乌东德水电站位于四川省会东县和云南省禄劝县交界处金沙江河道上,水电站坝顶高程988米,最大坝高270米,总库容74.08亿立方米。电站安装12台单机容量85万千瓦的水轮发电机组,装机总容量1020万千瓦,年发电量389.1亿千瓦时。
Highway on Tianlong Mountain
The construction of the highway on Tianlong Mountain 天龙山 in Taiyuan, N China’s Shanxi Province started in March 2019 after the old road built in 1996 suffered wear and tear. The new highway is about 30 kilometers long with a vertical gain of 350 meters. The entire highway reconstruction project also includes four bridges and a tunnel. It reduced the grade from 15% to 4%, which has greatly improved safety. The project completed in September 2019.
The world’s first large, three-engine utility drone
The world’s first large, three-engine utility drone recently made its first flight. Developed by Chengdu-based Tengden Technology Co, the drone is a three-engine variant of Tengden’s twin-engine TB Twin-tailed Scorpion, as this design is a world first for drones. The drone has a width of 20 meters and a length of 11 meters. It is equipped with three piston engines, with one under each wing and one on its tail, enabling it to have a maximum takeoff weight of 3.2 tons and an endurance of 35 hours.The drone has a flight ceiling of 9,500 meters, a max climb rate of 10 meters a second and a top speed of more than 300 kilometers an hour.
Evolution of the novel coronavirus from the ongoing Wuhan outbreak and modeling of its spike protein for risk of human transmission
http://engine.scichina.com/publisher/scp/journal/SCLS/63/3/10.1007/s11427-020-1637-5?slug=abstract
The occurrence of concentrated pneumonia cases in Wuhan city, Hubei province of China was first reported on December 30, 2019 by the Wuhan Municipal Health Commission (WHO, 2020). The pneumonia cases were found to be linked to a large seafood and animal market in Wuhan, and measures for sanitation and disinfection were taken swiftly by the local government agency. The Centers for Disease Control and Prevention (CDC) and Chinese health authorities later determined and announced that a novel coronavirus (CoV), denoted as Wuhan CoV, had caused the pneumonia outbreak in Wuhan city (CDC, 2020). Scientists from multiple groups had obtained the virus samples from hospitalized patients (Normile, 2020). The isolated viruses were morphologically identical when observed under electron microscopy.
One genome sequence (WH-Human_1) of the Wuhan CoV was first released on Jan 10, 2020, and subsequently five additional Wuhan CoV genome sequences were released (Zhang, 2020; Shu and McCauley, 2017) (Table S1 in Supporting Information). The current public health emergency partially resembles the emergence of the SARS outbreak in southern China in 2002. Both happened in winter with initial cases linked to exposure to live animals sold at animal markets, and both were caused by previously unknown coronaviruses. As of January 15, 2020, there were more than 40 laboratory-confirmed cases of the novel Wuhan CoV infection with one reported death. Although no obvious evidence of human-to-human transmission was reported, there were exported cases in Hong Kong China, Japan, and Thailand.
Under the current public health emergency, it is imperative to understand the origin and native host(s) of the Wuhan CoV, and to evaluate the public health risk of this novel coronavirus for transmission cross species or between humans. To address these important issues related to this causative agent responsible for the outbreak in Wuhan, we initially compared the genome sequences of the Wuhan CoV to those known to infect humans, namely the SARS-CoV and Middle East Respiratory Syndrome (MERS)-CoV (Cotten et al., 2013). The sequences of the six Wuhan CoV genomes were found to be almost identical (Figure S1A in Supporting Information). When compared to the genomes of SARS-CoV and MERS-CoV, the WH-human_1 genome that was used as representative of the Wuhan CoV, shared a better sequence homology toward the genomes of SARS-CoV than that of MERS-CoV (Figure S1B in Supporting Information). High sequence diversity between Wuhan-human_1 and SARS-CoV_Tor2 was found mainly in ORF1a and spike (S-protein) gene, whereas sequence homology was generally poor between Wuhan-human_1 and MERS-CoV.
