The virus meets the B cell

By the time we’ve reached adulthood, the vast majority of us have been infected by EBV. Transmitted in saliva, EBV infection typically occurs in childhood, from sharing a spoon with or drinking from the same glass as a sibling or a friend, or maybe during our teen years, from exchanging a kiss. EBV can cause mononucleosis, “the kissing disease,” which begins with a fever that subsides but lapses into a profound fatigue that can persist for months.

“Practically the only way to not get EBV is to live in a bubble,” Robinson said. “If you’ve lived a normal life,” the odds are nearly 20 to 1 you’ve got it.

Once you’ve been infected by EBV you can’t get rid of it, Robinson said, even if you remain or become symptom-free. EBV belongs to a large family of viruses, including those responsible for chickenpox and herpes, that can deposit their genetic material into the nuclei of infected cells. There the virus slumbers in a latent form, hiding from the immune system’s surveillance agents. This may last as long as the cell it’s hiding in stays alive. Or, under certain conditions, the virus may reactivate and force the infected cell’s replicative machinery to produce myriad copies of themselves that break out to infect other cells and other people.

Among the cell types in which EBV takes up permanent residence are B cells, immune cells that do a couple of important things after they ingest bits of microbial pathogens. For one, they can produce antibodies: customized proteins that find and bind immune-system-arousing proteins or other molecules (immunologists call them “antigens”) on microbial pathogens that have infected an individual, or are trying to. For another, B cells are what immunologists call “professional antigen-presenting cells”: They can process antigens and display them on their surfaces in a way that encourages other immune cells to raise the intensity of their hunt for the pathogen in question. That’s a substantial force multiplier for kick-starting an immune response.

Our bodies harbor hundreds of billions of B cells, which over the course of numerous rounds of cell division develop an enormous diversity of antibodies. In the aggregate, these antibodies can bind an estimated 10 billion to 100 billion different antigenic shapes. This is why we’re able to mount a successful immune response to so many different pathogens.

Practically the only way to not get EBV is to live in a bubble.”

Oddly, about 20% of the B cells in our bodies are autoreactive. They target antigens belonging to our own tissues — not by design, but due to the random way B-cell diversity comes about: through sloppy replication, apparently engineered by evolution to ensure diversification. Fortunately, these B cells are typically in a dopey state of inertia, and they pretty much leave our tissues alone.

But at times, somnolent autoreactive B cells become activated, take aim at our own tissues and instigate one of the disorders collectively called autoimmunity. Some awakened autoreactive B cells crank out antibodies that bind to proteins and DNA inside the nuclei of our cells. Such activated “antinuclear antibodies” — the hallmark of lupus — trigger damage to tissues randomly distributed throughout the body, because virtually all our body’s cells have nuclei.

The vast majority of EBV-infected people (most of us, that is) have no idea they’re still sheltering a virus and never get lupus. But essentially everyone with lupus is EBV-infected, studies have shown. An EBV-lupus connection has been long suspected but never nailed down until now.

The antinuclear B cell gets ornery

Although latent EBV is ubiquitous in the sense that almost everybody carries it, it resides in only a tiny fraction of any given person’s B cells. As a result, until the new study, it was virtually impossible for existing methods to identify infected B cells and distinguish them from uninfected ones. But Robinson and his colleagues developed an extremely high-precision sequencing system that enabled them to do this. They found that fewer than 1 in 10,000 of a typical EBV-infected but otherwise healthy individual’s B cells are hosting a dormant EBV viral genome.

Employing their new EBV-infected-B-cell-identifying technology along with bioinformatics and cell-culture experimentation, the researchers found out how such small numbers of infected cells can cause a powerful immune attack on one’s own tissues. In lupus patients, the fraction of EBV-infected B cells rises to about 1 in 400 — a 25-fold difference.

