A cloned cDNA encoding MAP1 detects a single copy gene in mouse and a brain-abundant RNA whose level decreases during development

Screening of a bacteriophage lambda gt11 cDNA expression library with a polyclonal anti-microtubule associated protein (MAP) antiserum resulted in the isolation of two non-cross-hybridizing sets of cDNA clones. One set was shown to encode MAP2 (Lewis, S. A., A. Villasante, P. Sherline, and N. J. Cowan, 1986, J. Cell Biol., 102:2098-2105). To determine the specificity of the second set, three non-overlapping fragments cloned from the same mRNA molecule via a series of "walking" experiments were separately subcloned into inducible plasmid expression vectors in the appropriate orientation and reading frame. Upon induction and analysis by immunoblotting, two of the fusion proteins synthesized were shown to be immunoreactive with an anti-MAP1-specific antibody, but not with an anti-MAP2-specific antibody. Since these MAP1-specific epitopes are encoded in non-overlapping cDNAs cloned from a single contiguous mRNA, these clones cannot encode polypeptides that contain adventitiously cross-reactive epitopes. Furthermore, these cDNA clones detected an abundant mRNA species of greater than 10 kb in mouse brain, consistent with the coding requirement of a 350,000-D polypeptide and the known abundance of MAP1 in that tissue. The MAP1-specific cDNA probes were used in blot transfer experiments with RNA prepared from brain, liver, kidney, stomach, spleen, and thymus. While detectable quantities of MAP1-specific mRNA were observed in these tissues, the level of MAP1 expression was approximately 500-fold lower than in brain. The levels of both MAP1-specific and MAP2-specific mRNAs decline in the postnatal developing brain; the level of MAP1-specific mRNA also increases slightly in rat PC12 cells upon exposure to nerve growth factor. These surprising results contrast sharply with reported dramatic developmental increases in the amount of MAP1 in brain and in nerve growth factor-induced PC12 cells. The cDNA clones encoding MAP1 detect a single copy sequence in mouse DNA, even under conditions of low stringency that would allow the detection of related but mismatched sequences. The cDNAs cross-hybridize with genomic sequences in rat, human, and chicken DNA, but not with DNA from frog, Drosophila, or sea urchin. These data are discussed in terms of the evolution and possible biological role of MAP1.     

Isolation and characteristics of clones complementary to mRNA of the murine cellular tumor antigen p53

43 cDNA clones specific for murine cellular tumor antigen p53 were isolated from a library constructed using 17S fraction of mRNA from the SV40 transformed murine fibroblasts (SVT2). These clones contain the whole coding region of p53 mRNA and the most of non-translated sequences. A plasmid containing 1.8 kb insert of p53 cDNA was constructed. The p53 specific insert in this plasmid was colinear with p53 mRNA, as revealed by S1 nuclease analysis. 5'-region of the p53 gene comprising non-translated and promoter areas was cloned from the mouse genomic library. A combined clone containing promoter and the whole region, corresponding to p53 mRNA has been constructed.     

The gene and the pseudogene for mouse p53 cellular tumor antigen are located on different chromosomes.

The chromosomal assignments of the two genes encoding the murine p53 cellular tumor antigen were determined by using a panel of mouse-Chinese hamster somatic cell hybrid clones and a mouse p53-specific cDNA clone. One gene, probably the functional member of the family, was found to be on chromosome 11. The other gene, which is probably a processed pseudogene, was assigned to chromosome 14. The potential relevance of these findings to documented cases of chromosome 11 trisomy are also discussed.     

Isolation of a full-length mouse cDNA clone coding for an immunologically distinct p53 molecule.

Transfection of a cloned p53 gene into a p53 nonproducer Abelson murine leukemia virus-transformed cell line, L12, reconstituted p53 expression. The protein expressed in these cells was indistinguishable from that naturally expressed in p53 producer tumor cells. Conversely, p53 protein expressed in L12-derived clones that were established by transfection with a full-length p53 cDNA clone (pM8) exhibited a discrete immunological form. Immunoprecipitation of p53 with a panel of monoclonal anti-p53 antibodies showed that L12-derived clones that were transfected with the genomic p53 clone contained the same antigenic determinants as those found in the p53 protein expressed in tumor cells. These p53 proteins bound all monoclonal antibody types as well as the polyclonal anti-p53 tested. However, L12-derived clones established by transfection of the p53 cDNA clone (pM8) expressed a p53 protein that bound the RA3-2C2 and PAb200.47 anti-p53 monoclonal antibodies as well as polyclonal anti-p53 serum but totally lacked the antigenic receptor for the PAb122 and PAb421 monoclonal antibodies. The p53 proteins expressed by either genomic or cDNA p53 clones exhibited the same apparent molecular sizes and identical partial peptide maps. We suggest that transfection of the p53 gene induced expression of the entire group of the possible mRNA species, whereas cloned p53 cDNA (pM8) represented a single mRNA molecule that codes for a discrete species of p53 protein.     

