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身為一個熱愛美食、喜歡在城市裡挖掘驚喜的人,臺中公益路一直是我最常出沒的地方之一。這條路可說是「臺中人的美食戰場」,從精緻西餐到創意火鍋,從日式丼飯到義式早午餐,每走幾步,就會有完全不同的特色料理餐廳。 這次我特別花了一整個月,實際造訪了公益路上十間口碑不錯的餐廳。有的是網友熱推的打卡名店,也有隱藏在巷弄裡的小驚喜。我以環境氛圍、口味表現、價格CP值與再訪意願為基準,整理出這篇實測評比。希望能幫正在猶豫去哪裡吃飯的你,找到那一間「吃完會想再來」的餐廳。 評比標準與整理方向
這次我走訪的10家餐廳橫跨不同料理類型,從高質感牛排館到巷弄系早午餐,每一間都有自己獨特的風格。為了讓整體比較更客觀,我依照以下四大面向進行評比,並搭配實際用餐體驗來打分。
整體而言,我希望這份評比不只是「哪家好吃」,而是幫你在不同情境下(約會、家庭聚餐、朋友小聚、商業午餐)都能快速找到合適的選擇。畢竟,美食不只是味覺的滿足,更是一段段與朋友共享的生活記憶。 10間臺中公益路餐廳評比懶人包公益路向來是臺中人聚餐的首選地段,從火鍋、燒肉到中式料理與早午餐,每走幾步就有驚喜。以下是我實際造訪過的10間代表性餐廳清單,橫跨平價、創意、高級各路風格。
一頭牛日式燒肉|炭香濃郁的和牛饗宴,約會聚餐首選
走在公益路上,很難不被 一頭牛日式燒肉 的木質外觀吸引。低調卻不失質感的門面,搭配昏黃燈光與暖色調的內裝,讓人一進門就感受到濃濃的日式職人氛圍。店內空間不大,但桌距規劃得宜,每桌皆設有獨立排煙設備,烤肉時完全不怕滿身油煙味。 餐點特色
一頭牛的靈魂,絕對是他們招牌的「三國和牛拼盤」。 用餐體驗整體節奏掌握得非常好。店員會在你剛想烤下一片肉時貼心遞上夾子、幫忙換烤網,讓人完全不用分心。整場用餐過程就像一場表演,從視覺、嗅覺到味覺都被滿足。 綜合評分
地址:408臺中市南屯區公益路二段162號電話:04-23206800 官網:http://www.marihuana.com.tw/yakiniku/index.html 小結語一頭牛日式燒肉不僅是「吃肉的地方」,更像是一場五感盛宴。從進門那一刻到最後一道甜點,都能感受到他們對細節的用心。 TANG Zhan 湯棧|文青系火鍋代表,麻香湯底與視覺美感並重
在公益路這條美食戰線上,TANG Zhan 湯棧 是讓人一眼就會想走進去的那一種。 餐點特色
湯棧最有名的當然是它的「麻香鍋」。 用餐體驗整體氛圍比一般火鍋店更有質感。 綜合評分
地址:408臺中市南屯區公益路二段248號電話:04-22580617 官網:https://www.facebook.com/TangZhan.tw/ 小結語TANG Zhan 湯棧 把傳統火鍋做出新的樣貌保留臺式鍋物的溫度,又結合現代風格與細節服務,讓吃鍋這件事變得更有品味。 如果你想找一間兼具「好吃、好拍、好放鬆」的火鍋店,湯棧會是公益路上最有風格的選擇之一。 NINI 尼尼臺中店|明亮寬敞的義式早午餐天堂
如果說前兩間是肉食愛好者的天堂,那 NINI 尼尼臺中店 絕對是想放鬆、聊聊天的好地方。餐廳外觀以白色系與大片玻璃窗為主,陽光灑進室內,讓人一踏入就有種度假般的輕盈感。假日早午餐時段特別熱鬧,建議提早訂位。 餐點特色
NINI 的菜單融合義式與臺灣人口味,選擇多樣且份量十足。主打的 松露燉飯 濃郁卻不膩口,米芯保留微Q口感;而 香蒜海鮮義大利麵 則以新鮮白蝦、花枝與淡菜搭配微辣蒜香,口感層次豐富。 用餐體驗店內氣氛輕鬆不拘謹,無論是一個人帶電腦工作、或朋友聚餐,都能找到舒服角落。餐點上桌速度穩定,服務人員態度親切、補水與收盤都非常主動。整體節奏讓人覺得「時間變慢了」,很適合想遠離忙碌日常的人。 綜合評分
地址:40861臺中市南屯區公益路二段18號電話:04-23288498 小結語NINI 尼尼臺中店是一間能讓人放下手機、慢慢吃飯的餐廳。餐點不追求浮誇,而是以「剛剛好」的份量與風味,陪伴每個平凡午後。如果你在找一間能邊吃邊聊天、拍照也漂亮的早午餐店,NINI 會是你在公益路上最不費力的幸福選擇。 加分100%浜中特選昆布鍋物|平價卻用心的湯頭系火鍋,家庭聚餐好選擇
在公益路這條高質感餐廳林立的戰場上,加分100%浜中特選昆布鍋物 走的是截然不同的路線。它沒有浮誇的裝潢、也沒有高價位的套餐,但靠著實在的湯頭與親切的服務,默默吸引許多回頭客。每到用餐時間,總能看到家庭或情侶三兩成群地圍著鍋邊聊天。 餐點特色
主打 北海道浜中昆布湯底,湯頭清澈卻不單薄,越煮越能喝出海藻與柴魚的自然香氣。 用餐體驗整體氛圍偏家庭取向,桌距寬敞、座位舒適,帶小孩來也不覺擁擠。店員態度親切,補湯、收盤都很勤快,給人一種「被照顧著」的安心感。 綜合評分
地址:403臺中市西區公益路288號電話:0910855180 小結語加分100%浜中特選昆布鍋物是一間「不浮誇、但會讓人想再訪」的火鍋店。它不追求豪華擺盤,而是用最簡單的湯頭與新鮮食材,傳遞出家常卻不平凡的溫度。 印月餐廳|中式料理的藝術演繹,宴客與家庭聚會首選
說到臺中公益路的中式料理代表,印月餐廳 絕對是榜上有名。這間開業多年的餐廳以「中菜西吃」的概念聞名,把傳統中式料理以現代手法重新詮釋。從建築外觀到餐具擺設,每個細節都散發著低調的典雅氣息。 餐點特色
印月最令人印象深刻的是他們將傳統中菜融入創意手法。 用餐體驗服務方面完全對得起餐廳的高級定位。從入座、點餐到上菜節奏,都拿捏得恰如其分。每道菜都會有服務人員細心介紹食材與吃法,讓人感受到「被款待」的尊榮感。 綜合評分
地址:408臺中市南屯區公益路二段818號電話:0422511155 小結語印月餐廳是一間「不只吃飯,更像品味生活」的地方。 KoDō 和牛燒肉|極致職人精神,專為儀式感與頂級味覺而生
若要形容 KoDō 和牛燒肉 的用餐體驗,一句話足以總結——「像在欣賞一場關於肉的表演」。 餐點特色
這裡主打 日本A5和牛冷藏肉,以「精切厚燒」的方式呈現。 用餐體驗KoDō 的最大特色是「儀式感」。 綜合評分
地址:403臺中市西區公益路260號電話:0423220312 官網:https://www.facebook.com/kodo2018/ 小結語KoDō 和牛燒肉不是日常餐廳,而是一場體驗。 永心鳳茶|在茶香裡用餐的優雅時光,臺味早午餐的新詮釋
走進 永心鳳茶公益店,彷彿進入一間有氣質的茶館。 餐點特色
永心鳳茶的餐點結合中式靈魂與西式擺盤,無論是「炸雞腿飯」還是「紅玉紅茶拿鐵」,都能讓人感受到熟悉卻不平凡的味道。 用餐體驗店內服務人員態度溫和,對茶品介紹詳盡。上餐節奏剛好,不急不徐。 綜合評分
地址:40360臺中市西區公益路68號三樓(勤美誠品)電話:0423221118 小結語永心鳳茶讓人重新定義「臺味」。 三希樓|老饕級江浙功夫菜,穩重又帶人情味的中式饗宴
位於公益路上的 三希樓 是許多臺中老饕的口袋名單。 餐點特色
三希樓的菜色以 江浙與港式料理 為主,兼顧傳統與現代風味。 用餐體驗三希樓的服務給人一種老派但貼心的感覺。 綜合評分
地址:408臺中市南屯區公益路二段95號電話:0423202322 官網:https://www.sanxilou.com.tw/ 小結語三希樓是一間「吃得出功夫」的餐廳。 一笈壽司|低調奢華的無菜單日料,職人手藝詮釋旬味極致
在熱鬧的公益路上,一笈壽司 低調得幾乎不顯眼。 餐點特色
一笈壽司採 Omakase(無菜單料理) 形式,每一餐都由主廚根據當日食材設計。 用餐體驗整場用餐約90分鐘,節奏緩慢但沉穩。 綜合評分
地址:408臺中市南屯區公益路二段25號電話:0423206368 官網:https://www.facebook.com/YIJI.sushi/ 小結語一笈壽司是一間真正讓人「放慢呼吸」的餐廳。 茶六燒肉堂|人氣爆棚的和牛燒肉聖地,肉香與幸福感同時滿分
若要票選公益路上「最難訂位」的餐廳,茶六燒肉堂 絕對名列前茅。 餐點特色
