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New Epigenetic Mark Confirmed in Mammals

The most all around examined epigenetic imprint is methylation of cytosine, and in reality 5-methylcytosine (the connection of a methyl gathering to the fifth particle in the six-molecule ring, checking counterclockwise from the nitrogen at the base) was the main known kind of methylation in mammalian cells, as indicated by GenomeWeb. In any case, analysts from Yale University have recorded that mammalian adenine bases can likewise convey methylation marks. The group distributed its outcomes this week (March 3) in Nature.

Adenine methylation, called N6-methyladenine, has for some time been known not in bacterial genomes, and was as of late found in the DNA of a few bugs, worms, and plants, too. At that point last December, a U.K.- based examination bunch discovered proof that the epigenetic imprint may likewise exist in grown-up human and mouse cells. Presently, Yale's Andrew Xiao and his associates have affirmed this finding in mouse immature microorganisms, distinguishing N6-methyladenine around six or seven times for each 1 million adenine bases—a few requests of size less as often as possible than cytosine methylation.

"Adenine methylation in DNA was completely disregarded for quite a while," Gerd Pfeifer of the Van Andel Research Institute in Grand Rapids, Michigan, who was not included in the study told Chemical and Engineering News (C&EN).

Xiao's group additionally distinguished the chemical (Alkbh1) in charge of expelling adenine methylation. Alkbh1-lacking cells had expanded levels of N6-methyladenine, prompting transcriptional quieting. The methylation stamp additionally relates with the quieting of LINE-1 transposons, the scientists discovered, in opposition to thinks about on worms and flies that recommend adenine methylation actuates close-by qualities.

"I've invested a considerable measure of energy attempting to make sense of this distinction," Xiao told C&EN. "We have to do significantly more research before we can interface every one of the dabs."
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Zooming In on an Antidepressant Target

Analysts at the Vollum Institute in Portland, Oregon, have determined the precious stone structures of the human serotonin transporter (SERT) bound to two distinctive energizer drugs. The structures show where the medications tie, how they hinder transporter capacity, and offer bits of knowledge for the configuration and advancement of new psychiatric pharmaceuticals.

"There are no other human transporters in this family that have been solidified and where we know the structure, so [the paper] is a turning point in that sense," said pharmacologist Gary Rudnick of Yale University who was not included in the study. "The structure can be utilized to comprehend insights about the way the protein works, the way it ties ligands [and] for medication improvement," he included.

Serotonin is a neurotransmitter that impacts neurological frameworks, for example, temperament, rest, perception, and yearning. Particular serotonin reuptake inhibitors (SSRIs) are medications that drag out the nearness, and consequently movement, of serotonin in neural neurotransmitters, and are utilized as a part of the treatment of wretchedness, tension and other related issue. They work by authoritative and inactivating SERT, which ordinarily transports serotonin from neurotransmitters into presynaptic neurons, however precisely where and how SSRIs tie has not been completely decided.

SERT is an individual from a substantial group of neurotransmitter sodium symporters (NSS) that incorporates the transporters for dopamine and norepinephrine. These NSS proteins are indispensable layer components, confounding basic examination by X-beam crystallography. "Layer proteins have a tendency to be happiest in a film bilayer," said Eric Gouaux of the Vollum Institute, who drove the concentrate, "however it turns out we can't ponder them exceptionally well in a layer, so we need to concentrate them." The issue is, without the backing of the encompassing layer the proteins turn out to be profoundly temperamental. "The human serotonin transporter was especially finicky," Gouaux said.

To handle the insecurity issue, the scientists efficiently presented transformations in SERT until they discovered ones that balanced out the free protein yet kept up its capacity. They additionally found that partner SERT with a SSRI kept up the protein's structure. "[The drugs] truly bolt the atom into a specific shape," said Gouaux, "so it's simpler to make precious stones."

The X-beam structures uncovered that a solitary atom of the SSRI paroxetine bound inside a depression that achieved profound into the transporter. By difference, two particles of the SSRI (S)- citalopram were found to tie SERT—one in the same spot as paroxetine (the assumed restricting site for serotonin), and another in an adjacent split inside the same pit.

