Tag Archives: evolution

Avandia side effects culprit found

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For better or worse, a popular class of anti-diabetic drugs does more than lower blood sugar. One known as rosiglitazone (trade name Avandia) has been in the spotlight for its possible link to increased cardiovascular events, but it also seems to come with unexplained vascular benefits and an unwelcome tendency for weight gain. Now, two separate studies in the July Cell Metabolism, explore those other effects of the drugs known collectively as thiazolidinediones (TZDs), both of which stem from their activity in fat.

The findings offer new biological insights into fat tissue and its role as a central component of metabolic control. They may also pave the way for the development of new and better drugs, according to the researchers.

“TZDs have lots of side effects,” said Jonathan Graff of the University of Texas Southwestern Medical Center. “We may find ways to replace them with drugs that have fewer.”

Earlier studies showed that TZDs remodel fat (adipose) tissue and that they lead to the recruitment of new fat cells known as adipocytes. “TZDs alter adipose tissue to make you fatter,” Graff said.

avandia

Avandia

His team wanted to know whether those effects could be traced to adipose stem cells as the source of all those new adipocytes. Adipose stem cells were earlier identified in the walls of the blood vessels that feed adipose tissue, suggesting they might be an accessible target for therapies.

Indeed, they show in mice that rosiglitazone markedly increases the evolution of adipose stem cells into new adipocytes, perhaps explaining why those taking the drugs tend to put on pounds. After two months on the drug, however, the animals’ stem cells were “profoundly altered” both molecularly and functionally. At that point, “they don’t proliferate in the same way and they no longer form fat cells,” Graff said. It was as if the fat cell progenitors had worked overtime and were spent.

The findings offer important evidence that the biology of fat might be altered for therapeutic ends via stem cells, the researchers say. They also provide important new insight into how TZDs work and how they might be improved.

“Although TZDs are effective at lowering blood glucose levels, side effects and concerns that TZDs increase cardiovascular risk have hastened the need to find alternative therapeutics,” Graff’s team wrote. “A better understanding of whether and how TZDs modulate the adipose lineage may shed light on their insulin-sensitizing efficacy, and may also help to develop the next generation insulin-sensitizers.”


In the second study, Yu Huang of Chinese University of Hong Kong and Aimin Xu of the University of Hong Kong tested whether the vascular benefits of rosiglitazone could be connected to the fat-derived hormone adiponectin. Adiponectin is unusual among fat hormones in that its levels generally decline in those who are obese and many earlier studies by Huang and Xu’s team and others suggested it might have a protective effect on blood vessels.

In diabetic mice, the researchers found that adiponectin is required for the vascular benefits of treatment with rosiglitazone. Rosiglitazone treatment also stimulated the release of adiponectin from isolated fat tissue, and fat tissue transplanted from treated mice relaxed the blood vessels of untreated diabetic mice.

” Our study emphasizes the importance of adipose tissue-derived adiponectin in response to TZD,” Huang said. “This suggests that development of pharmacological agents that can elevate adiponectin, but avoid the undesirable effects of TZDs, may represent an effective therapeutic approach for treating or preventing vascular diseases induced by obesity and diabetes.”

He says they have also identified several natural compounds in edible herbs that boost adiponectin levels by other means. They plan to test whether those compounds might have therapeutic use.

Antibiotic Resistance

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Deadly bacteria may be evolving antibiotic resistance by mimicking human proteins, according to a new study by the Translational Genomics Research Institute (TGen).

This process of “molecular mimicry” may help explain why bacterial human pathogens, many of which were at one time easily treatable with antibiotics, have re-emerged in recent years as highly infectious public health threats, according to the study appearing in the online journal PLoS ONE, published by the Public Library of Science.

“This mimicry allows the bacteria to evade its host’s defense responses, side-stepping our immune system,” said Dr. Mia Champion, an Assistant Professor in TGen’s Pathogen Genomics Division, and the study’s author.

Using genomic sequencing, the spelling out of billions of genetic instructions stored in DNA, the study identified several methyltransferase protein families that are very similar in otherwise very distantly related human bacterial pathogens. These proteins also were found in hosts such as humans, mouse and rat.

Antibiotics

Antibiotics

Researchers found methyltransferase in the pathogen Francisella tularensis subspecies tularensis, the most virulent form of Francisella. Just one cell can be lethal. Methyltransferase is a potential virulence factor in this pathogen, which causes Tularemia, an infection common in wild rodents, especially rabbits, that can be transmitted to humans though bites, touch, eating or drinking contaminated food or water, or even breathing in the bacteria. It is severely debilitating and even fatal, if not treated.

Similar methyltransferase proteins are found in other highly infectious bacteria, including the pathogen Mycobacterium tuberculosis that causes Tuberculosis, a disease that results in more than 1 million deaths annually. The study also identified distinct methyltransferase subtypes in human pathogens such as Coxiella, Legionella, and Pseudomonas.

In general, these bacterial pathogens are considered “highly clonal,” meaning that the overall gene content of each species is very similar. However, the study said, “The evolution of pathogenic bacterial species from nonpathogenic ancestors is … marked by relatively small changes in the overall gene content.”

Genomic comparisons were made with several strains of the bacteria, as well as with plants and animals, including humans. The methyltransferase protein also was found to have an ortholog, or similar counterpart, in human DNA. Although the overall sequence of the orthologs is highly similar, the study identifies a protein domain carrying distinct amino acid variations present in the different organisms.


“Altogether, evidence suggests a role of the Francisella tularensis protein in a mechanism of molecular mimicry. Upon infection, bacterial pathogens dump more than 200 proteins into human macrophage cells called ‘effector proteins.’ Because these proteins are so similar to the human proteins, it mimics them and enables them to interfere with the body’s immunity response, thereby protecting the pathogen,” Dr. Champion said.

“These findings not only provide insights into the evolution of virulence in Francisella, but have broader implications regarding the molecular mechanisms that mediate host-pathogen relationships,” she added.

Identifying small differences between the pathogen and human proteins through Next Generation genome-wide datasets could help develop molecular targets in the development of new drug treatments, she said.