Difference between revisions of "Team:Leicester/Description"

 
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         <li class="active"><a href="https://2015.igem.org/Team:Leicester/Description">Project</a></li>
         <li><a href="#Int">Introduction</a></li>
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<li> <a href="#ProAb">Project Abstract</a></li>
         <li><a href="#Col">Colonisation</a></li>
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         <li><a href="#ProEx">Project Explanation</a></li>
         <li><a href="#NAD">NAD Transport</a></li>
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         <li><a href="#YNAD">Why NAD?</a></li>
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         <li><a href="#Practical">Practical Components</a></li>
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         <li><a href="#conc">Conclusion</a></li>
 
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       <h2 id="Int"> Introduction </h2>
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       <h2 id="ProAb"> Project Abstract</h2>
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<p>Neurodegenerative disorders show decreased levels of NAD+/NAD(H). Using E. coli  to colonise the gut, NAD+/NAD(H) levels could be increased by upregulating nadD, nadE and PncB enzymes in the E. coli cytosol; these gene products will be tagged and exported into the periplasm via the tat system to produce NAD+/NAD(H), which will be exported into the gut. The genes and killswitch will be inserted into E. coli, whilst the remaining aspects of the project will be theoretical due to ethical and safety restrictions. Speculatively, increased NAD+/NAD(H) could treat neurodegenerative disorders by mitigating the destruction of neurons and help with muscle fatigue. Regeneration of muscle fibres to restore strength and overall energy levels would be achieved by increased oxidative phosphorylation triggered by NAD+/NAD(H). This treatment provides low-cost NAD+/NAD(H) as part of an autonomous system; increasing the patients’ quality of life.</p>
  
<p>Due to the allotted lab time for the iGEM project, and various other constraints this project would not go to completion. Knowing this in advance required important decisions to be made in the early phases of the project's design, meaning sections that would be theoretical and those that were feasible for a lab based approach had to be defined. At this point decisions were made that determined the overall direction of the project, with the most important factor being what was possible within the timescale all the while ensuring the parts that were created were those which were most associated with the fundamental aim of the project. This page describes the theoretical sections of the project, taking into consideration why they would be required, ethical implications for their use  as well as the steps and process that would have taken place to create them were the time available for a complete product. The reason as to why these particular components could not advance onto lab work stage will also be described.</P>
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      <h2 id="ProEx"> Project Explanation</h2>
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<p>For our project we wanted to look at a universal issue, something that affects every person indiscriminately. This lead us to aging as one such issue. Because the aging process is a highly dynamic and complex process intrinsic to our physiology, we knew that it was practically impossible to treat the condition, so we started looking at the symptoms. As we age our muscle strength declines, we become susceptible to a host of neurodegenerative diseases, and our overall physiological health declines. One common denominator to these conditions appears to be mitochondrial dysfunction (Gomes et al., 2013). We are hoping to address a few of the proximate aging symptoms, such as senescence of muscle tissue and neurones within the brain. One of the attributes of senescence is the gradual breakdown of the circadian clock of human physiology (Zamporlini et al., 2014).</p>
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<p>Through research we identified the coenzyme nicotinamide adenine dinucleotide (NAD<sup>+</sup>) – widely accepted as a mediator of redox reactions – as a suitable candidate for our purposes. Literature has identified the interplay of NAD<sup>+</sup> and SIRT1 working in concert to modulate metabolism and circadian rhythm (Zamporlini et al., 2014) which are closely linked to the mitochondria (Gomes et al., 2013). A hallmark of aging is the loss on NAD<sup>+</sup> with age (Gomes et al., 2013; Zamporlini et al., 2014), as well as mitochondrial dysfunction; It has been shown that these two phenomenon are correlated, but a causal link is still tenuous.</p>
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<p>Our project, simply put, is a self-sustaining integrated pharmacy for patients – a pseudo-organ in effect. Our ultimate goal for our project results would be to integrate an as yet undetermined strain Escherichia coli into the human gut microbiome. The purpose of the non-native bacteria is to produce a specified chemical compound – in this case NAD<sup>+</sup> – into the gut. We speculate that due to the large surface area and blood flow of the microvilli, as well as the low molecular weight of NAD<sup>+</sup> (Zamporlini et al., 2014), and proven uptake by mammalian cells (Billington et al., 2008), the NAD<sup>+</sup> will enter the blood stream and be transported rapidly and uniformly across the entire body. We predict that this will over time, re-establish the circadian rhythms of metabolic processes, restore oxidative metabolism –  especially in muscles –  and possibly have a neuroprotective effect against neurodegenerative disorders such as Parkinson’s and Alzheimer’s.</p>
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<p>For our project, we aim to develop several BioBricks with the purpose of increasing net extracellular NAD<sup>+</sup>/NAD(H) levels of the host organism – in this case it would be E.coli – the purpose being to allow transfer of NAD<sup>+</sup> into the gut microbiome for absorption into the bloodstream of patients.</p>
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<p>We believe this approach will enable a long term, and with further development, full integration of a bacterial pseudo-organ into people that suffer from deleterious conditions such as weaker muscle strength with age, as well as the neurodegenerative diseases that more common with aging. The end goal of this integration would be to ameliorate the symptoms of aging, possibly increasing longevity as a side-effect. This would have a tremendous impact as it could potentially restore the quality of life and self-sufficiency to the elderly and neurodegenerative sufferers relying on carers.</p>
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<h2 id="Col"> Colonisation </h2>
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<h2 id="YNAD"> Why NAD? </h2>
<p>Maximising NAD uptake by mammalian cells is an essential aim of the project and also a requirement for the efficacy of the final product. It was therefore essential that the GM E. coli were capable of colonising the intestine, the reason being so they could be maintained in the environment for a longer period of time and therefore have a longer lasting effect, ideally permanently. However colonisation also minimises NAD waste by reducing diffusion into the intestinal lumen by reducing the physical distance between the GM E. coli and intestinal cells, another point to consider is that by doing this it may also prevent the gut microbiome from utilising this additional NAD pool. To determine the most effective site of colonisation different regions of the intestine that could provide optimum NAD uptake via colonisation were investigated, the regions consisted of the mucosal layer and the epithelial layer. </p>
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<h3><b>Introduction</b></h3>
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<p>NAD<sup>+</sup> was first discovered by Arthur Harden and William Young 1906, during research on fermentative enzymes and was part of the 1929 Nobel Prize attributed to Harden and Hans von Euler-Chelpin (White and Schenk, 2012). It has long been known that NAD<sup>+</sup> is a coenzyme used in multiple redox reactions and, consisting of two covalently bound mononucleotides – nicotinamide mononucleotide (NMN) and AMP (Zamporlini et al., 2014). It exists in its oxidised form NAD<sup>+</sup>, and the reduced form, NADH which provide oxidoreductive power, perhaps most notably utilised within the mitochondria to produce ATP (White and Schenk, 2012), with some of the ATP in turn being used to activate the NAMPT protein for further production of NAD<sup>+</sup> (Hara et al., 2011). NAD<sup>+</sup> can be synthesised either synthesised de novo from tryptophan (Zhou et al., 2015) or from salvage pathways using nicotinic acid or nicotinamide, with a third pathway – using nicotinamide riboside precursors – having recently been discovered (Billington et al., 2008).</p>
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<p>The mitochondrial matrix is not the only cellular compartment containing an NAD<sup>+</sup> pool, with the others being the cytosol and the nucleus as shown in figure 1 (White and Schenk, 2012). Whilst the nuclear membrane is porous to NAD<sup>+</sup> to allow diffusion, mitochondrial membranes are not (White and Schenk, 2012). To transport NAD<sup>+</sup> across mitochondrial membranes, biochemical shuttles are required; the four shuttles that have been found and are as follows: glycerol 3-phosphate, malate-aspartate, lactate and NADH/cytochrome c electron transport (White and Schenk, 2012). These shuttles, as well as the conversion of pyruvate to lactate replenish NAD<sup>+</sup> levels via oxidation of the reduced form – NADH (White and Schenk, 2012). In addition to these mechanisms NADH is also oxidised into NAD<sup>+</sup> within mitochondrial matrices by the electron transport chain during respiration (White and Schenk, 2012).</p>
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<p>In recent years NAD<sup>+</sup> has been accepted to be a signalling molecule, constituting integral parts of large and dynamic regulatory pathways and integrated networks (White and Schenk, 2012), including sirtuins.</p>
  
