Michael Breslav

An oligopeptide transport gene from Candida albicans.

A Candida albicans oligopeptide transport gene, OPT1, was cloned from a C. albicans genomic library through heterologous expression in the Saccharomyces cerevisiae di-/tripeptide transport mutant PB1X-9B. When transformed with a plasmid harbouring OPT1, S. cerevisiae PB1X-9B, which did not express tetra-/pentapeptide transport activity under the conditions used, was conferred with an oligopeptide transport phenotype, as indicated by growth on the tetrapeptide Lys-Leu-Leu-Gly, sensitivity to toxic tetra- and pentapeptides, and an increase in the initial uptake rate of the radiolabelled tetrapeptide Lys-Leu-Gly-[3H]Leu. The level of oligopeptide transport was found to be influenced in the heterologous host by the source of nitrogen used for growth. The entire 3.8 kb fragment containing the oligopeptide transport activity was sequenced and an ORF of 2349 nucleotides containing a 58 nucleotide intron was identified. The deduced protein product of 783 amino acid residues contained 12 hydrophobic regions suggestive of a membrane transport protein. Sequence comparisons revealed that similar proteins are encoded by genes from S. cerevisiae and Schizosaccharomyces pombe and that OPT1 is not a member of the ABC or PTR membrane transport families.

Schizosaccharomyces pombe isp4 encodes a transporter representing a novel family of oligopeptide transporters

We have recently cloned an oligopeptide transport gene from Candida albicans denoted OPT1. This gene showed significant sequence similarity to three open reading frames (ORFs) with no previously established function: isp4 from Schizosaccharomyces pombe and Saccharomyces cerevisiae YJL212C and YPR194C, identified during the genome project. The S. pombe gene isp4 was originally identified by Sato et al. as a gene that was upregulated through nitrogen starvation induction of meiosis. However, an isp4Δ strain exhibited a wild‐type phenotype with respect to sexual differentiation. We have found that the same isp4Δ strain is deficient in tetrapeptide transport activity as measured by its resistance to toxic tetrapeptides, by its inability to accumulate a radiolabelled tetrapeptide and by the inability to use tetrapeptides as a sole source of an amino acid to satisfy an auxotrophic requirement. Similarly, we found that the ORF YPR194C from S. cerevisiae encodes an oligopeptide transporter. Sequence analyses as well as physiological evidence has led us to propose that the proteins encoded by isp4 and the genes identified from S. cerevisiae and C. albicans comprise a new group of transporters specific for small oligopeptides, which we have named the OPT family.

PTR3, a novel gene mediating amino acid-inducible regulation of peptide transport in Saccharomyces cerevisiae

We have isolated and characterized the Saccharomyces cerevisiae PTR3 gene by functional complementation of a mutant deficient for amino acid‐inducible peptide transport. PTR3 is predicted to encode a protein of 678 amino acids that exhibits no similarity to any other protein in the database. Deletion of the PTR3 open reading frame pleiotropically reduced the sensitivity to toxic peptides and amino acid analogues. Initial rates of radiolabelled dipeptide uptake demonstrated that elimination of PTR3 resulted in the loss of amino acid‐induced levels of peptide transport. PTR3 was required for amino acid‐induced expression of PTR2, the gene encoding the dipeptide/tripeptide transport protein, but was not necessary for nitrogen catabolite repression of peptide import or PTR2 expression. It was determined that PTR3 also modulates expression of BAP2, the gene encoding the branched‐amino acid permease. Furthermore, we present genetic evidence that suggests that PTR3 functions within a novel regulatory pathway that facilitates amino acid induction of the PTR system.

Structure of segments of a G protein-coupled receptor: CD and NMR analysis of the Saccharomyces cerevisiae tridecapeptide pheromone receptor.

