Rheumatoid arthritis

Posted on Lupus, Rheumatoid arthritis

RA and Lupus – Scientists reveal how our cells’ leaky batteries make us sick.

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Scientists reveal how our cells’ leaky batteries are making us sick

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“Now that we are beginning to understand how this inflammation starts, we might be able to prevent this process, with the ultimate goal of limiting inflammation and treating disease,” said researcher Laura E. Newman, PhD. CREDIT Courtesy Newman lab

Researchers have discovered how “leaky” mitochondria – the powerhouses of our cells – can drive harmful inflammation responsible for diseases such as lupus and rheumatoid arthritis. Scientists may be able to leverage the findings to develop better treatments for those diseases, improve our ability to fight off viruses and even slow ageing.

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The new discovery reveals how genetic material (mitochondria) can escape from our cellular batteries and prompt the body to launch a damaging immune response. By developing therapies to target this process, doctors may one day be able to stop the harmful inflammation and prevent its toll on our bodies.

“When mitochondria don’t correctly replicate their genetic material, they try to eliminate it. However, if this is happening too often and the cell can’t dispose of all of it, it can cause inflammation, and too much inflammation can lead to disease, including autoimmune and chronic diseases,” said researcher Laura E. Newman, PhD, of the University of Virginia School of Medicine. “Now that we are beginning to understand how this inflammation starts, we might be able to prevent this process, with the ultimate goal of limiting inflammation and treating disease.”

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Powering Inflammation

Mitochondria have their own set of genetic material, separate from the DNA that serves as the operating instructions for our cells. Scientists have known that this mitochondrial DNA, mtDNA, can escape into our cells and cause inflammation. But exactly what caused this has been a mystery until now.

“We knew that mtDNA was escaping mitochondria, but how was still unclear,” said Gerald Shadel, PhD, director of the San Diego-Nathan Shock Center of Excellence in the Basic Biology of Aging at the Salk Institute. “Using imaging and cell biology approaches, we’re able to trace the steps of the pathway for moving mtDNA out of the mitochondria, which we can now try to target with therapeutic interventions to prevent the resulting inflammation hopefully.”

Shadel and Newman, then a postdoctoral researcher in Shadel’s lab, and their collaborators used sophisticated imaging techniques to determine what was happening inside the leaky mitochondria. They found that a malfunction in mtDNA replication triggered the leak. This caused the accumulation of protein masses caused by nucleoids.

To try to fix this problem, the cell containing the faulty mitochondrion begins to export the excess nucleoids to its cellular trash bins. But the trash bins, called endosomes, can become overwhelmed by the volume of debris, the scientists found. These overburdened endosomes respond by releasing mtDNA into the cell – in short, the trash can overflows.

“We had a huge breakthrough when we saw that mtDNA was inside of a mysterious membrane structure once it left mitochondria. After assembling all of the puzzle pieces, we realized that structure was an endosome,” Newman said. “That discovery eventually led us to the realization that the mtDNA was being disposed of and, in the process, some of it was leaking out.”

The cell responds to this hazardous waste spill by flagging the nucleoids as foreign DNA, like a virus, and launches an immune response that results in harmful inflammation, the scientists determined.

“Using our cutting-edge imaging tools for probing mitochondria dynamics and mtDNA release, we have discovered an entirely novel release mechanism for mtDNA,” said researcher Uri Manor, PhD, former director of the Waitt Advanced Biophotonics Core at Salk and current assistant professor at UC San Diego. “There are so many follow-up questions we cannot wait to ask, like how other interactions between organelles control innate immune pathways, how different cell types release mtDNA, and how we can target this new pathway to reduce inflammation during disease and aging.”

Newman will continue to seek these answers in her new role at the UVA School of Medicine’s Department of Cell Biology. “We want to understand the physiological and disease contexts where this process can become activated,” she said. “For example, many viruses attack mitochondria during infection, so we will be testing whether mitochondria purposely use this pathway to sound the alarm against invading viruses, and whether over-reliance on this pathway to fight off infection can later trigger chronic diseases.”

