleoid and a cell with damaged DNA as a comet. Measurement of Comet parameters: % DNA in the tail, tail length and tail momente (the product of relative tail intensity and lenght, that provides a parameter of DNA damage) were obtained from the analysis. A MTT assay indicated that glass wool caused a decrease in cell viability and this decrease was concentration-dependent. The results of the Comet test for DNA damage detection indicated in cell exposed to glass wool fibers a significant increase of mean TM value. All these results provide that the glass wool fibers can induce cytotoxicity and genotoxicity

Conserved structure and promoter sequence similarity in the mouse and human genes encoding the zinc finger factor BERF-1/BFCOL1/ZBP-89

We have characterized the genomic structure of the mouse Zfp148 gene encoding Beta-Enolase Repressor Factor-1 (BERF-1), a Kruppel-like zinc finger protein involved in the transcriptional regulation of several genes, which is also termed ZBP-89, BFCOL1. The cloned Zfp148 gene spans 110 kb of genomic DNA encompassing the 5'-end region, 9 exons, 8 introns, and the 3'-untranslated region. The promoter region displays the typical features of a housekeeping gene: a high G+C content and the absence of canonical TATA and CAAT boxes consistent with the multiple transcription initiation sites determined by primary extension analysis. Computer-assisted search in the human genome database allowed us to determine that the same genomic structure with identical intron-exon organization is conserved in the human homologue ZNF 148. Functional analysis of the 5'-flanking sequence of the mouse gene indicated that the region from nucleotide -205 to +144, relative to the major transcription start site, contains cis-regulatory elements that promote basal expression. Such sequences and the overall promoter architecture are highly conserved in the human gene. Furthermore, we show that the complex transcription pattern of the Zfp148 gene might be due to a combination of alternative splicing and differential polyadenylation sites utilization.

Surface expression of a glycolytic enzyme, alpha-enolase, recognized by autoantibodies in connective tissue disorders

In systemic autoimmune diseases, autoantibodies specific for alpha-enolase are detected more frequently in patients with active renal involvement. To analyze the properties of anti-alpha-enolase antibodies and the distribution of the enzyme in the cell, mouse monoclonal and polyclonal antibodies were obtained from mice immunized with a glutathione-S-transferase-alpha-enolase fusion protein. Anti-alpha-enolase antibodies were purified from patient sera on enolase from human kidney. Using these antibodies, the distribution of alpha-enolase in the cell was analyzed in subcellular fractions and in the cell membrane by flow cytometry and immunoprecipitation. Plasminogen binding was studied by an immunoenzymatic assay. We observed that alpha-enolase was present in the cytosol and membrane fractions obtained from kidney and U937 cells. By flow cytometry, mouse polyclonal anti-enolase antibodies, one monoclonal and 7/9 human anti-enolase antibodies bound the membrane of U937 cells. One monoclonal antibody and mouse polyclonal anti-enolase antibodies immunoprecipitated a 48-kDa molecule from surface-labeled U937 cells and this molecule was recognized by rabbit anti-enolase antibodies. Both immunization-induced antibodies and 7/9 autoantibodies from patient sera inhibited the binding of plasminogen to alpha-enolase. The results show that alpha-enolase, an autoantigen in connective tissue diseases, is a cytoplasmic enzyme which is also expressed on the cell membrane, with which it is strongly associated. Anti-alpha-enolase autoantibodies isolated from patient sera recognize the membrane-associated form of the enzyme and/or interfere with its receptor function, thus inhibiting the binding of plasminogen. Autoantibodies specific for alpha-enolase could play a pathogenic role, either by a cytopathic effect or by interfering with membrane fibrinolytic activity.

The gene encoding the transcriptional repressor BERF-1 maps to a region of conserved synteny on mouse chromosome 16 and human chromosome 3 and a related pseudogene maps to mouse chromosome 8

We have recently identified and characterized a Kruppel-like zinc finger protein (BERF-1), that functions as a repressor of beta enolase gene transcription. By interspecific backcross analysis the gene encoding BERF-1 was localized 4.7 cM proximal to the Mtv6 locus on mouse chromosome 16, and an isolated pseudogene was localized to mouse chromosome 8, about 5.3 cM distal to the D8Mit4 marker. Nucleotide sequence identity and chomosome location indicate that the gene encoding BERF-1 is the mouse homologue (Zfp148) of ZNF148 localized to human chromosome 3q21, a common translocation site in acute myeloid leukemia patients.

