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SCIENCE FOCUS Issue 011, 2017 Evolution of the Tuskless Elephant The Story of Mankind We Need Our Nails to Grow, So Stop Biting Them! The Discovery of SCA40 with Prof. Ho-yin Chan SCA40 The Rhinovirus with Dr. Ellen Foxman

Contents Science Focus Issue 011, 2017 What s Happening in Hong Kong? A Virtual and Augmented Experience 1 Augmented Reality, Creativity and the Arts Save Orangutans at Hong Kong Ocean Park Science in History The Immortalised HeLa 2 Science Today Double Act 4 Evolution of the Tuskless Elephant 6 MVP of Space Travel 8 Unboiling An Egg 10 Amusing World of Science The Story of Mankind 12 A New State of Matter: Time Crystals 16 Could Australia Be Drifting Away So Fast 18 That GPS Can t Keep Up? We Need Our Nails to Grow, So Stop Biting Them! 20 Who s Who? The Discovery of SCA40 with Prof. Ho-yin Chan 22 The Rhinovirus with Dr. Ellen Foxman 24 Acknowledgements Message from the Editor-in-Chief Dear Readers, I hope everyone is getting some well-deserved vacation time this summer after a year of studying and examinations. This issue of Science Focus has particular emphasis on the roots of humanity and the history and science of our ancestors. Find out how our species fare in space and read about the science behind unboiling eggs. I would also like to use this platform to congratulate our newest Science Focus Article Submission Competition winner, Natalie Si Yeung Yu, of King George V School (Year 12), for her fascinating article on the science behind human finger nails. You can read her winning article on page 21. If you are interested in science and writing, send us your submission to our next Science Focus Article Competition for the potential to have your article published in our magazine and website, and an opportunity to win an Apple ipad Air. Visit our website for more details at http://sciencefocus.ust. hk. Enjoy the rest of the summer and don t forget to bring your copy of Science Focus to the beach! Yours faithfully, Prof. Yung Hou Wong Editor-in-Chief Scientific Advisors Prof Karen Chan Prof Tom Cheung Prof Daniel Lee Prof Pak Wo Leung Prof Ho Yi Mak Editor-in-Chief Prof. Yung Hou Wong Managing Editor Jing Zhao Student Editorial Board Editors January Lok Yi Cheung Long Him Cheung David Iu Thomas Lee Twinkle Ching Poon David Ren Reporter Teresa Ming Shan Fan Graphic Designers Rinaldi Gotama Steve Min Kyu Park Tommy Wong Copyright 2017 HKUST E-mail: sciencefocus@ust.hk Homepage: http://sciencefocus.ust.hk

WHAT S HAPPENING IN HONG KONG? This October, you have the opportunity to partake in Zürich Meets Hong Kong, where the two world-class cities join together to bring a week s worth of events and activities to different venues in Hong Kong. A Virtual and Augmented Experience You know those virtual reality headsets that are all the rage recently? Well, now you have a chance to experience the virtual reality of flying, animate your favourite cartoon characters, create art like a professional painter and more. Learn the science behind how virtual reality works and become part of the next generation of technology. Location: Hong Kong Science Museum Date: Wed 25 October 2017 Time: 7:00pm 9:00pm Augmented Reality, Creativity and the Arts Onto more augmented reality! Technology and art combined creates something beautiful. Join Bryan Chung Wai Ching, Assistant Professor at Hong Kong Baptist University, and Robert Sumner, Associate Director of Disney Research Zürich to experience technology and art together. Location: AAB201 Lecture Theatre, Hong Kong Baptist University Date: Mon 23 October 2017 Time: 5:00pm 7:00pm Save Orangutans at Hong Kong Ocean Park Hong Kong Ocean Park and Zoo Zürich Switzerland will work together to save our beloved and endangered orangutans. But how does conservation work? In a guided tour, find out the behind-the-scenes of keeping endangered animals in modern zoos. Location: Hong Kong Ocean Park Date: Tue 24 October 2017 Time: 10:00am 12:00pm Zürich Meets Hong Kong A Festival of Two Cities 1

Immortality may be far from possible, but some cells have been passed on for decades. Scientists call them immortalised cell lines for the simple fact that they can be grown for extended periods of time in a standardised laboratory setting. For many years, a number of immortalised cell lines were harvested from different tissues and species, revolutionising bioscience research on the study of gene function, toxin and medication testing, and the development of vaccines and antibodies. The first and most well-known human immortalised cell lines came from a cancer patient called Henrietta Lacks. While she was pregnant with her fifth child, Lacks complained of a knot sensation in her abdomen. After giving birth, Lacks suffered from a haemorrhage (or a ruptured blood vessel). The bleeding was later diagnosed to be caused by a malignant cervical tumour. Lacks died in 1951, but unbeknownst to her, the cancerous tissue samples removed by her surgeon were sent to Dr. George O. Gey, a cell biologist at the Johns Hopkins Hospital. He noticed that the cancerous tissues were unique in that they were able to divide indefinitely in vitro from a single cell, something that he had never seen in the laboratory before. This became the first line of human cells to be isolated and immortalised, now known as the HeLa cell line [1]. Normal human cells undergo a process called cellular senescence, where repeated divisions cause the genetic materials to age and become unstable. In a laboratory setting, this happens typically after around 50 cell divisions in healthy human cells. The mechanism is in place to prevent abnormal or faulty cells to self-destruct. However, cancer cells do not experience senescence and will continue to divide. In fact, HeLa cells are particularly aggressive and care had to be taken to prevent them from contaminating other cells. Since 1951, HeLa cells have made a significant impact in many areas of science and research. Image credit: European Molecular Biology Laboratory (EMBL)/Jonathan Landry Requests for HeLa were made by other researchers not long after Dr. Gey s publication, which gave rise to zillions of HeLa cells for scientific purposes. Since then, HeLa became a companion of researchers. Its impact on modern medicine is profound. For instance, the polio vaccine was tested on HeLa cells before going to human trial [1, 2]. Thereafter, HeLa became an instrument for studying the effects of viral infections for the invention of more vaccines. In the mid-1960s, HeLa was fused with mouse embryo cells to create the first References [1] Scherer, W. F., Syverton, J. T., Gey, G. O. Studies on the Propagation In Vitro of Poliomyelitis it Viruses. Journal of Experimental Medicine (1953). 97(5): 695-710. [2] Brownlee, K. A. Statistics of the 1954 Polio Vaccine Trials. Journal of the American Statistical Association (1955). Volume 50, Issue 272. [3] Harris, H., Miller, O. J., Klein, G., Worst, P., Tachibana, ana, T. Suppression of Malignancy by Cell l Fusion. Nature (1969). DOI: 10.1038/223363a0 [4] Schulman, A. N. What is the Body Worth? The New Atlantis (2012). Retrieved from http:// www.thenewatlantis.com/publications/what-is-the-body-worth -the-bod [5] Jones, B. How Henrietta Lacks Cells Fueled Medical Breakthroughs. roughs. USA Today. Retrieved from https://usatoday30.usatoday.com/news/health/2010-03-09-