Findings Published

Posted on Rheumatoid arthritis

The Ultimate Diet Guide for Managing Rheumatoid Arthritis: A Comprehensive Approach

Join Dr. Diana Girnita, a double board-certified Rheumatologist and Internal Medicine specialist, for a live YouTube lecture on “The Ultimate Diet Guide for Managing Rheumatoid Arthritis: A Comprehensive Approach.” Let us answer these questions: What are the worst foods for rheumatoid arthritis? The link between your gut and rheumatoid arthritis What are the best foods for rheumatoid arthritis? Throughout this video, we will explore various dietary recommendations scientifically proven to alleviate symptoms of rheumatoid arthritis. From incorporating anti-inflammatory foods to avoiding potential trigger foods, Dr. Girnita will explain how certain dietary choices can help minimize joint pain, swelling, and morning stiffness. You will learn about foods with these invaluable properties and how they can actively support your body’s healing and anti-inflammatory processes.

https://youtube.com/watch?v=HPK4ZfwKz_k%3Fsi%3DCNZiJHxVXkNzEODc

Posted on Rheumatoid arthritis

New treatment to reverse inflammation and arterial blockages in rheumatoid arthritis announced

Researchers from Queen Mary University of London have found that the molecule RvT4 enhances the body’s natural defences against atherosclerosis (hardening of the arteries) in patients with rheumatoid arthritis. 

Studies in mice undertaken by researchers from Queen Mary University of London’s William Harvey Research Institute and Centre for Inflammation and Therapeutic Innovation, and funded by the European Research Council (ERC) and Barts Charity, show that increasing levels of the RvT4 molecule in the body improves the ability of the body’s own defence mechanisms [macrophages] to reduce local inflammation and remove blockages in blood vessels. This breakthrough in understanding the processes involved could lead to better treatments for people who have rheumatoid arthritis (RA), and who are at higher risk of developing cardiovascular disease.  

Rheumatoid arthritis (RA) is the most common form of inflammatory arthritis in the UK and affects around 1% of the population. Approximately 10,000 people receive a diagnosis of RA every year. Alongside the more widely-known symptoms of joint inflammation, people with the condition are also twice as likely as others to develop blood vessel disease. This can lead to serious complications and an increased risk of premature death. 

One type of blood vessel disease seen in people with RA is atherosclerosis, which is caused by a build-up of fatty material called ‘plaque’ along the artery walls. This build-up causes the arteries to harden and narrow, making it more difficult to circulate blood around the body. These blockages can also break free, causing heart attacks and strokes. Understanding the reasons why RA patients are at increased risk of these cardiovascular problems is critical in developing better treatments for this group and others. 

To better understand the causes of blood vessel disease in patients with RA, researchers explored the role of a group of molecules called 13-series resolvins (RvTs). In experimental arthritis, the levels of one of these molecules, RvT4, are markedly reduced, a phenomenon that is associated with a higher degree of blood vessel disease. This study was designed to explore why this might be the case. 

The findings 

The study found that treating arthritic mice with RvT4 reduced blood vessel inflammation by re-programming macrophages – a group of white blood cells that accumulate in the diseased vessels – to release stored lipids. Researchers observed that these lipids were preventing the macrophage from carrying out their usual work of clearing dead cells and reducing localised inflammation in blood vessels. Once freed of their lipid burden, the macrophages were able to move and work much more effectively to reduce the causes of atherosclerosis. The observation that RvT4 restores protective macrophage biological activities is an exciting finding.   

RA patients also often present with metabolic dysfunction and this is thought to exacerbate vascular disease. The study found that administration of RvT4 to mice engineered to develop characteristics of metabolic dysfunction, advanced atherosclerosis, and arthritis led to an overall decrease in lipoprotein-associated cholesterol in plasma and an increase in the ratio of HDL-associated cholesterol to total cholesterol. 

Posted on autoimmune conditions, Multiple Sclerosis, Rheumatoid arthritis, Sjögren’s Syndrome

Study shows why women are at greater risk of autoimmune disease.

Women and pain

omewhere between 24 and 50 million Americans have an autoimmune disease, a condition in which the immune system attacks our own tissues. As many as 4 out of 5 of those people are women.

Rheumatoid arthritis, multiple sclerosis and scleroderma are examples of autoimmune disorders marked by lopsided female-to-male ratios. The ratio for lupus is 9 to 1; for Sjogren’s syndrome, it’s 19 to 1.

Stanford Medicine scientists and their colleagues have traced this disparity to the most fundamental feature differentiating biological female mammals from males, possibly paving the way for a better way to predict autoimmune disorders before they develop.

“As a practising physician, I see a lot of lupus and scleroderma patients because those autoimmune disorders manifest in the skin,” said Howard Chang, MD, PhD, dermatology professor and genetics professor and a Howard Hughes Medical Institute investigator. “The great majority of these patients are women.”

Chang, the Virginia and D.K. Ludwig Professor in Cancer Research and director of the RNA Medicine Program, is the senior author of the study, to be published Feb. 1 in Cell. Basic life research scientist Diana Dou, PhD, is its lead author.

