The histidine residue of codon 715 is essential for function of elongation factor 2

Several mutant cDNAs of elongation factor 2 (EF-2) were constructed by site-directed mutagenesis and their products expressed in mouse cells were investigated. Amino acid substitution for the histidine residue of codon 715, which is modified post-translationally to diphthamide, resulted in non-functional EF-2 and this substitution did not render EF-2 resistant to Pseudomonas aeruginosa exotoxin A, which inactivates EF-2 transferring ADP-ribose to the diphthamide residue. These non-functional EF-2s with replacements of the histidine-715 residue showed various extents of inhibition of protein synthesis by competing with functional EF-2 in vivo. These results suggest that histidine-715 is essential for the translocase activity of EF-2 and that the region around diphthamide functions in recognition of, and/or binding to ribosomes. Substitution of proline for the alanine-713 residue and substitution of glutamine for the glycine-717 residue converted EF-2 to partially toxin-resistant forms. Two-dimensional gel analysis with fragment A of diphtheria toxin of these toxin-resistant EF-2s revealed that their ADP-ribosylations by toxin were much less than that of wild-type EF-2.     

The post-translational trimethylation of diphthamide studied in vitro

The amino acid diphthamide is a complex post-translational derivative of histidine that exists in eukaryotic and Archaebacterial elongation factor 2 (EF-2). Diphtheria toxin and Pseudomonas exotoxin A catalyze the transfer of an ADP-ribose residue from NAD to diphthamide, causing the inactivation of EF-2. We have used cytosolic extracts of mutant CHO-K1 cells to study the biosynthesis of diphthamide in vitro. We have identified chromatographically a precursor form of diphthamide that exists in one complementation group of mutant cells and have documented the addition of 3 methyl residues from S-adenosylmethionine to this precursor. We have identified the presence of methyltransferase capable of carrying out this reaction in vitro in cells of 15 diverse eukaryotic species.     

Modulation of diphthamide synthesis by 5'-deoxy-5'-methylthioadenosine in murine lymphoma cells

The histidine derivative diphthamide occurs uniquely in eukaryotic elongation factor 2 (EF-2), and is the specific target for the diphtheria toxin mono(ADP-ribosyl)transferase. The first step in diphthamide biosynthesis may involve the transfer of aminocarboxypropyl moiety from S-adenosylmethionine to the imidazole ring of histidine in EF-2, to yield 2-(3-carboxy-3-aminopropyl)histidine and 5'-deoxy-5'-methylthioadenosine (MeSAdo). As the possible nucleoside product of the initial reaction in the diphthamide biosynthetic pathway, MeSAdo could be an inhibitor of diphthamide formation. In the present experiments, we have analyzed the effects of MeSAdo on diphthamide synthesis in a MeSAdo phosphorylase-deficient mutant murine lymphoma cell line (R1.1, clone H3). As measured by susceptibility to diphtheria toxin-induced ADP-ribosylation, MeSAdo inhibited the formation of diphthamide in EF-2. The inhibition was not due to a nonspecific effect on protein synthesis. Indeed, exogenous MeSAdo substantially protected the lymphoma cells from the lethal effects of diphtheria toxin. These results suggest that MeSAdo can specifically modulate the biosynthesis of diphthamide in EF-2 in murine malignant lymphoma cells.     

In vitro biosynthesis of diphthamide, studied with mutant Chinese hamster ovary cells resistant to diphtheria toxin.

Diphthamide, a unique amino acid, is a post-translational derivative of histidine that exists in protein synthesis elongation factor 2 at the site of diphtheria toxin-catalyzed ADP-ribosylation of elongation factor 2. We investigated steps in the biosynthesis of diphthamide with mutants of Chinese hamster ovary cells that were altered in different steps of this complex post-translational modification. Biochemical evidence indicates that this modification requires a minimum of three steps, two of which we accomplished in vitro. We identified a methyltransferase activity that transfers methyl groups from S-adenosyl methionine to an unmethylated form of diphthine (the deamidated form of diphthamide), and we tentatively identified an ATP-dependent synthetase activity involved in the biosynthesis of diphthamide from diphthine. Our results are in accord with the proposed structure of diphthamide (B. G. VanNess, et al., J. Biol. Chem. 255:10710-10716, 1980).     

