Compost raises orange yield

SOUTH AUSTRALIAN RESEARCH AND DEVELOPMENT INSTITUTE

A South Australian Research and Development Institute study has demonstrated yield increases in navel and Valencia orange orchards of 17 to 63 per cent after the application of soil amendments including grape marc, animal manure and compost. SARDI senior entomologist Dr Peter Crisp said fruit measured in the trial increased in diameter by 5 mm to 7 mm on average. “This could provide growers an extra $100 per tonne, with the benefits of the compost lasting well beyond the first year after application,” Dr Crisp said. The SARDI study also evaluated a range of tree and soil health factors including levels of soil moisture, nitrogen and soil carbon. The SARDI research team found that compost application during periods of drought improved tree health compared to trees that did not receive compost.  “Where composted green organics had been applied, trees had dense foliage, good leaf colour and the highest flower production,” Dr Crisp said. “Improved tree health where compost was applied may be attributed to increased soil moisture levels in the root zone. “Moisture sensors 10 cm to 15 cm deep in the soil showed that moisture levels were consistently higher under trees treated with the highest rate of compost compared to control trees.” A cost benefits analysis from this study found all compost applications trialled showed a positive return on the initial investment.  The highest benefit was recorded when an application of 40 m²/ha of compost was used, giving a cost benefit of 5.4 over five years.  The benefits recorded giving a return of between $1.90 to $5.40 for every dollar invested in compost over a five year period. “These are conservative estimates as the potential water savings and improvements in fruit quality were not included in the analysis,” Dr Crisp said. Data from this trial site at Loxton will be collected for a further three years with support from Horticulture Australia Limited and a voluntary contribution from the Australian compost industry.

Stars affect dark matter: study

MARION LOPEZ, SCIENCENETWORK WA

"...when we look at galaxies alone, the gas and stars become relatively more important and begin to influence dark matter..." Image: Akirastock/iStockphoto The interaction of dark matter with stars and gas in individual galaxies is more complicated than previously thought, according to International Centre for Radio Astronomy Research (ICRAR). After discovering a correlation between the concentration and mass of dark matter around clusters of galaxies, Dr Alan Duffy from ICRAR found this relationship breaks down around single galaxies, like our own Milky Way. “A basic assumption that astronomers often make is that the dark matter is so dominant that we can ignore the effects of gas and stars on its dynamics. “For massive clusters of galaxies this is a good approximation and there's a nice relation that drops out of the simulations between the mass of the cluster and the dark matter concentration, in full agreement with observations. “The problem is that when we look at galaxies alone, the gas and stars become relatively more important and begin to influence the dark matter, which causes the galaxies to lie off this concentration–mass relation.” Dr Duffy says that simulating the Milky Way is extremely computationally demanding and will require the use of the EPIC supercomputer housed at Murdoch University.   Dr Duffy hopes to find the answers as to why the dark matter around galaxies like our Milky Way is different, by creating some of the most detailed galactic simulations in the world. To verify these predictions as to the nature of Dark Matter, as well as its role in the formation of galaxies, Dr Duffy says the Australian Square Kilometre Array Pathfinder (ASKAP)—prototype of the Square Kilometre Array (SKA)—is a key project. ASKAP will enable astronomers at ICRAR to survey over half a million galaxies and help to determine what dark matter is, although it will find only a fraction of the billion galaxies that the SKA will study. In fact, Dr Duffy says the SKA will take astronomers to the edge of the Universe and will therefore be crucial in unveiling the processes by which galaxies form, by looking at the very first objects that were ever fashioned in the Universe. “The hope is that through better observations of dark matter we can begin to understand the type of particle that’s making it up. “When ASKAP comes online, we’ll be able to answer a lot of questions, while probably creating more questions that we know the SKA will have the potential to answer. “By creating mock observations from the simulations I can bridge the gap between the theory of how galaxies form and the processes which make the Milky Way look like it does, and what telescopes such as ASKAP, and ultimately the SKA, will see.” interaction of dark matter with stars and gas in individual galaxies is more complicated than previously thought, according to International Centre for Radio Astronomy Research (ICRAR).