The revelation of the second restricting site for (S)- citalopram affirms past proof for an allosteric site. Thinks about had demonstrated that high convergences of the medication could drag out its authoritative to SERT. As a result, "it recommends that the medication itself can upgrade its own particular capacity," said neuroscientist and pharmacologist Ulrik Gether of the University of Copenhagen who additionally did not partake in the study.

This allosteric site gives an extra conceivable medication target, clarified Gether. For instance, "you could outline particles with especially high liking for that site that could upgrade the impacts of different medications," he said. By and large, the precious stone structures could likewise advise changes to existing SSRIs, maybe making them more particular and compelling.

Both medications settled SERT in an "outward-open" adaptation, implying that, were the transporter in its typical film area, it would be kept from opening into the cytoplasm—important for transporting serotonin into the cell. The structures consequently clarify how the medications work, yet Gouaux and associates might likewise want to decide how serotonin, itself, is transported.

Deciding the structure of SERT bound to serotonin, be that as it may, "is a harder issue," said Gouaux. "At the point when serotonin is bound, the transporter is doing its regular thing of moving forward and backward and that makes perception testing," he clarified. "We need to figure out how to trap specific conditions of the transporter with the goal that we can basically develop a motion picture of this procedure [from] basic previews."
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“Hunger Hormone” No More?

Transgenic mice with an overactive type of the receptor for ghrelin—regularly named the "yearning hormone"— don't have the expanded voracities one may expect, yet still put on weight, as indicated by a paper distributed yesterday (April 19) in Science Signaling. The outcomes propose that the long-held perspective of ghrelin as a controller of sustenance admission may not be completely precise. However, not everybody is persuaded.

"It's a mentally charming finding," said Yale School of Medicine's Tamas Horvath who was not included in the study. "Am I 100 percent persuaded this demonstrates ghrelin has no impact on bolstering? No. Yet, I feel that [the authors] concoct a provocative arrangement of information and I think . . . it will start more exhaustive studies on this imperative inquiry," he included.

Ghrelin and its lone known receptor, the development hormone secretagogue receptor (GHSR), have been involved in, in addition to other things, sustenance consumption, development hormone discharge, and the generation of greasy tissue (adipogenesis). Infusions of ghrelin, for instance, have been appeared to build sustenance consumption and adipogenesis in rodents. In people, levels of ghrelin in the blood have been found to crest just before a supper—conceivably animating nourishment looking for conduct.

Be that as it may, endeavors to research how the hormone and receptor apply these impacts have just befuddled matters, said Jacques Pantel of INSERM's Center for Psychiatry and Neuroscience in Paris who drove the new study. Hereditary erasures of ghrelin, or GHSR, for instance, did not create the normal results. "The creatures were not anorexic," Pantel said, which was "a major frustration."

Since eating is so crucial for survival, it's conceivable that the complete expulsion of ghrelin or GHSR from these creatures may have advanced compensatory qualities and pathways to kick in, said Pantel. So to maintain a strategic distance from conceivable bewildering impacts of pay, Pantel and his associates utilized transgenic rats that needed just a little portion of GHSR—the distal tip—instead of the entire protein. They demonstrated that in refined cells and transgenic creatures, this mutant receptor had expanded movement in light of ghrelin contrasted and the wild-sort receptor.

In particular, the addition of-capacity change expanded GHSR motioning in light of ghrelin in refined human cells, and expanded the receptor's affectability to infused ghrelin in the transgenic creatures: development hormone discharge and sustenance admission were empowered by lower measurements of ghrelin in the transgenic creatures than in wild-sort creatures. Beside expanded action, notwithstanding, the reaction to infused ghrelin was comparative.

The reaction to endogenous ghrelin, then again, perplexed the group. While GHSR transgenic creatures nourished a standard eating regimen put on more weight than control creatures (which would be normal with a more dynamic ghrelin-GHSR pathway), this was not the aftereffect of expanded sustenance admission. "Surprisingly, for a purported orexigenic hormone, these creatures were not eating all the more relatively contrasted with their wild-sort partners," Pantel said.

Rather, Pantel thinks the weight pick up, which was particularly because of expanded muscle to fat quotients, may be on the grounds that "the hormone is assuming to a greater degree a part in fat stockpiling," he said. In light of this, he proposed that the watched top in ghrelin preceding suppers won't not drive the quest for sustenance, but rather "setting up a living being to metabolize and store the [incoming] vitality."