Site-specific mutagenesis of the histidine precursor of diphthamide in the human elongation factor-2 gene confers resistance to diphtheria toxin

Protein synthesis elongation factor 2 (EF-2) from eukaryotes contains a conserved post-translationally modified histidine residue known as diphthamide. Diphthamide is a unique site of ADP-ribosylation by diphtheria toxin (DT), which is responsible for cell killing. In this report, we describe the construction of DT-resistant HeLa cell lines by engineering the toxin-resistant form of its specific substrate, protein elongation factor-2. Using site-specific mutagenesis of the histidine precursor of diphthamide, the histidine residue of codon 715 in human EF-2 cDNA was substituted with one of four amino acid residue codons: leucine, methionine, asparagine or glutamine. Mutant EF-2s were subcloned into a pCMVexSVneo expression vector, transfected into HeLa cells, and DT-resistant cell clones were isolated. The protective effect of mutant EF-2s against cell killing by DT, after exposing all four mutant strains derived from HeLa cells to different concentrations of the toxin (5-20 ng/mL) was demonstrated by: (1) the normal morphological appearance of the cells; (2) their unaffected or slightly slower growth rates; (3) their undisturbed electrophoretic DNA profiles whose integrity was virtually preserved. Mutant cell strains showed also considerable levels of resistance to very high concentrations of DT, in that they maintained slower but consistent rates of cell growth. It was hence concluded that despite its strict conservation and unique modification, the diphthamide histidine appears not to be essential to the function of human EF-2 in protein synthesis. In addition, DT-resistant HeLa cell clones should prove valuable hosts for various DT gene-containing vectors that express the toxin intracellularly.     

Gene for the diphtheria toxin-susceptible elongation factor 2 from Methanococcus vannielii.

Protein synthesis elongation factor 2 (EF-2) from all archaebacteria so far analysed, is susceptible to inactivation by diphtheria toxin, a property which it shares with EF-2 from the eukaryotic 8OS translation system. To resolve the structural basis of diphtheria toxin susceptibility, the structural gene for the EF-2 from an archaebacterium, Methanococcus vannielii, was cloned and its nucleotide sequence determined. It was found that (i) this gene is closely linked to that coding for elongation factor 1 alpha-(EF-1 alpha), (ii) the size of the gene product, as derived from the nucleotide sequence, lies between those for EF-2 from eukaryotes and eubacteria, (iii) it displays a higher sequence similarity to eukaryotic EF-2 than to eubacterial homologues, and (iv) the histidine residue which is modified to diphthamide and then ADP-ribosylated by diphtheria toxin is present in a sequence context similar to that of eukaryotic EF-2 but it is not conserved in eubacterial EF-G. The EF-2 gene from Methanococcus is expressed in transformed Saccharomyces cerevisiae but is not ADP-ribosylated by diphtheria toxin. This indicates that the Saccharomyces enzyme system is unable to post-translationally convert the respective histidine residue from the Methanococcus EF-2 into diphthamide.     

Modulation of diphthamide synthesis by 5′-deoxy-5′-methylthioadenosine in murine lymphoma cells

The histidine derivative diphthamide occurs uniquely in eukaryotic elongation factor 2 (EF-2), and is the specific target for the diphtheria toxin mono(ADP-ribosyl)transferase. The first step in diphthamide biosynthesis may involve the transfer of an aminocarboxypropyl moiety from S-adenosylmethionine to the imidazole ring of histidine in EF-2, to yield 2-(3-carboxy-3-aminopropyl)histidine and 5′-deoxy-5′-methylthioadenosine (MeSAdo). As the possible nucleoside product of the initial reaction in the diphthamide biosynthetic pathway, MeSAdo could be an inhibitor of diphthamide formation. In the present experiments, we have analyzed the effects of MeSAdo on diphthamide synthesis in a MeSAdo phosphorylase-deficient mutant murine lymphoma cell line (R1.1, clone H3). As measured by susceptibility to diphtheria toxin-induced ADP-ribosylation, MeSAdo inhibited the formation of diphthamide in EF-2. The inhibition was not due to a nonspecific effect on protein synthesis. Indeed, exogenous MeSAdo substantially protected the lymphoma cells from the lethal effects of diphtheria toxin. These results suggest that MeSAdo can specifically modulate the biosynthesis of diphthamide in EF-2 in murine malignant lymphoma cells.     