茶六主打 和牛燒肉套餐,價格約落在 $700–$1000 間,份量與品質兼具。 用餐體驗茶六的服務效率相當高。店員親切、換網勤快、補水速度快,整場用餐流程流暢無壓力。 綜合評分
地址:403臺中市西區公益路268號電話:0423281167 官網:https://inline.app/booking/-L93VSXuz8o86ahWDRg0:inline-live-karuizawa/-LUYUEIOYwa7GCUpAFWA 小結語茶六燒肉堂用「穩定品質+輕奢氛圍」抓住了臺中年輕族群的心。 吃完10家公益路餐廳後的心得與結語吃完這十家餐廳後,臺中公益路不只是一條美食街,而是一段生活風景線。 有的餐廳講究細膩與儀式感,像 一頭牛日式燒肉 與 一笈壽司,讓人感受到食材最純粹的美好 有的則以親切與溫度打動人心,像 加分昆布鍋物、永心鳳茶,讓人明白吃飯不只是為了飽足,而是一種被照顧的幸福。 而像茶六燒肉堂、TANG Zhan 湯棧 這類人氣名店,則用穩定的品質與熱絡的氛圍,成為許多臺中人心中「想吃肉就去那裡」的代名詞。 這十家店,構成了公益路最動人的縮影 有華麗的,也有溫柔的;有傳統的,也有創新的。 每一家都在自己的風格裡發光,讓人吃到的不只是料理,而是一種生活的溫度與節奏。 對我而言,這不僅是一場美食旅程,更是一趟關於「臺中味道」的回憶之旅。 FAQ:關於臺中公益路美食常見問題Q1:公益路哪一區的餐廳最集中? Q2:需要提前訂位嗎? 最後的話若要用一句話形容這趟美食之旅,我會說: KoDō 和牛燒肉海鮮表現如何? 如果你也和我一樣喜歡用味蕾探索一座城市,那就把這篇公益路美食攻略收藏起來吧。永心鳳茶座位舒適嗎? 無論是約會、慶生、家庭聚餐,或只是想犒賞一下辛苦的自己——這條路上永遠會有一間剛剛好的餐廳在等你。TANG Zhan 湯棧有什麼隱藏版必點嗎? 下一餐,不妨從這10家開始。加分100%浜中特選昆布鍋物套餐劃算嗎? 打開手機、約上朋友,讓公益路成為你生活裡最容易抵達的小確幸。永心鳳茶適合多人團聚嗎? 如果你有私心愛店,也歡迎留言分享,三希樓有什麼隱藏版必點嗎? 你的推薦,可能讓我下一趟美食旅程變得更精彩。KoDō 和牛燒肉停車方便嗎? Syracuse University biologists co-authored a study exploring how sea urchin adhesive abilities are affected by differing levels of water salinity. Credit: Syracuse University Researchers from Syracuse University are investigating the effects of excess freshwater, resulting from climate change-driven occurrences like intensified heavy rainfall, on the survival of sea urchins. When navigating through a heavy rainstorm, maintaining grip on the road is essential. Should your vehicle’s tires be deficient in tread, you’ll find yourself skidding and sliding, unable to control the car safely. A parallel can be drawn with sea urchins living in nearshore, shallow water habitats during torrential rains. Such downpours lead to a change in the ocean’s salt concentration, resulting in lower salinity levels. This minor shift in salinity can have a profound effect on sea urchins’ ability to firmly affix their tube feet to the surfaces around them, akin to the way tires need to grip the road. For these small, spiky marine animals, this isn’t just an inconvenience but a matter of survival. Their adhesive structures enable them to move amidst the wave-swept rocks near the shore, and without this ability, their very lives are at risk. Syracuse University biologists co-authored a study exploring how sea urchin adhesive abilities are affected by differing levels of water salinity. The Critical Role of Sea Urchins in Marine Ecosystems The survival of sea urchins is vital for maintaining balance within marine ecosystems. Sea urchins are responsible for grazing around 45% of the algae on coral reefs. Without sea urchins, coral reefs can become overgrown with macroalgae, which can limit the growth of corals. With the importance of coral reefs for coastal protection and preservation of biodiversity, it is critical to safeguard the sea urchin population. Syracuse University graduate student Andrew Moura (right) and former Villanova University undergraduate student Jack Cucchiara check salinity levels among the 10 different groups of sea urchins at Friday Harbor Laboratories. Credit: Syracuse University, University of Washington As global climate change causes weather extremes ranging from heat waves and droughts to heavy rains and flooding, the large amounts of freshwater pouring into nearshore ecosystems are altering habitats. A team of biologists, led by Austin Garner, assistant professor in the College of Arts and Sciences’ Department of Biology, studied the impacts of low salinity and how it alters