A novel hydra matrix metalloproteinase (HMMP) functions in extracellular matrix degradation, morphogenesis and the maintenance of differentiated cells in the foot process.

As a member of Cnidaria, the body wall of hydra is structurally reduced to an epithelial bilayer with an intervening extracellular matrix (ECM). Biochemical and cloning studies have shown that the molecular composition of hydra ECM is similar to that seen in vertebrates and functional studies have demonstrated that cell-ECM interactions are important to developmental processes in hydra. Because vertebrate matrix metalloproteinases (MMPs) have been shown to have an important role in cell-ECM interactions, the current study was designed to determine whether hydra has homologues of these proteinases and, if so, what function these enzymes have in morphogenesis and cell differentiation in this simple metazoan. Utilizing a PCR approach, a single hydra matrix metalloproteinase, named HMMP was identified and cloned. The structure of HMMP was similar to that of vertebrate MMPs with an overall identity of about 35%. Detailed structural analysis indicated some unique features in (1) the cysteine-switch region of the prodomain, (2) the hinge region preceding the hemopexin domain, and (3) the hemopexin domain. Using a bacterial system, HMMP protein was expressed and folded to obtain an active enzyme. Substrate analysis studies indicated that recombinant HMMP could digest a number of hydra ECM components such as hydra laminin. Using a fluorogenic MMP substrate assay, it was determined that HMMP was inhibited by peptidyl hydroxamate MMP inhibitors, GM6001 and matlistatin, and by human recombinant TIMP-1. Whole-mount in situ studies indicated that HMMP mRNA was expressed in the endoderm along the entire longitudinal axis of hydra, but at relatively high levels at regions where cell-transdifferentiation occurred (apical and basal poles). Functional studies using GM6001 and TIMP-1 indicated that these MMP inhibitors could reversibly block foot regeneration. Blockage of foot regeneration was also observed using antisense thio-oligo nucleotides to HMMP introduced into the endoderm of the basal pole using a localized electroporation technique. Studies with adult intact hydra found that GM6001 could also cause the reversible de-differentiation or inhibition of transdifferentiation of basal disk cells of the foot process. Basal disk cells are adjacent to those endoderm cells of the foot process that express high levels of HMMP mRNA. In summary, these studies indicate that hydra has at least one MMP that is functionally tied to morphogenesis and cell transdifferentiation in this simple metazoan

The expression of gelatinase A (MMP-2) is required for normal development of zebrafish embryos.

Gelatinase A, also called matrix metalloproteinase 2 (MMP-2), belongs to the matrix metalloproteinase (MMP) family. MMP-2 cleaves type IV collagen, denatured collagen (gelatin), and other extracellular matrix (ECM) components. MMP-2 has been reported to be involved in a number of biological and pathological processes, but previous studies have not indicated that its expression is essential for early embryogenesis. In the current study, we have utilized zebrafish as a developmental model to study the role of MMP-2 during embryogenesis. We have successfully isolated a zebrafish MMP-2 (zMMP-2) homologue showing over 80% identity and over 90% similarity to its human counterpart. In situ analysis showed that zMMP-2 was expressed as early as the one-cell stage implying a maternal origin during oogenesis, and embryos continued to express zMMP-2 through at least the 72-h stage of development. RT-PCR analysis confirmed the in situ expression pattern and gelatin zymography indicated that a metalloproteinase with the same gel mobility as vertebrate MMP-2 was present in zebrafish embryos. Injection of zMMP-2 antisense morpholino oligonucleotides into 1- to 4-cell embryos resulted in a truncated axis, monitored through 72 h of development indicating that this metalloproteinase plays an important role in zebrafish embryogenesis. Monpholino-induced alterations in development began to be observed at 12 h of embryogenesis based on morphological and axis marker studies. The results obtained in zebrafish are in contrast to murine knockout studies that indicate that MMP-2 does not have a major role in mouse embryogenesis

The expression of tissue inhibitor of metalloproteinase 2 (TIMP-2) is required for normal development of zebrafish embryos.

MMP activities are controlled by a combination of proteolytic pro-enzyme activation steps and inhibition by endogenous inhibitors like alpha2-macroglobulin and the tissue inhibitors of metalloproteinases (TIMPs). TIMPs are the key inhibitors in tissue. The expression of both MMPs and TIMPs is controlled during tissue remodeling to maintain a balance in the turnover of extracellular matrix. Disruption of this balance may result in a broad spectrum of diseases. Additionally, TIMP-2 has been reported to have growth factor activities. To further study the function of TIMP-2 in development, we utilized zebrafish as an experimental model system. We have successfully isolated a TIMP-2 homologue from zebrafish (zTIMP-2). This zebrafish TIMP-2 showed high similarity to human TIMP-2 with all critical features conserved. Whole-mount in situ analysis showed that zTIMP-2 was expressed as early as the one-cell stage indicating a maternal origin. This expression continued through later stages of development. RT-PCR analysis confirmed the early expression pattern from the 16-cell stage through blastula, gastrula and 24-h stages. In addition, at the protein level, immunoreactive zTIMP-2 was detected using antibody against recombinant human TIMP-2. RFP-reporter analysis indicated that TIMP-2 can be secreted into the extracellular space where ECM is forming. Functional studies showed that the balance of TIMP-2 expression is important to normal development as reflected by the fact that both blockage of TIMP-2 translation using antisense morpholino oligonculeotides or increased translation of TIMP-2 using a mRNA microinjection approach resulted in abnormal zebrafish development. This is in contrast to murine knockout studies that indicate that TIMP-2 does not have a major role in mouse embryogenesis

The expression of novel membrane-type matrix metalloproteinase isoforms is required for normal development of zebrafish embryos.