To understand the origin of the Wuhan CoV and its genetic relationship with other coronaviruses, we performed phylogenetic analysis on the collection of coronavirus sequences from various sources. The results showed the Wuhan CoVs were clustered together in the phylogenetic tree, which belong to the Betacoronavirus genera (Figure 1A). Betacoronavirus is enveloped, single-stranded RNA virus that infects wild animals, herds and humans, resulting in occasional outbreaks and more often infections without apparent symptoms. The Wuhan CoV cluster is situated with the groups of SARS/SARS-like coronaviruses, with bat coronavirus HKU9-1 as the immediate outgroup. Its inner joint neighbors are SARS or SARS-like coronaviruses, including the human-infecting ones (Figure 1A, marked with red star). Most of the inner joint neighbors and the outgroups were found in various bats as natural hosts, e.g., bat coronaviruses HKU9-1 and HKU3-1 in Rousettus bats and bat coronavirus HKU5-1 in Pipistrellus bats. Thus, bats being the native host of the Wuhan CoV would be the logical and convenient reasoning, though it remains likely there was intermediate host(s) in the transmission cascade from bats to humans. Based on the unique phylogenetic position of the Wuhan CoVs, it is likely that they share with the SARS/SARS-like coronaviruses, a common ancestor that resembles the bat coronavirus HKU9-1. However, frequent recombination events during their evolution may blur their path, evidenced by patches of high-homologous sequences between their genomes (Figure S1B in Supporting Information).
Figure 1
Evolutionary analysis of the coronaviruses and modeling of the Wuhan CoV S-protein interacting with human ACE2. A, Phylogenetic tree of coronaviruses based on full-length genome sequences. The tree was constructed with the Maximum-likelihood method using RAxML with GTRGAMMA as the nucleotide substitution model and 1,000 bootstrap replicates. Only bootstraps ≥50% values are shown as filled circles. The host for each coronavirus is marked with corresponding silhouette. Known human-infecting betacoronaviruses are indicated with a red star. B, Amino acid sequence alignment of the RBD domain of coronavirus S-protein. Residues 442, 472, 479, 487, and 491 (numbered based on SARS-CoV S-protein sequence) are important residues for interaction with human ACE2 molecule. C, Structural modeling of the Wuhan CoV (WH-human_1 as representative) S-protein complexed with human ACE2 molecule. Middle panel: The model of the Wuhan CoV S-protein (brown ribbon) is superimposed with the structural template of the SARS CoV S-protein (light blue ribbon). The protein backbone structure of human ACE2 is represented in magenta ribbon. Left panel: The region is shown for hydrogen bonding interactions between Arg426 in S-protein and Gln325/Glu329 in ACE2. The relevant residues are presented in ball and stick representations. Right panel: The region is shown for hydrogen bonding interactions between Tyr436 in S-protein and Asp38/Gln42 in ACE2.
Overall, there is considerable genetics distance between the Wuhan CoV and the human-infecting SARS-CoV, and even greater distance from MERS-CoV. This observation raised an important question whether the Wuhan CoV adopted the same mechanisms that SARS-CoV or MERS-CoV used for transmission cross species/humans, or involved a new, different mechanism for transmission.