It’s known that the latent EBV, despite its near-total inactivity, nonetheless occasionally nudges the B cell it’s been snoozing in to produce a single viral protein, EBNA2. The researchers showed that this protein acts as a molecular switch — in geneticists’ language a “transcription factor” — activating a battery of genes in the B cell’s genome that had previously been at rest. At least two of the human genes switched on by EBNA2 are recipes for proteins that are, themselves, transcription factors that turn on a variety of other pro-inflammatory human genes.

The net effect of all these genetic fireworks is that the B cell becomes highly inflammatory: It dons its “professional antigen-presenting cell” uniform and starts stimulating other immune cells (called helper T cells) that happen to share a predilection for targeting cell-nuclear components. These helper T cells enlist multitudes of other antinuclear B cells as well as antinuclear killer T cells, vicious attack dogs of the immune system.

When that militia bulks up, it doesn’t matter whether any of the newly recruited antinuclear B cells are EBV-infected or not. (The vast majority of them aren’t.) If there are enough of them, the result is a bout of lupus.

What comes next?

Robinson said he suspects that this cascade of EBV-generated self-targeting B-cell activation might extend beyond lupus to other autoimmune diseases such as multiple sclerosis, rheumatoid arthritis and Crohn’s disease, where hints of EBV-initiated EBNA2 activity have been observed.

The million-dollar question: If about 95% of us are walking around with latent EBV in our B cells, why do some of us, but not all of us, get autoimmunity? Robinson speculates that perhaps only certain EBV strains spur the transformation of infected B cells into antigen-presenting “driver” cells that broadly activate huge numbers of antinuclear B cells.

Many companies are working on an EBV vaccine, and clinical trials of such a vaccine are underway. But that vaccine would have to be given soon after birth, Robinson noted, as such vaccines are unable to rid an already-infected person of the virus.

Stanford University’s Office of Technology Licensing has filed a provisional patent application on intellectual property associated with the study’s findings and technologies used to obtain them. Robinson, Younis and a third study co-author, Mahesh Pandit, PhD, a postdoctoral scholar in immunology and rheumatology, are named inventors on the application. They are co-founders and stockholders of a company, EBVio Inc., a company exploring an experimental lupus treatment, ultradeep B-cell depletion. This procedure involves total annihilation of all circulating B cells, which are replaced over the following few months by new, EBV-free B cells born continually in the bone marrow. Robinson is also a director of EBVio Inc. and a co-founder and shareholder of Flatiron Bio, LLC.

Researchers from the U.S. Department of Veterans Affairs Medical Center, Cincinnati; the University of Massachusetts School of Medicine; the University of Oklahoma Health Sciences Center; and Rockefeller University contributed to the work.

The study was funded by the National Institutes of Health (grants R01AR078268, R01AI173189-01, PATHO-PH2-SUB_17_23 and R01AI024717), the VA Palo Alto Health Care System, the Lupus Research Alliance and the Brennan Family.

About Stanford Medicine

Stanford Medicine is an integrated academic health system comprising the Stanford School of Medicine and adult and pediatric health care delivery systems. Together, they harness the full potential of biomedicine through collaborative research, education and clinical care for patients. For more information, please visit med.stanford.edu.

This research has application for many other conditions which are also pathogen mediated conditions currently understood as the virus altering genes, the bacteria protein being similar to tissue and cross-reacts, pathogens or dust being too damaging or altering the environment causing cancer for instance. The virus that causes cervical cancer is the Human Papillomavirus (HPV) — specifically, certain high-risk strains of HPV by expression genes. Cutis Laxa, bacterial proteins resemble parts of human extracellular matrix (ECM) components — particularly elastin, fibulin, and tropoelastin. The immune system makes antibodies against the bacteria — but those antibodies cross-react with the host’s elastic fibers. This leads to autoantibody-mediated attack on elastic tissue.

Pathogen-Triggered Autoimmune Responses:

Evidence and Scope

Autoimmune diseases arise from a combination of genetic predisposition and environmental triggers. A

recent Science Translational Medicine study shows that Epstein–Barr virus (EBV) infection can directly drive

systemic lupus erythematosus (SLE): EBV infects and “reprograms” autoreactive B cells into inammatory

antigen-presenting cells, a mechanism mediated by the viral protein EBNA2 . This nding provides

one of the most direct links ever observed between a pathogen and a specic autoimmune disease.