Matrix metalloproteinases (MMPs) play important roles in the turnover of components of extracellular matrix (ECM) and in the processing of active and latent-signaling molecules bound to the ECM or associated with the cell surface. Through such actions, MMPs regulate a variety of cellular and developmental processes. Membrane-type matrix metalloproteinases (MT-MMPs) are of particular importance because they function in the immediate pericellular environment that modulates both cell-cell and cell-ECM interactions. In this study, we utilized zebrafish as a developmental model to study the role of MT-MMPs during early embryogenesis. We successfully isolated two isoforms of a MT-MMP homologue that are structurally similar to MT1-MMP. They have been named zebrafish MT-MMPalpha and beta. Zebrafish MT-MMPbeta is unique among vertebrate MT-MMPs in that it contains an Arg-Glu-Asp (RED) multiple-repeat motif in its linker region. Whole mount in situ analysis, RT-PCR, immunofluorescence, reporter analysis, Western blot analysis, and zymography indicated that MT-MMPalpha and beta were expressed through at least the first 72 h of development and that this expression was targeted to the cell surface. Functional studies using injection of either mRNA or morpholino antisense oligonucleotides resulted in a truncation of the cranial to caudal axis as monitored through 72 h post fertilization, indicating that zebrafish MT-MMPalpha and beta had an important role in embryonic development. Axis markers indicated that these effects likely involved processes occurring later than 10 h of embryogenesis

Matrix metalloproteinase expression and function during fin regeneration in zebrafish: analysis of MT1-MMP, MMP2 and TIMP2.

Matrix metalloproteinases (MMPs) play key roles in the turnover of extracellular matrix (ECM) and, thereby, function as key regulators of cell-ECM interactions during development. In spite of their importance during developmental processes, relatively little has been reported about the role of these metalloproteinases during limb development and regeneration. To approach the problem of cell-ECM interactions during limb (fin) regeneration, we have utilized zebrafish as an experimental model. Based on previous MMP cloning studies from our laboratory, the current study has focused on the expression of membrane-type 1 metalloproteinase (MT1-MMP), gelatinase A (MMP-2) and endogenous tissue inhibitor 2 of metalloproteinases (TIMP-2) during fin regeneration in adult zebrafish. In situ analysis indicated co-expression of zmt1-mmp, zmmp-2, and ztimp-2 mRNA transcripts in regenerating caudal fins. In situ gelatin-zymography confirmed the presence of active metalloproteinases in regenerating fins. zmt1-mmp, zmmp-2, and ztimp-2 mRNA transcripts were expressed in the blastema and basal epithelium during caudal fin regeneration while expression of type IV collagen [zcol-IV(a5)] transcripts (a basal lamina component) was restricted to the basal epithelium. Fin outgrowth was greatly reduced in the presence of GM6001 (an inhibitor of MMP activity) indicating the importance of these enzymes during fin regeneration. Previous studies by Itoh (EMBO, 2001) indicated that expression of a vertebrate MT1-MMP construct containing only the hemopexin-transmembrane-cytoplasmic domains (MT1HPX) resulted in blockage of MT1-MMP homophilic complex formation and subsequent inhibition of pro-MMP-2 activation. Interference with homophilic complex formation was attributed to expression of the hemopexin domain at the cell surface. Building upon these earlier findings, the current study found that ectopic expression of MT1HPX in fin regenerates inhibited the regeneration process and resulted in a reduction in cell proliferation in the blastema. Taken together, these results indicate that MMPs have an important role during fin regeneration in zebrafish

Diabetes, adult neurogenesis and brain remodeling: New insights from rodent and zebrafish models

International audienceThe prevalence of diabetes rapidly increased during the last decades in association with important changes in lifestyle. Diabetes and hyperglycemia are well-known for inducing deleterious effects on physiologic processes, increasing for instance cardiovascular diseases, nephropathy, retinopathy and foot ulceration. Interestingly, diabetes also impairs brain morphology and functions such as (1) decreased neurogenesis (proliferation, differentiation and cell survival), (2) decreased brain volumes, (3) increased blood-brain barrier leakage, (4) increased cognitive impairments, as well as (5) increased stroke incidence and worse neurologic outcomes following stroke. Importantly, diabetes is positively associated with a higher risk to develop Alzheimer disease. In this context, we aim at reviewing the impact of diabetes on neural stem cell proliferation, newborn cell differentiation and survival in a homeostatic context or following stroke. We also report the effects of hyper- and hypoglycemia on the blood-brain barrier physiology through modifications of tight junctions and transporters. Finally, we discuss the implication of diabetes on cognition and behavior