Reconstitution of heterologous and chimeric casein kinase II with recombinant subunits from human andDrosophila: Identification of species-specific differences in the Β subunit

Casein kinase II is composed of two catalytic (a) and two regulatory (Β) subunits, the amino acid sequences of theα andΒ subunits are highly conserved between species. To examine whether heterologous casein kinase II could be formed, recombinantα andΒ subunits from human andDrosophila were reconstituted from inclusion bodies. Casein kinase II containing either humanα andDrosophila Β orDrosophila α and humanΒ subunits exhibited enzymatic properties similar to those of the homologous holoenzymes with regard to specific activity, salt optima, and autophosphorylation. However, renaturation and reconstitution of casein kinase II was dependent on the type ofΒ subunits and the redox conditions, with theDrosophila Β subunits requiring more reduced conditions. ChimericΒ subunits prepared from human andDrosophila cDNA revealed that the N-terminal region was responsible for the requirement for the reduced redox state during renaturation. TheN-terminal region also affected solubility and electrophoretic mobility of theΒ subunit.     

Gypsy homologous sequences inDrosophila subobscura (gypsyDS)

Summary Characterization of sequences homologous to theDrosophila melanogaster gypsy transposable element was carried out inDrosophila subobscura (gypsyDS). They were found to be widely distributed among natural populations of this species. From Southern blot and in situ analyses, these sequences appear to be mobile in this species.GypsyDS sequences are located in both euchromatic and heterochromatic regions. A completegypsyDS sequence was isolated from aD. subobscura genomic library, and a 1.3-kb fragment which aligns with the ORF2 of theD. melanogaster gypsy element was sequenced. Comparisons of this sequence in three species (D. subobscura, D. melanogaster, and D. virilis) indicate that there is greater similarity between theD. subobscura-D. virilis sequences than betweenD. subobscura andD. melanogaster. Molecular divergence ofgypsy sequences betweenD. virilis andD. subobscura is estimated at 16 MY, whereas the most likely divergence time of these two species is more than 60 MY. These data strongly suggest thatgypsy sequences have been horizontally transferred between these species.Offprint requests to: T.M. Alberola     

A New Family of Mouse Genes Homologous to the HumanMAGEGenes

The humanMAGEgenes are expressed in a wide variety of tumors but not in normal cells, with the exception of the male germ cells, placenta, and, possibly, cells of the developing embryo. These genes encode tumor-specific antigens recognized by cytolytic T lymphocytes. TheMAGEgenes are located on the X chromosome, in three clusters denotedMAGE-A, B,andC,mapping at q28, p21.3, and q26, respectively. The function of these genes remains unknown. Because mice offer many advantages for the study of genes that may be involved in embryonic development, we looked for the murine equivalents of the 12 humanMAGE-Agenes. Using aMAGE-Aprobe, we isolated 8 new murine genes that are homologous to theMAGEgenes. On average, the open reading frames (ORFs) of these 8 closely related genes display a slightly higher degree of nucleotide identity with theMAGE-AORFs than with theMAGE-BorMAGE-CORFs. Furthermore, likeMAGE-Agenes, they encode acidic proteins, whereas theMAGE-Bgenes encode basic proteins. Accordingly, these 8 murine genes were namedMage-a1to8(approved symbolsMagea1to8).Mage-agenes were mapped in two different loci on the mouse X chromosome.Mage-a4andMage-a7are located in a region that is syntenic to either Xp21 or Xq28. The 6 other genes are arranged in a cluster located in a region syntenic to Xp22. Like their human counterparts,Mage-agenes were found to be transcribed in adult testis, but not in other tissues. Expression of someMage-agenes was also detected in tumor cell lines. TwoMage-agenes were found to be expressed in blastocysts.     

Indirect evidence of alteration in the expression of the rDNA genes in interspecific hybrids betweenDrosophila melanogaster andDrosophila simulans

Crosses betweenDrosophila melanogaster females andD. simulans males produce viable hybrid females, while males are lethal. These males are rescued if they carry theD. simulans Lhr gene. This paper reports that females of the wild-typeD. melanogaster population Staket do not produce viable hybrid males when crossed withD. simulans Lhr males, a phenomenon which we designate as the Staket phenotype. The agent responsible for this phenomenon was found to be the StaketX chromosome (X ^mel ,Stk). Analysis of the Staket phenotype showed that it is suppressed by extra copies ofD. melanogaster rDNA genes and that theX ^mel ,Stk chromosome manifests a weak bobbed phenotype inD. melanogaster X ^mel ,Stk/0 males. The numbers of functional rDNA genes inX ^mel ,Stk andX ^mel ,y w (control) chromosomes were found not to differ significantly. Thus a reduction in rDNA gene number cannot account for the weak bobbedX ^mel ,Stk phenotype let alone the Staket phenotype. The rRNA precursor molecules transcribed from theX ^mel ,Stk rDNA genes seem to be correctly processed in both intraspecific (melanogaster) and interspecific (melanogaster-simulans) conditions. It is therefore suggested that theX ^mel ,Stk rDNA genes are inefficiently transcribed in themelanogaster-simulans hybrids.     