EBV and SLE: A Clear Causal Mechanism

In SLE, Younis et al. (2025) demonstrated that EBV+ B cells are enriched in autoreactive clones and express

transcription factors ZEB2 and T-bet, gaining antigen-presentation functions via EBNA2-driven gene

expression changes . These EBV-infected B cells produce the lupus autoantibodies (e.g. antinuclear

antibodies) and activate autoreactive T cells, sustaining a vicious cycle of autoimmunity . In eect,

EBV “hijacks” the B cells that normally protect us, turning them into disease drivers . This mechanism is

as clearly demonstrated as H. pylori causing ulcers: the virus was directly observed inside disease-driving

cells and shown to alter their gene regulation to initiate SLE . (By comparison, chronic autoimmunity

typically has no single proven cause.)

Infectious Triggers in Other Autoimmune Diseases

Many autoimmune diseases have suspected or known infectious triggers, but the evidence varies by

disease. For example:

Multiple sclerosis (MS) – A landmark study found that risk of MS increased 32‑fold after EBV

infection (and not after other viral infections) . This strongly implicates EBV as a key trigger for

MS, although the exact mechanism (molecular mimicry or reprogramming) is still under study.

Rheumatoid arthritis (RA) – RA patients often have immune responses to gut and oral bacteria. In

particular, Proteus mirabilis, Escherichia coli and periodontal pathogens (Porphyromonas gingivalis)

show molecular mimicry with joint proteins, and RA is strongly linked to smoking (which promotes

citrullination) . Viruses like EBV and hepatitis C have also been found at higher rates in RA

patients .

Type 1 diabetes (T1D) – Enteroviruses (e.g. Coxsackie B4), congenital rubella and other viral

infections have long been associated with T1D . These viruses may trigger autoimmunity in

pancreatic β-cells via sequence homology to self antigens (glutamic acid decarboxylase, insulin) .

Again, genetic factors (HLA-DR3/DR4, INS) are required for disease.

Guillain–Barré syndrome (GBS) – This acute autoimmune neuropathy is classically triggered by

Campylobacter jejuni (and sometimes CMV or other infections) through cross-reactive antibodies

against peripheral nerve components. (Molecular mimicry in GBS is a well-established cause.)

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Celiac disease – Although not triggered by infection, celiac is an immune-mediated disorder caused

by dietary gluten in genetically susceptible individuals (HLA‑DQ2/8). This shows that non-infectious

environmental antigens can act as “triggers.”

Others – Many other autoimmune diseases (thyroiditis, vasculitis, etc.) have proposed links to

infections or environmental exposures, but no single pathogen has been denitively proven in most

cases.

In fact, a comprehensive review notes that “almost all autoimmune diseases have been associated with at least

one infection” . However, association does not equal proof of causation for every case. The table below

summarizes some well-studied examples:

Autoimmune

Disease

Proposed Trigger(s) Evidence / Notes

SLE (lupus)

EBV infection (reprograms

autoreactive B cells) ; also

rubella, CMV, Toxoplasma

(autoantibody induction) .

Younis et al. show EBV directly infects lupus

B cells and drives autoimmunity . SLE

patients have very high EBV seroprevalence

.

RA

(rheumatoid

arthritis)

Proteus mirabilis, E. coli, Klebsiella

(molecular mimicry) ; periodontal

bacteria (P. gingivalis); EBV/HCV

association ; smoking.

Antibodies to these bacteria correlate with

RA; shared HLA-DRB1 “shared epitope”

mimics bacterial peptides . EBV/HCV

serology often elevated in RA .

MS (multiple

sclerosis)

EBV infection (32× higher MS risk

after EBV) ; other viruses/bacteria

(less certain).

Large cohort study: EBV seroconversion

preceded MS in nearly all cases .

Mechanism is still being dened.

