The presence of free d-aspartate in marine macroalgae is restricted to the Sargassaceae family.

The presence of d-aspartate (d-Asp), a biologically rare amino acid, was evaluated in 38 species of marine macroalgae (seaweeds). Despite the ubiquitous presence of free l-Asp, free d-Asp was detected in only 5 species belonging to the Sargassaceae family of class Phaeophyceae (brown algae) but not in any species of the phyla Chlorophyta (green algae) and Rhodophyta (red algae). All other members of Phaeophyceae, including 3 species classified into the section Teretia of Sargassaceae did not contain d-Asp. These results indicate that the presence of free d-Asp in marine macroalgae is restricted only to the Sargassaceae family, excluding the species in the section Teretia.

Prerequisites of Isopeptide Bond Formation in Microcystin Biosynthesis.

The biosynthesis of the potent cyanobacterial hepatotoxin microcystin involves isopeptide bond formation through the carboxylic acid side chains of d-glutamate and ß-methyl d-aspartate. Analysis of the in vitro activation profiles of the two corresponding adenylation domains, McyE-A and McyB-A2 , either in a didomain or a tridomain context with the cognate thiolation domain and the upstream condensation domain revealed that substrate activation of both domains strictly depended on the presence of the condensation domains. We further identified two key amino acids in the binding pockets of both adenylation domains that could serve as a bioinformatic signature of isopeptide bond-forming modules incorporating d-glutamate or d-aspartate. Our findings further contribute to the understanding of the multifaceted role of condensation domains in nonribosomal peptide synthetase assembly lines.

A rapid and sensitive detection of D-Aspartic acid in Crystallin by chiral derivatized liquid chromatography mass spectrometry.

A method for the determination of D-Aspartic acid (D-Asp) and its D/L ratio in peptides and proteins has been developed. This method was carried out with good separation of the D/L chiral peptide pairs by combination of a chiral derivatization and an ADME column separation. Furthermore, a cationic derivatization reagent, DBD-Py-NCS, increased the sensitivity of the ESI-MS/MS detection. To confirm the comprehensive peptide analysis, synthesized α-Crystallin tryptic peptides, which included D-Asp residues, were analyzed. The 5 pairs of D/L-Asp that included peptide diastereomers were well separated. Their peak resolutions were more than 1.5 and the results were reproducible (RSD<0.05, n=5). As an application of this method, we analyzed the α-Crystallin standard and UV irradiated α-Crystallin. After trypsin digestion and DBD-Py-NCS derivatization, the tryptic peptide derivatives were applied to LC-MS/MS. Based on the results of peptide sequence identification, almost all the tryptic peptides of the αA- and αB-Crystallin homologous subunits of α-Crystallin were detected as DBD-Py NCS derivatives. However, there was no D-Asp residue in the standard proteins. In the case of the UV irradiated α-Crystallin, Asp76 and Asp84 in the αA-Crystallin and Asp96 in αB-Crystallin were racemized to D-Asp. These results show that this proposed chiral peptide LC-MS/MS method using chiral derivatization provides a rapid and sensitive analysis for post translational Asp racemization sites in aging proteins.

Peptidyl prolyl isomerase Pin1-inhibitory activity of D-glutamic and D-aspartic acid derivatives bearing a cyclic aliphatic amine moiety.

Pin1 is a peptidyl prolyl isomerase that specifically catalyzes cis-trans isomerization of phosphorylated Thr/Ser-Pro peptide bonds in substrate proteins and peptides. Pin1 is involved in many important cellular processes, including cancer progression, so it is a potential target of cancer therapy. We designed and synthesized a novel series of Pin1 inhibitors based on a glutamic acid or aspartic acid scaffold bearing an aromatic moiety to provide a hydrophobic surface and a cyclic aliphatic amine moiety with affinity for the proline-binding site of Pin1. Glutamic acid derivatives bearing cycloalkylamino and phenylthiazole groups showed potent Pin1-inhibitory activity comparable with that of known inhibitor VER-1. The results indicate that steric interaction of the cyclic alkyl amine moiety with binding site residues plays a key role in enhancing Pin1-inhibitory activity.

The possible involvement of D-amino acids or their metabolites in Arabidopsis cysteine proteinase/cystatin N-dependent proteolytic pathway.

Cysteine proteinases and their inhibitors 'cystatins' play essential roles in plant growth and development. They are involved in various signaling pathways and in the response to wide ranges of biotic and abiotic environmental stresses. To investigate their possible influence from D-amino acids or their metabolism in vivo, Arabidopsis seedlings were allowed to grow under four physicochemically different D-amino acids including D-aspartate, D-serine, D-alanine and D-phenylalanine containing media. The reverse transcription polymerase chain reaction (R T-PCR) analysis of cysteine proteinase and cystatin gene expressions showed that the addition of D-amino acid to the plant growth media considerably induce the expression of proteinase transcript while decrease the expression level of inhibitor gene in the leaf and root tissues of the test plant in overall. Based on the obtained results the potential impact of D-amino acids or their metabolism on the activity of cysteine proteinase/cystatin-dependent proteolytic apparatus as well as their possible cooperation were predicted and discussed in the plant system.

