New cellular and molecular approaches to ageing brain.

The last decade has witnessed a mammoth progress in the area of brain ageing. Recent gene profiling and brain imaging techniques have made it possible to explore the dark areas of ageing neurons in a new molecular perspective. Many conserved pathways and cellular and molecular mechanisms particularly nuclear mitochondrial molecular interactions are known now. Disruptions in mitochondrial function and reduction in cellular antioxidative and immunoproteins contribute to generation of reactive oxygen species (ROS) which leads to deteriorated adult neurogenesis, reduced white matter and compromised neural plasticity. The overall deteriorated structure and function of neurons is manifested in form of cognitive decline and prolonged neurodegenerative disorders. Dietary restrictions (DR), physical and mental activities however have been shown to counter these ailments. However more precise molecular dynamics at protein levels is still debatable which is the future task for neuroscientists.

Introduction

Brain ageing is characterized by many physical, chemical or biological changes in the status of neurons which is often manifested as deterioration in the Cognitive function and demetia.[1] This phenominan is one of the most striking because it is the major risk factor for most common neurodegenerative diseases including alzheimer’s disease (AD), parkinson’s disease (PD), amylotrophic lateral sclerosis (ALS) and stroke. Recent studies indicate that normal brain aging is associated with subtle morphological and functional alterations in specific neuronal circuits rather then large scale loss of neurons.[2] The loss of neurons, however in normal brain aging is compensated by expanding dendritic arbors and synaptic contacts whilst in age related neurodegenerative disorders, dendritic arbors and synaptic connections are lost and compensation doest not occur.[3]

In fact, aging of the brain in diverse mammalian species shares many common features such as dendritic regression in pyramidal neurons, synaptic atrophy, decrease of striatal dopamine receptors, accumulation of fluorescent pigments, cyto skeletal abnormalities and reactive astrocytes and microglia.[4]

Although age associated defects in particular neuronal circuits have been described, the molecular basis of aging brain still remains debatable. Fortunately the last 15 years have witnessed a significant increase in our knowledge of the basic molecular mechanisms of aging. Most remarkably, functional genetic analysis has identified signaling pathways that act as master regulators of ageing and life span that are conserved in yeast, nematodes, flies and mammals.[1]

However, two important technical advances have provided new insight in to the biology of brain aging. Micro-array technology has made global gene expression analysis possible in human and model organism leading to the identification of evolutionary conserved changes during ageing. Functional brain imaging technology has enabled us to study the cognitive networks in the ageing human brain. The present review seeks to present a discussion on Neuro-anatomical and molecular alterations integrated with ageing process, mitochondrial dysfunction and autophagy related to ageing, alteration in gene expression during normal and degenerative ageing and its interaction with reactive oxygen species. The impact of dietary restriction as a preventive measure has also been discussed.

Neuro anatomical and Cellular Changes during Normal and Degenerative Brain Ageing

Brain aging is characterized by a plethora of anatomical changes which are the consequence of molecular and cellular alterations. Early studies suggested that substantial neuronal loss occurs in the ageing neocortex and hippocampus which are the most vulnerable regions of ageing. However, recent studies showed that neuronal loss was not significant in most regions of the ageing neocortex and hippocampus.[5] In contrast dendritic branching could increase in some hippocampal regions in aged individuals[6] while ageing prefrontal cortex (PFT) showed variable changes in dendritic branching patterns.[5] Many investigations have reported increased dendritic extent in dentate gyrus (a subregion of hippocampus) of old compared with middle aged humans.[7] In other subregions of human hippocampus including areas CA1[8] (Carnuammonis) and CA3[9] and the subiculum,[10] there is no change in dendritic branching with age. The morphology of PFC neurons seems to be more vulnerable to the effects of ageing than that of hippocampal neurons. In rat, dendritic branching of pyramidal neurons decreases with age in superficial Cortical layers.[11] A reduction in dendritic branching with age has also been observed in anterior cingulate layer V of rat[12] and the human medial PFC[13]. The data available, however, on spine density also suggested its region specific alterations[5]. The hippocampal region in aged human showed no significant reduction in spine density.[15,16] In addition to these changes reduction in synapse number is also markable in aged brains. An early electron microscopic study at the perforant path granule cell synapse showed 27% decrease in axodendritic synapse number in the middle molecular layer of dentate gyrus in aged rates as compared with that of young rats.[17,18] These neuro anatomical changes, however, result in impaired neuro plasticity and ultimately alter the network dynamics of neural ensembles that support cognition. At the cellular level, however, an extensive loss of myelinated nerve fibres from the white matter of the human cerebral hemispheres during normal ageing has been reported[19] with the greatest reduction in the PFC and corpus callosum.[20,21] In addition, alterations in their myelin sheaths with age are also reported.[22] Electron microscopic study has shown that integrity of myelin sheath is disrupted with age. Overall break down of myelin sheaths would cause disruption of conduction along nerve fibres and a reduction in the connectivity between parts of the brain,[22] consequently causing reduced speed of information.