cell hybrid, which helped researchers in mapping the human genome [3]. At present, HeLa has been widely used in virus and cancer research, medical diagnostics, and toxicology. It was also the first human cell line to be taken to outer space, where it divided just as fiercely as it did on Earth [4]. Sadly, Lacks never had the chance to give consent fo r he r cel l s to be used fo r med ica l y was not informed research. Furthermore, her family of further application until researchers tried to contact them to find out why HeLa cells were so aggressive in their replication, to the extent of contaminating other samples [5]. While the use of HeLa cells has raised numerous ethical concerns, it is undoubtable t h a t i t s ex i s te n ce h a s saved millions of lives for decades. ガ䙫ガ㲨 Ə憒䔆兒䘋㨊㜓ẋ䵍䳫俗ň更㙕憸㖖憒晉䙫㲢ň 咲ự 咲ự 㘖䴗僅䔆䉐 Ə䕀ヶ怀䘳䴫主凮 Ə䴗僅 Ọ 檻䄈昷墩 ẽ 㜑樾奲怵怀㨊䙫䴗僅Ə䨘Ḳ䂡 +H/DƏ㘖䬓㠑曉檻乳棱䙫ạ桅䴗僅䳢 > @ 㭊䙫ạ桅䴗僅䵺㭞䴗僅塗俨怵䧲Ə 䂡憴壮墩㛪凛恡ₚ䉐峑䩐樾 ḔƏ䴗僅塗俨态䙣䔆䳫㬈䴗僅墩Ḳ 怀㩆㩆 Ọ Ọ孺䕗䕗ㇽ㛰伡滅䙫䴗㬈䴗僅墩Ḳ 怀㩆 Ọ孺䕗ㇽ㛰伡滅䙫䴗僅凑㮧怵怵Ə䘳 Ə䘳䴗僅䴗僅㛪俨俨 Əḍ ḍ 㛪㛪乳怵Ə䘳䴗僅㛪俨 ḍ 㛪乳墩墩 + +H/ H/D D 䴗僅䳢Ⰻ⅝ ᾜ䕌䴗䴗僅䳢Ⰻ⅝ ⅝ ᾜ ᾜ䕌䕌 Ə奨嘼䏭Ə 墩 +H/D җҡ ಠफ 㰟 ℴ 㱈㞺㱈㞺⅝ ⅝ 䴗僅䴗僅 ℴ 㱈㞺⅝ 䴗僅咲ự 咲䙫䟻䩝ㇷ㞃䈯 Ə榓㛰㛰䦸咲ự 䙫䟻䩝ㇷ㞃䈯 Ə榓㛰䦸㰩㨊㜓Ə䴷㞃㛰䄈㕟㕟 +H/D + D 䴗僅䔏㖣䦸䴗㖣 HeLa 䔆ㇽ娘㘖恀䔆䔆ㇽ娘㘖㘖恀 ƏἭ㛰Ẃ䴗 Ẃ䴗僅僅 ⷙ ⷙ㴨ₚṭ㕟廰Ə䦸䨘Ḳ ƏἭ㛰Ẃ䴗僅 ⷙ㴨ₚṭ㕟廰Ə䦸䨘Ḳ 䂡㰟䔆䂡㰟䔆䴗僅䳢Ə 䂡 Ὸ Ọ 㨀㹽㹽䙫䙫樾樾䂡㰟䔆䴗僅䳢Ə 䂡 Ὸ Ọ 㨀㹽䙫樾䒗 Ḕ敞㜆䔆敞 ὭƏ䦸䴫䒗 Ḕ敞㜆䔆敞 Ὥ ὭƏ䦸 Ə䦸䴫䴫主⑳䉐䨕䍙㠑㰟䔆䴗僅䳢Ə䂡䟻主⑳䉐䨕䍙㠑㠑㰟䔆㰟䔆䴗僅䴗僅䳢䳢Ə䂡䂡䟻䟻䩝㮹䴇⑳嗌䉐㪉㸓 Ọ 䖒劾⑳ 檻䙫䩝㮹䴇䴇⑳嗌 ⑳嗌䉐㪉䉐㪉㸓㸓 Ọ 䖒劾⑳ 檻䙫檻䙫敲䙣敲 Ə Ə Ὥ材⑤ 䙫孱楽㠑Ṇ㘖楽㠑 Ṇ㘖㛧㛰㛧㛰䙫ạ桅㰟䔆䴗楽㠑Ṇ㘖㛧㛰䙫ạ桅㰟䔆䴗僅䳢僅䳢Ὥ凑䘳䖮り俬㵞䑅 ň Ⅎ㖖䕝㛰䬓ṻῲ 㘩Əㄆ兠惏㛰兒 ƞ䔉堧㘩Əㄆ兠惏㛰兒 ƞ ƞ䔉䔉堧堧䮈䠛墩堧Ə娡㖞 Ə 㖞㘖栟栟䮈䠛墩堧 Ə娡㖞㘖栟ト凛ト兒䘋㈧䘋㈧凛 Ⅎ 㖖䟌怄䟌䟌䟻 +H/D 㭋ㇷ䂡䟻䩝䙫 ἛƏ 䏥㭋ㇷ䂡䟻䩝䙫㭋䙫 Ἓ ἛƏ Ə 䏥 Ị憒 Ị憒㛰㛰㷘恇㷘恇柦柦 ὲ Ɲ僱 Ɲ僱檺䁗檺䁗峑峑 Ị憒㛰㷘恇柦 Ɲ僱檺䁗峑䁵䖒劾ᾦ 劾ᾦ㘖ℯ 㘖ℯ䔏䔏 +H/ + H/D D 䴗僅㸓婍Ə 䁵䖒劾ᾦ㘖ℯ䔏 +H/D 䄝䄝 ạ ạ檻ὃ婍樾 > @ ⅝ Ə 䄝 ạ檻ὃ婍樾 + H/D 䔏㖣䟻䩝䖬㮹ㄆ㞺Ə敲䙣 +H/D 㛛䖒劾凚䳧 ỊḔ㜆Ə ỊḔ ỊḔ㜆Ə 㜆Ə 䦸 +H/D 凮漇漇僁債僁債䴗僅䴗僅坴坴 Ə 凮漇僁債䴗僅坴䬓 ῲ曃ẋ䴗僅䴗僅Ə怀 ạ ạ桅䴫孃䙫乑乑䬓 ῲ曃ẋ䴗僅Ə怀 ạ桅䴫孃䙫乑壤㛰 > @ 䛕 > @ @ 䛕䛕 Ə+H/D Ə+H/D Ə+H / 㳂ㆰ䔏㖣䖬㮹⑳ 㳂ㆰ䔏㳂 ㆰ䔏㖣䖬㖣䖬㮹⑳ 㮹⑳ 壤㛰䘳䖮䖮䟻䩝䟻䩝憒憒娡㖞⑳ 㖞⑳㮹䏭㮹䏭䙫㘖Ə 䙫㘖Ə 䘳䖮䟻䩝憒娡㖞⑳㮹䏭 +H H/D D 㘖䬓㠑忨䩡䙫ạ桅䴗僅䳢ƞ 㘖䬓䬓㠑㠑忨忨䩡䩡䙫ạ ạ桅䴗僅䳢ƞ +H/D 䩡巆巆䏪䏪㨊㨊ƏṆ僤 Ṇ 僤䨴㥜怙堳墩 > @ 䩡巆䏪㨊 Ṇ僤䨴㥜怙堳墩ッƏ Ⅎ㖖㜑㛰㩆㛪ヶ ᾂ䴗 ᾂ䴗僅ὃ 僅ὃ憒憒䟻 Ə Ⅎ㖖㜑㛰㩆㛪ヶ ᾂ䴗僅ὃ憒䟻䩝䙫 ạ Ḳ 䙫ㆰ䔏Ṇ㘖䟌䟌ガƏ䛛䟻䩝䟻䩝䩝䙫 ạ Ḳ 䙫ㆰ䔏Ṇ㘖䟌ガƏ 䛛䟻䩝 ẽὸə 㜂ṭ ṭ姊 +H/D +H/D +H/ D 䴗僅䂡Ἴ僤㭋䨴㥜䴗䂡Ἴ僤䴗僅䂡㭋䨴㭋䨴㥜 ẽὸə 㜂ṭ姊壮 Ə䔁䔁凚凚 Ọ㱈㞺⅝ ⅝ 㨊㨊㜓㜓 > @ >> @ +H/D @ +H/ H/D D 䴗僅䙫ㆰ䔏䴗僅䙫ㆰ䔏䴗僅壮 Ə䔁凚 Ọ㱈㞺⅝ 㨊㜓姟䙣姟䙣娘娘䏭䏭字栳字 ƏἭ Ἥ㯒䄈䕸 Ə 怵㕟怀Ẃ 姟䙣娘䏭字栳ƏἭ㯒䄈䕸 Ə 怵㕟怀Ẃ 䴗僅㔸㔸ṭ㕟 ṭ㕟ọ䙥 Ọ䙥吓ạ 吓ạ䙫䔆⑤ 䴗僅㔸ṭ㕟Ọ䙥吓ạ䙫䔆⑤ The Immortalised HeLa By Thomas Lee 㘌㰧宠 3