ADP-ribosyltransferase from beef liver which ADP-ribosylates elongation factor-2

Fragment A of diphtheria toxin and Pseudomonas toxin A intoxicate cells by ADP-ribosylating the diphthamide residue of elongation factor-2 (EF-2) resulting in an inhibition of protein synthesis [1-3]. A cellular enzyme from polyoma virus transformed baby hamster kidney (pyBHK) cells ADP-ribosylates EF-2 in an identical manner [4]. Here we describe a similar cellular enzyme from beef liver which transfers [adenosine-14C]ADP-ribose from NAD to EF-2. The 14C-label can be removed from the EF-2 by snake venom phosphodiesterase as a soluble product which comigrates with AMP on TLC plates, indicating the 14C-label is present on EF-2 as monomeric units of ADP-ribose. Furthermore, the forward transferase reaction catalyzed by the beef liver ADP-ribosyltransferase is reversible by excess diphtheria toxin fragment A, with the formation of 14C-labeled NAD, indicating that both transferases ADP-ribosylate the same site on the diphthamide residue of EF-2. Thus, beef liver and pyBHK mono(ADP-ribosyl)transferases both modify the diphthamide residue of EF-2, in a manner identical to diphtheria toxin fragment A and Pseudomonas toxin A. These results suggest the cellular enzyme is probably ubiquitous among eukaryotic cells.     

OVCA1: tumor suppressor gene

OVCA1, also known as DPH2L1, is a tumor suppressor gene associated with ovarian carcinoma and other tumors. Ovca1 homozygous mutant mice die at birth with developmental delay and cell-autonomous proliferation defects. Ovca1 heterozygous mutant mice are tumor-prone but rarely develop ovarian tumors. OVCA1 appears to be the homolog of yeast DPH2, which participates in the first biosynthetic step of diphthamide, by modification of histidine on translation elongation factor 2 (EF-2). Yeast dph2 mutants are resistant to diphtheria toxin, which catalyses ADP ribosylation of EF-2 at diphthamide. Thus, there appears to be growing evidence implicating alterations in protein translation with tumorigenesis.     

The biosynthesis and biological function of diphthamide

Abstract

Eukaryotic and archaeal elongation factor 2 contains a unique post-translationally modified histidine residue, named diphthamide. Genetic and biochemical studies have revealed that diphthamide biosynthesis involves a multi-step pathway that is evolutionally conserved among lower and higher eukaryotes. During certain bacterial infections, diphthamide is specifically recognized by bacterial toxins, including diphtheria toxin, Pseudomonas exotoxin A and cholix toxin. Although the pathological relevance is well studied, the physiological function of diphthamide is still poorly understood. Recently, many new interesting developments in understanding the biosynthesis have been reported. Here, we review the current understanding of the biosynthesis and biological function of diphthamide.     

Characterization of the endogenous ADP-ribosylation of wild-type and mutant elongation factor 2 in eukaryotic cells.

Anti-[ADP-ribosylated elongation factor 2 (EF-2)] antiserum has been used to immunoprecipitate the modified form of EF-2 from polyoma-virus-transformed baby hamster kidney (pyBHK) cells [Fendrick, J. L. & Iglewski, W. J. (1989) Proc. Natl Acad. Sci. USA 86, 554-557]. This antiserum also immunoprecipitates a 32P-labelled protein of similar size to EF-2 from a variety of primary and continuous cell lines derived from many species of animals. One of these cell lines, chinese hamster ovary CHO-K1 cells was further characterized. The time course of labelling of ADP-ribosylated EF-2 with [32P]orthophosphate was similar in pyBHK cells and in CHO-K1 cells. The kinetics of labelling were more rapid for cells cultured in 2% serum than 10% serum, with incorporation of 32P reaching a maximum at 6 h and 10 h, respectively. EF-2 mutants of pyBHK and CHO-K1 cells resistant to diphtheria-toxin-catalyzed ADP-ribosylation of EF-2 remain sensitive to cellular ADP-ribosylation of EF-2. The 32P-labelled moiety of ADP-ribosylated EF-2 was digested by snake venom phosphodiesterase and the product was identified as AMP. The same 32P-labelled tryptic peptide was modified by toxin in wild-type EF-2 and by the cellular transferase in mutant EF-2. When purified EF-2 from pyBHK cells was incubated with [carbonyl-14C]nicotinamide and diphtheria toxin fragment A, under conditions for reversal of the ADP-ribosylation reaction, [14C]NAD was generated. The results suggest that cellular ADP-ribosylated EF-2 exists in a variety of cell types, and the ribosylated product is identical to that produced by toxin ADP-ribosylation of EF-2, except in diphthamide mutant cells. Studies with the mutant cell lines indicate that the toxin and the cellular transferase, however, recognize different determinants at the ADP-ribose acceptor site in EF-2. The cellular transferase does not require the diphthamide modification of the histidine ring in the amino acid sequence of EF-2 for the transfer of ADP-ribose to the ring. Therefore, we would expect the cellular transferase active site to be similar to, but not identical to, the critical amino acids demonstrated in the active site of diphtheria toxin and Pseudomonas exotoxin A.     