An approach to study the evolution of theDrosophila 5S ribosomal genes using P-element transformation

Summary The P-element-mediated gene transfer system was used to introduceDrosophila teissieri 5S genes into theDrosophila melanogaster genome. Eight transformedD. melanogaster strains that carryD. teissieri 5S mini-clusters consisting of 9–21 adjacent 5S units were characterized. No genetic exchanges betweenD. melanogaster andD. teissieri 5S clusters were detected over a 2-year survey of the eight strains. The occurrence of small rearrangements within theD. melanogaster 5S cluster was demonstrated in one of the transformed strains.     

Zur Position derJuglandaceae A. rich. ex Kunth im aktuellen System der Magnoliatae

The position of theJuglandaceae within theHamamelididae is critically analysed and discussed. TheJuglandales should be given an intermediate position betweenHamamelidanae andRosanae (asJuglandanae) within theRosidae.     

Sox andZfx genes in giant panda

By using PCR cloning techniques, the DNA sequences of the HMG box regions of sixSox genes (pSox) and the zinc finger domains of twoZfz genes (pZfx) in the giant panda were identified. The giant pandaSox genes fell into two subfamilies,SOX-S1 andSOX-S2. ThepSox andpZfx genes of the giant panda were highly homologous to the corresponding genes in mammals and revealed close substitution rates to those in the primates.     

Mapping of theHox-3.1 andMyc-1.2 genes on chromosome 15 of the mouse by restriction fragment length variations

Restriction endonuclease fragment length variations (RFLV) were detected by use of the cDNA probeHox-3.1 for the homeo box-3.1 gene and also thec-myc oncogene probe for exon 2. RFLV ofHox-3.1 were found inHindIII restriction patterns, and RFLV of theMyc-1.2 gene inEcoRV patterns. From the RFLV, theHox-3.1 andMyc-1.2 genes were mapped on chromosome 15. Three-point cross test data showed that the frequency of recombination is 26.4% betweenMyc-1.2 andGpt-1, 30.2% betweenGpt-1 andGdc-1, and 9.4% betweenGdc-1 andHox-3.1. The following order of these genes is proposed,Myc-1.2—Gpt-1—Gdc-1—Hox-3.1. All laboratory strains carry theHox-3.1 ^a andMyc-1.2 ^a alleles. Among strains of wild origin,domesticus strains carry only theHox-3.1 ^a andMyc-1.2 ^a alleles, as do the laboratory strains. One strain ofbrevirostris carries theHox-3.1 ^a andMyc-1.2 ^b alleles. Other wild subspecies from Europe and Asia,M. m. musculus, M. m. castaneus, M. m. molossinus, Chinese mice of wild origin, andM. m. yamashinai carry theHox-3.1 ^b andMyc-1.2 ^b alleles.     

Regulation of ammonium ion assimilation enzymes inNeurospora crassa nit-2 andms-5 mutant strains

InNeurospora crassa thenit-2 andnmr-1 (ms-5) loci represent the major control genes encoding regulatory proteins that allow the coordinated expression of various systems involved with the utilization of a secondary nitrogen source. In this paper we examine the effect of thenit-2 andms-5 (nmr-1 locus) mutations on the regulation of the ammonium assimilation enzymes, glutamine synthetase and glutamate dehydrogenase, which are regulated by the products of these genes; however, glutamate synthase is not so regulated. Glutamine synthetase and glutamate dehydrogenase levels are also regulated by the amino nitrogen content. We present evidence that thems-5 andgln ^r strains, which behave very similarly in their resistance to glutamine repression, are different and map in different loci.     

Comparative Genome Mapping of the Ataxia–Telangiectasia Region in Mouse, Rat, and Syrian Hamster

Chromosomal locations of theAtm(ataxia–telangiectasia (AT)-mutated) andAcat1(mitochondrial acetoacetyl-CoA thiolase) genes in mouse, rat, and Syrian hamster were determined by direct R-banding FISH. Both genes were colocalized to the C-D band of mouse chromosome 9, the proximal end of q24.1 of rat chromosome 8, and qa4–qa5 of Syrian hamster chromosome 12. The regions in the mouse and rat were homologous to human chromosome 11q. Fine genetic linkage mapping of the mouse AT region was performed using the interspecific backcross mice.Atm, Acat1,andNpat,which is a new gene isolated from the AT region, and 12 flanking microsatellite DNA markers were examined. No recombinations were found among theAtm, Npat, Acat1,andD9Mit6loci, and these loci were mapped 2.0 cM distal toD9Mit99and 1.3 cM proximal toD9Mit102.Comparison of the linkage map of mouse chromosome 9 (MMU9) and that of human chromosome 11 (HSA11) indicates that there is a chromosomal rearrangement due to an inversion betweenEts1andAtm–Npat–Acat1and that the inversion of MMU9 originated from the chromosomal breakage at the boundary betweenGria4andAtm–Npat–Acat1on HSA11. This type of inversion appeared to be conserved in the three rodent species, mouse, rat, and Syrian hamster, using additional comparative mapping data with theRckgene.     

