Identification of a C-rich element as a novel cytoplasmic polyadenylation element in Xenopus embryos.

During Xenopus early development, the length of the poly(A) tail of maternal mRNAs is a key element of translational control. Several sequence elements (cytoplasmic polyadenylation elements) localized in 3' untranslated regions have been shown to be responsible for the cytoplasmic polyadenylation of certain maternal mRNAs. Here, we demonstrate that the mRNA encoding the catalytic subunit of phosphatase 2A is polyadenylated after fertilization of Xenopus eggs. This polyadenylation is mediated by the additive effects of two cis elements, one being similar to already described cytoplasmic polyadenylation elements and the other consisting of a polycytosine motif. Finally, a candidate specificity factor for polycytosine-mediated cytoplasmic polyadenylation has been purified and identified as the Xenopus homologue of human alpha-CP2.

Germ-line expression of a functional LINE from Drosophila melanogaster: fine characterization allows for potential investigations of trans-regulators.

The I factor (IF) is a functional non-viral retrotransposon, or LINE, from Drosophila melanogaster. It is mobilized in the germ-line of dysgenic SF females during I-R hybrid dysgenesis. In previous papers (Lachaume et al., Development 115: 729-735, 1992; Lachaume and Pinon, Mol. Gen. Gen. 240: 277-285, 1993) we used a transgenic fusion between the 5' part of the IF and the lacZ gene to characterize IF expression and its regulation. This I-lacZ transgenic fusion expresses beta-galactosidase activity during oogenesis. We established a Drosophila line bearing four transgenic insertions (the 4I-lacZ line) and got new insights about IF expression: (1) I-lacZ expression is proportional to the copy number of transgenes present in the genome, (2) the expression occurs just before or when meiosis begins, (3) this expression seems to be subjected to a variegation effect within the germ-line cells, (4) the transgenic activity is mainly directed toward the decondensed chromatin of nurse cells. The close relationship between I factor expression and oogenesis led us to investigate the role played by genes expressed during oogenesis on I factor expression. We present recent data indicating that mutants which interfere with oogenesis can also affect I factor expression. From this data we propose an original screen using the 41-lacZline to detect identified mutations which also affect I factor expression.

Germ-line expression of the I factor, a functional LINE from the fruit fly Drosophila melanogaster, is positively regulated by reactivity, a peculiar cellular state.

I factor is a functional LINE (long interspersed nucleotidic element) which is mobilized in the germ-line of dysgenic SF females during I-R hybrid dysgenesis. Such females are obtained when an oocyte from a reactive stock, devoid of I factors but characterized by a level of reactivity, i.e. its potential for hybrid dysgenesis, is fertilized by a spermatozoon from an I factor-containing inducer stock. In a previous paper we described the expression of an I factor-lacZ fusion. Expression was detected in the ovaries of reactive and dysgenic flies only. In this paper we show that this transgenic activity can be quantified and depends upon the maternally inherited reactivity. Reactivity is not just a permissive state and modifiers of the reactivity level such as heat treatment and ageing change the level of expression of our transgenic fusion accordingly. Moreover, ageing through generations has the same cumulative and reversible effect on both reactivity and I factor expression. Using our fusion as a test for reactivity we show that the silencing of I factor after its introduction into a reactive genome may not be established in a single generation.

Spatial and temporal expression of the I factor during oogenesis in Drosophila melanogaster.

The I factor is a functional non-viral retrotransposon, or LINE, from Drosophila melanogaster. Its mobility is associated with the I-R hybrid dysgenesis. In order to study the expression pattern of this LINE in vivo, a translational fusion between the first ORF of the I factor and the lacZ gene of Escherichia coli has been carried out and introduced in the genome of reactive (R) flies. Homozygous transgenic Drosophila lines have been established and analysed. ORF1 expression is limited to germ-line cells (nurse cells and oocyte) between stage 2 and 10 of oogenesis. No somatic expression is found. Position effects may limit the level of expression of a given transgene but do not modify its basic pattern of expression during the development of the fly. This reproducible control demonstrates both that I factor is driven by its own promoter, probably the internal one suggested by Mizrokhi et al. (Mizrokhi, L.J., Georgevia, S.G. and Ilying, Y.V. (1988). Cell 54, 685-691), and that tissue-specific regulatory sequences are present in the 5' untranslated part of the I factor. The nuclear localization of the fusion protein reveals the presence of nuclear localization signals (NLS) in the ORF1-encoded protein correlating with the possible structural and/or regulatory role of this protein. This expression is restricted to dysgenic and reactive females, and is similar in the two conditions. All the results obtained in this work suggest that I factor transposition occurs as a meiotic event, between stage 2 and 10 of the oogenesis and is regulated at the transcriptional level. It also appears that our transgene is an efficient marker to follow I factor expression.

