A cis-acting element and associated binding factor required for CNS expression of the Drosophila melanogaster dopa decarboxylase gene.

A cis-acting sequence from the Drosophila melanogaster dopa decarboxylase (Ddc) gene is selectively required for Ddc expression in the central nervous system. We analyze several parameters influencing the function of the sequence element and describe a factor which interacts with it and mediates CNS expression of Ddc. The element, element I, can function in vivo when included on a synthetic oligonucleotide inserted near its normal location, or closer to the RNA startpoint. It displays partial activity when inverted. Two different 2-bp mutations in element I abolish its ability to stimulate neuronal Ddc expression in the CNS. A factor present in embryonic nuclear extracts specifically protects element I in DNase I footprinting assays. The binding affinity of this factor is reduced by each alteration of element I that inhibits neuronal expression, indicating a role in mediating CNS expression of Ddc. Element I alone has no detectable activity when placed adjacent to a heterologous promoter, although 2.2 kb of 5' Ddc sequences direct correct cell-specific expression of a heterologous promoter.     

The pleiohomeotic gene is required for maintaining expression of genes functioning in ventral appendage formation in Drosophila melanogaster

Polycomb group (PcG) proteins are negative regulators that maintain the expression of homeotic genes and affect cell proliferation. Pleiohomeotic (Pho) is a unique PcG member with a DNA-binding zinc finger motif and was proposed to recruit other PcG proteins to form a complex. The pho null mutants exhibited several mutant phenotypes such as the transformation of antennae to mesothoracic legs. We examined the effects of pho on the identification of ventral appendages and proximo-distal axis formation during postembryogenesis. In the antennal disc of the pho mutant, Antennapedia (Antp), which is a selector gene in determining leg identity, was ectopically expressed. The homothorax (hth), dachshund (dac) and Distal-less (Dll) genes involved in proximo-distal axis formation were also abnormally expressed in both the antennal and leg discs of the pho mutant. The engrailed (en) gene, which affects the formation of the anterior-posterior axis, was also misexpressed in the anterior compartment of antennal and leg discs. These mutant phenotypes were enhanced in the mutant background of Posterior sex combs (Psc) and pleiohomeotic-like (phol), which are another PcG genes. These results suggest that pho functions in maintaining expression of genes involved in the formation of ventral appendages and the proximo-distal axis.     

Cardiomyopathy is associated with ribosomal protein gene haplo-insufficiency in Drosophila melanogaster

The Minute syndrome in Drosophila melanogaster is characterized by delayed development, poor fertility, and short slender bristles. Many Minute loci correspond to disruptions of genes for cytoplasmic ribosomal proteins, and therefore the phenotype has been attributed to alterations in translational processes. Although protein translation is crucial for all cells in an organism, it is unclear why Minute mutations cause effects in specific tissues. To determine whether the heart is sensitive to haplo-insufficiency of genes encoding ribosomal proteins, we measured heart function of Minute mutants using optical coherence tomography. We found that cardiomyopathy is associated with the Minute syndrome caused by haplo-insufficiency of genes encoding cytoplasmic ribosomal proteins. While mutations of genes encoding non-Minute cytoplasmic ribosomal proteins are homozygous lethal, heterozygous deficiencies spanning these non-Minute genes did not cause a change in cardiac function. Deficiencies of genes for non-Minute mitochondrial ribosomal proteins also did not show abnormal cardiac function, with the exception of a heterozygous disruption of mRpS33. We demonstrate that cardiomyopathy is a common trait of the Minute syndrome caused by haplo-insufficiency of genes encoding cytoplasmic ribosomal proteins. In contrast, most cases of heterozygous deficiencies of genes encoding non-Minute ribosomal proteins have normal heart function in adult Drosophila.     

Solution structural studies of the Saccharomyces cerevisiae TATA binding protein (TBP)

The intrinsic fluorescence of the six tyrosines located within the C-terminal domain of the Saccharomyces cerevisiae TATA binding protein (TBP) and the single tryptophan located in the N-terminal domain has been used to separately probe the structural changes associated with each domain upon DNA binding or oligomerization of the protein. The unusually short-wavelength maximum of TBP fluorescence is shown to reflect the unusually high quantum yield of the tyrosine residues in TBP and not to result from unusual tryptophan fluorescence. The anisotropy of the C-terminal tyrosines is very high in monomeric, octameric, and DNA-complexed TBP and comparable to that observed in much larger proteins. The tyrosines have low accessibility to an external fluorescence quencher. The anisotropy of the single tryptophan located within the N-terminal domain of TBP is much lower than that of the tyrosines and is accessible to an external fluorescence quencher. Tyrosine, but not tryptophan, fluorescence is quenched upon TBP-DNA complex formation. Only the tryptophan fluorescence is shifted to longer wavelengths in the protein-DNA complex. In addition, the accessibility of the tryptophan residue to the external quencher and the internal motion of the tryptophan residue increase upon DNA binding by TBP. These results show the following: (i) The structure of the C-terminal domain structure is unchanged upon TBP oligomerization, in contrast to the N-terminal domain [Daugherty, M. A., Brenowitz, M., and Fried, M. G. (2000) Biochemistry 39, 4869-4880]. (ii) The environment of the tyrosine residues within the C-terminal domain of TBP is structurally rigid and unaffected by oligomerization or DNA binding. (iii) The C-terminal domain of TBP is uniformly in close proximity to bound DNA. (iv) While the N-terminal domain unfolds upon DNA binding by TBP, its increased correlation time shows that the overall structure of the protein is more rigid when complexed to DNA. A model that reconciles these results is proposed.     

Regulation of larval cuticle protein gene expression in Drosophila melanogaster

Genes that encode 3rd instar larval cuticle proteins (LCP's) of Drosophila melanogaster are located in at least two chromosomal sites. The genes encoding four of the five predominant LCP's are located in a cluster at the chromosomal region 44D. They are organized in pairs that are transcribed divergently, and expressed with different timing during the third larval instar. Towards understanding the basis of gene regulation within the 44D cluster, we have analyzed genetic variants, including the 2-3 variant, which has an insertion of a copia-like transposable element, H.M.S. Beagle, within the 44D cluster. The Beagle element appears to inactivate the LCP-3 gene by inserting into its TATA box, but also may cause the precocious expression of two other LCP genes, LCP-1 and LCP-f2, in the cluster. The long terminal repeat (LTR) of the Beagle element apparently contains a sequence, perhaps an enhancer-like element, which causes altered expression of these genes. We have also investigated the cis-regulatory elements involved in expression of the LCP-2 gene in wild-type larvae. We have identified two upstream regions that may contain separate cis-regulatory elements. The region between -252 bp and -515 bp may be essential for any expression of LCP-2. Additionally, the region between -515 bp and -795 bp appears to be required for the normal level of expression of the LCP-2 gene.