Spermine enhances IgM productivity of human-human hybridoma HB4C5 cells and human peripheral blood lymphocytes

Polyamines and hormesis: Making sense of a dose response dichotomy

The diverse biological effects of polyamines (putrescine, spermidine and spermine) were reviewed in the context of hormesis in an integrative manner for the first time. The findings illustrate that each of these polyamines commonly induces hormetic dose responses in a wide range of biological models and types of cells for multiple endpoints in numerous plant species and animal models. Plant research emphasized preconditioning experimental studies in which the respective polyamines conferred some protection against the damaging effects of a broad range of environmental stressors such as drought, salinity, cold/heat, heavy metals and UV-damage in an hormetic manner. Polyamine-based animal hormesis studies emphasized biomedical endpoints such as longevity and neuroprotection. These findings have important biological and biomedical implications and should guide experimental designs of low dose investigations.

Thermal effects on IgM-milk fat globule-mediated agglutination

The process of agglutination causes firm cream layers in bovine milk, and a functioning agglutination mechanism is paramount to the quality of non-homogenized milks. The phenomenon is not well-described, but it is believed to occur due to interactions between immunoglobulins (Ig) and milk fat globules. For the first time, this paper demonstrates how the process of agglutination can be visualized using confocal laser scanning microscopy, rhodamine red and a fluoresceinisothiocynat-conjugated immunoglobulin M antibody. The method was used to illustrate the effect on agglutination of storage temperature and pasteurization temperature. Storage at 5 °C resulted in clearly visible agglutination which, however, was markedly reduced at 15 °C. Increasing storage temperature to 20 or 37 °C cancelled any detectable interaction between IgM and milk fat globules, whereby the occurrence of cold agglutination was documented. Increasing 20 s pasteurization temperatures from 69 °C to 71 °C and further to 73 °C lead to progressively higher inactivation of IgM and, hence, reduction of agglutination. Furthermore, 2-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis showed that changes in storage temperature caused a redistribution of Ig-related proteins in milk fat globule membrane isolates. Poly-immunoglobulin G receptor was present in milk fat globule preparations stored at cold (4 °C) conditions, but absent at storage at higher temperature (25 °C). The findings provide valuable knowledge to dairy producers of non-homogenized milk in deciding the right pasteurization temperature to retain the crucial agglutination mechanism.

Effects of DNA on immunoglobulin production stimulating activity of alcohol dehydrogenase

Alcohol dehydrogenase-I (ADH-I) derived from horse liver stimulated IgM production by human-human hybridoma, HB4C5 cells and lymphocytes. The IPSF activity of ADH-I was suppressed by coexistence of short DNA whose chain length is less than 200 base pairs (bp) and fibrous DNA in a dose-dependent manner. These DNA preparations completely inhibited the IPSF activity at the concentration of 250 mug/ml and 1.0 mg/ml, respectively. DNA sample termed long DNA whose average chain length is 400-7000 bp slightly stimulated IPSF activity at 0.06 mug/ml. However, long DNA suppressed IPSF activity by half at 1.0 mg/ml. The laser confocal microscopic analysis had revealed that ADH-I was incorporated by HB4C5 cells. The uptake of ADH-I was strongly inhibited by short DNA and fibrous DNA. However, long DNA did not suppress the internalization of ADH-I into HB4C5 cells. These findings indicate that short DNA and fibrous DNA depress IPSF activity of ADH-I by inhibiting the internalization of this enzyme. According to the gel-filtration analysis using HPLC, ADH-I did not directly interact with short DNA. It is expected from these findings that short DNA influences HB4C5 cells to suppress the internalization of ADH-I. Moreover, these facts also strongly suggest that ADH-I acts as IPSF after internalization into the cell.

Lactate dehydrogenase enhances immunoglobulin production by human hybridoma and human peripheral blood lymphocytes