Double Act Mankind s yearning to acquire knowledge of the vast unknown spaces of the universe has been a mission stretching back to antiquity. And when Earth inevitably succumbs to the test of time, it is to the great unknown we hold our hopes of survival. While we dream of grand interstellar voyages and the ultimate conquest of nature, understanding how our biology reacts to space travel is essential. Does the arduous task of space travel and zero gravity take a toll on our bodies? In an attempt to further understand the effects of space travel on the human body, the National Aeronautics and Space Administration (NASA) initiated the Twins Study a major research project encompassing ten separate researchers from diverse backgrounds, featuring multi-faceted collaboration between academia, government and industry. This unprecedented project took Scott Kelly, a NASA astronaut, on an orbital journey between April 2015 and March 2016, while his twin brother Mark Kelly stayed on Earth for a ground-based control subject. Identical twins share nearly 100% of their genome, making them close to perfect test subjects for genetic and epigenetic research. Whether the stressors caused by zero gravity or other external stimuli from space travel trigger epigenetic changes will be more apparent with an exact genetic copy to compare to. The researchers were thus able to document any unique biological changes between Scott and Mark as a response of being in space. In addition, the 340 day-long investigation incorporated exciting new techniques from an array of emerging fields. For instance, genetic sequencing was employed in the establishment of individual molecular profiles, contributing to the development of personalised medicine. Preliminary results were released during the Human Research Programme Investigators Workshop in January 2017 and revealed several intriguing physiological phenomena as a result of Scott s stay at the International Space Station. Measurements before, during and after demonstrated notable divergences in DNA structure and gene expression patterns. One structure that showed change was telomeres. Protective sequences of repetitive DNA situated at the ends of chromosomes, telomere shortening is a hallmark of aging and age-related diseases. While in space, the length of Scott s telomeres increased, but eventually dropped back to his pre-flight levels after he returned to Earth. The implications of these results are still yet to be determined. Meanwhile, changes in the gene-expression signatures were reported. Where such changes are associated with the ever-shifting environmental factors, like diet and sleep pattern, the changes in Scott seemed more pronounced than expected, prompting the question of whether there may be the activation of a space gene. It has, however, been hypothesised hesised that gene expression could be affected by diet. T h e challenge now is to untangle how many of the observed ed changes are specific to the physical demands of spaceflight and how many might be simply due to natural variations. And because the Kelly twins are just NASA astronaut Scott Kelly

By David Iu two people, the results may not be generalised to others. For the most part, the jury s still out, and exactly how the stress of space travel leads to such changes remains to be delineated. As NASA eloquently put it, Each investigation is like an instrument. On its own, it plays solo music. But put them all together and you have something incredible. Further results are expected to be published later this year, while integrated theme papers are due in 2018. Witze, A. Astronaut twin study hints at stress of space travel. Nature (2017). Retrieved from http://www. nature.com/news/astronaut-twin-study-hints-atstress-of-space-travel-1.21380 Identical twin brother Mark Kelly 5

Elephants are often associated with their tusks. But these majestic biological structures are both a blessing and a curse. Highly sought for its ivory and poached to the point of endangerment, the number of African elephants born without tusks or born with smaller tusks has been increasing at an alarming rate, suggesting a selection disfavouring tusks. The largest elephants typically bear the largest tusks, and in general, tusks grow as the elephant ages. Male African elephant tusks can grow up to seven times the weight of female elephant tusks [1]. Due to the fact that poachers tend to go after elephants with the largest tusks, male elephants are particularly targeted at their reproductive prime. Many of these elephants are therefore taken out of the population and can no longer pass on their genes related to the development of large tusks. Even if there are younger elephants that carry the genes for large tusks toward the line, either they are not ready to breed or their mating success is relatively low due to their smaller sizes. Poachers are artificially selecting for tuskless elephants, by eliminating large tusks from the gene pool. Accelerated evolution of the tuskless elephant is not isolated in the African elephant alone. In fact, studies have documented that even female elephants with no tusks have increased from 10.5% to 38.2% between 1969 and 1989 during the time when poaching was heaviest. In most elephant populations, a normal percentage of elephants born tuskless is anywhere between 3% to 4%, but by 1989, one National Park reported the tuskless elephant population to be between an alarming 9% and 25%. The purpose of the elephant tusk is more farreaching than an aesthetic feature. Tusks are specialised teeth that continue growing throughout an elephant s life. If a tusk is broken off due to natural circumstances, the tusk will keep growing, unless the root of the tusk is exposed, which leaves the elephant to a very slow and painful death. Elephants use their tusks to fight, dig or move things. They also have the function of protecting the trunk of the elephant when they charge and defending an elephant from predators, which increases its survivability. There is also the fact that female elephants prefer to mate with male elephants with tusks. Reduced mating could affect long term population size. Despite the fact that the international ivory trade has been banned since 1989, illegal elephant poaching and ivory trafficking still run rampant in certain countries that lack the resources to battle poachers. Some surveys demonstrate that between 2007 and 2014, as many as 144 000 elephants were killed for their ivory [2]. Much of the demand of ivory stems from the nouveau-riche in Asian countries, who view owning items made of ivory as status symbols. Eliminating poaching entirely would require education and a collective global effort, but it is crucial to the survivability of elephants as a species and to prevent a tragic ending to these intelligent, social creatures. References [1] Garrigan, K. Going Tuskless. African Wildlife Foundation. Retrieved from https://www.awf. org/blog/going-tuskless [2] Morell, V. Recently Killed Elephants Are Fueling the Ivory Trade. Science (2016) Retrieved from http://www.sciencemag.org/ news/2016/11/recently-killed-elephants-arefueling-ivory-trade