Why, then, would infused yet not endogenous ghrelin help ravenousness? It's a long way from clear, said Pantel, yet one plausibility is that infusion gives such a sudden huge measurements of the hormone that it enacts GHSR receptors in specific parts of the cerebrum that typical endogenous vacillations would not. Such atypical incitement may then by one means or another trigger voracity.

Neuroscientist Sebastien Bouret of the University of Southern California who was not included in the study said he questions that endogenous ghrelin does not influence nourishment consumption, nonetheless. He said he supposes it is still conceivable a compensatory component, though one that decreases the normal gorging, could be grinding away in the transgenic creatures. "The perfect examination would be to have this addition of capacity solely amid grown-up life. . . with the goal that we won't have the compensatory instrument," he said. "At that point we would have the capacity to make an exceptionally solid conclusion."
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More Than Skin Deep

In 1978, Elaine Fuchs was only one year into a postdoctoral association at MIT when her PhD counselor, Charles Gilvarg of Princeton University, called to educate her regarding an accessible scholastic position at the University of Chicago. "He recalled that my family was from Chicago and that I might need to about-face," says Fuchs, now a teacher of sub-atomic hereditary qualities and cell science at Rockefeller University in New York City. "I let him know that was fine yet that I was all the while doing my postdoc, and he said that he would suggest me at any rate. I could regard the meeting as practice, he clarified, to get a feeling of what it resembled, for when I was prepared to land a position." Fuchs was welcomed for the meeting and the college's organic chemistry office took as much time as is needed choosing, at last offering her a partner residency in the fall of 1979. "I was casual, as it never jumped out at me that I would land a position offer," she says. "Conceivably, the office took as much time as necessary since I had let them know I hadn't connected anyplace else." Fuchs asked for one more year to complete her postdoc in Howard Green's research facility, where she was considering the science of refined human keratinocytes, the most bounteous cell sort found in the epidermis, the skin's defensive boundary at our body's surface.

"I completed an entire three years at MIT. What was pleasant in that last year was that I could arrange out precisely what I needed to do in my own particular lab. I composed for and had my NIH stipend before I touched base in Chicago. It was a truly decent formula to waste no time. Presently, thinking back, it was somewhat of a ready to-succeed circumstance," says Fuchs.
Since her time in the Green lab very nearly four decades prior, Fuchs has been snared on translating and disentangling the muddled science of epidermal cells. In her own labs at the University of Chicago and now at Rockefeller University, Fuchs has utilized the epidermal-cell society framework to characterize epithelial foundational microorganisms, extending her discoveries to comprehend fundamental standards of multipotent cells when all is said in done. Her exploration has additionally handled the science of other cell sorts inside the epidermis, distinguishing the begetter cells that offer ascent to sweat organs and conduits and segregating hair-follicle undifferentiated organisms. Fuchs' lab was additionally among the first to portray a malignancy foundational microorganism.

Here, Fuchs follows her exploration way from keratins to undeveloped cells, and talks about her hard working attitude and her adoration for world travel.

Fuchs Fascinated

Rural Chicago. Fuchs experienced childhood in a suburb of Chicago that at the time, in the late 1950s and 1960s, was "not so much suburb but rather more cornfields," she says. At home, her dad made furniture for the house, and her mom sewed attire for Fuchs and her sister furthermore oiled painting. Her folks kept an expansive bloom and vegetable greenery enclosure amid the spring and summer months. "I experienced childhood in an extremely dynamic, self-managing environment back in the days when we were permitted to stay out from after breakfast until it got to be dim outside," says Fuchs. "My mother made us butterfly nets and sent us out to the bogs and fields."

Limited appear. Fuchs' family lived close Argonne National Laboratory, which is subsidized by the US Department of Energy. Fuchs found out about how research is directed from her dad, Louis Fuchs, who was a geochemist there, taking a shot at distinguishing novel minerals in shooting star tests. The main mineralogist utilized at Argonne, he had found 8 of the 13 known extraterrestrial minerals when he resigned. "My dad was surely understood in the field, yet was truly a small time appear. He had an electron magnifying lens and worked generally all alone," says Fuchs.

