Mitochondrial DNA and RAPD polymorphisms in the haploid mite Brevipalpus phoenicis (Acari: Tenuipalpidae).

Brevipalpus phoenicis (Geijskes) (Acari: Tenuipalpidae) is recognized as the vector of citrus leprosis virus that is a significant problem in several South American countries. Citrus leprosis has been reported from Florida in the past but no longer occurs on citrus in North America. The disease was recently reported in Central America, suggesting that B. phoenicis constitutes a potential threat to the citrus industries of North America and the Caribbean. Besides B. phoenicis, B. obovatus Donnadieu, and B. californicus (Banks) have been incriminated as vectors of citrus leprosis virus and each species has hundreds of host plants. In this study, Brevipalpus mite specimens were collected from different plants, especially citrus, in the States of Florida (USA) and São Paulo (Brazil), and reared on citrus fruit under standard laboratory conditions. Mites were taken from these colonies for DNA extraction and for morphological species identification. One hundred and two Random Amplified Polymorphic DNA (RAPD) markers were scored along with amplification and sequencing of a mitochondrial cytochrome oxidase subunit I gene fragment (374 bp). Variability among the colonies was detected with consistent congruence between both molecular data sets. The mites from the Florida and Brazilian colonies were morphologically identified as belonging to B. phoenicis, and comprise a monophyletic group. These colonies could be further diagnosed and subdivided geographically by mitochondrial DNA analysis.

A general polyploid model for analyzing gene segregation in outcrossing tetraploid species.

Polyploidy has played an important role in higher plant evolution and applied plant breeding. Polyploids are commonly categorized as allopolyploids resulting from the increase of chromosome number through hybridization and subsequent chromosome doubling or autopolyploids due to chromosome doubling of the same genome. Allopolyploids undergo bivalent pairing at meiosis because only homologous chromosomes pair. For autopolyploids, however, all homologous chromosomes can pair at the same time so that multivalents and, therefore, double reductions are formed. In this article, we use a maximum-likelihood method to develop a general polyploid model for estimating gene segregation patterns from molecular markers in a full-sib family derived from an arbitrary polyploid combining meiotic behaviors of both bivalent and multivalent pairings. Two meiotic parameters, one describing the preference of homologous chromosome pairing (expressed as the preferential pairing factor) typical of allopolyploids and the other specifying the degree of double reduction of autopolyploids, are estimated. The type of molecular markers used can be fully informative vs. partially informative or dominant vs. codominant. Simulation studies show that our polyploid model is well suited to estimate the preferential pairing factor and the frequency of double reduction at meiosis, which should help to characterize gene segregation in the progeny of autopolyploids. The implications of this model for linkage mapping, population genetic studies, and polyploid classification are discussed.

Parental effects in the inheritance of nonnodulation in peanut.

A nonnodulating line (M4-2) and three normal nodulating lines (UF 487A, PI 262090, and Florunner) of peanut (Arachis hypogaea L.) were crossed in full diallel to investigate the inheritance of nodulation. Data from F1, F2, F3, F1BC1, and F2BC1 generations indicated that three genes control nodulation at three independent loci, with nodulation being a product of two genes and inhibited by a third gene when it is dominant and the others are homozygous recessive. A genetic model has been proposed that describes the nonnodulated genotypes as n1n1n2n2N3N3 or n1n1n2n2N3n3 and all other genotypes as normally nodulated except n1n1N2n2N3-, which has reduced nodulation when the n1n2N3 male gamete unites with the n1N2- female gamete or when the n1n2n3 male gamete unites with the n1N2N3 female gamete.

Linkage between loci controlling nodulation and testa variegation in peanut.

Linkage of loci controlling nodulation (N(1)) and testa variegation (V) was studied for cultivated peanut (Arachis hypogaea L.). The lines M4-2 (nonnodulating, variegated; VVn(1)n(1)n(2)n(2)N(3)N(3)) and UF 487A (nodulating, nonvariegated; vvN(1)N(1)n(2)n(2)N(3)N(3)) were used as parents in the crosses M4-2 x UF 487A, M4-2 x (UF 487A x M4-2), and their reciprocals. Individual plants were evaluated for nodulation and testa variegation in the F(1), F(2), F(3), F(1)BC(1), and F(2)BC(1) generations. Data indicate that the N(1) and V loci are linked with calculated crossover percentage of 7.1%.

Quantitative trait loci associated with resistance to Fusarium head blight and kernel discoloration in barley.

