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#ScienceMag Ambient-pressure synthesis of ethylene glycol catalyzed by C₆₀-buffered Cu/SiO₂ https://science.org/doi/10.1126/science.abm9257… fullerene can act as an electron buffer for a copper-silica catalyst. Hydrogenation of dimethyl oxalate over a C₆₀-Cu/SiO₂ had an ethylene glycol yield 98±1%.

#ScienceMag Fullerenes make copper catalysis better https://science.org/doi/10.1126/science.abo3155… In the bulk production of ethylene glycol from dimethyl oxalate, high pressure of hydrogen gas is usually needed. This can be problematic from an engineering and safety perspective. Fulleneres solve it.
 
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Chinese scientists create human stem cells by dint of chemicals

Source: Xinhua Editor: huaxia
2022-04-18 16:52:45

BEIJING, April 18 (Xinhua) -- Chinese scientists have translated human somatic cells back into pluripotent stem cells, an "adult" version of early embryonic cells, using chemical molecules.

A group of researchers led by Deng Hongkui from Peking University reported finding the chemical cellular reprogramming technique for the first time ever.

Previously, the cell-intrinsic components, including oocyte cytoplasm and transcription factors, are used to reprogram cells in human tissue or organs into pluripotent stem cells that can propagate to give rise to every other cell type in the body.

Inspired by how lower animals like axolotl regenerate its limb, the researchers demonstrated that the highly differentiated human somatic cells could experience plastic changes, triggered by certain chemical molecules, according to the study published recently in the journal Nature.

Then they successfully singled out a group of chemicals that help lead to the dedifferentiation of the cells, finally inducing pluripotent stem cells that exhibit key features of embryonic stem cells.

They identified a molecular pathway called JNK as a major barrier to chemical reprogramming, the inhibition of which was therefore indispensable for creating cell plasticity and a regeneration-like program, according to the study.

The chemical reprogramming is "safer, simpler and easier to be standardized and used clinically" than previously known approaches, said Deng, the paper's co-corresponding author.

The technique can be developed into universal knowhow to efficiently cultivate human cells of various functions, offering new possibilities for treating critical illnesses, the researchers said.

 
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Chinese scientists produce glucose, fatty acids with carbon dioxide

Source: Xinhua Editor: huaxia
2022-04-29 14:49:43

BEIJING, April 29 (Xinhua) -- Chinese scientists have developed a new method to translate carbon dioxide and water into glucose and fatty acids.

The technique comes after another group in China successfully synthesized starch from carbon dioxide in 2021, and it has provided fresh potential for artificial or semi-artificial food production.

The researchers from the University of Electronic Science and Technology of China, the University of Science and Technology of China and the Chinese Academy of Sciences described a hybrid electro-biosystem in a study published in the journal Nature Catalysis on Thursday.

The system couples spatially separate carbon dioxide electrolysis with yeast fermentation, which efficiently converts carbon dioxide into glucose with a high yield.

It employs a nanostructured copper catalyst that can stably catalyze pure acetic acid from carbon dioxide, and then use genetically engineered yeast to produce glucose in vitro from electro-generated acetic acid.

The method is also shown to be capable of producing other products like fatty acids using carbon dioxide, according to the study.

"This process can be understood as converting carbon dioxide into vinegar and feeding the yeast to produce glucose and fatty acids," said Zeng Jie, the paper's co-corresponding author from the University of Science and Technology of China.

The upcycling of carbon dioxide into value-added products represents the tantalizing possibility of a renewable-electricity-driven manufacturing industry and a substantially untapped opportunity to tackle environmental issues and achieve a circular economy, the researchers said.

"With an electrolyte reactor and different microorganisms, we can produce starch, pigment or medicines in the future," said Xia Chuan, the paper's co-corresponding author from the University of Electronic Science and Technology of China.

 
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China has developed Asia's 1st 9.4T ultrahigh field MRI system for human whole body imaging. Compared to MRI system for routine clinical application, this new system can obtain images with higher resolution in less time and visualize rare components in human bodies.
 
