Isolation and characterization of cloned DNA sequences containing ribosomal protein genes of Drosophila melanogaster

Picking Winners and Losers: Cell Competition in Tissue Development and Homeostasis

Viable cells with reduced fitness are often eliminated by neighboring cells with greater fitness. This phenomenon, called cell competition, is an important mechanism for maintaining a high-quality population of cells in tissues. Foundational studies characterizing cellular competition and its molecular underpinnings were first carried out utilizing Drosophila as a model system. More recently, competitive behavior studies have extended into mammalian cell types. In this review, we highlight recent advances in the field, focusing on new insights into the molecular mechanisms regulating competitive behavior in various cellular contexts and in cancer. Throughout the review, we highlight new avenues to expand our understanding of the molecular underpinnings of cell competition and its role in tissue development and homeostasis.

Expression of beta-lactamase by recombinant Escherichia coli strains containing plasmids of different sizes--effects of pH, phosphate, and dissolved oxygen

The characteristics of growth and synthesis of plasmid-encoded protein were studied for strains of recombinant E. coli JM103 which carried the beta-lactamase gene on plasmids of different sizes. The plasmids used included the vector pUC8 and its recombinant derivatives containing varying-sized inserts of Drosophila DNA (not expressed in E. coli). Luria broth (LB) and a minimal medium (M9) supplemented in some cases with additional inorganic phosphate were used as growth media. There was no evidence of segregational instability in these experiments, where no antibiotic selection pressure was employed. Responses of the recombinant strains to variations in environmental parameters including pH, phosphate concentration in the medium, and aeration rate were examined. While the cell growth rate in LB decreased with pH in the range 7.0-8.0, the bulk beta-lactamase activity was maximized at an intermediate pH. The recombinant cell growth rate decreases with increasing plasmid size in the minimal medium, while such decrease is not significant when a rich medium such as LB is used. There is an intermediate plasmid size in the range studied (2.7-8.7 kb), at which beta-lactamase activity is maximum. While reduction in aeration rate (which determines the dissolved oxygen level) is detrimental for cell growth, it is beneficial for beta-lactamase synthesis. The bulk beta-lactamase activity therefore exhibits a maximum with respect to aeration rate. Cell growth and beta-lactamase production are affected in a similar manner by phosphate concentration in the minimal medium and therefore both are maximized at the same phosphate concentration. This investigation demonstrates clearly how the production of a recombinant plasmid-encoded protein can be maximized by proper manipulation of culture conditions and how it is affected by plasmid size.

Cloning of the Drosophila melanogaster meiotic recombination gene mei-218: a genetic and molecular analysis of interval 15E

The mei-218 gene product is required for both meiotic crossing over and for the production of recombination modules, suggesting that these organelles are required for meiotic exchange. In this study the null phenotype of mei-218 was defined through the analysis of three preexisting and five new alleles. Consistent with previous studies, in homozygous mei-218 mutants meiotic crossing over is reduced to < 10% of normal levels. A molecular analysis of mei-218 was initiated with the isolation and mapping of lethal mutations and genome rearrangements in the region containing mei-218, polytene interval 15E on the X chromosome. This high resolution genetic map was aligned with a physical map constructed from cosmid and P1 clones by genetically mapping restriction fragment length polymorphisms and localizing rearrangement breakpoints. Within a region of 65 kb, we have identified seven transcription units, including mei-218 and the Minute(1)15D gene, which encodes ribosomal protein S5. The mei-218 mutant phenotype has been rescued by germline transformation with both a genomic fragment and a cDNA under the control of the hsp83 promoter. The mei-218 gene is predicted to produce an 1186-amino acid protein that has no significant similarities to any known proteins.

A newly identified Minute locus, M(2)32D, encodes the ribosomal protein L9 in Drosophila melanogaster

A gene encoding a ubiquitously expressed mRNA in Drosophila melanogaster was isolated and identified as the gene for ribosomal protein L9 (rpL9) by its extensive sequence homology to the corresponding gene from rat. The rpL9 gene is localized in polytene region 32D where two independent P element insertions flanking the locus are available. Remobilization of either P element generated lines with a typical Minute phenotype, e.g. thin and short bristles, prolonged development, and female semisterility in heterozygotes as well as homozygous lethality. All these characteristics can be rescued when a 3.9 kb restriction fragment containing the rpL9 gene is reintroduced by P element-mediated germline transformation. This result confirms that M(2)32D codes for ribosomal protein L9.