Evolution of the Tuskless Elephant This article may be useful as supplementary reading for biology classes, based on the DSE syllabus. By January Lok Yi Cheung 7

Extinction the end of a species of biological organisms. An estimated five billion species that have ever existed on Earth are believed to be extinct. It happens for a variety of reasons, sometimes due to human interference, but also due to unforeseen natural circumstances. It can be marked by the death of the last organism of the species, but equally importantly is the quantity of the Minimum Viable Population (or MVP), denoting the smallest size of a population required to avoid extinction for a certain period of time [1]. Extinction of a species is a common event that is currently estimated to occur at a rate of one species per year. One of the factors that lead to a species demise is stochastic perturbation, or random deviation of a system. These could be natural disasters for instance. An example of stochastic perturbation is in the extinction of the heath hen (Tympanuchus cupido cupido) [2]. Following a steady decline of the heath hen population during the early 1900s, conservation efforts rebounded the birds population to about 800 by 1916. In the summer of that year, a forest fire destroyed their nests and habitat, compounded by unusually high predation. These two random factors dramatically reduced the population to 100-150 birds. Then, in 1920, a disease outbreak caused the population to dip below 100. By 1932, the last heath hen was gone. A species cannot hold off extinction once its population goes below its MVP. With a stable population around or above its designated MVP, a species is thought to be able to ward off stochastic pertubations. What about humans? By some counts, there were only 10 000 of us at one point in time [3], but being the resilient species that we are, we have now rebounded to around 7.5 billion and growing. With limited resources on Earth, the question is what is the MVP we need for sustained space travel? According to University of Florida s Dr. John Moore, the number is 160 [4]. He obtained this number through a series of computer modelling he ran in 2002, setting the space travel period to 200 years and around 8 to 10 generations long. In fact, this model still held when extrapolated for 60 to 80 generations or approximately 2000 years. While that sounds low, history speaks otherwise. Clans of hunter gatherers, villages in pre-industrial societies and infantry groups in armies have been wellmaintained by 150 to 180 people [5]. However, a more recent study by anthropologist Cameron Smith, reported a minimum of 10 000 people would be needed to weed out inbreeding and maintain genetic diversity. He mapped out the trajectories of five starting populations (150, 500, 2 000, 10 000 and 40 000) in their percent of genetic variation io against the number of years, demonstrating that with a starting population of 150 people, inbreeding ng would cause a loss of over 80% of genetic diversity for a given hypothetical gene over 200 years. A starting population of 10 000 or more showed a high percent of variation, at close to 100% over at least 200 years. With 10 000, 0, Smith says, you can set off with good od amount of human genetic diversity, survive even a bad disease sweep, ep, and arrive in numbers, perhaps, and diversity sufficient ie to make a good go at Humanity 2.0. [6] MVP of By Rinaldi Gotama

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By Twinkle Poon Boiling an egg is a chemical change that uses heat to permanently alter the proteins in an egg in a process called denaturing. In this process, chemical bonds are broken and new ones are formed, causing chains of proteins to unfold and reset. Unlike physical changes, most chemical changes are difficult to reverse, but for the first time, international chemists have cracked the challenge of unboiling an egg or really, folding protein. Proteins are made up of long chains of amino acids and have a variety of essential functions within living organisms. DNA replication, molecule transportation and various metabolic reactions are all processes that rely on proteins. Folding proteins are important to many industries, from chemical reactions to medical research, but is a difficult process because proteins come out tangled. The same thing happens when an egg is boiled. Gregory Weiss, a researcher at the University of California at Irvine and his team set out to untangle and fold the proteins of a boiled egg back into that of an unboiled egg. They separated the yolk from the egg white and boiled the latter for 20 minutes at 90 degrees Celsius to allow the proteins to become tangled clumps. The physical manifestation of the tangled proteins is the hard and solid appearance of the egg white. The chemists then added urea, the primary component of urine, to break down the proteins and rearrange them into liquid egg white form using a specialised machine known as the vortex fluid device. The device is key, as it uses the shear forces of stress to separate the entangled proteins and allow them to refold. Weiss initially happened upon the vortex fluid device while visiting Australia s Flinders University. The device was designed for intricate chemical reactions, where molecules les are placed in a liquid to be spun in test tubes. The centripetal forces from spinning these test tubes are then applied to molecules in a controlled manner. Weiss realised that the same thing could be applied to tangled proteins when he saw that the device was able to separate molecularlythin graphene from a block of graphite. But while one of the main proteins that make up egg white lysozyme refolded d nicely using this technique, different proteins have different shapes and not all behave the same way, calling for an investigation of the procedures required for each type of protein. Researchers discovered that a protein produced by E. coli for instance would not refold. To encourage folding, they locked down one end of the protein to a bead, similar to that of a weight, reproducing the natural way of folding for the protein. Aside from being a fun science experiment, the effort has noble goals. To begin with, this discovery has the potential to minimise the cost of cancer treatment. Pharmaceutical companies typically create cancer-associated proteins by cultivating them inside ide costly hamster ovary cells, because this method prevents manufactured proteins from misfolding into undesired shapes during formation. Possessing a method to re-mold proteins from common E. coli bacteria or yeast could cut down costs of cancer research substantially by circumventing the need to cultivate proteins in the aforementioned ed method. In addition, the traditional path of salvaging protein is lengthy, whilst unboiling ng an egg only takes a few minutes.

Further Reading Lewin, S. Unboiled Egg Untangles a Knotty Protein Problem. Scientific American (2015). Retrieved from https:// www.scientificamerican.com/article/unboiled-egg-untangles-a-knotty-protein-problem/ 11

From a valley in Tanzania came a longarmed, hairy, ape-like creature whose genus would one day spread across the world. Homo habilis, or Handy Man, marks a bold step forward for the evolution of modern Homo sapien. Their brain capacity of 550cm 3 to 687cm 3 [1] was far larger than that of their predecessors. Improved cranial capacity lent credence to their name, especially since Homo habilis are thought to have mastered simple stone tools to butcher and skin animals [2]. Homo habilis continued to thrive in previously uninhabitable territory until they disappeared around 1.8 million years ago. one knows whether a vehicle ever came to haul away the discoveries, but if it did, no one knows where the vehicle went. However, the Peking Man was photographed meticulously, leaving behind a detailed description of late Homo erectus. He was far heavier in build than early Homo erectus, a sign of evolutionary adaption to colder climates. During the same time period, a new species named Homo erectus became anatomically distinct to Homo habilis. Perhaps due to changing environments, Homo erectus developed shorter arms that allowed for easier upright walking. Their larger skulls (800 cm 3 ) and less robust skeleton suggested that Homo erectus depended on wit rather than brute strength. It was Homo erectus that first made the journey out of Africa. In around one million years, they spread into Europe, the Middle East and Asia. The reason why early man left Africa is still disputed. Some suggest the population size approached the woodland carrying capacity (maximum population size that an environment can support indefinitely). Exploration of the savannah offered opportunities for a few. These few would evolve over time to become better suited toward traversing the open ground and so would Homo erectus. What is indisputable is how widely spread the ape-men lived: from Africa to eastern Asia, skeletal remains of Homo erectus exist. One famous example is the 750 000 year-old Peking Man, found near Beijing. The excavation site became a battlefield as the Japanese invaded, so it was decided that all archaeological discoveries should be shipped away to New York for safety. No This article may be useful as supplementary reading for chemistry classes, based on the DSE syllabus. Dating archaeological artifacts proves rather difficult. It was not until the discovery of carbon dating could archaeological finds be dated accurately. The technique relies on a radioisotope of carbon C14. Living matter contains a mixture of

