Molecular cloning and characterization of a translational inhibitory protein that binds to coding sequences of human acid beta-glucosidase and other mRNAs

Abstract

Acid beta-glucosidase (GCase) is the enzyme deficient in Gaucher disease, a prototypical inherited metabolic error for enzyme and gene therapy. An 80-kDa cytoplasmic protein, termed TCP80, was found to inhibit GCase mRNA translation in mammalian cells by binding to RNA-coding regions. The TCP80 cDNA was cloned by screening an expression library with the GCase-coding region RNA. The cDNA sequence was nearly identical to those for M-phase phosphoprotein (MPP4; 99%) and for the IL-2 enhancer binding protein (NF90; 96%). Expression of the carboxy-terminal third, TCP30, showed it to be an RNA-binding protein that bound to a 184-nt fragment of GCase-coding sequence near the 5' end of the mature mRNA. When added to reactions, a large molar excess of TCP30 diminished the translation inhibition of GCase RNA by cytoplasmic TCP80. TCP50, expressed from the NH(2)-terminal two-thirds of TCP80, did not bind to nor inhibit the translation of GCase RNA. Reconstitution of in vitro translation inhibition of GCase RNA required intact human TCP80 heterologously expressed in insect cells. Time course analyses show that TCP80 functions at the initiation phase of GCase mRNA translation, probably by inhibiting its binding to polysomes. Seven additional RNAs were isolated by specific binding to TCP30 including those for aldolase B, complement protein 8 gamma-subunit, fibronectin receptor beta1, ABL, lactate dehydrogenase A, fibrinogen gamma-chain, and peroxisomal proliferator-activated receptor alpha. In vitro translation of their RNAs was inhibited by TCP80. These studies show that TCP80 has RNA-binding (TCP30) and inhibitory (TCP50) domains that function to modulate translation of several mRNAs. TCP80 is likely identical to MPP4 and NF90, but has previously undescribed roles in cellular function.