Two Drosophila learning mutants, dunce and rutabaga, provide evidence of a maternal role for cAMP on embryogenesis

The dunce gene of Drosophila melanogaster encodes a cAMP-specific phosphodiesterase (form II). Mutant dunce flies have elevated levels of cAMP and exhibit a number of defects including learning deficiencies and female sterility. Two partial suppressors of the female sterility phenotype have been selected in an X chromosome containing a dunce null mutation. Both suppressors are associated with reduced AC2 activity. Complementation analyses suggest that both are alleles of the learning mutant rutabaga. Females homozygous for dunce null mutations that abolish PDE activity do not deposit eggs. The suppressors exhibit differential effects on egg deposition and production of progeny; double-mutant females deposit many eggs that fail to hatch, but some develop to adults. These adult progeny exhibit morphological defects that are confined mostly to the second and third thoracic segments or to the first five abdominal segments. These observations demonstrate that the dunce gene is required in adult females for egg laying and that the dunce gene provides an essential maternal function required for normal development of the zygote. Clonal analysis, employing the dominant female-sterile mutation ovoD1, demonstrates that the former requirement for PDE activity resides in somatic cells and that the latter requirement resides in germ line cells. Female germ line cells homozygous for a dunce null mutation produce oocytes that fail to develop. Thus, homozygous dunce null-mutant zygotes develop to adults solely because of the enzyme or mRNA present in the oocytes of heterozygous mothers. Mutant alleles of rutabaga act in the germ line cells to partially suppress the developmental defects caused by dunce mutations. Thus the rutabaga gene, as well as the dunce gene, functions in both somatic and germ line cells.     

Gprk2 controls cAMP levels in Drosophila development

G protein-coupled receptors mediate their biological responses through the generation of second messengers, such as cAMP. The down-regulation of their activity (desensitization) is carried out, in part, by the family of G protein-coupled receptor kinases, which phosphorylate activated receptors. The Gprk2 gene in Drosophila melanogaster is a putative member of this family. The GPRK2 protein is expressed most abundantly in the ovaries and in the mushroom bodies, the brain region that is implicated in learning and memory in insects. Many of the genes that are involved in learning in Drosophila are members of a cAMP-signaling pathway and are also expressed in the mushroom bodies. These observations suggest that the Gprk2 gene may be involved in a cAMP-mediated pathway. To investigate this possibility, we tested for a genetic interaction between Gprk2 and dunce (which encodes cAMP-specific phosphodiesterase). A mutant allele of Gprk2, called gprk2(6936), has decreased fertility as a result of reduced levels of egg laying and hatching, and developing egg chambers display defects in the formation of anterior structures. Similarly, many alleles of dunce are sterile, with an ovary phenotype that resembles gprk2(6936). Introduction of a single copy of a hypomorphic or null allele of dunce into the gprk2(6936) background suppressed all of these defects to a significant degree. Suppression was also observed when a single copy of gprk2(6936) was introduced into a dunce background. Like mutants of rutabaga (which encodes a calcium/calmodulin-dependent adenylate cyclase), gprk2(6936) has reduced levels of cAMP. Ovaries from gprk2(6936) females contain about one third of the normal amount of cAMP. In addition, in every mutant combination where fertility is increased, cAMP levels are closer to wild type levels. These results suggest that Gprk2 is functioning in a cAMP-signaling pathway and that the underlying basis of the interaction between Gprk2 and dunce is a normalization of cAMP levels.     

A ribosomal protein is encoded in the chloroplast DNA in a lower plant but in the nucleus in angiosperms. Isolation of the spinach L21 protein and cDNA clone with transit and an unusual repeat sequence

The distribution of chloroplast ribosomal protein genes between the organelle DNA and the nuclear DNA is highly conserved in land plants, but a notable exception is rpl21. This gene has been found in the completely sequenced chloroplast genome of a lower plant but not in that of two higher plants. We describe the purification and characterization of the spinach chloroplast ribosomal protein L21 and the isolation and nucleotide sequence of a cDNA clone that encodes its cytoplasmic precursor. The mature protein, identified by NH2-terminal sequencing, has 201 residues (Mr 22,766) and is thus substantially larger than either its Escherichia coli (103 residues) or the lower plant homologue (116 residues). The extra length is in peptide extensions at both amino and carboxyl termini. The COOH-terminal extension is unusual in that it comprises seven Ala-Glu repeats, a feature not found in any other ribosomal proteins described so far. The cDNA clone also encodes a 55-residue long transit peptide (with a high proportion of the polar residues, threonine and serine), to target the L21 protein into chloroplasts. The identification of rpl21 as a nuclear gene in a higher plant (spinach) and chloroplast gene in a lower plant (liverwort) suggests an organelle-to-nucleus gene relocation during the evolution of the former.     

