Ligand-induced conformational changes in the human retinoic acid receptor detected using monoclonal antibodies.

The mechanism by which the naturally occurring ligand for a nuclear hormone receptor regulates transcription remains largely unknown. One approach combines the specificity of monoclonal antibodies, which recognize a three-dimensional epitope, with ligand binding. Using purified retinoic acid receptor gamma D and E domains, a panel of six unique monoclonal antibodies were isolated and characterized using solid-state receptor binding and retinoic acid receptor (RAR)-RXR heterodimer supershift formation. Three antibodies are specific for RARgamma (mAbI, mAbII, and mAbV) and four recognize a three-dimensional epitope (mAbI, mAbIV, mAbV, and mAbVI). Three antibodies (mAbIII, mAbV, and mAbVI) dissociate from the receptor in electrophoretic mobility shift assays upon the addition of retinoic acid. In particular, the binding characteristics of mAbIII, whose epitope was mapped to a region identified as an omega-loop (amino acids 207-222), suggest a model for ligand binding to the receptor. In this model, ligand binding causes a positioning of helix 12 into a favorable conformation for interaction with the transcriptional machinery. The Omega-loop then closes in order to stabilize this "active" position. The results reported here also suggest that a region of the hinge or D domain of the receptor (amino acids 156-188), an area that can play a role in protein-protein interactions, may also be important in ligand-induced functional changes.

The ligand binding domain of the human retinoic acid receptor gamma is predominantly alpha-helical with a Trp residue in the ligand binding site.

Retinoic acid exerts its many biological effects by interaction with a nuclear protein, the retinoic acid receptor (RAR). The details of this interaction are unknown due mainly to the lack of sufficient quantities of pure functional receptor protein for biochemical and structural studies. We have recently subcloned the D and E domains of human RAR gamma for expression in Escherichia coli. Using nickel-chelation affinity chromatography with a polyhistidine amino-terminal tail, purification of the DE peptide with a pI of 5.18 was accomplished to greater than 98% purity. Scatchard analysis and fluorescence quenching techniques using the purified protein indicate a very high percentage of functional molecules ( > 95%) with a Kd for retinoic acid (t-RA) of 0.6 +/- 0.1 nM. Circular dichroism spectra of the purified domains predict a predominantly alpha-helical structure (approximately 56%) with little beta sheet present. No significant changes in these structural characteristics were observed upon binding of t-RA. Inspection of the amino acid sequence within these domains identified a single tryptophan residue at position 227. Modeling the amino acid sequence in this region as an alpha-helical structure indicates that this tryptophan is adjacent to alanine 234, which corresponds to alanine 225 in RAR beta that has previously been linked to the ligand binding site. Fluorescence of this tryptophan was quenched in a dose-dependent manner on the addition of t-RA, confirming that Trp-227 is within the ligand binding site. Tryptophan fluorescence quenching analysis also demonstrates that a single retinoic acid molecule is bound per receptor and suggests that receptor-ligand interactions occur within the amino-terminal portion of the predominantly alpha-helical ligand binding domain.

Homologs of the yeast neck filament associated genes: isolation and sequence analysis of Candida albicans CDC3 and CDC10.

Morphogenesis in the yeast Saccharomyces cerevisiae consists primarily of bud formation. Certain cell division cycle (CDC) genes, CDC3, CDC10, CDC11, CDC12, are known to be involved in events critical to the pattern of bud growth and the completion of cytokinesis. Their products are associated with the formation of a ring of neck filaments that forms at the region of the mother cell-bud junction during mitosis. Morphogenesis in Candida albicans, a major fungal pathogen of humans, consists of both budding and the formation of hyphae. The latter is thought to be related to the pathogenesis and invasiveness of C. albicans. We have isolated and characterized C. albicans homologs of the S. cerevisiae CDC3 and CDC10 genes. Both C. albicans genes are capable of complementing defects in the respective S. cerevisiae genes. RNA analysis of one of the genes suggests that it is a regulated gene, with higher overall expression levels during the hyphal phase than in the yeast phase. Not surprisingly, DNA sequence analysis reveals that the proteins share extensive homology at the amino acid level with their respective S. cerevisiae counterparts. Related genes are also found in other species of Candida and, more importantly, in filamentous fungi such as Aspergillus nidulans and Neurospora crassa. A database search revealed significant sequence similarity with two peptides, one from Drosophila and one from mouse, suggesting strong evolutionary conservation of function.

