Louis Yuge

Neural stem cells improve learning and memory in rats with Alzheimer's disease.

Objective: We investigated whether neural stem cells (NSC) with transgenic expression of human nerve growth factor (hNGF) transplanted into the brain could offer a therapeutic option for the treatment of Alzheimer’s disease (AD). Methods: We infused okadaic acid into rat lateral ventricles to establish a chronic AD animal model. In addition, NSC were stably transduced with hNGF and enhanced green fluorescent protein (eGFP) genes (NSC-hNGF-eGFP) by using a recombination adeno-associated virus serotype 2 (rAAV2) vector. These genetically modified stem cells were grafted into the cerebral cortex of AD rats. Results: AD model rats showed significant damage in learning and memory function, with the formation of senile plaques and neurofibrillary tangles in the cerebral cortex. The transferred hNGF gene conferred stable and high levels of protein expression in NSC in vitro. Moreover, the NSC-hNGF-eGFP, but not the NSC, survived, integrating into the host brain and enhancing cognitive performance after transplantation. Conclusion: The injection of okadaic acid into rat lateral ventricles constitutes a promising animal model for investigating selective aspects of AD. rAAV2-mediated hNGF delivery can render long-term and stable transduction of hNGF in NSC. NSC-hNGF-eGFP transplantation may offer a viable therapeutic approach for treatment of AD.

Induction of cell transformation by mutated 16K vacuolar H + -atpase (ductin) is accompanied by down-regulation of gap junctional intercellular communication and translocation of connexin 43 in NIH3T3 cells

The 16 K subunit of the vacuolar H+-ATPase (ductin) has been suggested to also play a role in gap junction channels. Since mutated 16 K subunits have transforming ability when transfected into NIH3T3 cells and since aberrant gap junctional intercellular communication (GJIC) is a hallmark of cancer cells, we hypothesized that mutated 16 K subunits might transform these cells via alteration of GJIC. When GJIC was measured by the dye-transfer assay, NIH3T3 cells transfected with the mutant 16 K protein genes (deletion of the fourth transmembrane domain or a point mutation at codon 143 from glutamic acid to arginine) showed significantly lower levels of GJIC than those transfected with the vector alone or with the wild-type 16 K subunit gene. GJIC levels of NIH3T3 cells transformed by v-ras and v-src were not significantly decreased, suggesting that low GJIC levels are not necessarily the result of cell transformation per se. NIH3T3 cells express C×43 as a major connexin gene. Although cells transfected with mutated 16 K subunits showed a level of C×43 protein expression similar to non-transfectants, their C×43 protein was localized aberrantly, i.e. intracytoplasmically. These results indicate that mutant 16 K subunits with transforming ability translocate C×43 proteins, thus inhibiting GJIC of NIH3T3 cells.

Novel Electrical Stimulation Sets the Cultured Myoblast Contractile Function to ‘On’

Objective: In the present study, the effect of electrical stimulation was examined for the ability to induce morphological, physiological, and molecular biological effects on myoblasts during cell differentiation. Methods: L6 rat myoblasts were electrically stimulated by newly developed methods on culture days 6, 8, 10 and 12. Results: This electrical stimulation accelerated the appearance of myotubes, and subsequently produced spontaneously contracting muscle fibers. Measurement of membrane potential showed that the contracting cell had functional ion channels and gap junctional intercellular communication. In the electrically stimulated cells, an enhanced expression of MyoD family and M-cadherin was also observed. Expression of connexin 43 was increased and maintained at a high level in the electrically stimulated cells. Conclusion: This is the first demonstration of in vitro induction of myoblasts in spontaneously contractile muscle fibers by intermittent stimulation. This novel method for induction of myoblast differentiation represents an important advance in cell therapy.