In quest for science. "The movement into science in school was characteristic," says Fuchs, whose more seasoned sister, Jannon Fuchs, is currently a neuroscientist at the University of North Texas. Her auntie, a University of Chicago alum, couldn't get into medicinal school since she was female. "She was a women's activist and supported my sister and me to accomplish something significant with our lives." Fuchs entered the University of Illinois in 1968 and majored in science on the grounds that, as indicated by her, the college's science program at the time was not as solid as those in science and material science. She researched while in school—including at Argonne for a late spring—and delighted in playing out the examinations, however didn't feel especially proficient at doing science.

Logical control. In the wake of graduating in 1972, Fuchs started graduate work at Princeton in the natural chemistry office. She floated towards the metabolic pathways she was finding out about in Gilvarg's class and joined his lab. Fuchs dealt with bacterial cell divider biosynthesis, investigating how lethargic spores from Bacillus megaterium get to be actuated and redesign their cell dividers to oblige a quickly isolating state. "It took my whole graduate vocation to wind up OK with atomic science and organic chemistry," she says. "What I picked up from my consultant was the capacity to deliberately plan an appropriately controlled examination. I understood later that this is more basic to turning into a decent researcher than whatever else."

Fuchs Focuses

Solid cell science balance. Next, Fuchs chose to concentrate how human cells make tissues, joining Green's lab at MIT in 1977. "I needed to dismantle the cell's science and organic chemistry and preferred working with a cell-society framework," she says. Fuchs had heard a workshop by Green, who had built up the 3T3 fibroblast cell line and was likewise the first to culture epithelial cells, which required a layer of illuminated "feeder" fibroblast cells keeping in mind the end goal to develop in the lab. The epithelial cells Green was considering were human keratinocytes, skin cells that make up around 90 percent of the phones of the epidermis, where they possess the basal layer of the stratified epithelium. "He didn't call them undeveloped cells, yet basically that is the thing that they were. These were cells that you could take from human skin, section long haul in society, and prompt them to make separated tissue," Fuchs says. "Green essentially opened up the way to the foundational microorganism field as we probably am aware it."

Fuchs distributed three Cell papers, one for every year spent at MIT. To begin with, utilizing an enzymatic protein cleavage response, she showed that keratins—the copious stringy, auxiliary proteins that shield epithelial cells from mechanical hassles—were likely unmistakable proteins originating from particular qualities as opposed to beginning from one single protein that is cut posttranslationally. For the second paper, Fuchs fractionated RNA species, isolated them on methylmercury gels, and demonstrated that human keratins are without a doubt coded by unmistakable errand person RNAs. The third paper appeared, surprisingly, that keratins are differentially communicated amid terminal separation inside the epidermis as well as in various epithelial tissues. "This is an idea we now underestimate, yet at the time, it was a critical finding. The utilization of particular middle of the road fiber proteins like keratins to distinguish a specific cell sort and phase of separation has been colossally valuable to pathologists in the conclusion of malignancies and other human ailment states," clarifies Fuchs. "The finding likewise framed the establishment of our comprehension of what are currently more than 20 human issue of halfway fiber qualities."

Towards autonomy. "It was shocking to go from physical science to organic chemistry and after that cell science. It took me always to get it. There were constantly very numerous variables in science. In science you could simply illuminate conditions however you can't explain conditions in science. It took me my entire graduate profession to feel great with that idea," Fuchs says. "And afterward, amid my postdoc, that is the point at which I began to understand that I didn't need to depend upon my preparation or my lab to direct my examination. When I expected to learn something, I could discover another lab to learn it. Somebody at MIT quite often had the mastery I expected to figure out how to advance my examination. This helped me create abilities to end up intuitive and to truly run a venture myself. So I was ingenious and gainful, yet despite everything I didn't think I was doing uncommonly well. A Cell paper didn't generally mean much to me at the time. I just thought this was a distribution like some other. I was simply satisfied with what I was doing and what I was finding."