ENO1 gene product binds to the c-myc promoter and acts as a transcriptional repressor: relationship with Myc promoter-binding protein 1 (MBP-1)

The Myc promoter-binding protein-1 (MBP-1) is a 37-38 kDa protein that binds to the c-myc P2 promoter and negatively regulates transcription of the protooncogene. MBP-1 cDNA shares 97% similarity with the cDNA encoding the glycolytic enzyme alpha-enolase and both genes have been mapped to the same region of human chromosome 1, suggesting the hypothesis that the two proteins might be encoded by the same gene. We show here data indicating that a 37 kDa protein is alternatively translated from the full-length alpha-enolase mRNA. This shorter form of alpha-enolase is able to bind the MBP-1 consensus sequence and to downregulate expression of a luciferase reporter gene under the control of the c-myc P2 promoter. Furthermore, using alpha-enolase/green fluorescent protein chimeras in transfection experiments we show that, while the 48 kDa alpha-enolase mainly has a cytoplasmic localization, the 37 kDa alpha-enolase is preferentially localized in the cell nuclei. The finding that a transcriptional repressor of the c-myc oncogene is an alternatively translated product of the ENO1 gene, which maps to a region of human chromosome 1 frequently deleted in human cancers, makes ENO1 a potential candidate for tumor suppressor.

Negative regulation of beta enolase gene transcription in embryonic muscle is dependent upon a zinc finger factor that binds to the G-rich box within the muscle-specific enhancer

We have previously identified a muscle-specific enhancer within the first intron of the human beta enolase gene. Present in this enhancer are an A/T-rich box that binds MEF-2 protein(s) and a G-rich box (AGTGGGGGAGGGGGCTGCG) that interacts with ubiquitously expressed factors. Both elements are required for tissue-specific expression of the gene in skeletal muscle cells. Here, we report the identification and characterization of a Kruppel-like zinc finger protein, termed beta enolase repressor factor 1, that binds in a sequence-specific manner to the G-rich box and functions as a repressor of the beta enolase gene transcription in transient transfection assays. Using fusion polypeptides of beta enolase repressor factor 1 and the yeast GAL4 DNA-binding domain, we have identified an amino-terminal region responsible for the transcriptional repression activity, whereas a carboxyl-terminal region was shown to contain a potential transcriptional activation domain. The expression of this protein decreases in developing skeletal muscles, correlating with lack of binding activity in nuclear extract from adult skeletal tissue, in which novel binding activities have been detected. These results suggest that in addition to the identified factor, which functionally acts as a negative regulator and is enriched in embryonic muscle, the G-rich box binds other factors, presumably exerting a positive control on transcription. The interplay between factors that repress or activate transcription may constitute a developmentally regulated mechanism that modulates beta enolase gene expression in skeletal muscle.

Hypoxia response elements in the aldolase A, enolase 1, and lactate dehydrogenase A gene promoters contain essential binding sites for hypoxia-inducible factor 1

Hypoxia-inducible factor 1 (HIF-1) is a basic helix-loop-helix transcription factor which is expressed when mammalian cells are subjected to hypoxia and which activates transcription of genes encoding erythropoietin, vascular endothelial growth factor, and other proteins that are important for maintaining oxygen homeostasis. Previous studies have provided indirect evidence that HIF-1 also regulates transcription of genes encoding glycolytic enzymes. In this paper we characterize hypoxia response elements in the promoters of the ALDA, ENO1, and Ldha genes. We demonstrate that HIF-1 plays an essential role in activating transcription via these elements and show that although absolutely necessary, the presence of a HIF-1 binding site alone is not sufficient to mediate transcriptional responses to hypoxia. Analysis of hypoxia response elements in the ENO1 and Ldha gene promoters revealed that each contains two functionally-essential HIF-1 sites arranged as direct and inverted repeats, respectively. Our data establish that functional hypoxia-response elements consist of a pair of contiguous transcription factor binding sites at least one of which contains the core sequence 5'-RCGTG-3' and is recognized by HIF-1. These results provide further evidence that the coordinate transcriptional activation of genes encoding glycolytic enzymes which occurs in hypoxic cells is mediated by HIF-1.