Low-Intensity Pulsed Ultrasound Accelerates Osteoblast Differentiation and Promotes Bone Formation in an Osteoporosis Rat Model

Objective: We examined the effects of low-intensity pulsed ultrasound (LIPUS) on cell differentiation, bone mineralized nodule formation and core-binding factor A1 (Cbfa1) expression in a normal human osteoblast (NHOst) cell line and bone formation in an osteoporosis animal model. Methods: NHOst cells were cultured in vitro in medium with or without LIPUS stimulation. The ultrasound stimulation frequency was 1.0 MHz at an intensity of 30 mW/cm2 for 20 min. Rats were divided into a sham-operated group (Sham) and an ovariectomized group (OVX). The right femur was treated with LIPUS (Sham-LIPUS and OVX-LIPUS) and the left femur was left untreated (Sham-CON and OVX-CON). Results: LIPUS stimulation accelerated bone nodule formation and enhanced alkaline phosphatase activity. The expression levels of Cbfa1 decreased and calcification occurred earlier and more frequently in the LIPUS than in the CON groups. The wet weight of the femur increased in OVX rats with LIPUS stimulation. Morphological images showed an increase in trabecular spongiosa in the OVX-LIPUS group. Conclusion: LIPUS accelerated osteogenesis. Moreover, since LIPUS prevents bone loss, it may be a promising treatment for osteoporosis.

DIFFERENTIATION OF MYOBLASTS IS ACCELERATED IN CULTURE IN A MAGNETIC FIELD

SummaryWe developed a new cell stimulation method in which magnetic microparticles (MPs) were introduced into the cytoplasm of cultured myoblasts and the cells were cultured in a magnetic field. The differentiation of myoblasts was examined from the viewpoint of their morphology and myogenin production. After exposure to the magnetic field, the cells containing MPs became larger and were elongated along the axis of the magnetic poles. Myogenin, a muscle-specific regulatory factor involved in controlling myogenesis, was formed earlier, and myotubes were seen earlier and more frequently in this group of myoblasts than in the other groups (cells alone without magnetic field, cells containing MPs but without magnetic field, and cells alone with magnetic field). Moreover, we succeeded in differentiation of early muscle cells with striated myofibrils in culture at 0.05 T. The precisely quantitative and stable stimulus induced by a magnetic field developed in the present study offers a new approach to elucidate the entire process of myoblast differentiation into myotubes.

CELL DIFFERENTIATION AND p38MAPK CASCADE ARE INHIBITED IN HUMAN OSTEOBLASTS CULTURED IN A THREE-DIMENSIONAL CLINOSTAT

SummaryA three-dimensional (3D) clinostat is a device for multidirectional G force generation. By controlled rotation of two axes, a 3D clinostat cancels the cumulative gravity vector at the center of the device and produces an environment with an average of 10−3 G over time. We cultured a human osteoblast cell line in a 3D clinostat and examined the growth properties and differentiation of the cells, including morphology, histological detection of calcification, and mitogenactivated protein kinase (MAPK) cascades. In a normal 1G condition, alkaline phosphatase (AIPase) activity was detected on day 7 of culture, bone nodules were formed on day 12, and calcium deposits were seen on day 20. In the 3D clinostat, the cell looked larger and bulged. AIPase activity was detected on day 10 of culture. However, neither bone nodules nor calcification was found in the 3D clinostat up to day 21. The expression levels of core-binding factor A1 (a transcription factor for bone formation) and osteocalcin (a bone matrix protein) increased in the control culture but decreased in culture in 3D clinostat. Phosphorylation of p38MARK (p38) was repressed in culture in 3D clinostat, whereas total p38 as well as total and phosphorylated forms of extracellular signal-regulated kinases and stress-activated protein kinase/jun N-terminal kinase were not changed in the 3D clinostat. When a p38 inhibitor, SB 203580, was added to the culture medium in a normal 1 G environment, AIPase activity and formation of bone nodules and calcium deposits were strongly inhibited. On the other hand, they were inhibited only partially by a MARK kinase inhibitor, U-0126. On the basis of these results, it is concluded that (1) osteoblast differentiation is inhibited in culture in a 3D clinostat and (2) this inhibition is mainly due to the suppression of p38 phophorylation.

LIF-free embryonic stem cell culture in simulated microgravity.