Lactate dehydrogenase (LDH) derived from rabbit muscle enhanced IgM production by human-human hybridoma HB4C5 cells 12.4-fold at 320 mug/ml under serum-free conditions. LDHs from pig muscle and pig heart also accelerated IgM production 8.4- and 6.4-fold, respectively. The immunoglobulin production stimulating activity of LDH was not accompanied by activation of cell proliferation. LDH from rabbit muscle facilitated IgM and IgG production by human peripheral blood lymphocytes. This means LDH stimulates immunoglobulin production not only by the specified hybridoma cell line, but also by unspecified immunoglobulin producers. LDH from rabbit muscle enhanced IgM production of transcription-suppressed HB4C5 cells treated with actinomycin D. The immunoglobulin production-stimulating factors (IPSFs) effect of LDH was slightly weakened by sodium fluoride (translation inhibitor) treatment of HB4C5. Moreover, the amount of intracellular IgM of monensin-treated HB4C5 cells was obviously enhanced by LDH. This result means that the IPSF effect of LDH is irrelevant to the post-translation activity of target cells. It is expected from these findings that LDH from rabbit muscle accelerates the translation step to enhance immunoglobulin productivity. The immunoglobulin production-stimulating activity of LDH was inhibited by colchicine, endocytosis inhibitor. This fact suggests that it is necessary for LDH to be taken by target cells to act as an IPSF.

Properties of ras-amplified recombinant BHK-21 cells in protein-free culture

We compared serum and protein-free cultures ofa ras-amplified recombinant BHK-21 cell line(ras-rBHK-IgG), which hyperproduces a lungcancer specific recombinant human monoclonal antibody. Ras-rBHK-IgG cells were shown to grow well, evenin protein-free medium and to be morphologicallysimilar to cells cultured in serum containing medium. However, the growth rate of ras-rBHK-IgG cellswas considerably slower in protein-free medium, whichresults in a longer maintenance period compared with cells cultured in serum containing medium. In addition, it was found that antibody production in protein-free culture had a ten times higher maximum than cells cultured in serum containing medium. On theother hand, in high density culture, using the hollowfiber bioreactor system, ras-rBHK-IgG cellscould be maintained for a month in protein-freeculture in contrast with serum culture, which onlylasted for half a month. However, the markedincrease of antibody production was not observed. A total amount of about 15 mg of the recombinantantibody, obtained in protein-free culture, was abouttwo times of that obtained in serum culture, and wasshown to be reactive to lung cancer cells in tissue. From these properties in protein-free medium, it isconcluded that protein-free culture of ras-rBHK-IgG cells is suitable for middle scaleproduction of recombinant human monoclonal antibody.

Enhancement of antibody production by the addition of Coenzyme-Q(10)

Recently, there has been a growing demand for therapeutic monoclonal antibodies (MAbs) on the global market. Because therapeutic MAbs are more expensive than low-molecular-weight drugs, there have been strong demands to lower their production costs. Therefore, efficient methods to minimize the cost of goods are currently active areas of research. We have screened several enhancers of specific MAb production rate (SPR) using a YB2/0 cell line and found that coenzyme-Q(10) (CoQ(10)) is a promising enhancer candidate. CoQ(10) is well known as a strong antioxidant in the respiratory chain and is used for healthcare and other applications. Because CoQ(10) is negligibly water soluble, most studies are limited by low concentrations. We added CoQ(10) to a culture medium as dispersed nanoparticles at several concentrations (Q-Media) and conducted a fed-batch culture. Although the Q-Media had no effect on cumulative viable cell density, it enhanced SPR by 29%. In addition, the Q-Media had no effect on the binding or cytotoxic activity of MAbs. Q-Media also enhanced SPR with CHO and NS0 cell lines by 30%. These observations suggest that CoQ(10) serves as a powerful aid in the production of MAbs by enhancing SPR without changing the characteristics of cell growth, or adversely affecting the quality or biological activity of MAbs.

Effects of polyamines on proliferation and IgM productivity of human-human hybridoma, HB4C5 cells

Immunoglobulin production stimulating activity of polyamines was investigated. Spermidine, thermine and triethylenetetraamine (TETA) stimulated IgM production of human-human hybridoma, HB4C5 cells under serum-free condition. IgM production of HB4C5 cells was accelerated 5.9-, 5.3-, and 3.7-fold by spermidine at 4.5 mM, thermine at 2 mM and TETA at 2.5 mM, respectively. However, putrescine did not enhance IgM production. Spermidine enhanced IgM productivity of the hybridoma cells in spite of its growth suppression activity. TETA also inhibited cell proliferation and the effect on the acceleration of IgM productivity disappeared during 5 days because of its cytotoxicity. On the other hand, thermine facilitated IgM productivity of the hybridoma cells without growth suppression. The laser confocal microscopic analysis revealed that IgM content inside HB4C5 cells was increased by thermine. This result suggests that thermine facilitates IgM synthesis in hybridoma cells.