Transcription of the human beta enolase gene (ENO-3) is regulated by an intronic muscle-specific enhancer that binds myocyte-specific enhancer factor 2 proteins and ubiquitous G-rich-box binding factors

To provide evidence for the cis-regulatory DNA sequences and trans-acting factors involved in the complex pattern of tissue- and stage-specific expression of the beta enolase gene, constructs containing fragments of the gene fused to the chloramphenicol acetyltransferase gene were used in transient-transfection assays of C2C12 myogenic cells. Deletion analysis revealed the presence of four major regions: two negative regions in the 5'-flanking sequence, a basal promoter region which directs expression at low levels in proliferating and differentiated muscle cells, and a positive region within the first intron that confers cell-type-specific and differentiation-induced expression. This positive regulatory element is located in the 3'-proximal portion of the first intron (nucleotides +504 to +637) and acts as an enhancer irrespective of orientation and position from the homologous beta enolase promoter or the heterologous thymidine kinase promoter, conferring in both cases muscle-specific expression to the linked reporter gene. Deletion of a putative myocyte-specific enhancer factor 1 (MEF-1) binding site, containing a canonical E-box motif, had no effects on muscle-specific transcription, indicating that this site is not required for the activity of the enhancer. Gel mobility shift assays, competition analysis, DNase I footprinting, and mutagenesis studies indicated that this element interacts through an A/T-rich box with a MEF-2 protein(s) and through a G-rich box with a novel ubiquitous factor(s). Mutation of either the G-rich box or the A/T-rich box resulted in a significantly reduced activity of the enhancer in transient-transfection assays. These data indicate that MEF-2 and G-rich-box binding factors are each necessary for tissue-specific expression of the beta enolase gene in skeletal muscle cells.

Conserved alternative splicing in the 5'-untranslated region of the muscle-specific enolase gene. Primary structure of mRNAs, expression and influence of secondary structure on the translation efficiency

We report here the isolation and characterization of cDNAs covering the 5'-end region of mouse and rat mRNAs that encode the beta or muscle-specific isoform of the glycolytic enzyme enolase. As previously determined for humans, two classes of beta-enolase transcripts with distinct sequences in their 5'-untranslated regions are present in both mouse and rat muscles. A mechanism of alternative splicing, conserved from mouse to man, generates the two forms of mRNA. Secondary-structure predictions indicated that, in all cases, a more stable secondary structure could exist in the 5' end of the message with the longer leader. In vitro transcripts containing defined human or mouse 5'-untranslated sequences were obtained by fusion of the different cDNA clones and tested for their relative translational efficiencies in rabbit reticulocyte lysates. Transcripts containing the human long and short leader sequences showed differences in the translational rate, suggesting a role for the 5'-untranslated region in the regulation of translation. No detectable difference was found between transcripts with the two distinct mouse leader sequences. In addition, both transcripts are bound to polysomes and are equally distributed along differently sized polysomes in C2C12 myogenic cells. The relative expression of the two spliced forms in developing and adult muscle tissues by means of reverse transcription and polymerase chain reaction did not show a stage-specific or a tissue-type-specific pattern. A putative functional role for the 5'-untranslated sequences of beta-enolase transcripts is discussed.

Structural features of the human gene for muscle-specific enolase. Differential splicing in the 5'-untranslated sequence generates two forms of mRNA

We report here the isolation and characterization of the human gene for the beta or muscle-specific isoform of the glycolytic enzyme enolase. The nucleotide sequence analysis revealed structural features, such as organization as 11 coding exons, the first exon consisting of an untranslated sequence and hence resembling sequences of the other two members of the gene family, the alpha and gamma enolase genes. The beta enolase locus spans about 6 kbp genomic DNA. Sequences matching the consensus sequence for muscle-specific regulatory factors are present in the 5'-flanking region and within the first intron. A combination of primer extension, S1 nuclease protection and RNA-sequencing experiments indicates that the gene has a unique transcriptional start site, 26 bp downstream of a TATA-like box; the differential usage of two donor sites within the untranslated exon I generates two alternatively spliced transcripts. The existence of the two mRNA, differing from one another in the presence or absence of a 42-nucleotide fragment in the leader sequence, was confirmed by cloning the corresponding cDNA using the rapid amplification of cDNA ends strategy. Secondary-structure predictions indicated that the leader sequences of the spliced forms could form hairpin structures with different free energies of formation, suggesting translational control.