Occurrence of diphthamide in archaebacteria

We examined the nature of the diphtheria toxin fragment A recognition site in the protein synthesis translocating factor present in cell-free preparations from the archaebacteria Thermoplasma acidophilum and Halobacterium halobium. In agreement with earlier work (M. Kessel and F. Klink, Nature (London) 287:250-251, 1980), we found that extracts from these organisms contain a protein factor which is a substrate for the ADP-ribosylation reaction catalyzed by diphtheria toxin fragment A. However, the rate of the reaction was approximately 1,000 times slower than that typically observed with eucaryotic elongation factor 2. We also demonstrated the presence of diphthine (the deamidated form of diphthamide, i.e., 2-[3-carboxyamide-3-(trimethylammonio)propyl]histidine) in acid hydrolysates of H. halobium protein in amounts comparable to those found in hydrolysates of similar preparations from eucaryotic cells (Saccharomyces cerevisiae and HeLa). Diphthine could not be detected in hydrolysates of protein from the eubacterium Escherichia coli. Whereas both archaebacterial and eucaryotic elongation factors contain diphthamide, they differ importantly in other respects.     

The role of the diphthamide-containing loop within eukaryotic elongation factor 2 in ADP-ribosylation by Pseudomonas aeruginosa exotoxin A

eEF2 (eukaryotic elongation factor 2) contains a post-translationally modified histidine residue, known as diphthamide, which is the specific ADP-ribosylation target of diphtheria toxin, cholix toxin and Pseudomonas aeruginosa exotoxin A. Site-directed mutagenesis was conducted on residues within the diphthamide-containing loop (Leu693-Gly703) of eEF2 by replacement with alanine. The purified yeast eEF2 mutant proteins were then investigated to determine the role of this loop region in ADP-ribose acceptor activity of elongation factor 2 as catalysed by exotoxin A. A number of single alanine substitutions in the diphthamide-containing loop caused a significant reduction in the eEF2 ADP-ribose acceptor activities, including two strictly conserved residues, His694 and Asp696. Analysis by MS revealed that all of these mutant proteins lacked the 2'-modification on the His699 residue and that eEF2 is acetylated at Lys509. Furthermore, it was revealed that the imidazole ring of Diph699 (diphthamide at position 699) still functions as an ADP-ribose acceptor (albeit poorly), even without the diphthamide modification on the His699. Therefore, this diphthamide-containing loop plays an important role in the ADP-ribosylation of eEF2 catalysed by toxin and also for modification of His699 by the endogenous diphthamide modification machinery.     

Saccharomyces cerevisiae elongation factor 2. Genetic cloning, characterization of expression, and G-domain modeling.

The elongation factor 2 (EF-2) genes of the yeast Saccharomyces cerevisiae have been cloned and characterized with the ultimate goal of gaining a better understanding of the mechanism and control of protein synthesis. Two genes (EFT1 and EFT2) were isolated by screening a bacteriophage lambda yeast genomic DNA library with an oligonucleotide probe complementary to the domain of EF-2 that contains diphthamide, the unique posttranslationally modified histidine that is specifically ADP-ribosylated by diphtheria toxin. Although EFT1 and EFT2 are located on separate chromosomes, the DNA sequences of the two genes differ at only four positions out of 2526 base pairs, and the predicted protein sequences are identical. Genetic deletion of each gene revealed that at least one functional copy of either EFT gene is required for cell viability. Messenger RNA levels of yeast EF-2 parallel cellular growth and peak in mid-log phase cultures. The EF-2 protein sequence is strikingly conserved through evolution. Yeast EF-2 is 66% identical to, and shares over 85% homology with, human EF-2. In addition, yeast and mammalian EF-2 share identical sequences at two critical functional sites: (i) the domain containing the histidine residue that is modified to diphthamide and (ii) the threonine residue that is specifically phosphorylated in vivo in mammalian cells by calmodulin-dependent protein kinase III, also known as EF-2 kinase. Furthermore, yeast EF-2 also contains the Glu-X-X-Arg-X-Ile-Thr-Ile "effector" sequence motif that is conserved among all known elongation factors, and its GTP-binding domain exhibits strong homology to the G-domain of Escherichia coli elongation factor Tu (EF-Tu) and other G-protein family members. Based upon these observations, we have modeled the G-domain of the deduced EF-2 protein sequence to the solved crystallographic structure for EF-Tu.     

