Cell cycle kinetics of the accumulation of heavy and light chain immunoglobulin proteins in a mouse hybridoma cell line

Rates of accumulation of immunoglobulin proteins have been determined using flow cytometry and population balance equations for exponentially growing murine hybridoma cells in the individual G₁, S and G₂+M cell cycle phases. A producer cell line that secretes monoclonal antibodies, and a nonproducer clone that synthesizes only -light chains were analyzed. The pattern for the kinetics of total intracellular antibody accumulation during the cell cycle is very similar to the previously described pattern for total protein accumulation (Kromenaker & Srienc 1991). The relative mean rate of heavy chain accumulation during the S phase was approximately half the relative mean rate of light chain accumulation during this cell cycle phase. This indicates an unbalanced synthesis of heavy and light chains that becomes most pronounced during this cell cycle phase. The nonproducer cells have on average an intracellular light chain content that is 42% lower than that of the producer cells. The nonproducer cells in the G₁ phase with low light chain content did not have a significantly higher rate of light chain accumulation relative to other G₁ phase nonproducer cells. This is in sharp contrast to what was observed for the G₁ phase producer cells. In addition, although the relative mean rate of accumulation of light chain was negative for G₂+M phase nonproducer cells, the magnitude of this relative mean rate was less than half that observed for the producer cells in this cell cycle phase. This suggests that the mechanisms that regulate the transport of fully assembled antibody molecules through the secretion pathway differ from those which regulate the secretion of free light chains. The results reported here indicate that there is a distinct pattern for the cell cycle dynamics of antibody synthesis and secretion in hybridomas. These results are consistent with a model for the dynamics of secretion which suggests that the rate of accumulation of secreted proteins will be greatest for newborn cells due to an interruption of the secretion pathway during mitosis.     

Cell-cycle-dependent protein accumulation by producer and nonproducer murine hybridoma cell lines: a population analysis

Single-cell rates of accumulation of cellular protein have been determined as a function of total protein content using flow cytometry and population balance equations for exponentially growing murine hybridoma cells in the individual G(1), S(1) and G(2) + M cell cycle phases. A novel flow cytometric technique for the identification of hybridoma cells in mitosis was developed and implemented. The data were obtained from a producer cell line which synthesizes and secretes high levels of monoclonal antibodies, and from a nonproducer clone which does not synthesize and secrete substantial amounts of antibody. The results indicate that the kinetics of single-cell protein accumulation in these two cell lines are considerably different. In particular, low protein content G(1) phase producer cells were characterized by a rate of protein accumulation which was approximately five times higher than the mean rate observed for higher protein content producer cells cycle phase. In contrast, the rate of accumulation of protein increased continuously with totalprotein content for the G(1) phase nonproducer cells. S phase hybridoma cells were characterized by a considerably lower rate of protein accumulation which did not vary much with protein content for either cell line. Finally, G(2) + M phase producer cells demonstrated a negative rate of protein accumulation which indicates that the rates of protein synthesis. It was hypothesized that these differences in total protein accumulation are caused by differences in monoclonal antibody accumulation. The distribution of rates suggests the need for a segregated approach to the modeling of the kinetics of antibody production in hybridomas.     

Characterization of cross-reacting antigens on the Epstein-Barr virus envelope and plasma membranes of producer cells.

A rabbit antiserum has been prepared against the B95-8 transforming strain of EBV. The antiserum has a high virus neutralizing titer (approximately 1:1000) against both the marmoset B95-8 EBV and the human P3HR-1 EBV. The neutralizing antibodies may be absorbed completely with EBV producer cell lines, but not with nonproducer cell lines or producer cell lines treated with phosphonoacetic acid (PAA) so as to be nonproducer. After repeated absorption with PAA-treated B95-8, the serum remains reactive with the membranes of producer cell lines as judged by immunofluorescence or the 125I--Staphylococcal protein A radioimmunoassay. Thus the neutralizing antigens are expressed on the membranes of producer cell lines and may be purified from this source using the serum and 125I--Staph A binding as an assay. The ability of the serum to differentiate between producer and nonproducer cells by means of cell surface determinants has been exploited to achieve a separation of these two populations from the same culture. Immunoprecipitation by the protein A technique shows that the serum recognizes two polypeptides from producer cells of approximate molecular weights 150,000 and 75,000.     