How a fish lives on land

THE UNIVERSITY OF NEW SOUTH WALES

The study throws new light on how animal life first evolved to colonise the land. Image: courtney morgans/UNSW One of the world's strangest animals – a unique fish that lives on land and can leap large distances despite having no legs – has a rich and complex social life, a new study has found. The odd lifestyle of the Pacific leaping blenny (Alticus arnoldorum) has been detailed for the first time in research findings that shed light on how animal life evolved to colonise the land. The Pacific leaping blenny is a marine fish yet is terrestrial in all aspects of its daily adult life, eking out a precarious existence in the intertidal zone of rocky shores in Micronesia, according to the study published in the journal Ethology , led by Dr Terry Ord, of the UNSW Evolution and Ecology Research Centre. "This remarkable little fish seems to have made a highly successful transition across the water–land interface, although it still needs to stay moist to enable it to breathe through its gills and skin," says Dr Ord, who is an evolutionary ecologist with a special interest in animal behaviour. "Our study showed that life on land for a marine fish is heavily dependent on tide and temperature fluctuations, so much so that almost all activity is restricted to a brief period at mid-tide, the timing of which changes daily. During our field study on Guam we never saw one voluntary return to water. Indeed, they spend much of their time actively avoiding submersion by incoming waves, even when we tried to capture them for study. "I can tell you they are very hard to catch and are extremely agile on land. They move quickly over complex rocky surfaces using a unique tail-twisting behaviour and expanded pectoral and tail fins that let them cling to almost any firm surface. To reach higher ground quickly, they can twist their bodies and flick their tails to leap many times their own body length." Working with Toni Hsieh, of Temple University in the US, Dr Ord found that adult blennies shelter in rock crevices at high and low tide, emerging at mid-tide to feed, breed and socialise in surprisingly complex ways – given their brief window of opportunity. The researchers discovered that males are territorial and use complex visual displays to warn off rivals and attract mates. Females were seen aggressively defending feeding territory at the start of their breeding season. At the same time, males displayed a red-coloured fin and nodded their heads vigorously to attract females to their closely defended rock holes. The team filmed females inspecting these holes before entering with a chosen mate. Little is known of the breeding and development of the young, but females lay their eggs in a chosen rock hole and then play no further role in parenting, leaving the male to guard the eggs. "The Pacific leaping blenny offers a unique opportunity to discover in a living animal how a water–land transition has taken place," says Dr Ord. "We know that our ancient ancestors evolved originally from lobe-finned fish but, today, all such fish are fully aquatic. Within the blenny family, however, are species that are either highly terrestrial, amphibious or entirely aquatic. Remarkably, representatives of all these types can be found on or around Guam, making it a unique evolutionary laboratory." Download: eType1.com/f.php

The New Entrepreneur: A Case Study

So far I’ve tried to lay the foundations for what I call the new entrepreneurial process—an approach to entrepreneurship with roots in design thinking, strategy in dynamic environments, and experimental processes that has been evangelized in several movements like Customer Development and Lean Startup. I thought I would try something different this time: give a concrete case study of the process. Then, we can drill down and more concretely identify traps that catch entrepreneurs and how they escape them. Let me know how you like this approach.

The Crime Reports Case Study

It was the process. Doing everything right was killing his business. It all started several years earlier when Greg’s apartment building had been robbed. Frustrated and feeling a need to do something about it, he joined a neighbourhood watch group and offered to map crimes that were happening in the area. As Greg continued, he came to believe that mapping the locations of crimes would align and empower the efforts of citizens and police to reduce crimes in each neighborhood.

When Doing Everything Right Leads You to Failure

With real motivation and passion, Greg did what all good entrepreneurs are supposed to do—he wrote a business plan and developed a website to report crime statistics (with an underlying revenue model built on advertising). Website in hand, he contacted a friend at the Washington DC police department and together, Greg and his friend convinced the police chief to commit to a trial run. Excited by his success, Greg took the next step and presented to venture capitalists, who were impressed by Greg’s vision and provided seed capital to grow the business. Capital in hand, Greg continued building CrimeReports.com and hired developers and sales people to expand before competitors could catch up. But then something perplexing began to happen. Despite all his efforts, the business didn’t take off. New deals with police departments seemed to hover in a state of limbo, never closing; and despite moments of hope and seeming progress, CrimeReports.com remained stuck in a purgatory that had now lasted for several years without producing any new customers. After investing the first two tranches of venture funding, Greg began to dig deeper and ask himself why. Why, when he had done everything right, had things gone so wrong?