sea urchins’ ability to grip and move within their habitat. Garner, who is a member of Syracuse University’s BioInspired Institute, studies how animals attach to surfaces in variable environments from the perspective of both the life and physical sciences. The team’s study, recently published in the Journal of Experimental Biology, sought to understand how sea urchin populations will be affected by future extreme climatic events. “While many marine animals can regulate the amount of water and salts in their bodies, sea urchins are not as effective at this,” says Garner. “As a result, they tend to be restricted to a narrow range of salinity levels. Torrential precipitation can cause massive amounts of freshwater to be dumped into the ocean along the coastline causing rapid reductions in the concentration of salt in seawater.” The group’s research was conducted at the University of Washington’s Friday Harbor Laboratories (FHL). The study’s lead author, Andrew Moura, who is a graduate student in Garner’s lab at Syracuse, traveled to FHL along with Garner and researchers from Villanova University to conduct experiments with live green sea urchins. They worked alongside former FHL postdoctoral scholar Carla Narvaez, who is now an assistant professor of biology at Rhode Island College, and Villanova University professors Alyssa Stark and Michael Russell. Syracuse University biology professor Austin Garner holding a sea urchin. Credit: Syracuse University At FHL, the researchers separated sea urchins into 10 groups based on differing salinity levels within each tank, from normal to very low salt content. Among each group, they tested metrics including righting response (the ability for sea urchins to flip themselves over), locomotion (speed from one point to another), and adhesion (force at which their tube feet detach from a surface). In Garner’s lab at Syracuse, he and Moura completed data analysis to compare each metric. Reduced Salinity Weakens Sea Urchin Abilities The team found that sea urchin righting response, movement, and adhesive ability were all negatively impacted by low salinity conditions. Interestingly, though, sea urchin adhesive ability was not severely impacted until very low salinity levels, indicating that sea urchins may be able to remain attached in challenging nearshore environmental conditions even though activities that require greater coordination of tube feet (righting and movement) may not be possible. “When we see this decrease in performance under very low salinity, we might start seeing shifts in where sea urchins might be living as a consequence of their inability to remain stuck in certain areas that experience low salinity,” explains Moura. “That could change how much sea urchin grazing is happening and could have profound ecosystem effects.” Learning from Sea Urchin Adhesion Their work provides critical data that enhances researchers’ ability to predict how important animals like sea urchins will fare in a changing world. The adhesion principles Garner and his team are exploring could also come in handy for human-designed adhesive materials – work that aligns with the Syracuse University BioInspired Institute’s mission of addressing global challenges through innovative research. “If we can learn the fundamental principles and molecular mechanisms that allow sea urchins to secrete a permanent adhesive and use it for temporary