Good News for Brain Energy Use

Prologue
Brain work has enjoyed wide-spread scientific interest since Roy and Sherrington (1890) observed that sensory nerve stimulation expanded cerebral cortex as a result of an increase in blood flow. Increased brain function seemed to produce metabolites that caused the dilation of cerebral blood vessels presumably to fulfill the increased demand for nutrients. These findings sparked intense research to identify the cellular metabolic pathways involved and to uncover the mechanisms that couple blood flow to brain function.

Indeed, brain cells need plenty calories. The brain accounts for an estimated 20 percent of our body's energy consumption. The aerobic metabolism of glucose, also known as aerobic glycolysis, has been shown to constitute the most prominent source for the brain's energy needs.

Aerobic glycolysis entails the oxidation of glucose into water and carbon dioxide to produce energy-rich phosphorous compounds, mainly adenosine triphosphate (ATP). The compounds are used to fuel active transmembrane transport mechanisms of ions and molecules that are needed for nerve cell communication and information processing. However, only insufficient amounts of glucose and no oxygen can be stored in the brain. Both have to be delivered to the brain tissue on demand.

In the late 1960s, Lou Sokoloff and his colleagues at the National Institute of Mental Health succeeded in developing a procedure with which the local cerebral metabolic rates of glucose could be determined in vivo. They named it the autoradiographic deoxyglucose method (Sokoloff and others, 1977). Autoradiography involves the administration of a radioactively labeled tracer, the distribution of which in the tissue can be visualized postmortem by apposing X-ray films to tissue sections. The grain density in the autoradiograms on the developed films corresponds to the tracer concentration in the sections. The grain density can be measured with an optical densitometer and calibrated to represent  tracer concentration in the tissue.

Glucose is rapidly metabolized and the metabolites are quickly removed from the brain. Therefore, Sokoloff and colleagues could not use radioactively labeled glucose as tracer for their measurements. They used deoxyglucose instead. Deoxyglucose is a competitive analogue of glucose. It is phosphorylated to deoxyglucose-6-phosphate by the enzyme hexokinase in the first step of glycolysis, but is not metabolized further, and accumulates in the brain tissue. The tracer accumulation is proportionate to the rate of glucose metabolism.

Using this method, numerous studies have shown that glucose metabolism in the central nervous system is associated with electrical nerve cell spiking activity (e.g. Kadekaro and others, 1985). That is, nerve cell stimulation evokes electrical millivolt spikes in the nerve cell's axon by rapid fluxes of sodium ions into the cell and potassium ions out of the cell through ion-specific membrane channels. The spikes are known as action potentials. The axon is the long process that connects the nerve cells. Trains of action potentials traveling along axons essentially constitute packets of data transmitted to other nerve cells. 

In order to prepare the cell for the next spike, the ion concentrations must be restored to their pre-action potential level, known as resting potential. The sodium ions must be pumped out of the cells with an energy-consuming pump. In accord, Mata and others, (1980) observed that glucose metabolism diminishes significantly, when the sodium pump is blocked and the production of action potentials ceases, supporting the idea that cerebral energy consumption is related to the spiking activity of nerve cells.

Sokoloff encountered criticism. One critic was the Dutch biochemist Cees Van den Berg, who claimed that the deoxyglucose method did not measure glucose metabolism accurately. He had measured concentrations of pyruvate, a glycolytic key intermediate, and his results suggested a much greater glucose consumption (Van den Berg and Bruntink, 1983). I met him after he had applied for a grant to fund experiments designed to support his claim.  He was invited to present a lecture on what he thought needed to be done. Many years later, I asked Lou Sokoloff about Van den Berg's ideas. Lou swiftly and resolutely retorted, "Nonsense!" In as much as the size of a lake does not tell us how fast water is running through it, the concentration of a metabolite is no indication of its metabolic rate.

However, one of Van den Berg's claims still resonates in my mind. He noted that the rate of glucose metabolism measured with the deoxyglucose method would increase no more than two-fold from baseline in normal physiological circumstances. I have carried out hundreds of experiments with this method in rodents. On this point, Van den Berg was correct. Physiological whisker stimulation increases glucose metabolic rates in primary somatic sensory cortex less than two-fold. Indeed, the average is about 1.3-fold.

Nerve cell activity-related increases in glucose metabolism should have been greater, if they had been  tightly correlated with the energy demands of axonal sodium pump activity estimated at the time. In their pioneering work, the Noble Prize-laureates Hodgkin and Huxley were the first to describe the ion currents that produced action potentials in squid giant axons (Hodgkin and Huxley, 1952a). In a subsequent paper, the authors suggested a model quantifying these currents (Hodgkin and Huxley,1952b). According to the model, sodium influx was anticipated to rise 4-fold or greater. Consequentially, stimulus-evoked nerve cell spiking activity should have resulted in much greater increases in glucose use to pump out the ions than found with the deoxyglucose method.