Differential expression and function of ABCG1 and ABCG4 during development and aging

ABCG1 and ABCG4 are highly homologous members of the ATP binding cassette (ABC) transporter family that regulate cellular cholesterol homeostasis. In adult mice, ABCG1 is known to be expressed in numerous cell types and tissues, whereas ABCG4 expression is limited to the central nervous system (CNS). Here, we show significant differences in expression of these two transporters during development. Examination of β-galactosidase-stained tissue sections from Abcg1^−/−LacZ and Abcg4^−/−LacZ knockin mice shows that ABCG4 is highly but transiently expressed both in hematopoietic cells and in enterocytes during development. In contrast, ABCG1 is expressed in macrophages and in endothelial cells of both embryonic and adult liver. We also show that ABCG1 and ABCG4 are both expressed as early as E12.5 in the embryonic eye and developing CNS. Loss of both ABCG1 and ABCG4 results in accumulation in the retina and/or brain of oxysterols, in altered expression of liver X receptor and sterol-regulatory element binding protein-2 target genes, and in a stress response gene. Finally, behavioral tests show that Abcg4^−/− mice have a general deficit in associative fear memory. Together, these data indicate that loss of ABCG1 and/or ABCG4 from the CNS results in changes in metabolic pathways and in behavior.     

A genetic study of tolerance and resistance to colicin A inCitrobacter freundii

Colicin A-insensitive mutants ofCitrobacter freundii were isolated and grouped into six phenotypic classes characterized by sensitivity, insensitivity or partial insensitivity to the bacteriocins S6, DF 13 and colicin A, and sensitivity or insensitivity to deoxycholate (DOC) and ampicillin. Mapping by the gradient-of-transmission method revealed the chromosomal regions in which the responsible genes are situated. Res-3 mapped nearpur betweenpur andthr; Tol-5 mapped betweenaro andilv and Tol-4 betweengal andpyr; Tol-1, Tol-2 and Tol-3 are situated close togal. All the mutations that mapped neargal rendered the bacteria more sensitive to DOC and ampicillin. Complementation analysis withE. coli plasmids showed that the three phenotypic groups that map neargal were complemented byE. coli plasmids and fall into three complementation groups. Two of these are equivalent with thetol A andtol B genes inE. coli.     

Evidence for interspecific transfer of the transposable element mariner betweenDrosophila andZaprionus

Summary The transposable element mariner occurs widely in themelanogaster species group ofDrosophila. However, in drosophilids outside of themelanogaster species group, sequences showing strong DNA hybridization with mariner are found only in the genusZaprionus. the mariner sequence obtained fromZaprionus tuberculatus is 97% identical with that fromDrosophila mauritiana, a member of themelanogaster species subgroup, whereas a mariner sequence isolated fromDrosophila tsacasi is only 92% identical with that fromD. mauritiana. BecauseD. tsacasi is much more closely related toD. mauritiana than isZaprionus, the presence of mariner inZaprionus may result from horizontal transfer. In order to confirm lack of a close phylogenetic relationship between the genusZaprionus and themelanogaster species group, we compared the alcohol dehydrogenase (Adh) sequences among these species. The results show that the coding region of Adh is only 82% identical betweenZ. tuberculatus andD. mauritiana, as compared with 90% identical betweenD. tsacasi andD. mauritiana. Furthermore, the mariner gene phylogeny obtained by maximum likelihood and maximum parsimony analyses is discordant with the species phylogeny estimated by using the Adh genes. The only inconsistency in the mariner gene phylogeny is in the placement of theZaprionus mariner sequence, which clusters with mariner fromDrosophila teissieri andDrosophila yakuba in themelanogaster species subgroup. These results strongly suggest horizontal transfer.     

Noggin Expression in the Adult Retina Suggests a Conserved Role during Vertebrate Evolution

Vertebrates share common mechanisms in the control of development and in the maintenance of neural and retinal function. The secreted factor Noggin, a BMP inhibitor, plays a crucial role in neural induction during embryonic development. Moreover, we have shown its involvement in retinal differentiation of pluripotent cells. Here we show Noggin expression in the adult retina in three vertebrate species. Four Noggin genes are present in zebrafish (Danio rerio; ZbNog1, 2, 3, 5), three in frog (Xenopus laevis; XenNog1, 2 and 4), and one in mouse (Mus musculus; mNog). Quantitative RT-PCR experiments show the presence of ZbNog3 and ZbNog5 mRNAs, but not ZbNog1 and ZbNog2, in the adult zebrafish retina. All three genes are expressed in the frog retina, and mNog in the mouse. Immunohistochemistry data show that Noggin proteins are predominantly localized in the Golgi apparatus of photoreceptors and in the fibers of the outer plexiform layer. Lower expression levels are also found in inner plexiform layer fibers, in ganglion cells, in the ciliary marginal zone, and in retinal pigmented epithelium. Our results show that Noggin has a specific cellular and sub-cellular expression in the adult vertebrate retina, which is conserved during evolution. In addition to its established role during embryonic development, we postulate that Noggin also exerts a functional role in the adult retina.