Brain-specific expression of MAP2 detected using a cloned cDNA probe

We describe the isolation of a set of overlapping cDNAs encoding mouse microtubule associated protein 2 (MAP2), using an anti-MAP antiserum to screen a mouse brain cDNA expression library cloned in bacteriophage lambda gt11. The authenticity of these clones was established by the following criteria: (a) three non-identical clones each expressing a MAP2 immunoreactive fusion protein were independently isolated from the expression library; each of these clones cross-hybridized at the nucleic acid level; (b) anti-MAP antiserum was affinity purified using nitrocellulose-bound fusion protein; these antibodies detected only MAP2 in an immunoblot experiment of whole brain microtubule protein; (c) a series of cDNA "walking" experiments was done so as to obtain a non-overlapping cloned fragment corresponding to a different part of the same mRNA molecule. Upon subcloning this non-overlapping fragment into plasmid expression vectors, a fusion protein was synthesized that was immunoreactive with an anti-MAP2 specific antiserum. Thus, a single contiguous cloned mRNA molecule encodes at least two MAP2-specific epitopes; (d) the cloned cDNA probes detect an mRNA species in mouse brain that is of a size (approximately 9 kb) consistent with the coding capacity required by a 250,000-D protein. The MAP2-specific cloned cDNA probes were used in RNA blot transfer experiments to assay for the presence of MAP2 mRNA in a variety of mouse tissues. Though brain contained abundant quantities of MAP2 mRNA, no corresponding sequences were detectable in RNA prepared from liver, kidney, spleen, stomach, or thymus. We conclude that the expression of MAP2 is brain-specific. Use of the MAP2 specific cDNA probes in genomic Southern blot transfer experiments showed the presence of a single gene encoding MAP2 in mouse. The microheterogeneity of MAP2 is therefore ascribable either to alternative splicing within a single gene, or to posttranslational modification(s), or both. Under conditions of low stringency, the mouse MAP2 cDNA probe cross-hybridizes with genomic sequences from rat, human, and (weakly) chicken, but not with sequences in frog, Drosophila, or sea urchin DNA. Thus, there is significant interspecies divergence of MAP2 sequences. The implications of the above observations are discussed in relationship to the potential biological function of MAP2.     

Mutation is required to activate the p53 gene for cooperation with the ras oncogene and transformation.

Previous experiments have brought into question which amino acid sequence of the p53 oncogene product should be considered wild type and whether the normal protein is capable of cooperating with the ras oncogene to transform cells in culture. To address these questions, a series of p53 cDNA-genomic hybrid clones have been compared for the ability to cooperate with the ras oncogene in transformation assays. From these experiments, it has become clear that the amino acid alanine at position 135, in either the genomic clone or the cDNA clone, failed to produce a p53 protein that cooperated with the ras oncogene and transformed cells. Replacing alanine with valine at this position in either the genomic or the cDNA clone activated for transformation in this assay. Using restriction enzyme polymorphisms in the p53 gene, it was shown that normal mouse DNA encodes alanine at position 135 in the p53 protein. Thus, mutation is required to activate the p53 protein for cooperation with the ras oncogene. After cotransfection with the activated ras gene, the genomic p53 DNA clone always produced more transformed cell foci (1.7-fold) than similar cDNA clones and these foci were more readily cloned (3.6-fold) into permanent cell lines. A series of deletion mutants of the genomic p53 clone were employed to show that the presence of intron 4 in the p53 gene was sufficient to provide much enhanced clonability of transformed foci from culture dishes. The presence of introns in the p53 gene constructions also resulted in elevated levels of p53 protein in the p53-plus-ras-transformed cell lines. Thus, qualitative changes in the p53 protein are required to activate p53 for transformation with the oncogene ras. Quantitative improvements of transformation frequencies are associated with the higher expression levels of altered p53 protein that are provided by having one of the p53 introns in the transforming plasmid.     