The intron-containing ribosomal protein-encoding genes L5, L7a and L37a are unlinked in chicken

Chicken ribosomal protein (rp)-encoding genes are currently being studied at the nucleotide level and three independent recombinant phages have been isolated from chicken genomic libraries using cloned cDNA probes. Each of these was shown to include an intron-containing rp gene of chicken (L5, L7a, L37a). In this study the chromosomal location of these three intron-containing rp from the large subunit of the chicken ribosome was determined by fluorescence in situ hybridization. L7a mapped to a microchromosome, whereas L5 and L37a mapped to macrochromosomes 8 and 7, respectively. The results demonstrate that these functionally related genes are widely dispersed in the genome. Furthermore, as in the case of many other evolutionarily advanced eukaryotes, there is no apparent linkage of rp and rRNA genes.

Drosophila ribosomal protein L18a: cDNA sequence, expression and chromosomal localization of the gene

We describe the cDNA sequence of the Drosophila homologue of the rat ribosomal protein L18a. The protein sequence predicted has identical or conservatively substituted amino acids in 80% of positions. It is distinctly basic in character with an overall net positive charge of + 20. Analysis of L18a RNA with the Northern blot technique shows it to be expressed both during embryonic development and in the adult fly. In situ hybridisation to polytene chromosomes reveals that the L18a gene(s) is located at 54B on the second chromosome.

A Drosophila third chromosome Minute locus encodes a ribosomal protein

Minutes (M) are a group of over 50 phenotypically similar Drosophila mutations widely believed to affect ribosomal protein genes. This report describes the characterization of the P element-induced M(3)95A(Plac92) mutation [allelic to M(3)95A]. This mutation can be reversed by the mobilization of the P element, demonstrating that the mutation is caused by insertion of this transposable element. The gene interrupted by insertion of the P element was cloned by use of inverse polymerase chain reaction. Nucleotide sequence analysis revealed a 70-75% identity to the human and rat ribosomal protein S3 genes, and to the Xenopus ribosomal protein S1a gene. At the amino acid level, the overall identity is approximately 78% for all three species. This is only the second time that a Minute has been demonstrated to encode a ribosomal protein.

The Drosophila melanogaster homolog of ribosomal protein S18

The sequence of the cDNA encoding the Drosophila melanogaster homolog of the human and rat small-subunit ribosomal protein, S18 (rpS18), is presented. The deduced 152-amino-acid (aa) sequence exhibits 76% identity to that of the human and rat rpS18 (152 aa), and is, like them, a member of the larger rpS13 family which includes archaebacterial, eubacterial and plant mitochondrial (mt) rpS13. The D. melanogaster rpS18 gene is single copy and maps at 56F, a chromosome region encompassing a previously characterised Minute locus, M(2)56F. The rpS18 gene gives rise to a single 700-nucleotide transcript present throughout development. A comparison of the rpS13 family members suggests that conservation is greatest at the N- and C-termini, whilst additional insertions are present in the Drosophila, mammalian and archaebacterial proteins relative to the eubacterial and plant mt proteins.

A member of the Notch group of interacting loci, deltex encodes a cytoplasmic basic protein

Prior genetic studies have suggested a functional relationship between the product of the deltex gene and those of three of the so-called "neurogenic" loci, Notch, Delta and mastermind. To gain further insight into this relationship, we have proceeded with a molecular characterization of deltex. We report that deltex encodes a maternally and zygotically expressed transcript that conceptually translates to a basic protein of novel sequence. Immunolocalization of the protein reveals an apparently ubiquitous distribution in embryonic and imaginal tissues. Because our detection methods also reveal a very low level of protein accumulation within the cytoplasm of cells, we have used transgenic flies to confirm this observation by ectopically expressing deltex under the control of a heat shock gene promoter. The resulting overexpression rescues deltex mutant defects but does not produce any obvious phenotypic abnormalities in otherwise wild-type flies. Finally, we examine genetically several Supressor of deltex mutations for evidence of functional integration with deltex and other neurogenic genes. We demonstrate that in addition to suppressing all adult morphological defects of deltex alleles, these suppressors also are capable of suppressing most synergistic effects involving deltex and Notch, Delta and mastermind.