Peptides representing both loop and the sixth transmembrane regions of the alpha-factor receptor of Saccharomyces cerevisiae were synthesized by solid-phase procedures and purified to near homogeneity. CD, nmr, and modeling analysis indicated that in aqueous media the first extracellular loop peptide E1(107-125), the third intracellular loop peptide I3(231-243), and the carboxyl terminus peptide I4(350-372) were mostly disordered. In contrast, the second extracellular loop peptide E2(191-206) assumed a well-defined structure in aqueous medium and the sixth transmembrane domain peptide receptor M6(252-269, C252A) was highly helical in trifluoroethanol/water (4:1), exhibiting a kink at Pro258. A synthetic peptide containing a sequence similar to that of the sixth transmembrane domain of a constitutively active alpha-factor receptor M6(252-269, C252A, P258L) in which Leu replaces Pro258 exhibited significantly different biophysical properties than the wild-type sequence. In particular, this peptide had very low solubility and gave CD resembling that of a beta-sheet structure in hexafluoroacetone/water (1:1) whereas the wild-type peptide was partially helical under identical conditions. These results would be consistent with the hypothesis that the constitutive activity of the mutant receptor is linked to a conformational change in the sixth transmembrane domain. The study of the receptor segments also indicate that peptides corresponding to loops of the alpha-factor receptor do not appear to assume turn structures.

Long-distance rotational echo double resonance measurements for the determination of secondary structure and conformational heterogeneity in peptides

The utility of rotational echo double resonance (REDOR) NMR spectroscopy for determining the conformations of linear peptides has been examined critically using a series of crystalline and amorphous samples. The focus of the present work was the evaluation of long-distance (> 5 A) interactions using 13C-15N dephasing. Detailed studies of specifically labeled melanostatin and synthetic analogs of the alpha-factor yeast mating hormone show that nitrogen-dephased, carbon-observe REDOR measurements are reliable for distances up to 6.0 A, and that dipolar interactions can be detected for distances up to 7 A. By contrast, nitrogen-observe REDOR gives reliable results only for distances shorter than 5.0 A. To measure distances accurately, REDOR data must be corrected for the effects of natural-abundance spins. These corrections are particularly important for measuring long distances, which are of the greatest value for determining peptide secondary structure. We have developed a spherical shell model for calculating the effect of these background spins. The REDOR studies also indicate that in a lyophilized powder, the tridecapeptide alpha-factor mating pheromone from Saccharomyces cerevisiae (WHWLQLKPGQPMY) probably exists as a distribution of different turn structures around the KPGQ region. This finding revises previous solid-state NMR studies on this peptide, which concluded alpha-factor assumes a distorted type-I beta-turn in the Pro-Gly central region of the molecule [J.R. Garbow, M. Breslav, O. Antohi, F. Naider, Biochemistry, 33 (1994) 10094].

Dithioketal formation during synthesis of Bpa containing peptides

Acidolytic cleavage of peptides from polymeric supports often employs dithiols as scavengers. A significant impurity was found during the synthesis of peptides containing p-benzoylphenylalanine (Bpa) when 1,2-ethanedithiol was the scavenger. Herein we describe a new side reaction involving Bpa containing peptides and dithiols that results in dithioketal formation and report a strategy to eliminate this side reaction.

Long-distance REDOR NMR measurements for determination of secondary structure and conformational heterogeneity in peptides

High-resolution NMR spectroscopy of liquids has become a standard method for conformational studies in biochemistry. This method provides information on the secondary and tertiary structure of macromolecules and on intermolecular interactions such as ligand receptor binding. These determinations are based mainly on interatomic distance measurements by quantitative analysis of NOESY spectra and, to a lesser degree, on torsion angle measurements based on homoor heteronuclear scalar coupling constants. As with liquids, internuclear distances in solids are reflected in dipole-dipole coupling constants between the nuclear magnetic dipoles. Rotational-echo double resonance (REDOR) spectroscopy has been employed to determine heteronuclear dipole-dipole coupling constants [1,2] and to study internuclear distances in peptides, proteins and bound ligands. An important target for the REDOR experiment is an amorphous solid. For biologically important amorphous solids that cannot be obtained in crystalline form, NMR spectroscopy is the only method for direct investigation of conformation at the atomic level. In the present study we examine the REDOR of selectively labeled peptide hormone in lyophilized powders. In order to understand the contribution of naturalabundance nuclei to the REDOR data at long evolution times, we have used a three-body calculation [3,4] and assumed a spherical distance distribution for natural abundance corrections. In addition we have evaluated the REDOR results in terms of a superposition of different distances with appropriate weighting factors. These approaches allow us to fit the experimental data on the to a high degree of accuracy and to conclude that this peptide has a tendency to be bent in a lyophilized powder.