Applying the New Entrepreneurial Process

After he’d spent many years of his life and hundreds of thousands of dollars of investors’ money, it still wasn’t clear if CrimeReports.com was a hobby or a business. When his investors requested that the next tranche of financing be contingent on the company running the Nail It then Scale It process, it created a crisis that drove Greg to stop selling and start listening to the customer and understand what was missing in order to break through the barrier of customer adoption. He created a road show to take his product prototype and business model hypothesis out to the market and really listen—and what he learned shocked him. Greg and his team set up meetings with the full buying panel (all the decision makers in a purchasing decision) at four different police agencies to get feedback on their “prototype” and business model. For police departments, the buying panel meant the police chief, the IT director, the crime analyst, and the police officer. Once Greg had his team and the entire buying panel in the same room, a rich discussion ensued in which a few key insights emerged.  First, the founders were on to something—police departments were feeling increasing pressure to share information with the public about crime and to increase transparency and their accountability.  Second, the police departments felt that the website was ugly and needed to be improved. Fair enough. Third, although the founders believed that the business model depended on hosting advertisements, police departments absolutely refused to have advertising hosted on the site.

At this point, the founders began to despair, but as they continued to listen (rather than sell), they found out some crucial pieces of information. For one, police officers were actually fascinated by the data possibilities of the website and were truly excitied about the possibility of leveraging the internet to increase the quality of their communication with the citizens of their town. The chiefs of police were interested in sharing data with the citizens and leveraging that data to increase the quality of their policing efforts. Many police chiefs were familiar with how New York City had used the “Comp Stat” model to decrease crime by identifying patterns and targeting “hot spots”; but for most departments, “hot spots” were tracked with a spreadsheet, cork board, and colored pins. If the data was hosted online,  police chiefs could use a data “dashboard” to track trends and daily activity. For the first time, police officers could see what had happened on their beat the night before. As it turned out, this was surprisingly difficult for existing departments to do. As one police chief stated, sometimes it took up to six months to see what happened the day before. As the enthusiasm built in each conversation, the CrimeReports founders learned that police would actually pay them to post their data—advertising wasn’t necessary. But they also learned, from the IT directors, that they needed to significantly improve their security protocols in order to allow CrimeReports to host the data. Last, the founders discovered that a touch-and-feel approach was the best approach to selling the new product. At the end of the day, by showing a “prototype” to customers and then listening rather than selling, the CrimeReports team learned crucial facts that had been hidden from view for years.

Greg Whisenant took all the feedback, refined his prototype, and then took it out on the road for another test. The new website was greatly improved in look and feel and had no advertising. And when the Public Engines team took the new version back to the potential customers, the feedback was astonishing. Their customers said things like:

“This blows other choices out of the water.”

“This is a great idea. You guys have really hit on something here.”

FROM RAGS TO RICHES: AN AMERICAN SUCCESS STORY

If you don’t know his name, John Paul Dejoria (of the hair care line John Paul Mitchell and the CEO of Patron Spirits) then you are definitely familiar with some of his businesses. But are you familiar with his unlikely, and incredible, story that beat the odds?

John Paul DeJoria, From Homeless To Billionaire

An Interview with John Paul DeJoria, owner of Patrón Spirits and cofounder and CEO of John Paul Mitchell Systems

John Paul DeJoria is one of the great stories of achieving the American Dream. Twenty years after being homeless, he was able to buy a seat on the New York Stock Exchange. Along the way he built two iconic companies — John Paul Mitchell Systems and Patrón Spirits. Today, DeJoria has a personal net worth of over $4 billion, but perhaps his most significant contribution is his business philosophy, which is at the intersection of helping the world, helping people individually and creating profit — all with a genuine smile on his face. He’s definitely having fun. I recently sat down with DeJoria.

What was your childhood like?

We grew up in downtown LA, in the Echo Park area. We didn’t know that we were really going through tough times because everybody was going through the same thing. I remember once in junior high school, on a Friday, my mom came home from work and said to my brother and I, “You know, between us, we have only 27 cents, but we have food in the refrigerator, we have our little garden out back, and we’re happy, so we are rich.”

Talk about the initial visions behind Patrón Spirits and John Paul Mitchell Systems?