Sequence and expression of a gene encoding a ribosomal protein S4 homolog from Drosophila melanogaster

We describe a Drosophila melanogaster cDNA clone encoding an amino acid (aa) sequence 75% identical to human ribosomal protein S4 (RPS4). The D. melanogaster RPS4 has 260 aa, if the NH2-terminal methionine is removed after translation of the mRNA. The mRNA for the protein is about 1 kb in length and is detected throughout the developmental stages tested (i.e., embryo, larva, pupa and adult). The cDNA clone hybridizes to two sites on the X chromosome, 1B1-2 and 3A3-6.

The Drosophila stubarista phenotype is associated with a dosage effect of the putative ribosome-associated protein D-p40 on spineless

We describe the molecular characterization of the Drosophila melanogaster gene stubarista (sta) that encodes the highly conserved putative ribosome-associated protein D-p40. sta maps to cytological position 2A3-B2 on the X chromosome and encodes a protein (D-p40) of 270 amino acids. D-p40 shares 63% identity with the human p40 ribosomal protein. P element-mediated transformation of a 4.4-kb genomic fragment encompassing the 1-kb transcript corresponding to D-p40 was used to rescue both a lethal (sta2) and a viable (sta1) mutation at the stubarista (sta) locus. Developmental analysis of the sta2 mutation implicates a requirement for D-p40 during oogenesis and imaginal development, which is consistent with the expression of sta throughout development. In addition, we have analyzed the basis of the sta1 visible phenotype which consists of shortened antennae and bristles. sta1 is a translocation of the 1E1-2 to 2B3-4 region of the X chromosome onto the third chromosome at 89B21-C4. We provide genetic evidence that Dp(1;3)sta1 is mutant at the spineless (ss) locus and that it is associated with partial D-p40 activity. We demonstrate that sta1 acts as a recessive enhancer of ss; reduction in the amount of D-p40 provided by the transposed X chromosomal region of sta1 reveals a haplo-insufficient phenotype of the otherwise recessive ss mutations. This phenomenon is reminiscent of the enhancing effect observed with Minute mutations, one of which, rp49, has previously been shown to encode a ribosomal protein.

A Minute encoding a ribosomal protein enhances wing morphogenesis mutants

E(Dl)KP135 has been isolated previously as a recessive lethal Drosophila P element insertion line with a dominant enhancing effect on the phenotype of Delta, a gene encoding a surface membrane protein. We show here that this P insertion also enhances the wing phenotype of nd1, an allele of Notch encoding another transmembrane protein, the putative receptor of Delta, as well as that of if3, an allele of the integrin gene PS2 alpha. Moreover, we noticed that this P insertion causes a severe Minute phenotype. Molecular characterisation revealed that the P element disrupts the putative mRNA leader sequence of the ribosomal protein L19 gene. We tested further Minute genes and found that two of them, similarly to E(Dl)KP135, strongly enhance the nd1 wing phenotype. Our results suggest that the pleiotropic Minute syndrome can affect, probably indirectly, one or more steps of wing morphogenesis that involve surface adhesion of epithelial cells.

Ribosomal protein S14 is not responsible for the Minute phenotype associated with the M(1)7C locus in Drosophila melanogaster

A locus associated with a severe Minute effect has been mapped at 7C on the X chromosome of Drosophila melanogaster. Previous work has suggested that this Minute encodes ribosomal proteins S14A and S14B. We have made a chromosomal deficiency that removes the S14 ribosomal protein genes, yet does not display the Minute phenotype. These data suggest that the S14 genes do not actually correspond to the Minute locus.

A small gene family in barley encodes ribosomal proteins homologous to yeast YL17 and L22 from archaebacteria, eubacteria, and chloroplasts

The amino acid sequences of two barley ribosomal proteins, termed HvL17-1 and HvL17-2, were decoded from green leaf cDNA clones. The N-terminal sequences of the derived barley proteins are 48% identical to the N-terminal amino acid sequence of protein YL17 from the large subunit of yeast cytoplasmic ribosomes. Via archaebacterial ribosomal proteins this homology extends to ribosomal protein L22 from eubacteria and chloroplast. Barley L17, and ribosomal proteins L22 and L23 from the archaebacteria Halobacterium halobium and H. marismortui, are 25-33% identical. Interestingly, the barley and archaebacterial proteins share a long, central stretch of amino acids, which is absent in the corresponding proteins from eubacteria and chloroplasts. Barley L17 proteins are encoded by a small gene family with probably only two members, represented by the cDNA clones encoding HvL17-1 and HvL17-2. Both these genes are active in green leaf cells. The expression of the L17 genes in different parts of the 7-day old barley seedlings was analyzed by semiquantitative hybridization. The level of L17 mRNA is high in meristematic and young cells found in the leaf base and root tip. In the leaf, the L17 mRNA level rapidly decreases with increasing cell age, and in older root cells this mRNA is undetectable.