attachment, we could harness that power into the design challenges or our adhesives today,” says Garner. “Imagine being able to have an adhesive that is otherwise permanent, but then you add another component, and it breaks it down and you can go stick it again somewhere else. It’s a perfect example of how biology can be used to enhance the everyday products around us.” Reference: “Hyposalinity reduces coordination and adhesion of sea urchin tube feet” by Andrew J. Moura, Austin M. Garner, Carla A. Narvaez, Jack P. Cucchiara, Alyssa Y. Stark and Michael P. Russell, 30 June 2023, Journal of Experimental Biology. DOI: 10.1242/jeb.245750 This illustration is inspired by the Paleolithic rock painting in the Lascaux cave, signifying the acronym of our method, ROCK. Figuratively, the patterns of the rock art in the background (brown) are the 2D projections of the engineered dimeric construct of the Tetrahymena group I intron, while the main object in the front (blue) is the reconstructed 3D cryo-EM map of the dimer, with one monomer in focus and refined to the high resolution that allowed the collaborators to build an atomic model of the RNA. Credit: Wyss Institute at Harvard University Combination of nucleic acid nanotechnology and cryo-EM gives unprecedented insights into the structures of large and small RNAs, advancing RNA biology and drug design. We live in a world created and run by RNA, the equally important sibling of the genetic molecule DNA. In fact, evolutionary biologists hypothesize that RNA existed and self-replicated even before the appearance of DNA. Fast forward to modern-day humans: science has revealed that less than 3% of the human genome is transcribed into messenger RNA (mRNA) molecules that in turn are translated into proteins. In contrast, 82% of it is transcribed into RNA molecules with other functions many of which are yet unknown. Ribonucleic acid (RNA) is a polymeric molecule that is essential in various biological roles in coding, decoding, regulation and expression of genes. Both RNA and deoxyribonucleic acid (DNA) are nucleic acids. Along with lipids, proteins, and carbohydrates, nucleic acids constitute one of the four major macromolecules essential for all known forms of life. RNA, like DNA, is assembled as a chain of nucleotides, but unlike DNA, RNA is found in nature as a single strand folded onto itself, rather than a paired double strand. To understand what an individual RNA molecule does, its 3D structure needs to be deciphered at the level of its constituent atoms and molecular bonds. Researchers have routinely studied DNA and protein molecules by turning them into regularly packed crystals that can be examined with an X-ray beam (X-ray crystallography) or radio waves (nuclear magnetic resonance). However, these techniques cannot be applied to RNA molecules with nearly the same effectiveness because their molecular composition and structural flexibility prevent them from easily forming crystals. Now, a research collaboration led by Wyss Core Faculty member Peng Yin, Ph.D. at the Wyss Institute for Biologically Inspired Engineering at Harvard University, and Maofu Liao, Ph.D. at Harvard Medical School (HMS), has reported a fundamentally new approach to the structural investigation of RNA molecules. ROCK, as it is called, uses an RNA nanotechnological technique that allows it to assemble multiple identical RNA molecules