First Page (Title Page)

Title

Peptidylarginine deiminase type 4, anti-citrullinated peptide antibodies, and rheumatoid arthritis

Author

Ryo Yamada

Affiliation

Laboratory for Rheumatic Diseases, SNP Research Center, The Physical and Chemical Research Institute (RIKEN), Yokohama, Japan

Supported byThe Japanese Millennium Project

Corresponding Author

Ryo Yamada

1-7-22 Suehirocho, Tsurumiku, Yokohama, Kanagawa 230-0045, Japan

Tel: +81-45-503-9569

Fax: +81-45-503-9590

Email:

Second Page

Abstract

Anti-citrullinated peptide antibodies seem to be one of the most clinically reliable serologic markers for rheumatoid arthritis (RA). A genetic approach revealed that one of the citrullinating enzymes has a RA-susceptible variant. Peptidyl citrullination alters the chemical character of peptides and subsequently their antigenicity as well. This change in antigenicity of self-peptides seems to invoke citrulline-related autoimmunity. Although the precise physiologic role of citrullination is still unknown, accumulating data indicates that citrullination has a definite role in biologic phenomena, along with other post-translational protein modifications, such as methylation and phosphorylation. In RA synovial tissue, two of five PADI isotypes are known to be expressed and their expression is regulated at multiple steps: transcription, translation, intra-cellular localization, andactivation/inactivation of PADI proteins. Further investigations on citrulline and PADIs from various aspects will provide a more profound understanding of RA-related autoimmunity.

Key Words

(1) Rheumatoid arthritis

(2) Citrullination

(3) Anti-CCP antibody

(4) PADI

Take-Home messages

(1)Anti-citrullinated peptide antibodies are the most reliable autoantibody for rheumatoid arthritis.

(2)Peptidylarginine deiminase (PADI) enzymes produce peptidyl citrulline by deimination/demethylimination of arginine/methylarginine residues in proteins.

(3)The physiologic role of peptidyl citrullination is still unknown.

(4)PADI2 and PADI4 and citrullinated proteins are present in synovial tissue from patients with rheumatoid arthritis.

(5)SNP-based whole genome surveys have identified rheumatoid arthritis-associated variants in PADI4.

(6)Enzymatic activity of PADIs takes place over several steps: transcription, translation intracellular localization,and Ca2+-dependent enzyme activation.

1. Introduction

Rheumatoid arthritis (RA) is one of the most common human systemic autoimmune diseasesand is characterized by autoantibody production and synovial inflammation. The fact that autoantibody production against citrullinated proteins is highly specific to RA (1)and that peptidylarginine deiminase type 4 (PADI4), a gene encoding one of the citrullinating enzymes, is associated with RA (2), leads us to believe that citrullination by PADI is a fundamental phenomenon in RA.This paper reviewsthe role of anti-citrullinated peptide antibody, citrullination, and PADI in RA.

2. Anti-citrullinated peptide antibodies in RA

Although various autoantibodies can be detected in the sera of patients with RA, several of these autoantibodies have been reported to be more specific and to have higher positive predictive value for RA than others. Many highly RA-specific autoantibodies, such as antiperinuclear factor (3), anti-keratin antibody (4-6), and anti-Sa antibody (7)have been found to recognize citrullinated peptides (8-12) Based on these findings, an enzyme-liked immunosorbent assay, recognizing anti-cyclic citrullinated peptide antibody, was developed. Clinical evaluations of this assay have shown it is one of the best diagnostic tests in rheumatology clinics (Table 1).(13)(14)(15)(16)(17) This assay is not only very specific for RA (up to 98%), but the production of these autoantibodies can be detected very early in the disease—even several years before disease onset—and titre values tend to correlate with an erosive subtype of RA. (10, 13-19)

3. Citrulline and peptidyl arginine deiminase enzymes

3.1Citrulline and arginine

Citrulline is a non-coding native amino acid. It is a deiminated form of arginine. The biggest difference between arginine and citrulline is that arginine is one of the most basic amino acids and citrulline lacks the charged feature. The enzyme responsible for the conversion of peptidyl arginine to peptidyl citrulline is peptidylarginine deiminase (PADI) (20). Although some biological events, such as inflammation, apoptosis, trauma, aging, and gene expression regulation by histones have been reported to be associated with post-translational citrullination(21, 22), the precise physiologic role of citrullination is still unknown(23-26). Although the physiologic role of citrulline in peptides is not clear, what is known about citrullination and its consequences is that various proteins are citrullinated with subsequent changesin their conformation that lead to breakdowns in immunologic tolerance (18).

