Members of the metalloproteinase family (MMPs) are known to play a crucial role in the metastatic cascade. Here, we report some investigations about the synthesis of interstitial and type-IV collagenases (gelatinases A and B) in a model of coculture of human fibroblasts and HT 1080 fibrosarcoma cells. The interstitial collagenase activity, mainly found in the conditioned medium of fibroblasts, and its mRNA level were increased in the in vitro coculture model. In contrast, gelatinase A was produced by both cell types. The HT 1080 cells additionally synthesised gelatinase B. In coculture, an enhancement of gelatinase A and the presence of its activated form were observed. Northern blot analysis demonstrated that this enzymatic enhancement occurred at a pretranslational level. The stimulation of the interstitial collagenase activity was partially mediated through soluble factor(s), whereas increased gelatinase A appeared to require direct cell-cell interactions. The extracellular matrix component, type-I collagen, stimulated the enzymatic activities released by the individual cells, but it did not modulate the synthesis of interstitial collagenase in coculture. Our results demonstrate that distinct MMPs are modulated by distinct mechanisms, all depending on specific interactions between tumour cells and host fibroblasts.
The editors are publishing this note to alert readers to concerns about this article (1). In Fig. 2, the actin loading control bands for cyclin D1 and cyclin D2 are identical–the authors clarified that the Western blots for cyclin D1 and cyclin D2 were performed on the same samples, however, this was not indicated in the figure legend. Additionally, in Fig. 6C, the p-EGFR bands in MDA-MB-231 cells showing stimulation by TGFα treatment are identical to the p-EGFR bands showing stimulation by EGF treatment. In the original submission of this manuscript, a correct version of this figure was used to show both TGFα and EGF could stimulate p-EGFR in control vector (CTR)– and MT4-MMP–expressing (MT4) MDA-MB-231 cells, but these panels were mistakenly duplicated in the revised and final versions of the manuscript.
The influence of various normal and malignant human cells on the level of collagen synthesis by human fibroblasts was tested in coculture. As revealed by immunoperoxidase staining, in cocultures with breast adenocarcinoma cells (MCF7, SA52, T47D) fibroblasts synthesized collagen while tumor cells did not. Fibroblasts displayed increased collagen production without change in the overall protein synthesis. Several other types of cells derived from normal human tissues (keratinocytes, normal mammary cells) or from fibrosarcoma, melanoma, cervical carcinoma, choriocarcinoma, or other breast adenocarcinoma (SW613, MDA, BT20) did not affect collagen synthesis of fibroblasts. Although to a lesser extent, this stimulating effect was reproduced by using the conditioned medium (CM) of the active cells but not with CM of the other cell types. A slight stimulation was also obtained when tumoral MCF7 cells and fibroblasts shared the same medium but were physically separated, suggesting that close contact was required for optimal stimulation of collagen synthesis. The collagen synthesis stimulating activity was not related to a modification of fibroblast proliferation rate. The production of collagen types I, III, and VI and fibronectin were increased in cocultures of fibroblasts with MCF7 cells. The increased synthesis of collagen types I and III and fibronectin was paralleled by similar changes in the steady-state level of their mRNAs. On the contrary, the increased production of collagen type VI appeared regulated at a post-transcriptional level.
Levonorgestrel-releasing intrauterine system (LNG-IUS), although inserted to reduce heavy menstruation, causes irregular early transient bleeding. The objective of the study was to document quantitative changes in endometrial vessels of short- (< or =3 months) and long-term (> or =12 months) LNG users. The area, density and maturation of endometrial vessels were quantified in 19 endometrial biopsies of women with LNG-IUS and in 10 normally ovulating patients during mid-luteal phase.Vessel maturation was evaluated by double immunostaining using anti-von Willebrand factor (endothelial cell marker) and anti-alpha Smooth Muscle Actin (vascular smooth muscle cells) antibodies. Vessel area, number and density were quantified with a novel computer-assisted image analysis system.Endometrium exposed to LNG-IUS for 1-3 months displayed a 11.5-fold increase in small naked vessel number. The partially mature vessel (alphaSMA partially positive) number increased six times. After long-term LNG-IUS treatment, the immature and partially mature vessel number remained four times higher than in the control group. Vessel area and density also increased dramatically in a time-dependent pattern with LNG-IUS use.Levonorgestrel affects blood vessel number, area, density and maturation in a time-dependent pattern that may explain the early transient increase in breakthrough bleeding with the LNG-IUS.