The S-protein of coronavirus is divided into two functional units, S1 and S2. S1 facilitates virus infection by binding to host receptors. It comprises two domains, the N-terminal domain and the C-terminal RBD domain that directly interacts with host receptors (Li, 2012). To investigate the Wuhan CoV and its host interaction, we looked into the RBD domain of its S-protein. The S-protein was known to usually have the most variable amino acid sequences compared to those of ORF1a and ORF1b from coronavirus (Hu et al., 2017). However, despite the overall low homology of the Wuhan CoV S-protein to that of SARS-CoV (Figure S1 in Supporting Information), the Wuhan CoV S-protein had several patches of sequences in the RBD domain having a high homology to that of SARS-CoV_Tor2 and HP03-GZ01 (Figure 1B). The residues at positions 442, 472, 479, 487, and 491 in SARS-CoV S-protein were reported to be at receptor complex interface and considered critical for cross-species and human-to-human transmission of SARS-CoV (Li et al., 2005). Despite the patches of highly conserved regions in the RBD domain of the Wuhan CoV S-protein, four of the five critical residues are not preserved except Tyr491 (Figure 1B). Although the polarity and hydrophobicity of the replacing amino acids are similar, they raised serious questions about whether the Wuhan CoV would infect humans via binding of S-protein to ACE2, and how strong the interaction is for risk of human transmission. Note MERS-CoV S-protein displayed very little homology toward that of SARS-CoV in the RBD domain, due to the different binding target for its S-protein, the human dipeptidyl peptidase 4 (DPP4) (Raj et al., 2013).
To answer the serious questions and assess the risk of human transmission of the Wuhan CoV, we performed structural modeling of its S-protein and evaluated its ability to interact with human ACE2 molecules. Based on the computer-guided homology modeling method, the structural model of the Wuhan CoV S-protein was constructed by Swiss-model using the crystal structure of SARS coronavirus S-protein (PDB accession: 6ACD) as a template (Schwede et al., 2003). Note the amino acid sequence identity between the Wuhan-CoV and SARS-CoV S-proteins is 76.47%. Then according to the crystal structure of SARS-CoV S-protein RBD domain complexed with its receptor ACE2 (PDB code: 2AJF), the 3-D complex structure of the Wuhan CoV S-protein binding to human ACE2 was modeled with structural superimposition and molecular rigid docking (Li et al., 2005) (Figure 1C).
The computational model of the Wuhan CoV S-protein (using the WH-human_1 sequence as representative) showed a Cα RMSD of 1.45 Å on the RBD domain compared to the SARS-CoV S-protein structure (Figure 1C). The binding free energies for the S-protein to human ACE2 binding complexes were calculated by MOE 2019 with amber ff14SB force field parameters (Maier et al., 2015). The binding free energy between the Wuhan CoV S-protein and human ACE2 was –50.6 kcal mol–1, whereas that between SARS-CoV S-protein and ACE2 was –78.6 kcal mol–1. A value of –10 kcal mol–1 is usually considered significant. Because of the loss of hydrogen bond interactions due to replacing Arg426 with Asn426 in the Wuhan CoV S-protein, the binding free energy for the Wuhan CoV S-protein increased by 28 kcal mol–1 when compared to the SARS-CoV S-protein binding. Although comparably weaker, the Wuhan CoV S-protein is regarded to have strong binding affinity to human ACE2. So to our surprise, despite replacing four out of five important interface amino acid residues, the Wuhan CoV S-protein was found to have a significant binding affinity to human ACE2. Looking more closely, the replacing residues at positions 442, 472, 479, and 487 in the Wuhan CoV S-protein did not alter the structural confirmation. The Wuhan CoV S-protein and SARS-CoV S-protein shared an almost identical 3-D structure in the RBD domain, thus maintaining similar van der Waals and electrostatic properties in the interaction interface.
In summary, our analysis showed that the Wuhan CoV shared with the SARS/SARS-like coronaviruses a common ancestor that resembles the bat coronavirus HKU9-1. Our work points to the important discovery that the RBD domain of the Wuhan CoV S-protein supports strong interaction with human ACE2 molecules despite its sequence diversity with SARS-CoV S-protein. Thus the Wuhan CoV poses a significant public health risk for human transmission via the S-protein–ACE2 binding pathway. People also need to be reminded that risk and dynamic of cross-species or human-to-human transmission of coronaviruses are also affected by many other factors, like the host’s immune response, viral replication efficiency, or virus mutation rate.
