Laura A. Herbon

Physical and gene mapping studies reveal that chloroplast DNA from geranium (Pelargonium hortorum) has sustained a number of extensive duplications and inversions, resulting in a genome arrangement radically unlike that of other plants. At 217 kilobases in size, the circular chromosome is about 50% larger than the typical land plant chloroplast genome and is by far the largest described to date, to our knowledge. Most of this extra size can be accounted for by a 76-kilobase inverted duplication, three times larger than the normal chloroplast DNA inverted repeat. This tripling has occurred primarily by spreading of the inverted repeat into regions that are single copy in all other chloroplast genomes. Consequently, 10 protein genes that are present only once in all other land plants are duplicated in geranium. At least six inversions, occurring in both the inverted repeat and large single-copy region, must be postulated to account for all of the gene order differences that distinguish the geranium genome from other chloroplast genomes. We report the existence in geranium of two families of short dispersed repeats and hypothesize that recombination between repeats may be the major cause of inversions in geranium chloroplast DNA.

Gonadotropin-releasing hormone (GnRH) induces both synthesis and release of pituitary gonadotropins, but rapid or slow frequencies of stimulation result in reduced LH and FSH secretion. We determined the effects of frequency of GnRH stimulation on pituitary GnRH receptors (GnRH-R). Castrate male rats received testosterone implants (cast + T) to inhibit endogenous GnRH secretion. GnRH pulses were injected by a pump into a carotid cannula and animals received GnRH (25 ng/pulse) at various frequencies for 48 h. In control animals (saline pulses) GnRH-R was 307 +/- 21 fmol/mg protein (+/- SE) in cast + T and 598 +/- 28 in castrates. Maximum GnRH-R was produced by 30-min pulses and was similar to that seen in castrate controls. Faster or slower frequencies resulted in a smaller GnRH-R response and GnRH given every 240 min did not increase GnRH-R over saline controls. Equalization of the total GnRH dose/48 h (6.6 ng/pulse every 7.5 min or 200 ng/pulse every 240 min) did not increase receptors to the maximum concentrations seen after 30-min (25 ng) pulses. Serum LH responses after 48 h of injections were only present after 30-min pulses, and peak FSH values were also seen after this frequency. Serum LH was undetectable in most rats after other GnRH frequencies, even though GnRH-R was increased. These data show that GnRH pulse frequency is an important factor in the regulation of GnRH-R. A reduction of GnRH-R is part of the mechanism of down-regulation of LH secretion by fast or slow GnRH frequencies, but altered frequency also exerts effects on secretory mechanisms at a site distal to the GnRH receptor.

In this study we examined the changes in alpha and LH beta mRNAs in anterior pituitaries of male and female rats after castration. mRNA concentrations were measured by an optimized RNA dot blot hybridization assay. Rat alpha and LH beta cDNAs were nick-translated to specific activities of 2-5 X 10(8) cpm/micrograms and were used as hybridization probes. The total RNA per assay, RNA per dot, and saturating amounts of probe were optimized. The intra- and interassay coefficients of variation were 5% and 28%, respectively. Both alpha and LH beta mRNA concentrations increased after castration, but marked differences were observed in the kinetics of responses in male and female rats. In males, alpha and LH beta mRNAs were increased by 24 h postcastration (by 25% and 38%, respectively), and 4- to 5-fold increases over intact controls were evident by 18 days. Alpha mRNA rose rapidly and had doubled by 2 days, whereas LH beta mRNA concentrations showed a similar increase by 6-7 days postcastration. The slower rise in LH beta mRNA was associated with a transient decline in serum and pituitary LH concentrations between 2 and 6 days after castration. In female rats, alpha mRNA increased more slowly. Alpha concentrations had doubled by 10 days, while a similar increase in LH beta mRNA occurred 7 days after castration. Thereafter, both subunit mRNAs continued to rise, and by day 20 alpha mRNA was increased 5-fold and LH beta mRNA 16-fold over values in intact females. Serum and pituitary LH concentrations rose gradually, and both were increased by 7-10 days after castration. The increase in serum and pituitary LH followed a time course similar to that of the progressive rise in LH beta mRNA concentrations. These data show that an increase in steady state LH subunit mRNA concentrations is one of the mechanisms involved in increased gonadotropin biosynthesis and secretion after castration. The kinetics of LH subunit mRNA and LH secretory responses are different in male and female rats and suggest that the concentration of LH beta mRNA may be a limiting factor in LH secretion.

We constructed complete physical maps of the tripartite mitochondrial genomes of two Crucifers, Brassica nigra (black mustard) and Raphanus sativa (radish). Both genomes contain two copies of a direct repeat engaged in intragenomic recombination. The outcome of this recombination in black mustard is to interconvert a 231 kb master chromosome with two subgenomic circles of 135 kb and 96 kb. In radish, a 242 kb master chromosome interconverts with subgenomic circles of 139 kb and 103 kb. The recombination repeats are 7 kb in size in black mustard and 10 kb in radish, and are nearly identical except for two insertions in the radish repeat relative to the black mustard one. The two repeat configurations present on the master chromosome of black mustard are located on the subgenomes of radish and vice-versa. To explain this, we postulate the existence of an evolutionarily intermediate mitochondrial genome in which the recombination repeats were (are) present in an inverted orientation. The recombination repeats described for these two species are completely different from those previously found in the closely related species B. campestris, implying that such repeats are created and lost frequently in plant mitochondrial DNAs and making it less than likely that recombination occurs in a site-specific manner.