Monitoring developmental force distributions in reconstituted embryonic epithelia.

The way cells are organized within a tissue dictates how they sense and respond to extracellular signals, as cues are received and interpreted based on expression and organization of receptors, downstream signaling proteins, and transcription factors. Part of this microenvironmental context is the result of forces acting on the cell, including forces from other cells or from the cellular substrate or basement membrane. However, measuring forces exerted on and by cells is difficult, particularly in an in vivo context, and interpreting how forces affect downstream cellular processes poses an even greater challenge. Here, we present a simple method for monitoring and analyzing forces generated from cell collectives. We demonstrate the ability to generate traction force data from human embryonic stem cells grown in large organized epithelial sheets to determine the magnitude and organization of cell-ECM and cell-cell forces within a self-renewing colony. We show that this method can be used to measure forces in a dynamic hESC system and demonstrate the ability to map intracolony protein localization to force organization.

Identification and characterization of glycosylation sites in human serum clusterin.

Clusterin is a ubiquitous, heterodimeric glycoprotein with multiple possible functions that are likely influenced by glycosylation. Identification of oligosaccharide attachment sites and structural characterization of oligosaccharides in human serum clusterin has been performed by mass spectrometry and Edman degradation. Matrix-assisted laser desorption ionization mass spectrometry revealed two molecular weight species of holoclusterin (58,505 +/- 250 and 63,507 +/- 200). Mass spectrometry also revealed molecular heterogeneity associated with both the alpha and beta subunits of clusterin, consistent with the presence of multiple glycoforms. The data indicate that clusterin contains 17-27% carbohydrate by weight, the alpha subunit contains 0-30% carbohydrate and the beta subunit contains 27-30% carbohydrate. Liquid chromatography electrospray mass spectrometry with stepped collision energy scanning was used to selectively identify and preparatively fractionate tryptic glycopeptides. Edman sequence analysis was then used to confirm the identities of the glycopeptides and to define the attachment sites within each peptide. A total of six N-linked glycosylation sites were identified, three in the alpha subunit (alpha 64N, alpha 81N, alpha 123N) and three in the beta subunit (beta 64N, beta 127N, and beta 147N). Seven different possible types of oligosaccharide structures were identified by mass including: a monosialobiantennary structure, bisialobiantennary structures without or with one fucose, trisialotriantennary structures without or with one fucose, and possibly a trisialotriantennary structure with two fucose and/or a tetrasialotriantennary structure. Site beta 64N exhibited the least glycosylation diversity, with two detected types of oligosaccharides, and site beta 147N exhibited the greatest diversity, with five or six detected types of oligosaccharides. Overall, the most abundant glycoforms detected were bisialobiantennary without fucose and the least abundant were monosialobiantennary, trisialotriantennary with two fucose and/or tetrasialotriantennary. Clusterin peptides accounting for 99% of the primary structure were identified from analysis of the isolated alpha and beta subunits, including all Ser- and Thr-containing peptides. No evidence was found for the presence of O-linked or sulfated oligosaccharides. The results provide a molecular basis for developing a better understanding of clusterin structure-function relationships and the role clusterin glycosylation plays in physiological function.

Differential display RT PCR of total RNA from human foreskin fibroblasts for investigation of androgen-dependent gene expression.

Male sexual differentiation is a process that involves androgen action via the androgen receptor. Defects in the androgen receptor, many resulting from point mutations in the androgen receptor gene, lead to varying degrees of impaired masculinization in chromosomally male individuals. To date no specific androgen regulated morphogens involved in this process have been identified and no marker genes are known that would help to predict further virilization in infants with partial androgen insensitivity. In the present study we first show data on androgen regulated gene expression investigated by differential display reverse transcription PCR (dd RT PCR) on total RNA from human neonatal genital skin fibroblasts cultured in the presence or absence of 100 nM testosterone. Using three different primer combinations, 54 cDNAs appeared to be regulated by androgens. Most of these sequences show the characteristics of expressed mRNAs but showed no homology to sequences in the database. However 15 clones with significant homology to previously cloned sequences were identified. Seven cDNAs appear to be induced by androgen withdrawal. Of these, five are similar to ETS (expression tagged sequences) from unknown genes; the other two show significant homology to the cDNAs of ubiquitin and human guanylate binding protein 2 (GBP-2). In addition, we have identified 8 cDNA clones which show homologies to other sequences in the database and appear to be upregulated in the presence of testosterone. Four of these clones again are similar to ETS from unknown genes. Three differential expressed sequences that appear to be upregulated in the presence of testosterone show significant homology to the cDNAs of L-plastin and one to the cDNA of testican. This latter gene codes for a proteoglycan involved in cell social behavior and therefore of special interest in this context. The results of this study are of interest in further investigation of normal and disturbed androgen-dependent gene expression.

Oncogenic targeting of BRM drives malignancy through C/EBPß-dependent induction of α5 integrin.

Integrin expression and activity are altered in tumors, and aberrant integrin signaling promotes malignancy. However, how integrins become altered in tumors remains poorly understood. We discovered that oncogenic activation of MEK signaling induces cell growth and survival, and promotes the malignant phenotype of mammary epithelial cells (MECs) by increasing α5 integrin expression. We determined that MEK activates c-Myc to reduce the transcription of the SWI/SNF chromatin remodeling enzyme Brahma (BRM). Our studies revealed that reduced BRM expression and/or activity drives the malignant behavior of MECs by epigenetically promoting C/EBPß expression to directly induce α5 integrin transcription. Consistently, we could show that restoring BRM levels normalized the malignant behavior of transformed MECs in culture and in vivo by preventing C/EBPß-dependent α5 integrin transcription. Our findings identify a novel mechanism whereby oncogenic signaling promotes malignant transformation by regulating transcription of a key chromatin remodeling molecule that regulates integrin-dependent stromal-epithelial interactions.