HOMOLOGOUS REGIONS OF THE ALPHA-SUBUNIT OF EUKARYOTIC TRANSLATIONAL INITIATION-FACTOR-2 (EIF2-ALPHA) AND THE VACCINIA VIRUS K3L GENE-PRODUCT INTERACT WITH THE SAME DOMAIN WITHIN THE DSRNA-ACTIVATED PROTEIN-KINASE (PKR)
Tv. Sharp et al., HOMOLOGOUS REGIONS OF THE ALPHA-SUBUNIT OF EUKARYOTIC TRANSLATIONAL INITIATION-FACTOR-2 (EIF2-ALPHA) AND THE VACCINIA VIRUS K3L GENE-PRODUCT INTERACT WITH THE SAME DOMAIN WITHIN THE DSRNA-ACTIVATED PROTEIN-KINASE (PKR), European journal of biochemistry, 250(1), 1997, pp. 85-91
The vaccinia virus K3L gene product, pK3, binds to the dsRNA-activated
protein kinase, PKR, reducing its ability to interact with and phosph
orylate eIF2 alpha. On the basis of this characteristic and the homolo
gy of pK3 to the N-terminus of eIF2 alpha, several laboratories have u
tilized pK3 to investigate the molecular determinants that specify sub
strate recognition by PKR. The data presented here demonstrate that th
e natural substrate, eIF2 alpha, also binds to PKR in vitro and intera
cts with the same or an overlapping domain within PKR. A truncated for
m of eIF2 alpha, representing the N-terminal 123 amino acids and conta
ining the regions of homology to pK3, retains the ability to bind PKR.
pK3, eIF2 alpha, and the truncated form of eIF2 alpha all bind to the
C-terminus of PKR containing the catalytic domain, but not to the reg
ulatory N-terminus. Variants of pK3 and eIF2 alpha, des-(75-78)-K3L (p
K3 Delta GYID), and des-(80-83)-eIF2 alpha (eIF2 alpha Delta-GYID), fr
om which the conserved amino acids GYID have been deleted, exhibit a d
ecreased ability to interact with PKR. Similarly, the in vitro binding
of pK3, eIF2 alpha, and the truncated form of eIF2 alpha to PKR can b
e competed with purified pK3 but not with pK3 Delta GYID. In addition,
the deletion of GYID from eIF2 alpha significantly reduces its abilit
y to be phosphorylated by PKR, demonstrating that PKR recognizes its s
ubstrate, at least in part through interaction with sequences remote f
rom the phosphorylation site. In summary, we have shown that the regio
n within PKR that interacts with the pseudosubstrate, pK3, is the same
region that interacts with the authentic substrate, eIF2 alpha. In ad
dition, we have shown that the N-terminal 123 amino acids of eIF2 alph
a contains structural elements necessary for recognition by PKR. The r
esults pinpoint the GYID motif, shared between pK3 and eIF2 alpha and
distant from the phosphorylation site, as being important for the inte
raction of eIF2 alpha with PKR, as well as its phosphorylation.