Kevin M. Curtis

EF1α and RPL13a represent normalization genes suitable for RT-qPCR analysis of bone marrow derived mesenchymal stem cells

BackgroundRT-qPCR analysis is a widely used method for the analysis of mRNA expression throughout the field of mesenchymal stromal cell (MSC) research. Comparison between MSC studies, both in vitro and in vivo, are challenging due to the varied methods of RT-qPCR data normalization and analysis. Therefore, this study focuses on putative housekeeping genes for the normalization of RT-qPCR data between heterogeneous commercially available human MSC, compared with more homogeneous populations of MSC such as MIAMI and RS-1 cells.ResultsEight genes including; ACTB, B2M, EF1α, GAPDH, RPL13a, YWHAZ, UBC and HPRT1 were tested as possible housekeeping genes based on their expression level and variability. EF1α and RPL13a were validated for RT-qPCR analysis of MIAMI cells during expansion in varied oxygen tensions, endothelial differentiation, neural precursor enrichment, and during the comparison with RS-1 cells and commercially available MSC. RPL13a and YWHAZ were validated as normalization genes for the cross-species analysis of MIAMI cells in an animal model of focal ischemia. GAPDH, which is one of the most common housekeeping genes used for the normalization of RT-qPCR data in the field of MSC research, was found to have the highest variability and deemed not suitable for normalization of RT-qPCR data.ConclusionsIn order to make comparisons between heterogeneous MSC populations, as well as adult stem cell like MSC which are used in different laboratories throughout the world, it is important to have a standardized, reproducible set of housekeeping genes for RT-qPCR analysis. In this study we demonstrate that EF1α, RPL13a and YWHAZ are suitable genes for the RT-qPCR analysis and comparison of several sources of human MSC during in vitro characterization and differentiation as well as in an ex vivo animal model of global cerebral ischemia. This will allow for the comparative RT-qPCR analysis of multiple MSC populations with the goal of future use in animal models of disease as well as tissue repair.

EGF and bFGF pre-treatment enhances neural specification and the response to neuronal commitment of MIAMI cells

AIMS Multipotent mesenchymal stromal cells raise great interest for regenerative medicine studies. Some MSC subpopulations have the potential to undergo neural differentiation, including marrow isolated adult multilineage inducible (MIAMI) cells, which differentiate into neuron-like cells in a multi-step neurotrophin 3-dependent manner. Epidermal and basic fibroblast growth factors are often used in neuronal differentiation protocols for MSCs, but with a limited understanding of their role. In this study, we thoroughly assessed for the first time the capacity of these factors to enhance the neuronal differentiation of MSCs. MATERIALS AND METHODS We have characterized MIAMI cell neuronal differentiation program in terms of stem cell molecule expression, cell cycle modifications, acquisition of a neuronal morphology and expression of neural and neuronal molecules in the absence and presence of an EGF-bFGF pre-treatment. RESULTS EGF-bFGF pre-treatment down-regulated the expression of stemness markers Oct4A, Notch1 and Hes5, whereas neural/neuronal molecules Nestin, Pax6, Ngn2 and the neurotrophin receptor tyrosine kinase 1 and 3 were up-regulated. During differentiation, a sustained Erk phosphorylation in response to NT3 was observed, cells began to exit from the cell cycle and exhibit increased neurite-like extensions. In addition, neuronal β3-tubulin and neurofilament expression was increased; an effect mediated via the Erk pathway. A slight pre-oligodendrocyte engagement was noted, and no default neurotransmitter phenotype was observed. Overall, mesodermal markers were unaffected or decreased, while neurogenic/adipogenic PPARγ2 was increased. CONCLUSION EGF and bFGF pre-treatment enhances neural specification and the response to neuronal commitment of MIAMI cells, further increasing their potential use in adult cell therapy of the nervous system.

Na-K-Cl cotransporter-1 in the mechanism of cell swelling in cultured astrocytes after fluid percussion injury.