For women facing gonadotoxic treatment, cryopreservation of ovarian tissue with subsequent retransplantation during remission is a promising technique for fertility preservation. However, follicle loss within grafted ovarian tissue can be caused by ischemia and progressive revascularization. Several xenograft models using different immunodeficient rodent lines are suitable for studying ovarian tissue survival and follicular viability after frozen-thawed ovarian cortex transplantation. SCID mice, which are deficient for functional B and T cells, are the most commonly used mice for ovarian xenograft studies. However, due to incomplete immunosuppression, NOD-SCID mice displaying low NK cell function and an absence of circulating complement might be more appropriate. The present study aims to define the most appropriate immunodeficient mouse strain for ovarian tissue xenotransplantation by comparing ovarian graft recovery in SCID and NOD-SCID mice following engraftment in the presence of isoform 111 of vascular endothelial growth factor.Sheep ovarian cortex fragments were embedded in a collagen matrix, with or without VEGF111, before being stitched onto the ovaries of SCID and NOD-SCID mice. Transplants were recovered after 3 days to study early revascularization or after 3 weeks to evaluate follicle preservation and tissue fibrosis through histological analyses.At day 3, vessels were largely reorganized in the ovarian grafts of both mouse strains. After 3 weeks, the cortical tissue was clearly identifiable in SCID mice but not in NOD-SCID mice. Upon VEGF111 treatment, vascularization was significantly improved 3 days after transplantation in SCID mice. This increase in vessel density was correlated with better follicular preservation in SCID mice 3 weeks after transplantation. Fibrosis was not decreased by VEGF treatment in either mouse strain.Tissue architecture and follicular morphology were better preserved in ovarian tissues grafted in SCID mice in comparison with NOD-SCID mice. Moreover, tissue revascularization was improved in SCID mice by VEGF111 graft treatment. Thus, we consider SCID mice to be the best murine model for studying ovarian tissue xenografts.
Murine placentation is associated with the invasion of maternal endometrium by trophoblasts and an extensive maternal and fetal angiogenesis. Plasminogen activator inhibitor-1 (PAI-1) is transiently produced by spongiotrophoblasts and trophoblast giant cells at 10.5-11.5 days postcoitum (dpc). Knowing the key contribution of PAI-1 in the regulation of angiogenesis, we have now analyzed the consequence of PAI-1 deficiency on murine placentation. Morphological and quantitative computer-assisted image analysis revealed abnormal placental morphology in PAI-1-/- mice at 10.5 and 12.5 dpc. At 10.5 dpc, the genetic ablation of PAI-1 resulted in a transient reduction of both maternal and fetal vascularizations in the placenta and increased trophoblast cell density. This was associated with a poorer development of the labyrinth and an extension of the decidua. A larger spongiotrophoblast layer appeared at 12.5 dpc in PAI-1-deficient mice. Placental morphology was normalized at 14.5 dpc. Microarray analyses performed on laser capture microdissected labyrinths revealed that 46 genes were differentially expressed between the two genotypes at 10.5 dpc. However, only 11 genes were still differently modulated at 14.5 dpc, when normalization of placental morphology had taken place. This transcriptomic profiling highlighted a dysregulation in the expression of placenta-related cathepsin family members. Altogether our data provide evidence for a transient impaired placental morphology in PAI-1-deficient mice that is then normalized, leading to normal embryonic development.
Abstract Background Currently, the only fertility preservation option of prepubertal patients is ovarian tissue cryopreservation followed by autotransplantation (OTCTP). Once in remission and patients desire to conceive, autotransplantation of frozen/thawed tissue is performed. A major issue of this technique is follicular loss directly after transplantation, mainly due to follicle activation. Our previous research showed that adding rapamycin to the freezing medium counteracted follicle proliferation and activation induced by OTCTP in heterotopic autotransplantation of ovaries in mice. Our current study aimed to test the potential of this approach to improve fertility restoration in mice. Methods Forty 4-week-old female C57BL/6 mice underwent unilateral oophorectomy followed by slow-freezing of ovaries with or without rapamycin. After chemically disabling the remaining ovary, orthotopic autotransplantation was performed. After recovery, estrus cycle analysis was conducted using daily vaginal smears. The mice were mated with males for 4 months, and pregnancy outcomes were recorded. After mating, half the females were super-ovulated for oocyte quantification and ovarian analysis, while the others had their ovaries collected for analysis of remaining primordial follicles using immunohistochemistry. Results Female mice whose ovaries were cryopreserved with rapamycin prior to chemically disabling the remaining ovary and orthotopic autotransplantation, gave birth to more pups (102 rapamycin, 48 control). The live birth rate was also higher (P = 0.0025) when ovaries were cryopreserved in rapamycin compared to control medium. Additionally, more mice in the rapamycin group gave birth (13 rapamycin, 8 control) with a higher average litter size (P = 0.0837). More mice had primordial follicles left at the end of the experiment in the rapamycin group (P = 0.0397). Superovulation showed a similar number of oocytes collected (P = 0.4462). While rapamycin did not influence cyst formation after autotransplantation, mice that developed ovarian cysts gave birth to fewer pups per dam (P = 0.0119) with a lower live birth rate compared to mice without ovarian cysts (P = 0.0032). Conclusion The use of rapamycin improved fertility restoration in mice. Using rapamycin during OTCTP in humans could potentially resolve the massive follicular loss directly after grafting, and thus eventually lead to better opportunities for women to become pregnant.