The silence of the second X

Women have too much of a good thing: It’s called the X chromosome.

Throughout the mammalian kingdom, biological sex is determined by the presence of two X chromosomes in every female cell. Male cells pack just one X chromosome, paired with a much shorter one designated the Y chromosome.

The stubby Y chromosome contains only a handful of active genes. It’s quite possible to live a full life without a Y chromosome. In fact, more than half of the people on Earth — women — lack Y chromosomes and do just fine. But no mammalian male or female cell can survive without at least one copy of the X chromosome, which holds many hundreds of active protein-specifying genes.

Still, having two X chromosomes risks the production, in every female cell, of twice the amount of the myriad proteins specified by the X but not the Y chromosome. Such massive overproduction of so many proteins would be lethal.

Nature has devised a clever, if complicated, workaround called X-chromosome inactivation. Early in embryogenesis, each cell in the nascent female mammal decides to shut down the activity of one or the other of its two X chromosomes. Once that decision is made, it’s handed down to these cells’ progeny in the developing fetus. That way, the same amount of each X-chromosome-specified protein is produced in a female cell as in a male cell.

As the researchers discovered, X-chromosome inactivation can lead to autoimmune disorders, but other factors can also cause these disorders — which is why men sometimes develop them.

The great equalizer

X-chromosome inactivation is achieved courtesy of a molecule called Xist. The gene for Xist is present on all X chromosomes, including the single one male cells have. But Xist itself is produced only when the X chromosome that its gene resides on is one of a matched XX pair — and is produced and deployed on only one pair member.

Xist consists of RNA, a substance best known for being a simple-minded messenger that shuttles genes’ instructions for making proteins to the intracellular machines that make them. Yet RNA can do a whole lot more than schlep genetic information. There are as many different kinds of so-called long noncoding RNA (lncRNA) molecules — lengthy RNA stretches that don’t carry instructions for making proteins — as there are of the protein-encoding RNA variety. These lncRNA molecules can park themselves on stretches of chromosomes and change the likelihood that the cellular machinery charged with reading the genes in those locations will do so.

Xist, a type of lncRNA, is much longer than most. Xist coats long sections of one of a female mammalian cell’s two X chromosomes — but always just one — cutting that chromosome’s output to zero or close to it. The other X chromosome, left undisturbed, pumps out just enough RNA-encoded instructions to keep the cell humming.

But Xist’s nestling into the extra X chromosome generates odd combinations of lncRNA, proteins that bind to it, other proteins that bind to those proteins, and DNA some of those proteins cling to. These complexes can trigger a strong immune response, Chang and his colleagues have learned.

In 2015, Chang’s group identified close to 100 proteins that either bound to Xist or that bound to those proteins, collectively enabling this molecule to lay anchor along gene-specifying regions of the X chromosome.

Inspecting this Xist “parts list,” Chang realized that many of Xist’s collaborator proteins were known to be associated with autoimmune disorders. Might the RNA-protein-DNA complexes generated in the course of X-chromosome inactivation be triggering the notoriously high rate of autoimmunity in women compared with men? That question was the impetus for the new study.

What if males made Xist?

To eliminate possible competing causes such as female hormonal action or aberrant protein production by the supposedly silenced second X chromosome, the researchers tossed the Xist ball into the male court. They sewed the gene for Xist into the genomes of two different strains of male lab mice. One strain is quite susceptible to autoimmune symptoms mimicking lupus, with females more susceptible than males. The other is resistant to it.

The inserted Xist gene had been modified in two ways. It could be turned on or off by chemical means, pumping out Xist only when the scientists wanted it to. The Xist gene was also tweaked slightly so that its RNA product would no longer silence the genes of the male mouse’s chromosome into which it was stitched.

Merely inserting that modified Xist gene had no noticeable effect on the mice. But the Xist produced from the inserted gene, once that gene was activated, still formed characteristic complexes with almost all the proteins found earlier to be collaborating closely with Xist.

Now, the scientists could ask: Is a bioengineered male mouse that’s been coaxed to produce Xist more prone to autoimmunity than a normal male mouse, which never produces it, or than a male in whom the gene for Xist has been inserted but not activated?

By injecting an irritant known to induce a lupus-like autoimmune condition in the susceptible mouse strain, the investigators could compare its effect on males who made Xist with its effect on normal males, who made none.

In these susceptible mice, males in which the Xist gene was activated developed lupus-like autoimmunity at a rate approaching that of females — and considerably more so than non-bioengineered males.