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In my view, the only war between the West, and Russia-China Axis is the Chip industry, especially semiconductors. China is breaking the West monopoly by producing its own Lithograpy Machine.
At this stage China is producing 28-14 nanometres Lithography machines, the next step could be reached in a few years. After 2025 it is reasonable to think that China will be able to make a Lithography Machine that can produce 1-nanometer chip, ending once for all the Western monopoly in this area.
China self reliance on the production of semiconductors is good news for the rest of the world, but not for the USA. I think America is on the verge of expelling China's high-tech companies out of the western world. It could trigger a real war.
If someone among you does have other news please bring them.
 
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New study hails effectiveness of China-made cancer drug

By Zhou Wenting | chinadaily.com.cn | Updated: 2022-06-08 18:21

A clinical study recently published in the Journal of Clinical Oncology, the official journal of the American Society of Clinical Oncology, has shown that a China-developed pill containing third-generation EGFR-tyrosine kinase inhibitors (TKI) can offer the longest progression-free survival among Chinese patients suffering from non-small cell lung cancer.

Led by a team of researchers from Shanghai Chest Hospital, the study also found that the drug, almonertinib, can significantly reduce risks of disease progression and death in patients with brain metastases and certain gene mutations.

China's first and the world's second third-general EGFR targeted therapy, almonertinib has been considered a breakthrough in cancer treatment in China as it provides domestic patients with another avenue for advanced lung cancer treatment. Previously, patients could only rely on imported drugs.

The drug received approved for use in China in April 2020.

The clinical study of 429 participants showed that the drug, compared with the first-generation targeted therapy, could increase progression-free survival from 9.9 months to 19.3 months, while reducing the risk of disease progression by 62 percent.

The progression-free survival of participants with brain metastases was also increased by 8.2 months to 15.3 months.

"The results of this study can better represent the benefits of Chinese patients, and have high clinical value for the treatment of the entire Asian population as well," said Jian Hong, a doctor of tumor treatment at Shanghai Chest Hospital.

 
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Gene Interaction That Contributes to Rice Heat Tolerance Identified​

Editor: CHEN Na | Jun 17, 2022

Molecular pinpoint could lead to more heat resistant rice cultivation, researchers say

W020220617390580927251.jpg

Rice is one of the most important staple crops, on which more than half of the world’s population depends. But as temperatures rise and extreme weather events increase, rice is becoming more vulnerable. Genetically modified strains can withstand some flooding, but few, if any, can survive the heat stress caused by the combination of high temperatures and draught. There may be hardier crops on the horizon, though, with the help of a molecular map that details the specific gene interactions that control how tolerant rice is to heat.

Published June 17 in Science, the map may not lead to pirate treasure, according to the study authors, but it does lay the foundation for something far more valuable to far more people — food security.

"During its lifecycle, rice is easily influenced by heat stress, and it’s even more vulnerable under global warming,” said corresponding author LIN Hongxuan, professor, National Key Laboratory of Plant Molecular Genetics, Chinese Academy of Science Centre for Excellence in Molecular Plant Sciences, Shanghai Institute of Plant Physiology and Ecology. “Improving the thermal tolerance of rice plays a key role in maintaining and increasing the yield of rice crops under high temperatures, ensuring supply for the food demand of the world population.”

The thermal tolerance of rice is a quantitative trait that results from how multiple genes interact, as well as input from the environment. According to Lin, plants have multiple mechanism developed specifically to protect themselves against heat, but how the cells sense high temperatures and communicate that information internally has remained elusive — until now.

In a series of experiments with African and Asian rice varieties, the researchers knocked out various genes and studied how that influenced the genetic make-up and physical manifestation of the resulting plants.

"We found that a genetic module in rice links heat signals from the cell’s plasma membrane to its internal chloroplasts to protect them from heat-stress damage and increase grain yield under heat stress,” Lin said.

