Chromatographic analysis of the acidic and basic species of recombinant monoclonal antibodies

The existence of multiple variants with differences in either charge, molecular weight or other properties is a common feature of monoclonal antibodies. These charge variants are generally referred to as acidic or basic compared with the main species. The chemical nature of the main species is usually well-understood, but understanding the chemical nature of acidic and basic species, and the differences between all three species, is critical for process development and formulation design. Complete understanding of acidic and basic species, however, is challenging because both species are known to contain multiple modifications, and it is likely that more modifications may be discovered. This review focuses on the current understanding of the modifications that can result in the generation of acidic and basic species and their affect on antibody structure, stability and biological functions. Chromatography elution profiles and several critical aspects regarding fraction collection and sample preparations necessary for detailed characterization are also discussed.     

Charge variants in IgG1

Antibody charge variants have gained considerable attention in the biotechnology industry due to their potential influence on stability and biological activity. Subtle differences in the relative proportions of charge variants are often observed during routine biomanufacture or process changes and pose a challenge to demonstrating product comparability. To gain further insights into the impact on biological activity and pharmacokinetics (PK) of monoclonal antibody (mAb) charge heterogeneity, we isolated the major charge forms of a recombinant humanized IgG1 and compared their in vitro properties and in vivo PK. The mAb starting material had a pI range of 8.7-9.1 and was composed of about 20% acidic variants, 12% basic variants, and 68% main peak. Cation exchange displacement chromatography was used to isolate the acidic, basic, and main peak fractions for animal studies. Detailed analyses were performed on the isolated fractions to identify specific chemical modification contributing to the charge differences, and were also characterized for purity and in vitro potency prior to being administered either subcutaneously (SC) or intravenously (IV) in rats. All isolated materials had similar potency and rat FcRn binding relative to the starting material. Following IV or SC administration (10 mg/kg) in rats, no difference in serum PK was observed, indicating that physiochemical modifications and pI differences among charge variants were not sufficient to result in PK changes. Thus, these results provided meaningful information for the comparative evaluation of charge-related heterogeneity of mAbs, and suggested that charge variants of IgGs do not affect the in vitro potency, FcRn binding affinity, or the PK properties in rats.     

Cell culture media supplementation of bioflavonoids for the targeted reduction of acidic species charge variants on recombinant therapeutic proteins

Charge variants in recombinant proteins are an important series of protein modifications, whose potential role on protein stability, activity, immunogenicity, and pharmacokinetics continues to be studied. Monoclonal antibodies in particular have been shown to have a wide range of acidic species variants, including those associated with the addition of covalent modifications as well as the chemical degradation at specific peptide regions on the antibody. These variants play a significant role toward the overall heterogeneity of recombinant therapeutic proteins and are typically monitored during manufacturing to ensure they lie within proven acceptable ranges. In this work, it has been found that the supplementation of members of the bioflavonoid chemical family into mammalian cell culture media was effective toward the reduction of acidic species charge variants on recombinant monoclonal antibodies and dual variable domain immunoglobulins. The demonstrated reduction in acidic species through the use of bioflavonoids facilitates the manufacturing of a less heterogeneous product with potential improvements in antibody structure and function. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:1039–1052, 2015     

Elucidating the effects of pH shift on IgG1 monoclonal antibody acidic charge variant levels in Chinese hamster ovary cell cultures

Charge variants, especially acidic charge variants, in recombinant monoclonal antibodies are critical quality attributes, which can affect antibodies’ properties in vitro and in vivo. Meanwhile, charge variants are cumulative effects of various post-translational modifications and chemical degradations on antibody. In this work, to investigate the effect of lowering culture pH in the stationary phase on acidic charge variant contents in fed-batch cultures and its mechanism, cell culture experiments in 2-L bioreactors were firstly performed to explore the changes in the charge distribution under the pH downshift condition using weak cation exchange chromatography. It is found that acidic charge variant contents were significantly decreased by pH downshift. Then, to reveal the mechanism by which the content of acidic charge variants is reduced under pH downshift condition, the variation of post-translational modifications and chemical degradations under the pH downshift condition was explored. Meanwhile, the structure of the acidic charge variants was characterized. Several analysis experiments including size exclusion chromatography, capillary electrophoresis-sodium dodecyl sulfate under non-reducing conditions, tryptic peptide map, and reduced antibody mass were applied in this study. The results show that the mechanism by which the content of acidic charge variants is reduced is that the contents of disulfide bond reduction, galactosylation, and asparagine deamination of the HC-N388 in the Fc domain were reduced by pH downshift.     