By David Ren References [1] Brown, G., Fairfax, S., Soarao, N. Human Evolution. Tree of Life (Web Project) (2006). Retrieved from http://tolweb.org/ treehouses/?treehouse_id=3710 [2] Pobiner, B. The First Butchers. Sapiens (2016). Retrieved from http://www.sapiens.org/evolution/homo-sapiens-and-tool-making/ 13

C12 (carbon s most abundant and stable isotope) and C14, but C14 radioactively decays after the organism expires. A neutron in the carbon nucleus will convert into a proton after releasing a beta particle (electron) and an antineutrino, resulting in an N14 atom. By using a Geiger counter to measure the beta decay activity of an organic matter sample, it becomes possible to date the sample. To verify the validity of this method, peat trapped under glacier was carbon dated. Since it was known that the glacier formed during the last ice age, the accuracy of carbon dating was confirmed. To understand whether Homo erectus could communicate in a recognisably modern way, carbon dating is not sufficient. An excavation on the island of Flores in Indonesia revealed an adult skeleton no more than 106 cm tall. Initially, the specimen was declared to be Sundathropus floresianus but the relatively large size of its skull compared with its height convinced researchers to classify it as Homo floresiensis. It seemed that Homo erectus had managed to reach Flores and lost height to become Homo floresiensis [3]. The island of Flores lies east of the Wallace line that marks the faunal ecospheres of South Asia and Australia. For most of history, the Wallace islands have been difficult to reach by land. For this reason, the evolutionary development of fauna only kilometres apart are vastly different [4]. The presence of humans east of the Wallace line 800 000 years ago suggests a great degree of cooperation and complex communication. Indeed, stone tools have been found on the island of Crete estimated to be 130 000 years old and on Flores since 800 000 years ago [5]. The loss of Flores Man s height is a surprisingly common occurrence for large animals confined to small environments. Smaller hominids require less food, have shorter gestation periods and have improved thermoregulation in tropical climates. The dodo experienced the reverse phenomenon gigantism. Upon first arriving on Mauritius, the dodo was approximately the size of a pigeon. But after centuries without natural predators, the dodo grew larger; until it grew so large it lost its ability to fly [6]. Far away in sub-saharan Africa, a distinctly modern ape-man was emerging. The new species, appearing approximately 150 000 years ago, displayed flatter faces, less muscular limbs and larger neural canals than Homo erectus or its predecessors. The developments reflected a preference for bipedalism and a greater capacity for communication. Two ice ages between 190 000 and 90 000 BCE pushed humanity to its limits. The dearth of fossil records during this period attest to the harshness of the environment. Some estimate that there were only 20 000 Homo sapiens alive in 100 000 BCE on the planet [7]. Adverse conditions encouraged genetic mutations to flourish, particularly those favouring higher intelligence. When climate conditions settled, humans with those genetic mutations were able to out-compete other ape-men. As the human homelands struggled with an increase in population, people migrated out of Africa via the land bridge at Somalia into the Middle East. Civilisation began soon after the end of the last Ice Age at around 13 000 BCE. Within the lucky latitudes, hunter-gatherers were able to begin to leverage a warmer planet. No place was better suited than the Hilly Flanks, incorporating the Tigris, Euphrates and Jordan Valleys in the Middle East. Desperate and hungry, people had deposited seeds into fertile soil and stayed year-round to ensure they grew into healthy crops. Humanity spread to every corner of the globe in a relatively short period of time, overcoming multiple ice ages on the way. We have demonstrated our ability to adapt to new challenges like no other creature due to complex communication, cooperation and intelligence and we continue to show this spirit as the challenges of the 21 st century loom overhead.

Ϡ ߞ ڰ 怵Ə奨䟌怺䛛䪲ạ㘖 ㆩ 䔏䏥Ị㖠㲼㺄态Ə 杇䢚怵怵Ə奨怵Ə奨奨䟌怺䟌怺䛛䪲䛛䪲䛛䪲䪲ạ㘖 ạ㘖 ạ 㘖 ㆩ ㆩ 䔏䔏䏥Ị 䔏䏥Ị㖠㲼䏥Ị Ị㖠㲼㖠㲼㺄态㺄态Ə Ə 杇䢚杇䢚䢚恀恀恇䙫恇䙫㑹㑹㑹 Ọ Ọ Ọ 䙫杅㴙䙫䙫杅杅㴙㴙㴙 Ə⅞ ⅞㛰㗵㛰㗵桖桖䏥䏥Ị Ị䌦䌦䌦ạ䉠 ạ䉠 ạ 䉠恀恇䙫㑹 Ọ 䙫杅㴙 Ə⅞㛰㗵桖䏥Ị䌦ạ䉠堺㘖嶚䙫 Ⱓ奦ẅ䙫㴂㖖ⳝ 䙣 ṭ 䙫䉐䨕ⴂ嵞 ẽὸ 䏥䳫吓 Ə凮䛛䪲ạㇽ ⅞庒檿嶚䱚䙫ㇷạ檟檏㛧 Ə怀ῲ㨀㜓墒媋 ạ䛟㮻ə杉惏弑廪 Ə 傉偳偰廪 Ə䥅䵺䮈廪䱾怀䂡䍏䪲ạ䨕 6XQGDQWKURSXV IORUHVLDQXV Ἥ㘖凮⅝檿䛟䨕䨕䉠桖䤡ẽῸ Ọ曀嶚㭌堳Ə㺄态僤㛛奦K 㮻Ə桘檏桖 Ə㈧Ọ䟻䩝ạ 憴㖗 ẽ 桅䂡 ὂ佬㖖吓凚吓 Ḳ敺䙫⅐㬈㲚㜆Ə ạ桅㥜昷怀 ạ 䛲Ὥ䛛䪲ạ㛥䵺总㴂曞㖖ƏḲ 孱䟕俳ㇷ䂡ὂ 㮜㘩㜆䕀䙫䟚姿拫䧧 Ə嶚嬰䕝㘩䒗ト姯奦佬㖖ạ > @ K 吓 Ə 䏪䙫ạ > @ ト䙫䒗 ₓ ṭ 䩨孱ƏⰋ⅝㘖䔉䔆檿㙡 ạ桅㰊 ⑳ 㴂㖖ⳝἴ㖣 ẅ⑳㾚 ẅ 䉐䔆ㄲ 䙫取叱㝘杉敞ḬỌὭƏ取叱 ⅐ 䙫例ⳝ曊㖣晟巖㘩Ə怀Ẃ㔃恡ₚ孱䕗䙫ạ桅㶿㱗ṭ⅝ẽ䌦ạ 暏吾惰ạ ƏạῸ 杅㴙䵺怵䴉榓憳晟㨲䧢Ⱜ Ḕ㝘总Ə 㭋䛟巄㛰㕟 ⅓憳䙫䉐例ƏṆ㛪䵺㭞㨊䙫㻻怵䧲 > @ Ἥạ桅㗐吓 ᾦ 取叱㝘䕀奦K Ə㛧㬈㲚㜆䴷㝆Əạ桅㕮㗵㖲幋 Ə䔘㭋塏䏥檿䙫 ὃ⑳壮曃䙫㺄态僤 Ⅎ憳䉠敲怲 ḔƏ 䍜俬 Ọ敲怲䔏䏪㙽 ⳝ⑳ 㴂㖖ⳝ 䙫䟚 ⷌ⅞Ə 姯㛰吓 ⑳ ㈧ Ὥ䙫岮㹷㻀偁ṭḔ㝘䙫㠣憳㖖㲚Ə 䙣㲚⑳䳫吓䙫㭞 > @ 㗍㲚尞䙫晜⅐俣 Ə㛛㘖 ᾂṭ Ⱜ㧩䩿忒棉棺䙫ạ侊䨕㑹傌㱪䙫 ḔƏ ὂ佬㖖ạ䙫庒檿孱䟕Ə 䋠䒗䔆㴢䙫䉐䵺㕛 Ọ䢡ῄὃ䉐ㇷ敞㛪䏥怀䨕䏥屈庒廪䙫 ạ桅曧奨廪䙫棆䉐Ə 㛰廪䟔䙫㜆Ə 䆘㰊 Ḕ㛛僤㛰㔯媦䮧檻㺒㸈㸈 ạ桅ⅎ㛴ṭ 㬈㲚㜆Ə 䛟䟔䙫㘩敺ⅎ㓛㕊䔳泌䵺㭞ṭ䛟䙫怵䧲㸈㸈泌总㯂憳㰩㖖㘩Ə ῲ妹吤ㇸῸ 壮曃䙫㺄态僤 ㆩ ṹ䛟 ὃə俳㒨庒巆洦 ⷕ ƏἭ䔘㖣伡Ḷ 㕜Ə嵱敞嵱 Ə䔁凚 ṭ 㛰檿㙡ㅎƏ㈧Ọ㮻䙫䔆䉐㛛僤ㆰ 㖗杉棂堳䙫僤 > @ 䳧㈧ Ὥ䙫䨕䨕㘩ƏㇸῸṆ僤㗉 Ə徵曊俳 References 仁宅㑗 [3] Brown, P., Sutikna, Morwood, M. J., Soejono, R. P., Jatmiko, E., Saptomo, W., Due, R. A. A New Small-Bodied Hominin From the Late Pleistocene of Flores, Indonesia. Nature (2004). DOI: 10.1038/nature02999 [4] Smithsonian National Museum of Natural History. Hobbits on Flores, Indonesia (2016). Retrieved from http://humanorigins.si.edu/ research/asian-research-projects/hobbits-flores-indonesia [5] Bower, B. Hominids Went Out of Africa On Rafts. Wired (2010). Retrieved from https://www.wired.com/2010/01/ancient-seafarers/ [6] Tyson, P. Gigantism & Dwarfism On Islands. PBS (2008). Retrieved from http://www.pbs.org/wgbh/nova/evolution/gigantism-anddwarfism-islands.html [7] Morris, I. Why the West Rules For Now: The Patterns of History and What They Reveal About the Future (2011). Retrieved from https:// books.google.co.uk/books?id=bmi1xvxal48c&pg=pa3&source=gbs_toc_r&cad=3#v=onepage&q&f=false 15