With John Paul Mitchell Systems, we wanted to sell only to hairdressers, but we wanted something different. We came up with a shampoo that required only one wash to save time and money, and a conditioner that you left in. This acted as a sculpting lotion for the hairdresser, protected against the heat of a blow dryer, and helped neutralize chemicals on hairdressers’ hands. We knew we wouldn’t do what other companies did; many said they would only be in the professional hairdressing industry, but went full retail when they got big. In fact, today, 31 years later, if you ever see a Paul Mitchell product in the drug store or supermarket, it’s counterfeit or black market. We stayed true to our word.

As for Patrón, we wanted to produce the smoothest tequila people had ever tried; tequila that didn’t get you really sick the next day; something you could sip. That was our vision: to have something that could one day be an ultimate premium tequila. People would treat themselves by having Patrón. Once people in every segment of society are turned on to Patrón, they become hooked, because Patrón is not only an ultra-premium, high-quality tequila, but also it’s one that’s made with a lot of love.

Very different business models. Are there similarities?

If you are involved with Patrón Spirits or Paul Mitchell Salon hair care products, you’ve got to love the product, you’ve got to love your customer, and you’ve got to love the planet: It’s our culture. We hire people with that attitude, because if you don’t love what you do, within three months, you could leave us. At John Paul Mitchell Systems — the older of the two [companies] — we’re 31 years old, and our turnover has been less than 30 people in 31 years!

By loving yourself, you’re going to be a happy person.  A lot of people don’t like themselves for whatever reason. Being able to communicate with a loved one that you haven’t talked to in a while because of some communication break makes their life and your life in a much better place.  Now you’re getting along, and people are in more harmony.

So the love helps us a lot because, no matter what you do — whether it’s shipping, manufacturing of products, or putting ingredients in — you always make sure you do it the best because you love who your customer is and what you stand for.

Secrets of Aging

What does a normally aging brain look like? Are diseases of aging such as Alzheimer’s inevitable?

By Carol Barnes | 

CORBIS, OWAKI/KULLA

Only 40 years ago it was widely believed that if you lived long enough, you would eventually experience serious cognitive decline, particularly with respect to memory. The implication was that achieving an advanced age was effectively equivalent to becoming senile—a word that implies mental defects or illness. As a graduate student back then, I was curious why such conclusions were being drawn about the elderly. I had only to look as far as my own great-grandmother and great-aunt to begin questioning the generalization. They lived to 102 and 93, respectively, and were exceptionally active and quick-witted enough to keep us twentysomethings on our toes. A closer look at the literature didn’t give me any confidence that either the biological basis of memory or how it might change with age was well understood. Many discoveries made in the years since have given us better tools to study memory storage, resulting in a major shift away from the view of “aging as a disease” and towards the view of “aging as a risk factor” for neurological diseases. So why do some people age gracefully, exhibiting relatively minor—and at worst annoying—cognitive changes, while others manifest significant and disabling memory decline? Answers to these questions are fundamental for understanding both how to prevent disease and how to promote quality of life.

A test for normal aging

Cognitive decline at older ages is marked by gradual loss in the ability to retain new information or to recall the past. Although many other changes occur during the aging process—impairment in range of motion, speed of gait, acuity of vision and hearing—none of these factors are as central to one’s personal identity as are one’s cumulative experiences. For me, it seemed that understanding memory, and how it changes with age or disease, was the key to understanding the aging brain.

Infographic: Molecular Learning
View full size JPG | PDFTAMI TOLPA

When I was in graduate school, in 1973, two papers came out that would change the shape of neuroscience and memory research. Terje Lømo, Tim Bliss, and Tony Gardner-Medwin devised a method that could experimentally alter synaptic strength. Earlier theoretical ideas had implied that strengthening the connection between neurons might explain how memories were formed: the stronger the connection, the better a message could be relayed or recalled. As electrophysiologists, Lømo and colleagues tested this idea by sending electrical currents through a group of neurons in the rabbit hippocampus in patterns that mimicked normal electrical activity, and measuring how the connections between the neurons changed. By stimulating neurons, they could create a durable increase in synaptic strength, which was later dubbed long-term potentiation, or LTP. But more than just an intriguing physiological observation, the research presented a fully controllable experimental proxy for learning that made it possible to study memory across the lifespan of an animal for the first time.

