Sustained epidermal growth factor receptor levels and activation by tethered ligand binding enhances osteogenic differentiation of multi-potent marrow stromal cells

Epidermal growth factor receptor (EGFR)-mediated signaling helps regulate bone development and healing through its effects on osteogenic cells. Here, we show how EGFR activity and osteogenic differentiation responses in primary human bone marrow-derived multipotent stromal cells (MSCs) are influenced by presenting covalently tethered epidermal growth factor (tEGF) on the culture substratum, a presentation mode that reduces EGFR internalization and restricts signaling to the cell surface. In both absence and presence of tEGF, MSCs increase expression levels of EGFR and its heterodimerization partner HER2 during the course of osteogenic differentiation. tEGF substrata increased levels of phosphorylated EGFR and phosphorylated extracellular regulated kinase (ERK) compared to control substrata, and these elevations were associated with a twofold enhancement of MSC alkaline phosphatase activity at day 7 and matrix mineralization at day 21. Surprisingly, addition of soluble EGF (sEGF) to cells cultured on tEGF substrata reduces osteogenic differentiation, even though EGFR signaling is more strongly activated in acute, short-term manner by sEGF treatment than by tEGF treatment. A striking concomitant result of the sEGF effects is near-complete downregulation of EGFR and HER2, demonstrating that the tEGF/EGFR interaction is dynamically reversible even though temporally sustained. Taken together, our results show that enhanced MSC osteogenic differentiation corresponds to a sustained combination of receptor expression and ligand presentation, both of which are maintained by tEGF. J. Cell. Physiol. 221: 306–317, 2009. © 2009 Wiley-Liss, Inc.     

Correcting eggshell indices of raptor eggs for hole size and eccentricity

Eggshell thickness is often expressed by means of an index based on the length, breadth and weight of the shell. The effect of the blow-hole and egg eccentricity on Ratcliffe's shell thickness index was investigated in a sample of 585 eggs from six raptor species. Corrections for the size of the hole and egg eccentricity are proposed, as is a combined formula to correct both sources of error at the same time. It is shown that by using these formulae, considerable improvements in estimates of shell thinning are obtained. These may be especially useful when sample sizes are small, which is often the case when working with species that have been reduced in numbers.     

Histological evidence for the role of mechanical stress in modulating thermal denaturation of collagen

The hyperthermia and thermal denaturation literatures reveal a time-temperature equivalency when heating cells or connective tissues: thermal damage increases with increasing temperature (for the same duration) and increases with increasing duration (for the same temperature). Recent findings conversely suggest that increasing the mechanical loading on a tissue during heating decreases the thermal damage (for a given temperature and duration of heating). Surprisingly, however, there are few histological correlates of such damage. In this paper, we show that progressive light microscopic changes – swelling of collagen bands, thickening of collagen-rich layers, hyalinization, and loss of birefringence~– correlate very well with both increased heating times and decreased mechanical loading. Increased mechanical stress is thus thermally protective and should be considered in the design of clinical procedures that use heating to treat diseases or injuries. P. B. Wells and S. Thomsen contributed equally to this work.     

Growth regulators and the control of nucleotide sugar flux

A small number of plant growth regulators are involved in the control of cell expansion. Despite knowledge of some of their signal transduction cascades, surprisingly little is known of how basic cell expansion-related processes, such as cell wall biosynthesis, are affected during growth. The Arabidopsis (Arabidopsis thaliana) mutant root hair defective1 (rhd1) lacks a functional UDP-glucose 4-epimerase gene, UGE4, which is involved in channeling UDP-D-galactose (UDP-D-Gal) into cell wall polymers. Here, we use rhd1 as a genetic model to analyze the physiological and genetic controls of nucleotide sugar flux. We find that ethylene specifically suppresses all visible aspects of the rhd1 phenotype. The ethylene-triggered suppression of rhd1 is negatively regulated by CONSTITUTIVE TRIPLE RESPONSE1 and requires the function of the wild-type genes ETHYLENE INSENSITIVE2 (EIN2), EIN4, AUXIN-RESISTENT1, and ETHYLENE-INSENSITIVE ROOT1 but does not depend on the activity of wild-type ETHYLENE RECEPTOR1 or EIN3 genes, highlighting the nonlinearity of ethylene signal transduction. Ethylene does not induce the expression of alternative UGE genes but, instead, suppresses the expression of two isoforms, UGE1 and UGE3, in a tissue-specific manner. Ethylene restores the biosynthesis of galactose-containing xyloglucan and arabinosylated galactan cell wall polymers in rhd1 back to wild-type levels. However, the dependence on UGE4 of pectic (1-->4)-beta-D-galactan and glucuronosyl-modified AGP biosynthesis is exacerbated. Our data suggest that ethylene and auxin together participate in the flux control of UDP-D-Gal into cell wall polymers and that the genetic control of this process is qualitatively distinct from previously described responses to ethylene.     

Man the nanoscopes

New light microscopy techniques are pushing the limits of resolution to 50 nm and below. Fluorescence microscopy that rivals electron microscopy in resolution but operates on intact cells may be within reach.