Background Leukemia inhibitory factor (LIF) is an indispensable factor for maintaining mouse embryonic stem (ES) cell pluripotency. A feeder layer and serum are also needed to maintain an undifferentiated state, however, such animal derived materials need to be eliminated for clinical applications. Therefore, a more reliable ES cell culture technique is required. Methodology/Principal Findings We cultured mouse ES cells in simulated microgravity using a 3D-clinostat. We used feeder-free and serum-free media without LIF. Conclusions/Significance Here we show that simulated microgravity allows novel LIF-free and animal derived material-free culture methods for mouse ES cells.

Impact of the microgravity environment in a 3-dimensional clinostat on osteoblast- and osteoclast-like cells

Mechanical unloading conditions result in decreases in bone mineral density and quantity, which may be partly attributed to an imbalance in bone formation and resorption. To investigate the effect of mechanical unloading on osteoblast and osteoclast differentiation, and the expression of RANKL and OPG genes in osteoblasts, we used a three‐dimensional (3D) clinostat system simulating microgravity to culture MC3T3‐E1 and RAW264.7 cells. Long‐term exposure (7 days) of MC3T3‐E1 cells to microgravity in the 3D clinostat inhibited the expression of Runx2, Osterix, type I collagen αI chain, RANKL and OPG genes. Similarly, 3D clinostat exposure inhibited the enhancement of β3‐integrin gene expression, which normally induced by sRANKL stimulation in RAW264.7 cells. These results, taken together, demonstrate that long‐term 3D clinostat exposure inhibits the differentiation of MC3T3‐E1 cells together with suppression of RANKL and OPG gene expression, as well as the RANKL‐dependent cellular fusion of RAW264.7 cells, suggesting that long‐term mechanical unloading suppresses bone formation and resorption.

Simulated microgravity maintains the undifferentiated state and enhances the neural repair potential of bone marrow stromal cells.

Recently, regenerative medicine with bone marrow stromal cells (BMSCs) has gained significant attention for the treatment of central nervous system diseases. Here, we investigated the activity of BMSCs under simulated microgravity conditions. Mouse BMSCs (mBMSCs) were isolated from C57BL/6 mice and harvested in 1G condition. Subjects were divided into 4 groups: cultured under simulated microgravity and 1G condition in growth medium and neural differentiation medium. After 7 days of culture, the mBMSCs were used for morphological analysis, reverse transcription (RT)-polymerase chain reaction, immunostaining analysis, and grafting. Neural-induced mBMSCs cultured under 1G conditions exhibited neural differentiation, whereas those cultured under simulated microgravity did not. Moreover, under simulated microgravity conditions, mBMSCs could be cultured in an undifferentiated state. Next, we intravenously injected cells into a mouse model of cerebral contusion. Graft mBMSCs cultured under simulated microgravity exhibited greater survival in the damaged region, and the motor function of the grafted mice improved significantly. mBMSCs cultured under simulated microgravity expressed CXCR4 on their cell membrane. Our study indicates that culturing cells under simulated microgravity enhances their survival rate by maintaining an undifferentiated state of cells, making this a potentially attractive method for culturing donor cells to be used in grafting.

Detrimental Effects of Microgravity on Mouse Preimplantation Development In Vitro

Sustaining life beyond Earth either on space stations or on other planets will require a clear understanding of how the space environment affects key phases of mammalian reproduction. However, because of the difficulty of doing such experiments in mammals, most studies of reproduction in space have been carried out with other taxa, such as sea urchins, fish, amphibians or birds. Here, we studied the possibility of mammalian fertilization and preimplantation development under microgravity (µG) conditions using a three-dimensional (3D) clinostat, which faithfully simulates 10–3 G using 3D rotation. Fertilization occurred normally in vitro under µG. However, although we obtained 75 healthy offspring from µG-fertilized and -cultured embryos after transfer to recipient females, the birth rate was lower than among the 1G controls. Immunostaining demonstrated that in vitro culture under µG caused slower development and fewer trophectoderm cells than in 1G controls but did not affect polarization of the blastocyst. These results suggest for the first time that fertilization can occur normally under µG environment in a mammal, but normal preimplantation embryo development might require 1G.