Effect of selective nitration of ovine lutropin on the subunit association and biological activity of the hormone

Comparison of nitrotyrosine antibodies and development of immunoassays for the detection of nitrated proteins

Three monoclonal antibodies (mAb) and three polyclonal antibodies (pAb) have been characterized and compared with respect to their cross-reactivities and affinities for 3-nitrotyrosine, eight aromatic compounds with similar chemical structures, a peptide containing a single nitrotyrosine residue, and fourteen nitrated protein standards (bovine serum albumin, BSA) containing different numbers of nitrotyrosine residues per protein molecule (0.2 to 16.8). In indirect competitive immunoassays, mAb Alexis 39B6 exhibited the highest affinity for free 3-nitrotyrosine (10(6) L mol(-1)), while the pAb Oxis 24312 from sheep exhibited the highest affinities for nitrated proteins (up to 10(8) L mol(-1)). The apparent affinities determined in the indirect competitive assays were inversely correlated with the limits of detection (LOD) determined in one-sided immunoassays. With the sheep pAb minimum LOD on the order of 10 pmol L(-1) were achieved for highly nitrated proteins, corresponding to effective LOD on the order of 100 pmol L(-1) for nitrotyrosine residues. In the one-sided assays, however, the LOD for nitrated proteins increased proportionally with increasing background concentrations of native proteins in the investigated samples. Sandwich immunoassays combining pAb and mAb for selective enrichment and detection of nitrated proteins allowed to eliminate this native protein matrix effect and to achieve LOD on the order of 300 pmol L(-1) for highly nitrated proteins independent of native protein background concentrations.

Nitration modifying function of proteins, hormones and neurotransmitters

Several lines of evidence have been accumulated for occurrence of nitration in vivo. In this brief review, we summarized nitration studies on functional changes of proteins, hormones and neurotransmitters, before as well as after the discovery of peroxynitrite. Most of nitrated molecules exhibit less active properties than the parental compounds. It is still unknown whether nitration is merely a footprint of oxidative stress, an important pathway of nitric oxide metabolisms or a part of integral processes for maintaining cellular homeostasis.

Hybrids from equine LH: alpha enhances, beta diminishes activity

LH hybrids were prepared by combining eLH alpha and eLH beta with the corresponding subunits of oLH, pLH and hCG. Recombinants were isolated by gel filtration and assessed by SDS-polyacrylamide gel electrophoresis under both dissociating and non-dissociating conditions. All combinations of subunits produced hybrid LH molecules. Hybrids prepared by combining eLH beta with oLH alpha, pLH alpha or hCG alpha were very inactive in rat radioligand and Leydig cell in vitro bioassays. Hybrids prepared with eLH alpha were very active in both assays. The greatest potentiating activity was observed when eLH alpha was combined with pLH beta. The resulting hybrid was 49 times as active as pLH in stimulating steroidogenesis by Leydig cells.

On the optical activity of ionized tyrosyl residues in ovine lutropin

The effect of alkali on the circular dichroic (CD) spectra of ovine lutropin and its subunits has been studied. Mild alkaline pH induces the appearance of a new optically active band in the 250-nm region of the spectra of lutropin without any detectable alteration in the secondary structure of the protein. This change is reversible and can be correlated with ionization of 2--3 exposed tyrosyl residues in the intact hormone. In a previous report from this laboratory it was concluded that the three exposed tyrosyl residues are located in the alpha subunit, in positions 21, 92 and 93 [Burleigh, B.D., Liu, W.-K, and Ward, D.M. (1976) J. Biol. Chem. 251, 308--315]. Nitration of these residues lowers the pH at which the intensity of the 250-nm band is maximal. The importance of the tyrosyl residues of lutropin alpha (as opposed to those of lutropin beta) is also supported by the similarity of the effect of alkali on the CD spectra of lutropin and lutropin alpha. Further evidence for this involvement was also obtained by a comparison of the alkali-induced changes of refolded lutropin (alpha + beta recombinant) and the product obtained by recombination of des-(92--96)-lutropin alpha (obtained from carboxypeptidase treatment of the alpha-subunit) and lutropin beta. The results indicate that removal of tyrosines alpha 92 and alpha 93 results in a decrease of the intensity of the 235-nm band of ovine lutropin (at pH7.5) as well as that of the 250-nm band observed under alkaline conditions. It is therefore concluded that the 250-nm band observed in alkaline solutions of lutropin arises (at least partially) from the red shift produced in the short-wavelength optically active band of tyrosines alpha 21, alpha 92, and alpha 93 upon ionization.