A model of interorganelle monoclonal antibody transport and secretion in mouse hybridoma cells

A three compartment model (ER --> Golgi --> extracellular medium) is used here to describe the interorganelle transport and final secretion of an IgG(2a) monoclonal antibody (MAb) in 9.2.27 murine hybridoma cells. Model simulations of pulse-chase and continuous labeling experiments are used to gain a better understanding of the kinetics of MAb interorganelle traffic. Simulation results for the continuous labeling case compare well with experimental data obtained during continuous labeling of 9.2.27 hybridoma cells. Incorporation of this compartmental transport model into our previously developed model of MAb synthesis and assembly can provide a useful tool for analyzing the dynamics and regulation of the complete antibody secretory pathway under different growth and/or nutritional conditions.     

Epitope map for a growth hormone receptor agonist monoclonal antibody,MAb 263

Monoclonal antibody (MAb) 263 is a widely used monoclonal antibody that recognizes the extracellular domain (ECD) of the GH receptor. It has been shown to act as a GH agonist both in vitro and in vivo, and we report here that it must be divalent to exert its effect on the full-length receptor. To understand the mechanism of its agonist action, we have determined the precise epitope for this antibody using a novel random PCR mutagenesis approach together with expression screening in yeast. A library of 5200 clones of rabbit GH receptor ECD mutants were screened both with MAb 263 and with an anticarboxy-tag antibody to verify complete ECD expression. Sequencing for clones that expressed complete ECD but were not MAb 263 positive identified 20 epitope residues distributed in a discontinuous manner throughout the ECD. The major part of the epitope, as revealed after mapping onto the crystal structure model of the ECD molecule, was located on the side and upper portion of domain 1, particularly within the D-E strand disulfide loop 79-96. Molecular dynamics docking of an antibody of the same isotype as MAb 263 was used to dock the bivalent antibody to the 1528-A2 epitope and to visualize the likely consequences of MAb binding. The minimized model enables the antibody to grasp two receptors in a pincer-like movement from opposite sides, facilitating alignment of the receptor dimerization domains in a manner similar to, but not identical with, GH.     

Acquisition of an anti-idiotypic cytotoxic T lymphocyte repertoire in B cell-transferred or tetraparental bone marrow chimeric mice

In previous studies we showed that major histocompatibility complex-restricted cytotoxic T lymphocytes (CTL) specific for the cross-reactive idiotype (CRI) of MOPC-104E myeloma protein could only be induced in BALB/c or BAB-14 mice which have the ability to produce the CRI, but not in C.AL-20 or C.B-20 mice which have no ability to produce the CRI. The strong correlation between CRI-specific CTL responder strains and CRI producers supports the idea that the VH gene products are intrinsic primary antigenic stimuli for the generation of the anti-idiotypic CTL. To investigate the role of B lymphocytes in the selection of T lymphocyte repertoire, the purified B cells of CRI producer strains were repeatedly injected into anti-CRI CTL nonresponder neonatal mice. CRI-specific CTL activity was successfully induced in the CRI nonproducer mice only when they were exposed to CRI producer strain B lymphocytes from neonatal life. When the CTL nonresponder adult mice received CRI producer B lymphocytes, the nonresponder phenotype was not changed into the responder phenotype. Inducibility of CRI-specific CTL was also analyzed in tetraparental bone marrow chimeras. When CRI nonproducer bone marrow cells repopulated along with CRI producer bone marrow cells, the anti-CRI CTL of CRI nonproducer origin were generated. Adaptive differentiation of haplotype preference was also observed. When these observations are taken collectively, we see that the anti-idiotypic T lymphocyte repertoire is not a genetically determined one, but rather that the repertoire of T lymphocytes strongly depends on the postnatal selection process through the intrinsic idiotypic repertoire of B lymphocytes, i.e., internal images.     