Discriminating D-amino acid-containing peptide epimers by radical-directed dissociation mass spectrometry.

The presence of a single D-amino acid in a peptide is very difficult to detect. Mass spectrometry-based approaches rely on differences in fragmentation between all L-amino acid-containing peptides and single D-amino acid-containing peptides (which are epimers) for identification. The success of this approach is dependent on the structural sensitivity of the fragmentation method. Recently, experiments have demonstrated that fragmentation initiated by radical chemistry, or radical-directed dissociation (RDD), is particularly sensitive to the structure of the ion being fragmented. Herein, RDD is used to identify the presence of D-serine, D-alanine, or D-aspartic acid in eight biologically relevant peptides. It is demonstrated that chiral disambiguation by RDD is dependent on both the initial radical site and subsequent radical migration. Fortuitously, RDD can be initiated by a variety of different radical precursors which can be associated with the peptide via covalent or noncovalent means, and RDD can be examined in all observable charge states (both positive and negative). This diversity enables numerous initial radical sites and migration pathways to be explored. For all but one of the peptides that were examined, RDD provides significantly better chiral discrimination than CID. Quantitation of peptide epimers by RDD is also described.

Oostatic peptides containing D-amino acids: synthesis, oostatic activity, degradation, accumulation in ovaries and NMR study.

Analogs of the H-Tyr-Asp-Pro-Ala-Pro-OH pentapeptide with D-amino acid residues either in differing or in all of the positions of the sequences were prepared and their oostatic potency was compared with that of the parent pentapeptide. The D-amino acid residue containing analogs exhibited an equal or even higher oostatic effect in the flesh fly Neobellieria bullata than the parent peptide. Contrary to the rapid incorporation of radioactivity from the labeled H-Tyr-Asp-[3H]Pro-Ala-Pro-OH pentapeptide into the ovaries of N. bullata in vitro, the radioactivity incorporation from the labeled pentapeptides with either D-aspartic acid or D-alanine was significantly delayed. As compared to the parent pentapeptide, also the degradation of both the D-amino acid-containing analogs mentioned above proceeded at a significantly lower rate. The decreased intake of radioactivity, the lower degradation and finally also the high oostatic effect may be ascribed to the decreased enzymatic degradation of the peptide bonds neighboring the D-amino acid residues in the corresponding peptides. The introduction of the non-coded D: -amino acids thus enhances the oostatic effect in N. bullata owing to the prolonged half-life of the corresponding pentapeptides, which can thus affect more ovarian cells.

Substrate stereoselectivity of mammalian D-aspartyl endopeptidase.

The formation and accumulation of D-aspartate residue (D-Asp) in proteins caused by oxidative stress leads to dysfunction and/or denaturation of proteins, and is consequently responsible for aging-related misfolding diseases such as cataracts, prion disease, and Alzheimer's disease. We sought to identify that an unknown protease selectively degrades the noxious D-Asp-containing protein, namely D-aspartyl endopeptidase (DAEP), and finally purified it from the inner mitochondrial membrane of mouse liver. In order to analyze the substrate stereoselectivity of DAEP, we synthesized a peptide corresponding to 55-65 (Thr-Val-Leu-Asp-Ser-Gly-Ile-Ser-Glu-Val-Arg) of human αA-crystallin and its corresponding diastereoisomers in which L-α-Asp was replaced with L-ß-, D-α- or D-ß-Asp residue at position 58. Following incubation of that peptide with purified DAEP, it was only degraded at D-α-Asp(58), independent of ATP or NAD. This result indicates that DAEP stereoselectively recognizes and degrades its substrate at the internal D-α-Asp residue. DAEP therefore seems to physiologically serve as the quality control system against the noxious D-Asp-containing protein in the long life span of mammals.

Computational investigation of the substrate recognition mechanism of protein D-aspartyl (L-isoaspartyl) O-methyltransferase by docking and molecular dynamics simulation studies and application to interpret size exclusion chromatography data.