Charge variants in IgG1: Isolation,characterization, in vitro binding properties and pharmacokinetics in rats

Antibody charge variants have gained considerable attention in the biotechnology industry due to their potential influence on stability and biological activity. Subtle differences in the relative proportions of charge variants are often observed during routine biomanufacture or process changes and pose a challenge to demonstrating product comparability. To gain further insights into the impact on biological activity and pharmacokinetics (PK) of monoclonal antibody (mAb) charge heterogeneity, we isolated the major charge forms of a recombinant humanized IgG1 and compared their in vitro properties and in vivo PK. The mAb starting material had a pI range of 8.7–9.1 and was composed of about 20% acidic variants, 12% basic variants and 68% main peak. Cation exchange displacement chromatography was used to isolate the acidic, basic and main peak fractions for animal studies. Detailed analyses were performed on the isolated fractions to identify specific chemical modification contributing to the charge differences and were also characterized for purity and in vitro potency prior to being administered either subcutaneously (SC) or intravenously (IV) in rats. All isolated materials had similar potency and rat FcRn binding relative to the starting material. Following IV or SC administration (10 mg/kg) in rats, no difference in serum PK was observed, indicating that physiochemical modifications and pI differences among charge variants were not sufficient to result in PK changes. Thus, these results provided meaningful information for the comparative evaluation of charge-related heterogeneity of mAbs and suggested that charge variants of IgGs do not affect the in vitro potency, FcRn binding affinity or the PK properties in rats.Key words: mAb IgG1, charge heterogeneity, isoelectric point, neonatal Fc receptor (FcRn), pharmacokinetics, potency     

Modulating cell culture oxidative stress reduces protein glycation and acidic charge variant formation

Controlling acidic charge variants is critical for an industrial bioprocess due to the potential impact on therapeutic efficacy and safety. Achieving a consistent charge variant profile at manufacturing scale remains challenging and may require substantial resources to investigate effective control strategies. This is partially due to incomplete understanding of the underlying causes for charge variant formation during the cell culture process. To address this gap, we examined the effects of four process input factors (temperature, iron concentration, feed media age, and antioxidant (rosmarinic acid) concentration) on charge variant profile. These factors were found to affect the charge profile by modulating the cell culture oxidative state. Process conditions with higher acidic peaks corresponded to elevated supernatant peroxide concentration, intracellular reactive oxygen species (ROS) levels, or both. Changes in glycation level were the primary cause of the charge heterogeneity, and for the first time, supernatant peroxide was found to positively correlate with glycation levels. Based on these findings, a novel mathematical model was developed to demonstrate that the rate of acidic species formation was exponentially proportional to the concentrations of supernatant peroxide and protein product. This work provides critical insights into charge variant formation during the cell culture process and highlights the importance of modulating of cell culture oxidative stress for charge variant control.     

Unbiased in-depth characterization of CEX fractions from a stressed monoclonal antibody by mass spectrometry

Characterization of charge-based variants by mass spectrometry (MS) is required for the analytical development of a new biologic entity and its marketing approval by health authorities. However, standard peak-based data analysis approaches are time-consuming and biased toward the detection, identification, and quantification of main variants only. The aim of this study was to characterize in-depth acidic and basic species of a stressed IgG1 monoclonal antibody using comprehensive and unbiased MS data evaluation tools. Fractions collected from cation ion exchange (CEX) chromatography were analyzed as intact, after reduction of disulfide bridges, and after proteolytic cleavage using Lys-C. Data of both intact and reduced samples were evaluated consistently using a time-resolved deconvolution algorithm. Peptide mapping data were processed simultaneously, quantified and compared in a systematic manner for all MS signals and fractions. Differences observed between the fractions were then further characterized and assigned. Time-resolved deconvolution enhanced pattern visualization and data interpretation of main and minor modifications in 3-dimensional maps across CEX fractions. Relative quantification of all MS signals across CEX fractions before peptide assignment enabled the detection of fraction-specific chemical modifications at abundances below 1%. Acidic fractions were shown to be heterogeneous, containing antibody fragments, glycated as well as deamidated forms of the heavy and light chains. In contrast, the basic fractions contained mainly modifications of the C-terminus and pyroglutamate formation at the N-terminus of the heavy chain. Systematic data evaluation was performed to investigate multiple data sets and comprehensively extract main and minor differences between each CEX fraction in an unbiased manner.     