An HIV-1 gp120 envelope human monoclonal antibody that recognizes a C1 conformational epitope mediates potent antibody-dependent cellular cytotoxicity (ADCC) activity and defines a common ADCC epitope in human HIV-1 serum

Among nonneutralizing HIV-1 envelope antibodies (Abs), those capable of mediating antibody-dependent cellular cytotoxicity (ADCC) activity have been postulated to be important for control of HIV-1 infection. ADCC-mediating Ab must recognize HIV-1 antigens expressed on the membrane of infected cells and bind the Fcγ receptor (FcR) of the effector cell population. However, the precise targets of serum ADCC antibody are poorly characterized. The human monoclonal antibody (MAb) A32 is a nonneutralizing antibody isolated from an HIV-1 chronically infected person. We investigated the ability of MAb A32 to recognize HIV-1 envelope expressed on the surface of CD4(+) T cells infected with primary and laboratory-adapted strains of HIV-1, as well as its ability to mediate ADCC activity. The MAb A32 epitope was expressed on the surface of HIV-1-infected CD4(+) T cells earlier than the CD4-inducible (CD4i) epitope bound by MAb 17b and the gp120 carbohydrate epitope bound by MAb 2G12. Importantly, MAb A32 was a potent mediator of ADCC activity. Finally, an A32 Fab fragment blocked the majority of ADCC-mediating Ab activity in plasma of subjects chronically infected with HIV-1. These data demonstrate that the epitope defined by MAb A32 is a major target on gp120 for plasma ADCC activity.     

Necessity for two human chromosomes for human chorionic gonadotropin production in human-mouse hybrids

Through a series of human-mouse hybrids we have identified that two human chromosomes, 10 and 18, must be present for production of the pregnancy protein hormone human chorionic gonadotropin (hCG). Human choriocarcinoma cells producing hCG were hybridized to mouse cells. From 49 independent clones three hybrid clones continued to produce whole hCG. Chromosomal analysis was done on the 3 producer clones and 5 nonproducer clones. The additional 41 nonproducer clones were genetically characterized by isozymes. Only when chromosomes 10 and 18 were present in a clone would the whole hCG molecule be produced. Clones with only 10 or only 18 did not produce hormone. Nine subclones of a producer clone confirmed this observation. Three subclones retaining both 10 and 18 continued to produce hCG. This study demonstrated the need to use cellular chromosome data and population enzyme data to identify two chromosomes necessary for hCG production in heterogeneous human-mouse hybrids.     

The production of monoclonal antibody in growth-arrested hybridomas cultivated in suspension and immobilized modes.

The effects of the microenvironment and the nature of the limiting nutrient on culture viability and overall MAb productivity were explored using a hybridoma cell line which characteristically produces MAb in the stationary phase. A direct comparison was made of the changes in the metabolic profiles of suspension and PEG-alginate immobilized (0.8 mm beads) batch cultures upon entry into the stationary phase. The shifts in glucose, glutamine, and amino acid metabolism upon entry into the stationary phase were similar for both microenvironments. While the utilization of most nutrients in the stationary phase decreased to below 20% of that in the growth phase, antibody production was not dramatically affected. The immobilized culture did exhibit a 1.5-fold increase in the specific antibody rate over the suspension culture in both the growth and stationary phases. The role of limiting nutrient on MAb production and cell viability was assessed by artificially depleting a specific nutrient to 1% of its control concentration. An exponentially growing population of HB121 cells exposed to these various depletions responded with dramatically different viability profiles and MAb production kinetics. All depletions resulted in growth-arrested cultures and nongrowth-associated MAb production. Depletions in energy sources (glucose, glutamine) or essential amino acids (isoleucine) resulted in either poor viability or low antibody productivity. A phosphate or serum depletion maintained antibody production over at least a six day period with each resulting in a 3-fold higher antibody production rate than in growing batch cultures. These results were translated to a high-density perfusion culture of immobilized cells in the growth-arrested state with continued MAb expression for 20 days at a specific rate equal to that observed in the phosphate- and serum-depleted batch cultures.     

