Mapping the Neural Substrates of Recent and Remote Visual Imprinting Memory in the Chick Brain.

Social attachment formed by filial imprinting in newborn chicks undergoes a process of memory consolidation that involves rearrangement of its neural storage substrates. In the first 3 h after imprinting it depends on the integrity of the intermediate medial mesopallium (IMM) and beyond that time on unidentified memory storage structures dubbed S'. To search for the S' memory system in the chick brain, we mapped and compared patterns of activity induced by retrieval of filial attachment memory before and after this critical transition. Chicks were trained in the visual imprinting task, and their memory was reactivated by imprinting stimulus either 1 h (recent memory retrieval) or 24 h (remote memory retrieval) after the completion of training. Patterns of brain activity were mapped by in situ hybridization to mRNA of an immediate early gene c-fos. We also mapped c-fos expression induced by the first presentation of the imprinting stimulus. Memory retrieval triggered massive c-fos expression in the chick brain both 1 and 24 h after the end of training. These activity patterns mostly coincided with the c-fos expression induced by the first presentation of imprinting stimulus. However, in the hippocampus c-fos induction was observed only after the first exposure to imprinting stimulus but not after memory retrieval. In the IMM, medio-rostral nidopallium/mesopallium, and hyperpallium densocellulare c-fos activation was induced by retrieval of only the remote but not of the recent memory. These c-fos mapping data point to the candidate brain structures for systems reorganization of imprinting memory in chicks.

RNA folding in transcription elongation complex: implication for transcription termination.

Intrinsic transcription termination signal in DNA consists of a short inverted repeat followed by a T-rich stretch. Transcription of this sequence by RNA polymerase (RNAP) results in formation of a "termination hairpin" (TH) in the nascent RNA and in rapid dissociation of the transcription elongation complex (EC) at termination points located 7-8 nt downstream of the base of TH stem. RNAP envelops 15 nt of the RNA following RNA growing 3'-end, suggesting that folding of the TH is impeded by a tight protein environment when RNAP reaches the termination points. To monitor TH folding under this constraint, we halted Escherichia coli ECs at various distances downstream from a TH and treated them with single-strand specific RNase T1. The EC interfered with TH formation when halted at 6, 7, and 8, but not 9, nt downstream from the base of the potential stem. Thus, immediately before termination, the downstream arm of the TH is protected from complementary interactions with the upstream arm. This protection makes TH folding extremely sensitive to the sequence context, because the upstream arm easily engages in competing interactions with the rest of the nascent RNA. We demonstrate that by de-synchronizing TH formation and transcription of the termination points, this subtle competition significantly affects the efficiency of transcription termination. This finding can explain previous puzzling observations that sequences far upstream of the TH or point mutations in the terminator that preserve TH stability affect termination. These results can help understand other time sensitive co-transcriptional processes in pro- and eukaryotes.

Inhibition of a transcriptional pause by RNA anchoring to RNA polymerase.

We describe a mechanism by which nascent RNA inhibits transcriptional pausing. PutL RNA of bacteriophage HK022 suppresses transcription termination at downstream terminators and pausing within a nearby U-rich sequence. In vitro transcription and footprinting assays reveal that this pausing results from backtracking of RNA polymerase and that binding of nascent putL RNA to polymerase limits backtracking by restricting re-entry of the transcript into the RNA exit channel. The restriction is local and relaxes as the transcript elongates. Our results suggest that putL RNA binds to the surface of polymerase close to the RNA exit channel, a region that includes amino acid residues important for antitermination. Although binding is essential for antipausing and antitermination, these two activities of put differ: antipausing is limited to the immediate vicinity of the putL site, but antitermination is not. We propose that RNA anchoring to the elongation complex is a widespread mechanism of pause regulation.

DNA sequences in gal operon override transcription elongation blocks.

The DNA loop that represses transcription from galactose (gal) promoters is infrequently formed in stationary-phase cells because the concentration of the loop architectural protein HU is significantly low at that state, resulting in expression of the operon in the absence of the gal inducer D-galactose. Unexpectedly, transcription from the gal promoters under these conditions overrides physical block because of the presence of the Gal repressor bound to an internal operator (O(I)) located downstream of the promoters. We have shown here that although a stretch of pyrimidine residues (UUCU) in the RNA:DNA hybrid located immediately upstream of O(I) weakens the RNA:DNA hybrid and favors RNA polymerase (RNAP) pausing and backtracking, a stretch of purines (GAGAG) in the RNA present immediately upstream of the pause sequence in the hybrid acts as an antipause element by stabilizing the RNA:DNA duplex and preventing backtracking. This facilitates forward translocation of RNAP, including overriding of the DNA-bound Gal repressor barrier at O(I). When the GAGAG sequence is separated from the pyrimidine sequence by a 5-bp DNA insertion, RNAP backtracking is favored from a weak hybrid to a more stable hybrid. RNAP backtracking is sensitive to Gre factors, D-galactose, and antisense oligonucleotides. The ability of a native DNA sequence to override transcription elongation blocks in the gal operon uncovers a previously unknown way of regulating gal metabolism in Escherichia coli. It also explains the synthesis of gal enzymes in the absence of inducer for biosynthetic reactions.

Shortening of RNA:DNA hybrid in the elongation complex of RNA polymerase is a prerequisite for transcription termination.

Passage of E. coli RNA polymerase through an intrinsic transcription terminator, which encodes an RNA hairpin followed by a stretch of uridine residues, results in quick dissociation of the elongation complex. We show that folding of the hairpin disrupts the three upstream base pairs of the 8 bp RNA:DNA hybrid, a major stability determinant in the complex. Shortening the weak rU:dA hybrid from 8 nt to 5 nt causes dissociation of the complex. During termination, the hairpin does not directly compete for base pairing with the 8 bp hybrid. Thus, melting of the hybrid seems to result from spatial restrictions in RNA polymerase that couple the hairpin formation with the disruption of the hybrid immediately downstream from the stem. Our results suggest that a similar mechanism disrupts elongation complexes of yeast RNA polymerase II in vitro.

Transcription termination: primary intermediates and secondary adducts.

In living organisms, stable elongation complexes of RNA polymerase dissociate at specific template positions in a process of transcription termination. It has been suggested that the dissociation is not the immediate cause of termination but is preceded by catalytic inactivation of the elongation complex. In vitro reducing ionic strength can be used to stabilize very unstable and catalytically inactive complex at the point of termination; the previous biochemical characterization of this complex has led to important conclusions regarding termination mechanism. Here we analyze in detail the complexes formed between DNA template, nascent RNA, and Escherichia coli RNA polymerase during transcription through the tR2 terminator of bacteriophage lambda. At low ionic strength, the majority of elongation complexes fall apart upon reaching the terminator. Released RNA and DNA efficiently rebind RNA polymerase (RNAP) and form binary RNAP.RNA and RNAP.DNA complexes, which are indistinguishable from binary complexes obtained by direct mixing of the purified nucleic acids and the enzyme. A small fraction of elongation complexes that reach termination point escapes dissociation because RNA polymerase has backtracked from the terminator to an upstream DNA position. Thus, transcription elongation to a terminator site produces no termination intermediates that withstand dissociation in the time scale appropriate for biochemical studies.