Development of a Lyophilized Formulation of Pegaspargase and Comparability Versus Liquid Pegaspargase.

INTRODUCTION: Pegaspargase, a pegylated asparaginase, is a core component in the treatment of acute lymphoblastic leukemia. Pegaspargase in liquid form has a limited shelf life of 8 months due to depegylation, leading to changes in purity and potency over time. Lyophilization is an approach that can improve the stability of biological drug conjugates. METHODS: Here we describe the development of a lyophilized formulation of pegaspargase and present results of a series of tests demonstrating that the lyophilized form has comparable physicochemical properties to the liquid form. RESULTS: Stability tests of critical quality attributes, including purity, potency, aggregates and total free polyethylene glycol, demonstrate that lyophilized pegaspargase remains stable for at least 3 years, with optimum stability achieved with storage under refrigerated conditions (2-8 °C). CONCLUSIONS: Lyophilization improved the stability of pegaspargase without altering other physicochemical properties, permitting a prolonged shelf life of at least 2 years when stored at 2-8 °C. This may enable greater storage flexibility and allow for better management of pegaspargase. FUNDING: Study Sponsor: Baxalta (now part of Takeda). Publication Sponsor: Servier Affaires Médicales.

The prolyl isomerase, FKBP25, interacts with RNA-engaged nucleolin and the pre-60S ribosomal subunit.

Peptidyl-proline isomerases of the FK506-binding protein (FKBP) family belong to a class of enzymes that catalyze the cis-trans isomerization of prolyl-peptide bonds in proteins. A handful of FKBPs are found in the nucleus, implying that the isomerization of proline in nuclear proteins is enzymatically controlled. FKBP25 is a nuclear protein that has been shown to associate with chromatin modifiers and transcription factors. In this study, we performed the first proteomic characterization of FKBP25 and found that it interacts with numerous ribosomal proteins, ribosomal processing factors, and a small selection of chromatin modifiers. In agreement with previous reports, we found that nucleolin is a major FKBP25-interacting protein and demonstrated that this interaction is dependent on rRNA. FKBP25 interacts with the immature large ribosomal subunit in nuclear extract but does not associate with mature ribosomes, implicating this FKBP's action in ribosome biogenesis. Despite engaging nascent 60S ribosomes, FKBP25 does not affect steady-state levels of rRNAs or its pre-rRNA intermediates. We conclude that FKBP25 is likely recruited to preribosomes to chaperone one of the protein components of the ribosome large subunit.

The archaeal proteasome is regulated by a network of AAA ATPases.

The proteasome is the central machinery for targeted protein degradation in archaea, Actinobacteria, and eukaryotes. In its basic form, it consists of a regulatory ATPase complex and a proteolytic core particle. The interaction between the two is governed by an HbYX motif (where Hb is a hydrophobic residue, Y is tyrosine, and X is any amino acid) at the C terminus of the ATPase subunits, which stimulates gate opening of the proteasomal α-subunits. In archaea, the proteasome-interacting motif is not only found in canonical proteasome-activating nucleotidases of the PAN/ARC/Rpt group, which are absent in major archaeal lineages, but also in proteins of the CDC48/p97/VAT and AMA groups, suggesting a regulatory network of proteasomal ATPases. Indeed, Thermoplasma acidophilum, which lacks PAN, encodes one CDC48 protein that interacts with the 20S proteasome and activates the degradation of model substrates. In contrast, Methanosarcina mazei contains seven AAA proteins, five of which, both PAN proteins, two out of three CDC48 proteins, and the AMA protein, function as proteasomal gatekeepers. The prevalent presence of multiple, distinct proteasomal ATPases in archaea thus results in a network of regulatory ATPases that may widen the substrate spectrum of proteasomal protein degradation.

Analysis of the Plasmodium falciparum proteasome using Blue Native PAGE and label-free quantitative mass spectrometry.