Investigation of the correlation between charge and glycosylation of IgG1 variants by liquid chromatography–mass spectrometry

A recombinant IgG1 monoclonal antibody (mAb) showed multiple charge variants in a cation exchange chromatography profile. To better understand the correlation between charge heterogeneity and glycosylation, a rapid reversed phase ultra-performance liquid chromatography–mass spectrometry (UPLC–MS) method with integrated mass analysis has been developed for simultaneous determination of N-terminal pyroglutamate, C-terminal lysine truncation, and Fc glycosylation. The results show that various degrees and/or types of N-terminal pyroglutamate formation and C-terminal lysine (Lys) cleavage account for the majority of charge heterogeneity; and the charge variants showed Fc glycosylation patterns in relation to their terminal modifications. The amount of G1F decreased in the basic variants, whereas Man5 and G0F-GN increased. The complement-dependent cytotoxicity (CDC) activity of purified charge variants also suggested the potential impact of the charge differences on the glycosylation profile.     

Impact of mammalian cell culture conditions on monoclonal antibody charge heterogeneity: an accessory monitoring tool for process development

Recombinant monoclonal antibodies are predominantly produced in mammalian cell culture bioprocesses. Post-translational modifications affect the micro-heterogeneity of the product and thereby influence important quality attributes, such as stability, solubility, pharmacodynamics and pharmacokinetics. The analysis of the surface charge distribution of monoclonal antibodies provides aggregated information about these modifications. In this work, we established a direct injection pH gradient cation exchange chromatography method, which determines charge heterogeneity from cell culture supernatant without any purification steps. This tool was further applied to monitor processes that were performed under certain process conditions. Concretely, we were able to provide insights into charge variant formation during a fed-batch process of a Chinese hamster ovary cell culture, in turn producing a monoclonal antibody under varying temperatures and glucose feed strategies. Glucose concentration impacted the total emergence of acidic variants, whereas the variation of basic species was mainly dependent on process temperature. The formation rates of acidic species were described with a second-order reaction, where a temperature increase favored the conversion. This platform method will aid as a sophisticated optimization tool for mammalian cell culture processes. It provides a quality fingerprint for the produced mAb, which can be tested, compared to the desired target and confirmed early in the process chain.

     

Digital twin of a continuous chromatography process for mAb purification: Design and model-based control

Model-based design of integrated continuous train coupled with online process analytical technology (PAT) tool can be a potent facilitator for monitoring and control of Critical Quality Attributes (CQAs) in real time. Charge variants are product related variants and are often regarded as CQAs as they may impact potency and efficacy of drug. Robust pooling decision is required for achieving uniform charge variant composition for mAbs as baseline separation between closely related variants is rarely achieved in process scale chromatography. In this study, we propose a digital twin of a continuous chromatography process, integrated with an online HPLC-PAT tool for delivering real time pooling decisions to achieve uniform charge variant composition. The integrated downstream process comprised continuous multicolumn capture protein A chromatography, viral inactivation in coiled flow inverter reactor (CFIR), and multicolumn CEX polishing step. An online HPLC was connected to the harvest tank before protein A chromatography. Both empirical and mechanistic modeling have been considered. The model states were updated in real time using online HPLC charge variant data for prediction of the initial and final cut point for CEX eluate, according to which the process chromatography was directed to switch from collection to waste to achieve the desired charge variant composition in the CEX pool. Two case studies were carried out to demonstrate this control strategy. In the first case study, the continuous train was run for initially 14 h for harvest of fixed charge variant composition as feed. In the second case study, charge variant composition was dynamically changed by introducing forced perturbation to mimic the deviations that may be encountered during perfusion cell culture. The control strategy was successfully implemented for more than ±5% variability in the acidic variants of the feed with its composition in the range of acidic (13%–17%), main (18%–23%), and basic (59%–68%) variants. Both the case studies yielded CEX pool of uniform distribution of acidic, main and basic profiles in the range of 15 ± 0.8, 31 ± 0.3, and 53 ± 0.5%, respectively, in the case of empirical modeling and 15 ± 0.5, 31 ± 0.3, and 53 ± 0.3%, respectively, in the case of mechanistic modeling. In both cases, process yield for main species was >85% and the use of online HPLC early in the purification train helped in making quicker decision for pooling of CEX eluate. The results thus successfully demonstrate the technical feasibility of creating digital twins of bioprocess operations and their utility for process control.     