3.2Enzymatic reaction and isozymes of PADIs

PADI enzymes catalyze the conversion of arginine residues to citrulline residues in proteins. Five isotypes of PADI—PADI1, 2, 3, 4, and 6—have been cloned from several mammals, including humans (20).All these isotypes possess a Ca-binding motif, and they depend on high concentrations of Ca2+ for their enzymatic activity. The tissue distribution of the isotypes of PADIs varies. PADI2 and PADI4 were reported to be expressed in synovial tissue and intranuclear localization seems to characterize PADI4 (20).

3.3PADIs in RA synovial tissue

3.3.1PADI2 and PADI4

PADI2 and PADI4 were reported to be present in RA synovial tissue. As anticipated from the fact that PADI4 has an NLS but PADI2 does not, PADI4 was detected in the nucleus (20)and cytoplasm and PADI2 was detected only in cytoplasm. SNP-basedwhole genome surveys have identified RA-associated variants in PADI4 (27). Increases in PADI4 activity due to polymorphisms in the gene seem to accelerate RA development.(18)Although one study from the United Kingdomdid not report statistically significant results(28), it was not contradictory to the original study (2)and the association was replicated in another Japanese study (29). A genetic contribution to RA of PADI4 variants, but not PADI2 variants, seems to be true, at least for the Japanese population, for the following reasons: all five PADI genes, including PADI2 and PADI4, cluster in chromosome 1p; genetic analysis discriminates PADI4 from PADI2; and the association with RA was only detected in PADI4 but not in PADI2.

3.3.2Control of expression and activation of PADI2 and PADI4

PADI2 and PADI4 have different profiles of tissue distribution. PADI2 is relatively ubiquitously expressed and PADI4 is more specifically expressed in leukocytes(27)The differences in tissue distribution, transcription, and translation of PADI2 and PADI4 are also regulated separately. Depending on cell lineages and their stages of differentiation, transcription and translation are regulated differently (30). Moreover, enzymes of PADI2 and PADI4 are inactivated in steady state. Because a much higher concentration of intracellular Ca2+ is required for PADIs to be active as enzymes, regulation of Ca2+ seems to play a pivotal role in the regulation of PADI enzyme activation. A structural study of PADI4 revealed that binding of Ca2+ to PADI4 molecules produced catalytic sites in homodimers (31). Figure 1 illustratesthis multi-step regulation of PADI activity.

4 Summaries

Studies on RA-specific autoantibodies have revealed that autoimmunity against citrulline-containing self-peptides is highly specific to RA and measurement of the quantity of anti-CCP, one of the anti-citrullinated peptide antibodies, is useful and reliable in rheumatology clinics. Along with the immunologic findings on citrullination, a genetic approach has identified a genetic connection between RA and PADI4, a specific gene encoding one of the citrullinating enzymes.Two mutually independent approaches highlighted citrulline in self-proteins as a breakthrough for understandingthe precise pathophysiology of RA. For the last few years, new insights on PADIs have been presented, such as the crystal structure of PADI4 enzyme (31) and involvement of citrullination in a physiologic role in histone-related gene expression regulation (32, 33), along with expressional evidence on PADI isozymes, as well as validating data on the use of anti-CCP antibodies in clinics(16)(17).Further investigations on citrulline and PADIs from various aspects will provide a more profound understanding of RA-related autoimmunity.

Acknowledgment

We thank all the members of the Laboratory for Rheumatic Diseases, SRC, RIKEN, particularly Ms. K. Komakine for providing illustrations.

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