Joseph E. Gabriels

Microporosity of the substratum regulates differentiation of MDCK cells in vitro

SummaryWe have analyzed the ability of the physical substratum to modulate both the ultrastructural and protein synthetic characteristics of the Madin-Darby canine kidney (MDCK) renal cell line. When MDCK cells were seeded on Millipore Millicell CM microporous membrane cell culture inserts they demonstrated a more columnar organization with an increase in cell density sixfold greater than the same cells seeded on conventional plastic substrata. After 1 wk postseeding on the microporous membrane a partial basal lamina was noted, with a contiguous basement membrane being apparent after 2 wk. One-dimensional sodium dodecyl sulfate gel electrophoresis was used to analyze detergent-solubilized proteins from MDCK cells maintained on plastic substrata vs. microporous membranes. When proteins were pulse-labeled with [35S]methionine, a 55 kDa protein was evident in the cytosolic extract of cells grown on collagen, laminin, and nontreated plastic substrata; but this labeled protein was not evident in similar extracts from cells grown on collagen and laminin-coated microporous membranes. To test if the polarized, basement-membrane secreting phenotype of the MDCK cells could be generated on a microporous membrane without pretreatment with any extracellular matrix (ECM) components, cells were seeded on the Millipore Millicell HA (cellulosic) microporous membrane. This type of substrata does not need a coating of ECM components for cell attachment. A partial basement membrane was formed below cells where the basal surface of the cell was planar, but not in areas where the cell formed large cytoplasmic extensions into the filter. This led us to the conclusion that the microporous nature of the substrata can dictate both ultrastructural and protein synthetic activities of MDCK cells. Furthermore, we suggest that both the planar nature of the basal surface and the microporosity of the substrate are corequisites for the deposition of the basement membrane.

PC12 cells grown on cellulosic filters differentiate in response to NGF and exhibit a polarity not seen when they are grown on solid substrata

SummaryStudies were performed with cellulosic filters and standard culture plates to compare methods of cell culture and differentiation of the cell line PC12, a clone originating from a rat pheochromocytoma. PC12 cells respond to nerve growth factor (NGF) by flattening of the cell body and subsequent extension of neurite-like processes. When PC12 cells are cultured in dishes without NGF, they have a diameter of approximately 3 to 7 μm and exhibit short processes of no longer than 3 to 5 μm. If PC12 cells are grown on a cellulosic filter they have the same average soma diameter and similar short processes extending laterally, but in addition have branching processes which extend as far as 10 to 15 μm into the filter substrate. When dish-cultured and filter-cultured cells are incubated with 50 ng/ml NGF they both exhibit differentiation-specific ultrastructural changes by 3 d of treatment. In the case of dish-cultured cells, large cytoplasmic processes exhibit an increase in the number of chromaffin cell-like secretory granules by 3 d of treatment. This characteristic is also demonstrated by filter-cultured cells, but the processes containing these granules are found concentrated within the cellulosic meshwork. Thus the timing of the NGF-elicited differentiation program is similar to both filter-cultured and dish-cultured cells, but the ultrastructural consequences are different. The filter-cultured PC12 cells exhibit a polarity not demonstrated by dish-cultured cells. Growing PC12 cells on cellulosic filters is a technique useful for “anchoring” neurons without the complication of the addition of extracellular matrix components. Filter-culture may represent a more in vivo-like method for studying neuronal growth and differentiation.