Global and regional brain metabolic scaling and its functional consequences

Background: Information processing in the brain requires large amounts of metabolic energy, the spatial distribution of which is highly heterogeneous reflecting complex activity patterns in the mammalian brain. Results: Here, it is found based on empirical data that, despite this heterogeneity, the volume-specific cerebral glucose metabolic rate of many different brain structures scales with brain volume with almost the same exponent around -0.15. The exception is white matter, the metabolism of which seems to scale with a standard specific exponent -1/4. The scaling exponents for the total oxygen and glucose consumptions in the brain in relation to its volume are identical and equal to $0.86\pm 0.03$, which is significantly larger than the exponents 3/4 and 2/3 suggested for whole body basal metabolism on body mass. Conclusions: These findings show explicitly that in mammals (i) volume-specific scaling exponents of the cerebral energy expenditure in different brain parts are approximately constant (except brain stem structures), and (ii) the total cerebral metabolic exponent against brain volume is greater than the much-cited Kleiber's 3/4 exponent. The neurophysiological factors that might account for the regional uniformity of the exponents and for the excessive scaling of the total brain metabolism are discussed, along with the relationship between brain metabolic scaling and computation.Comment: Brain metabolism scales with its mass well above 3/4 exponen

Identification of proteins involved in neural progenitor cell targeting of gliomas

<p>Abstract</p> <p>Background</p> <p>Glioblastoma are highly aggressive tumors with an average survival time of 12 months with currently available treatment. We have previously shown that specific embryonic neural progenitor cells (NPC) have the potential to target glioma growth in the CNS of rats. The neural progenitor cell treatment can cure approximately 40% of the animals with malignant gliomas with no trace of a tumor burden 6 months after finishing the experiment. Furthermore, the NPCs have been shown to respond to signals from the tumor environment resulting in specific migration towards the tumor. Based on these results we wanted to investigate what factors could influence the growth and progression of gliomas in our rodent model.</p> <p>Methods</p> <p>Using microarrays we screened for candidate genes involved in the functional mechanism of tumor inhibition by comparing glioma cell lines to neural progenitor cells with or without anti-tumor activity. The expression of candidate genes was confirmed at RNA level by quantitative RT-PCR and at the protein level by Western blots and immunocytochemistry. Moreover, we have developed <it>in vitro </it>assays to mimic the antitumor effect seen <it>in vivo</it>.</p> <p>Results</p> <p>We identified several targets involved in glioma growth and migration, specifically CXCL1, CD81, TPT1, Gas6 and AXL proteins. We further showed that follistatin secretion from the NPC has the potential to decrease tumor proliferation. <it>In vitro </it>co-cultures of NPC and tumor cells resulted in the inhibition of tumor growth. The addition of antibodies against proteins selected by gene and protein expression analysis either increased or decreased the proliferation rate of the glioma cell lines <it>in vitro</it>.</p> <p>Conclusion</p> <p>These results suggest that these identified factors might be useful starting points for performing future experiments directed towards a potential therapy against malignant gliomas.</p

Rodent models of focal cerebral ischemia: procedural pitfalls and translational problems

Rodent models of focal cerebral ischemia are essential tools in experimental stroke research. They have added tremendously to our understanding of injury mechanisms in stroke and have helped to identify potential therapeutic targets. A plethora of substances, however, in particular an overwhelming number of putative neuroprotective agents, have been shown to be effective in preclinical stroke research, but have failed in clinical trials. A lot of factors may have contributed to this failure of translation from bench to bedside. Often, deficits in the quality of experimental stroke research seem to be involved. In this article, we review the commonest rodent models of focal cerebral ischemia - middle cerebral artery occlusion, photothrombosis, and embolic stroke models - with their respective advantages and problems, and we address the issue of quality in preclinical stroke modeling as well as potential reasons for translational failure

Molecular mechanisms of acidosis-mediated damage

The present article is concerned with mechanisms which are responsible for the exaggerated brain damage observed in hyperglycemic animals subjected to transient global or forebrain ischemia. Since hyperglycemia enchances the production of lactate plus H+ during ischemia, it seems likely that aggravation of damage is due to exaggerated intra- and extracellular acidosis. This contention is supported by results showing a detrimental effect of extreme hypercapnia in normoglycemic rats subjected to transient ischemia or to hypoglycemic coma. Enhanced acidosis may exaggerate ischemic damage by one of three mechanisms: (i) accelerating free radical production via H(+)-dependent reactions, some of which are catalyzed by iron released from protein bindings by a lowering of pH, (ii) by perturbing the intracellular signal transduction pathway, leading to changes in gene expression or protein synthesis, or (iii) by activating endonucleases which cause DNA fragmentation. While activation of endonucleases must affect the nucleus, the targets of free radical attack are not known. Microvessels are considered likely targets of such attack in sustained ischemia and in trauma; however, enhanced acidosis is not known to aggravate microvascular dysfunction, or to induce inflammatory responses at the endothelial-blood interface. A more likely target is the mitochondrion. Thus, if the ischemia is of long duration (30 min) hyperglycemia triggers rapidly developing mitochondrial failure. It is speculated that this is because free radicals damage components of the respiratory chain, leading to a secondary deterioration of oxidative phosphorylation