Differential expression of neuron-specific enolase mRNA in mouse neuroblastoma cells in response to differentiation inducing agents

1. The mouse neuroblastoma cell line N-115 was used as a model system to study neuronal differentiation induced by treatment of cells with different agents. 2. The extent of morphological differentiation obtained with dibutyryl cyclic AMP (dbc-AMP), dimethyl sulfoxide (DMSO), retinoic acid (RA), and serum-free medium was correlated to the expression of the mRNA for the gamma isoform of the glycolytic enzyme enolase, a recognized neuron-specific marker. 3. A 4-day treatment of the cells with any of the differentiation inducing agents used in this study resulted in the extension of long neurites, though differences in cell body shape were observed depending on the agent used. 4. Northern blot analysis revealed that changes in the level of gamma enolase-specific mRNA correlate with the extent of morphological differentiation, with a 5- to 20-fold increase depending on the differentiation inducing agent used. 5. Finally, we found that a high cell density causes a significative increase in the level of the gamma enolase-specific message in cells maintained in growing conditions.

Gamma enolase expression as early marker of neuronal differentiation of murine neuroblastoma cells N-115

In this study we determined the levels of gamma enolase mRNA in mouse neuroblastoma cell line N-115 at early period of induction of differentiation by serum withdrawal. The expression of gamma enolase was examined by Northern blot analysis of total RNA extracted from cells induced for different lengths of time. We found a 3-fold increase in the level of gamma enolase mRNA after 24 hours of induction of differentiation and higher levels were detected in cells induced for longer time, reaching a 10-fold increase after four days.

The organization and expression of the Saccharomyces cerevisiae L4 ribosomal protein genes and their identification as the homologues of the mammalian ribosomal protein gene L7a

A cDNA for the mouse ribosomal protein (rp) L7a, formerly called Surf-3, was used as a probe to isolate two homologous genes from Saccharomyces cerevisiae. The two yeast genes (L4-1 and L4-2) were identified as encoding S. cerevisiae L4 by 2D gel analysis of the product of the in vitro translation of hybrid-selected mRNA and additionally by direct amino acid sequencing. The DNA sequences of the two yeast genes were highly homologous (95%) over the 771 bp that encode the 256 amino acids of the coding regions but showed little homology outside the coding region. L4-1 differed from L4-2 by 7 out of the 256 amino acids in the coding region, which is the greatest divergence between the products of any two duplicated yeast ribosomal protein genes so far reported. There is strong homology between the mouse rpL7a/Surf-3 and the yeast L4 genes -57% at the nucleic acid level and also 57% at the amino acid level (though some regions reach as much as 80-90% homology). While most yeast ribosomal protein genes contain an intron in their 5' region both L4-1 and L4-2 are intronless. The mRNAs derived from each yeast gene contained heterogenous 5' and 3' ends but in each case the untranslated leaders were short. The L4-1 mRNA was found to be much more abundant than the L4-2 mRNA as assessed by cDNA and transcription analyses. Yeast cells containing a disruption of the L4-1 gene formed much smaller colonies than either wild-type or disrupted L4-2 strains. Disruption of both L4 genes is a lethal event, probably due to an inability to produce functional ribosomes.

Complete structure of the human gene encoding neuron-specific enolase

At least three genes encode the different isoforms of the glycolytic enzyme enolase. We have isolated the gene for the human gamma- or neuron-specific enolase and determined the nucleotide sequence from upstream to the 5' end to beyond the polyadenylation site. The gene contains 12 exons distributed over 9213 nucleotides. Introns occur at positions identical to those reported for the homologous rat gene, as well as for the human alpha- or nonneuronal enolase gene, supporting the existence of a single ancestor for the members of this gene family. Primer extension analysis indicates that the gene has multiple start sites. The putative promoter region lacks canonical TATA and CAAT boxes, is very G + C-rich, and contains several potential regulatory sequences. Furthermore, an inverted Alu sequence is present approximately 572 nucleotides upstream of the major start site. A comparison of the 5'-flanking region of the human gamma-enolase gene with the same region of the rat gene revealed a high degree of sequence conservation.