The Drosophila dunce locus: learning and memory genes in the fly.

The dunce gene, one of several genes critical for normal learning and memory in Drosophila, is organized in a complex and bizarre way, with enormous introns containing several other unrelated genes. Recent studies have focused on the spatial expression pattern of the product, cAMP phosphodiesterase, and have provisionally identified the mushroom bodies as important sites of action of dunce within adult brain. In addition, the recent cloning and characterization of dunce counterparts from mammals has revealed that these too may participate in animal behavior and, in particular, in the regulation of mood.     

Sexual Hyperactivity and Reduced Longevity of dunce Females of Drosophila melanogaster

The dunce gene of Drosophila melanogaster codes for a cyclic adenosine-3',5'-monophosphate-specific phosphodiesterase. Mutations of dunce alter or abolish the activity of this enzyme, produce elevated cAMP levels, cause recessive female sterility, and produce learning deficiencies in both sexes. Aberrant male sexual behavior has also been associated with the memory defects of dunce mutants. Here we show that the longevity of dunce mutant females, homozygous for null-enzyme alleles, is reduced by 50% in the presence of males compared to control dunce females kept without males. Mutant dunce females, mate every 22-24 hr. We propose a cause-effect relationship between mating and reduced longevity. Pheromones or peptides transferred during mating may activate adenylate cyclase and create an increase in cAMP levels that cannot be damped in dunce females. This increase may affect basic physiological functions and lead to reduced longevity.     

Isolation of the Drosophila melanogaster dunce chromosomal region and recombinational mapping of dunce sequences with restriction site polymorphisms as genetic markers.

Using the method of chromosomal walking, we have isolated a contiguous region of the Drosophila melanogaster X chromosome which corresponds to salivary gland chromosome bands 3C12 to 3D4. This five-band region contains approximately 100 kilobases of DNA, including those sequences comprising dunce, a gene which functions in memory and cyclic nucleotide metabolism. Genome blots of DNA from flies carrying several different chromosomal aberrations with breakpoints in the region have been probed with the isolated clones to map the breakpoints on the cloned DNA and to delimit dunce sequences. This has localized dunce to a 50-kilobase region. In addition, we have searched this 50-kilobase region for restriction site polymorphisms between X chromosomes from different Drosophila strains by genome blotting experiments, and we have followed the segregation of detected polymorphisms and dunce alleles after meiotic recombination. The data map one dunce mutation between two polymorphisms located 10 to 12 kilobases apart.     

Structure and expression of a human gene coding for a 71 kd heat shock ''cognate'' protein.

In all eukaryotes examined so far, hsp70 gene families include cognate genes (hsc70) encoding proteins of about 70 Kd which are expressed constitutively during normal growth and development. We have investigated the structural relationship of heat-inducible and cognate members of the human hsp70 gene family. Among several human genomic clones isolated using Drosophila hsp/hsc70 probes, one contained an hsc70 gene. Its complete sequence is reported here. It is split by eight introns and encodes a predicted protein of 70899 d that would be 81% homologous to hsp70. Structural comparisons with corresponding genes from other species provide one of the most striking examples of gene conservation. Isolation of a corresponding cDNA clone, RNA-mapping and in vitro translation data demonstrate that the gene is expressed constitutively and directs the synthesis of a 71 kd protein. The latter is very likely to be identical to a clathrin uncoating ATPase recently identified as a member of the hsp70-like protein family.     

A new periplasmic protein of Escherichia coli which is synthesized in spheroplasts but not in intact cells.

The gene spy from Escherichia coli has been cloned and sequenced. It encodes a precursor of a so far unknown 139-residue, rather basic periplasmic protein. It was not detectable immunologically in intact cells but was produced abundantly in spheroplasts. It could be a stress protein specific for spheroplasting.     

