NAD functions in multiple aspects of cellular metabolism and signaling through enzymes that covalently transfer ADP-ribose from NAD to acceptor proteins, thereby altering their function. NAD is a substrate for two enzyme families, mono-ADP-ribosyltransferases (mARTs) and poly(ADP-ribose) polymerases (PARPs), that covalently transfer an ADP-ribose monomer or polymer, respectively, to acceptor proteins. ART2, a mART, is a phenotypic marker of immunoregulatory cells found on the surface of T lymphocytes, including intestinal intraepithelial lymphocytes (IELs). We have shown that the auto-ADP-ribosylation of the ART2.2 allelic protein is multimeric. Our backbone structural alignment of ART2 (two alleles of the rat art2 gene have been reported, for simplicity, the ART2.2 protein investigated in this study will be referred to as ART2) and PARP suggested that multimeric auto-ADP-ribosylation of ART2 may represent an ADP-ribose polymer, rather than multiple sites of mono-ADP-ribosylation. To investigate this, we used highly purified recombinant ART2 and demonstrated that ART2 catalyzes the formation of an ADP-ribose polymer by sequencing gel and by HPLC and MS/MS mass spectrometry identification of PR-AMP, a breakdown product specific to poly(ADP-ribose). Furthermore, we identified the site of ADP-ribose polymer attachment on ART2 as Arg-185, an arginine in a crucial loop of its catalytic core. We found that endogenous ART2 on IELs undergoes multimeric auto-ADP-ribosylation more efficiently than ART2 on peripheral T cells, suggesting that these distinct lymphocyte populations differ in their ART2 surface topology. Furthermore, ART2.2 IELs are more resistant to NAD-induced cell death than ART2.1 IELs that do not have multimeric auto-ADP-ribosylation activity. The data suggest that capability of polymerizing ADP-ribose may not be unique to PARPs and that poly(ADP-ribosylation), an established nuclear activity, may occur extracellularly and modulate cell function.

Elucidation of signaling pathways that prevent immune cells from damaging self-tissue could help target diseases like lupus and juvenile diabetes. Through one such pathway, NAD and its metabolites appear to inhibit T cells of the immune system. NAD is a substrate for two enzyme families that covalently transfer ADP-ribose from NAD to acceptor proteins -- mono-ADP-ribosyl transferases (mARTs) and poly(ADP-ribose) polymerases (PARPs). PARPs distinguish themselves by polymerizing ADP-ribose on the acceptor proteins. Despite differences in amino acid sequences, mARTs and PARPs have similar structural elements in their catalytic cores. Here we report that in the presence of NAD, ART2, a mART and T cell surface protein, forms ADP-ribose polymers on an arginine in a crucial loop of its catalytic core. ART2 appears to be the first hybrid between the mARTs and PARPs, and structural data suggest a mechanism for polymerization activity. The data suggest that signaling with NAD metabolites like ADP-ribose may be a more versatile process than previously recognized, and that molecules like ART2 may have the potential to participate in novel immune cell signaling pathways.

The glycophosphatidylinositol(GPI)-linked membrane protein ART2 is an antigenic determinant for T lymphocytes that regulate the expression of diabetes in the BB/W rat model. Though little is understood of the physiologic role of ART2 on T lymphocytes, ART2 is a member of the mono-ADP-ribosyl transferase subgroup ofthe ADP-ribosyl transferase (ART) protein family. The ART protein family, which traditionally has been divided into mono-ADP-ribosyl transferases (mono-ARTs), poly(ADP)-ribose polymerases (PARPs), and ADP-ribosyl cyclases, influences various aspects of cellular physiology including: apoptosis, DNA damage repair, chromatin remodeling, telomere replication, cellular transport, immune regulation, neuronal function, and bacterial virulence. A structural alignment of ART2.2 with chicken PARP indicated the potential for ART2.2 to catalyze ADP-ribose polymers in an activity thought to be specific to the PARP subgroup and important for their regulation of nuclear processes. Kinetic studies determined that the auto-ADP-ribosyl transferase activity of ART2.2 is multitmeric and heterogeneous in nature. Hydroxylamine-cleaved ADP-ribose moieties from the ART2.2 multimers ran as polymers on a modified sequencing gel, and digestion of the polymers with snake-venom phosphodiesterase produced AMP and the poly(ADP)ribose-specific product, PR-AMP, which was resolved by analytical HPLC and structurally confirmed by ESI-MS. The ratio of AMP to PR-AMP was higher than that of PARP raising the possibility that the ART2.2 polymers had a different branching structure than those of PARP. This alternative branching was confirmed by the presence of ribose phosphate polymers in the snake venom phophodiesterase treated samples. The site of the auto-poly(ADP)-ribose modification was determined to be R185, a residue previously proposed to influence the level of auto-ADP ribosylation of ART2.2 by mutational analysis. These data provide the first demonstration of a hybrid between mono-ARTs and PARPs and are the earliest indication that PARP-like enzymes can exist outside the nucleus and on the cell surface.