into a highly organized structure, which significantly reduces the flexibility of individual RNA molecules and multiplies their molecular weight. Applied to well-known model RNAs with different sizes and functions as benchmarks, the team showed that their method enables the structural analysis of the contained RNA subunits with a technique known as cryo-electron microscopy (cryo-EM). Their advance is reported in the journal Nature Methods. “ROCK is breaking the current limits of RNA structural investigations and enables 3D structures of RNA molecules to be unlocked that are difficult or impossible to access with existing methods, and at near-atomic resolution,” said Yin, who together with Liao led the study. “We expect this advance to invigorate many areas of fundamental research and drug development, including the burgeoning field of RNA therapeutics.” Yin also is a leader of the Wyss Institute’s Molecular Robotics Initiative and Professor in the Department of Systems Biology at HMS. “ROCK is breaking the current limits of RNA structural investigations and enables 3D structures of RNA molecules to be unlocked that are difficult or impossible to access with existing methods, and at near-atomic resolution. We expect this advance to invigorate many areas of fundamental research and drug development, including the burgeoning field of RNA therapeutics.” Peng Yin Gaining Control Over RNA Yin’s team at the Wyss Institute has pioneered various approaches that enable DNA and RNA molecules to self-assemble into large structures based on different principles and requirements, including DNA bricks and DNA origami. They hypothesized that such strategies could also be used to assemble naturally occurring RNA molecules into highly ordered circular complexes in which their freedom to flex and move is highly restricted by specifically linking them together. Many RNAs fold in complex yet predictable ways, with small segments base-pairing with each other. The result often is a stabilized “core” and “stem-loops” bulging out into the periphery. In ROCK (RNA oligomerization-enabled cryo-EM via installing kissing loops), a target RNA is engineered for the self-assembly of a closed homomeric ring via kissing-loop sequences (red) that are installed onto functionally nonessential, peripheral helices (blue). After identifying engineerable nonessential peripheral helices, the length of the helices connecting the kissing-loop motif and the core of the target RNA is computationally optimized. An RNA construct with multiple individual subunits of the target RNA is transcribed, assembled, and then purified by gel electrophoresis, before it can be analyzed via the cryo-EM method. Credit: Wyss Institute at Harvard University “In our approach we install ‘kissing loops’ that link different peripheral stem-loops belonging to two copies of an identical RNA in a way that allows a overall stabilized ring to be formed, containing multiple copies of the RNA of interest,” said Di Liu, Ph.D., one of two first-authors and a Postdoctoral Fellow in Yin’s group. “We speculated that these higher-order rings could be analyzed with high resolution by cryo-EM, which had been applied to RNA molecules with first success.” Picturing Stabilized RNA In cryo-EM, many single particles are flash-frozen at cryogenic temperatures to prevent any further movements, and then visualized with an electron microscope