Crystals, microscopically arranged in a highly ordered fashion of molecules, are common solid structures of many compounds and elements. The crystal s structure is distinguished by its unit cell, which consists of at least one atom within an imaginary cube, repeated and stacked in three-dimensional space in any direction. Snowflakes, for instance, are typically a single crystal or a conglomerate of several crystals. Solid sodium chloride, or more commonly known as table salt, is another example of a common crystal. Or perhaps most iconic is the giant covalent network of diamond. These tangible structures are easy to grasp, because they exist in space. Yet, in 2012, the same idea of a repeated structural unit in time was proposed by Nobel laureate Frank Wilczek, known as a time crystal. These abstract structures would pulse without the need of energy input. Instead of a repeating unit of molecules that extend in all directions of a crystal lattice in space, a time crystal would theoretically consist A New State of Matter: By Long Him Cheung

of a pattern that repeats in time, akin to a clock that ticks forever without being wound. [1] Furthermore, unlike a wave s periodic oscillations, time crystal oscillations would be intrinsic, whereas wave patterns demand a driving force. Wilczek s proposition to physically manifest this abstruse idea was met with several challenges. Most fundamentally, the idea that a pulse could oscillate perpetually without initial energy input seems to defy the laws of thermodynamics. Symmetry in physics, for instance, means that the laws apply to all points in space and time, yet there are exceptions to the rules. At the ground state or its lowest energy level, a magnet will fall toward either north or south that is they are asymmetrical since they look different on both sides. Crystals in space are also asymmetrical at their ground states, and do not look the same on all sides. However, regardless of symmetry, crystals in their ground states do not move unless given energy because by definition, that is where something is at its most stable state. Objects with asymmetry across time instead of space would then be considered as time crystals. The notion is counterintuitive because it is analogous to an object in its ground state moving around without added energy. For example, if one were to drop a marble in a bowl, the marble should intuitively come to an eventual rest, but instead the marble continues to roll around perpetually. However, scientists from the University of Maryland and Harvard reported to have independently created time crystals, except neither party s time crystals fit the definition of what Wilczek initially proposed. Alternating lasers were fired at a chain of ytterbium ions so that the chains are constantly oscillating in random directions. What was significant was that even after the frequency of the initiations were changed, the oscillation did not change. Crystals in space are likewise stable to changes to their repeated structures. There is still some debate as to whether this type of system is a time crystal as it fulfills time asymmetry but still requires some type of energy input to begin with. Scientists believe that the stability from these systems may have applications in quantum computing. Time Crystals 㛧㠠㜓䙫栳㘖Ɲ 㱹㛰弟僤憶䙫ガ㲨 Ə㰟恇憴壮䙫㨈 ἣḵ怼傳ṭ䆘㖣䉐䏭 Ḕ䙫䨘 Ə怀Ẃ ㆰ 恐䔏㖣䩡敺⑳㘩敺䙫㮶滅Ə 怵Ṇ㛰ὲ 䢨搜 ㄲㇽ㛧ἵ僤憶䙫䊧ㄲ㘩Ə㛪ㇽ㖠 Ə㈧Ọ⅐恱䛲Ὥ 㨊ƏṆⰘ㘖䨘嘼㖣 ㄲ䙫䩡敺㙝檻㨊㘖䨘䙫Ə 㖠妧䙫婘㛪䛲䙫杉屳䄝俳Ə䄈媽䨘凮 Ə晋杅嶚僤憶Ə嘼㖣 ㄲ䙫㙝檻惤㛪䧢 Ə 䂡 ㄲⰘ㘖㛧䩐䙫䊧ㄲ 㘩敺俳杅䩡敺Ḕ㒨㛰䨘䙫䉐檻Ə Ọ墒好䂡㘩敺㙝檻怀ῲ㥩凮䏭傳怺俳榚Ə 䂡怀ヶ吾嘼㖣 ㄲ䙫䉐檻Ə Ọ 㱹㛰僤憶䙫ガ㲨䧢 ƞ䬰媑Ḇ怙䡾ⅎ䙫栭㳉㖞㻥 Ə 㛪ざ䡾䄝䄝俳㓁 Ə 榓憳嘔 ⑳ ὂ 䙫䟻䩝晱ⷙ 壤怇ṭ㘩敺㙝檻Ə 㘖曀㖠䙫ㇷ㞃惤㜑僤䬍枲䈥 Ⅎ㛧 Ⅎ ㈧㈧䈥 Ⅎ㛧㈧䙫侐䦸 Ọ㾧ℰẋ㛦㒱䔘搦曉㦲䙫掯㢄Ə孺搦曉掯暏㩆㖠㖞啐憴滅㘖 ὦ㔠孱 ṭ僯塄䙫栢䍮ə搦曉䙫栢䍮Ṇ僤ῄ 孱怀Ⱈ巆䩡敺㙝檻㨊 Ọ䶔䩐䙫憴壮䴷㦲怀桅䳢䵘僤䨘㘖㘩敺㙝檻ƏẴ䄝䈔媽暽䄝㻦嶚ṭ 㘩敺䨘䙫㢄ờƏἭ恫㘖曧奨弟僤憶僤䦸䛟Ὲ怀Ẃ䳢䵘䙫䩐ㇽ娘 Ọㆰ䔏憶姯䭾Ḕ References 仁宅㑗濣 [1] Powell, D. Can Matter Cycle Through Shapes Eternally? Nature (2013). Retrieved from http://www.nature.com/news/can-matter-cyclethrough-shapes-eternally-1.13657 17