<p>Once the investigation began it became apparent that the mucosal layer was unsuitable for our purposes, as it is associated with the same issues that the investigation intends to avoid. Therefore the epithelial layer </p>
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<h3><b>NAD</b></h3>
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<img src="https://static.igem.org/mediawiki/2015/4/4b/NAD_movement.jpg" alt="NAD movement" align="right">
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<p> Our projects ultimate goal, to increase NAD<sup>+</sup> levels within human cells, could have been achieved a variety of ways. Before the main body of research is presented we will briefly discuss the reasoning as to why each method was discarded and how we arrived at our final decision.</p>
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<p>One possible way would be to directly manipulate people’s genomes, but it comes with an array of risks such as lack of uniformity of genome modification – not every cell may be altered. Unintended complications may arise, such as immune response, organ failure and ultimately, death. These ethical considerations also lead on to the idea of eugenics if gene therapy became commonplace. This approach is also beyond our team’s current capabilities and conflict with iGEM regulations. Aside from the obvious ethical implications of human genetic modifications, studies have shown that in vivo upregulation of relevant genes pertaining to the NAD<sup>+</sup> synthesis pathways, did not significantly affect the NAD<sup>+</sup>/NADH redox ratio (Frederick et al., 2015). Interestingly though, germ line knock-down of genes coding for NAD<sup>+</sup> consuming enzymes has shown to perturb the NAD<sup>+</sup>/NADH redox ratio of cells, in favour of NAD<sup>+</sup> (Frederick et al., 2015). This gene treatment was insufficient and was therefore inadequate to stimulate oxidative metabolism within skeletal muscle cells (Frederick et al., 2015), which is one of our project goals.</p>
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<p>We briefly considered trying to transport the rate limiting enzyme in de novo NAD synthesis, NAMPT (Koltai et al., 2010; Hara et al., 2011; Liang et al., 2013; Canto, Menzies and Auwerx, 2015), into the viscera with the target being the cytosol of cells. We discarded this as we realised that the final product produced by the enzyme was smaller and more stable than the enzyme. Enzymes are large, require specificity when being transported – requiring human modifications to existing transport mechanisms – and can require numerous other criteria for efficacy, specific temperature, pH, and post-translational modifications.</p>
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<p>There are non-synthetic biology alternatives, for example NAMPT can be chemically activated by P7C3 (Zhao et al., 2015), but more research is needed to confirm its safety.</p>
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<p>Many of the papers looked at indicated that a rise in intracellular NAD<sup>+</sup> was achieved through supplementation of NAD<sup>+</sup> intermediates such as NMN, NR or Acipimox (see figure 2) (Zamporlini et al., 2014; van der Weijer et al., 2015; Felici et al., 2015). Whilst we could have targeted genes to upregulate NMN synthesis (see figure 2) such as Namnt within the E. coli, we decided to synthesise the end-product. We did this because with age the components maintaining the circadian rhythms decline, reducing the amount of NAMPT (Zamporlini et al., 2014). Whilst upregulating this may seem the simplest way to achieve our goal we were worried that the activity of NAMPT may be reduced due to lower ATP levels, which is required for NAMPT activation (Hara et al., 2011), due to the mitochondrial dysfunction. Later we will discuss the direct effect of NAD<sup>+</sup> on cell biochemistry.</p>
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<p>We were interested in the diversity of applications NAD<sup>+</sup>, conferred likely due to its role in integrated networks (White and Schenk, 2012) and as such were looking into its neurological effects on humans.</p>
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<p>Sirtuins are a family of proteins that act as deacylases and depend on NAD<sup>+</sup> to be biologically active (Koltai et al., 2010; Zamporlini et al., 2014). Mammals such as humans have seven sirtuins (SIRT1-7), with early work being carried out on the yeast Sir2 homologue (Ying, 2007; Koltai et al., 2010). Evidence confirms that SIRT1 promotes mitochondrial function, shown by the lack of upregulation of OXPHOS genes in both the nucleus and mitochondria when SIRT1 iKO mammals were subjected to fasting and calorie restriction (CR), leading to deacreased mitochondrial functionality (Gomes et al., 2013). Fasting and CR activate SIRT1, as does DNA damage from ionising radiation sources such as UV radiation sunlight (Zamporlini et al., 2014). It was speculated by Gomes and his team that the induced activity of increased mitochondrial oxidative metabolism – and increased transcription of mitochondrial OXPHOS genes due to these conditions – was via SIRT1 deacetylating PGC-1α (Gomes et al., 2013). However this was disproved as SIRT1 continued to function in KO PGC-1α/β mice (Gomes et al., 2013), suggesting an as of yet undiscovered mechanism.</p>
  