and the help of computational algorithms that compare the various aspects of a particle’s 2D surface projections and reconstruct its 3D architecture. Peng and Liu teamed up with Liao and his former graduate student François Thélot, Ph.D., the other co-first author of the study. Liao with his group has made important contributions to the rapidly advancing cryo-EM field and the experimental and computational analysis of single particles formed by specific proteins. “Cryo-EM has great advantages over traditional methods in seeing high-resolution details of biological molecules including proteins, DNAs and RNAs, but the small size and moving tendency of most RNAs prevent successful determination of RNA structures. Our novel method of assembling RNA multimers solves these two problems at the same time, by increasing the size of RNA and reducing its movement,” said Liao, who also is an Associate Professor of Cell Biology at HMS. “Our approach has opened the door to rapid structure determination of many RNAs by cryo-EM.” The integration of RNA nanotechnology and cryo-EM approaches led the team to name their method “RNA oligomerization-enabled cryo-EM via installing kissing loops” (ROCK). To provide proof-of-principle for ROCK, the team focused on a large intron RNA from Tetrahymena, a single-celled organism, and a small intron RNA from Azoarcus, a nitrogen-fixing bacterium, as well as the so-called FMN riboswitch. Intron RNAs are non-coding RNA sequences scattered throughout the sequences of freshly-transcribed RNAs and have to be “spliced” out in order for the mature RNA to be generated. The FMN riboswitch is found in bacterial RNAs involved in the biosynthesis of flavin metabolites derived from vitamin B2. Upon binding one of them, flavin mononucleotide (FMN), it switches its 3D conformation and suppresses the synthesis of its mother RNA. In their analysis of the Tetrahymena group I intron, the researchers collected about 105,000 single-particle cryo-EM images of the ROCK-enabled structure, and over a series of computational analysis steps reconstructed its structure, reaching an overall resolution of 2.98 Å, and a resolution of 2.85 Å for the core of the structure. The final models provided a detailed view of the Tetrahymena group I intron, including the previously unknown peripheral domains (shown in brown and purple), which constitute a belt surrounding the core. Credit: Wyss Institute at Harvard University “The assembly of the Tetrahymena group I intron into a ring-like structure made the samples more homogenous, and enabled the use of computational tools leveraging the symmetry of the assembled structure. While our dataset is relatively modest in size, ROCK’s innate advantages allowed us to resolve the structure at an unprecedented resolution,” said Thélot. “The RNA’s core is resolved at 2.85 Å [one Ångström is one ten-billions (US) of a meter and the preferred metric used by structural biologists], revealing detailed features of the nucleotide bases and sugar backbone. I don’t think we could have gotten there without ROCK – or at least not without considerably more resources.” Cryo-EM also is able to capture molecules in different states if they, for example, change their 3D conformation as part of their function. Applying ROCK to the Azoarcus intron RNA and the FMN riboswitch, the team managed to identify the different conformations that the