The New Find
Yesterday, Science Magazine published a study the results of which may resolve this apparent inconsistency (Alle and others, 2009). The authors used intracellular patch clamp recordings in mice to quantify the action potential-related transmembrane sodium and potassium ion fluxes in mossy fibers of a phylogenetically old part of the cerebral cortex known as hippocampus. They are unmyelinated. That is, like axons of short-distance nerve cell connections in neocortex, mossy fibers lack a fatty sheeth for electrical insulation and, therefore, propagate action potentials similarly as the axons of local intracortical circuits. The authors observed sodium and potassium ion fluxes that were less overlapping and smaller than those found in squid giant axons. They suggest that these differences reduce the action potential-related increase in energy demand to 1.3-fold. This increase is in good agreement with the observed stimulus-related increases in glucose utilization rates discussed above.

In addition, supra-cellular mechanism play a crucial role in the reduction of cortical energy needs. Cortical nerve cells are able to control their gain. That is, the rate of action potentials can be reduced in response to an increase in the strength of stimulation without losing information (Melzer and others, 2006). Van den Berg erred in his critique of deoxyglucose method, because the energy demand of cerebral function is lower than he presumed.

On the other hand, it must be noted that sodium pump activity does not solely account for stimulus-related increases in cerebral glucose metabolism. Nerve cells release glutamate at their synapses, that is the contacts between nerve cells, to excite other nerve cells. Glutamate is the most prevalent neurotransmitter in the cerebral cortex. Astrocytes near the synapses are known to remove the released glutamate with active, that is energy-consuming, transport (Pellerin and Magistretti, 1994; Takahashi and others, 1995). Hence, astrocytic glutamate uptake may contribute considerably to the cerebral rates of glucose metabolism. This contribution remains to be quantified.

References

• Alle H, Roth A, Geiger JRP (2009) Energy-efficient potentials in hippocampal mossy fibers. Science 325:1405-1408.
• Hodgkin AL, Huxley AF (1952a) Propagation of electrical signals along giant nerve fibers. Proc R Soc Lond B Biol Sci 140:177-183.
• Hodgkin AL, Huxley AF (1952b) A quantitative description of membrane current and its application to conduction and excitation in nerve. J Physiol (Ldn) 117:500-544.
• Kadekaro M, Crane AM, Sokoloff L (1985) Differential effects of electrical stimulation of sciatic nerve on metabolic activity in spinal cord and dorsal root ganglion in the rat. Proc Natl Acad Sci U S A 82:6010-6013.
• Mata M, Fink DJ, Gainer H, Smith CB, Davidsen L, Savaki H, Schwartz WJ, Sokoloff L (1980) Activity-dependent energy metabolism in rat posterior pituitary primarily reflects sodium pump activity. J Neurochem 34:213-215.
• Melzer P, Sachdev RN, Jenkinson N, Ebner FF (2006) Stimulus frequency processing in awake rat barrel cortex. J Neurosci 26:12198-2205.
• Pellerin L, Magistretti PJ (1994) Glutamate uptake into astrocytes stimulates aerobic glycolysis: a mechanism coupling neuronal activity to glucose utilization. Proc Natl Acad Sci U S A 91:10625-10629.
• Roy CS, Sherrington CS (1890) On the regulation of the blood-supply of the brain. J Physiol (Ldn) 11:85-108.
• Sokoloff L, Reivich M, Kennedy C, Des Rosiers MH, Patlak CS, Pettigrew KD, Sakurada O, Shinohara M (1977) The [14C]deoxyglucose method for the measurement of local cerebral glucose utilization: theory, procedure, and normal values in the conscious and anesthetized albino rat. J Neurochem 28:897-916.
• Takahashi S, Driscoll BF, Law MJ, Sokoloff L (1995) Role of sodium and potassium ions in regulation of glucose metabolism in cultured astroglia. Proc Natl Acad Sci U S A 92:4616-4620.
• Van den Berg CJ, Bruntink R (1983) Glucose oxidation in the brain during seizures: experiments with labeled glucose and deoxyglucose. In Glutamine, Glutamate and GABA in the Central Nervous System (Hertz L, Kvamme E, McCeer EG, Schousboe A, eds), New York, Alan R. Liss:pp 619−624.

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Constantin von Economo's Spindle Cells & The Mind

Today we celebrate the birthday of Constantin von Economo. He was born in 1876. A comprehensive biography of his life entitled "Baron Constantin von Economo His Life and Work"can still be found as a used book. He was known as an avid aviator and a superb physician scientist. Elaborating on Korbinian Brodmann's ground-breaking maps of cerebral cortex, he meticulously charted his own divisions based on the composition of nerve cells seen in histological preparations. In this process, he identified a rare and special type of nerve cell that has intrigued neuroscientists to this day.

