Sarah C. Glover

ROCK-II mediates colon cancer invasion via regulation of MMP-2 and MMP-13 at the site of invadopodia as revealed by multiphoton imaging.

The ROCK-II isoform of Rhos downstream effector, Rho kinase, has been linked with greater invasion and metastasis in solid tumors. We have previously shown that ROCK-II is overexpressed at the advancing edge of colon cancers. The mechanism whereby ROCK-II contributes invasion, particularly in the setting of colon cancer, remains to be elucidated fully. To better understand its contribution, we evaluated ROCK-II expression in both non-malignant (NCM460 and IEC-6) and malignant (Caco-2 E, SW620, and HCT-116) intestinal epithelial cell lines grown in type I collagen scaffolds. Using multiphoton microscopy, we observed that ROCK-II localized to the actin cytoskeleton in non-malignant cells but localized to the cell periphery as focal collections with an absence of adjacent collagen in all colon cancer cell lines. By transmission electron microscopy, these collections corresponded with finger-like projections previously described as invadopodia. Immunogold staining with cortactin, matrix metalloprotease (MMP)-2, -9, and -13 confirmed that these were indeed invadopodia. To further link ROCK-II to colon cancer invasion, we treated non-malignant and malignant intestinal epithelial cell lines with ROCK-II siRNA and evaluated depth of invasion, proliferation, and MMP-2, -9, and -13 activities. The most striking effect was seen in the highly tumorigenic cell lines, SW620 and HCT-116, wherein ROCK-II knockdown resulted in a two-fold or more reduction in invasion. This reduction in invasion was not due to a decrease in cell proliferation, as a significant reduction in proliferation was only observed in the two non-malignant intestinal cell lines. Finally, both MMP-2 and -13 activities were significantly decreased in all colon cancer cell lines. Taken together, these data suggest for the first time that ROCK-II is a critical mediator of colon cancer cell invasion through its modulation of MMP-2 and -13 at the site of invadopodia but regulates proliferation in non-malignant intestinal cells.

Expression of GRP and Its Receptor in Well-differentiated Colon Cancer Cells Correlates with the Presence of Focal Adhesion Kinase Phosphorylated at Tyrosines 397 and 407

Gastrin-releasing peptide (GRP) and its receptor (GRP-R) are not normally expressed by epithelial cells lining the colon but are aberrantly expressed in cancer, where they act as morphogens and regulate tumor cell differentiation. Studies of colon cancer formation in mice genetically incapable of synthesizing GRP-R suggested that this receptors morphogenic properties were mediated via focal adhesion kinase (FAK). We therefore set out to determine the presence of both total and phosphorylated forms of FAK in human colon cancer specimens as a function of tumor cell differentiation and GRP/GRP-R co-expression. Ten colon cancers containing 25 regions of distinct differentiation were randomly selected from our GI Cancer Tumor Bank. All specimens were immunohistochemically probed using antibodies recognizing GRP, GRP-R, total FAK, and FAK specifically phos-phorylated at tyrosine (Y) 397, 407, 576, 577, 861, and 925. Antibody-specific chromogen was determined by quantitative immunohistochemistry (IHC) for each region of defined differentiation. Here we confirm that GRP/GRP-R co-expression is a function of differentiation, with highest levels observed in well-differentiated tumor cells. We also show that the amount of total FAK and of FAK phosphorylated at Y397 and Y407 tightly correlates with differentiation and with the amount of GRP/GRP-R co-expression. These findings are consistent with GRP/GRP-R acting as a morphogen by activating FAK, and suggest that this occurs via phosphorylation of this enzyme at two specific tyrosine residues.

Phosphorylation of focal adhesion kinase tyrosine 397 critically mediates gastrin-releasing peptide's morphogenic properties.

