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Recent research suggests that schizophrenia is associated with the development of an advanced aging phenotype (carbonyl stress) and erythrocytes from schizophrenics also exhibit symptoms of cellular aging (increased levels of glycated proteins and ubiquitinated proteins), possibly due to excessive glycolysis-induced methylglyoxal (MG) generation. The endogenous dipeptide carnosine (beta-alanyl-L-histidine), which can delay cellular aging, suppress glycolysis and inhibit MG-induced protein glycation, also exerts some beneficial effects towards schizophrenia. Carnosine is present in human erythrocytes and the olfactory bulb (olfactory dysfunction is associated with schizophrenia).
It is suggested that enhanced erythrocyte and olfactory carnosine levels may be more therapeutic towards schizophrenia, if carnosine was also administered intra-nasally to avoid serum carnosinase activity. Many studies have indicated a relationship between schizophrenia and dysfunctional energy metabolism [1,2,3 ] whilst others indicate that carbonyl stress and generation of advanced glycation end-products (AGEs) accompany schizophrenia [4,5]. Furthermore a recent study suggests that changes in glycolysis and accelerated cellular aging in glial cells contribute to the condition [6]. The glycolytic intermediates glyceraldehyde-3-phosphate and dihydroxyacetone-phosphate are the most likely sources of AGE formation due to their ability to spontaneously decompose into methylglyoxal (MG).
MG is well recognised as a major glycating agent and is thought to be responsible for much macromolecular modifications associated with type-2 diabetes and age-related neurodegenerative conditions [7,8 ]. However, there is no clear evidence whether suppression of MG generation, via decreased glycolytic activity, has any effect on schizophrenia. The suggestion that schizophrenia seems to be associated with accelerated cellular aging [6] is supported by another recent observation reporting that erythrocytes obtained from schizophrenics contain elevated mounts of ubiquitinated proteins [9]. This might arise from either increased generation of targets for ubiquitination (e.g. aberrant polypeptides or denatured misfolded proteins), or decreased de-ubiquitinating activity, or decreased proteasomal proteolytic activity which would normally complete polypeptide destruction. Interestingly, MG and other agents responsible for carbonyl stress, also induce protein cross-linking which not only renders the target protein less susceptible to proteolytic attack but can also result in inhibition of proteasome activity generally [10]. Thus it is conceivable that excessive glycolysis can provoke an aging phenotype (AGE accumulation and proteostatic dysfunction) via increased MG generation; such a relationship has been demonstrated in mice fed a high glycaemic- index diet [11].
Never-the-less it is necessary to show whether glycation compromises proteostasis in erythrocytes from schizophrenics. A number of recent papers have revealed that erythrocytes obtained from patients with neurological problems, such as Alzheimers disease (AD) and Parkinsons disease (PD), exhibit symptoms typical of aging cells in general. For example, compromised proteolytic activity and MG detoxification were detected in AD erythrocytes [12] and accumulation of aggregated protein occurs in red cells from PD patients [13]. Furthermore, dysfunctional energy metabolism, especially in relation to glycolysis culminating in carbonyl stress, are now regarded as characteristics of both AD and PD [14,15]. Therefore it is not surprising that evidence of carbonyl stress is also accompanied by enhanced protein glycation [16] and accumulation of ubiquitinated proteins [9] in erythrocytes (and possibly other cells) obtained from schizophrenic individuals [17]. Moreover, one of the glycated proteins from schizophrenic red cells has been identified as a selenium-binding protein (SBP1) [18]; dysfunctional selenium metabolism has long been regarded as an important contributor to schizophrenia [19,20]. Selenium plays an important role in sulphur metabolism required for synthesis of anti-oxidant enzymes such as glutathione peroxidase [21]. Thus, one is beginning understand the relationship between AGE generation, carbonyl and oxidative stress and the apparently disparate biochemical attributes to schizophrenia. That erythrocytes can contain elevated amounts of MG and glycated proteins suggests the possibility that such red cells could become systemic sources of MG and AGEs to the brain and other tissues, following MG-induced eryptosis [22]. Consequently it is important to consider whether suppression of carbonyl stress, not only in erythrocytes but in astrocytes and glia, could possibly be a therapeutic strategy.
The naturally-occurring dipeptide carnosine (beta-alanyl-L-histidine) has been shown to suppress glycolysis in cultured cells [23,24], delay replicative senescence [25], stimulate proteolysis of long-lived proteins in late passage cells [26] and inhibit AGE formation [27]. Furthermore, there is one study showing that schizophrenics subjected to dietary supplementation with carnosine exhibited some beneficial effects [28], possibly due to the dipeptides pluripotent properties [29]. It is also interesting to note that (i) olfactory dysfunction is also associated with schizophrenia [30,31] and (ii) carnosine is enriched in the olfactory bulb [32]. Thus one has to consider whether raising olfactory carnosine levels could also be useful. However all studies employing dietary carnosine supplementation are subject to the problem of the presence of serum carnosinase activity which would destroy the dipeptide [33]. There is an alternative route however, which is to use an intra-nasal approach. This could involve a nasal spray of a carnosine solution; another approach could involve use of carnosine powder. Indeed snorting carnosine could be far more useful than most white powders some people use, be it illegal drugs or medicinal snuff of old. In fact, intra-nasal delivery of potential therapeutic agents is currently being explored [34] with respect to neurodegenerative conditions, as proposed many years ago [35]. Carnosine has been detected in human erythrocytes [36] but in lower amounts when obtained from elderly individuals [36]. It is presumed that red cell carnosine is synthesized (from beta-alanine and histidine) during erythropoiesis.
Consequently it would be useful to determine whether dietary supplementation with carnosine or beta-alanine raises erythrocyte carnosine levels and whether there are any beneficial effects with respect to the recognised changes in schizophrenic erythrocytes. Additionally, it is suggested that any carnosine (dietary or nasally administered) supplementation period should last for at least 120 days to ensure maximal numbers of carnosine-enriched erythrocytes. It has been proposed that excessive and continuous glycolysis in erythrocytes enhances red cell MG levels, and thus also facilitate delivery of erythrocyte MG to the tissues including the brain [22]. Consequently it will be also important to determine whether such supplementation protocols decrease carbonyl stress and MG levels not only in red cells but the tissues generally including glia [6].
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