J. Neurochem. (2011) 117, 437–448.

Aquaporin-4 Expression in Cultured Astrocytes after Fluid Percussion Injury

The development of cytotoxic brain edema resulting in increased intracranial pressure is a major cause of death occurring in the early phase of traumatic brain injury (TBI). Such edema predominantly develops as a consequence of astrocyte swelling. We recently documented that fluid percussion injury (FPI) to cultured astrocytes causes cell swelling. Since aquaporin-4 (AQP4) has been strongly implicated in the development of brain edema/astrocyte swelling in various neurological conditions, this study examined the effect of in vitro trauma on AQP4 protein expression in cultured astrocytes. Exposure of astrocytes to FPI resulted in a significant upregulation of AQP4 protein in the plasma membrane due to neosynthesis, as cycloheximide blocked the trauma-induced AQP4 upregulation. Silencing the aqp4 gene by siRNA resulted in a significant reduction in trauma-induced astrocyte swelling, indicating a critical role of AQP4 in this process. We recently documented that oxidative/nitrative stress (ONS), the mitochondrial permeability transition (mPT), and activation of mitogen-activated protein kinases (MAPKs), contribute to trauma-induced astrocyte swelling in culture. We now show that inhibition of these factors reduces the upregulation of AQP4 following trauma. Since TBI has been shown to activate nuclear factor-kappa B (NF-κB), as well as the Na(+),K(+),Cl(-) co-transporter (NKCC), both of which are implicated in brain edema/astrocyte swelling in other conditions, we also examined the effect of BAY 11-7082 and bumetanide, inhibitors of NF-κB and NKCC, respectively, and found that these agents also significantly inhibited the trauma-induced AQP4 upregulation. Our findings show that in vitro trauma upregulates AQP4, and that ONS, MAPKs, mPT, NF-κB, and NKCC are involved in its upregulation.

Neuroprotective properties of marrow-isolated adult multilineage-inducible cells in rat hippocampus following global cerebral ischemia are enhanced when complexed to biomimetic microcarriers

J. Neurochem. (2011) 119, 972–988.

Aquaporin-4 in manganese-treated cultured astrocytes

Manganese in excess is neurotoxic and causes CNS injury resembling that of Parkinsons disease. In brain, astrocytes predominantly take up and accumulate manganese and are thus vulnerable to its toxicity. Manganese was shown to induce cell swelling in cultured astrocytes, and oxidative/nitrosative stress (ONS) mediates such swelling. As aquaporin‐4 (AQP4) is important in the mechanism of astrocyte swelling, we examined the effect of manganese on AQP4 protein levels in cultured astrocytes. Treatment of cultures with manganese increased AQP4 protein in the plasma membrane (PM), whereas total cellular AQP4 protein and mRNA levels were unchanged, suggesting that increased AQP4 levels is due to its increased stability and/or increased trafficking to the PM and not to its neosynthesis. AQP4 gene silencing by small interfering ribonucleic acid resulted in a marked reduction in astrocyte swelling by manganese. Antioxidants, as well as an inhibitor of nitric oxide synthase, diminished the increase in AQP4 protein expression, suggesting a role of ONS in the mechanism of AQP4 increase. As ONS is known to activate mitogen‐activated protein kinases (MAPKs) and MAPK activation has been implicated in astrocyte swelling, we examined the effect of manganese on the activation of MAPKs and found an increased phosphorylation of extracellular signal‐regulated kinase (ERK)1/2, C‐Jun amino‐terminal kinase (JNK)1/2/3, and p38‐MAPK. Inhibitors of ERK1/2 and p38‐MAPK (but not of JNK) blocked (40–60%) the manganese‐induced increase in AQP4 protein content and astrocyte swelling, suggesting the involvement of these kinases in the increased AQP4 content. Inhibition of oxidative stress or MAPKs may represent potential strategies for counteracting AQP4‐related neurological complications associated with manganese toxicity.

Decreased Astrocytic Thrombospondin-1 Secretion After Chronic Ammonia Treatment Reduces the Level of Synaptic Proteins: In Vitro and In Vivo Studies

Chronic hepatic encephalopathy (CHE) is a major complication in patients with severe liver disease. Elevated blood and brain ammonia levels have been implicated in its pathogenesis, and astrocytes are the principal neural cells involved in this disorder. Since defective synthesis and release of astrocytic factors have been shown to impair synaptic integrity in other neurological conditions, we examined whether thrombospondin‐1 (TSP‐1), an astrocytic factor involved in the maintenance of synaptic integrity, is also altered in CHE. Cultured astrocytes were exposed to ammonia (NH4Cl, 0.5–2.5 mM) for 1–10 days, and TSP‐1 content was measured in cell extracts and culture media. Astrocytes exposed to ammonia exhibited a reduction in intra‐ and extracellular TSP‐1 levels. Exposure of cultured neurons to conditioned media from ammonia‐treated astrocytes showed a decrease in synaptophysin, PSD95, and synaptotagmin levels. Conditioned media from TSP‐1 over‐expressing astrocytes that were treated with ammonia, when added to cultured neurons, reversed the decline in synaptic proteins. Recombinant TSP‐1 similarly reversed the decrease in synaptic proteins. Metformin, an agent known to increase TSP‐1 synthesis in other cell types, also reversed the ammonia‐induced TSP‐1 reduction. Likewise, we found a significant decline in TSP‐1 level in cortical astrocytes, as well as a reduction in synaptophysin content in vivo in a rat model of CHE. These findings suggest that TSP‐1 may represent an important therapeutic target for CHE.