<p>The potential genes we selected were cofA, fibronectin and BFP. </p>
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<img src="https://static.igem.org/mediawiki/2015/6/6e/Fig3_NAD.jpg" align="right" width="250px" height="250px"><p>We decided to use the NAD<sup>+</sup> molecule for our project as we have seen evidence that it has neuroprotective effect in humans, as when NAD<sup>+</sup> starvation occurs a misfolded amyloidogenic protein stimulates the activation of autophagic mechanisms and neurodegeneration (Zhou et al., 2015). Mitochondrial dysfunction is present in a multitude of neurodegenerative diseases including Parkinson’s (Zhou et al., 2015) and Alzheimer’s (Long et al., 2015; Zhou et al., 2015); with NAD<sup>+</sup> loss being a contributory factor. Administration of the precursor NMN was shown to restore the respiratory capacity of ailing mitochondria, as well as reducing mitochondrial fission and reducing fragmentation – which might explain the reduction of mitochondrial bioenergetics defects – after this they identified that NAD<sup>+</sup> may be a limiting factor when the oxygen consumption rate (OCR) deficiencies normalised upon administration (Long et al., 2015). This neuroprotective action can be mainly attributed to SIRT1 which deacetylases PGC-1α, which when activated, stimulates mitochondrial biogenesis (Long et al., 2015).</p>
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<p>Recent research has indicated that these neurodegenerative diseases are prion based, with affected neurones having decreased ATP productions as well as reduced NAD<sup>+</sup> levels (Zhou et al., 2015). This can be a destructive cycle as ATP is required by the rate limiting enzyme NAMPT for de novo synthesis of NAD<sup>+</sup> which in turn is required for metabolic production of ATP, leading to a gradual decline of both.</p>
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<p>The NAMPT-NAD<sup>+</sup> axis has been shown to have both neuroprotective and neuroregenerative effect via the combined actions of SIRT1, SIRT2 and SIRT6 (Ido et al., 2001). These proneurogenesis effects have been corroborated by the reduced activity of SIRT1, SIRT2 and SIRT6 when these deacetylases were knocked down (Zhao et al., 2015).</p>
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<p>There are many causes of neuronal cell death, one of which is ischemia. This is the restriction of blood flow from to areas of the body by narrowing of arteries or spasm; when this occurs this can cause a stroke, called an ischemic stroke. NAD<sup>+</sup> has been shown to protect against ischemic cell death, as ischemic injury depletes the supply of neurological NAD<sup>+</sup> (Zhao et al., 2015). This indicates that continued neuronal viability is dependent on the activities of NAD+, possibly due to the activity of NAD<sup>+</sup> consuming enzymes such as the aforementioned sirtuins. However neuronal death can be caused by an array of diseases as well – Parkinson’s, Alzheimer’s and multiple sclerosis.</P>
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<P>We did hope that the excess in NAD<sup>+</sup> consumption by Sirtuins and other NAD<sup>+</sup> consuming enzymes would result in a far larger pool of NMN, an NAD<sup>+</sup> intermediate that has been consistently shown to increase NAD<sup>+</sup> levels (Gomes et al., 2013; Frederick et al., 2015; Zhao et al., 2015). However even with sensitive instruments and assays, NMN has not been found within blood plasma of mice (Hara et al., 2011). Interestingly, however, NAD+ has been shown to be present in the blood stream at nanomolar concentrations, possibly due to the use of NAD(P) by ectoenzymes (Billington et al., 2008). We were unable to determine through literary research as to whether NAD<sup>+</sup> is able to traverse the blood brain barrier (BBB), but it has been shown that NMN can cross the BBB to modulate intracellular NAD levels (Zhao et al., 2015). NMN is safe for long-term use for clinical applications as it is a native endogenous substrate (Wang et al., 2015). This leads us to speculate that either NMN is contained within cells by membranes and is therefore not subject to high enough diffusion gradients between cell interiors and exteriors or that the majority of NMN is used in NAD<sup>+</sup> synthetic pathways. This could also indicate that cells are completely impermeable to NMN, however this is unlikely due to the droves of evidence that NMN supplements can increase the NAD<sup>+</sup> pool, meaning that NMN can traverse membranes even if it is only unidirectional, which if the case will require further development of our GMO to address. <img src="https://static.igem.org/mediawiki/2015/8/81/Leicester_fig4_NAD_cycle.jpg" align="right">Assays need to be carried out to detect whether increased NAD<sup>+</sup> can perturb and therefore increase the NMN pool. By effectively reducing the activity of NAD<sup>+</sup> synthesis and salvage pathways’ activities and thereby reducing NMN consumption, we hope that NMN may enter the bloodstream to create an extracellular NMN pool. Concurrently we believe that NMN levels may be actively produced from exogenous NAD<sup>+</sup> by the proteins coded for by the NadD and NudC genes (Zhou et al., 2011) as shown in figure 4.
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NMN has been shown to have a positive effect on the insulin levels secreted in culture and in vivo, due to the stimulation of SIRT1 in pancreatic β cells (Zhao et al., 2015).</p>
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<p>Studies have revealed that inhibition of other NAD<sup>+</sup> consuming enzymes such as PARP (1 & 2) enzymes can convey long-term neuroprotection (Ying, 2007). As a future consideration for the development of the neurological aspect of our project, this inhibition of PARPs could potentially yield a more layered and therefore more refined approach.</p>
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<img src="https://static.igem.org/mediawiki/2015/3/3e/Leicester_fig5.jpg" align="right" width="350px" height="350px"><p>Our project relies on the capacity of mammalian cells to uptake NAD<sup>+</sup> for use in various biochemical reactions. Experiments have proven that NAD<sup>+</sup> is taken up in two stages, initially there is a rapid transport followed by a period of uptake lasting an hour or so (Billington et al., 2008), with transport rate shown in figure 5.</p>
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<p>NAMPT has been shown to significantly increase the number of mitochondria within cells, and NAD<sup>+</sup> increases myocyte mitochondria biogenesis (Kim, Yoon and Park, 2014). This indicates that NAMPT increases the NMN levels, which in turn, increase the NAD<sup>+</sup> levels to increase mitochondria concentration. As previously mentioned NMN increases insulin levels – evidence shows that SIRT1 has been linked to increased insulin sensitivity (Kim, Yoon and Park, 2014). These increased insulin levels coupled with increased biogenesis may have a positive effect on bodily energy levels, reducing age-related fatigue. The site of action of this biogenesis may be due to the modulation of hypoxia inducing factor-1 alpha (HIF-1α), which is known to increase with age to combat the decline of appropriate redox conditions – especially within skeletal muscle (Koltai et al., 2010; Gomes et al., 2013). Once again returning to sirtuins, SIRT1 increases the transcriptional activity of HIF-1α – which seems counter intuitive to its other areas of effect – but SIRT3 destabilises the HIF-1α protein structure, with SIRT6 acting as a corepressor (Gomes et al., 2013). These data imply that the benefits of increasing the activity of sirtuins thus far outweighs the cost.</p>
  
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<p>Nuclear activity of SIRT1 and the level of acylation of proteins show an inverse correlation (Koltai et al., 2010) indicating that with increasing age target proteins are subjected to a lesser degree of acylation, possibly contributing to the detrimental proximate effects of aging. Exercise has been shown to increase the activity of NAMPT, the rate limiting enzyme in NAD<sup>+</sup> synthesis, which thereby increases the NAD<sup>+</sup> pool, increasing the SIRT1 deacetylase which is dependent upon NAD<sup>+</sup> to function (Koltai et al., 2010). SIRT6, in conjunction with SIRT1 regulate DNA repair mechanisms (Liang et al., 2013) as previously mentioned, indicating that stimulation may enable partial protection from DNA damage and increase replicative lifespan of cells as shown in figure 6.</p>
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<img src="https://static.igem.org/mediawiki/2015/7/7f/Leicester_fig6.jpg" align="right" width="300px" height="300px">
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<p>As NAD<sup>+</sup> is required by E. coli for glucose oxidation (Liang et al., 2013), we predict that an increase in NAD<sup>+</sup> synthesis will confer a selective advantage over other gut fauna, promoting better growth rates as overexpression of the pncB genes has been shown to confer a significant increase in the mass of the cell (Liang et al., 2013). Experiments were done on a strain of E. coli (BA002) that could not anaerobically use glucose as an energy source due to the lack of NAD<sup>+</sup> regeneration; the decreased NAD(H)/NAD<sup>+</sup> ratio due to increase in the NAD(H) pool, improved glucose uptake and growth of cell – substantiated by the increase of dry mass of cells – also conferring succinic acid production (Liang et al., 2013). However the excess NAD<sup>+</sup> may also increase the prevalence of other gut fauna and a full analysis of bacterial interaction will need to be completed before any clinical considerations as NAD<sup>+</sup> may confer different behaviour to pathogenic organisms.</p>
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<p>However the lab space we were working in was category one and the utilisation of the selected colonisation factor operon, the Bundle Forming Pilus (BFP) required a category two lab. There were various colonisation factors which had potential however, BFP was ideal for gut colonisation as it had the least ethical implications, but also would enable optimum NAD uptake.</p>
 