Abelson murine leukemia virus-transformed cells that lack p53 protein synthesis express aberrant p53 mRNA species.

Cells of the Abelson murine leukemia virus-transformed line L12 that lack the p53 protein also lack polyadenylated mRNA capable of directing the synthesis of p53 in a cell-free system. Direct analysis of stable polyadenylated mRNA from a variety of cell lines shows that all p53 producers shared a common mRNA species (2.0 kilobases) which hybridized with a p53-specific cDNA probe. This species, which appears to be the mature, normal-sized p53 mRNA, was totally undetectable in L12 cells, which did not produce p53 in vivo. However, L12 cells contained two major p53-specific mRNA species of a substantially larger size (3.5 and 6.5 kilobases) than the p53-specific mRNA in the p53-producing cells. Genomic DNA analysis uncovered an apparent alteration in the 5' proximal part of only one p53 gene, which is unique to the L12 cell line. It is thus possible that the nonproducer phenotype of L12 cells is due at least in part to an alteration within a p53-specific DNA sequence. These findings define a system in which production of p53 appears to be efficiently regulated at the level of stable mRNA and which can be used to study the mechanisms controlling p53 expression in Abelson murine leukemia virus-transformed cells.     

Properties of rat and mouse beta-glucuronidase mRNA and cDNA, including evidence for sequence polymorphism and genetic regulation of mRNA levels

cDNA clones containing partial sequences for beta-glucuronidase (beta G) were constructed from rat preputial gland RNA and identified by their ability to selectively hybridize beta G mRNA. One such rat clone was used to isolate several cross-hybridizing clones from a mouse-cDNA library prepared from kidney RNA from androgen-treated animals. Together, the set of mouse clones spans about 2.0 kb of the 2.6-kb beta G mRNA. Using these cDNA clones as probes, a genomic polymorphism for DNA restriction fragment size was found that proved to be genetically linked to the beta G gene complex. A fragment of beta G cDNA was subcloned into a vector carrying an SP6 polymerase promoter to provide a template for the in vitro synthesis of single-stranded RNA complementary to beta G mRNA. This provided an extremely sensitive probe for the assay of beta G mRNA sequences. Using either nick-translated cDNA or transcribed RNA as a hybridization probe, we found that mouse beta G RNA levels are strongly induced by testosterone, and that induction by testosterone is pituitary-dependent. During the lag period preceding induction, during the induction period itself, and during deinduction following removal of testosterone, beta G mRNA levels paralleled rates of beta G synthesis previously measured by in vivo pulse-labelling experiments. Genetic variation in the extent of induction affected either the level of beta G mRNA or its efficiency of translation depending on the strain of mice tested.     

The DNF15S2 locus at 3p21 is transcribed in normal lung and small cell lung cancer

Small cell lung cancer (SCLC) has been associated with a deletion of the short arm of chromosome 3. One SCLC cell line, H748, has an interstitial deletion of chromosome 3p and shows allele loss for the DNF15S2 locus detected by the probe lambda H3. Conservation of DNF15S2 sequences in mouse indicated that this human genomic fragment may contain coding sequences. Screening of a normal lung cDNA library with chromosome 3-specific fragments of the lambda H3 probe resulted in the isolation of 18 positive clones. The cDNA clones detect an additional DNA polymorphism that is in linkage disequilibrium with the HindIII polymorphism of the DNF15S2 locus. Sequence analysis indicated that the DNF15S2 locus could potentially code for a previously unreported protein of 67 kDa which has 26 cysteine residues. DNF15S2 is part of the coding region of a 3.3-kb mRNA expressed in lung. Northern analysis indicated that this mRNA was not detectable in one of five SCLC lines. This SCLC line, H128, also lacks the enzyme aminoacylase 1.     

Mouse ferritin H multigene family is polymorphic and contains a single multiallelic functional gene located on chromosome 19.