The cerebral cortex constitutes our brain's most prominent feature. It consists of a large convoluted sheet of nervous tissue separated at the mid-line into two hemispheres. Its gray matter can be divided into layers of nerve cells of varying shape and density with characteristic in- and output. Pyramidal cells are the predominant type of nerve cell providing output to nerve cells in other layers of the same area, other cortical areas as well as to nerve cells in subcortical structures and to the motor neurons in the spinal cord that innervate the musculature. The roughly triangular cell bodies of the majority of pyramidal cells are located in the deep layers of cortex near the white matter, that Ramon y Cajal defined as layers 5 and 6.

Pyramidal cells feature a distinct distribution of dendrites, that is the processes on which inputs from other nerve cells terminate. The apical dendrite points straight up. It traverses all cortical layers and ramifies in layer 1 under the cortical surface. In addition, a set of dendrites, known as basal dendrites, spreads out radially from the cell body, collecting input from the layer in which the cell body resides. The axon, that is the process conveying the nerve cell's output, emerges from the underside of the cell body. The axons of pyramidal cells are wrapped in sheaths of a fatty substance, known as myelin, for insulation and form the cortical white matter.

Clustered among the ubiquitous pyramidal cells, nerve cells of peculiar, strikingly different shape caught Constantin von Economo's eye. They were unique to only a select few areas in anterior cingulate and insular cortex. The cells possessed conspicuous large cell bodies. Like pyramidal cells, they featured a prominent straight dendrite spanning the cortical thickness and an axon projecting to distant brain structures,  but lacked basal dendrites, resulting in a distinctly bipolar appearance. Von Economo named them "Spindelzellen" or spindle cells in English.

In the past, spindle cells had only been found in humans and other great apes (Nimchinsky and others, 1999). The exclusivity has been taken to suggest that this type of nerve cell may be associated with the complex higher cognitive and affective mental functions that seem to distinguish us from the rest of animaldom, e.g. language, decision making and empathy. Spindle cells are known to be particularly prone to degenerate in people with Alzheimer's disease (Nimchinsky and others, 2004). Recently however, the cells have also been discovered in cetaceans (Marino and others, 2007) and pachyderms (Hakeem and others, 2009).

Little is known about the function of spindle cells. The distribution of their dendrites suggests that they collect input from other nerve cells along narrow radial columns across the cortical thickness, supporting the idea that the cerebral cortex is a functionally organized in discrete modules rather than in broad layers. Their long-distance projections suggest a role in a distributed neural network, processing information across sensory modalities. However, more research clearly needs to be carried out to examine their responsiveness to stimulation and the influences they exert on other nerve cells before any specific role can be assigned with certainty to Constantin von Economo's Spindelzellen.

The Elusive Sense of Magnetism

Pigeons were my constant companions in the early years of academic study. They descended on the university buildings in flocks, settling on the railings of the balconies that ran along the stories outside. They cooed and bantered outside, watching us study hard inside. At times, their habits were annoying. But I always liked to watch them take off in bunches, swaying from one side to the other and then lifting off up and away. The burghers of our city commonly considered pigeons a pest. Pest control was often called in to get rid of them.

However, this did not happen in our case. Our birds were homing pigeons. Wolfgang Wilschko, the most enthusiastic zoology professor I ever met, his wife and students were studying the birds' ability to use Earth's magnetic field for flight orientation. Other migratory birds have demonstrated this capability. However, how the magnetic sense actually works was little understood. The team transported marked birds to various locations in about a sixty mile radius in a battered, mouse-gray VW microbus on loan from the Deutsche Forschungsgemeinschaft, the German equivalent of the National Science Foundation. They recorded the time the pigeons needed to find back to their loft. Their travel time was compared to the geography they had to navigate, in particular whether magnetic field perturbations produced by intersecting power lines distracted them on their path, delaying their return.

Exposing the pigeons to artificial magnetic fields in the laboratory left them temporarily disoriented. Regardless, the birds commonly found their way back home. For this, they appeared to rely on the inclination, rather than the polarity, of geomagnetic field vectors. That is, the birds could discriminate between equatorial and polar directions of the magnetic field vectors for compass orientation and proved profoundly sensitive to disturbances in the field. Fine-grain local field aberrations may provide additional cues for the birds' navigation (Wilschko and Wilschko, 2005). Sensitivity to the geomagnetic field has been observed in a number of vertebrate animals other than birds (Lohmann and Johnsen, 2000). Begall and others (2008) showed that domestic cattle as well as free roaming deer align their bodies according to the magnetic poles.

Despite the formidable evidence for a magnetic sense, conclusive evidence for magnetoreceptor cells remains elusive to date. An early hypothesis posited that migrating birds could virtually see magnetic field polarity, detecting in the clear sky streaks of light of differing intensity polarized by the geomagnetic field.