Dubbed thermotolerance 3, or TT3, the genetic module is the physical location in the cell’s genetic material containing the genes, TT3.1 and TT3.2, that interact to enhance rice thermotolerance. A piece of TT3.1 appears to serve as a heat sensor, as it moves away from the plasma membrane to the cell’s transport pathway, where it tags its partner, TT3.2, to be degraded and removed by the cell. TT3.2 is involved in jeopardizing chloroplasts, and the cell can better protect against heat stress when the abundance of TT3.2 is decreased in chloroplasts, according to LIN.

In the plant analysis, the researchers found that TT3, whether it occurred naturally or was genetically edited, enhanced heat tolerance and reduce yield loss caused by heat stress.

"After seven years of effort, we successfully finely mapped and cloned a newly identified thermotolerant rice module, comprising two genes, and revealed a new plant thermotolerant mechanism,” Li said. “This study demonstrates that this genetic interaction can enhance the thermotolerance of rice, significantly reduce the yield loss caused by heat stress and maintain the stable yield of rice.”

The researchers plan to continue identifying thermotolerant genes and developing genetic resources to integrate into crop breeding.

"The genes we have already identified are conserved in other major crops, such as maize and wheat,” Lin said. “They are valuable resources for breeding highly heat stress-tolerant crops to address food security concerns caused by global warming.”

The National Natural Science Foundation of China, CAS, Laboratory of Lingnan Modern Agriculture Project, Shanghai Jiao Tong University, CAS-Croucher Funding Scheme for Joint Laboratories and National Key Laboratory of Plant Molecular Genetics supported this work.

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Phenotypes of mature plants and total grains per plant in NIL-TT3, WYJ, overexpression-TT3.1CG14 (OE-TT3.1CG14) and tt3.2 mutant plants after 30 days of high temperature treatment (38° and 34°C, day and night) at the heading stage. Scale bars, 5cm (Credit to Science)

Rice is one of the most important staple crops, on which more than half of the world’s population depends. But as temperatures rise and extreme weather events increase, rice is becoming more vulnerable. Genetically modified strains can withstand some flooding, but few, if any, can survive the heat stress caused by the combination of high temperatures and draught. There may be hardier crops on the horizon, though, with the help of a molecular map that details the specific gene interactions that control how tolerant rice is to heat. Published today (June 17) in Science, the map may not lead to pirate treasure, according to the study authors, but it does lay the foundation for something far more valuable to far more people — food security.

 
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Scientists take the first step to master an all-powerful cell type in the beginning of life


NEWS PROVIDED BY
School of Pharmaceutical Sciences, Tsinghua University
Jun 21, 2022, 11:10 ET

BEIJING, June 21, 2022 /PRNewswire/ -- From cloning to regeneration, how to find alternative paths to create or rejuvenate life has been one of the big questions for biologists. It is this question that's behind the work of generations of scientists who went on to win Nobel Prizes. It is also this question that drives the recent research led by Sheng Ding at Tsinghua University, School of Pharmaceutical Sciences, now published in the top scientific journal Nature magazine.

Chemically induced ciTotiSC from mESC (OCT4-green fluorescence-labeled pluripotent stem cells and MERVL-red fluorescence-labeled totipotent stem cells)
Chemically induced ciTotiSC from mESC (OCT4-green fluorescence-labeled pluripotent stem cells and MERVL-red fluorescence-labeled totipotent stem cells)

In the current study, Ding and colleagues have identified a drug cocktail that induces an all-powerful stem cell type at will, a cell type that can turn into an entire organism on its own. The researchers are also able to maintain the resulting cells' differentiation potential in the lab, allowing a stable system for later researchers to demystify the creation of life. This alternative path – obtaining a clean slate of life's earliest raw materials from more mature cells, instead of new sperms and eggs -- can have a wide range of implications. "Such an alternate to nature's way of creating the beginning of life is a holy grail of biology", Ding says.