Multiple ferritin H subunit sequences are present in the genome of higher vertebrates, but it is not yet known with certainty if more than one is expressed. In this paper, we provide evidence that there is only one functional ferritin H gene in the mouse. We screened a mouse genomic library using a mouse ferritin H cDNA as a probe and characterized five clones. These genomic clones proved to contain three pseudogenes and two allelic forms of a unique functional gene. These two alleles differed by only two point mutations in the promoter and three in the first intron and by a 31-bp insertion in the first intron. They were equally expressed when transiently transfected in HeLa cells. These five genomic clones account for all the bands observed on a Southern blot of mouse genomic DNA hybridized with a ferritin H cDNA, and these bands present a restriction fragment length polymorphism between various representatives of the genus Mus. Using a DNA panel prepared from the backcross progeny (C57BL/6 X Mus spretus)F1 X C57BL/6, we localized the functional ferritin H gene (Fth) in region B of mouse chromosome 19 and established cen-Ly-1-Fth-Pax-2 as the most likely gene order, thus defining a conserved syntenic fragment with human chromosome 11q.     

Differential splicing of thymosin beta 4 mRNA

A cDNA clone was isolated from a mouse pre-B cell line, the sequence of which has a very high homology with rat and human thymosin beta 4 genes. However, the mouse clone has an insertion of 98 bp relative to the published rat and human sequences upstream of the coding region. By isolation of a second set of clones from a different cDNA library and by cloning a PCR amplified region of mouse genomic DNA it was confirmed that the insertion is not a cloning artifact. Furthermore, it was shown by RNase protection assays with RNA from the pre-B cell line that two sizes of thymosin beta 4 mRNA exist, a long form containing the 98 nucleotide insertion, and a short form that corresponds to the known rat and human mRNA. The short form is about 50 times more abundant than the long form. Analysis of genomic DNA by sequencing and Southern blotting revealed that both forms are encoded by a single gene in the mouse. The two forms of mRNA arise by differential RNA splicing; the long mRNA contains three separate exons, whereas the short mRNA is missing exon 2. The long mRNA is present in two different pre-B cell lines, spleen and thymus, but could not be detected in brain, liver, and kidney. It is possible that the longer mRNA, which encodes a hydrophobic NH2-extension of six additional amino acids, plays a role in lymphocyte function or development. In contrast to the mouse which has a single thymosin beta 4 gene, rat and human have multiple homologs. Most or all of these also contain sequences that cross-hybridize with the newly discovered exon 2. A polymorphic thymosin beta 4 gene has been found in human DNA.     

The ILtat 1.4 surface antigen gene family of Trypanosoma brucei.

The cDNA sequence for the variable surface glycoprotein (VSG) expressed in Trypanosoma brucei clone ILtat 1.4 (called clone D for brevity) hybridizes strongly to three regions in trypanosome genomic DNA. These three regions were extensively characterized by Southern hybridization analyses, genomic DNA cloning and DNA sequence determinations. All three regions occur in the genomes of all trypanosome clones of the ILTAR 1 repertoire regardless of whether or not VSG D was being expressed. Extensive (clone dependent) DNA rearrangements and a (clone independent) double strand DNA break were found distal to the 3'-end of the VSG D coding sequence of one of the regions. VSG D mRNA is most likely synthesized from this region, but a recombinant DNA clone of the VSG coding sequence could not be obtained for confirmation. Recombinant clones of the other two regions were obtained. DNA sequence analyses revealed that their coding sequences differ from each other by 17%. They differ from the ILtat 1.4 cDNA sequence by 4% in one case, and 13% in the other. By analogy with another VSG gene system, one of these two regions may have originally given rise to the third region from which the mRNA is probably transcribed.     

Expression of the mouse p53 cellular tumor antigen in monkey cells.

DNA specific for the murine p53 cellular tumor antigen was linked to the early simian virus 40 promoter and introduced into monkey COS cells either by transfection with recombinant plasmids or by infection with virus. Recipient cells made substantial amounts of a protein apparently identical to mouse p53. Severalfold-larger quantities were detected when cells were transfected with an intron-containing p53-specific segment, as compared with transfection with intronless cDNA. The p53 encoded by the recombinant DNA was capable of complexing with the simian virus 40 T antigen. Transfected p53 was also probably associated with a cellular 68-kilodalton protein, which may be related to a protein coprecipitating with p53 in some transformed cells. These findings confirm the predicted reading frame and protein boundaries and demonstrate that apparently functional p53 can be produced in cells via experimentally introduced recombinant DNA.