Missing continent: houses 20 million people, last seen 5 feet to the south. Notice any problem? Yes, the title is misleading and the adjustment is actually quite small compared to Australia s gigantic size of 8,600,000 square kilometres. Though, putting in perspective how points are projected on the Global Positioning System (GPS), how the continent moves does affect the accuracy of locating someone, or impair the ability to differentiate between two neighbouring places. As Australia continues on its journey to the north, the GPS would be due for a major adjustment once every couple of years and the next one is scheduled at the end of this year. The GPS is basically a giant map of our threedimensional world. That is, we can know precisely where everyone, everything, every place is by simply obtaining three numbers the x, y and z numbers form the basis for a global positioning system; by treating the world as one giant grid of coordinates; one can assign numbers to each and every specific place, thus annotating their respective positions. If you would like to know more about the physics of the GPS, please read Science Focus Issue 10 The GPS and Its Connection to Relativity. Cartography, the study of maps and pinpointing locations, is a delicate art. Maps are but static projections of our dynamic, ever-changing world. Every once in a while, the sets of reference points used to locate places on the coordinate system have to be updated. These reference points constitute a geodetic system which approximates or defines geographical distances, i.e. the latitude, longitude and altitude relative to these reference points, and make up the virtual framework on which we overlay the real world on. Usually, these reference points are major static structures such as roads and electrical grids, surveyed relative to other existing reference points. However, this implies that densely populated areas would be much better mapped than sparsely populated ones in fact, Alaska is only as well mapped as Mars in this sense! [1] Now, back to Australia. The current geodetic datum for the land down under was formalised way back in 1994. Updates for these datums have been sporadic Australia has only ever seen three renditions of geodetic datums. Any further changes to the grid matrix of locations are based on the 1994 datum, minor edits and marks on a stationary canvas. The thing is, all continents are essentially tectonic plates floating around, colliding and sliding against each other land masses shift over time, and Australia is no different. Except, Australia s movement has exceeded that of other continents due to its unique geology. The last update for the geodetic datum, i.e. the 1994 one, corrected its latitude and longitude by a staggering 656 feet. Some countries are more stationary than others. When there is a significant shift in land masses over time we need to revise the models of the Earth from which GPS coordinates are calculated, so for example your neighbour doesn't end up with your old coordinates, said Damien Saunders, Director of Cartography for National Geographic. Aside from the adjustment set for the end of this year, plans have been made for a modernised datum to be introduced by 2020, in order to keep up with the pace of advancements in mapping technologies which is probably way faster than the rate at which Australia drifts. It s not that Australia is drifting away so fast the GPS couldn t keep up we know where it is, we are just constantly pushing the very boundaries of precision and accuracy.

By David Iu References [1] Bourne, J. K., Jr. Alaska Has Finally Been Mapped as Precisely as Mars. National Geographic (2016). Retrieved from http://news. nationalgeographic.com/2016/09/alaska-has-finally-been-mapped-as-precisely-as-mars/ 19

You have most likely seen a friend whose nails are uneven and jagged stubs, or perhaps you have them yourself. Onychophagia is the compulsive act of biting one s nails. It is surprisingly prevalent at young ages, around 45% of adolescents are nail-biters, and it may become a lifelong habit [1]. Onychophagia is also identified as an obsessive-compulsive disorder (OCD). For longterm nail biters, to rid of this compulsive behaviour, a 2012 study suggested that becoming aware of the need to rid the habit is one of the first steps [2]. So, to fellow nail biters, friends and families supporting our kind, let us understand why our nails are gifted to us and what biting them might incur. Our nails have several important functions, including protecting the delicate phalangeal tissue and allowing for precise mechanical movements. Fingertips have high innervation density and are very sensitive. Our fingernails contribute to this feature by providing a counterforce to the fingertips when the finger s skin is touched, which heightens twopoint discrimination [3]. Nails also direction of growth and the duplicated cells grow distally toward the nail plate. The newly formed cells flatten and elongate from the resistance of the established nail [6]. Eventually, the nail plate is pushed out forming the free edge of the nail. Nail-biting can cause irreversible damage to this growth process. By removing the free edge of the nail plate and exposing the distal nail bed to the environment, the nail bed can irreversibly disappear thereby permanently shortening the nail plate [7]. With less of a free edge, not only is a smaller area of the finger protected, but precision i manoeuvres are impeded. Onychophagia can also increase the risk of onychomycosis, cosis, a fungal infection of the nail, which can stunt We Need Our Nails To Grow, So STOP Biting Them! enhance the precision of the pincer grip, the finest grip that humans can muster [4]. So how do these useful appendages grow and how can onychophagia stunt this? The visible nail or the nail plate is composed of keratin, a fibrous protein which gives the nail its translucent nature. This plate is held down to the nail bed by the proximal nail fold (the skin around your nail) and the eponychium (the cuticle) [5]. The growth of the nail begins at the nail matrix which is part of the nail bed. The cells near the matrix replicate and undergo enlargement. The nail folds limit the n a i l growth a n d contribute t o t h e destruction of the nail bed or the matrix [8]. With such deleterious effects, compounded by the unhygienic factor, it is hardly surprising that a social stigma exists for nail-biting. For young children, when onychophagia has yet to develop beyond occasional biting, we can make use of biological responses and use topical bitter concoctions to discourage biting [2].