Another hypothesis suggested that nerve cells containing minute deposits of biogenic magnetic minerals may detect magnetism. For example, the iron oxides magnetite (Fe₃O₄) and maghemite (Fe₂O₃) have been identified in trigeminal nerve fibers innervating the skin on pigeons' bills (Fleissner and others, 2007). In accord, preliminary evidence shows that trigeminal nerve fibers respond to changes in magnetic field strength of geomagnetic magnitude (Semm and Beason, 1990).

In a separate line of investigation, external magnetic fields of strengths comparable to those found in nature proved in principle capable of temporarily altering the concentration of short-lived pairs of radicals intermediate to photo-chemical reactions (Maeda and others, 2006). The interconversion of the pairs' spin states eventually determines the type of reaction product, the yield of which is proportionate to magnetic field strength and direction. Cryptochromes, that is blue light-sensitive flavoproteins, spatially-oriented in the photoreceptor cells of the avian retina are suggested as likely candidates to sustain such reaction (Rodgers and Hore, 2009). The magneto-sensitive process may modulate the birds' perception of light not unlike that originally proposed for magnetic field-related polarized light.

Taken together, much evidence suggests that migratory animals possess a keen sense for magnetic fields, using a "built-in" biological magnetic compass to orient themselves in their environments. Two fundamentally different molecular mechanisms are presently suggested to underlie this ability. One involves magnetic matter embedded in nerve cell fibers of the peripheral sense of touch. The other involves the formation of radical pairs in photoreceptors of the visual system. With either proposal, the precise mechanisms of stimulus reception, stimulus transduction and sensory pathway processing need yet to be uncovered.

Footnote

• The text of the post is available for download in pdf-format from the scribd store.

Addenda

• Perhaps this incident was caused by sudden strong local disturbances of the earth's magnetic field that the blackbirds use for navigation (01/05/11):

• Putman and others (2011) provide behavioral evidence that also loggerhead turtle hatchlings use the Earth's magnetic field to determine latitude as much as longitude for navigation on their migrations. Listen to Joe Palca's segment with the title "For Turtles, Earth's Magnetism Is A Built-In GPS" broadcast today on National Public Radio's Morning Edition (03/02/11).
• In a blow to the hypothesis that magnetic sensory receptor cells invest the avian beak, Treiber and others (2012) provide histological evidence that the previously implicated magnetite containing cells are iron-rich macrophages. Moreover, Wu and Dickman (2012) showed that nerve cell electrical spiking in the pigeon's vestibular brainstem known for processing information on balance and spatial orientation (equilibrioception) encodes magnetic field direction, intensity, and polarity, suggesting that magnetic receptor cells are located in the inner ear (05/31/2012).

References

• Begall S, Cerveny J, Neef J, Vojtech O, Burda H (2008) Magnetic alignment in grazing and resting cattle and deer. Proc Natl Acad Sci USA 105:13451-13455.
• Fleissner G, Stahl B, Thalau P, Falkenberg G, Fleissner G (2007) A novel concept of Fe-mineral-based magnetoreception: histological and physicochemical data from the upper beak of homing pigeons. Naturwissenschaften 94:631-642.
• Lohmann KJ, Johnsen S (2000) The neurobiology of magnetoreception in vertebrate animals. Trends Neurosci 23:153-159.
• Maeda K, Henbest KB, Cintolesi F, Kuprov I, Rodgers CT, Liddell PA, Gust D, Timmel CR, Hore PJ (2008) Chemical compass model of avian magnetoreception. Nature 453:387-390.
• Putman NF, Endres CS, Lohmann CMF, Kenneth J. Lohmann KJ (2011) Longitude Perception and Bicoordinate Magnetic Maps in Sea Turtles. Current Biol: CB doi:10.1016/j.cub.2011.01.057.
• Rodgers CT, Hore PJ (2009) Chemical magnetoreception in birds: the radical pair mechanism. Proc Natl Acad Sci USA 106:353-360.
• Semm P, Beason RC (1990) Responses to small magnetic variations by the trigeminal system of the bobolink. Brain Res Bull 25:735-740.
• Treiber CD, Salzer MC, Riegler J, Edelman N, Sugar C, Breuss M, Pichler P, Cadiou H, Saunders M, Lythgoe M, Shaw J, Keays DA (2012) Clusters of iron-rich cells in the upper beak of pigeons are macrophages not magnetosensitive neurons. Nature 484:367-370.
• Wiltschko W, Wiltschko R (2005) Magnetic orientation and magnetoreception in birds and other animals. J Comp Physiol A Neuroethol Sens Neural Behav Physiol 191:675-693.
• Wu L-Q, Dickman DJ (2012) Neural correlates of a magnetic sense. Science 336:1054-1057.

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