Estrogen signaling to GnRH neurons is critical for coordinating the preovulatory surge release of LH with follicular maturation. Until recently it was thought that estrogen signaled GnRH neurons only indirectly through numerous afferent systems. This minireview presents new evidence indicating that GnRH neurons are directly regulated by estradiol (E2), primarily through estrogen receptor (ER)-beta, and indirectly through E2-sensitive neurons in the anteroventral periventricular (AVPV) region. The data described suggest that E2 generally represses GnRH gene expression but that this repression is transiently overcome by indirect E2-dependent signals relayed by AVPV neurons. We also present evidence that the AVPV neurons responsible for relaying E2 signals to GnRH neurons are multifunctional gamma aminobutyric acid-ergic/glutamatergic/neuropeptidergic neurons.
Turnip crinkle virus (TCV) is associated with satellite (sat) RNAs (sat‐RNA D, sat‐RNA F), defective interfering (DI) RNAs (DI RNA G, DI1 RNA), and one RNA with properties of both sat‐RNAs and DI RNAs (sat‐RNA C). When plants were inoculated with TCV, sat‐RNA D and in vitro sat‐RNA C transcripts containing non‐viable mutations in the 5′ domain, recombinant sat‐RNAs were recovered. These recombinants were composed of sat‐RNA D at the 5′ end and sat‐RNA C sequences at the 3′ end. Analysis of 20 independent recombination junctions revealed that unequal crossing‐over had occurred in planta in a region of sequence similarity between the two sat‐RNAs which resulted in the duplication of 3‐16 nucleotides. Thirty percent of the sat‐RNA recombinants also had one to three additional nucleotides inserted at the crossover junctions which did not correspond to either sat‐RNA C or sat‐RNA D sequence. The right side of the recombination junctions always began with one of three consecutive nucleotides of sat‐RNA C. Based on the similarity between this sequence of sat‐RNA C, the right side junction of DI RNA G and the 5′ end of TCV, as well as the sequence similarity between right side junctions of DI1 RNA and sat‐RNA C and the 5′ end of the sat‐RNAs, a replicase‐driven copy choice mechanism is proposed.(ABSTRACT TRUNCATED AT 250 WORDS)
Dioxin exposure alters a variety of neural functions, most likely through activation of the arylhydrocarbon receptor (AhR) pathway. Many of the adverse effects, including disruption of circadian changes in hormone release and depressed appetite, seem to be mediated by hypothalamic and/or brainstem neurons. However, it is unclear whether these effects are direct or indirect, because there have been no comprehensive studies mapping the expression of components of the AhR pathway in the brain. Therefore, we used a sensitive in situ hybridization histochemical (ISHH) method to map the neural expression of AhR mRNA, as well as those of the mRNAs encoding the AhR dimerization partners, arylhydrocarbon receptor nuclear translocator (ARNT) and ARNT2. We found that AhR, ARNT, and ARNT2 mRNAs were widely distributed throughout the brain and brainstem. There was no neuroanatomic evidence that AhR is preferentially colocalized with ARNT or ARNT2. However, ARNT2, unlike ARNT expression, was relatively high in most regions. The most noteworthy regions in which we found AhR, ARNT, and ARNT2 mRNA were several hypothalamic and brainstem regions involved in the regulation of appetite and circadian rhythms, functions that are disrupted by dioxin exposure. These regions included the arcuate nucleus (Arc), ventromedial hypothalamus (VMH), paraventricular nucleus (PVN), suprachiasmatic nucleus (SCN), nucleus of the solitary tract (NTS), and the dorsal and median raphe nuclei. This neuroanatomic information provides important clues as to the sites and mechanisms underlying the previously unexplained effects of dioxins in the central nervous system.
In vivo genetic selection was used to study the sequences and structures required for accumulation of subviral sat-RNA C associated with turnip crinkle virus (TCV). This technique is advantageous over site-specific mutagenesis by allowing side-by-side selection from numerous sequence possibilities as well as sequence evolution. A 22 base hairpin and 6 base single-stranded tail located at the 3'-terminus of sat-RNA C were previously identified as the promoter for minus strand synthesis. Approximately 50% of plants co-inoculated with TCV and sat-RNA C containing randomized sequence in place of the 22 base hairpin accumulated sat-RNA in uninoculated leaves. The 22 base region differed in sat-RNA accumulating in all infected plants, but nearly all were predicted to fold into a hairpin structure that maintained the 6 base tail as a single-stranded sequence. Two additional rounds of sat-RNA amplification led to four sequence family 'winners', with three families containing multiple variants, indicating that evolution of these sequences was occurring in plants. Three of the four sequence family winners had the same 3 bp at the base of the stem as wild-type sat-RNA C. Two of the winners shared 15 of 22 identical bases, including the entire stem region and extending two bases into the loop. These results demonstrate the utility of the in vivo selection approach by showing that both sequence and structure contribute to a more active 3'-end region for accumulation of sat-RNA C.
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