Thus, with the discovery of LTP, and the idea that animal models of human memory could be developed, I sought to finish my dissertation research in a lab that was routinely conducting LTP experiments. At the time, there were only three labs in the world that were doing these types of experiments: Graham Goddard’s laboratory at Dalhousie University, Tim Bliss’s at University College London, and Gary Lynch’s at UC, Irvine. As it turned out, my thesis advisor Peter Fried, at Carleton University in Ottawa, had been one of Goddard’s students, and introduced me to him by saying, “I don’t really want you to steal my student, but she has this idea that she thinks you might be interested in.” I explained to Goddard that I wanted to track an animal’s ability to make and keep spatial memories as it aged. Since the hippocampus—the area of the brain where LTP was first discovered—was also involved in spatial memory, I wanted to use Goddard’s setup and surgically implant electrodes that could measure LTP in awake, freely behaving rats. In an act of faith and generosity, Goddard soon purchased animals for me and began to “age” them in anticipation of my arrival the following year.

The behavioral tests used to study spatial memory at this time all used somewhat severe methods to motivate animals: either with shock—a significant stress—or by restricting eating or drinking, both of which were potentially detrimental to survival. Because the precious aged animals could not be replaced without waiting two years to grow another “old” batch, I developed a novel, milder task that is now often referred to as the Barnes maze. With rodents’ natural aversion to open, well-lit areas in mind, I designed a circular platform with many openings around its circumference, only one of which would allow the animal to escape into a dark box beneath the platform’s surface.

Aging is not equivalent to the aberrant process of Alzheimer’s disease; it is in fact a distinctly different neurological process.

At 2–3 years old (an age equivalent to about 70-80 human years), the rats were old enough to begin the behavior and electrophysiological experiments in the latter part of 1975. The animals were permanently implanted with electrodes that could both stimulate the neurons and record their activity. The electrodes allowed us to measure baseline synaptic transmission with single stimuli, then to induce LTP, and finally to monitor its decay over several weeks. We found that LTP decayed about twice as fast in the old rats as it did in the young, with the “synaptic memory” lasting 20 days rather than 40. Most importantly, the durability of LTP was correlated with the memory of the correct hole on the circular platform task. In fact, by combining behavior and electrophysiology techniques, we produced the first demonstration that instead of acting as a mere proxy for learning, LTP might actually represent the cellular mechanism by which all memories are created.¹

Just one year before I published my work on aging rats, Bruce McNaughton, then at Dalhousie University, demonstrated that for synaptic strengthening to occur, synapses from several neurons needed to converge and be coactive on the target neuron. The finding made perfect sense, since learning often comes from the association of two or more pieces of information, each of which could be carried by an individual neuron. Later experiments also demonstrated that under some conditions, LTP can be more difficult to induce in aged rats, and conversely, that a reduction in synaptic strength—called long-term depression or LTD—is easier to induce in the hippocampus of old rats.² This may mean that LTD participates in “erasing” LTP, or reducing its longevity, and thus possibly increases forgetting.

By the mid-1980s it was clear that even in normal aging there are subtle changes in the biological processes that underlie memory, and in the relationship between the strength of memory and the strength of the synapses. But the real message of these experiments was that old animals can and do learn. None of the older animals exhibited what could be considered behaviorally to be “dementia,” nor were their biological mechanisms that allow memory traces to be laid down completely dysfunctional.

Aging networks

While there is much to be learned about the physiology of neural systems by direct artificial stimulation, even the mildest currents do not exactly mimic the selective and distributed activity of cells in normal behavioral states. To more realistically understand the aging brain, it is necessary to monitor cell circuits driven by natural behaviors. Around the time that LTP was discovered, John O’Keefe at University College London discovered “place cells” in the hippocampus—a major breakthrough for the field. By simply placing small microwires very close to hippocampal cells, without stimulating them, John and his student Jonathan Dostrovski noted that individual hippocampal cells discharge action potentials only when a rat is at select physical locations as it traverses a given environment.³ The unique property of these place cells is that their “receptive fields,” or the features that make each of these cells fire, are related to specific regions of space.

Infographic: Lost in Space
View full size JPG | PDFTAMI TOLPA (MAZE); CAROL BARNES (COGNITIVE MAPS, SOURCE: NATURE 388/ 17 JULY 1997)

By recording from many individual place cells at once, using a multipronged electrode (the tetrode) developed by McNaughton, and determining which physical locations activated different cells in the brain, it was possible to visualize how the hippocampus constructs a “cognitive map” of the surroundings. If young rats were given one maze-running session in the morning, and another session in the afternoon, the same hippocampal map was retrieved at both time points—suggesting that the pattern of neuronal firing represented the memory of their walking through the rectangular, figure-eight maze. What surprised us was that about 30 percent of the time, when old rats went back for their second run of the day, a different place-cell distribution would appear—as if the older animals were retrieving the wrong hippocampal map.⁴ Certainly a rat navigating a familiar space with the wrong map is likely to appear lost, or as though it had forgotten its way. But why was the rat retrieving the wrong map?