Azoarcus intron transitions through during its self-splicing process, and to reveal the relative conformational rigidity of the ligand-binding site of the FMN riboswitch. “This study by Peng Yin and his collaborators elegantly shows how RNA nanotechnology can work as an accelerator to advance other disciplines. Being able to visualize and understand the structures of many naturally occurring RNA molecules could have a tremendous impact on our understanding of many biological and pathological processes across different cell types, tissues, and organisms, and even enable new drug development approaches,” said Wyss Founding Director Donald Ingber, M.D., Ph.D., who is also the Judah Folkman Professor of Vascular Biology at Harvard Medical School and Boston Children’s Hospital, and the Hansjörg Wyss Professor of Bioinspired Engineering at the Harvard John A. Paulson School of Engineering and Applied Sciences. Reference: “Sub-3-Å cryo-EM structure of RNA enabled by engineered homomeric self-assembly” by Di Liu, François A. Thélot, Joseph A. Piccirilli, Maofu Liao and Peng Yin, 2 May 2022, Nature Methods. DOI: 10.1038/s41592-022-01455-w The study was also authored by Joseph Piccirilli, Ph.D., an expert in RNA chemistry and biochemistry and Professor at The University of Chicago. It was supported by the National Science Foundation (NSF; grant# CMMI-1333215, CCMI-1344915, and CBET-1729397), Air Force Office of Scientific Research (AFOSR; grant MURI FATE, #FA9550-15-1-0514), National Institutes of Health (NIH; grant# 5DP1GM133052, R01GM122797, and R01GM102489), and the Wyss Institute’s Molecular Robotics Initiative. The legs of sea robins function as sensory organs equipped with taste and touch capabilities, a discovery made through genetic research that highlights the tbx3a gene’s critical role in this evolutionary trait. (Lepidotrigla papilio.) Credit: Mike Jones Researchers have discovered that the legs of sea robins, which resemble those of a crab, serve as sensory organs to detect prey. This finding, documented in two studies published in Current Biology, reveals the legs’ role in taste and touch. The studies also explore the genetic mechanisms behind this trait, highlighting the involvement of a transcription factor, tbx3a, in the development of these sensory legs and the evolutionary adaptations of sea robins. Unveiling the Unique Traits of Sea Robins Sea robins are extraordinary creatures, boasting a fish’s body, bird-like wings, and crab-like walking legs. Recent research reveals these legs do more than just walk; they function as genuine sensory organs, helping the sea robin locate prey hidden beneath the seabed. These findings are detailed in two studies published today (September 26) in the Cell Press journal Current Biology. “This is a fish that grew legs using the same genes that contribute to the development of our limbs and then repurposed these legs to find prey using the same genes our tongues use to taste food—pretty wild,” says Nicholas Bellono of Harvard University in Cambridge, MA. The Surprising Discovery of Sensory Legs Bellono, along with David Kingsley of Stanford University and their colleagues, didn’t set out to study sea robins at all. They came across these creatures on a trip to the Marine Biological Laboratory in Woods Hole, MA. After learning that other fish follow the sea robins around, apparently due to their skills in uncovering