NTP-entry routes in multi-subunit RNA polymerases

The recent elucidation of crystal structures for multi-subunit RNA polymerases immediately revealed a mystery: how do nucleotide triphosphate (NTP) substrates reach an active site that is buried deep within the enzyme? The prevailing view is that NTPs enter through an approximately 20A-long secondary channel between the active site and the enzyme surface. Recently, an alternative view has been advocated; namely, NTPs enter the active site pre-bound to the DNA template from the downstream DNA portion of the main channel of the enzyme.     

Immunological relationships between Artemia RNA polymerases and between RNA polymerases II from different eukaryotic organisms

Summary Rabbit antibodies against Artemia RNA polymerase II have been raised and utilized to study the immunological relationships between the subunits from RNA polymerases I, II and III from this organism and RNA polymerase II from other eukaryotes. We describe here for the first time the subunit structure of Artemia RNA polymerases I and III. These enzymes have 9 and 13 subunits respectively. The anti-RNA polymerase II antibodies recognize two subunits of 19.4 and 18 kDa common to the three enzymes, and another subunit of 25.6 kDa common to RNA polymerases II and III. The antibodies against Artemia RNA polymerase II also react with the subunits of high molecular weight and with subunits of around 25 and 33 kDa of RNA polymerase II from other eukaryotes (Drosophila melanogaster, Chironomus thummi, triticum (wheat) and Rattus (rat)). This interspecies relatedness is a common feature of eukaryotic RNA polymerases.Abbreviations RNAp RNA polymerase - DPT diazophenylthioether - SDS sodium dodecylsulfate     

Zinc-binding subunits of yeast RNA polymerases

The zinc-binding subunits of yeast RNA polymerase A(I) and B(II) have been identified by a zinc-blotting technique. The two largest subunits of each enzyme (A190, A135, B220, and B150), as well as A12.2, A10, B44.5, B12.6, and B10, bind 65Zn(II). Predicted zinc-binding motifs have been noted in the NH2-terminal part of B220 and the COOH-terminal region of B150 subunits. Subdomains encompassing these motifs have been overproduced as MalE-fusion proteins and shown to retain zinc binding activity. Site-directed mutagenesis in the predicted metal-binding domain of B150 demonstrated its role in zinc binding. Mutations of cysteine residues C1163, C1166, C1182, and C1185 affected 65Zn2+ binding in vitro and caused a lethal or thermosensitive phenotype for growth. The ability to bind zinc is not sufficient for function since mutations in vicinal residues not affecting zinc binding were either lethal or thermosensitive. The role of zinc in RNA polymerase structure and function is discussed in the light of the present results.