Investigating residual trace metals in recombinant monoclonal antibodies to facilitate drug development with LC-UV-ICPMS-HRMS.

Background: The biopharmaceutical industry is increasingly interested in the analysis of trace metals due to their significant impact on product quality and drug safety. Certain metals can potentially accelerate the formation of degradants or aggregates in biotherapeutic proteins, leading to drug product quality concerns. A better understanding of metal-mAb interactions would aid in the development of purification processes and formulations, thereby ensuring better drug quality and safety.

Characterization of Therapeutic Antibody Charge Heterogeneity Under Stress Conditions by Microfluidic Capillary Electrophoresis Coupled with Mass Spectrometry.

Therapeutic antibodies are a major class of biopharmaceutics that are applied in disease treatment because of their many advantages, including high specificity and high affinity to molecular targets. Between their production and administration, therapeutic antibodies are exposed to multiple stress conditions. Forced degradation and stress stability studies are conducted to simulate the risk of degradation and the effects of these stresses, thereby enhancing understanding of the drug product to support strategies to mitigate the impact from stressed conditions.

High-sensitivity and high-resolution therapeutic antibody charge variant and impurity characterization by microfluidic native capillary electrophoresis-mass spectrometry.

Therapeutic antibodies are a major class of pharmaceutical drugs used to treat a wide variety of diseases. They have several advantages including the high specificity and binding affinity to their molecular targets, and generally low immunotoxicity and mild adverse effects. The characterization of therapeutic antibodies is crucial to ensure drug efficacy and safety.

High sensitivity and high-confidence compound identification with a flexible BoxCar acquisition method.

Liquid chromatography-mass spectrometry (LC-MS) is in wide use for compound identification and quantification in complex matrices. While advances in mass spectrometry and the incorporation of new acquisition methods have resulted in greatly improved detection, there is an ongoing need to expand the limits of highly sensitive and confident identification of low abundance species in complex samples. The data acquisition method known as "BoxCar" was originally designed to achieve in-depth proteome profiling on an Orbitrap mass analyzer by decomposing ions into segments with narrow m/z windows.

Integrated Use of Biochemical, Native Mass Spectrometry, Computational, and Genome-Editing Methods to Elucidate the Mechanism of a Salmonella deglycase.

Salmonellais a foodborne pathogen that causes annually millions of cases of salmonellosis globally, yet Salmonella-specific antibacterials are not available. During inflammation, Salmonella utilizes the Amadori compound fructose-asparagine (F-Asn) as a nutrient through the successive action of three enzymes, including the terminal FraB deglycase. Salmonella mutants lacking FraB are highly attenuated in mouse models of inflammation due to the toxic build-up of the substrate 6-phosphofructose-aspartate (6-P-F-Asp).

Salmonella-Mediated Inflammation Eliminates Competitors for Fructose-Asparagine in the Gut.

elicits intestinal inflammation to gain access to nutrients. One of these nutrients is fructose-asparagine (F-Asn). The availability of F-Asn to during infection is dependent upon pathogenicity islands 1 and 2, which in turn are required to provoke inflammation.

Measurement of Fructose-Asparagine Concentrations in Human and Animal Foods.

The food-borne bacterial pathogen, Salmonella enterica, can utilize fructose-asparagine (F-Asn) as its sole carbon and nitrogen source. F-Asn is the product of an Amadori rearrangement following the nonenzymatic condensation of glucose and asparagine. Heating converts F-Asn via complex Maillard reactions to a variety of molecules that contribute to the color, taste, and aroma of heated foods.

Chemical and pathogen-induced inflammation disrupt the murine intestinal microbiome.

Background: Salmonella is one of the most significant food-borne pathogens to affect humans and agriculture. While it is well documented that Salmonella infection triggers host inflammation, the impacts on the gut environment are largely unknown. A CBA/J mouse model was used to evaluate intestinal responses to Salmonella-induced inflammation.

A metabolic intermediate of the fructose-asparagine utilization pathway inhibits growth of a Salmonella fraB mutant.

Insertions in the Salmonella enterica fra locus, which encodes the fructose-asparagine (F-Asn) utilization pathway, are highly attenuated in mouse models of inflammation (>1000-fold competitive index). Here, we report that F-Asn is bacteriostatic to a fraB mutant (IC50 19 μM), but not to the wild-type or a fra island deletion mutant. We hypothesized that the presence of FraD kinase and absence of FraB deglycase causes build-up of a toxic metabolite: 6-phosphofructose-aspartate (6-P-F-Asp).