Dph3, a small protein required for diphthamide biosynthesis, is essential in mouse development

The translation elongation factor 2 in eukaryotes (eEF-2) contains a unique posttranslationally modified histidine residue, termed diphthamide, which serves as the only target for diphtheria toxin and Pseudomonas aeruginosa exotoxin A. Diphthamide biosynthesis is carried out by five highly conserved proteins, Dph1 to Dph5, and an as-yet-unidentified amidating enzyme. The evolutionary conservation of the complex diphthamide biosynthesis pathway throughout eukaryotes implies a key role for diphthamide in normal cellular physiology. Of the proteins required for diphthamide synthesis, Dph3 is the smallest, containing only 82 residues. In addition to having a role in diphthamide biosynthesis, Dph3 is also involved in modulating the functions of the Elongator complex in yeast. To explore the physiological roles of Dph3 and to begin to investigate the function of diphthamide, we generated dph3 knockout mice and showed that dph3+/- mice are phenotypically normal, whereas dph3-/- mice, which lack the diphthamide modification on eEF-2, are embryonic lethal. Loss of both dph3 alleles causes a general delay in embryonic development accompanied by lack of allantois fusion to the chorion and increased degeneration and necrosis in neural tubes and is not compatible with life beyond embryonic day 11.5. The dph3-/- placentas also developed abnormally, showing a thinner labyrinth lacking embryonic erythrocytes and blood vessels. These results attest to the physiological importance of Dph3 in development. The biological roles of Dph3 are also discussed.     

Characterization of the diphtheria toxin-resistance system in Chinese hamster ovary cells.

Variations in two general classes of diphtheria toxin-resistant mutants which may be selected from Chinese hamster ovary (CH0-K1) cells and the conditions for their selection are described. The resistance of class I mutants can be overcome with increasing concentrations of toxin. Their entire complement of EF-2 is susceptible to ADP-ribosylation by toxin. Class I includes those strains in which resistance resides at the level of the plasma membrane. The resistance of class II, translational, mutants cannot be overcome by high concentrations of toxin, as all, or a portion, of their EF-2 is insensitive to the action of diphtheria toxin and Pseudomonas exotoxin A. Adjustment of the concentration of toxin used to select resistant mutants can be used to regulate the class of mutant recovered. Metabolic cooperation between cells does not affect recovery of either class I or class II mutants. Resistance is stable in class I strains, but class IIb strains, which possess 50% resistant and 50% sensitive EF-2, display a transient high level of resistance which is retained for varying lengths of time following exposure to toxin. Class IIa strains, which possess 100% resistant EF-2, grow normally in saturating concentrations of toxin, but class IIb strains grow at a reduced rate. Evidence is presented which suggests that the gene for EF-2 is functionally diploid in CHO-K1 cells.     

Identification of the gene encoding the mitochondrial elongation factor G in mammals.

Protein synthesis in cytosolic and rough endoplasmic reticulum associated ribosomes is directed by factors, many of which have been well characterized. Although these factors have been the subject of intense study, most of the corresponding factors regulating protein synthesis in the mitochondrial ribosomes remain unknown. In this report we present the cloning and initial characterization of the gene encoding the rat mitochondrial elongation factor-G (rEF-Gmt). The rat gene encoding EF-Gmt (rMef-g) maps to rat chromosome 2 and it is expressed in all tissues with highest levels in liver, thymus and brain. Its DNA sequence predicts a 752 amino acid protein exhibiting 72% homology to the yeast Saccharomyces cerevisiae mitochondrial elongation factor-G (YMEF-G), 62% and 61% homology to the Thermus thermophilus and E. coli elongation factor-G (EF-G) respectively and 52% homology to the rat elongation factor-2 (EF-2). The deduced amino acid sequence of EF-G contains characteristic motifs shared by all GTP binding proteins. Therefore, similarly to other elongation factors, the enzymatic function of EF-Gmt is predicted to depend on GTP binding and hydrolysis. EF-Gmt differs from its cytoplasmic homolog, EF-2, in that it contains an aspartic acid residue at amino acid position 621 which corresponds to the EF-2 histidine residue at position 715. Since this histidine residue, following posttranslational modification into diphthamide, appears to be the sole cellular target of diphtheria toxin and Pseudomonas aeruginosa endotoxin A, we conclude that EF-Gmt will not be inactivated by these toxins. The severe effects of these toxins on protein elongation in tissues expressing EF-Gmt suggest that EF-Gmt and EF-2 exhibit nonoverlapping functions. The cloning and characterization of the mammalian mitochondrial elongation factor G will permit us to address its role in the regulation of normal mitochondrial function and in disease states attributed to mitochondrial dysfunction.     