The absence of autoimmunity in some female or Xist-activated male mice in the susceptible strain showed that not just activation of Xist but also some kind of tissue-damaging stress (caused, in this case, by injection of the irritant) is required to get the autoimmunity ball rolling.

In the autoimmune-resistant strain, activating Xist in bioengineered male mice wasn’t enough to induce autoimmunity — as might be predicted by the fact that in this strain even females seldom develop autoimmunity. That suggests that not only Xist activation but also an appropriate genetic background is necessary for autoimmunity to develop.

These constraints on autoimmunity are fortunate, because if there were none all women might be more susceptible to develop immunity, Chang noted.

Toward a better autoimmunity-screening panel

An early step in the development of autoimmunity is the appearance of autoantibodies: antibodies targeting one’s own tissues or cell products. Autoantibodies to the contents of cell nuclei are called anti-nuclear antibodies. Close examination of blood samples from about 100 patients with autoimmunity showed the presence of autoantibodies to many of the complexes associated with Xist. Some of these autoantibodies were specific to one or another autoimmune disorder, indicating their potential utility in identifying particular emergent autoimmune disorders before symptoms develop. Autoantibodies to still other Xist-associated proteins spanned several disorders, designating them as possible common markers of autoimmunity.

“Every cell in a woman’s body produces Xist,” Chang said. “But for several decades, we’ve used a male cell line as the standard of reference. That male cell line produced no Xist and no Xist/protein/DNA complexes, nor have other cells used since for the test. So, all of a female patient’s anti-Xist-complex antibodies — a huge source of women’s autoimmune susceptibility — go unseen.”

Posted on Rheumatoid arthritis

Men with inflammatory joint disease less likely to be childless than healthy peers

James Lind - the father of clinical trials
James Lind – the father of clinical trials

Men with inflammatory joint disease, such as rheumatoid arthritis, are less likely to be childless and have more children than their healthy peers, suggests research published online in the Annals of the Rheumatic Diseases.

As yet unknown factors associated with developing the disease and/or its treatment might influence fertility, suggest the researchers. 

Autoimmune diseases are on the rise in the West, and impaired fertility has been reported in Norwegian women with inflammatory joint diseases. But only a few studies looking at the potential impact on men’s fertility have been carried out, explain the researchers.

To explore these issues further, using childlessness and number of children as proxies for fertility, the researchers drew on a national group of 10,865 Norwegian men with either rheumatoid arthritis (37%), psoriatic arthritis (33%), or spondyloarthritis (30%). Each of them was matched with 5 healthy men (54,325) from the general population.

Between 1967 and August 2021, 111, 246 children were born to the total number of 65,190 men. Average age of first time fatherhood was 27 among the men with inflammatory joint disease and 28 in the comparison group. The average age at diagnosis was 44.

Births and childlessness were divided into 3 time periods, reflecting major changes in drug treatment for inflammatory joint diseases:1967-85 (before the advent of methotrexate; 575); 1986–99 (methotrexate;1360); and 2000–21 (use of biologics; 8930).

The average number of children each patient fathered was 1.8 compared with 1.7 in the comparison group, and around 1 in 5 (21%) of the patients was childless compared with more than 1 in 4 (27%) in the comparison group.

The number of children born to men in both groups was as follows: one child, 15% vs 14%; two, 36% vs 33%; three, 20% vs 19%; and four or more, 7% vs 7%.  

The difference in childlessness and number of children between the two groups was seen in all age brackets, except for those aged 19 and younger. Similarly, the proportion of childless men remained significantly lower among the patients than in the comparison group for those diagnosed between the ages of 20 and 79.

These differences were consistent over time, but the largest difference in number of children was numerically highest for those diagnosed after 2000: average of 1.8 vs 1.6. These patients also had the lowest risk of childlessness: 22% vs 28%. 

In the 2000–21 era, the largest absolute difference in childlessness was observed among men diagnosed in their 30s: 22% vs 32%. In the 1967–85 and 1986–99 eras, the differences were less obvious.

This is an observational study, and as such, no firm conclusions can be drawn about cause. And aside from the disease itself, psychological and socioeconomic factors, employment status and smoking could all influence fertility—factors that the researchers were unable to evaluate.

But they conclude: “Male patients with [inflammatory joint disease] may be reassured that no impairment of fertility is expected. However, substudies according to specific diagnoses should be performed to offer more targeted patient information.”

And they add: “Our finding of less childlessness and a higher number of children per man in patients with [inflammatory joint disease] is novel and generates new hypotheses regarding associations between fertility, inflammatory rheumatic diseases and immune-modulating drugs. This ought to be investigated further.”