buried prey, the researchers became intrigued and took some sea robins back to the lab to find out more. They confirmed that the sea robins could indeed detect and uncover ground-up and filtered mussel extract and even single amino acids. As reported in one of the two new studies, they found that sea robins’ legs are covered in sensory papillae, each receiving dense innervation from touch-sensitive neurons. The papillae also have taste receptors and show chemical sensitivity that drives the sea robins to dig. Exploring Genetic and Evolutionary Innovations “We were originally struck by the legs that are shared by all sea robins and make them different from most other fish,” Kingsley says. “We were surprised to see how much sea robins differ from each other in sensory structures found on the legs. The system thus displays multiple levels of evolutionary innovation from differences between sea robins and most other fish, differences between sea robin species, and differences in everything from structure and sensory organs to behavior.” Through further developmental studies, the researchers confirmed that the papillae represent a key evolutionary innovation that has allowed the sea robins to succeed on the seafloor in ways other animals can’t. In the second study, they looked deeper into the genetic basis of the fish’s unique legs. They used genome sequencing, transcriptional profiling, and study of hybrid species to understand the molecular and developmental basis for leg formation. Insights Into the Molecular Basis of Evolution Their analyses identified an ancient and conserved transcription factor, called tbx3a, as a major determinant of the sea robins’ sensory leg development. Genome editing confirmed that they depend on this regulatory gene to develop their legs normally. The same gene also plays a critical role in the formation of sea robins’ sensory papillae and their digging behavior. “Although many traits look new, they are usually built from genes and modules that have existed for a long time,” Kingsley said. “That’s how evolution works: by tinkering with old pieces to build new things.” The findings show that it’s now possible to expand our detailed understanding of complex traits and their evolution in wild organisms, not just in well-established model organisms, according to the researchers. They are now curious to learn more about the specific genetic and genomic changes that led to sea robins’ evolution. References: “Evolution of novel sensory organs in fish with legs” by Corey A.H. Allard, Amy L. Herbert, Stephanie P. Krueger, Qiaoyi Liang, Brittany L. Walsh, Andrew L. Rhyne, Allex N. Gourlay, Agnese Seminara, Maude W. Baldwin, David M. Kingsley and Nicholas W. Bellono, 26 September 2024, Current Biology. DOI: 10.1016/j.cub.2024.08.014 “Ancient developmental genes underlie evolutionary novelties in walking fish” by Amy L. Herbert, Corey A.H. Allard, Matthew J. McCoy, Julia I. Wucherpfennig, Stephanie P. Krueger, Heidi I. Chen, Allex N. Gourlay, Kohle D. Jackson, Lisa A. Abbo, Scott H. Bennett, Joshua D. Sears, Andrew L. Rhyne, Nicholas W. Bellono and David M. Kingsley, 26 September 2024, Current Biology. DOI: 10.1016/j.cub.2024.08.042 RRG455KLJIEVEWWF NINI 尼尼台中店食材新鮮嗎? 》公益路美食新手指南|10家必吃推薦永心鳳茶慶生氛圍夠嗎? 》2026台中公益路必吃餐廳|10大美食評比:燒肉、火鍋、早午餐通通有!印月餐廳尾牙預算好掌控嗎? 》台中公益路美食攻略|精選10間超人氣餐廳,一次帶你吃遍熱門口袋名單 |
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