Regulation of BMP and activin signaling in Drosophila.

Cytokines of the TGF-beta superfamily act through an evolutionarily conserved signaling pathway to elicit a diverse range of biological responses in vertebrates as well as invertebrates. Drosophila has proved to be a powerful system to unravel the profound complexities underlying the regulation of this superficially simple signaling system for two reasons--the availability of sophisticated genetic tools and the restricted number of core signaling components compared to vertebrates. A BMP signaling pathway in Drosophila that regulates growth, differentiation and morphogenesis of the embryo and the larva has been extensively characterized. This work has provided major insights into how gradients of secreted proteins can be established and maintained in vivo, allowing a single ligand to induce multiple cell fates rather than function as an on-off switch. More recently, an activin signaling pathway has also been delineated that is required for growth and neuronal function during development. This review provides an overview of TGF-beta signaling in Drosophila with emphasis on the extensive modulation of signaling activity both within and outside the cell, that enables ligands to trigger specific and context-dependent effects.

Genomic organization of human DLG4, the gene encoding postsynaptic density 95.

We have determined the exon-intron organization and characterized the 5'-flanking promoter region of DLG4. Encompassing approximately 30 kb, the DLG4 locus is composed of 22 exons that range in size from 28 to 1,218 nucleotides. All splice sites conform to the GT-AG rule, except for the splice acceptor site of intron 5, which is TG instead of AG. Three different exons of DLG4 were found to be alternatively spliced in a subset of tissues. Two of these variants result in altered postsynaptic density 95 (PSD95) isoforms that dramatically truncate the protein. The third splicing variant represents an extension of exon 4 that encodes an additional 33-amino acid segment. Analysis of the core promoter region for DLG4 suggests that the expression of this gene is controlled by a TATA-less promoter using a single transcriptional start site embedded within a CpG island. DLG4 maps to a region on chromosome 17p13.1 known to contain a locus for autosomal dominant cone dystrophy 5. Scanning for mutations in the DLG4 coding region and splice sites was performed in 15 cone dystrophy patients, including probands from five families showing linkage to the DLG4 region. No disease-causing mutations were identified in any patients, suggesting that DLG4 is not the causative gene for this genetic eye disorder.

Signaling pathways are focused at specialized regions of the plasma membrane by scaffolding proteins of the MAGUK family.

The MAGUKs (membrane-associated guanylate kinase homologs) are a family of proteins that act as molecular scaffolds for signaling pathway components at the plasma membrane of animal cells. They are localized in and required for the formation of several types of cell junctions, including epithelial tight and septate junctions as well as synaptic and neuromuscular junctions. They are also localized at the plasma membrane of other cell types, including erythrocytes, where they contribute to cell shape maintenance. MAGUKs function mainly by binding directly to the cytoplasmic termini of transmembrane proteins as well as to other signal transduction proteins. They appear to hold together elements of individual signaling pathways, thereby contributing to the efficiency and specificity of signaling interactions while simultaneously maintaining the structural specializations of the plasma membrane. BioEssays 1999;21:912-921.

The catecholamines up (Catsup) protein of Drosophila melanogaster functions as a negative regulator of tyrosine hydroxylase activity.

We report the genetic, phenotypic, and biochemical analyses of Catecholamines up (Catsup), a gene that encodes a negative regulator of tyrosine hydroxylase (TH) activity. Mutations within this locus are semidominant lethals of variable penetrance that result in three broad, overlapping effective lethal phases (ELPs), indicating that the Catsup gene product is essential throughout development. Mutants from each ELP exhibit either cuticle defects or catecholamine-related abnormalities, such as melanotic salivary glands or pseudotumors. Additionally, Catsup mutants have significantly elevated TH activity that may arise from a post-translational modification of the enzyme. The hyperactivation of TH in Catsup mutants results in abnormally high levels of catecholamines, which can account for the lethality, visible phenotypes, and female sterility observed in these mutants. We propose that Catsup is a component of a novel system that downregulates TH activity, making Catsup the fourth locus found within the Dopa decarboxylase (Ddc) gene cluster that functions in catecholamine metabolism.

DLG3, the gene encoding human neuroendocrine Dlg (NE-Dlg), is located within the 1.8-Mb dystonia-parkinsonism region at Xq13.1.

