Isoform-specific Targeting and Interaction Domains in Human Nicotinamide Mononucleotide Adenylyltransferases

Corinna Lau,Christian Dölle,Toni I Gossmann,Line Agledal,Marc Niere,Mathias Ziegler

doi:10.1074/jbc.m110.107631

Corinna Lau, Christian Dölle + Show 4 more

Open Access

https://doi.org/10.1074/jbc.m110.107631

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Abstract

Several important signaling pathways require NAD as substrate, thereby leading to significant consumption of the molecule. Because NAD is also an essential redox carrier, its continuous resynthesis is vital. In higher eukaryotes, maintenance of compartmentalized NAD pools is critical, but so far rather little is known about the regulation and subcellular distribution of NAD biosynthetic enzymes. The key step in NAD biosynthesis is the formation of the dinucleotide by nicotinamide/nicotinic acid mononucleotide adenylyltransferases (NMNATs). The three human isoforms were localized to the nucleus, the Golgi complex, and mitochondria. Here, we show that their genes contain unique exons that encode isoform-specific domains to mediate subcellular targeting and post-translational modifications. These domains are dispensable for catalytic activity, consistent with their absence from NMNATs of lower organisms. We further demonstrate that the Golgi-associated NMNAT is palmitoylated at two adjacent cysteine residues of its isoform-specific domain and thereby anchored at the cytoplasmic surface, a potential mechanism to regulate the cytosolic NAD pool. Insertion of unique domains thus provides a yet unrecognized enzyme targeting mode, which has also been adapted to modulate subcellular NAD supply.

Highlights

The metabolism of NAD has emerged as a complex network of reactions with immediate impact on fundamental biological processes [1,2,3]
We studied the distribution of wild-type NMNAT2 and the FLAGISTID2-enhanced green fluorescent protein (eGFP) fusion protein following treatment of cells with nocodazole or Brefeldin A (BFA), which both disrupt Golgi structures
In conwas tested using HeLa S3 cells transiently transfected with plas- trast, the isoform-specific targeting and interaction domains (ISTIDs) of NMNAT3 apparently evolved neutrally, not mids encoding wild-type NMNAT2 or the FLAG-ISTID2- being subject to selective pressure

Summary

Unique Targeting Domains in NMNATs

Human NMNAT2 was localized to the Golgi complex, whereas NMNAT3 is a mitochondrial protein [27, 28]. The Golgi localization of NMNAT2 is puzzling because little is known about NAD-dependent processes in this compartment. This study was based on the intriguing presence of the unresolved region in human NMNAT1 and its potential role in signaling and subcellular targeting. We hypothesized that additional functional domains could have been acquired by NMNATs of higher eukaryotes to mediate non-catalytic functions such as subcellular localization and regulatory interactions. Our analyses demonstrate that all three human NMNAT genes contain unique exons encoding isoform-specific sequence insertions. These domains have evolved to mediate subcellular targeting, post-translational modifications, and regulatory functions, and we designate them as isoform-specific targeting and interaction domains (ISTIDs)

EXPERIMENTAL PROCEDURES

RESULTS

Several observations of this study support the conclusion that

Estimation of evolutionary pressure on ISTIDs

Statistical significance of model E compared with