  
  
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<h2 id="NAD">NAD Transport</h2>
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<h2 id="Practical">Practical Components</h2>
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<h5><i><b>pncB</b></i></h5>
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<p>We identified one gene called pncB which encodes nicotinic acid phosphoribosyltransferase (NAPRTase) (Liang et al., 2013), as seen in figure (from Zhou et al., 2011) is responsible for the conversion of NA into NAMN. We selected this gene as experiments have shown that cooverexpression with another gene, nadE, increased the NAD(H) by 7-fold. This was of particular use to us as the shuttling mechanisms, among others, as mentioned previously are able to oxidise the NAD(H) into NAD<sup>+</sup> (White and Schenk, 2012). From this we can deduce that whilst the NAD(H)/NAD<sup>+</sup> axis is perturbed in favour of NAD(H) the net concentration of NAD<sup>+</sup> increases in vivo over time due to the oxidative actions of the shuttles and other mechanisms (Liang et al., 2013).</p>
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<h5><i><b>nadD and nadE</b></i></h5>
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<p>The second and third gene sequences we were interested in were nadD, which encodes the NAMN adenylyltransferase and nadE which codes for NAD Synthetase in the NAD(H) biosynthetic pathway responsible for the interconversion of NAD<sup>+</sup> and NMN (Zhou et al., 2011, Zamporlini et al., 2014). This is of particular use to us as we wish, as a secondary objective, to increase NMN levels for reasons discussed previously. We believe this will be feasible due to the increase in NAD<sup>+</sup> in cells, potentially reducing a limiting factor of NMN production (see figure 4 NadD).</p>
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<p>Experiments have shown that individually upregulating pncB, nadE and nadD increases the NAD(H) pool (Liang et al., 2013). Despite this extremely promising theoretical increase for single genes we decided to maximise the output by using all three. We did this as we were concerned that very high concentrations of NAD<sup>+</sup> may be required to enter cells in useful concentrations, as some may be lost to other gut fauna, the gut environment itself, or not be concentrated enough in the blood to enter cells. Further experiments would be required to ascertain the efficiency of uptake whereupon we would regulate the NAD<sup>+</sup> output.</p>
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<h2 id=conc> Conclusion</h2>
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<p>To conclude, we believe that our pseudo-organ can provide a long-term treatment to slow and potentially reverse some of the symptoms of aging both in skeletal muscle in terms of strength and energy levels and neurologically in terms of neurone viability and functioning.</p>
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<p>We are aware that some members of the public may be hesitant to a therapeutic GMO, but our project has the added advantage of having the integrated BioBricks within the pSB1C3 high copy number vector to be compatible with bioreactor technology. Possibly providing a cheaper manufacturing of supplements. This may serve as a temporary measure until public opinion is assured of the clinical safety of therapeutic GMOs.</p>
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<p>Due to the effects on human physiology we believe our GMO will provide a better standard of living by increasing certain aspects of health and increasing self-sufficiency of neurodegenerative sufferers and the elderly. This may even have a knock on effect on reducing the economic assets invested in care systems allowing reinvestment into other health sectors.</p>
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<a href="https://2015.igem.org/Team:Leicester/Description">Back to the top</a>
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<h2> Reference</h2>
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<li>BILLINGTON, R.A., TRAVELLI, C., ERCOLANO, E., GALLI, U., ROMAN, C.B., GROLLA, A.A., CANONICO, P.L., CONDORELLI, F. and GENAZZANI, A.A., 2008. Characterization of NAD uptake in mammalian cells. Journal of Biological Chemistry, 283(10), pp. 6367-6374.</li>
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<li>CANTO, C., MENZIES, K.J. and AUWERX, J., 2015. NAD(+) Metabolism and the Control of Energy Homeostasis: A Balancing Act between Mitochondria and the Nucleus. Cell Metabolism, 22(1), pp. 31-53.</li>
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<li>FELICI, R., LAPUCCI, A., CAVONE, L., PRATESI, S., BERLINGUER-PALMINI, R. and CHIARUGI, A., 2015. Pharmacological NAD-Boosting Strategies Improve Mitochondrial Homeostasis in Human Complex I-Mutant Fibroblasts. Molecular pharmacology, 87(6), pp. 965-971. </li>
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<li>FREDERICK, D.W., DAVIS, J.G., DAVILA, A.,JR., AGARWAL, B., MICHAN, S., PUCHOWICZ, M.A., NAKAMARU-OGISO, E. and BAUR, J.A., 2015. Increasing NAD Synthesis in Muscle via Nicotinamide Phosphoribosyltransferase Is Not Sufficient to Promote Oxidative Metabolism. Journal of Biological Chemistry, 290(3), pp. 1546-1558. </li>
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<li>GOMES, A.P., PRICE, N.L., LING, A.J.Y., MOSLEHI, J.J., MONTGOMERY, M.K., RAJMAN, L., WHITE, J.P., TEODOR, J.S., WRANN, C.D., HUBBARD, B.P., MERCKEN, E.M., PALMEIRA, C.M., DE CABO, R., ROLO, A.P., TURNER, N., BELL, E.L. and SINCLAIR, D.A., 2013. Declining NAD(+) Induces a Pseudohypoxic State Disrupting Nuclear-Mitochondrial Communication during Aging. Cell, 155(7), pp. 1624-1638. </li>
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<li>HARA, N., YAMADA, K., SHIBATA, T., OSAGO, H. and TSUCHIYA, M., 2011. Nicotinamide Phosphoribosyltransferase/Visfatin Does Not Catalyze Nicotinamide Mononucleotide Formation in Blood Plasma. Plos One, 6(8), pp. e22781.</li>
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<li>IDO, Y., CHANG, K., WOOLSEY, T.A. and WILLIAMSON, J.R., 2001. NADH: sensor of blood flow need in brain, muscle, and other tissues. Faseb Journal, 15(6), pp. 1419-+. </li>
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<li>IMAI, S. and GUARENTE, L., 2014. NAD(+) and sirtuins in aging and disease. Trends in cell biology, 24(8), pp. 464-471.</li>
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<li>KIM, J.S., YOON, C. and PARK, D.R., 2014. NAMPT regulates mitochondria biogenesis via NAD metabolism and calcium binding proteins during skeletal muscle contraction. Journal of exercise nutrition & biochemistry, 18(3), pp. 259-66.</li>
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<li>KOLTAI, E., SZABO, Z., ATALAY, M., BOLDOGH, I., NAITO, H., GOTO, S., NYAKAS, C. and RADAK, Z., 2010. Exercise alters SIRT1, SIRT6, NAD and NAMPT levels in skeletal muscle of aged rats. Mechanisms of ageing and development, 131(1), pp. 21-28. </li>
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<li>LIANG, L., LIU, R., CHEN, X., REN, X., MA, J., CHEN, K., JIANG, M., WEI, P. and OUYANG, P., 2013. Effects of overexpression of NAPRTase, NAMNAT, and NAD synthetase in the NAD(H) biosynthetic pathways on the NAD(H) pool, NADH/NAD(+) ratio, and succinic acid production with different carbon sources by metabolically engineered Escherichia coli. Biochemical engineering journal, 81, pp. 90-96.</li>
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<li>LONG, A.N., OWENS, K., SCHLAPPAL, A.E., KRISTIAN, T., FISHMAN, P.S. and SCHUH, R.A., 2015. Effect of nicotinamide mononucleotide on brain mitochondrial respiratory deficits in an Alzheimer's disease-relevant murine model. Bmc Neurology, 15, pp. 19.</li>
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<li>VAN DE WEIJER, T., PHIELIX, E., BILET, L., WILLIAMS, E.G., ROPELLE, E.R., BIERWAGEN, A., LIVINGSTONE, R., NOWOTNY, P., SPARKS, L.M., PAGLIALUNGA, S., SZENDROEDI, J., HAVEKES, B., MOULLAN, N., PIRINEN, E., HWANG, J., SCHRAUWEN-HINDERLING, V.B., HESSELINK, M.K.C., AUWERX, J., RODEN, M. and SCHRAUWEN, P., 2015. Evidence for a Direct Effect of the NAD(+) Precursor Acipimox on Muscle Mitochondrial Function in Humans. Diabetes, 64(4), pp. 1193-1201.</li>
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<li>WANG, Q., QIAN, L., CHEN, S., CHU, C., WILSON, B., OYARZABAL, E., ALI, S., ROBINSON, B., RAO, D. and HONG, J., 2015. Post-treatment with an ultra-low dose of NADPH oxidase inhibitor diphenyleneiodonium attenuates disease progression in multiple Parkinson's disease models. Brain, 138, pp. 1247-1262.</li>
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<li>WHITE, A.T. and SCHENK, S., 2012. NAD(+)/NADH and skeletal muscle mitochondrial adaptations to exercise. American Journal of Physiology-Endocrinology and Metabolism, 303(3), pp. E308-E321.</li>
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<li>YING, W., 2007. NAD(+) and NADH in neuronal death. Journal of Neuroimmune Pharmacology, 2(3), pp. 270-275.</li>
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<li>ZAMPORLINI, F., RUGGIERI, S., MAZZOLA, F., AMICI, A., ORSOMANDO, G. and RAFFAELLI, N., 2014. Novel assay for simultaneous measurement of pyridine mononucleotides synthesizing activities allows dissection of the NAD(+) biosynthetic machinery in mammalian cells. Febs Journal, 281(22), pp. 5104-5119.</li>
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<li>ZHAO, Y., GUAN, Y., ZHOU, X., LI, G., LI, Z., ZHOU, C., WANG, P. and MIAO, C., 2015. Regenerative Neurogenesis After Ischemic Stroke Promoted by Nicotinamide Phosphoribosyltransferase-Nicotinamide Adenine Dinucleotide Cascade. Stroke, 46(7), pp. 1966-1974.</li>
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<li>ZHOU, M., OTTENBERG, G., SFERREZZA, G.F., HUBBS, C., FALLAHI, M., RUMBAUGH, G., BRANTLEY, A.F. and LASMEZAS, C.I., 2015. Neuronal death induced by misfolded prion protein is due to NAD(+) depletion and can be relieved in vitro and in vivo by NAD(+) replenishment. Brain, 138, pp. 992-1008.</li>
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<li>ZHOU, Y., WANG, L., YANG, F., LIN, X., ZHANG, S. and ZHAO, Z.K., 2011. Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD(+)-Auxotrophic Mutant. Applied and Environmental Microbiology, 77(17), pp. 6133-6140.</li>
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<h2 id=kswitch> Kill Switch </h2>
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<a href="https://2015.igem.org/Team:Leicester/Description">Back to the top</a>
  
