Nutritional requirements of mouse adrenal cortex tumor cells in culture

A tribute to Dr. Gordon Hisashi Sato (December 24, 1927-March 31, 2017)

Gordon H. Sato, an innovator in mammalian tissue culture and integrated cellular physiology, passed away in 2017. In tribute to Dr. Sato, In Vitro Cellular and Developmental Biology-Animal presents a collection of invited remembrances from six colleagues whose associations with Dr. Sato spanned more than 40 years. Dr. Sato was a past president of the Tissue Culture Association (now the Society for In Vitro Biology), editor-in-chief of In Vitro Cellular and Developmental Biology (1987-1991), and the recipient of the lifetime achievement award from the Society for In Vitro Biology (2002). He was elected to the US National Academy of Sciences in 1984.

The control of oxidative phosphorylation in the adrenal gland (Y1) cell line

We determined the proportion of oxygen consumption due to oxidative phosphorylation by mitochondria in an adrenal gland cell line (Y1 cells). In addition we determined the relative proportion of in situ mitochondrial oxygen consumption attributable to (i) proton leak and (ii) ATP turnover in these cells. This approach allowed use of top-down elasticity analysis to determine control of oxidative phosphorylation by mitochondrial (a) proton leak flux (b) substrate oxidation flux and (c) ATP turnover flux, as a function of changes in in situ mitochondrial membrane potential. Our data show that resting oxygen consumptions rates of Y1 cells to be 87 +/- 7 nmolO/min/10(7) cells of which 38 +/- 3% was not due to oxidative phosphorylation. We demonstrated that mitochondrial proton leak accounted for 7 +/- 3% of total cellular oxygen consumption or 12 +/- 6% of resting mitochondrial oxygen consumption, with ATP turnover accounting for 55 +/- 3% of total cellular oxygen consumption or 78 +/- 6% of mitochondrial oxygen consumption. Control of resting mitochondrial oxygen consumption in Y1 cells was shared by (a) substrate oxidation flux (37 +/- 8%), (b) proton leak flux (15 +/- 8%) and (c) ATP turnover (56 +/- 8%). Our data demonstrate, for the first time, that the majority of oxygen consumption by resting Y1 cells is due to oxidative phosphorylation.

Improved basal medium for Y-1 mouse adrenal cortex tumor cells in culture. I. Dependence of growth and steroid response on calcium ion concentration

An improved basal medium is presented that required only minimal supplementation with dialyzed fetal bovine serum or bovine serum albumin and fetuin to be comparable to Ham's F-10, which requires 15% horse serum (HS) and 2.5% fetal bovine serum (FBS) for the growth and function of Y-1, mouse adrenal cortex tumor, cells. Cell monolayers maintained for up to 2 weeks without any protein supplementation have retained their steroid response to ACTH. The medium differs from Ham's F-10 in its buffer composition and higher calcium-ion concentration. This medium should be a useful adjunct to studies pertaining to steroid and lipid intermediary metabolism, the retention of a specialized physiological function in a chemically defined medium, and the mechanism of hormonal response.

Scanning electron microscopy of induced cell rounding of mouse adrenal cortex tumor cells in culture

The surface topologies of mouse adrenal cortex tumor cells of primary or clonal origin grown as monolayer cell cultures were observed by scanning electron microscopy following their exposure to substances that effect steroid release and/or cell rounding. ACTH induced cell rounding with a concomitant profuse development of fine microvilli in a non-synchronously dividing cell population. This was less pronounced with other steroidogenic substances and absent in EGTA or trypsin-treated cells. Morphological alterations occurred most rapidly with cAMP and least rapidly with dbcAMP. The rapid development of fine microvilli with ACTH is proposed to be a specific hormone mediated response.