Neuroendocrine-Dlg (NE-Dlg) is a member of the discs-large-related (DLG) subfamily of the membrane-associated guanylate kinase-related protein family. Based on evidence from model systems, this protein appears to be critical for synaptogenesis, acting as a site-specific organizational center for integral membrane proteins and their downstream signaling molecules associated with the cytoskeleton. NE-Dlg also directly interacts with the colorectal tumor suppressor adenomatous polyposis coli, suggesting that it may play a role in regulating cell proliferation in epithelial cells. To explore the genetic control of NE-Dlg, we developed a physical map of the chromosome region containing DLG3, the locus encoding NE-Dlg. Using human-hamster radiation hybrid mapping panels, we mapped DLG3 to Xq13.1 and established a sequence-tagged site marker map of the surrounding region. We then developed a yeast artificial chromosome (YAC) contig for this region. Encompassing approximately 2.0 Mb contained within five overlapping YACs, this contig also includes the dystonia-parkinsonism syndrome (DYT3) locus. The close proximity of DLG3 to the DYT3 region suggests that the gene encoding NE-Dlg is a candidate locus for this neurological disorder.

Human postsynaptic density-95 (PSD95): location of the gene (DLG4) and possible function in nonneural as well as in neural tissues.

We have determined the cDNA sequence, expression pattern, and chromosomal location of the human gene DLG4, encoding the postsynaptic density-95 (PSD95) protein. hPSD95 is a 723-amino-acid protein that is 99% identical to its rodent counterparts. This is the fourth human protein identified as showing significant similarity to the Drosophila tumor suppressor Dlg. These proteins constitute the DLG subfamily of the membrane-associated guanylate kinase protein family. The expression of DLG4 in neural tissue is consistent with the pattern observed for its rat homolog. However, DLG4 is also expressed in a wide range of nonneural tissues, suggesting that the protein may have additional roles in humans. Using radiation-hybrid mapping panels, we mapped the DLG4 locus to 17p13.1, a region associated with several diseases, the phenotypes of which are consistent with loss of PSD95 function.

The genetic and molecular organization of the Dopa decarboxylase gene cluster of Drosophila melanogaster.

We report the complete molecular organization of the Dopa decarboxylase gene cluster. Mutagenesis screens recovered 77 new Df(2L)TW130 recessive lethal mutations. These new alleles combined with 263 previously isolated mutations in the cluster to define 18 essential genes. In addition, seven new deficiencies were isolated and characterized. Deficiency mapping, restriction fragment length polymorphism (RFLP) analysis and P-element-mediated germline transformation experiments determined the gene order for all 18 loci. Genomic and cDNA restriction endonuclease mapping, Northern blot analysis and DNA sequencing provided information on exact gene location, mRNA size and transcriptional direction for most of these loci. In addition, this analysis identified two transcription units that had not previously been identified by extensive mutagenesis screening. Most of the loci are contained within two dense subclusters. We discuss the effectiveness of mutagens and strategies used in our screens, the variable mutability of loci within the genome of Drosophila melanogaster, the cytological and molecular organization of the Ddc gene cluster, the validity of the one band-one gene hypothesis and a possible purpose for the clustering of genes in the Ddc region.

Characterization of Xenopus laevis gamma-crystallin-encoding genes.

In order to gain insight into crystallin (Cry)-encoding gene (cry) evolution and developmental function, we have determined the gene structure and sequence of several Xenopus laevis gamma-cry. These encode the most abundant Cry in the embryonic lens. Four of the X. laevis gamma-cry, which are part of a multigene family, were isolated from a X. laevis genomic library and demonstrated to have the same gene structure as gamma-cry from other vertebrates, thereby providing further evidence that the split between beta and gamma members of the beta gamma cry family occurred relatively early in evolution. Sequence comparisons indicate that these X. laevis genes share 88-90% nucleotide sequence identity in the protein coding regions, which is slightly higher than the identity observed between gamma-cry of other species. The 5' upstream regions of X. laevis gamma-cry contain a few short stretches of homology and one putative promoter element conserved among all cry genes but lack other regions common to gamma-cry promoters from other organisms. The deduced amino acid sequences of all four genes and one cDNA suggest that the structure of X. laevis gamma-Cry is highly conserved with that of other vertebrate gamma-Cry, as deduced from the known three-dimensional structure of bovine gamma B Cry.