<img src="https://static.igem.org/mediawiki/2015/2/2b/Kill_Switch_Fig1.jpg" align="right">
 
<p>There are two kill switch systems in the genetically engineered bacteria: One, a kill switch which causes the bacteria to die upon addition of an inducer; the other, a maintenance kill switch whereupon the bacteria die if they leave the gut. This dual containment system allows for the reduction in bacterial escape and horizontal gene transfer as well as the death of the bacteria as a backup option if it goes wrong. </p>
 
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<p>Potentially could use a toxin-antitoxin system but with a modified antitoxin protein which incorporates a nonstandard amino acid that is vital for the toxin function. Therefore upon induction of the nonstandard amino acid the toxin will have the right amino acids needed for its correct synthesis and thus will kill the cell. It is easier and simpler than the altering 22 essential enzymes like Rovner et al, 2015 but more effective than toxin-antitoxin systems. However, this approach will need to add a stop codon for the nonstandard amino acid in a key hydrophobic region (if the nonstandard amino acid is hydrophobic) (Rovner et al, 2015) so that without the non-natural amino acid the protein cannot fold correctly and thus be subject to proteolysis. This results in cell death upon the addition of the non-standard amino acid. However this would require the changing of the stop codon used to another stop codon in all other genes as well as engineering a tRNA synthase that charges the non-natural amino acid to an edited tRNA molecule that is cognate for the stop codon used.</p>
 
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<p>The CCDA/CCDB kill switch is in an operon system with CCDA under the control of a temperature sensitive RBS (Part BBa_K115002) whereas the CCDB is under the control of a generic RBS (Part BBa_K581008). This means that at under 37<sup>O</sup>C (i.e. not in the human body) the translation rate  of the CCDA will dramatically decrease relative to other genes in the bacteria at the same temperature, whilst CCDB will remain the same in respect to the fundamental decrease in rate due to the lower temperature. Thus there will be a high enough ratio of CCDB (once translated) to kill the cell. Summed up: When the temperature is too cold, the antitoxin (CCDA) doesn’t work, so the toxin (CCDB) kills the cell.</p>
 
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<p>However, CCDB is patented so another toxin/antitoxin system would be preferred such as MazF/MazE. If no antitoxin is available then the antitoxin in the system described above could be replaced with a polymerase gene (e.g. T7 Polymerase) and the desired toxin under the control of a promoter for that polymerase (i.e. a T7 consensus promoter). This would give higher levels of transcription and would be perhaps a more sure system. For our iGEM team however, due to time requirements, the simpler the system the better.</p>
 