The possible answer to this question was published in 1998 by Cliff Kentros, now at the University of Oregon. In young rats, Cliff pharmacologically blocked the NMDA receptor, a critical gateway regulating LTP and synaptic strengthening. When he and colleagues used a dose large enough to block the formation of LTP, the cognitive maps of the young rats began to degrade over time in much the same way as observed in aged rats, suggesting that faulty LTP mechanisms may be responsible for map instability in aging.⁵

Connecting the hippocampal dots

Even though the new multiple tetrode recording method was a large advance over the limitations of recording one or two neurons at a time, these methods were still constrained to sample sizes of ~100 to 200 cells.

One recent advance has allowed us to monitor cell activity on a broader scale, not with electrodes, but by tracking the expression of genes that are rapidly expressed during behavior. Monitoring the expression of one such gene, Arc, during behavioral tests, for example, John Guzowski in my lab developed a method that could report on activity over hundreds of thousands of cells across the brain (the ‘catFISH’ method).⁶ This large-scale imaging of single cells has been critical for identifying which cells, within which memory circuits, are altered during normal aging.

This technique also allowed us to tease apart which cells might be more susceptible to decline with age. Unlike electrodes that record LTP, which cannot differentiate between different types of neurons, the catFISH method allows us to distinguish between the three primary cell groups within the hippocampus—the granule cells of the dentate gyrus and the pyramidal cells of regions CA1 and CA3. We were able to show that cell-specific gene expression (and therefore cell activity) did not change with age in CA1 and CA3 cell regions, but that the number of granule cells engaged during behavior showed a continuous decline in aging rats, suggesting these cells are a weak link in the aging rat hippocampus.⁷ Could this also be true in primates?

Scott Small at Columbia University Medical Center helped me answer this question in young and old monkeys. Although MRI methods do not have single-cell resolution, they can provide an indirect gauge of activity over large segments of the brain. Using a variation of standard MRI that measures regional cerebral blood volume (CBV), we monitored the resting brain activity of monkeys ranging in age from 9 to 27 years (equivalent to 27 to 87 human years), and could then relate this brain activation to an individual animal’s performance in memory tests. There were no differences in resting metabolic measures in the areas of the brain that send most of the signals into or out of the hippocampus, nor were there differences in brain activity within CA1 or CA3. But the old monkeys did show reduced activity in the dentate gyrus, similar to what we had found in aging rats. Critically, we observed that the lower the activity in the dentate gyrus, the poorer the memory.⁷

Scott had observed a similar pattern in an earlier human aging study. However, with human studies there is always a concern that some of the people we assume are aging normally in fact have the undiagnosed beginnings of human-specific neurological disease, such as Alzheimer’s. Confirming the observation in aging animals, which do not spontaneously get this disease, provides strong evidence that the dentate gyrus is a major player in the changes that occur in normally aging mammals.

Furthermore, these data refute the contention that aging is effectively equivalent to an aberrant process like Alzheimer’s disease, revealing that it is in fact a distinctly different neurological process. In contrast to the results showing that aging primarily affects the dentate gyrus, the granule cells of this brain region in Alzheimer’s patients do not show changes (with respect to age-matched controls) until very late in the illness. Instead, it is the cells in CA1 and in the entorhinal cortex that are dramatically affected. Thus, while aging and Alzheimer’s may in some cases be “superimposed,” there is not a simple linear trajectory that leads us all to end up with the disease.

