Measurement of transcribed human X-chromosomal DNA sequences transferred to rodent cells by chromosome-mediated gene transfer.

Transfer of genetic information can be effected by incubation of cultured eucaryotic cells with isolated metaphase chromosomes. In most cases, a resulting transformed cell contains only a fragment of a donor chromosome. The amount of transferred donor DNA has been quantified in 11 independent mouse A9 transformants by nucleic acid hybridization analysis. Each transformant had been selected for hprt (hypoxanthine phosphoribosyltransferase; EC 2.4.2.8) transfer and contained part of the human X chromosome. A labeled probe of transcribed human X-chromosomal DNA was prepared by hybridization of nick-translated unique-sequence human DNA with whole cellular RNA from a human-mouse hybrid cell line, A9/HRBC2-A, containing a single human chromosome., X. The amount of human X-chromosomal DNA in the transformants was quantitated by comparing the hybridization of this probe with transformant and A9/HRBC2-A DNAs. Two unstable transformants which had a microscopically detectable donor chromosome fragment contained 15% of the human X-chromosomal single-copy DNA. Four other unstable transformants contained 4 to 7% of human X-chromosomal DNA sequences. The transferred DNA was below the level of detection in three other unstable and in all three stable transformants. We conclude that the initial transfer event can introduce a substantial amount of genetic information but only smaller amounts of DNA are stably incorporated by integration.     

The X-linked methylated DNA binding protein,Mecp2, is subject to X inactivation in the mouse

DNA methylation at the promoter region of X-linked genes is associated with the maintenance of X inactivation in mammals. One of the methylated DNA binding proteins, MECP2, that binds to methylated bases in DNA is encoded by a gene (Mecp2) located on the mouse X Chromosome (Chr). To determine whether this gene was expressed from the inactive X Chr, and X-autosome translocation (T(X;16)16H) system in which expression from the Mecp2 allele on the inactive X Chr could be assayed was used. Results from these experiments indicate that Mecp2 is subject to X inactivation in mouse.     

Low-copy-number human transgene is recognized as an X inactivation center in mouse ES cells, but fails to induce cis-inactivation in chimeric mice

X chromosome inactivation is initiated from a segment of the mammalian X chromosome called the X inactivation center. Transgenes from this region of the murine X chromosome are providing the means to identify the DNA needed for cis inactivation in mice. We recently showed that chimeric mice carrying transgenes from the human X inactivation center (XIC) region also provide a functional assay for human XIC activity; approximately 6 copies of a 480-kb human transgene (ES-10) were sufficient to initiate random X inactivation in cells of male chimeric mice (Migeon et al., 1999, Genomics, 59, 113-121). Now, we report studies of another human transgene (ES-5), which contains less than 300 kb of the human XIC region on Xq13.2 including an intact XIST locus and which has inserted in one or two copies into mouse chromosome 6. The ES-5 transgene is recognized as an X inactivation center in mouse embryonic stem cells, but is not sufficient to induce random X inactivation in somatic cells of highly chimeric mice. Human transgenes in chimeric mice provide a means to uncouple the key steps in this complex pathway and facilitate the search for essential components of the human XIC region.     

The Bacillus subtilis outB gene is highly homologous to an Escherichia coli ntr-like gene.

The Bacillus subtilis outB gene was found to have strong similarities to an Escherichia coli gene complementing ntr-like mutations in Rhodobacter capsulatus. The deduced gene products had 52% identical amino acids (65% similar residues). The phenotype of strains affected in the OutB function indicates that this B. subtilis gene may be involved in nitrogen utilization.     

Mitochondrial sequence migrated downstream to a nuclear V-ATPase B gene is transcribed but non-functional.

