Human Fetal Tissue from Elective Abortions in Research and Medicine: Science, Ethics, and the Law.

Since the U.S. Supreme Court issued its landmark decision in 1973 to legalize abortion, over 60 million preborn have been killed by elective abortion. While alive in the womb, these preborn are abandoned and not protected under current law. But once aborted, their body parts are a highly esteemed and prized commodity amongst certain members of the scientific community. Moral discourse is disregarded for the sake of science. The public have been lulled and lured into believing that this practice must continue in order to understand and develop cures for some of the most debilitating diseases of our day. But they are mistaken. This practice is not necessary, especially in light of numerous noncontroversial alternatives. Here, we expose and consider the false and misleading claims regarding human fetal tissue (HFT) in research from scientific, legal, and ethical points of view. We endeavor deeply to understand the depth of the injustice in this practice and what forces promote and maintain it; and by revealing and understanding these forces, we set forth how these inhumane practices can be ended. An accurate portrayal of the history of HFT use in research is provided, along with a close examination of the current state of this practice under existing laws. The serious societal implications are also discussed, which will worsen beyond comprehension if these practices are allowed to continue. The timeliness of this information cannot be overstated, and a thorough understanding is paramount for anyone who desires to know the facts about HFT in research and medicine and its detrimental impact for humanity.

Proteomic approaches to analyze protein tyrosine nitration.

SIGNIFICANCE: The conversion of protein-bound Tyr residues to 3-nitrotyrosine (3NY) can occur during nitrative stress and has been correlated to aging and many disease states. Proteomic analysis of this post-translational modification, using mass spectrometry-based techniques, is crucial for understanding its potential role in pathological and physiological processes. RECENT ADVANCES: To overcome some of the disadvantages inherent to well-established nitroproteomic methods using anti-3NY antibodies and gel-based separations, methods involving multidimensional chromatography, precursor ion scanning, and/or chemical derivatization have emerged for both identification and quantitation of protein nitration sites. A few of these methods have successfully detected endogenous 3NY modifications from biological samples. CRITICAL ISSUES: While model systems often show promising results, identification of endogenous 3NY modifications remains largely elusive. The frequently low abundance of nitrated proteins in vivo, even under inflammatory conditions, is especially challenging, and sample loss due to derivatization and cleaning may become significant. FUTURE DIRECTIONS: Continued efforts to avoid interference from non-nitrated peptides without sacrificing recovery of nitrated peptides are needed. Quantitative methods are emerging and are crucial for identifying endogenous modifications that may have significant biological impacts.

Tyrosine modifications in aging.

SIGNIFICANCE: The understanding of physiological and pathological processes involving protein oxidation, particularly under conditions of aging and oxidative stress, can be aided by proteomic identification of proteins that accumulate oxidative post-translational modifications only if these detected modifications are connected to functional consequences. The modification of tyrosine (Tyr) residues can elicit significant changes in protein structure and function, which, in some cases, may contribute to biological aging and age-related pathologies, such as atherosclerosis, neurodegeneration, and cataracts. RECENT ADVANCES: Studies characterizing proteins in which Tyr has been modified to 3-nitrotyrosine, 3,4-dihydroxyphenylalanine, 3,3'-dityrosine and other cross-links, or 3-chlorotyrosine are reviewed, with an emphasis on structural and functional consequences. CRITICAL ISSUES: Distinguishing between inconsequential modifications and functionally significant ones requires careful biochemical and biophysical analysis of target proteins, as well as innovative methods for isolating the effects of the multiple modifications that often occur under oxidizing conditions. FUTURE DIRECTIONS: The labor-intensive task of isolating and characterizing individual modified proteins must continue, especially given the expanding list of known modifications. Emerging approaches, such as genetic and metabolic incorporation of unnatural amino acids, hold promise for additional focused studies of this kind.

Physicochemical stability of the antibody-drug conjugate Trastuzumab-DM1: changes due to modification and conjugation processes.

In the manufacture of the antibody-drug conjugate Trastuzumab-DM1 (T-DM1), the lysine residues on the antibody trastuzumab (Tmab) are modified to form the intermediate Tmab-MCC (T-MCC) and then conjugated with the drug DM1. Our goal is to understand the effects of modification and conjugation steps on the physicochemical stability of the antibody. The structural stability of Tmab relative to its modified and conjugated forms was assessed, employing thermally induced stress conditions to formulations containing Tmab, T-MCC, and T-DM1. DSC, SEC, CE-SDS, and LC-MS were used to study the stability of Tmab, T-MCC, and T-DM1 to thermal stress. The DSC thermograms show a decrease in melting temperature for the CH2 transition, in the order Tmab > T-MCC > T-DM1. As per SEC analysis, a significant increase in level of aggregation was detected in T-MCC (∼32%) and T-DM1 (∼5%) after 14 days at 40 °C. Tmab did not show significant aggregate formation. CE-SDS and LC-MS data demonstrate that the aggregation in the case of T-MCC is largely covalent and involves mechanisms other than formation of intermolecular disulfide cross-links. The aggregation observed for T-MCC was significantly inhibited upon addition of amino acids with nucleophilic side chains containing thiol (Cys) and hydroxyl moieties (Ser, Tyr). The covalent aggregation observed for T-MCC and the ability of nucleophilic amino acids, particularly Cys, to inhibit it indicate that the maleimide moiety in the MCC linker may react to form intermolecular covalent cross-links between T-MCC molecules, possibly through a Michael addition mechanism. In addition, DSC results demonstrate that the conjugation of the drug moiety DM1 to Tmab results in destabilization of the CH2 domain of the antibody.