Hard working attitudes. Fuchs began her own particular lab at the University of Chicago in 1980. "I practically knew precisely what I needed to do when I began my lab. I didn't have an expert or graduate understudy. I just began doing probes my own particular after I had tidied up the lab and office I acquired. After two months, the office seat descended and inquired as to whether I was always going to employ a specialist. I was so innocent. I realized what I needed to do and how to do it, and I would not like to take out time to meeting or prepare anybody," says Fuchs. "I contracted the main individual I met and she was great, and I understood that she was truly useful. Both of us did all the work for the primary year. I was extremely mindful about taking individuals on and just taking great individuals, and I very suggest that course."

Getting down to business. Fuchs' lab quickly started to clone and portray the different keratins and their qualities. As her lab developed, they started doing in vitro fiber get together studies with recombinant proteins, and they built changes that bothered keratin fiber get together in a test tube and in refined keratinocytes. Protein physicists had attempted unsuccessfully for quite a long time to take shape keratins, however remained obstructed by the proteins' inclination to self-total. By getting the protein arrangements through cloning and DNA sequencing, Fuchs defeated these obstacles. Utilizing transgenic strategies, the lab made mice that communicated different keratin mutants to disentangle their capacities. Point changes in one of the keratin qualities brought about mice with a malady much the same as epidermolysis bullosa simplex (EBS), a human skin sickness portrayed by serious rankling. From skin biopsies got from such patients, her group checked that EBS, and other related skin issue, originated from keratin transformations.

Fuchs Flourishes

A major move. While still at the University of Chicago, Fuchs started to disconnect and describe the cells from skin that could make new tissue or repair injured tissue. This included distinguishing the flagging pathways included and the cell connection fundamental for self-restoration. Fuchs' group demonstrated that Wnt is a basic sign for enacting immature microorganisms to make follicles. Subsequent to pressing up the lab—incorporating three trucks loaded with research center mice—and moving to Rockefeller University in New York in 2002, the group built up an approach to fluorescently tag moderate multiplying cells by naming a histone, checking undifferentiated cells by their one of a kind calm property. "It was a smart system, additionally let us illustrate, in transplantation measures, that these cells were carrying on like immature microorganisms," says Fuchs. "After that, we could screen their conduct in typical tissue arrangement, wound repair, and afterward threatening change." That same year, the lab demonstrated that these undifferentiated organisms could make epidermis and hair when united onto the backs of naked (smooth) mice.

A fragile equalization. In 2011, Fuchs' lab characterized the undifferentiated organisms that can start squamous cell carcinoma, a sort of skin growth, and described the flagging pathways that drive harm. "Undeveloped cells in their specialty are quie
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Observing the Nuclear Pore

Utilizing ultra quick examining nuclear power microscopy (AFM), researchers have taped atomic pore edifices in real life surprisingly. The work uncovers how these structures specifically ban a few substances from entering the core, analysts at the University of Basel, Switzerland, reported today (May 2) in Nature Nanotechnology.

"With the fast AFM we could, interestingly, look inside local atomic pore buildings just forty nanometers in size," study coauthor Roderick Lim of the University of Basel said in an announcement. "This technique is a genuine distinct advantage."

Atomic pores comprise of a focal transport channel encompassed by inherently cluttered proteins called nucleoporins. Lim and his partners utilized rapid AFM to imagine the conduct of phenylalanine-glycine nucleoporins (FG Nups) inside the cores of African ripped at frog (Xenopus laevis) cells at a determination of around 100 milliseconds. To get to the atomic pore at such high determination, the specialists needed to develop ultra-sharp carbon nanofibers on the AFM tests.

AFM imaging uncovered how the FG Nups quickly extend and contract, similar to limbs, to frame a sort of lattice over the atomic opening. Substantial particles move more gradually than these pore proteins and are hindered from entering the core, though little atoms move all the more rapidly and have a greatly improved possibility of getting in, the scientists clarified in their paper.

Lim's group is presently examining how to make atomic pore-propelled channels for nonbiological frameworks, as indicated by the announcement.
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Embryo Watch

A youthful developing life inserts into the mass of the womb around seven days after treatment. The main week of embryonic improvement is genuinely clear to think about in vitro; after that, it gets dubious. Be that as it may, another mix of amino acids, hormones, and development calculates now gives analysts an approach to keep human incipient organisms alive in vitro for any longer. In two separate studies distributed in Nature and Nature Cell Biology yesterday (May 4), analysts refined and watched human incipient organisms produce for a sum of 13 days post-treatment. (Universal directions allow the investigation of human incipient organisms in the lab for up to 14 days.) The exploration uncovered that undeveloped cells in the blastocyst self-sort out into a depression that was once thought to be shaped by apoptosis, affirmed contrasts amongst murine and human improvement, and recommended that the fetus at first grows to a great extent with no contribution from mother.