Memory genes

Infographic: The Seat of Memory
View full size JPG | PDFTAMI TOLPA

Presently, the omics revolution is leading us closer to an understanding of individual differences in aging and cognition. One example with respect to memory is a study that used a genome-wide association approach in 351 young adults to identify the single nucleotide polymorphisms (SNPs) most strongly related to memory. The most significant SNP identified was a simple nucleotide base change in the normal cytosine-thymine sequence at a specific location in the KIBRA gene, which encodes a neural protein that had been suspected of playing a role in memory. Those who had the thymine-thymine SNP had the best memories.⁸ This was further confirmed in an independent elderly population,⁹supporting the view that this particular SNP in the KIBRA gene predisposed people of any age to have “better memory.” This could be another clue to help guide our understanding of the molecular cascades that support good memory, as the activity of the KIBRA protein may influence mechanisms related to LTP. Could there be a link between KIBRA and age-related memory decline? One way to test this hypothesis was to find a way to manipulate part of the molecular circuit in which KIBRA is involved. Performing just such an experiment in collaboration with my lab, Matt Huentelman at the Translational Genomics Research Institute in Arizona identified a promising compound, hydroxyfasudil, a metabolite of a drug already approved for use in treatment of chest pain, or angina. As predicted, hydroxyfasudil improved spatial learning and working memory in aged rats.¹⁰The clinical applications of the drug’s effects on learning and memory are currently being explored.

David Sweatt at the University of Alabama at Birmingham also recently documented DNA methylation changes in response to learning, and was very interested in collaborating with us to determine whether changes in this epigenetic process during aging might explain our data on Arc expression, which is related to LTP formation and learning. Methylation of DNA typically downregulates transcription. After young and old rats performed exploratory behaviors that engaged the hippocampus, the methylation state of the Arc gene in hippocampal cells was, in fact, reduced in both age groups (which allowed more of the Arc mRNA to be transcribed). The difference between young and old animals was that certain cells of older animals, such as hippocampal granule cells, had higher overall methylation levels in the resting state, which resulted in production of less Arc protein during behavior, and the diminished ability to alter synapses via a mechanism such as LTP.¹¹ There are many complex facets of these data, but the results have led us and others to hypothesize that there may well be a number of epigenetic marks that accumulate during aging, and that epigenetic dysregulation may be a fundamental contributor to normal age-related cognitive decline. While the details of exactly how aging affects epigenetic modifications remain to be elucidated, it is at least a reasonable guess that understanding these mechanisms will be critical for future experimental designs aimed at optimizing cognition across the life span. Luckily, these processes are also amenable to pharmacological manipulation.

Aging in the future

Looking back on the rather grim expectations concerning memory and the elderly that were held only a few decades ago, the vision today is very different and much more positive. There are many who live to very old ages with minimal cognitive decline—and certainly no dementia. One particularly interesting study in this regard followed individuals who were 100 years of age (centenarians) at the beginning of the study until the time of their death, monitoring cognitive function and other factors in the “oldest old.” Interestingly, 73 percent of these centenarians were dementia free at the end of their lives (the oldest reaching an age of 111 years).¹² Watching the remarkable discoveries in biology over the past half century, one cannot help but look with excitement towards the next groundbreaking findings that are surely in the making. The future holds great promise for the once remote dream of understanding the core biological processes required for optimal cognitive health during aging—and progress in this regard should also provide the needed backdrop for understanding and preventing the complex neurological diseases that can be superimposed on the aging brain.

Carol Barnes is Director of the Evelyn F. McKnight Brain Institute and a Regents’ Professor of Psychology and Neurology at the University of Arizona.

This article is adapted from an upcoming review in F1000 Biology Reports. It will be available for citation at f1000.com/reports (open access).

References

1. C. A. Barnes, “Memory deficits associated with senescence: A neuro-physiological and behavioral study in the rat,” J Comp Physiol Psychol, 93:74-104, 1979. ↩
2. C. Norris et al., “Increased susceptibility to induction of long-term depression and long-term potentiation reversal during aging,” J Neurosci, 16:5382-92, 1996. ↩
3. J. O’Keefe, J. Dostrovsky, “The hippocampus as a spatial map: Preliminary evidence from unit activity in the freely-moving rat,” Brain Res, 34:171-75, 1971. ↩
4. C. Barnes et al., “Multistability of cognitive maps in the hippocampus of old rats,” Nature,388:272-75, 1997. ↩
5. C. Kentros et al., “Abolition of long-term stability of new hippocampal place cell maps by NMDA receptor blockade,” Science, 280:2121-26, 1998. ↩
6. J.F. Guzowski et al., “Environment-specific expression of the immediate-early gene Arc in hippocampal neuronal ensembles,” Nat Neurosci, 2:1120-24, 1999. ↩
7. S.A. Small et al., “Imaging correlates of brain function in monkeys and rats isolates a hippocampal subregion differentially vulnerable to aging,” PNAS, 101:7181-86, 2004. ↩
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