Chlorophylla biosynthetic routes and chlorophylla chemical heterogeneity in plants

A six-branched chlorophyll a biosynthetic pathway instead of a four-branched pathway has been proposed as being responsible for the formation of chlorophyll a in green plants. The several biosynthetic routes that make up the pathway have been described as leading to the formation of ten chemically different groups of chlorophyll a species. The latter differ from one another by one or more of the following modifications: (a) by having a vinyl or ethyl group at position 4 of the macrocycle, (b) by the nature of the long-chain fatty alcohols at position 7 of the macrocycle, and (c) by having a 6-membered lactone ring instead of a 5-membered cyclopentanone ring. The chemical structure of several of the metabolic intermediates of that pathway and of some of the chlorophyll a species have now been determined by primary chemical derivatization methods coupled to spectrofluorometric, nuclear magnetic resonance and mass spectral analyses. The formation of highly organized photosynthetic membranes in which some of the chlorophyll alpha molecules are specifically oriented is ascribed to the multiplicity of chlorophyll biosynthetic routes which result in the formation of multiple chlorophyll alpha chemical species. Proper orientation of chlorophyll in the photosynthetic membranes is visualized as being controlled by peripheral group modifications that either modulate the polarity of the Chl chromophore or control the magnitude of the net positive charge on the central Mg atom. Finally it is proposed that in addition to the proper orientation of chlorophyll a, chemical heterogeneity of the chlorophyll chromophores in the photosynthetic reaction centers is mandatory for efficient charge separation, and proper vectorial electron transfer.     

Characterization of Myelin Basic Protein Charge Microheterogeneity in Developing Mouse Brain and in the Transgenic Shiverer Mutant

Abstract: Myelin basic protein (MBP) is a highly heterogeneous family of membrane proteins consisting of several isoforms resulting from alternative splicing and charge isomers arising from posttranslational modifications. Although well characterized in the bovine and human species, those in the mouse are not. With the availability of a number of transgenic and knockout mice, the need to understand the chemical nature of the MBPs has become very important. To isolate and characterize the MBP species in murine brain, two methods were adapted for use with the small amounts of MBP available from mice. The first was a scaled-down version of the preparative CM-52 chromatographic system commonly used to isolate MBP charge isomers; the second was an alkaline-urea slab gel technique that required five times less material than the conventional tube gel system and, from these gels, western blots were readily obtained. Murine MBP was resolved into two populations of charge isomers: the 18.5- and 14-kDa isoforms. Isolation and characterization of these charge isomers or components permitted us to assign possible posttranslational modifications to some of them. Component 1 (C-1), the most cationic isomer, had a molecular weight of 14,140.38 ± 0.79. C-2 consisted of two 14-kDa species, 14,136.37 ± 0.74 and 14,204.45 ± 0.70. Two variants, 14,215.57 ± 0.94 and 18,413.57 ± 0.76, constituted C-3. C-4, C-5, and C-8 (the least cationic isomer) each consisted of both 14- and 18.5-kDa isoforms. During myelinogenesis, the 18.5-kDa isoform appeared first (day 4); the 14-kDa isoform appeared at day 16 and subsequently became the dominant isoform. The transgenic shiverer mutant synthesized mainly the 18.5-kDa isoform, but none of the 14-kDa isoform, similar to the 4-day-old mouse. We concluded that the trangenic shiverer was able to initiate myelinogenesis with the 18.5-kDa isoform, but was unable to complete myelinogenesis because of the absence of the 14-kDa isoform.     

Modifications of nucleosides by endogenous mutagens-DNA adducts arising from cellular processes

DNA damage plays a significant role in mutagenesis, carcinogenesis and ageing. Chemical transformations leading to DNA damage include reactions of the base units with agents of endogenous and exogenous origin. The vast majority of damage arising from cellular processes such as metabolism and lipid peroxidation are identical or very similar to those induced by exposure to environmental agents. A detailed knowledge of the types and prevalence of endogenous DNA damage provides insight into the chemical nature of species involved in these modifications and may be of help in understanding their influence on the induction of cancer or other diseases. This knowledge may also be essential to the development of rational chemopreventive strategies directed against the initiation of oxidative stress- and lipid peroxidation-associated pathology.The present work reviews findings regarding the interaction between DNA bases and various reactive species arising from lipid peroxidation and other cellular processes, drawing attention to the mechanism responsible for the formation of the resulted modifications. The biological consequences of these interactions are also briefly discussed.     

