Regular consumption of Nile river fish could ameliorate the low milk DHA of Southern Sudanese women living in Khartoum City area.

We have reported that milk of Northern Sudanese women contained very low level of docosahexaenoic acid (DHA). This was puzzling since the mothers were not malnourished and some had claimed to eat fish from time to time. War-displaced Southern Sudanese live in Khartoum City and its vicinity. They are distinct in genetic background and traditional dietary culture from the Northerners. Milk DHA is influenced by diet and ethnicity. Fatty acid content of Southern Sudanese milk, and six of the popular River Nile fish species were evaluated. Mature milk compared with transition milk had lower arachidonic (AA, 0.6±0.19 vs. 0.75±0.3; p<0.001), adrenic (0.14±0.1 vs. 0.33±0.23), osbond (0.07±0.05 vs. 0.14±0.08; p<0.0001), eicosapentaenoic (0.04±0.02 vs.0.08±0.07; p<0.01) and DHA (0.10±0.07 vs. 0.16±0.1; p=0.003) acids. The milk of the Southerners like their counterparts from the North had low DHA and total n-3 and high AA and total n-6 levels. Regular consumption of the local fish could provide adequate DHA to help enrich their milk.

Functional conservation of a glucose-repressible amylase gene promoter from Drosophila virilis in Drosophila melanogaster.

Previous studies have demonstrated that the expression of the alpha-amylase gene is repressed by dietary glucose in Drosophila melanogaster. Here, we show that the alpha-amylase gene of a distantly related species, D. virilis, is also subject to glucose repression. Moreover, the cloned amylase gene of D. virilis is shown to be glucose repressible when it is transiently expressed in D. melanogaster larvae. This cross-species, functional conservation is mediated by a 330-bp promoter region of the D. virilis amylase gene. These results indicate that the promoter elements required for glucose repression are conserved between distantly related Drosophila species. A sequence comparison between the amylase genes of D. virilis and D. melanogaster shows that the promoter sequences diverge to a much greater degree than the coding sequences. The amylase promoters of the two species do, however, share small clusters of sequence similarity, suggesting that these conserved cis-acting elements are sufficient to control the glucose-regulated expression of the amylase gene in the genus Drosophila.

Concerted evolution of duplicated protein-coding genes in Drosophila.

Very rapid rates of gene conversion were observed between duplicated alpha-amylase-coding sequences in Drosophila melanogaster. This gene conversion process was also seen in the related species Drosophila erecta. Specifically, there is virtual sequence identity between the coding regions of the two genes within each species, while the sequence divergence between species is close to that expected based on their phylogenetic relationship. The flanking, noncoding regions are much more highly diverged and do not appear to be subject to gene conversion. Comparison of amylase sequences between the two species provides a clear demonstration that recurrent gene conversion does indeed lead to the concerted evolution of the gene pair.

A general model for the evolution of nuclear pre-mRNA introns.

We present an overview of the evolution of eukaryotic split gene structure and pre-mRNA splicing mechanisms. We have drawn together several seemingly conflicting ideas and we show that they can all be incorporated in a single unified theory of intron evolution. The resulting model is consistent with the notion that introns, as a class, are very ancient, having originated in the "RNA world"; it also supports the concept that introns may have played a crucial role in the construction of many eukaryotic genes and it accommodates the idea that introns are related to mobile insertion elements. Our conclusion is that introns could have a profound effect on the course of eukaryotic gene evolution, but that the origin and maintenance of intron sequences depends, largely, on natural selection acting on the intron sequences themselves.

DNA rearrangement causes multiple changes in gene expression at the amylase locus in Drosophila melanogaster.

A spontaneous null mutation at the alpha-amylase locus in Drosophila melanogaster was recovered from a laboratory population. The mutant strain was found to lack amylase enzyme production and to produce low, but detectable, levels of amylase mRNA. Moreover, the null strain is also lacking the glucose repression of amylase mRNA production which is seen in wild-type strains. The mutant phenotype correlates with a rearrangement in genomic DNA which, in turn, corresponds to a simple inversion in the arrangement observed most frequently in North American populations of D. melanogaster, including the common laboratory strain, Oregon-R. These results have implications for our understanding of both the evolution of the duplicated amylase gene structure and the regulation of amylase gene expression.

Evolutionary conservation of the chromosomal configuration and regulation of amylase genes among eight species of the Drosophila melanogaster species subgroup.

Nuclear DNA was extracted from each of the eight species comprising the Drosophila melanogaster species subgroup. Southern hybridization of this DNA by using a molecular probe specific for the alpha-amylase coding region showed that the duplicated structure of the amylase locus, first found in D. melanogaster, is conserved among all species of the melanogaster subgroup. Evidence is also presented for the concerted evolution of the duplicated genes within each species. In addition, it is shown that the glucose repression of amylase gene expression, which has been extensively studied in D. melanogaster, is not confined to this species but occurs in all eight members of the species subgroup. Thus, both the duplicated gene structure and the glucose repression of Drosophila amylase gene activity are stable over extended periods of evolutionary time.

Molecular cloning of DNA complementary to Drosophila melanogaster alpha-amylase mRNA.

Several lambda clones containing cDNAs from Drosophila melanogaster were identified in a lambda cDNA bank using two different approaches: (i) cross-species hybridization using a mouse amylase cDNA probe, and (ii) probing with a differential probe, generated from Drosophila RNA. An amylase cDNA fragment was used, in turn, for the isolation and characterization of amylase genomic clones. The size of the Drosophila amylase mRNA was estimated at 1650 b. This is comparable with the size of the murine amylase messenger that encodes a protein of similar molecular weight. In Drosophila larvae, amylase mRNA can account for as little as 0.01% of the poly(A)+ RNA under conditions of dietary glucose repression or greater than 1% of poly(A)+ RNA under derepressing dietary conditions.

Enzyme-coding genes as molecular clocks: the molecular evolution of animal alpha-amylases.

We constructed a cDNA library for the beetle, Tribolium castaneum. This library was screened using a cloned amylase gene from Drosophila melanogaster as a molecular probe. Beetle amylase cDNA clones were isolated from this bank, and the nucleotide sequence was obtained for a cDNA clone with a coding capacity for 228 amino acids. Both the nucleotide sequence and predicted amino acid sequence were compared to our recent results for D. melanogaster alpha-amylases, along with published sequences for other alpha-amylases. The results show that animal alpha-amylases are highly conserved over their entire length. A broader comparison, which includes plant and microbial alpha-amylase sequences, indicates that parts of the gene are conserved between prokaryotes, plants, and animals. We discuss the potential importance of this and other enzyme-coding genes for the construction of molecular phylogenies and for the study of the general question of molecular clocks in evolution.