Equol production changes over time in postmenopausal women

Equol (EQ) is produced by intestinal bacteria from the soy isoflavone daidzein (DE) in 30%-60% of the population and is believed to provide benefits from soy intake. A robust EQ status definition is lacking, and it is uncertain whether EQ is formed consistently within an individual and ceases upon oral antibiotic treatment. In a randomized, double-blind, placebo-controlled soy intervention trial with 350 postmenopausal women, DE and EQ were analyzed by liquid chromatography/tandem mass spectrometry at baseline and every 6 months over 2.5 years in overnight urine, spot urine and plasma. Equol production changes and status (remaining an EQ producer or nonproducer or changing towards an EQ producer or nonproducer) were assessed. Equol status was determined most dependably by overnight urine applying as cutoff a ratio of EQ/DE≥0.018 with a DE threshold ≥2 nmol/mg creatinine: the soy and placebo groups had approximately 30% consistent EQ producers during the study, but 14% and 35%, respectively, changed EQ status (mean 1.4-1.7 times), while 27% and 17%, respectively, had antibiotic treatment (P<.01 for inverse association). No significant trend in change of EQ production or status was observed when overnight urine was limited to collections closest to before and after antibiotic treatment. Similarly, antibiotic type or class, duration, dose or time between antibiotic treatment and overnight urine collection showed no consistent influence on EQ production. Equol production can markedly change intraindividually over 2.5 years, and antibiotic treatment impacts it inconsistently. Factors other than antibiotic treatment must be considered as causes for EQ production changes.     

Multicoloured greenbeards,bacteriocin diversity and the rock‐paper‐scissors game

Greenbeard genes identify copies of themselves in other individuals and cause their bearer to behave nepotistically towards those individuals. Bacterial toxins (bacteriocins) exemplify the greenbeard effect because producer strains carry closely linked genes for immunity, such that toxicity is limited to nonproducer strains. Bacteriocin producers can be maintained in a dynamic polymorphism, known as rock‐paper‐scissors (RPS) dynamics, with immune and susceptible strains. However, it is unclear whether and how such dynamics will be maintained in the presence of multiple toxin types (multiple beard ‘colours’). Here, we analyse strain dynamics using models of recurrent patch colonization and population growth. We find that (i) polymorphism is promoted by a small number of founding lineages per patch, strong local resource competition and the occurrence of mutations; (ii) polymorphism can be static or dynamic, depending on the intensity of local interactions and the costs of toxins and immunity; (iii) the occurrence of multiple toxins can promote RPS dynamics; and (iv) strain diversity can be maintained even when toxins differ in toxicity or lineages can exhibit multitoxicity/multi‐immunity. Overall, the factors that maintain simple RPS dynamics can also promote the coexistence of multiple toxin types (multiple beard colours), thus helping to explain the remarkable levels of bacteriocin diversity in nature. More generally, we contrast these results with the maintenance of marker diversity in genetic kin recognition.     

Production of a monoclonal antibody specific for Salmonella spp.

A monoclonal antibody (MAb) specific for heat-treated Salmonella spp. which shows no cross-reactivity with other enteric bacteria when tested by an ELISA system, has been developed. The MAb isotype is IgG2a and has been successfully purified using protein A. Preliminary work suggests that the MAb recognizes a protein present in the Boivin lipopolysaccharide extracts of Salmonella spp.     