Dunce mutants of Drosophila melanogaster: mutants defective in the cyclic AMP phosphodiesterase enzyme system

The cyclic AMP and cyclic GMP phosphodiesterase activities present in flies of six mutant strains of the dunce gene and in the parent wild-type strains are characterized. All of the mutants exhibit aberrant cyclic AMP metabolism. The mutant strains dunceM14, dunceM11, and dunceML appear to be amorphic, because they completely lack the cAMP-specific phosphodiesterase normally present in adult flies. These strains exhibit extremely high levels of cAMP. The mutant strains dunce1, dunce2, and dunceCK are hypomorphic and exhibit reduced levels of the cAMP-specific phosphodiesterase. These strains exhibit less marked increases in cAMP content compared with the three amorphic strains. The dunce2 strain possesses a residual enzyme activity that exhibits anomalous kinetics compared with those of the normal enzyme. The possibility that the dunce locus is the structural gene for the cAMP-specific phosphodiesterase is discussed.     

Molecular cloning and expression of a Tetrahymena pyriformis ubiquitin fusion gene coding for a 53-amino-acid extension protein.

Summary The genome of Tetrahymena pyriformis has been shown to contain a ubiquitin multigene family consisting of several polyubiquitin genes and at least one ubiquitin fusion gene. We report here the isolation and characterization of one genomic clone (pTUl1), that encodes a ubiquitin extension protein. A comparison of the predicted amino acid sequence of the ubiquitin extension protein gene of T. pyriformis with those from other organisms indicated a high degree of homology. However, the Tetrahymena ubiquitin extension protein contains 53 and not 52 amino acids. This feature is different from all ubiquitin 52-amino-acid extension protein genes thus far sequenced. Furthermore, we found an array of four cysteine residues similar to those found in nucleic acid binding proteins. Also, the C-terminal sequence possesses a conserved motif which may represent a nuclear translocation signal. The ubiquitin 53-amino-acid extension protein gene encodes the smallest class of ubiquitin mRNAs in T. pyriformis.     

Levels of RNA from a family of putative serine protease genes are reduced in Drosophila melanogaster dunce mutants and are regulated by cyclic AMP.

We have isolated several genes expressed at abnormal levels in the memory mutant, dunce (dnc), of Drosophila melanogaster. These mutants have an elevated cyclic AMP (cAMP) content due to a mutation in the structural gene for cAMP phosphodiesterase, so the isolated genes are potentially ones regulated by cAMP. Here, we describe the characterization of a genomic clone and corresponding cDNA clones which contain sequences that are underexpressed in dnc mutants. Sequence analysis of portions of the genomic clone and representative cDNAs revealed the presence of two uninterrupted and complete open reading frames (SER1 and SER2) and part of a third (SER3). The predicted amino acid sequences of all of these were found to be homologous to the serine protease family of enzymes. The genomic clone was localized to the polytene chromosome region 99C-D, although genome-blotting experiments indicated the existence of several other genes related to the cloned serine protease-like genes. Hybridization experiments with probes representing each of the three sequenced genes showed that only the SER1-related genes were differentially expressed in dnc mutants. The putative serine protease genes were abundantly expressed in the larval gut, suggesting a major function in digestion. Feeding normal flies cAMP, isobutylmethylxanthine, or forskolin resulted in a decreased RNA level of the SER1-related genes. Thus, RNA levels of this serine protease gene family are negatively regulated by cAMP.     

Molecular characterization and expression of a tobacco histone H1 cDNA

We have isolated a 1104 bp tobacco cDNA clone (H1c12) which includes an 846 bp open reading frame. This encodes a polypeptide of 282 amino acid residues and represents the largest plant H1 histone identified so far. The structure of the deduced protein shows the classical tripartite organization of the H1-type linker histones. The expression of the tobacco H1 histone gene(s) corresponding to the H1c12 cDNA clone was examined during different developmental stages. We found that, at the level of steadystate mRNA, expression of gene(s) encoding this H1 histone was rapidly induced in germinating seeds. The H1 gene was expressed in all tissues examined. However, its expression was higher in tissues known to contain meristematic cells. Furthermore, in the leaves of mature plants accumulation of the H1 mRNA exhibits a very characteristic oscillation. This latter finding indicates that, at least in fully developed plants, the expression of this type of H1 histone gene(s) is modulated by a diurnal cycle.