Isolation from lactalbumin hydrolysate of a high molecular weight mitogenic factor

Applications and analysis of hydrolysates in animal cell culture

Animal cells are used in the manufacturing of complex biotherapeutic products since the 1980s. From its initial uses in biological research to its current importance in the biopharmaceutical industry, many types of culture media were developed: from serum-based media to serum-free to protein-free chemically defined media. The cultivation of animal cells economically has become the ultimate goal in the field of biomanufacturing. Serum serves as a source of amino acids, lipids, proteins and most importantly growth factors and hormones, which are essential for many cell types. However, the use of serum is unfavorable due to its high price tag, increased lot-to-lot variations and potential risk of microbial contamination. Efforts are progressively being made to replace serum with recombinant proteins such as growth factors, cytokines and hormones, as well as supplementation with lipids, vitamins, trace elements and hydrolysates. While hydrolysates are more complex, they provide a diverse source of nutrients to animal cells, with potential beneficial effects beyond the nutritional value. In this review, we discuss the use of hydrolysates in animal cell culture and briefly cover the composition of hydrolysates, mode of action and potential contaminants with some perspectives on its potential role in animal cell culture media formulations in the future.

Serum-free culture of rabbit meniscal fibrochondrocytes: proliferative response

We have formulated a serum-free medium capable of supporting DNA synthesis in rabbit meniscal fibrochondrocytes at a level equivalent to 10% fetal bovine serum (FBS). The medium consists of a 1:1 mixture of Dulbecco's Modified Eagle's Medium and Ham's F-12 medium supplemented with transferrin (1 microgram/ml), selenium (1 pg/ml), trace metal mix (1:100), dexamethasone (100 ng/ml), insulin-like growth factors I and II (50 ng/ml each), pituitary fibroblast growth factor (100 ng/ml), and lactalbumin hydrolysate (2 micrograms/ml). Endothelial cell growth supplement could be substituted for lactalbumin hydrolysate to obtain similar results. Ventrex PC-1, a commercially available, low-protein, serum-free medium, was found to support proliferation of fibrochondrocytes but not as well as 10% FBS or our medium formulation. Lipid supplements, which are known to support the serum-free growth of hyaline chondrocytes, were found to be either of no value or antagonistic for the culture of fibrochondrocytes. Likewise, vitamin E alone, progesterone, putrescine, and hydrocortisone were also without benefit in our culture system. The cells had a more chondrocytic morphology when grown in defined medium as opposed to 10% FBS. The results of this study should now make it possible to identify and quantitate those factors necessary to affect meniscal repair by utilizing further techniques in vitro.

Elevation of intracellular glutathione content associated with mitogenic stimulation of quiescent fibroblasts

The relationship between total glutathione (GSH) content and cell growth was examined in 3T3 fibroblasts. The intracellular GSH level of actively growing cultures gradually decreases as these cells become quiescent by either serum deprivation or high cell density. Upon mitogenic stimulation of sparse, quiescent (G0/G1) cultures with serum, there is a rapid 2.3-fold elevation in intracellular GSH levels which is maximal by 1 h and returns to baseline by 2 h. This is followed by a more gradual increase in GSH content as cells enter the S phase. In addition, the elevation in GSH content is required for maximum induction of DNA synthesis. Treatments that prevent the early increase in intracellular GSH levels do not affect protein synthesis but result in a reversible dose-dependent decrease in the percent of cells capable of entering S phase. These results indicate that GSH may be important in the regulation of cellular proliferation.

Retinoic acid alters subcellular compartmentalization of ATP pools in 3T3 cells but not in HeLa cells

Retinoic acid (RA; beta-all-trans) inhibits the proliferation of both murine 3T3 cells and human HeLa cells. Flow cytometric analyses of exponentially growing cultures show that 3T3 cells are inhibited during the S phase of their cell cycle, while HeLa cells show only a small increase in G1 phase cells. RA (10 microM) causes a 50% increase in total cellular adenosine triphosphate (ATP) pools of 3T3 cells, but not of HeLa cells. We have previously demonstrated that the effects of RA on cellular ATP pools of 3T3 cells are directly related to its inhibition of cellular growth, and now report data which provide a biochemical basis for this process. Established procedures were utilized to investigate the effects of RA on the functional compartmentalization of the nuclear ATP pool which serves as a precursor for RNA synthesis in these cells, and which is shown to be a small pool in comparison with cytoplasmic ATP pools. Expansion of total cellular ATP pools by 1 mM of exogenously supplied unlabeled adenosine is ineffective in reducing the subsequent incorporation of [3H]adenosine into RNA of 3T3 cells. Similar treatment of HeLa cells yields a modest reduction in the incorporation of [3H]adenosine into RNA. RA treatment of HeLa cells does not affect the preferential uptake of exogenous [3H] adenosine into the immediate precursor ATP pool for RNA synthesis. RA treatment of 3T3 cells markedly reduces the incorporation of [3H] adenosine into RNA, indicating a lesser degree of functional compartmentalization of the nuclear ATP pool. Similar conclusions are drawn from correlations of the specific radioactivities of total cellular [3H] ATP pools and the levels of incorporation of radioactive label into cellular RNA. In addition, pulse-chase experiments show that RA-treated 3T3 cells continue to incorporate radioactive label from pools prelabeled with [3H]adenosine despite the presence of a large excess of unlabeled adenosine in the chase medium. Control 3T3 and both control and RA-treated HeLa cells cease to incorporate label immediately upon the start of the chase, suggesting that the functional precursor ATP pool for RNA synthesis is small and readily diluted. These data suggest that RA decreases the degree of functional compartmentalization for 3T3, but not HeLa cell ATP pools, and provides a probable mechanism for expansion of nuclear ATP pools of 3T3 cells. The expanded nuclear ATP pools may provide the biochemical mechanism for the inhibition of DNA synthesis during the S phase of the 3T3 cell cycle.

Anti-immunoglobulin-induced proliferative response of rabbit lymphocytes in a serum-free medium

The aim of this study was to determine if rabbit lymphocytes were activated with a specific ligand, anti-immunoglobulin (anti-Ig) in a well-defined serum-free medium. A modified medium, composed of Neuman-Tytell (NT) basal medium supplemented with BSA, transferrin (Tf), and fatty acids (FA), was found to support a vigorous anti-Ig-induced proliferative response of rabbit lymphocytes. The optimal concentrations of BSA, Tf and FA supplements were determined for the mitogen-induced response. The mitogenesis was enhanced by addition of 2-mercaptoethanol. The proliferation could be maintained for 10 days provided cells received fresh medium and mitogen on day 5. The presence of anti-Ig throughout the culture period is required for this extended proliferation. The response did not require the Fc portion of the anti-Ig and was blocked by soluble rabbit F(ab')2 fragments. The anti-Ig-activated blasts lacked a T cell surface marker and about half of them re-expressed sIg when anti-Ig was washed out (assayed 24 h later). The viability of the mitogen-induced cells on day 5 was above 55%, whereas the viability of the cells without mitogen was 36%. The supplemented NT medium could also support Con A-induced mitogenesis of rabbit lymphocytes. Additionally, Con A- and LPS-stimulated murine lymphocytes showed considerable proliferation for up to 5 days in the supplemented NT medium.