Chemical and Neurophysiological Changes

Brain ageing is not merely accompanied by morphological and anatomical deterioration but a large number of neurochemical and neurophysiological alterations are also witnessed in an integrated form. Reductions are found in neurochemical systems most notably in dopaminergic, noradrenergic, and cholinergic pathways[23-26] thus resulting in increased cognitive impairments and dementia. In the human and rhesus macaque pre frontal cortex (PFC) the secretion of inhibitory neurotransmitter gama – amino butyric acid (GABA) is diminished in aging brain due to reduced gene expression thus altering the balance between inhibitory and excitatory neurotransmission.[27] This may contribute to increased neural activity in PFC which could predispose individuals to excitotoxicity and neurodegenerative pathology. Positron Emission Tomography (PET) in humans have shown significant decrease in dopamine synthesis,[28] notably in the striatum and extrastreatal regions excluding mid brain.[29] Significant age related decrease in dopamine receptors D1, D2 and D3 are also noticed, particularly receptors binding in to caudate nucleus and putamen.[30,31]

PET studies in humans have also shown decrease in the level of serotonin receptor S2 in the caudate nucleus, putamen and frontal cortex in aging brains[34] as well as a decreased binding capacity of the serotonin transportor, 5HHT, in the thalamus and the mid brain.[35] In addition glutamate also shows decreased level in aging brains particularly in parietal gray matter, basal ganglia and frontal white matter.[36,37] However, electrical properties of the neurons remain constant over the life span in all the subrigions of the hippocampus.[38]

In contrast numerous studies have shown an increase in Ca++ conductance in aged neurons. CA1 pyramidal cells in the aged hippocampus have an increased density of L – type Ca++ channels.[39] In addition to changes in Ca++ channels, impaired intraneuronal calcium buffering capacity may increase cytoplasmic free Ca++ levels.[19]

A major neuronal calcium buffering protein, calbindin 1 has been reported to be reduced in basal forebrain cholinergic and cortical neurons in aging human and non-human primates.[40] More over these decrements could be attributed to reduced in RNA expressions of calbindin and Ca++ channel genes, in PFC[41]. It is proposed therefore that impaired Ca++ homeostasis could lead to altered synaptic plasticity.

Alterations in gene expression in ageing brain

There are ample evidence suggesting that cognitive impairments and neurodegenerative disorders may be associated with specific changes in gene expression. Gene expression profiling studies of ageing mouse, rat, monkey and human have shown significant alteration in the expression of synaptic genes.[42-45] More than 150 genes have been noted to undergo age-dependent expression changes in these organisms which may be up regulated or down regulated.[1]

Most of the micro-array studies have shown reduced expression of genes involved in mitochondrial energy metabolism which may become more pronounced in humans with cognitive decline and AD.[46-48] Another significant set of genes which shows increased expression during aging is that involved in stress response pathways.[1] Gene expression studies of the ageing neocortex in mice, monkey and humans has shown age-dependent up regulation of the apolipoprotein D gene.[49] The expression of this gene in Drosophila extends life span playing role as a lipid antioxidant conferring resistance to oxidative stress.[49-51] Moreover apolipoprotein D expression is induced in the brains of individuals with AD. In over all picture however genes responsible for glial activity, myelin proteins, metal ion homeostasis, immune response and stress response in humans show upregulated gene expression while genes pertaining to mitochondrial function, neural plasticity, ubiquitin – proteaosome pathways show down regulated expression in human ageing brains.[7]

In addition, genes involved in synaptic functions that mediate memory and learning including glutamate receptor sub unites, synaptic vesicle proteins and members of major signal transduction systems that mediate long term potentiation showed down regulated expression.[19]

Moreover, genes involved in stess response including antioxidant defense, DNA repair and immune function constitute largest category of age upregulated genes.[19] Among the gene expression profiling studies of the ageing brain to neurodegenerative disorders such as AD, up regulated expression of signaling and tumor suppressor genes and down regulated expression of protein folding, metabolism and energy related gene has been reported.[46]

Mitochondrial dysfunction

Many gene expression profiling studies have clearly shown a progressive degeneration in mitochondrial function which could contribute to the accelerated ageing particularly in brain, since brain and muscle are more susceptible to mitochondrial dysfunction. Mitochondrial oxidative phophorylation is the key source of energy intensive ion fluxes and axonal transport in the projection neurons of cerebral cortex which degenerate in alzheimer’s desease.[19] These neurons, therefore, are highly vulnerable to mitochondrial dysfunction. Respiratory chain enzymes and mitochondrial DNA are the prime targets of mitochondrial damage[52] (Fig. 1).

