Drosophila Enhancer of Rudimentary Homolog, ERH, Is a Binding Partner of RPS3, RPL19, and DDIT4, Suggesting a Mechanism for the Nuclear Localization of ERH.

The protein enhancer of rudimentary homolog, ERH, is a small, highly conserved protein that has been found in animals, plants, and protists. Genetic and biochemical interactions have implicated ERH in the regulation of pyrimidine biosynthesis, DNA replication, transcription, mRNA splicing, cellular proliferation, tumorigenesis, and the Notch signaling pathway. In vertebrates and insects, ERH is nuclearly localized; however, an examination of the ERH amino-acid sequence does not reveal any nuclear localization signals. In this paper we show that the first 24 amino acids contain sequences necessary and sufficient for nuclear localization. Through yeast two-hybrid screens, three new binding partners of ERH, RPS3, RPL19, and DDIT4, were identified. RPS3 was isolated from both human and Drosophila screens. These interactions suggest functions of ERH in cell growth, cancer, and DNA repair. The ERH sequences necessary for the interactions between ERH and RPS3 and RPL19 are mapped onto the same 24-amino-acid region in ERH which are necessary for nuclear localization, suggesting that ERH is localizing to the nucleus through binding to one of its DNA-binding partners, such as RPS3 or RPL19.

Interactions between enhancer of rudimentary and Notch and deltex reveal a regulatory function of enhancer of rudimentary in the Notch signaling pathway in Drosophila melanogaster.

Enhancer of rudimentary, e(r), encodes a small nuclear protein, ER, that has been implicated in the regulation of pyrimidine metabolism, DNA replication, and cell proliferation. In Drosophila melanogaster, a new recessive Notch allele, N (nd-p) , was isolated as a lethal in combination with an e(r) allele, e(r) (p2) . Both mutants are viable as single mutants. N (nd-p) is caused by a P-element insertion in the 5' UTR, 378-bp upstream of the start of translation. Together the molecular and genetic data argue that N (nd-p) is a hypomorphic allele of N. The three viable notchoid alleles, N (nd-p) , N (nd-1) , and N (nd-3) , are lethal in combination with e(r) (-) alleles. Our present hypothesis is that e(r) is a positive regulator of the Notch signaling pathway and that the lethality of the N e(r) double mutants is caused by a reduction in the expression of the pathway. This is supported by the rescue of the lethality by a mutation in Hairless, a negative regulator of N, and by the synthetic lethality of dx e(r) double mutants. Further support for the hypothesis is a reduction in E(spl) expression in an e(r) (-) mutant. Immunostaining localizes ER to the nucleus, suggesting a nuclear function for ER. A role in the Notch signaling pathway, suggests that e(r) may be expressed in the nervous system. This turns out to be the case, as immunostaining of ER shows that ER is localized to the developing CNS.

The generation and analysis of deficiencies within a small genomic region on the X chromosome of Drosophila melanogaster containing two genes, enhancer of rudimentary and CG15352.

The enhancer of rudimentary gene, e(r), encodes a 104-amino-acid, highly conserved transcription cofactor. Hypomorphic mutations of e(r) show an enhancement of a hypomorphic rudimentary mutant wing phenotype. These mutants in a wild-type background are viable, fertile, and morphologically wild-type. Since the only mutant alleles were hypomorphic, it was important to isolate null mutations to determine if any other phenotypes might be associated with a loss-of-function of e(r). We utilized a marked P element, P{SUPor-P, y(+)}, located 895 bp upstream of the start of transcription of e(r) to generate nineteen deficiencies in the region. Deficiencies of e(r) enhance the mutant wing phenotype of a hypomorphic rudimentary allele, r(hd1). In a wild-type background, the deficiencies of e(r), unlike the hypomorphic alleles, have a low viability and females have low fertility. The expression of e(r) in the nurse cells of the ovary is consistent with the low fertility, and suggests an ovarian function for e(r). Deficiencies of CG15352, the gene directly upstream of e(r), are not associated with any obvious mutant phenotypes and present the possibility that it encodes a nonvital or redundant function.

Regulation of the Drosophila melanogaster protein, enhancer of rudimentary, by casein kinase II.

The Drosophila melanogaster gene enhancer of rudimentary, e(r), encodes a conserved protein, ER. Most ER homologs share two casein kinase II (CKII) target sites. In D. melanogaster, these sites are T18 and S24. A third CKII site, T63, has been seen only in drosophilids. The conservation of these CKII sites, particularly T18 and S24, suggests a role for these residues in the function of the protein. To test this hypothesis, these positions were mutated either to alanine as a nonphosphorylated mimic or to glutamic acid as a phosphorylated mimic. The mutations were tested individually or in double or triple combinations for their ability to rescue either a wing truncation characteristic of the genotype e(r)(p1) r(hd1-12) or the synthetic lethal interaction between e(r)(p2) and the Notch allele N(nd-p). All of the substitutions as single mutations rescued both mutant phenotypes, arguing that individually the phosphorylation of the three residues does not affect ER activity. The double mutants T18A-S24A and T18E-S24E and the triple mutants T18A-S24A-T63A and T18E-S24E-T63E failed to rescue. Together the data support the following model for the regulation of ER by CKII. ER that is unphosphorylated at both T18A and S24 is inactive. CKII activates ER by phosphorylating either T18 or S24. Further phosphorylation to produce the doubly phosphorylated protein inactivates ER.