Stress-mediated adaptive response leading to genetic diversity and instability in metabolite contents of high medicinal value: an overview on Podophyllum hexandrum

Podophyllum hexandrum, known for its diversified clinical importance particularly for antineoplastic activity and valuable source for biological protection against high doses of radiation, has its unique position in the plant kingdom. Detailed understanding of mechanism and opportunity of chemical manipulations has amplified the scope of its bioactivity. Podophyllotoxin, the major active principle of this plant, has passed through various structural deviations with the basic aim of making the end product clinically more effective with minimal toxicity. However, over exploitation and limited growth has categorized this plant under endangered species. Depending upon the geographical variations, different species and subspecies of this plant have been explored. Morphological variations and quantitative differences in active principles are the major concern of its unstable medicinal value in whole and semifractionated preparations. The current review has addressed the issues related to the genetic diversity of P. hexandrum, extrinsic and intrinsic stresses responsible for its diversified nature, chemical modifications to enhance its multitasking bioactivity, and efforts for its cultivation and production of important metabolites to avoid collection of wild species due to its critically endangered nature.     

Multiple molecular forms of mouse liver arginase

Hepatic arginase (L-arginine amidinohydrolase, EC 3.5.3.1) is an oligomer composed of three or four subunits. The present studies indicate heterogeneity in the size and charge of arginase subunits in mouse liver. Two types of arginase subunits with molecular weights of approximately 35,000 and 38,000 have been found. These two subunits are detected in liver cytosol or in purified preparations of arginase after sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western blotting. Two dimensional SDS-PAGE revealed multiple ionic forms of arginase for both the 35,000 and 38,000 subunits; the subunits contain basic proteins (pI range 7.8-9.1) and acidic proteins (pI range 5.8-6.4). Limited proteolysis by trypsin eliminated the molecular weight differences between the subunits without substantially affecting either their isoelectric points or activity. Comparative peptide maps and amino acid analyses of the 35,000- and 38,000-Da subunits showed that they were very similar. The data indicate that a neutral peptide (approx 3000 Da) is responsible for the differences in subunit molecular weight and that the multiple sized and charged forms are variants of the same protein.     

离子交换色谱对抗VEGFR2单抗的电荷异质性分析

目的采用离子交换高效液相色谱(CEX-HPLC)分析抗VEGFR2(抗血管内皮生长因子受体2)单抗制品的电荷异质性。方法应用CEX-HPLC技术,对VEGFR2单抗进行电荷异质性分析,并结合羧肽酶B(CpB)和N-糖酰胺酶F(EndoF2)酶切,初步研究其电荷异质性的成因。结果用CEX-HPLC分析CpB酶切前后单抗,证明其碱性变异体主要由C末端赖氨酸不均一性引起;分析EndoF2酶切前后处理的单抗,证明其酸性变异体部分由N-糖末端上的唾液酸修饰所引起。通过2种酶的顺序酶切可相对准确地分析含C-末端赖氨酸以及含唾液酸单抗的比例。结论采用CEX-HPLC可较好地分析单抗的电荷异质性;并结合合适的酶切处理,可判断单抗主要电荷异质性的来源,为保证单抗制品生产工艺的稳定性及质量控制提供了有效手段。     

Free energies of protein-protein association determined by electrospray ionization mass spectrometry correlate accurately with values obtained by solution methods

The advantages of electrospray ionization mass spectrometry (ESIMS) to measure relative solution-phase affinities of tightly bound protein-protein complexes are demonstrated with selected variants of the Bacillus amyloliquefaciens protein barstar (b*) and the RNAase barnase (bn), which form protein-protein complexes with a range of picomolar to nanomolar dissociation constants. A novel chemical annealing procedure rapidly establishes equilibrium in solutions containing competing b* variants with limiting bn. The relative ion abundances of the complexes and those of the competing unbound monomers are shown to reflect the relative solution-phase concentrations of those respective species. No measurable dissociation of the complexes occurs either during ESI or mass detection, nor is there any evidence for nonspecific binding at protein concentrations < 25 microM. Differences in DeltaDeltaG of dissociation between variants were determined with precisions < 0.1 kcal/mol. The DeltaDeltaG values obtained deviate on average by 0.26 kcal/mol from those measured with a solution-phase enzyme assay. It is demonstrated that information about the protein conformation and covalent modifications can be obtained from differences in mass and charge state distributions. This method serves as a rapid and precise means to interrogate protein-protein-binding surfaces for complexes that have affinities in the picomolar to nanomolar range.     