Research suggests that incentive is a useful remedy, and can be particularly effective for older children. But when all else fails and no amount of instinctive responses or information gathering can strike the habit, stigmatisation may be the only way left. Let me end with a confession and the unfortunate irony of the nail-nibbling that occurred when I wrote this article. I am beyond the age of relying on biological responses, and I have learnt (even written) about onychophagia. I guess I have no choice but to ready myself for the only other option now: come my way, social stigma! inning article of the Science Focus W Article Submission Competition. By Natalie Si Yeung Yu King George V School, Year 12 References [1] Leung, A. K., & Robson, L. M. Nailbiting (1990). Clinical Pediatrics, 29(12), 690-692. doi:10.1177/000992289002901201 [2] Sachan, A., Chaturvedi, T. Onychophagia (Nail biting), Anxiety, and Malocclusion (2012). Indian Journal of Dental Research, 23(5), 680. doi:10.4103/0970-9290.107399 [3] Johnson, B. A., Wang, Q. C. Fingertip Injuries. American Family Physician (2001): n. pag. Web. 20 May 2017. [4] Palastanga, N., Derek, F., and Soames, R. W. Anatomy and Human Movement Structure and Function (2013). Burlington: Elsevier Science. Print. [5] Berker, D. A., De, R., Baran, R. Science of the Nail Apparatus (2012). Baran & Dawber's Diseases of the Nails and Their Management. doi: 10.1002/9781118286715.ch1 [6] Benjamin, P. Z., Scott, S. T., Reena, B. A. Nail Anatomy (2016). Retrieved from http://emedicine.medscape.com/ article/1948841-overview#a3 [7] Lee, D. Y. Chronic Nail Biting and Irreversible Shortening of the Fingernails (2009). Journal of the European Academy of Dermatology and Venereology. doi: 10.1111/j.1468-3083.2008.02760.x [8] Elewski, B. E. Onychomycosis: Pathogenesis, Diagnosis, and Management (1998). Clinical Microbiology Reviews 415 429. Print. 21

Genetic diseases, caused by abnormalities in a person s genome, are typically extremely difficult to treat, and many are incurable. Spinocerebellar ataxia (SCA) is one of them. It is a degenerative disease that eventually strips patients of their ability to coordinate movement. There are numerous types of SCA, with each type affecting a different gene and manifesting into a specific set of symptoms. Physiotherapy is often prescribed but only relieves symptoms to a certain degree. SCA40 was discovered by Prof. Edwin Ho-yin Chan during a three-year study of the genetic sequence of SCA patients in Hong Kong. He is Professor of Life Sciences at The Chinese University of Hong Kong and Director of the Laboratory of Drosophila Research. In the latter part of the 90s, it was nigh impossible to identify genes that caused genetic diseases. The gene mutation responsible for causing cystic fibrosis, for instance, was not discovered until 1988 by Francis Collins, Lap-Chee Tsui and John R. Riordan. As a high school student and college freshman, Prof. Chan aspired to follow in their footsteps. In his junior year in college, Prof. Chan met his mentor, Dr. Sandy Luk, who urged him to first understand the biology of normal individuals before investigating pathological conditions. Equipped with his mentor s sage advice, he began studying developmental biology on the fruit fly, Drosophila melanogaster and conducting research which helped explain how genes control an organism s egg development, as many genetic diseases unfold from young. Thus began his commitment to biomedical research. Prof. Chan s life s work began in 2002 after he had returned to Hong Kong from University of Pennsylvania, bringing with him the dream to dedicate himself to the SCA patient society. Together with the Hong Kong Spinocerebellar Ataxia Association, scientists, neurologists and genetic counsellors, they created a spinocerebellar ataxia patient registry that compiled patient data. It was during this period that they came across the SCA40 family where five individuals were diagnosed with adult-onset spinocerebellar ataxia. Using genetic and biochemical analyses, Prof. Chan and his team were able to isolate the mutation in a gene called CCDC88C in these patients. Carriers of this gene mutation will develop SCA40. Identification of the mutation is pivotal to developing better treatment and a potential cure to SCA40. We take a structure-based drug design approach to develop inhibitors that can neutralise RNA-toxicity in SCAs. Based on the toxic RNA structure, we virtually fit molecules to the RNA and attempt to find one that binds tightly to the toxic RNA, said Prof. Chan, After we identify such molecule(s), we then synthesise these compounds in the lab and then test them in our disease models, including ipsc, Drosophila and mice. Parallel to the research on SCA40, Prof. Chan and his team also investigate other neuromuscular diseases, including myotonic dystrophy and amyotrophic lateral sclerosis (ALS). The latter garnered viral attention in 2014 in an activity called the ALS Ice Bucket Challenge, aiming to bring awareness and donation toward ALS research.

The Discovery of SCA40 with Prof. Ho-yin Chan SCA40 By Teresa Ming Shan Fan Prof. Chan insists that creativity, paying attention to unobvious phenomena and perseverance are the keys to being a successful scientist. He also suggested, Work hard, play harder! 23

in patients than had been previously thought. In fact, the data that emerged from use of these techniques revealed that certain viruses visited the body so often that they could be considered part of the microbiome, said Dr. Foxman. However, as common as viruses were present, only half of the infections cause diseases and symptoms. I became very interested in how variations in hostvirus interactions affect the outcome of common viral infections. This intrigue fuels her current research on the topic. Photo credits: Yale Medicine Many myths shroud the rhinovirus, the culprit responsible for causing the common cold, including the set of circumstances in which the virus transforms from being dormant to causing infections in humans. We know surprisingly little about this common virus and attempting to set right the old wives tale on staying away from cold weather to avoid getting sick, is more complex than it seems. Yale University s Dr. Ellen Foxman and her research team investigate this very problem, exploring the mechanisms in which the rhinovirus manifests itself into symptoms and the body s defense in response to infection. Dr. Foxman s research career began as an undergraduate, where she received a wide spectrum of research experiences. During my first summer in college I did field research on Cliff Swallows, birds that migrate from the Midwestern United States to South America and back every year. The next summer, I was a research assistant in a virology lab, and the next year I worked in a yeast genetics lab, she said. These experiences paved the path for her future career in medical research. By the time she was in her medical residency, the normalisation of the use of polymerase chain reaction (PCR) to detect viruses helped to show that viral infections occur much more frequently Several factors enhance the replication of the rhinovirus; one of which is temperature, and whether the rhinovirus replicates more readily in cooler environments. Previous observations have suggested that many strains of the virus do become more virulent at temperatures of 33 35 C in the nasal cavity, as opposed to an average body temperature of 37 C. Dr. Foxman and her group discovered with compelling evidence that at a lower temperature, the defense response of infected cells are compromised, thus allowing the virus to become more infectious. Other factors that lower the defense response of cells include patients who have asthma, but the mechanism is not yet understood. Hong Kong s flu seasons are marked with seas of mask-donning citizens in an effort to curb the spread of viruses. While masks act as barriers for airborne germs and viruses, Dr. Foxman believes there may be a possibility that warming up the nasal airway by wearing masks could also be a factor in extra protection against infection. The best strategy to prevent symptoms is probably to prevent replication from happening in the first place, which is what our airway epithelial cell defence mechanisms aim to do. Meanwhile, Dr. Foxman and her team will continue to study and uncover the mechanisms that change the way our airway defence systems deal with viruses. A deeper understanding of these mechanisms is essential to the development of better strategies for the prevention of ubiquitous infections such as the common cold.

By Teresa Ming Shan Fan Micrograph of human bronchial epithelial cells, seven hours after exposure to rhinovirus 1B. Rhinovirus infection of airway epithelial cells results in accumulation of double stranded RNA (dsrna; blue) during viral genome replication. Cells are also stained with Mitotracker red to reveal the location of mitochondria, the cellular structures associated with innate immune signaling via the RIG-I like receptor pathway(red). Photo credits: Ulysses Isidro, Yale University senior thesis student. 25

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