A promiscuous nuclear sequence containing a mitochondrial DNA fragment was isolated from rice. Nucleotide sequence analysis reveals that the cDNA clone #21 carries a mitochondrial sequence homologous to the 3' portion of the rps19 gene followed by the 5' portion of the rps3 gene. The mitochondrial sequence is present in an antisense orientation. Sequence comparison of the #21 cDNA with the original mitochondrial sequence shows 99% similarity, suggesting a recent transfer event. Moreover, evidence for a lack of an RNA editing event and retaining of the group II intron sequence strongly suggests that the sequence was transferred from mitochondrion to the nucleus via DNA rather than RNA as an intermediate. The upstream region to the mitochondria-derived sequence shows homology to part of the vacuolar H(+)-ATPase B subunit (V-ATPase B) gene. Isolation of a functional V-ATPase B cDNA and its comparison with the #21 cDNA reveal a number of nucleotide substitutions resulting in many translational stop codons in the #21 cDNA. This indicates that the #21 cDNA sequence is not functional. Analysis of genomic sequences shows the presence of five intron sequences in the #21 cDNA, whereas the functional V-ATPase B gene has 14 introns. Of these, three exons and their internal two introns are homologous to each other, suggesting a duplication event of V-ATPase B genomic DNA. The results of this investigation strongly suggest that the mitochondrial sequence was integrated in an antisense orientation into the pre-existing V-ATPase B pseudogene that can be transcribed and spliced. This represents a case of unsuccessful gene transfer from mitochondrion to the nucleus.     

The mutant vasopressin gene from diabetes insipidus (Brattleboro) rats is transcribed but the message is not efficiently translated

The vasopressin gene from normal and diabetes insipidus (Brattleboro) rats has been isolated and sequenced. Except for a single deletion of a G residue in region coding for the neurophysin carrier protein the approximately 2300 nucleotides of both genes are identical. Blot analysis of hypothalamic RNA as well as transfection and microinjection experiments indicate that the mutant gene is correctly transcribed and spliced, however the resulting mRNA is not efficiently translated.     

The root epidermis-specific pea gene RH2 is homologous to a pathogenesis-related gene

Two-dimensional gel electrophoresis of pea root and root hair proteins revealed the existence of at least 10 proteins present at elevated levels in root hairs. One of these, named RH2, was isolated and a partial amino acid sequence was determined from two tryptic peptides. Using this sequence information oligonucleotides were designed to isolate by PCR an RH2 cDNA clone. In situ hybridization studies with this cDNA clone showed that rh2 is not only expressed in root hairs, but also in root epidermal cells lacking these tubular outgrowths. During post-embryonic development the gene is switched on after the transition of protoderm into epidermis and since rh2 is already expressed in a globular pea embryo in the protoderm at the side attached to the suspensor, we conclude that the expression of rh2 is developmentally regulated. At the amino acid level RH2 is 95% homologous to the pea PR protein I49a. These gene encoding I49a is induced in pea pods upon inoculation with the pathogen Fusarium solani [12]. We postulate that rh2 contributes to a constitutive defence barrier in the root epidermis. A similar role has been proposed for chalcone synthase (CHS) and chitinase, pathogenesis-related protein that are also constitutively present in certain epidermal tissues.     

The human P2X4 receptor gene is alternatively spliced

ATP acts as a fast excitatory neurotransmitter by binding to a large family of membrane proteins, P2X receptors, that have been shown to be ligand-gated, non-selective cation channels. We report the cloning of a full-length and alternatively spliced form of the human P2X₄ gene. Clones were identified from a human stomach cDNA library using a rat P2X₄ probe. Nucleotide sequence analysis of positive clones identified the full-length human P2X₄ cDNA, which codes for a 388-residue protein that is highly homologous (82%) to the rat gene, and an alternatively spliced cDNA. In the alternatively spliced cDNA, the 5′-untranslated region and the first 90 amino acids in the coding region of full-length human P2X₄ are replaced by a 35 amino acid coding sequence that is highly homologous with a region of chaparonin proteins in the hsp-90 family. The open reading frames of the full-length and splice variant clones were confirmed by in vitro translation. Northern analysis indicated expression of the full-length P2X₄ message in numerous human tissues including smooth muscle, heart, and skeletal muscles. Alternatively spliced RNAs were identified in smooth muscle and brain by RT–PCR and confirmed by RNAse protection assays using a 710 bp anti-sense RNA probe that spanned the alternatively spliced and native P2X₄ regions. Injection of full-length, but not alternatively spliced, cRNA into Xenopus oocytes resulted in the expression of ATP gated non-selective cation currents.