"This is the time of our lives that the absolute most critical [biological] choices are made," the University of Cambridge's Magdalena Zernicka-Goetz, whose gathering built up the way of life framework and has officially shown its utility in refined mouse fetuses, told The Wall Street Journal. "It was completely a black box of advancement that we were not ready to access as of not long ago."

Zernicka-Goetz, a creator on the Nature Cell Biology paper, noticed that numerous formative deformities happen right away after implantation. "This new procedure gives us a one of a kind chance to get a more profound comprehension of our own advancement amid these essential stages and help us comprehend what happens, for instance, amid unsuccessful labor," she said in a public statement.

The framework could permit analysts to track fetuses for more timeframes, however the groups finished their trials at 13 days post-treatment to be consistent with the generally perceived 14-day standard. Some contend that this number is subjective and ought to be reevaluated in light of such innovative advances, in any case. "I don't see anything hallowed in the 14 days," University of Pennsylvania bioethicist Jonathan Moreno told STAT News. "What's truly more imperative than whether it's allowable to move those goalposts is the means by which we settle on that choice."
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In Failing Hearts, Cardiomyocytes Alter Metabolism

As organs go, the heart is a vitality pig. To keep it energized, mitochondria inside cardiomyocytes (heart muscle cells) always produce ATP as a result of the citrus extract cycle. In the heart, the majority of the cycle's substrates originate from the digestion system of unsaturated fats, yet the organ can likewise make utilization of different mixes, for example, lactate or ketones.

At the point when Daniel Kelly of Sanford Burnham Prebys Medical Discovery Institute in Orlando, Florida, discovered that some uncommon hereditary issue both cause brokenness of the heart muscle and at the same time disturb unsaturated fat oxidation and expansion ketone digestion system, he thought about whether ketones may assume a part in heart disappointment. "It was somewhat of a hereditary verification of idea that these fuel changes may truly be imperative, instead of simply honest spectators," he says.

Amid starvation, the liver makes additional ketones, permitting the mind to change to ketones for fuel when glucose is low. To see if a comparable procedure happens right on time in heart disappointment, Kelly's group mirrored two regular reasons for human heart disappointment—heart assault and hypertension created by aorta narrowing—in mice, and performed proteomic examinations four weeks after the fact.

They watched brought down levels of proteins that procedure unsaturated fats for vitality and expanded levels of a ketone-metabolizing compound called βOHB dehydrogenase 1 (BDH1). They additionally discovered hoisted levels of three ketone metabolites, and when the group perfused extracted hearts with a radioactively marked form of the ketone βOHB, hypertrophied hearts gobbled up a greater amount of the ketone to create substrates for the citrus extract cycle than solid hearts.

Kenneth Margulies and associates at the University of Pennsylvania saw comparable metabolic changes in fizzling human hearts inspected amid surgery or expelled amid cardiovascular transplantation (Circulation, 133:706-16, 2016). Margulies' group watched that the declaration of the qualities for BDH1 and other ketone-metabolizing chemicals sloped up in falling flat heart tissue. Albeit falling flat hearts and solid controls (from organ contributors) showed no distinctions in the plenitude of proteins required in unsaturated fat oxidation, coming up short ones had lower levels of unsaturated fat intermediates called acylcarnitines, proposing the hearts were not utilizing their typical fuel source.

Both mice and people with heart disappointment had expanded convergences of ketones in their serum, implying that ketone generation in the liver was expanded. "This was truly intriguing in light of the fact that that implies there is a liver-heart association," Kelly says. To see whether that is the situation, he wants to study mice without a chemical required for ketone generation in the liver.

These mice will likewise be helpful in observing whether the change to ketones is something worth being thankful for. "We don't know whether it's adjustment or maladaptation," says Heinrich Taegtmeyer, a cardiologist at the University of Texas Health Science Center in Houston. Making sense of that could possibly illuminate approaches to secure hearts in terrible circumstances.
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