The creation of life starts with one cell. Your blood, brain, and liver cells can all be traced back to this one-cell embryo or zygote.

In nature, a zygote is produced as sperm and egg merge together. And the event kicks off an irreversible process where the zygote divides, forms new cells and the new cells continue to divide and become increasingly specialized.

As specialization is gained, something is lost along the way. Once the one-cell embryo divides and hits the two-cell embryo stage, the later cells will quickly lose the differentiation potential to give rise to all cell types for generating an entire organism and its supportive tissues like the yolk sac and placenta, becoming less potent stem cells.

Scientists call these all-powerful cells in the one-cell and two-cell embryo stages totipotent stem cells. And there are pluripotent and multipotent stem cells further down the continuum. "Normally after totipotent cells, none of the other stem cells have the possibility to turn into a life on its own," Ding says.

To better study and control the totipotent stem cells, Ding and his team established a system that achieves the induction and maintenance of these cells, and confirmed their identity with stringent criteria.

With 20 years of work and understanding of cell fate and stem cell regulation by chemical compounds, the team selected and screened thousands of small molecule combinations. Through multiple rounds of analyses, they identified three small molecules that could coax mouse pluripotent stem cells into cells exhibiting totipotent characteristics. The researchers called the molecules TAW cocktail. Each letter in TAW stands for a molecule known to regulate a specific cell fate decision. But their combined effect was not known till the current discovery, Ding explains.

Then the researchers examined cells receiving the TAW cocktail treatment in detail, both their totipotency and none-pluripotency. These cells passed strict molecular testing criteria, at all transcriptome, epigenome, and metabolome levels. For example, the team found that hundreds of critical genes were turned on in the TAW cells. These genes are typically found in totipotent cells and have been indicated by other researchers in the field as the bar to determine totipotency. At the same time, genes associated with pluripotent cells were silenced in the TAW cells.

To further prove that the resulting cells have a true totipotent state, the team tested their differentiation potential in vitro, and also injected them into a mouse early embryo to see the differentiation potential in vivo. They found that not only did the cells behave like true totipotent ones in a petri dish, but they also differentiated into both embryonic and extraembryonic lineages in vivo. This is a typical characteristic of normal totipotent cells, which have the potential to develop into both fetus and the surrounding yolk sac and placenta, whereas pluripotent cells can only develop into a fetus.

In addition, when the researchers used special culture conditions for the TAW cocktail-induced totipotent cells, the subsequent cells also showed similar totipotency traits. This observation suggests that the totipotency of TAW-induced cells can be maintained in a lab environment, and thus a stable system is established.

Such a system is important, as it will enable many scientific investigations concerning the beginning of life. For example, scientists can use this system to manipulate the totipotent cells to better understand the highly orchestrated process at the beginning of life. "Certain cells will have to appear at the right time and the right location for life to occur," Ding says, and one cannot study this without proper tools.

In this sense, "this paper is the first step and opens up tremendous opportunities," he says.

Moreover, having a deeper understanding and thus control over totipotent cells will have a wide range of implications, such as earning a second chance at the creation of individual life and even accelerating the evolution of a species.

Many of the possibilities will spur controversies, Ding acknowledges. It's worth noting that while those possibilities lie in the distant future, he mentions, it's hard to predict what society's ethical concerns will be. After all, the science community hasn't seen any lighter restrictions around human embryo research in the past decade. But last year, people started to seriously consider extending how long a human embryo can be kept in a petri dish from the original 14-days rule.

While the team is highly conscious of ethical considerations, Ding believes that as scientists their main job is to focus on making discoveries in the present, and lay the ground for future generations. Then the latter will have the knowledge and tools to make decisions.

SOURCE School of Pharmaceutical Sciences, Tsinghua University

 
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Chinese e-vehicle battery Qilin enables 1,000-km journey on single charge. With the third generation of cell-to-pack technology, the battery has a volume utilization efficiency of 72% and an energy density of up to 255 Wh/kg for ternary battery systems, said battery maker CATL.
 
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