DPH5, a methyltransferase gene required for diphthamide biosynthesis in Saccharomyces cerevisiae.

A mutant of Saccharomyces cerevisiae defective in the S-adenosylmethionine (AdoMet)-dependent methyltransferase step of diphthamide biosynthesis was selected by intracellular expression of the F2 fragment of diphtheria toxin (DT) and shown to belong to complementation group DPH5. The DPH5 gene was cloned, sequenced, and found to encode a 300-residue protein with sequence similarity to bacterial AdoMet:uroporphyrinogen III methyltransferases, enzymes involved in cobalamin (vitamin B12) biosynthesis. Both DPH5 and AdoMet:uroporphyrinogen III methyltransferases lack sequence motifs commonly found in other methyltransferases and may represent a new family of AdoMet:methyltransferases. The DPH5 protein was produced in Escherichia coli and shown to be active in methylation of elongation factor 2 partially purified from the dph5 mutant. A null mutation of the chromosomal DPH5 gene did not affect cell viability, in agreement with other studies indicating that diphthamide is not required for cell survival. The dph5 null mutant survived expression of three enzymically attenuated DT fragments but was killed by expression of fully active DT fragment A. Consistent with these results, elongation factor 2 from the dph5 null mutant was found to have weak ADP-ribosyl acceptor activity, which was detectable only in the presence of high concentrations of fragment A.     

Highly frequent single amino acid substitution in mammalian elongation factor 2 (EF-2) results in expression of resistance to EF-2-ADP-ribosylating toxins

Toxin-resistant polypeptide chain elongation factor 2 cDNA has been cloned from a mutant hamster cell line with only non-ADP-ribosylatable elongation factor 2. The mutation conferring resistance to diphtheria toxin and Pseudomonas aeruginosa exotoxin A is a G-to-A transition in the first nucleotide of codon 717. Codon 715 encodes a histidine residue that is modified post-translationally to diphthamide, which is the target amino acid for ADP-ribosylation by both toxins. Transfection of mouse L cells with a recombinant elongation factor 2 cDNA differing from the wild-type only by this G-to-A transition confers resistance to P. aeruginosa exotoxin A. The degrees of toxin-resistant protein synthesis of stable transfectants are dependent on the ratio of non-ADP-ribosylated elongation factor 2 to wild-type elongation factor 2, not the amount of non-ADP-ribosylated elongation factor 2. The mutation creates a new Mbo II restriction site in the elongation factor 2 gene. Several independently isolated diphtheria toxin-resistant Chinese hamster ovary cell lines show the same alteration in the Mbo II restriction pattern.     

1-N6-Etheno-ADP-ribosylation of elongation factor-2 by diphtheria toxin

Diphtheria toxin fragment A is able to inhibit protein synthesis in the eukaryotic cell by ADP-ribosylating the diphthamide residue of elongation factor-2 (EF-2) [(1980) J. Biol. Chem. 255, 10710-10720]. The reaction requires NAD as ADP-ribose donor. This work reports on the capacity of an NAD analog, the nicotinamide 1-N6-ethenoadenine dinucleotide (epsilon NAD), to be a substrate of diphtheria toxin fragment A in the transferring reaction of the fluorescent moiety, the epsilon ADP-ribose, to the EF-2. As a consequence of the transfer of the epsilon ADP-ribosyl moiety to the EF-2, there is an increase in the emission intensity of the fluorophore and a blue shift in its emission maximum. The epsilon ADP-ribosylated EF-2, like ADP-ribosylated EF-2, retains the capacity to bind GTP and ribosome. The utility of introducing a fluorescent probe in a well defined point of the EF-2 molecule for conformational or binding studies is discussed.