RNA-Seq for Enrichment and Analysis of IRF5 Transcript Expression in SLE

Stone, R. C., Du, P., Feng, D., Dhawan, K., Rönnblom, Lars, Eloranta, Maija-Leena, Donnelly, R., Barnes, B. J.

January 2013

Polymorphisms in the interferon regulatory factor 5 (IRF5) gene have been consistently replicated and shown to confer risk for or protection from the development of systemic lupus erythematosus (SLE). IRF5 expression is significantly upregulated in SLE patients and upregulation associates with IRF5-SLE risk haplotypes. IRF5 alternative splicing has also been shown to be elevated in SLE patients. Given that human IRF5 exists as multiple alternatively spliced transcripts with distinct function(s), it is important to determine whether the IRF5 transcript profile expressed in healthy donor immune cells is different from that expressed in SLE patients. Moreover, it is not currently known whether an IRF5-SLE risk haplotype defines the profile of IRF5 transcripts expressed. Using standard molecular cloning techniques, we identified and isolated 14 new differentially spliced IRF5 transcript variants from purified monocytes of healthy donors and SLE patients to generate an IRF5 variant transcriptome. Next-generation sequencing was then used to perform in-depth and quantitative analysis of full-length IRF5 transcript expression in primary immune cells of SLE patients and healthy donors by next-generation sequencing. Evidence for additional alternatively spliced transcripts was obtained from de novo junction discovery. Data from these studies support the overall complexity of IRF5 alternative splicing in SLE. Results from next-generation sequencing correlated with cloning and gave similar abundance rankings in SLE patients thus supporting the use of this new technology for in-depth single gene transcript profiling. Results from this study provide the first proof that 1) SLE patients express an IRF5 transcript signature that is distinct from healthy donors, 2) an IRF5-SLE risk haplotype defines the top four most abundant IRF5 transcripts expressed in SLE patients, and 3) an IRF5 transcript signature enables clustering of SLE patients with the H2 risk haplotype.

interferon

interferon regulatory factor 5

SLE

The role of interferon regulatory factor-5 in systemic lupus erythematosus (SLE) and SLE-associated atherosclerosis

Watkins, Amanda Ann

22 January 2016

Gain-of-function polymorphisms in the gene encoding human interferon regulatory factor-5 (IRF5) are associated with an increase in risk for the development of the autoimmune disease Systemic Lupus Erythematosus (SLE). IRF5 is a transcription factor that participates in the activation of the immune system through its role in both innate and adaptive immune cells. To determine the role of IRF5 in lupus pathogenesis in vivo, we evaluated the effect of Irf5-deficiency in the MRL/lpr mouse lupus model. We find that Irf5-deficient (Irf5-/-) MRL/lpr mice develop much less severe disease than their Irf5-sufficient (Irf5+/+) littermates, demonstrating an important role for IRF5 in disease pathogenesis in vivo. Patients with SLE are at increased risk for the development of atherosclerosis due in large part to poorly-defined lupus-specific risk factors. One such lupus-specific risk factor is thought to be chronic inflammation associated with the autoimmune process. As IRF5 is involved in pro-inflammatory responses we hypothesized that Irf5-deficiency would ameliorate atherosclerosis development in the context of autoimmunity. We therefore examined the role of IRF5 in the gld.apoE-/- mouse model of lupus and lupus-associated atherosclerosis. Irf5-deficiency led to a decrease in splenomegaly, lymphadenopathy, anti-nuclear autoantibody production and the severity of kidney disease. Surprisingly, despite the reduction in systemic autoimmunity, Irf5-deficiency led to a marked increase in the severity of atherosclerosis and to metabolic dysregulation characterized by hyperlipidemia, increased adiposity and insulin-resistance. Bone marrow chimera studies revealed that the pathogenic role of IRF5 in lupus was solely due to its expression in hematopoietic cells. The atheroprotective effect of Irf5 and the suppression of adiposity were found to be due to Irf5 expression in both hematopoietic and non-hematopoietic cells, whereas protection from hyperlipidemia was solely due to the expression of Irf5 in non-hematopoietic cells. Together, our results reveal a role for IRF5 in metabolic homeostasis, as well as in protection against atherosclerosis even in the setting of reduced lupus severity.

Immunology

Atherosclerosis

Interferon regulatory factor 5

Metabolism

Systemic lupus erythematosus

Toll like receptor

The Genetics of Systemic Lupus Erythematosus : The Specificity of IRF5 to SLE.