Resistance to Fusarium head blight (FHB), deoxynivalenol (DON) accumulation, and kernel discoloration (KD) in barley are difficult traits to introgress into elite varieties because current screening methods are laborious and disease levels are strongly influenced by environment. To improve breeding strategies directed toward enhancing these traits, we identified genomic regions containing quantitative trait loci (QTLs) associated with resistance to FHB, DON accumulation, and KD in a breeding population of F(4:7) lines using restriction fragment length polymorphic (RFLP) markers. We evaluated 101 F(4:7) lines, derived from a cross between the cultivar Chevron and an elite breeding line, M69, for each of the traits in three or four environments. We used 94 previously mapped RFLP markers to create a linkage map. Using composite interval mapping, we identified 10, 11, and 4 QTLs associated with resistance to FHB, DON accumulation, and KD, respectively. Markers flanking these QTLs should be useful for introgressing resistance to FHB, DON accumulation, and KD into elite barley cultivars.

Effects of tissue type and promoter strength on transient GUS expression in sugarcane following particle bombardment.

Effects of tissue type and promoter strength on transient GUS expression in the sugarcane (Saccharum spp. hybrids) cultivar NCo 310 were evaluated following microprojectile bombardment of leaf explants. GUS expression was histochemically or fluorometrically measured 48 h after delivery of the uidA gene. High levels of GUS expression were obtained in leaf segments isolated from young, expanding sugarcane leaves cultured for 1, 3, or 6 d prior to bombardment. The promoter derived from the maize ubiquitin 1 gene (Ubi-1) produced significantly more GUS foci and higher GUS activity levels compared to the recombinant Emu, rice actin 1 (Act1), and CaMV 35S promoters. Our transient expression system should facilitate efforts to identify promoters and elements which will regulate desired gene expression patterns in sugarcane and aid in development of an efficient stable transformation system.

Light regulatory sequences are located within the 5' portion of the Fed-1 message sequence.

We have previously shown that element(s) mediating a light-induced increase in the abundance of Fed-1 mRNA in the leaves of transgenic tobacco plants are located within the transcribed portion of the gene. As part of an effort to define the mechanism of this effect, we report here that cis-acting elements capable of mediating a 5-fold light-induced increase in the abundance of this mRNA are located within a region comprising the 5' leader and first third of the Fed-1 coding sequence. No activity was detected in the 3' untranslated region of the gene. In a gain-of-function assay, the 5' region was found to be capable of conferring light responsiveness on three different reporter sequences, although experiments with the gusA reporter were complicated by an apparent negative light effect on the stability of this mRNA. Deletion experiments show that at least one essential light regulatory element is located in the 5' untranslated region of Fed-1 between nucleotides +19 and +57. Additional Fed-1 sequences, including a portion of the protein coding region, are required to confer positive responsiveness on the gusA reporter. These additional sequences may include specific light regulatory elements or simply provide an environment in which the leader element can function normally.

Both internal and external regulatory elements control expression of the pea Fed-1 gene in transgenic tobacco seedlings.

In previous studies using leaves of light-grown transgenic tobacco plants, we have shown that sequences located within the transcribed region of the pea Fed-1 gene (encoding ferredoxin I) are major cis-acting determinants of light-regulated mRNA accumulation. However, we show here that these internal sequences are less important for the Fed-1 light response in etiolated tobacco seedlings than they are in green leaves and that upstream elements confer organ specificity and contribute significantly to Fed-1 light responses in etiolated material. Light effects mediated by upstream response elements are thus most pronounced during the initial induction of gene activity, whereas internal elements play a more prominent role in modulating Fed-1 expression once the gene is already active.

The pea ferredoxin I gene exhibits different light responses in pea and tobacco.

We monitored Fed-1 (encoding ferredoxin I) mRNA levels in etiolated transgenic tobacco seedlings containing the intact pea Fed-1 gene to determine if the characteristic light responses of this gene in pea seedlings are also observed in transgenic tobacco. Fed-1 transcript levels in transgenic tobacco seedlings closely paralleled those of the native gene in pea buds when etiolated seedlings were transferred to white light. However, the response to red light was much smaller in tobacco than in pea and was not efficiently reversed by far-red light. The red light response of endogenous tobacco ferredoxin transcripts is closely comparable to that of the Fed-1 transgene, with a similar lack of photoreversibility. Thus, the pea Fed-1 transgene responds normally to tobacco gene-regulatory factors, but these factors are less influenced by phytochrome in tobacco cotyledons than in pea buds.