The world’s largest composite cable-saddle bridge Xiangli Expressway Tiger Leaping Gorge Jinshajiang Bridge
世界上最大的複合索鞍——香麗高速虎跳峽金沙江特大橋複合索鞍安裝完成。至此,香麗高速虎跳峽金沙江特大橋2套主索鞍、2個散索鞍、2個複合索鞍全部安裝到位,大橋即將進入主纜安裝施工。
The two sides of the bridge were joined together on Monday. With a total length of 1,017 meters, the bridge is a key project of the construction of the Shangri-La-Lijiang expressway.
China-Russia highway bridge ready for opening
The first highway bridge connecting #China and #Russia across the Heilongjiang River has recently passed the final acceptance test, the department of transport of Northeast China’s Heilongjiang province said Friday.
Experts with Harbin Institute of Technology and counterparts of the Russian side participated in the test on Tuesday. The maximum load capacity of the bridge reached 318 tonnes during the test.
The bridge is expected to open in April, according to the provincial transport department.
Measuring 1,284 meters long and 14.5 meters wide, the bridge across the Heilongjiang River, known in Russia as the Amur River, stretches from Heihe, a border city in Heilongjiang province, to the Russian city of Blagoveshchensk. Two sides of the bridge were joined together on May 31, 2019.
Brazil inaugurates state-of-the-art Chinese built Antarctic base
Brazil inaugurated a brand new state-of-the-art research station in Antarctica this week.
It took eight years and an investment of almost 100 million dollars to build Brazil’s new research station, after the old one was destroyed in a fire in 2012.
This Comandante Ferraz Antarctic Station is entirely new and built by the Chinese company CEIEC, chosen through an international bidding process.
Myanmar, China ink deals to accelerate Belt and Road as Xi courts an isolated Suu Kyi
https://www.reuters.com/article/us-myanmar-china/myanmar-china-ink-deals-to-accelerate-belt-and-road-as-xi-courts-an-isolated-suu-kyi-idUSKBN1ZH054?feedType=RSS&feedName=worldNews&utm_source=feedburner&utm_medium=feed&utm_campaign=Feed%3A+Reuters%2FworldNews+%28Reuters+World+News%29&fbclid=IwAR0lkT1mkNxGtA1zEswIalzFB_fg0BA6egMBwBsvD4drcVqm_jDLbpstIh0
China and Myanmar inked dozens of deals on Saturday to speed up infrastructure projects in the Southeast Asian nation, as Beijing seeks to cement its hold over a neighbor increasingly isolated by the West.
Xi and Myanmar leader Aung San Suu Kyi signed 33 agreements shoring up key projects that are part of the flagship Belt and Road Initiative.
They agreed to hasten implementation of the China Myanmar Economic Corridor, a giant infrastructure scheme worth billions of dollars, with agreements on railways linking southwestern China to the Indian Ocean, a deep sea-port in conflict-riven Rakhine state, a special economic zone on the border, and a new city project in the commercial capital of Yangon.
Building a bridge span without any support from below
位于乌蒙山区川滇黔交界处的鸡鸣三省大桥全面建成通车。鸡鸣三省大桥位于我国集中连片特困地区乌蒙山区深处,此处渭河与倒流河交汇入赤水河,形成的“Y”字形大峡谷将四川、云南、贵州三省分割开来,每个省的扇形区域都是临崖绝壁,属于地理区位上的交通死角。鸡鸣三省大桥的建成,不仅解决了群众长久以来相互隔绝、相望难相通的历史,还将贯通鸡鸣三省一带独特的峡谷自然风光和红色旅游资源,密切三省之间的经济往来,助推脱贫攻坚。
False killer whale (Pseudorca crassidens) Victoria Harbour, Hong Kong
False killer whale (Pseudorca crassidens) 伪虎鲸 1-17-20 香港维多利亚港 Victoria Harbour, Hong Kong. Rare appearance, not since 2015.