Detailed knowledge of the composition of protein complexes is crucial for the understanding of their structure and function; however, appropriate techniques for compositional analyses of complexes largely rely on elaborate tagging, immunoprecipitation, cross-linking and purification strategies. The proteasome is a prototypical protein complex and therefore an excellent model to assess new methods for protein complex characterisation. Here we evaluated the applicability of Blue Native (BN) PAGE in combination with label-free protein quantification and protein correlation profiling (PCP) for the investigation of proteasome complexes directly from biological samples. Using the purified human 20S proteasome we showed that the approach can accurately detect members of a complex by clustering their gel migration profiles. We applied the approach to address proteasome composition in the schizont stage of the malaria parasite Plasmodium falciparum. The analysis, performed in the background of the whole protein extract, revealed that all subunits comigrated and formed a tight cluster with a single maximum, demonstrating presence of a single form of the 20S proteasome. This study shows that BN PAGE in combination with label-free quantification and PCP is applicable to the analysis of multiprotein complexes directly from complex protein mixtures.

Mitochondrial localization of the threonine peptidase PfHslV, a ClpQ ortholog in Plasmodium falciparum.

Plasmodium falciparum belongs to a group of eukaryotes expressing an ortholog of the prokaryotic T1-threonine peptidase, heat shock locus V (HslV). Bacterial HslV is a particularly well studied protease, due to its structural and biochemical similarity to the eukaryotic proteasome. Plasmodium falciparum HslV (PfHslV) is expressed in schizonts and merozoites of the asexual blood stage. Strong sequence conservation between plasmodial species, absence of HslV homologs in the human genome, and availability of specific inhibitors led us to explore its function and potential use as a drug target. In a first step, we investigated localization of PfHslV, using a bioinformatics approach and a transgenic P. falciparum line expressing a PfHslV-enhanced yellow fluorescent protein (EYFP) fusion protein from the endogenous pfhslV locus. PfHslV-EYFP was found in the mitochondrial matrix under fluorescence and immunoelectron microscopy. Endogenous, non-modified PfHslV was present in purified mitochondria and interference with mitochondrial membrane potential by drug treatment led to impairment of PfHslV processing. Import of heterologous EYFP into the plasmodial mitochondrion is mediated by the N-terminal 37 amino acids of PfHslV. PfHslV's targeting sequence is also functional in human cells, demonstrating strong conservation of mitochondrial targeting in eukaryotes. In conclusion, our data shows that PfHslV is located to the plasmodial mitochondrion and presumably has vital function within this organelle which makes it an attractive target for interventions.

Specific modification of peptide-bound citrulline residues.

Immune reactions to citrulline-containing proteins appear to be central in the immunopathogenesis of rheumatoid arthritis. Citrulline residues are introduced into proteins by deimination of arginine residues, likely by an enzymatic process. There is a need to characterize which proteins in the inflamed joints of rheumatoid patients contain citrulline in situ. The characterization of deiminated proteins will be greatly facilitated by specific modification of peptide-bound citrulline residues that will enable specific enrichment and detection of citrulline-containing peptides. This study presents the details of such a modification method. The chemistry behind the reaction of the ureido group of citrulline with 2,3-butanedione in the presence of antipyrine is unraveled. Parameters for optimization of the reaction with respect to specificity and completeness, including the testing of different acids, reactant concentrations, and reaction time, are presented. This modification reaction is specific for citrulline residues. The modified product shows a characteristic mass shift of +238Da, as demonstrated by mass spectrometry. The product absorbs UV-Vis radiation at 464nm, and it is demonstrated that this can be used to selectively monitor citrulline-containing peptides during the separation of protein digests. Finally, the structure of the product of modified citrulline is solved by nuclear magnetic resonance spectroscopy using N-butylurea as a model substance. The results presented should facilitate the development of tags that can be used for the enrichment and subsequent detection of citrulline-containing protein fragments by mass spectrometry.