The species concept as an emergent property of population biology

Resurgent interest in the genetics of population divergence and speciation coincides with recent critical evaluation of species concepts and proposals for species delimitation. An important result of these parallel trends is a slight but important conceptual shift in focus away from species diagnoses based on prior species concepts or definitions, and toward analyses of the processes acting on lineages of metapopulations that eventually lead to differences recognizable as species taxa. An advantage of this approach is that it identifies quantitative metapopulation differences in continuous variables, rather than discrete entities that do or do not conform to a prior species concept, and species taxa are recognized as an emergent property of population-level processes. The tension between species concepts and diagnosis versus emergent recognition of species taxa is at least as old as Darwin, and is unlikely to be resolved soon in favor of either view, because the products of both approaches (discrete utilitarian taxon names for species, process-based understanding of the origins of differentiated metapopulations) continue to have important applications.     

An examination of the peroxidases from Lupinus albus L. hypocotyls

Peroxidases (EC 1.11.1.7) from hypocotyls of Lupinus albus L. cv. Rio Maior have been characterised using one- and two-dimensional, native electrophoretic techniques. Data are presented showing the complexity in charge and molecular size or shape of these peroxidases. We report the finding of a new acidic peroxidase and several new basic peroxidases in these hypocotyls, and of their stability to treatments considered to break ligand-induced variants and conformational variants derived from differences in polypeptide folding. Densitometric data demonstrate that these new peroxidases contribute up to 60 of the total peroxidase activity in hypocotyls. Studies of intercellular fluid, cell-wall and soluble fractions, with assays of purity were conducted in an attempt to define the subcellular locations of these additional peroxidases. The acidic form (pI 4.1) is greatly enriched in soluble fractions, three of the basic peroxidases (pIs 9.5, 9.7 and >9.7) are strongly associated to the cell wall, ad a minor, basic component (pI 9.7) is enriched in the intercellular fluid. Individual peroxidase activities with the substrates coniferyl alcohol, ferulic acid or indole acetic acid were compared by densitometric analysis of zymograms with those for guaiacol, and notable differences between these peroxidases in their capacity to oxidise indole acetic acid in vitro were identified. The possible functions of these peroxidases in vivo and their implications to current understanding of peroxidases in L. albus are discussed.Abbreviations APAGE anionic polyacrylamide gel electrophoresis - CA coniferyl alcohol - CPAGE cationic polyacrylamide gel electrophoresis - IEF isoelectric focusin - NEIEF non-equilibrated isoelectric focusing - 2D two dimensional - pI isoelectric point - RCPAGE reversed current polyacrylamide gel electrophoresis     

Intracellular turnover of stable and labile soluble liver proteins

The cytosol proteins of mouse or rat liver were separated on the basis of charge and characterized with respect to molecular size, turnover in vivo, and several chemical properties. The basic proteins, which were synthesized and degraded slower than acidic proteins, were generally smaller, as multimers and subunits, than the acidic proteins. Charge and size, therefore, did not appear to be independent characteristics for soluble liver proteins. The amino acid composition of the smaller, basic, stable proteins was very similar to that of the larger, acidic, labile proteins. The charge differences between these two protein fractions could be attributed to the ratio of acidic to basic amino acid residues rather than to carbohydrate, nucleic acid, or phosphate content. The percentage of hydrophobic amino acid residues in the two protein fractions was the same. The acidic labile proteins were more vulnerable to proteolysis and associated with the lysosomal-mitochondrial fractions somewhat more extensively in vitro than the basic, stable proteins. These studies indicate that the information determining the half-lives of soluble enzymes is in the protein moiety of those enzymes and that the factors that correlate with turnover may not be independent variables for soluble mammalian proteins.