Increased toll-like receptor 4 in cerebral endothelial cells contributes to the astrocyte swelling and brain edema in acute hepatic encephalopathy.

Astrocyte swelling and the subsequent increase in intracranial pressure and brain herniation are major clinical consequences in patients with acute hepatic encephalopathy. We recently reported that conditioned media from brain endothelial cells (ECs) exposed to ammonia, a mixture of cytokines (CKs) or lipopolysaccharide (LPS), when added to astrocytes caused cell swelling. In this study, we investigated the possibility that ammonia and inflammatory agents activate the toll‐like receptor 4 (TLR4) in ECs, resulting in the release of factors that ultimately cause astrocyte swelling. We found a significant increase in TLR4 protein expression when ECs were exposed to ammonia, CKs or LPS alone, while exposure of ECs to a combination of these agents potentiate such effects. In addition, astrocytes exposed to conditioned media from TLR4‐silenced ECs that were treated with ammonia, CKs or LPS, resulted in a significant reduction in astrocyte swelling. TLR4 protein up‐regulation was also detected in rat brain ECs after treatment with the liver toxin thioacetamide, and that thioacetamide‐treated TLR4 knock‐out mice exhibited a reduction in brain edema. These studies strongly suggest that ECs significantly contribute to the astrocyte swelling/brain edema in acute hepatic encephalopathy, likely as a consequence of increased TLR4 protein expression by blood‐borne noxious agents.

Amyloid-β inhibits thrombospondin 1 release from cultured astrocytes: effects on synaptic protein expression.

Among the consequences of Alzheimer disease are disturbances in synaptic integrity that ultimately lead to impaired cognitive functions. Thrombospondins are extracellular matrix proteins that, in the CNS, are predominantly produced by astrocytes and have been implicated in synaptogenesis. This study examined the effects of amyloid-β (Aβ(1-42); Aβ) peptide on intracellular and extracellular levels of thrombospondin 1 (TSP-1) in cultured astrocytes. Amyloid-β caused a significant (1- to 3-fold) increase in astrocytic intracellular levels of TSP-1 (increased retention) that was associated with a reduction of its release from astrocytes. Because Aβ is known to induce oxidative stress in astrocytes, we examined the effects of the antioxidants tempol and apocynin on astrocytic TSP-1 levels and release. Treatment of Aβ-exposed astrocyte cultures with antioxidants significantly diminished its cellular retention and stimulated its release. Furthermore, the addition of conditioned media derived from Aβ-treated cultured astrocytes that contained a reduced TSP-1 content resulted in a significant loss of synaptophysin and PSD95 in cultured neurons. These findings suggest that Aβ-mediated reduction in astrocytic TSP-1 release, possibly related to oxidative stress, contributes to the loss of synaptophysin in neurons. Strategies aimed at enhancing the astrocytic release of TSP-1 may have a therapeutic benefit in Alzheimer disease.

Brain Aquaporin-4 in Experimental Acute Liver Failure

Intracranial hypertension caused by brain edema and associated astrocyte swelling is a potentially lethal complication of acute liver failure (ALF). Mechanisms of edema formation are not well understood, but elevated levels of blood and brain ammonia and its by-product glutamine have been implicated in this process. Since aquaporin-4 (AQP4) has been implicated in brain edema in other conditions, we examined its role in a rat model of ALF induced by the hepatotoxin thioacetamide. Rats with ALF showed increased AQP4 protein in the plasma membrane (PM). Total tissue levels of AQP4 protein and mRNA levels were not altered, indicating that increased AQP4 is not transcriptionally mediated but likely reflects a more stable anchoring of AQP4 to the PM and/or interference with its degradation. An increase inAQP4 immunoreactivity in thePM was observed in perivascular astrocytes in ALF. Rats with ALF also showed increased levels of &agr;-syntrophin, a protein involved in anchoringAQP4 to perivascular astrocytic end-feet. Increased AQP4 and&agr;-syntrophin levels were inhibited by L-histidine, an inhibitor of glutamine transport into mitochondria, suggesting a role for glutamine in the increase of PM levels of AQP4. These results indicate that increased AQP4 PM levels in perivascular astrocytic end-feet are likely critical to the development of brain edema in ALF.