Unusual amino acid residues such as L-ß-aspartyl (Asp), D-α-Asp, and D-ß-Asp have been detected in proteins and peptides such as α-crystallin in the lens and ß-amyloid in the brain. These residues increase with age, and hence they are associated with age-related diseases. The enzyme protein D-aspartyl (L-isoaspartyl) O-methyltransferase (PIMT) can revert these residues back to the normal L-α-Asp residue. PIMT catalyzes transmethylation of S-adenosylmethionine to L-ß-Asp and D-α-Asp residues in proteins and peptides. In this work, the substrate recognition mechanism of PIMT was investigated using docking and molecular dynamics simulation studies. It was shown that the hydrogen bonds of Ser60 and Val214 to the carboxyl group of Asp are important components during substrate recognition by PIMT. In addition, specific hydrogen bonds were observed between the main chains of the substrates and those of Ala61 and Ile212 of PIMT when PIMT recognized L-ß-Asp. Hydrophobic interactions between the (n-1) residue of the substrates and Ile212 and Val214 of PIMT may also have an important effect on substrate binding. Volume changes upon substrate binding were also evaluated in the context of possible application to interpretation of size exclusion chromatography data.

Effect of the L- or D-aspartate on ecto-5'nucleotidase activity and on cellular viability in cultured neurons: participation of the adenosine A(2A) receptors.

Glutamate increases the extracellular adenosine levels, an important endogenous neuromodulator. The neurotoxicity induced by glutamate increases the ecto-5'-nucleotidase activity in neurons, which produces adenosine from AMP. L- and D-aspartate (Asp) mimic most of the actions of glutamate in the N-methyl-D-aspartate (NMDA) receptors. In the present study, both amino acids stimulated the ecto-5'-nucleotidase activity in cerebellar granule cells. MK-801 and AP-5 prevented the L- and D-Asp-evoked activation of ecto-5'-nucleotidase. Both NMDA receptor antagonists prevented completely the damage induced by L-Asp, but partially the D-Asp-induced damage. The antagonist of adenosine A(2A) receptors (ZM 241385) prevented totally the L- Asp-induced cellular death, but partially the neurotoxicity induced by D-Asp and the antagonist of adenosine A(1) receptors (CPT) had no effect. The results indicated a different involvement of NMDA receptors on the L- or D-Asp-evoked activation of ecto-5'-nucleotidase and on cellular damage. The adenosine formed from ecto-5'-nucleotidase stimulation preferentially acted on adenosine A(2A) receptor which is probably co-operating with the neurotoxicity induced by amino acids.

Isolation and characterization of mammalian D-aspartyl endopeptidase.

The accumulation of D-isomers of aspartic acid (D-Asp) in proteins during aging has been implicated in the pathogenesis of Alzheimer's disease (AD), cataracts and arteriosclerosis. Here, we identified a specific lactacystin-sensitive endopeptidase that cleaves the D-Asp-containing protein and named it D-aspartyl endopeptidase (DAEP). DAEP has a multi-complex structure (MW: 600 kDa) and is localized in the inner mitochondrial membrane. However, DAEP activity was not detected in E. coli, S. cerevisiae, and C. elegans. A specific inhibitor for DAEP, i-DAEP: (benzoyl-L-Arg-L-His-[D-Asp]-CH(2)Cl; MW: 563.01), was newly synthesized and inhibited DAEP activity (IC(50), 3 microM), a factor of ten greater than lactacystin on DAEP. On the other hand, i-DAEP did not inhibit either the 20S or 26S proteasome. And we identified succinate dehydrogenase and glutamate dehydrogenase 1 as components of DAEP by affinity label using biotinylated i-DAEP. In the long life span of mammals, DAEP may serve as a scavenger against accumulation of racemized proteins in aging. Insights into DAEP will provide the foundation for developing treatments of diseases, such as AD, in which accumulation of D-Asp-containing proteins are implicated.

First evidence on induced topological changes in supercoiled DNA by an aluminium D-aspartate complex.

Aluminium is a debatable and suspected etiological factor in neurodegenerative disorders. Aluminium-amino acid complexes also play an important role in the complex biology of the metal. Recent reports indicate the presence of D-aspartate and D-glutamate in aging brain, human breast tumors, core amyloid plaques and neurofibrillary tangles of Alzheimer's brain. This stereoinversion from the L- to the D-enantiomer is enhanced by Al. Further, the observation that Al is localized in the chromatin region encouraged the present study of the interaction of Al-amino acid complexes with DNA. This study used circular dichroism of supercoiled DNA and showed that Al- D-Asp caused a native B-DNA to C-DNA conformational change, while Al- L-Asp, Al- L-Glu and Al- D-Glu did not alter the native B-DNA conformation. This differential DNA binding property of Al-amino acid complexes is assigned to the stereoisomerism and chirality of the complexes. Interestingly, polyamines like spermine further induced an asymmetric condensation of the "limit C-motif" induced by Al- D-Asp to a Psi-DNA. The results were supported by computer modeling, gel studies and ethidium bromide binding. We also propose a mechanism of Al- D-Asp binding and its ability to modulate DNA topology.