Fig. 1:

Molecular pathways showing Role of ROS, DR and IIS in neural ageing: Dysfunctional mitochondria and ubiquitinated protein aggregates, promote ageing (⊣ indicate inhibition;→ shows activation).

Generation of Reactive Oxygen Species (ROS)

Due to irregularities in the electron transport chain in mitochondria during progressive aging many super oxides are generated as a byproduct which may cause damage to respiratory chain proteins and mitochondrial DNA. In normal course mitochondria passes sufficient machinery to counter these ROS in form of antioxidant enzymes including Cu-Zn super oxide dismutase, cytochrome oxidase and redox reactions mediated by cytochrome C.[19] In case of aging, the action of these antioxidants is diminished, resulting in local oxidative damage to mitochondrial proteins and DNA. Super Oxide Dismutase (SOD) reacts with superoxide radicles and converts them in to hydrogen peroxide (H2O2) which is a stable molecule and may diffuse into cytoplasm where it is enzymatically neutralized by cytoplasmic glutathione peroxidase and peroxisomal catalase. However besides super oxides and H2O2, redox mediated iron is a major sourse of ROS mediated cellular damage.[19] Elevated levels of redox – active iron accumulates in normal ageing brain and in several neurodegenerative diseases.[50]

Gene profiling studies, however, have shown the age related reduced expression of mitochondrial genes in organisms ranging from nematode to humans.[5,6,19,54,55] Conversely augmented mitochondrial function has been shown to extend life span.[56] Targeted over expression of the antioxidant enzyme catalase specifically in rat mitochondria extends the life span.[57] Although the actual mechanism that extends the life span in organisms is still debatable, one hypothesis is that efficient electron transport chain (ETC) function reduces the generation and release of ROS. In addition, many nuclear transcripts that declined in the aging brains are required for mitochondria function.[54] These included NADP transhydrogenase, ubiquinol – cytochrome C reductase complex, subumite VIII of cytochrome Coxidase and gama and delta subunites of F1 particle.[19] All these components are the integral members of ETC. This profile suggests that mitochondria function may be compromised in ageing brains.

Neurodegeneration and accelerated brain ageing.

Of late many interesting microarray studies have shown contradictory findings to above mentioned facts regarding role of mitochondrial dysfunction in ageing.[1]

CKL – I is required for synthesis of ubiquinone, a key component of ETC. CLK – I mutants have reduced respiratory chain but have long life spans.[58] Subsequent studies based on RNA interference screens found that reduction of function in many genes affecting ETC can increase life span.[59,60] This effect appears to be dose dependent because a modeost reduction in ETC activity can increase life span whereas a more severe reduction shorten it.[56] Recent evidence suggests that this life span extension may be mediated by nuclear transcriptional response to mitochondrial defects termed as retrograde response involving the induction of oxidative stress resistance and xenobiotic detoxification genes.[61] Moreover in Drosophila and a mouse model with a reduced expression of ETC components in neurons life span is extended.[62,63] Intriguingly this mouse model also shows protection against neuronal excitotoxicity.[19] The signaling mechanisms, however, mediating increased longevity in this context are not well known. It is probable that ROS in a modestly increased concentration may act as signaling molecule to promote longevity. This observation further raises the possibility that the initial decline in mitochondrial gene expression during brain aging may be a part of an active compensatory mechanism that increases stress resistance.

Autophagy and protein homeostasis as a regulatory mechanisms in aging brains

Recent studies in worms, flies and mouse have established autophagy of mitochondria as a key component to extend life span[64-66] and reduced autophagy may contribute to neuro degeneration.[66,67] Reduced autophagy, however in neuro degenerating brains in flies and mice is accompanied by aggregation of ubiquitinated proteins, similar to those observed in human neurodegenerative disorder such as Huntington’s disease (HD) and AD.[1] The clearance of a mutant protein huntingtin in HD is directly under the regulation of expressed BECN I.[68] In addition to BECN I a number of other genes related to autophagy have been reported to be declined in brain ageing (T Lu and BA Yankner, unpublished results). Thus, accumulation of dysfunctional protein in reduced autophagy may contribute to severe ROS generation and the release of redox active iron leading to neuronal impairements.