Characterization of a novel Minute-locus in Drosophila melanogaster: a putative ribosomal protein gene

We describe a novel Minute locus, M(1)7C, on the X-chromosome of Drosophila melanogaster. Heterozygous deficient females have most, if not all, of the Minute features (short and fine bristles, rough and somewhat larger eyes, thin-textured wings, missing aristae, affected antennae, delayed development, reduced fertility, and decreased viability). Both Minute and non-Minute adult progeny from Minute mothers suffer from Minute maternal effects such as abdominal segmentation defects, fused tergites, and missing or defective legs and halteres. Using a plasmid clone from region 7C5-9, which harbours the D. melanogaster ribosomal protein gene RPS14, we have found that the accumulation of a single transcript of approximately 650 b is extremely reduced in Minute larvae in comparison with wild-type. We have localized the RPS14 gene to approximately 28 kbp distal from the singed locus. The results suggest that M(1)7C and RPS14 may be the same gene.

Molecular and genetic organization of the suppressor of sable and minute (1) 1B region in Drosophila melanogaster

Recessive mutations at the suppressor of sable [su(s)] locus in Drosophila melanogaster result in suppression of second site mutations caused by insertions of the mobile element 412. In order to determine whether su(s) mutations might have other phenotypes, a saturation mapping of the su(s) region was carried out. The screen yielded 76 mutations that comprise ten genetic complementation groups ordered distal to proximal as follows: l(1)1Bh, l(1)1Bi, M(1)1B, su(s), l(1)1Bk, l(1)1Ca, mul, tw, l(1)lDa and brc. Twenty-three of the mutations are su(s) alleles, and all are suppressors of the 412-insertion-caused v1 allele. Although the screen could have detected su(s) mutations causing sex-specific dominant lethality or sterility as well as all types of recessive lethality or sterility, the only other phenotype observed was male sterility that is enhanced by cold temperature. This type of sterility is exhibited only by alleles induced by base-substitution-causing mutagens. Genetic functions of the poly(A+) messages transcribed from the su(s) microregion were identified by the reintroduction of cloned sequences into embryos by P element transformation. su(s) function has been attributed to a 5-kb message. The segment of DNA encoding only this 5-kb message rescues both the suppression and cold-sensitive male sterility phenotypes of su(s). Minute (1) 1B has been provisionally identified as encoding a 3.5-kb message; lethal (1)1Bi encodes a 1-kb message; and lethal (1)1Bk encodes a 4-kb message. The possible functions of su(s) and M(1)1B are discussed.

Sequence analysis of a processed gene coding for mouse ribosomal protein L32

The nucleotide sequence of a mouse ribosomal protein gene, identified by hybridization with the gene encoding the Drosophila ribosomal (r-) protein 49, was determined by cloning in the phage M13 and dideoxy sequencing. The mouse gene, L32', is a member of the multigene family encoding mammalian r-protein L32. L32' is a processed gene that could encode a 135 amino acid protein similar to that of mouse L32 and Drosophila r-protein 49.

Identification and germline transformation of the ribosomal protein rp21 gene of Drosophila: complementation analysis with the Minute QIII locus reveals nonidentity

Minute loci represent a class of about 50 different Drosophila genes that appear to be functionally related. These genes may code for components of the protein synthetic apparatus. While one Minute locus has been recently shown to code for a ribosomal protein, it is not yet known whether any of the other Minute loci also code for ribosomal proteins. We have addressed this question by a combined molecular and genetic approach. In this report, a cloned DNA encoding the ribosomal protein rp21 is partially characterized. The rp21 gene maps to the same region (region 80 of chromosome 3L) as the temperature-sensitive Minute QIII gene. Using P-element mediated transformation, the rp21 gene was transformed into the germline of Drosophila. RNA blot experiments revealed that the transformed gene is expressed in transgenic flies. However, genetic complementation analysis indicated that the QIII locus and the rp21 gene are not identical. Implications of these findings for the relationship between Minutes and ribosomal protein genes are discussed.