Developmental changes of neuron-specific enolase mRNA in primary cultures of rat neurons

1. The level of mRNAs for neuron-specific enolase (NSE) and nonneuronal enolase (NNE) was studied in developing rat brain and in pure neuronal cultures of corresponding ages treated or not treated with triiodothyronine (T3). 2. In brain cortices both messages are already detectable at the earliest age (embryonal day 16; E16). During development the mRNA for NNE remains at a steady level, with a transient decline at postnatal day 5 (P5). 3. On the other hand, NSE mRNA follows a biphasic curve: the signal increases threefold from E-16 to P0 and threefold from P5 to P18, with a plateau between P0 and P5. 4. In neuronal cultures the NNE message is present at a constant level until day 10 and declines sharply thereafter, while in T3-treated cultures it reaches a minimum beforehand. 5. The NSE mRNA, on the other hand, increases continuously throughout the whole culture life span, and a slightly higher level is observed in T3-treated cells during the first ten days.

Differential expression of muscle-specific enolase in embryonic and fetal myogenic cells during mouse development

Three isoforms of the glycolytic enzyme enolase are present in mammals and birds. During development, a switch from the alpha to the beta form takes place in skeletal muscle. In order to investigate the molecular basis of this developmental transition of enolase isoforms, we extracted total RNA from limbs of mouse embryos of different ages, and from cultures of embryonic and fetal myogenic cells. The beta message was detected in limbs from 16-day-old fetuses by Northern-blot analysis and its level was found to increase in newborn and adult muscle; no significant amount of beta mRNA was present in samples from earlier developmental stages, which did however express high levels of the muscle-specific actin mRNA. Analysis of RNA extracted from embryonic and fetal myoblasts differentiated in culture revealed that the level of beta mRNA is about 9-fold higher in fetal myotubes than in embryonic myotubes, although the level of muscle actin is comparable in both types of myotubes. These results were confirmed by S1 nuclease protection experiments. Our data show that the appearance of beta enolase transcripts temporally correlates with the formation of the second generation of muscle fibers and suggest that the developmental transition from alpha to beta enolase is linked to a developmental program which takes place in fetal but not in embryonic muscle.

Structure of the human gene for alpha-enolase

In mammals there are at least three isoforms of the glycolytic enzyme enolase encoded by three similar genes: alpha, beta and gamma. In this report we describe the isolation and characterization of the human alpha-enolase locus. The gene appears to exist as a single copy in the haploid genome and is composed of 12 exons distributed over more than 18,000 bases. The structure of this gene has a high degree of similarity to that of the human and rat gamma-enolase genes, with identical positions for all the intron regions. Primer extension and S1 nuclease protection experiments indicate that transcription is initiated at multiple sites. The putative promoter region, like that of other house-keeping genes, lacks canonical TATA and CAAT boxes, is extremely G + C-rich and contains several potential SP1 binding sites. Furthermore, various sequences similar to known regulatory elements were detected.

The human genome contains a single processed pseudogene for alpha enolase located on chromosome 1

We have isolated and characterized human genomic clones containing an alpha enolase pseudogene which lacks introns and has the hallmarks of having been generated by reverse transcription. Two in-frame termination codons renders its coding region incapable of producing a functional protein. An Alu-like sequence is present in the region homologous to the 3' untranslated of the alpha enolase mRNA. Comparison of the two sequences shows that the pseudogene diverged from its functional counterpart about 14 million years ago and interestingly it is the only alpha enolase pseudogene present in the human genome. Chromosomal mapping locates the processed pseudogene to human chromosome 1, the same chromosome where the functional gene has been mapped.

The gene for the muscle-specific enolase is on the short arm of human chromosome 17

The human gene encoding the muscle-specific beta-enolase has been isolated. The beta-enolase gene was mapped to chromosome 17 by analysis of a panel of rodent-human somatic cell hybrids. The gene was further localized to the short arm and tentatively to the region 17pter-p11 by analysis of cell hybrids and transfectant cell lines carrying different portions of chromosome 17.

Cloning, expression and sequence homologies of cDNA for human gamma enolase

The nucleotide sequence of the human gamma-enolase mRNA was determined from recombinant cDNA clones. The sequence spans 2273 bp and includes the complete coding region of 1299 bp, a 5'-noncoding region of 74 bp and a 897-bp-long 3'-noncoding region containing a variant polyadenylation signal (ATTAAA). The deduced amino acid (aa) sequence is 433 aa long and shows a 97% similarity with rat gamma-enolase. Both the 5'- and 3'-untranslated regions are similar (82% and 68%, respectively) to the analogous regions of the rat gamma-enolase gene, suggesting that a strong selective pressure operates on noncoding segments of gamma-enolase mRNAs. The size of the gamma-enolase mRNA expressed in human brain is 2.4 kb. A crosshybridizing 1.5-kb message is detected in human skeletal muscle which may be derived from the beta-enolase-coding gene.