Stability and localization of biotin-labeled murine monoclonal antibody to human gastric cancer in normal mice and nude mice-human tumor models

We examined the tissue localization of biotin-labeled murine monoclonal antibody (MAb) S202 directed against the human scirrhous gastric carcinoma cell line MK-01 in normal and tumor-bearing mice after intravenous (IV) administration. The biotin-labeled MAb proved to be stable in vivo under normal conditions, antibody titer being 1:256 at 4 hr after IV injection. At 24 hr after injection, the tumor was stained by the avidin-biotin-peroxidase complex (ABC) method. Biotin-labeled MAb was found to be suitable for detection of the xenografted tumor of nude mice. This study provides new information concerning the dynamics of the distribution of biotin-labeled MAb in vivo.     

Kinetic analysis of hybridoma growth and monoclonal antibody production in semicontinuous culture

Hybridoma I.13.17 was grown in semicontinuous culture in an attempt to investigate the steady-state concentrations of key components of monoclonal antibody (MAb) synthesis (e.g., intracellular MAb, IgG messenger RNAs) at different dilution rates between 0.008 and 0.055 h(-1). There was a general trend of increasing steady-state levels of total cytoplasmic RNA, total cell-associated MAb or cytoplasmic MAb, DNA synthesis rate, cellular metabolic activity, heavy (H-) and light (L-) chain IgG mRNAs with the increase in dilution rates. Increase in the half-lives of H- and L-chain mRNAs with increase in dilution rates may be sufficient to account for their increasing levels found under the same conditions. The specific growth rate was profoundly affected by the dilution rate, particularly near the lower end of the dilution rate range. Linear relationships were observed between the steady-state amounts of total cell-associated MAb and the relative levels of H- and L-chain mRNAs. Material balances on intracellular MAb demonstrated an increasing percentage of antibody not released into the growth medium (e.g., stored within the cell or anchored to the cell membrane) with increasing dilution rate. The MAb production rate per cell decreased significantly with the increase in dilution rates. No correlation was found between the relative levels of H- or L-chain mRNAs and the specific MAb production rate. Possible implications of rate-limiting steps in MAb synthesis and secretion are discussed.     

An experimental study and a mathematical model of interactions in mixed culture of invertebrates and algae in the "producer-consumer" aquatic biotic cycle

An experimental investigation was carried out, and a mathematical model of interaction between invertebrates (infusoria Paramecium caudatum and rotifera Brachionus plicatilis) and algae (Chlorella vulgaris and Scenedesmus quadricauda) in the "producer-consumer" aquatic biotic cycle with spatially divided links was constructed. The model describes the dynamics of a mixed culture of infusoria and rotifera in the "consumer" link, when they consume a mixed culture of algae coming from the "producer" link. A negative influence of products of algae Scenedesmus metabolism upon the reproduction of infusoria P. caudatum was revealed. Taking this into account, a qualitative coincidence of the results of mathematical modeling with experimental data was obtained. It was shown that the co-existence of mixed algae culture in the "producer" link with invertebrates in the "consumer" link in the "producer-consumer" aquatic biotic cycle is impossible because of the displacement of infusoria P. caudatum by rotifera Brachionus plicatilis.     

Reactivity of Paul-Bunnell type heterophile antibody in sera from infectious mononucleosis patients with the surface of lymphoid cells carrying Epstein-Barr virus genomes.

The possible presence of Paul-Bunnell (PB) antigen on Epstein-Barr virus (EBV)-transformed lymphocytes were investigated. Of 23 EBV genome-positive lymphoblastoid cell lines tested all but one absorbed PB type antibody from the serum of an infectious mononucleosis patient. The one EBV-negative B cell line tested did not absorb the heterophile antibody. PB antibody, purified by an immunoadsorbent procedure using beef cell antigen, reacted with the EBV producer P3HR-1 cell line in an indirect membrane immunofluorescence test and was shown to be IgM antibody. Titers of heterophile agglutinin and reactivity with the cell surface were reduced to the same degree by absorption with beef cell antigen but not with guinea pig kidney antigen. PB antibody was distinct from IgM antibody against the EBV-determined membrane antigen, since the latter was not absorbed by beef cell antigen. PB antibody was also reactive with other EBV-positive B cell lines (QIMR-WIL, NC-37, and Raji) which were free of surface IgM. No reaction occurred with the nonproducer P3HR-1 line, a null cell line, and two T cell lines. The results suggest the presence of PB antigen on most EBV-transformed B lymphocytes, and its appearance in each of the transformed lymphocytes of patients with acute infectious mononucleosis.     