T1D (type 1

diabetes)

Coxsackie B4 virus, congenital

rubella, other enteroviruses .

Viral infections correlated with T1D onset;

viral peptides resemble β-cell autoantigens

(e.g. GAD) .

GBS (Guillain–

Barré)

Campylobacter jejuni, CMV, others

(molecular mimicry).

Well-established post-infectious

neuropathy: cross-reactive antibodies

attack myelin.

Celiac disease

Dietary gluten (gliadin) – not an

infection (requires HLA-DQ2/8).

Clear antigenic trigger; removal of gluten

halts disease.

ANCA-

associated

vasculitis

Silica dust, possibly chronic nasal

infections (unclear).

No denitive microbial cause established;

environmental exposures contribute.

(References in text above detail the evidence for each.)

Mechanisms of Pathogen-Induced Autoimmunity

Pathogens can break immune tolerance by several mechanisms . The classic pathway is molecular

mimicry, where immune responses to a microbe cross-react with similar self-antigens . Another route is

bystander activation, in which infection-induced inammation non-specically activates autoreactive

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lymphocytes . Chronic infections or superantigens can sustain a polyclonal autoimmune response .

The newly described EBV→SLE mechanism is a variant: the virus directly reprograms infected B cells’ gene

expression via EBNA2, converting them into pathogenic “driver” cells . In general, intracellular

pathogens can alter host gene transcription and cellular behavior .

Scope and Limitations: Not a Universal Rule

Although many autoimmune diseases have infectious/environmental triggers, there is no single pathogen

or mechanism underlying all autoimmunity. Each disease has a unique mix of risk factors. Genetic

susceptibility (especially HLA alleles) is crucial for breaking tolerance . Environmental factors vary widely:

for instance, smoking is a well-known trigger for RA , silica and UV exposure aect SLE risk, and diet

drives celiac. In contrast to ulcers (where H. pylori infection is a proven sole cause), autoimmune disorders

are almost always multifactorial . The NIH review explicitly notes that applying Koch’s postulates to

autoimmunity is problematic, because genetics, epigenetics and environment all interact .

In summary, the new EBV-SLE data provide one of the clearest causal chains ever demonstrated

(pathogen→cellular reprogramming→autoimmune disease) . Similar strong evidence exists for EBV’s

role in MS and classic cases like Campylobacter in GBS. However, many autoimmune diseases lack a

single proven microbial cause; they arise from complex interactions of genes, immune regulation and

diverse environmental exposures (infections, diet, chemicals). Pathogen-triggered reprogramming is a

powerful mechanism in some cases, but it is not a universal rule for all autoimmune diseases .

Sources: The above conclusions are drawn from recent peer-reviewed studies and authoritative reviews

. Citations provide the experimental evidence and epidemiological data for each statement.

Q&A with William Robinson, MD: Epstein-Barr Virus and Lupus — Unlocking a Long-Standing Mystery |

Department of Medicine News | Stanford Medicine

https://medicine.stanford.edu/news/current-news/standard-news/ebv-lupus.html

Infection and autoimmune diseases - Autoimmunity - NCBI

Bookshelf

https://www.ncbi.nlm.nih.gov/books/NBK459437/

Epstein-Barr virus reprograms autoreactive B cells as antigen-presenting cells in systemic lupus

erythematosus, Younis et al., 2025 | Science for ME

https://www.s4me.info/threads/epstein-barr-virus-reprograms-autoreactive-b-cells-as-antigen-presenting-cells-in-systemic-lupus-

erythematosus-younis-et-al-2025.47139/

Longitudinal analysis reveals high prevalence of Epstein-Barr virus associated with multiple sclerosis -

PubMed

https://pubmed.ncbi.nlm.nih.gov/35025605/

Evolving understanding of autoimmune mechanisms and new therapeutic strategies of autoimmune

disorders | Signal Transduction and Targeted Therapy

https://www.nature.com/articles/s41392-024-01952-8?error=cookies_not_supported&code=f06d6366-

d2aa-4137-98f6-923cf86f4b33

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