Isolation and sequence analysis of the gene encoding translation elongation factor 3 from Candida albicans.

The structural gene encoding translation elongation factor 3 (EF-3) has been cloned from a Candida albicans genomic library by hybridization to a Saccharomyces cerevisiae probe containing the Saccharomyces gene, YEF3 (Sandbaken et al., 1990b). The sequences were shown to be functionally homologous to the Saccharomyces gene by three criteria: (1) a Saccharomyces strain transformed with a high copy plasmid containing CaEF3 sequences overproduces the EF-3 peptide two-fold; (2) extracts from this strain exhibit a two-fold increase in the EF-3-catalysed, ribosome-dependent ATPase activity (Kamath and Chakraburtty, 1988); and (3) the Candida gene complements a Saccharomyces null mutant. The coding region, identified by DNA sequencing, indicates that CaEF3 encodes a 1050 amino acid polypeptide having a potential molecular weight of 116,865 Da. This protein shows 77% overall identity to the Saccharomyces YEF3 gene, with a significantly greater identity (94%) concentrated in the region of the protein thought to contain the catalytic domain of EF-3 (Sandbaken et al., 1990a). The upstream non-coding region contains T-rich regions typical of many yeast genes and several potential RAP1/GRF1 elements shown to regulate expression of a number of translational genes (Mager, 1988). The data confirm a high degree of conservation for EF-3 among the two organisms.

Protein synthesis in yeast. Structural and functional analysis of the gene encoding elongation factor 3.

The yeast translational elongation factor 3 (EF-3) stimulates EF-1 alpha-dependent binding of aminoacyl-tRNA by the ribosome. The requirement for EF-3 is unique to fungi; a functional analog has not been found in prokaryotes or other eukaryotes. We have isolated and characterized the structural gene, YEF3, that encodes EF-3. The YEF3 gene is present in one copy/haploid genome and is essential for vegetative growth. DNA sequence analysis revealed that the YEF3 gene contains an open reading frame of 1044 codons. The deduced amino acid sequence contains two repeats of a nucleotide-binding motif, which is similar to the nucleotide-binding consensus sequences of hydrophilic, membrane-associated ATPases. EF-3 catalyzes ATP hydrolysis in a ribosome-dependent manner. A modified assay procedure has been developed that allows measurement of the ATP hydrolytic activity of EF-3 in cell-free extracts without interference by other nucleotide hydrolyase activities. Using this modified assay, we have shown that the wild-type YEF3 gene restores heat stable EF-3 activity in a yeast strain containing a temperature-sensitive EF-3. Introduction of the YEF3 gene on a high copy number plasmid into yeast strains increases the ribosome-dependent ATPase activity. The level of EF-3 protein is also increased 3-5-fold. Elevated EF-3 protein levels did not cause a significant increase in EF-1 alpha and EF-2 protein. Yeast strains containing elevated EF-3 protein levels are more sensitive to the aminoglycoside antibiotics hygromycin and paromomycin. These drugs are known to increase translational errors. This observation suggests that EF-3 may indirectly affect translational accuracy.

Isolation and characterization of the structural gene encoding elongation factor 3.

The unique yeast translational factor EF-3 participates in the elongation cycle by stimulating the function of EF-1 alpha in binding aminoacyl-tRNA to the ribosome. We have isolated the structural gene encoding EF-3 from the yeast Saccharomyces cerevisiae. The YEF3 gene is found in one copy per haploid genome and is essential for vegetative growth. DNA sequence analysis reveals that the YEF3 gene contains an open reading frame of 1044 codons. The deduced amino acid sequence has two repeats of a nucleotide-binding motif. Each of these repeats shows similarity to the nucleotide-binding motif of hydrophilic, membrane-associated ATPases including human multidrug resistant protein MDR. Factor 3 manifests ribosome-dependent ATP hydrolysis. Introduction of the YEF3 gene on a high copy number plasmid into yeast strains increases the ribosome-dependent ATPase activity and EF-3 protein levels by 3-5-fold. Yeast strains containing elevated EF-3 protein levels also exhibit increased sensitivity to the aminoglycoside antibiotics hygromycin and paromomycin. These drugs are known to increase translational errors. These observations suggest that EF-3 may affect translational accuracy.