Unequivocal identification of intracellular aluminium adjuvant in a monocytic THP-1 cell line.

Aluminium-based adjuvants (ABA) are the predominant adjuvants used in human vaccinations. While a consensus is yet to be reached on the aetiology of the biological activities of ABA several studies have identified shape, crystallinity and size as critical factors affecting their adjuvanticity. In spite of recent advances, the fate of ABA following their administration remains unclear. Few if any studies have demonstrated the unequivocal presence of intracellular ABA. Herein we demonstrate for the first time the unequivocal identification of ABA within a monocytic T helper 1 (THP-1) cell line, using lumogallion as a fluorescent molecular probe for aluminium. Use of these new methods revealed that particulate ABA was only found in the cell cytoplasm. Transmission electron microscopy revealed that ABA were contained within vesicle-like structures of approximately 0.5-1 μm in diameter

Increased proportion of CD8+ tumor responsive T cells after immunization with tum- versus tum+ rat glioma

Previously established immunogenic (tum-) clones of an ENU (ethyl-N-nitrosourea)-induced rat glioma, N32, were compared to the original tumor concerning their capacity to induce T lymphocyte responses after in vivo immunization and in vitro restimulation of responder spleen cells in mixed lymphocyte tumor culture (MLTC) assays. Quite unexpectedly, original N32 (tum+) in vivo primed spleen cells proliferated to the same extent in vitro in response to tum+ stimulator cells as did tum- in vivo primed spleen cells. However, flow-cytometric analysis of parallel cultures showed a greatly increased proportion of CD3+CD8+ lymphocytes in the proliferating responder cell population from tum- immunized hosts, contrary to a CD3+CD4+ lymphocyte dominance after tum+ immunization. Although the original tum+ N32 tumor cells are not capable of inducing a clearly demonstrable isograft rejection response, they induce a strong T cell response readily detectable in MLTC assays. We propose that the increased CD8+ lymphocyte proliferation could be an essential feature of the isograft rejection response induced by tum- tumor variants. Possible mechanisms of the augmented CD8+ T cell response are discussed

Regression of intracerebral rat glioma isografts by therapeutic subcutaneous immunization with interferon-gamma, interleukin-7, or B7-1-transfected tumor cells

Progress in the definition of the roles of various costimulators and cytokines in determining the type and height of immune responses has made it important to explore genetically altered tumor cells expressing such molecules for therapeutic immunizations. We have studied the effect of therapeutic subcutaneous (s.c.) immunizations on the growth of preexisting intracerebral brain tumor isografts in the rat. Transfectant glioma cell clones expressing either rat interferon-gamma (IFN-gamma), rat interleukin-7 (IL-7), or rat B7-1 were selected. After irradiation (80 Gy) the clones were used for immunization (administered in up to four s.c. doses in a hind leg over 14-day intervals starting 1 day after the intracranial isografting of the parental tumor). Significant growth inhibition of the intracerebral parental tumors was induced by transfectants expressing IFN-gamma and IL-7, respectively. The strongest effect was observed with IFN-gamma-expressing cells, resulting in cures in 37% of the males and in 100% of the females. Immunization with IL-7 had a similar, strong initial effect, with significantly prolonged survival in the majority of the rats but a lower final cure rate (survival for >150 days). The B7-1-expressing tumor clones induced cures in seven of eight female rats; however, no cures were seen in the male rats. It was also shown that the B7-1-expressing cells were themselves strongly immunogenic in female rats, requiring high cell numbers to result in a progressively growing tumor upon s.c. isografting; this was not the case in male rats. As a whole, the results imply that despite the unfavorable location of intracerebral tumors, therapeutic s.c. immunizations with certain types of genetically altered tumor cells can induce complete regressions with permanent survival and without gross neurological or other apparent signs of brain damage. The present results demonstrate complete regressions when immunizations are initiated shortly after intracranial isografting, when the intracerebral tumor is small