Two significant pathways accelerating neural aging

Target of rapamycin (TOR) pathway normally inhibits autophagy, contributing in impaired protein homeostasis. Reduced TOR signaling has been reported to extend life span in yeast, worms, flies, mice.[69,70] Though the extent to which TOR signaling affects life span is unknown but together with autophagy this has significant role in age dependent neurodegenerative diseases caused by protein aggregates. Another significant signaling mechanism contributing to brain aging is insulin/IGF – I signaling (IIS) pathway. Reduced IIS pathway has been shown to extend life span in worms, flies and mammal.[71] In contrast, in mammals, insulin and IGF – I are neurotrophic and promote neuronal survival by inhibiting apoptosis.[72] These can also promote learning and memory in humans and animal models.[71,72] There exists a dichotomy therefore, between neuro-protective effects of insulin and IGF – I and their adverse effects on life span. Interestingly the effects on life span parallel the effects on neurodegeneration. Knockout mouse of Irs2 or IGF – I receptor can reduce cognitive impairment and neurodegeneration in models of AD.[73,74] In patients with AD, reduced expression of IGF signaling is reported.[75] The role of IIS pathway is therefore debatable about its response as an effective neuro-protector as well as indicator of neuro-degenerative process.

Delaying the Effects of Neural Ageing

After having a thorough review over cellular and molecular components and pathways of brain ageing, it is worthwhile to discuss the preventive measures of cognitive impairments and neuro degenerative processes. Brain supportive healthy diets including omega 3 fatty acid, vitamin C, vitamin E (an effective anti-oxidant) vitamin B12, vitamin B6, folic acid iron, calcium, zink, docosa hexaenoic acid (DHA) and breast milk proteins have been primarily reported to delay the effects of normal brain aging and cognitive decline.

Recent investigation on the impact of dietary restriction (DR) as brain aging and neuro degenerative disorders have shown many striking features. Dietary restriction (reduction in diet without causing malnutrition) has been reported to play multi-dimentional roles at cellular and molecular levels. DR has been reported to reduce age related gene expression alterations upto substantial level associated with stress and immune responses respectively.[54] These effects of DR on immune stress related transcripts indicates that both autoimmunity and oxidative damages are reduced in the brains of DR mice.[76] In addition to its suppressive role on many gene transcripts, DR is shown to induce many gene expressions.

One of the largest classes of transcripts induced by DR (9%) comprised growth and neurotrophic factors including the develop mentally regulated homeobox genes which might be involved in neural development and gene encoding neuroserpin, a factor that promotes neural plasticity.[3] Other transcripts that are induced by DR include transforming growth factor (TF) and brain derived neurotrophic factor (BDNF) which can protect neurons against excitotoxic and metabolic insults.[77] Other genes to be induced under DR influence are that related to DNA synthesis. This observation might be related to increased neurogenesis in rodents under DR.[78] These gene profiling studies are supportive of the fact that modulation of energy metabolenin, oxidative stress, ion homeostasis by DR could affect brain ageing in the mouse[3] (Fig. 3). More recent studies have shown that enhancement of BDNF and other neurotrophic factors due to DR, exerts beneficial effects on synaptic plasticity and might therefore facilitate learning and memory.[79] The capacity of the brain for neurogenesis might decrease in ageing[80] and DR has been shown to increase the number of newly generated neural cells in dentate gyrus of the rat hippocampus.[78] HSP – 70 and GRP – 78 proteins which protect neurons against excitotoxic and oxidative insults[81,82] have been noted to be increased in cortical, strial and hippocampal neurons of DR rats.[83,84]

Fig. 3:

Anti ageing components and their role in prevention of brain ageing.

In addition to its protective role in normal brain ageing, DR is reported to exert protective role against neurodegenerative disorder AD[85] and PD.[86]

However in addition to multifaceted contribution of DR in protection of normal brain ageing and neurodegenerative disorder, regular physical exercise has been shown to increase neurogenesis and neurotrophic factors.[87] Over the past decade a number of epidemiological studies have shown a decreased risk for PD and dementia of subjects who exercise regularly.[88-90]

Conclusion

Gene expression profiling and brain imaging techniques have given a new insight to the cellular, molecular and behavioral alterations in aging brains. After having an overview over the recent developments on neural ageing, in the present review neural ageing has been discussed as the consequence of decreased neurogenesis and synaptic plasticity, altered neuro chemical and signaling pathways, reduced white matter, mitochondrial dysfunction, enhanced stress responses and accumulation of ROS and dysfunctional proteins, reduced antioxidative, DNA repair enzymes and decreased immune responses etc. At the molecular level, however, it is due to alterations in the expression of a wide array of genes involved in these processes.

Moreover, neocortex, hippocampus and striatal centres are the most vulnerable areas, affected in aging with a variable degree of changes in their subcentres. Therapeutic and preventive measures have also been briefly discussed, with particular reference to DR since recent studies are focused on it. Hence, management of these canditions through medical and life style interventions is likely to benefit in order to cope with these age related impairments. Moreover, the function of nervous system depends upon highly specific intricate intercellular signaling networks whose regulatory mechanisms extend beyond gene transcription. It is, therefore essential to understand such mechanisms at the level of protein interactions within individual cells, organelles and synapses.[3] It is, therefore, imperative prospect to explore this molecular dynamics through combined proteomic and brain imaging techniques in a more comprehensive manner.