We have proposed that gastrin‐releasing peptide (GRP) and its receptor (GRP‐R) are morphogens that when aberrantly re‐expressed in colon cancer promote tumor cell differentiation and retard metastasis. Because circumstantial evidence suggested that these properties were mediated via focal adhesion kinase (FAK), the purpose of this study was to elucidate the role of GRP‐induced activation of this enzyme on properties fundamental to metastasis including cell attachment, motility, and deformability. To do this, we studied 293 cells, a non‐malignant epithelial cell line that we show expresses GRP and GRPR. To dissect out the role of FAK, 293 cells were modified to inducibly express the dominant negative enzyme FAK‐related non‐kinase (FRNK) under control of a Tet‐On (i.e., doxycycline‐sensitive) promoter. Under serum‐free conditions, GRP acting in an autocrine manner caused FAK to be phosphorylated at Y397; and this could be completely inhibited either by incubating with the specific GRP‐R antagonist D‐Phe6(bombesin) methyl ester, or by upregulating FRNK using doxycycline. To measure cell attachment, we designed a cone‐plate viscometer that recorded the shear stress required to detach cells from their underlying matrix. To assess motility, confluent cells were wounded and behavior assessed by time‐lapse photography. To measure deformability, we recorded the ability of cells to be completely drawn into a micropipette <50% the size of the non‐deformed cell. Control 293 cells adhered more avidly to their underlying matrix, rapidly remodeled wounded tissues without any increase in overall proliferation, and were less distensible than cells treated with antagonist or doxycycline. Thus, these findings suggest that expression of GRP/GRPR in cancer inhibits metastasis by enhancing cell attachment to the matrix, regulating motility in the context of remodeling, and decreasing deformability. J. Cell. Physiol. 199: 77–88, 2004© 2003 Wiley‐Liss, Inc.

Increased frequency of gastrin‐releasing peptide receptor gene mutations during colon‐adenocarcinoma progression

Epithelial cells lining the mature human colon do not normally express receptors for gastrin‐releasing peptide (GRPR). In contrast, we have shown that when aberrantly expressed in functional form in colon cancer, this protein acted as a morphogen where it caused tumor cells to adopt a better‐differentiated phenotype. Importantly, GRPR mRNA is ubiquitously mutated in human colon cancer cell lines, with inactivating mutations detected in all cell lines not expressing functional receptor. Since colon cancers are heterogeneously differentiated, we set out to determine if the GRPR gene was mutated as a function of tumor cell differentiation in archived human colon cancers. We used laser capture microscopy to dissect out 67 regions of defined differentiation from 20 human colon cancers randomly selected from the UIC GI Tumor Bank. Except for two polymorphisms, the GRPR gene was not mutated in nonmalignant epithelial cells. In contrast, 42 distinct mutations were identified in malignant cells. Overall mutation number inversely correlated with the degree of tumor cell differentiation. Within any cancer, all GRPR mutations found within better‐differentiated cells were conserved in more poorly‐differentiated cells; while all poorly‐differentiated cells contained mutations resulting in GRPR pharmacological inactivation. These data suggest that accumulation of mutations within the GRPR gene ultimately resulting in the production of nonfunctional receptors may represent a previously unappreciated mechanism allowing for the dedifferentiation of tumor cells within any particular colon cancer; and that poorly‐differentiated tumor cells within any individual cancer may arise clonally from their better‐differentiated precursors.

Tumor stiffness is unrelated to myosin light chain phosphorylation in cancer cells.

Many tumors are stiffer than their surrounding tissue. This increase in stiffness has been attributed, in part, to a Rho-dependent elevation of myosin II light chain phosphorylation. To characterize this mechanism further, we studied myosin light chain kinase (MLCK), the main enzyme that phosphorylates myosin II light chains. We anticipated that increases in MLCK expression and activity would contribute to the increased stiffness of cancer cells. However, we find that MLCK mRNA and protein levels are substantially less in cancer cells and tissues than in normal cells. Consistent with this observation, cancer cells contract 3D collagen matrices much more slowly than normal cells. Interestingly, inhibiting MLCK or Rho kinase did not affect the 3D gel contractions while blebbistatin partially and cytochalasin D maximally inhibited contractions. Live cell imaging of cells in collagen gels showed that cytochalasin D inhibited filopodia-like projections that formed between cells while a MLCK inhibitor had no effect on these projections. These data suggest that myosin II phosphorylation is dispensable in regulating the mechanical properties of tumors.

Accumulation of ILC1 Cells in a DiGeorge Syndrome Patient withIntestinal Inflammation

DiGeorge Syndrome (DGS) is a genetic disorder caused by a microdeletion of chromosome 22q11.2. Its classical features include congenital heart disease, abnormal facies, speech delay and hypocalcaemia [1]. The gastrointestinal complaints are also very common. However, the mechanisms of DGS with intestinal inflammation remain elusive.