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<p>Another Kill Switch which could be used to selectively kill the bacteria would be to use the X and Y expansion of the genetic code by Malyshev, et al 2014. This would use a toxin (Such as MazF toxin) that is dependent on the bases X and Y. This can be done by using long-range PCR for the MazF inside pUC19 but leaving a few bases in between the forward and the reverse primer. Then synthesis and PCR amplify an oligonucleotide which contains the primers and the X (dNaM)/Y (d5SICS) codon (Malyshev, et al 2014) for the non-natural amino acid for that codon (assuming there is a tRNA synthase for this). This can then be inserted into the PCR amplified pUC19 plasmid (with the gaps) through Gibson Assembly to then be transformed (Malyshev, et al 2014) as can be seen in figure 1. Proof will be needed for the incorporation of the X/Y through testing whether the transformed cells only die through addition of the X and/or Y base in a medium lacking these. This would significantly reduce the likelihood of the bacterium kill switch being activated naturally in the human microbiome. However, like through the addition of a nonstandard amino acid via stop codons, a tRNA molecule will be needed that can recognise the synthetic bases as well as a tRNA synthase which can accurately charge the nonstandard amino acid to this tRNA. As such this method can only be used in theory for our iGEM team. This will be a very useful application of synthetic biology once these key tRNA’s and tRNA synthases are ready. </p> 
 
  
<h4> References: </h4>
 
  
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<li>Malyshev.D., Dhami, K., Lavergne, T., Chen, T., Dai,N., Foster,J., Correa,I. & Romesberg, F. 2014. A semi-synthetic organism with an expanded genetic alphabet. Nature 509 (7500) 385-388. </li>
 
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<li>Rovner,A., Haimovich, A., Katz,S., Li, Z., Grome, M., Gassaway, B., Amiram,M., Patel,J., Gallagher,R., Rinehart,J. & Isaacs, F. 2015. Recoded organisms engineered to depend on synthetic amino acids. Nature, <b>518</b> (7537), 89-93. </li>
 
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Latest revision as of 22:45, 17 September 2015

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Project Abstract

Neurodegenerative disorders show decreased levels of NAD+/NAD(H). Using E. coli to colonise the gut, NAD+/NAD(H) levels could be increased by upregulating nadD, nadE and PncB enzymes in the E. coli cytosol; these gene products will be tagged and exported into the periplasm via the tat system to produce NAD+/NAD(H), which will be exported into the gut. The genes and killswitch will be inserted into E. coli, whilst the remaining aspects of the project will be theoretical due to ethical and safety restrictions. Speculatively, increased NAD+/NAD(H) could treat neurodegenerative disorders by mitigating the destruction of neurons and help with muscle fatigue. Regeneration of muscle fibres to restore strength and overall energy levels would be achieved by increased oxidative phosphorylation triggered by NAD+/NAD(H). This treatment provides low-cost NAD+/NAD(H) as part of an autonomous system; increasing the patients’ quality of life.

Project Explanation

For our project we wanted to look at a universal issue, something that affects every person indiscriminately. This lead us to aging as one such issue. Because the aging process is a highly dynamic and complex process intrinsic to our physiology, we knew that it was practically impossible to treat the condition, so we started looking at the symptoms. As we age our muscle strength declines, we become susceptible to a host of neurodegenerative diseases, and our overall physiological health declines. One common denominator to these conditions appears to be mitochondrial dysfunction (Gomes et al., 2013). We are hoping to address a few of the proximate aging symptoms, such as senescence of muscle tissue and neurones within the brain. One of the attributes of senescence is the gradual breakdown of the circadian clock of human physiology (Zamporlini et al., 2014).

Through research we identified the coenzyme nicotinamide adenine dinucleotide (NAD+) – widely accepted as a mediator of redox reactions – as a suitable candidate for our purposes. Literature has identified the interplay of NAD+ and SIRT1 working in concert to modulate metabolism and circadian rhythm (Zamporlini et al., 2014) which are closely linked to the mitochondria (Gomes et al., 2013). A hallmark of aging is the loss on NAD+ with age (Gomes et al., 2013; Zamporlini et al., 2014), as well as mitochondrial dysfunction; It has been shown that these two phenomenon are correlated, but a causal link is still tenuous.

Our project, simply put, is a self-sustaining integrated pharmacy for patients – a pseudo-organ in effect. Our ultimate goal for our project results would be to integrate an as yet undetermined strain Escherichia coli into the human gut microbiome. The purpose of the non-native bacteria is to produce a specified chemical compound – in this case NAD+ – into the gut. We speculate that due to the large surface area and blood flow of the microvilli, as well as the low molecular weight of NAD+ (Zamporlini et al., 2014), and proven uptake by mammalian cells (Billington et al., 2008), the NAD+ will enter the blood stream and be transported rapidly and uniformly across the entire body. We predict that this will over time, re-establish the circadian rhythms of metabolic processes, restore oxidative metabolism – especially in muscles – and possibly have a neuroprotective effect against neurodegenerative disorders such as Parkinson’s and Alzheimer’s.

For our project, we aim to develop several BioBricks with the purpose of increasing net extracellular NAD+/NAD(H) levels of the host organism – in this case it would be E.coli – the purpose being to allow transfer of NAD+ into the gut microbiome for absorption into the bloodstream of patients.

We believe this approach will enable a long term, and with further development, full integration of a bacterial pseudo-organ into people that suffer from deleterious conditions such as weaker muscle strength with age, as well as the neurodegenerative diseases that more common with aging. The end goal of this integration would be to ameliorate the symptoms of aging, possibly increasing longevity as a side-effect. This would have a tremendous impact as it could potentially restore the quality of life and self-sufficiency to the elderly and neurodegenerative sufferers relying on carers.

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Why NAD?

Introduction

NAD+ was first discovered by Arthur Harden and William Young 1906, during research on fermentative enzymes and was part of the 1929 Nobel Prize attributed to Harden and Hans von Euler-Chelpin (White and Schenk, 2012). It has long been known that NAD+ is a coenzyme used in multiple redox reactions and, consisting of two covalently bound mononucleotides – nicotinamide mononucleotide (NMN) and AMP (Zamporlini et al., 2014). It exists in its oxidised form NAD+, and the reduced form, NADH which provide oxidoreductive power, perhaps most notably utilised within the mitochondria to produce ATP (White and Schenk, 2012), with some of the ATP in turn being used to activate the NAMPT protein for further production of NAD+ (Hara et al., 2011). NAD+ can be synthesised either synthesised de novo from tryptophan (Zhou et al., 2015) or from salvage pathways using nicotinic acid or nicotinamide, with a third pathway – using nicotinamide riboside precursors – having recently been discovered (Billington et al., 2008).

The mitochondrial matrix is not the only cellular compartment containing an NAD+ pool, with the others being the cytosol and the nucleus as shown in figure 1 (White and Schenk, 2012). Whilst the nuclear membrane is porous to NAD+ to allow diffusion, mitochondrial membranes are not (White and Schenk, 2012). To transport NAD+ across mitochondrial membranes, biochemical shuttles are required; the four shuttles that have been found and are as follows: glycerol 3-phosphate, malate-aspartate, lactate and NADH/cytochrome c electron transport (White and Schenk, 2012). These shuttles, as well as the conversion of pyruvate to lactate replenish NAD+ levels via oxidation of the reduced form – NADH (White and Schenk, 2012). In addition to these mechanisms NADH is also oxidised into NAD+ within mitochondrial matrices by the electron transport chain during respiration (White and Schenk, 2012).