Synthesis of a Neu2en5Ac analog hapten and isolation of monoclonal antibody to Neu2en5Ac.

Neu2en5Ac is a minor component of body fluids and is abundant in sialuria, but no antibody to detect it has been reported. 5-Acetamido-2,6-anhydro-9-glutaramido-3,5,9-trideoxy-D-glycero-D- galacto-non-2-enonic acid has been synthesized and conjugated with keyhole limpet hemocyanin (KLH) for immunization. A hybridoma named SIC172 was obtained that produces a monoclonal antibody (MAb) to Neu2en5Ac. SIC172 MAb in culture supernatant bound strongly to the hapten conjugated to BSA in ELISA, but slightly to fetuin, a glycoprotein which is rich in Neu5Ac. SIC172 MAb (IgG3(kappa)), purified with a protein A/G affinity column, bound strongly to fetuin. Neu2en5Ac competed with the MAb in binding in amounts as low as 3 microM, while the competition of Neu5Ac appeared at amounts of more than 300 microM. SIC172 MAb is a unique MAb specific to Neu2en5Ac and might be useful for detecting Neu2en5Ac, which occurs naturally and in sialuria.     

Viral protein expression in producer and nonproducer clones of friend erythroleukemia cell lines.

Erythroleukemia cell lines HFL/d and HFL/b, derived from tumors induced in vivo in BALB/c (H-2d) and congenic BALB.B (H-2b) mice, respectively, by a polycythemia-inducing strain of Friend virus, produced both spleen focus-forming virus (SFFV) and its native NB-tropic helper virus (Friend murine leukemia virus [FMuLV]) during early-passage generations in culture. Eventually each line ceased production of both infectious viruses but retained its tumorigenic potential in syngeneic hosts. Virus-producer and -nonproducer clones of these cell lines were examined for expression of proteins encoded by the SFFV or FMuLV genomes. Lysates of labeled cells were treated with various antiviral sera, and the precipitates were examined by gel electrophoresis. Expression of the FMuLV env gene-encoded precursor protein, gPr84env, was observed in all producer and most nonproducer clones, but the FMuLV gag and pol gene products, Pr65gag and Pr200gag-pol, were uniformly undetectable in nonproducer clones. All HFL/d and HFL/b clones expressed appreciable amounts of the SFFV-encoded envelope protein, gp52, including one exceptional clone which had ceased to express any FMuLV-encoded proteins. The molecular weight of this SFFV-encoded envelope protein was consistently smaller in all HFL/b clones than in HFL/d clones, regardless of their producer or nonproducer status. The virus-nonproducer phenotype thus appears to be due to shutdown of expression of the 5' portion of the FMuLV genome in two independent cell lines.     

Use of a structured kinetic model of antibody synthesis and secretion for optimization of antibody production systems: II. Transient analysis

The dynamic behavior of the monoclonal antibody (MAb) secretory pathway is studied by transient simulations using our previously developed structured kinetic model for antibody synthesis and secretion by hybridoma cells. The response of the secretory pathway to blocks in specific pathway steps and step changes in characteristic pathway parameters is presented in order to gain a better understanding of pathway dynamics and identify possible ratelimiting steps in the pathway. Model simulations suggest that the step of antibody assembly in the endoplasmic reticulum (ER) is a very good candidate for a rate-limiting step in the antibody secretory pathway in fast-growing hybridoma cells, whereas translation of the heavy and light chains is most likely rate-limiting in slowly growing or stationary phase cells. Transient simulation results are compared with experimentally observed transient changes in specific antibody secretion rates and used to suggest strategies for optimizing antibody secretion in large-scale production systems.