Ribosomal protein L7a is encoded by a gene (Surf-3) within the tightly clustered mouse surfeit locus

The mouse Surfeit locus, which contains a cluster of at least four genes (Surf-1 to Surf-4), is unusual in that adjacent genes are separated by no more than 73 base pairs (bp). The heterogeneous 5' ends of Surf-1 and Surf-2 are separated by only 15 to 73 bp, the 3' ends of Surf-1 and Surf-3 are only 70 bp apart, and the 3' ends of Surf-2 and Surf-4 overlap by 133 bp. This very tight clustering suggests a cis interaction between adjacent Surfeit genes. The Surf-3 gene (which could code for a basic polypeptide of 266 amino acids) is a highly expressed member of a pseudogene-containing multigene family. By use of an anti-peptide serum (against the C-terminal nine amino acids of the putative Surf-3 protein) for immunofluorescence and immunoblotting of mouse cell components and by in vitro translation of Surf-3 cDNA hybrid-selected mRNA, the Surf-3 gene product was identified as a 32-kilodalton ribosomal protein located in the 60S ribosomal subunit. From its subunit location, gel migration, and homology with a limited rat ribosomal peptide sequence, the Surf-3 gene was shown to encode the mouse L7a ribosomal protein. The Surf-3 gene is highly conserved through evolution and was detected by nucleic acid hybridization as existing in multiple copies (multigene families) in other mammals and as one or a few copies in birds, Xenopus, Drosophila, and Schizosaccharomyces pombe. The Surf-3 C-terminal anti-peptide serum detects a 32-kilodalton protein in other mammals, birds, and Xenopus but not in Drosophila and S. pombe. The possible effect of interaction of the Surf-3 ribosomal protein gene with adjacent genes in the Surfeit locus at the transcriptional or posttranscriptional level or both levels is discussed.

Molecular cloning and nucleotide sequence of a full-length cDNA for human alpha enolase

We previously purified a 48-kDa protein (p48) that specifically reacts with an antiserum directed against the 12 carboxyl-terminal amino acids of the c-myc gene product. Using an antiserum directed against the purified p48, we have cloned a cDNA from a human expression library. This cDNA hybrid-selects an mRNA that translates to a 48-kDa protein that specifically reacts with anti-p48 serum. We have isolated a full-length cDNA that encodes p48 and spans 1755 bases. The coding region is 1299 bases long; 94 bases are 5' noncoding and 359 bases are 3' noncoding. The cDNA encodes a 433 amino acid protein that is 67% homologous to yeast enolase and 94% homologous to the rat non-neuronal enolase. The purified protein has been shown to have enolase activity and has been identified to be of the alpha type by isoenzyme analysis. The transcriptional regulation of enolase expression in response to mitogenic stimulation of peripheral blood lymphocytes and in response to heat shock is also discussed.

Isolation and partial characterization of a 48-kDa protein which is induced in normal lymphocytes upon mitogenic stimulation

A 48-kDa protein (p48) crossreactive with an antiserum directed against the 12 C-terminal amino acids of the human cellular myc gene-encoded protein was isolated from a Burkitt lymphoma cell line. The p48 protein is a basic protein and has a cytoplasmic localization. An antiserum prepared against purified p48 reacts specifically with a 48-kDa protein present in a variety of mouse and human cells. This polypeptide is detected at very low levels in normal, resting, peripheral blood lymphocytes, but is induced several-fold by stimulation with either concanavalin A or pokeweed mitogen. The association of p48 induction with a proliferative response and the crossreactivity with the cellular myc protein are discussed.

