At least four mRNAs for oat phytochrome A~phyA! are present in etiolated oat tissue. The complete amino acid sequences of two phyA isoforms~A3 and A4! and the N-terminal amino acid sequence of a third isoform~A5! were deduced from cDNA sequencing~Hershey et al., 1985!. In the present study, heterogeneity of phyA on a protein level was studied by tryptic mapping using electrospray ionization mass-spectrometry~ESIMS!. The total tryptic digest of iodoacetamide-modified phyA was fractionated by gel filtration chromatography followed by reversed-phase highperformance liquid chromatography. ESIMS was used to identify peptides. Amino acid sequences of the peptides were confirmed or determined by collision-induced dissociation mass spectrometry~CID MS!, MS0MS, or by subdigestion of the tryptic peptides followed by ESIMS analysis. More than 97% of the phyA3 sequence~1,128 amino acid residues! was determined in the present study. Mass-spectrometric analysis of peptides unique to each form showed that phyA purified from etiolated oat seedling is represented by three isoforms A5, A3, and A4, with ratio 3.4:2.3:1.0. Possible light-induced changes in phytochrome in vivo phosphorylation site at Ser7~Lapko VN et al., 1997, Biochemistry 36:10595-10599! as well at Ser17 and Ser598~known as in vitro phosphorylation sites! were also analyzed. The extent of phosphorylation at Ser7 appears to be the same for phyA isolated from dark-grown and red-light illuminated seedlings. In addition to Ser7, Ser598 was identified as an in vivo phosphorylation site in oat phyA. Ser598 phosphorylation was found only in phyA from the red light-treated seedlings, suggesting that the protein phosphorylation plays a functional role in the phytochrome A-mediated light-signal transduction.
Phytochrome A (phyA) is a photoreceptor of higher plants which mediates a variety of biochemical and physiological processes in response to red/far-red light. By detailed structural analysis of the peptides of the total tryptic digest of oat phyA, we found that the photoreceptor isolated from red light irradiated seedlings contains only one site of phosphate attachment, in the N-terminal Ser-rich region. The N-terminal tryptic phosphopeptide (residues 1-12) contains eight serine residues, any of which may be phosphorylated. Direct fast atom bombardment mass spectrometry (FAB MS/MS) analysis of the phosphorylated peptide as well as of its phosphate-containing fragment (residues 1-9) was not successful due to their hydrophilic nature and instability of the phosphate bond. beta-Elimination of the phosphorylated tryptic peptide in the presence of ethanethiol converted the phosphoserine residue to S-ethylcysteine that is stable under FAB MS/MS. FAB MS/MS analysis of the modified peptide clearly showed that the phosphate group was attached to Ser7. The in vivo phosphorylation site at Ser7 in oat phyA is discussed for its possible regulatory role in phyA function.
The alpha-crystallins are the most abundant structural proteins of the lens and, because of their chaperone activity, contribute to the solubility of the other crystallins. With aging, the lens crystallins undergo a variety of modifications which correlate with a loss of solubility and the development of cataract. A recent study demonstrating that alpha-crystallins exposed in vitro to FeCl3 and H2O2 exhibit decreased chaperone activity, implicates metal catalyzed oxidations of alpha-crystallins in this loss of solubility. The present study has determined that alpha-crystallins incubated with FeCl3 and H2O2 are modified by the nearly complete oxidation of all methionine residues to methionine sulfoxide, with no other detectable reaction products. The modifications were identified from the molecular weights of peptides formed by enzymatic digestion of the alpha-crystallins and located by tandem mass spectrometric analysis of the fragmentation pattern of the mass spectra of the fragments from peptides with oxidized methionine is loss of 64 Da, which corresponds to loss of CH3SOH from the methionine sulfoxide. These fragments are useful in identifying peptides that include oxidized methionine residues.
In an earlier report we showed that incubation of ␣-crystallin with oxidized glutathione results in significant loss of its chaperone-like activity. In the present study, we determined the effect of protein-glutathione mixed disulfides (PSSG), formed at Cys-131 in bovine ␣A-crystallin, and Cys-131 and Cys-142 in human ␣A-crystallin, on the function of ␣-crystallin as a molecular chaperone. After incubation of calf and young human ␣ L -crystallin fractions with oxidized glutathione, levels of PSSG were determined by performic acid oxidation of the mixed disulfides followed by reversed-phase high pressure liquid chromatography separation of phenylisothiocyanate-derivatized glutathione sulfonic acid. Levels of PSSG increased from 0.01 to 0.14 nmol/nmol (20 kDa) in bovine ␣ L -crystallin and from 0.022 to 0.25 nmol/ nmol in human ␣ L -crystallin. The presence of glutathione adducts at Cys-131 and Cys-142 were confirmed by mass spectral analysis. The chaperone-like activity was determined by the heat denaturation assay using  Lcrystallin as the target protein. To examine the reversibility of the effect of mixed disulfides on chaperone activity, studies were done before and after reduction with the glutathione reductase system. Increased levels of PSSG resulted in lower chaperone activities. Treatment with the glutathione reductase system led to 80% reduction in PSSG levels with a concomitant recovery of the chaperone activity. These results suggest that cysteine(s) in the ␣A-crystallin subunit play an important role in the function of ␣-crystallin as a molecular chaperone.
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