Identification and analysis of the dog keratin 9 (KRT9) gene.

We have identified the gene coding for the canine ortholog of the human keratin 9 protein using the inverse-polymerase chain reaction (PCR) strategy. Sequence comparison and structure analysis of the gene show marked similarity with the human gene. This gene spans about 7 kb and spreads over eight exons. In the dog gene, the reading frame is extended by 20 codons, the first in-frame stop codon being in exon 8 in the dog rather than in exon 7 as in humans. Alignment of human and dog predicted amino acid sequences confirms the high analogy, reaching 75% identity and 95% similarity in the rod domain. Interestingly, the glycine-loop motif number in the C-terminal V2 variable subdomain of the protein increases from 19 in human to 43 in dog, generating a size difference of 12 kDa between the two proteins. Due to its restricted expression pattern in mammalian epidermis, dog keratin 9 gene was a good candidate gene for the genetic palmoplantar hyperkeratosis observed in the Dogue de Bordeaux. However, no polymorphism associated with the pathology was detected within an affected Dogue de Bordeaux pedigree ruling out this hypothesis.

Molecular evolution of the genes encoding receptor tyrosine kinase with immunoglobulinlike domains.

Receptor tyrosine kinases (RTK) with five, three, or seven immunoglobulinlike domains in their extracellular regions are classified as subclasses III, IV, and V, respectively. Conservation of the exon/intron structure of the downstream part of the human KIT, FMS, and FLT3 genes that encode RTK of subclass III together with the particular chromosomal localization of these genes suggests that RTKIII genes have evolved from a common ancestor by cis and trans duplications. To strengthen this model of evolution and to determine if it can be extended to RTKIV and V genes, we constructed a phylogenetic tree of RTKIII, IV, and V on the basis of a multiple alignment of their catalytic tyrosine kinase domain sequences and determined the exon/intron structure of PDGFRA (subclass III), FGFR4 (subclass IV), and FLT4 (subclass V) genes in their downstream part. Phylogenetic analyses with amino acid or nucleotide sequences both resulted in one most parsimonious tree. The phylogenetic trees obtained indicate that all three subclasses are well individuated and that RTKIII and RTKV are closer to each other than RTKIV. Furthermore, RTKIII and FLT4 (subclass V) genes possess the same exon/intron structure in their downstream part while the structure of the RTKIV genes is very similar to that of RTKIII and FLT4. Both approaches are in complete agreement and indicate that RTKIII, IV, and V genes most probably evolved from a common ancestor already "in pieces" by successive duplications involving entire genes.

Identification and characterization of a set of 100 tri- and dinucleotide microsatellites in the canine genome.

A set of 100 canine microsatellite markers--83 dinucleotides and 17 trinucleotides--is reported. A study of their frequency in the dog genome showed that, while the frequency of the CA repeats is one (CA)n every 47 kb, the 10 trinucleotidic frequencies vary from one every 117 kb (AGG)n to one every 875 kb (AGT)n. Polymorphism analysis performed on 16 unrelated mongrel dogs showed that 80% of dinucleotides are polymorphic, while only 30% of the trinucleotides are so. Of this set of 100 markers, 56 have been mapped on the RHDF5000 dog/hamster whole genome radiation hybrid panel. Moreover, through systematic BLAST analogy searches of the microsatellite-containing clone sequence, three new dog genes could be identified, based on their human ortholog. All of the markers presented may prove useful in physical mapping methods, and polymorphic microsatellites in genetic linkage studies or parentage controls in dog.

Sequence analysis of two genomic regions containing the KIT and the FMS receptor tyrosine kinase genes.

The KIT and FMS tyrosine kinase receptors, which are implicated in the control of cell growth and differentiation, stem through duplications from a common ancestor. We have conducted a detailed structural analysis of the two loci containing the KIT and FMS genes. The sequence of the approximately 90-kb KIT locus reveals the position and size of the 21 introns and of the 5' regulatory region of the KIT gene. The introns and the 3'-untranslated parts of KIT and FMS have been analyzed in parallel. Comparison of the two sequences shows that, while introns of both genes have extensively diverged in size and sequence, this divergence is, at least in part, due to intron expansion through internal duplications, as suggested by the discrete extant analogies. Repetitive elements as well as exon predictions obtained using the GRAIL and GENEFINDER programs are described in detail. These programs led us to identify a novel gene, designated SMF, immediately downstream of FMS, in the opposite orientation. This finding emphasizes the gene-rich characteristic of this genomic region.