Expression of a translocated c-abl gene in hybrids of mouse fibroblasts and chronic myelogenous leukaemia cells

Chronic myelogenous leukaemia (CML) is a clonal disease arising from malignant transformation of pluripotent hematopoietic stem cells. In most cases, it is characterized by the presence of the Philadelphia (Ph1) chromosome (22q-) which results from a reciprocal translocation between chromosomes 9 and 22 (refs 1-3). In this translocation, the human homologue of the Abelson virus oncogene, c-abl, normally on chromosome 9, is moved to chromosome 22, while c-sis, the cellular homologue of the simian sarcoma virus oncogene, is moved from chromosome 22 to chromosome 9 (refs 4-6). CML cells carrying the t(9;22) chromosomal translocation are known to produce an 8-kilobase (kb) c-abl transcript in addition to the normal 6- and 7-kb transcripts and to express the normal p145 abl protein and a p210 c-abl protein possessing a tyrosine kinase activity not detected in the p145 species. Results of our analyses using somatic cell hybrids between a mouse fibroblast line and two human CML-derived cell lines which carry the Ph1 chromosome and are phenotypically identical to the fibroblast parent indicate that only the hybrid cells containing Ph1 chromosome express both the 8-kb c-abl RNA and the p210 protein. Thus, expression of the altered c-abl transcripts and protein depends on the presence of the Ph1 chromosome and is not myeloid-specific.

Identification of the c-myc oncogene product in normal and malignant B cells

Antiserum to a synthetic peptide corresponding to the carboxyl-terminus of the human c-myc protein immunoprecipitated a 48,000-dalton protein from a number of normal and malignant human and mouse cells. The size of the protein is consistent with the potential coding region predicted from the c-myc nucleotide sequence, and is the same for malignant cells carrying either a rearranged or an unrearranged c-myc oncogene. Because c-myc transcripts are expressed at higher levels in malignant than in normal B cells, it appears that an increased level of the c-myc protein rather than a change in the gene product is the relevant factor in determining transformation.

Chromosomal localization of the human homolog (c-sis) of the simian sarcoma virus onc gene

Nonrandom chromosome rearrangements of chromosome 22 have been identified in different human malignancies. As a result of Southern blot hybridization of a c-sis probe to DNA's from mouse-human somatic cell hybrids, the human homolog (c-sis) of the transforming gene of simian sarcoma virus was assigned to chromosome 22. Hybrids between thymidine kinase-deficient mouse cells and human fibroblasts carrying a translocation of the region q11-qter of chromosome 22 to chromosome 17 were also analyzed. These studies demonstrate that the human c-sis gene is on region 22q11 greater than qter.

Enzyme and radioimmunoassays for specific murine IgE and IgG with different solid-phase immunosorbents

Enzyme and radioimmunoassays of specific murine IgE and IgG were done using antigen-coated flex vinyl plates, antigen-coupled paper discs or Sepharose 4B beads as solid-phase immunosorbents. These 3 immunosorbents differ in their antibody binding capacities. Only Sepharose beads have a high capacity so that they can be used to assay specific IgE in serum samples without interference from specific IgG which can be present in concentrations of several thousand times greater than those of specific IgE. All 3 types of immunosorbents are equally useful for assaying specific IgG, but the flex vinyl plate is the immunosorbent of choice since it requires less time and gives lower blanks than do the other two. Under the conditions tried, the lowest detectable concentration of specific IgE or IgG was about 1 ng/ml on enzyme or radioimmunoassay. The immunoassays described in this paper are useful for following the kinetics of specific IgE and IgG responses in mice. This was demonstrated with sera from mice immunized with ragweed antigen E.

Circulating immune complexes in patients with usual interstitial pulmonary fibrosis: partial characterization and relationship with Thermoactinomyces vulgaris

Sixty-six sera were analysed by solid-phase conglutinin binding assay, to detect the levels of circulating immune complexes (CIC), and by enzyme-linked immunosorbent assay (ELISA) to show a correlation with antibodies to Thermoactinomyces vulgaris. Sixty per cent of patients with usual interstitial pulmonary fibrosis (UIP), were positive for CIC; and T. vulgaris antibodies were detected in 60% of the same patients. In comparison, there was a low frequency of positive results in bronchitis patients (5% for CIC and 35% for T. vulgaris), and in normal blood donors (0% for CIC and 30% for T. vulgaris). Furthermore 31% of patients with lung cancer were found positive for CIC, but not for T. vulgaris. Immune complexes purified on Protein A-Sepharose and by sucrose density gradient from patients with UIP, showed a sedimentation coefficient higher than 19 S. The purified material was found to contain IgG and IgM as antibodies. Binding of immune complexes, purified by sedimentation on sucrose gradient, to conglutinin was inhibited by the presence of T. vulgaris antigen; thus suggesting that this antigen might be present in the complexes.