In recent years NAD+ has been accepted to be a signalling molecule, constituting integral parts of large and dynamic regulatory pathways and integrated networks (White and Schenk, 2012), including sirtuins.

NAD

NAD movement

Our projects ultimate goal, to increase NAD+ levels within human cells, could have been achieved a variety of ways. Before the main body of research is presented we will briefly discuss the reasoning as to why each method was discarded and how we arrived at our final decision.

One possible way would be to directly manipulate people’s genomes, but it comes with an array of risks such as lack of uniformity of genome modification – not every cell may be altered. Unintended complications may arise, such as immune response, organ failure and ultimately, death. These ethical considerations also lead on to the idea of eugenics if gene therapy became commonplace. This approach is also beyond our team’s current capabilities and conflict with iGEM regulations. Aside from the obvious ethical implications of human genetic modifications, studies have shown that in vivo upregulation of relevant genes pertaining to the NAD+ synthesis pathways, did not significantly affect the NAD+/NADH redox ratio (Frederick et al., 2015). Interestingly though, germ line knock-down of genes coding for NAD+ consuming enzymes has shown to perturb the NAD+/NADH redox ratio of cells, in favour of NAD+ (Frederick et al., 2015). This gene treatment was insufficient and was therefore inadequate to stimulate oxidative metabolism within skeletal muscle cells (Frederick et al., 2015), which is one of our project goals.

We briefly considered trying to transport the rate limiting enzyme in de novo NAD synthesis, NAMPT (Koltai et al., 2010; Hara et al., 2011; Liang et al., 2013; Canto, Menzies and Auwerx, 2015), into the viscera with the target being the cytosol of cells. We discarded this as we realised that the final product produced by the enzyme was smaller and more stable than the enzyme. Enzymes are large, require specificity when being transported – requiring human modifications to existing transport mechanisms – and can require numerous other criteria for efficacy, specific temperature, pH, and post-translational modifications.

There are non-synthetic biology alternatives, for example NAMPT can be chemically activated by P7C3 (Zhao et al., 2015), but more research is needed to confirm its safety.

Many of the papers looked at indicated that a rise in intracellular NAD+ was achieved through supplementation of NAD+ intermediates such as NMN, NR or Acipimox (see figure 2) (Zamporlini et al., 2014; van der Weijer et al., 2015; Felici et al., 2015). Whilst we could have targeted genes to upregulate NMN synthesis (see figure 2) such as Namnt within the E. coli, we decided to synthesise the end-product. We did this because with age the components maintaining the circadian rhythms decline, reducing the amount of NAMPT (Zamporlini et al., 2014). Whilst upregulating this may seem the simplest way to achieve our goal we were worried that the activity of NAMPT may be reduced due to lower ATP levels, which is required for NAMPT activation (Hara et al., 2011), due to the mitochondrial dysfunction. Later we will discuss the direct effect of NAD+ on cell biochemistry.

We were interested in the diversity of applications NAD+, conferred likely due to its role in integrated networks (White and Schenk, 2012) and as such were looking into its neurological effects on humans.

Sirtuins are a family of proteins that act as deacylases and depend on NAD+ to be biologically active (Koltai et al., 2010; Zamporlini et al., 2014). Mammals such as humans have seven sirtuins (SIRT1-7), with early work being carried out on the yeast Sir2 homologue (Ying, 2007; Koltai et al., 2010). Evidence confirms that SIRT1 promotes mitochondrial function, shown by the lack of upregulation of OXPHOS genes in both the nucleus and mitochondria when SIRT1 iKO mammals were subjected to fasting and calorie restriction (CR), leading to deacreased mitochondrial functionality (Gomes et al., 2013). Fasting and CR activate SIRT1, as does DNA damage from ionising radiation sources such as UV radiation sunlight (Zamporlini et al., 2014). It was speculated by Gomes and his team that the induced activity of increased mitochondrial oxidative metabolism – and increased transcription of mitochondrial OXPHOS genes due to these conditions – was via SIRT1 deacetylating PGC-1α (Gomes et al., 2013). However this was disproved as SIRT1 continued to function in KO PGC-1α/β mice (Gomes et al., 2013), suggesting an as of yet undiscovered mechanism.

We decided to use the NAD+ molecule for our project as we have seen evidence that it has neuroprotective effect in humans, as when NAD+ starvation occurs a misfolded amyloidogenic protein stimulates the activation of autophagic mechanisms and neurodegeneration (Zhou et al., 2015). Mitochondrial dysfunction is present in a multitude of neurodegenerative diseases including Parkinson’s (Zhou et al., 2015) and Alzheimer’s (Long et al., 2015; Zhou et al., 2015); with NAD+ loss being a contributory factor. Administration of the precursor NMN was shown to restore the respiratory capacity of ailing mitochondria, as well as reducing mitochondrial fission and reducing fragmentation – which might explain the reduction of mitochondrial bioenergetics defects – after this they identified that NAD+ may be a limiting factor when the oxygen consumption rate (OCR) deficiencies normalised upon administration (Long et al., 2015). This neuroprotective action can be mainly attributed to SIRT1 which deacetylases PGC-1α, which when activated, stimulates mitochondrial biogenesis (Long et al., 2015).

Recent research has indicated that these neurodegenerative diseases are prion based, with affected neurones having decreased ATP productions as well as reduced NAD+ levels (Zhou et al., 2015). This can be a destructive cycle as ATP is required by the rate limiting enzyme NAMPT for de novo synthesis of NAD+ which in turn is required for metabolic production of ATP, leading to a gradual decline of both.

The NAMPT-NAD+ axis has been shown to have both neuroprotective and neuroregenerative effect via the combined actions of SIRT1, SIRT2 and SIRT6 (Ido et al., 2001). These proneurogenesis effects have been corroborated by the reduced activity of SIRT1, SIRT2 and SIRT6 when these deacetylases were knocked down (Zhao et al., 2015).

There are many causes of neuronal cell death, one of which is ischemia. This is the restriction of blood flow from to areas of the body by narrowing of arteries or spasm; when this occurs this can cause a stroke, called an ischemic stroke. NAD+ has been shown to protect against ischemic cell death, as ischemic injury depletes the supply of neurological NAD+ (Zhao et al., 2015). This indicates that continued neuronal viability is dependent on the activities of NAD+, possibly due to the activity of NAD+ consuming enzymes such as the aforementioned sirtuins. However neuronal death can be caused by an array of diseases as well – Parkinson’s, Alzheimer’s and multiple sclerosis.