Increased ECM Density Increases Rock's Ability to Modulate Colon Cancer Proliferation but Does Not Change Its Impact on Invasion

Background:Mucins are a family of large glycoproteins that have been implicated in colorectal carcinogenesis. Our group has explored the role of MUC4, a transmembrane mucin, which is generally upregulated in most cancers (pancreas, lung etc), during colorectal carcinogenesis and noted that MUC4 is paradoxically downregulated in colorectal cancers. The progressive downregulation occurs since early stages of carcinogenesis (premalignant mucosa). However, the mechanism remains unclear. CDX2 is a caudal-related homeobox gene that has been known to be dysregulated in colon carcinogenesis. Intriguingly, a recent report implicated CDX2 in MUC4 regulation in Barretts esophagus. We, therefore, wanted to elucidate the role of CDX2 in the MUC4 loss in colon carcinogenesis Materials and Methods:HT29 cells were incubated in standard conditions and transiently transfected with CDX2 siRNA using Lipofectamine. Separately, HT29 cells were stably transfected withMUC4 shRNA and suitable control vector (CV). MUC4 shRNA transfected HT29 cells and CV transfected HT29 cells were treated with PI3K inhibitor LY294002. Protein lysates and RNA were obtained from the transfected cells and western blotting and qRT-PCR performed to assess the expression of MUC4, CDX2 and pAKT (S473). Results:In HT29 cells, a modest decrease in CDX2 expression by SiRNA (34% decreased CDX2 expression) concomitantly reduced MUC4 expression by 20%. Conversely, MUC4 shRNA transfection of HT29 cells (75% reduced MUC4 expression; p=0.05) resulted in 80% reduction in CDX2 mRNA expression and 60% reduction (p<0.02) in CDX2 protein levels. Since PI3K-AKT signaling cascade is known to modulate CDX2 levels, we assessed this pathway in MUC4 shRNA transfected HT29 cells, and demonstrated 50% increase (p<0.02) in Serine 473 phosphyrated AKT, which was mitigated by PI3K inhibitor, LY294002. However, despite the fact that MUC4 knockdown activated AKT, there was no effect of LY294002 treatment on the expression of CDX2 in MUC4 shRNA transfected HT29 cells, indicating that MUC4 modulates CDX2 expression via PI3K/pAKT independent manner. Conclusions: We report, herein, for the first time, that the dysregulation of two putative tumor suppressor genes, MUC4 and CDX2, is intimately related in colon cancer. Not only do CDX2 and MUC4 mirror each others expression but also mutually regulate each other. Further studies are ongoing to dissect this important novel pathway in colon carcinogenesis.

Expression of Grp and its receptor in well differentiated human colon cancer cells correlates with the presence of focal adhesion kinase phosphorylated at tyrosines 397 and 407

Gastrin-releasing peptide (GRP) and its receptor (GRP-R) are not normally expressed by epithelial cells lining the colon but are aberrantly expressed in cancer, where they act as morphogens and regulate tumor cell differentiation. Studies of colon cancer formation in mice genetically incapable of synthesizing GRP-R suggested that this receptors morphogenic properties were mediated via focal adhesion kinase (FAK). We therefore set out to determine the presence of both total and phosphorylated forms of FAK in human colon cancer specimens as a function of tumor cell differentiation and GRP/GRP-R co-expression. Ten colon cancers containing 25 regions of distinct differentiation were randomly selected from our GI Cancer Tumor Bank. All specimens were immunohistochemically probed using antibodies recognizing GRP, GRP-R, total FAK, and FAK specifically phosphorylated at tyrosine (Y) 397, 407, 576, 577, 861, and 925. Antibody-specific chromogen was determined by quantitative immunohistochemistry (IHC) for each region of defined differentiation. Here we confirm that GRP/GRP-R co-expression is a function of differentiation, with highest levels observed in well-differentiated tumor cells. We also show that the amount of total FAK and of FAK phosphorylated at Y397 and Y407 tightly correlates with differentiation and with the amount of GRP/GRP-R co-expression. These findings are consistent with GRP/GRP-R acting as a morphogen by activating FAK, and suggest that this occurs via phosphorylation of this enzyme at two specific tyrosine residues.