Linga Reddy, MV Prasad

January 2007

<p>The breakdown of self-tolerance is the main driving force behind susceptibility to SLE. When this occurs, T and B cells are activated in an uncontrolled manner and produce autoantibodies against self fragmented DNA, RNA and sometimes other parts of the cell such as cardiolipin, phosphatidylserine, etc.</p><p>The mechanism behind the breakdown of self-tolerance may be genetic factors that are triggered by environmental factors. SLE is not caused by a single gene, but by many genes, and is thus a polygenic disease. So far only a few genes have been found to be associated with SLE including PDCD1, FcγRs, and PTPN22. The main aim of my thesis is to find susceptibility genes responsible for SLE.</p><p>Recently, a gene called IRF5 was found to be associated with SLE. In paper one, we performed a thorough study and confirmed its association to SLE. In addition, we found a few other SNPs in the gene that were associated to the disease. Among them, SNP rs2004640 is very strongly associated and was found to affect the splicing of the gene. Another SNP, rs2280714, correlated with overexpression of the gene, although SNP rs10954213 was much more highly correlated with expression adding to this, in paper two we found a few other SNPs that were associated to SLE and played crucial roles in gene function. An indel in exon 6, though not associated by itself, regulated which isoforms were expressed. Individuals with 2 repeats expressed isoforms V1 and V4, while individuals with 4 repeats expressed isoforms V5 and V6. SNP rs2070197 was also very strongly associated, but did not have a functional role. In paper three, the same polymorphisms were studied in a Mexican population, which showed an even stronger association when compared to a European population.</p><p>It is known that autoimmune diseases share susceptibility genes, therefore we wanted to see if the IRF5 gene is associated with any other autoimmune diseases. In papers four and five, we tested its association to RA (using three sets of patients and controls from Sweden, Argentina and Spain) and psoriasis (using a set of patients and controls from Sweden). Association was not found in either of the diseases. Therefore, we believe that this association may be SLE-specific.</p>

Molecular genetics

Systemic lupus erythematosus

Interferon regulatory factor 5

Transmission-Disequilibrium Test

Family-based association test

Linkage Disequilibrium

Hardy-Weinberg equilibrium

Genetik

The Genetics of Systemic Lupus Erythematosus : The Specificity of IRF5 to SLE.

Linga Reddy, MV Prasad

January 2007

The breakdown of self-tolerance is the main driving force behind susceptibility to SLE. When this occurs, T and B cells are activated in an uncontrolled manner and produce autoantibodies against self fragmented DNA, RNA and sometimes other parts of the cell such as cardiolipin, phosphatidylserine, etc. The mechanism behind the breakdown of self-tolerance may be genetic factors that are triggered by environmental factors. SLE is not caused by a single gene, but by many genes, and is thus a polygenic disease. So far only a few genes have been found to be associated with SLE including PDCD1, FcγRs, and PTPN22. The main aim of my thesis is to find susceptibility genes responsible for SLE. Recently, a gene called IRF5 was found to be associated with SLE. In paper one, we performed a thorough study and confirmed its association to SLE. In addition, we found a few other SNPs in the gene that were associated to the disease. Among them, SNP rs2004640 is very strongly associated and was found to affect the splicing of the gene. Another SNP, rs2280714, correlated with overexpression of the gene, although SNP rs10954213 was much more highly correlated with expression adding to this, in paper two we found a few other SNPs that were associated to SLE and played crucial roles in gene function. An indel in exon 6, though not associated by itself, regulated which isoforms were expressed. Individuals with 2 repeats expressed isoforms V1 and V4, while individuals with 4 repeats expressed isoforms V5 and V6. SNP rs2070197 was also very strongly associated, but did not have a functional role. In paper three, the same polymorphisms were studied in a Mexican population, which showed an even stronger association when compared to a European population. It is known that autoimmune diseases share susceptibility genes, therefore we wanted to see if the IRF5 gene is associated with any other autoimmune diseases. In papers four and five, we tested its association to RA (using three sets of patients and controls from Sweden, Argentina and Spain) and psoriasis (using a set of patients and controls from Sweden). Association was not found in either of the diseases. Therefore, we believe that this association may be SLE-specific.

Molecular genetics

Systemic lupus erythematosus

Interferon regulatory factor 5

Transmission-Disequilibrium Test

Family-based association test

Linkage Disequilibrium

Hardy-Weinberg equilibrium

Genetik