We did hope that the excess in NAD+ consumption by Sirtuins and other NAD+ consuming enzymes would result in a far larger pool of NMN, an NAD+ intermediate that has been consistently shown to increase NAD+ levels (Gomes et al., 2013; Frederick et al., 2015; Zhao et al., 2015). However even with sensitive instruments and assays, NMN has not been found within blood plasma of mice (Hara et al., 2011). Interestingly, however, NAD+ has been shown to be present in the blood stream at nanomolar concentrations, possibly due to the use of NAD(P) by ectoenzymes (Billington et al., 2008). We were unable to determine through literary research as to whether NAD+ is able to traverse the blood brain barrier (BBB), but it has been shown that NMN can cross the BBB to modulate intracellular NAD levels (Zhao et al., 2015). NMN is safe for long-term use for clinical applications as it is a native endogenous substrate (Wang et al., 2015). This leads us to speculate that either NMN is contained within cells by membranes and is therefore not subject to high enough diffusion gradients between cell interiors and exteriors or that the majority of NMN is used in NAD+ synthetic pathways. This could also indicate that cells are completely impermeable to NMN, however this is unlikely due to the droves of evidence that NMN supplements can increase the NAD+ pool, meaning that NMN can traverse membranes even if it is only unidirectional, which if the case will require further development of our GMO to address. Assays need to be carried out to detect whether increased NAD+ can perturb and therefore increase the NMN pool. By effectively reducing the activity of NAD+ synthesis and salvage pathways’ activities and thereby reducing NMN consumption, we hope that NMN may enter the bloodstream to create an extracellular NMN pool. Concurrently we believe that NMN levels may be actively produced from exogenous NAD+ by the proteins coded for by the NadD and NudC genes (Zhou et al., 2011) as shown in figure 4. NMN has been shown to have a positive effect on the insulin levels secreted in culture and in vivo, due to the stimulation of SIRT1 in pancreatic β cells (Zhao et al., 2015).

Studies have revealed that inhibition of other NAD+ consuming enzymes such as PARP (1 & 2) enzymes can convey long-term neuroprotection (Ying, 2007). As a future consideration for the development of the neurological aspect of our project, this inhibition of PARPs could potentially yield a more layered and therefore more refined approach.

Our project relies on the capacity of mammalian cells to uptake NAD+ for use in various biochemical reactions. Experiments have proven that NAD+ is taken up in two stages, initially there is a rapid transport followed by a period of uptake lasting an hour or so (Billington et al., 2008), with transport rate shown in figure 5.

NAMPT has been shown to significantly increase the number of mitochondria within cells, and NAD+ increases myocyte mitochondria biogenesis (Kim, Yoon and Park, 2014). This indicates that NAMPT increases the NMN levels, which in turn, increase the NAD+ levels to increase mitochondria concentration. As previously mentioned NMN increases insulin levels – evidence shows that SIRT1 has been linked to increased insulin sensitivity (Kim, Yoon and Park, 2014). These increased insulin levels coupled with increased biogenesis may have a positive effect on bodily energy levels, reducing age-related fatigue. The site of action of this biogenesis may be due to the modulation of hypoxia inducing factor-1 alpha (HIF-1α), which is known to increase with age to combat the decline of appropriate redox conditions – especially within skeletal muscle (Koltai et al., 2010; Gomes et al., 2013). Once again returning to sirtuins, SIRT1 increases the transcriptional activity of HIF-1α – which seems counter intuitive to its other areas of effect – but SIRT3 destabilises the HIF-1α protein structure, with SIRT6 acting as a corepressor (Gomes et al., 2013). These data imply that the benefits of increasing the activity of sirtuins thus far outweighs the cost.

Nuclear activity of SIRT1 and the level of acylation of proteins show an inverse correlation (Koltai et al., 2010) indicating that with increasing age target proteins are subjected to a lesser degree of acylation, possibly contributing to the detrimental proximate effects of aging. Exercise has been shown to increase the activity of NAMPT, the rate limiting enzyme in NAD+ synthesis, which thereby increases the NAD+ pool, increasing the SIRT1 deacetylase which is dependent upon NAD+ to function (Koltai et al., 2010). SIRT6, in conjunction with SIRT1 regulate DNA repair mechanisms (Liang et al., 2013) as previously mentioned, indicating that stimulation may enable partial protection from DNA damage and increase replicative lifespan of cells as shown in figure 6.

As NAD+ is required by E. coli for glucose oxidation (Liang et al., 2013), we predict that an increase in NAD+ synthesis will confer a selective advantage over other gut fauna, promoting better growth rates as overexpression of the pncB genes has been shown to confer a significant increase in the mass of the cell (Liang et al., 2013). Experiments were done on a strain of E. coli (BA002) that could not anaerobically use glucose as an energy source due to the lack of NAD+ regeneration; the decreased NAD(H)/NAD+ ratio due to increase in the NAD(H) pool, improved glucose uptake and growth of cell – substantiated by the increase of dry mass of cells – also conferring succinic acid production (Liang et al., 2013). However the excess NAD+ may also increase the prevalence of other gut fauna and a full analysis of bacterial interaction will need to be completed before any clinical considerations as NAD+ may confer different behaviour to pathogenic organisms.

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Practical Components

pncB

We identified one gene called pncB which encodes nicotinic acid phosphoribosyltransferase (NAPRTase) (Liang et al., 2013), as seen in figure (from Zhou et al., 2011) is responsible for the conversion of NA into NAMN. We selected this gene as experiments have shown that cooverexpression with another gene, nadE, increased the NAD(H) by 7-fold. This was of particular use to us as the shuttling mechanisms, among others, as mentioned previously are able to oxidise the NAD(H) into NAD+ (White and Schenk, 2012). From this we can deduce that whilst the NAD(H)/NAD+ axis is perturbed in favour of NAD(H) the net concentration of NAD+ increases in vivo over time due to the oxidative actions of the shuttles and other mechanisms (Liang et al., 2013).

nadD and nadE

The second and third gene sequences we were interested in were nadD, which encodes the NAMN adenylyltransferase and nadE which codes for NAD Synthetase in the NAD(H) biosynthetic pathway responsible for the interconversion of NAD+ and NMN (Zhou et al., 2011, Zamporlini et al., 2014). This is of particular use to us as we wish, as a secondary objective, to increase NMN levels for reasons discussed previously. We believe this will be feasible due to the increase in NAD+ in cells, potentially reducing a limiting factor of NMN production (see figure 4 NadD).

Experiments have shown that individually upregulating pncB, nadE and nadD increases the NAD(H) pool (Liang et al., 2013). Despite this extremely promising theoretical increase for single genes we decided to maximise the output by using all three. We did this as we were concerned that very high concentrations of NAD+ may be required to enter cells in useful concentrations, as some may be lost to other gut fauna, the gut environment itself, or not be concentrated enough in the blood to enter cells. Further experiments would be required to ascertain the efficiency of uptake whereupon we would regulate the NAD+ output.

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Conclusion

To conclude, we believe that our pseudo-organ can provide a long-term treatment to slow and potentially reverse some of the symptoms of aging both in skeletal muscle in terms of strength and energy levels and neurologically in terms of neurone viability and functioning.

We are aware that some members of the public may be hesitant to a therapeutic GMO, but our project has the added advantage of having the integrated BioBricks within the pSB1C3 high copy number vector to be compatible with bioreactor technology. Possibly providing a cheaper manufacturing of supplements. This may serve as a temporary measure until public opinion is assured of the clinical safety of therapeutic GMOs.

Due to the effects on human physiology we believe our GMO will provide a better standard of living by increasing certain aspects of health and increasing self-sufficiency of neurodegenerative sufferers and the elderly. This may even have a knock on effect on reducing the economic assets invested in care systems allowing reinvestment into other health sectors.

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Reference

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