Identification of cDNAs corresponding to mosquito ribosomal protein genes

Sequences encoding mosquito (Aedes albopictus) ribosomal proteins L8, L14 and L31 were identified from a cDNA library made from size-selected polyadenylated mRNA. Candidate cDNAs corresponding to moderately abundant mRNAs were screened by translation of hybrid-selected transcripts in wheat-germ lysates. Translation products were extracted with acetic acid and analyzed by electrophoresis in two dimensions in the presence of unlabeled ribosomal proteins. The identity of translation products that coelectrophoresed with purified ribosomal protein standards was supported by peptide mapping. The cDNAs corresponding to L8 (pL8) and L31 (pL31) hybridized to cytoplasmic mRNAs of 1.4 and 0.9 kb, respectively. In Southern blots of genomic DNA digested with BamHI, HindIII or EcoRI, the cDNA inserts from both pL8 and pL31 gave simple hybridization patterns suggestive of a low copy number for mosquito ribosomal protein genes.

Effects of recombinant plasmid size on cellular processes in Escherichia coli

The effects of recombinant plasmid size on cell growth and viability, plasmid copy number, and synthesis of plasmid-encoded protein were investigated in Escherichia coli using plasmid pUC8 and four recombinant derivatives containing inserts of Drosophila melanogaster DNA of 1.7-6.0 kb. Growth in log phase was unaffected by plasmid size, but as plasmid size increased, maximum cell density decreased and, with the largest plasmid, cell death was accelerated after the stationary phase was reached. There was also a correlation between increasing plasmid size and decreased viability at high ampicillin concentrations, resistance to which is conferred by the plasmids. These effects were shown not to be due to transcription or translation of Drosophila sequences carried on the recombinant plasmids. Cells harboring the largest plasmid, pBS5 (8.7 kb), fared poorly in competition with plasmid-free cells in mixed cultures, compared with cells harboring pUC8 (2.7 kb). In addition, pBS5 was harbored at significantly fewer copies per cell than pUC8 at all phases of growth and supported much less production of the plasmid-encoded protein, beta-lactamase, than did pUC8. The results suggest that recombinant plasmid size may be an important parameter in the optimization of large-scale production of plasmid-encoded proteins.

A Drosophila Minute gene encodes a ribosomal protein

Minute genes have long constituted a special problem in Drosophila genetics. For at least 50-60 different genes scattered throughout the genome, dominant mutations and/or deficiencies have been recognized which result in a common phenotype consisting of short thin bristles, slow development, reduced viability, rough eyes, small body size and etched tergites. Schultz proposed that the Minute loci encode similar but separate functions involved in growth and division common to all cells. Atwood and Ritossa suggested that Minute loci encode components of the protein synthetic machinery, specifically the transfer RNA genes; this now seems unlikely on grounds of both mapping and mutability studies. More recently, we and others suggested that the Minute loci are ribosomal protein genes. We report here that transformation with a cloned 3.3-kilobase (kb) region containing the gene encoding the large subunit ribosomal protein 49 (rp49) suppresses the dominant phenotypes of Minute (3)99D, a previously undescribed Minute associated with a chromosomal deficiency of the 99D interval. This activity is specific to the 99D Minute as it does not suppress other Minute loci elsewhere in the genome. This result provides direct evidence that the Minute locus at the 99D interval encodes the ribosomal protein 49.

Characterization of the ribosomal proteins from mosquito (Aedes albopictus) cells

Proteins from the large and small subunits of Aedes albopictus (mosquito) cytoplasmic ribosomes were characterized by two-dimensional polyacrylamide gel electrophoresis. The small subunit contained 28-31 proteins ranging in molecular mass from 10 to 49 kDa. The large subunit contained 36-39 proteins that ranged in molecular mass from 11 to 53 kDa. The largest protein on the small subunit, S1, was the predominant phosphorylated ribosomal protein. Under long-term labelling conditions, L4 and L33 were also phosphorylated. Peptide mapping by partial proteolysis indicated that Ae. albopictus S1 may share partial amino acid homology with the phosphorylated ribosomal protein S6 from Drosophila melanogaster. Unlike Drosophila S6, however, Aedes S1 was not dephosphorylated during heat shock. Treatment of mosquito cells with the insect molting hormone 20-hydroxyecdysone did not affect phosphorylation of ribosomal proteins.