Arrangement of the rRNA sequences in the rDNA of Lytechinus variegatus

The arrangement of the 26S RNA and 18S RNA sequences of the ribosomal DNA (rDNA) from the sea urchin Lytechinus variegatus was investigated by an electron microscopic analysis of R-loops formed between the ribosomal RNA genes and the mature ribosomal RNAs. Ninety-eight percent of observed molecules contained R-loops clearly seen as a three-stranded complex. The size of DNA complementary to mature cytoplasmic 18S and 26S ribosomal RNA (rRNA) was calculated by measuring the double-strand (ds) and single-strand (ss) part of the R-loops separately. The values for the 18S R-loop are 1.75±0.24 kb¹ (ss) and 1.56±0.23 kb (ds). The 26S R-loop is 3.34±0.39 kb (ss) and 3.33±0.33 kb (ds). These measurements agree fairly well with the rRNA sizes measured on denaturing sucrose density gradients: 3.23±0.22 kb for the 26S and 1.93±0.10 kb for 18S. The short spacer between the 18S and 26S R-loops is 1.03±0.24 kb and the longer spacer is 5.36±0.53 kb. In long molecules a repeating pattern was observed. The average length of an rDNA repeat unit is 11.33±0.64 kb when computed using double-strand R-loop measurements and 11.50±0.72 when computed using R-loop single-strand lengths.Abbreviations kb kilobases, 1000 bases of RNA or single-strand DNA, and kilobase pairs, 1000 base pairs of duplex DNA or DNA/RNA hybrid - EDTA ethylenediaminetetraacetate - SSC 0.15 M NaCl, 0.015 M sodium citrate - PIPES piperazine-N,N-bis (2-ethanesulfonic acid)-Na_1.4     

Isolation and some properties of a mammalian ribosomal DNA

The DNA coding for 28 S and 18 S ribosomal RNA, including the spacer regions, has been isolated from calf (Bos taurus) thymus gland. The method used included shearing of the total DNA to a highly homogeneous size population, selective heat denaturation and S 1 nuclease treatment to remove single stranded DNA. Repeated centrifugation on density gradients yields a 140-fold purified rDNA fraction with a GC content of 61.2%. Eco RI nuclease cleaves this DNA into two fragments of 16.4 and 4.9×10⁶ daltons. Hybridization of these fragments with 28 S and 18 S rRNA shows that the 28 S coding sequence is located mostly on the 4.9×10⁶ dalton fragment, while both the 16.4 and 4.9×10⁶ dalton fragments contain the 18 S sequence. The data indicate that the ribosomal RNA gene has a repeat unit of 21.3×10⁶ daltons which includes a nontranscribed spacer of about 12.5×10⁶ daltons.     

Genotype-phenotype associations in Sotos syndrome: an analysis of 266 individuals with NSD1 aberrations

We identified 266 individuals with intragenic NSD1 mutations or 5q35 microdeletions encompassing NSD1 (referred to as "NSD1-positive individuals"), through analyses of 530 subjects with diverse phenotypes. Truncating NSD1 mutations occurred throughout the gene, but pathogenic missense mutations occurred only in functional domains (P < 2 x 10(-16)). Sotos syndrome was clinically diagnosed in 99% of NSD1-positive individuals, independent of the molecular analyses, indicating that NSD1 aberrations are essentially specific to this condition. Furthermore, our data suggest that 93% of patients who have been clinically diagnosed with Sotos syndrome have identifiable NSD1 abnormalities, of which 83% are intragenic mutations and 10% are 5q35 microdeletions. We reviewed the clinical phenotypes of 239 NSD1-positive individuals. Facial dysmorphism, learning disability, and childhood overgrowth were present in 90% of the individuals. However, both the height and head circumference of 10% of the individuals were within the normal range, indicating that overgrowth is not obligatory for the diagnosis of Sotos syndrome. A broad spectrum of associated clinical features was also present, the occurrence of which was largely independent of genotype, since individuals with identical mutations had different phenotypes. We compared the phenotypes of patients with intragenic NSD1 mutations with those of patients with 5q35 microdeletions. Patients with microdeletions had less-prominent overgrowth (P = .0003) and more-severe learning disability (P = 3 x 10(-9)) than patients with mutations. However, all features present in patients with microdeletions were also observed in patients with mutations, and there was no correlation between deletion size and the clinical phenotype, suggesting that the deletion of additional genes in patients with 5q35 microdeletions has little specific effect on phenotype. We identified only 13 familial cases. The reasons for the low vertical transmission rate are unclear, although familial cases were more likely than nonfamilial cases (P = .005) to carry missense mutations, suggesting that the underlying NSD1 mutational mechanism in Sotos syndrome may influence reproductive fitness.     

Membrane topology mapping of vitamin K epoxide reductase by in vitro translation/cotranslocation

Vitamin K epoxide reductase (VKOR) catalyzes the conversion of vitamin K 2,3-epoxide into vitamin K in the vitamin K redox cycle. Recently, the gene encoding the catalytic subunit of VKOR was identified as a 163-amino acid integral membrane protein. In this study we report the experimentally derived membrane topology of VKOR. Our results show that four hydrophobic regions predicted as the potential transmembrane domains in VKOR can individually insert across the endoplasmic reticulum membrane in vitro. However, in the intact enzyme there are only three transmembrane domains, residues 10-29, 101-123, and 127-149, and membrane-integration of residues 75-97 appears to be suppressed by the surrounding sequence. Results of N-linked glycosylation-tagged full-length VKOR shows that the N terminus of VKOR is located in the endoplasmic reticulum lumen, and the C terminus is located in the cytoplasm. Further evidence for this topological model of VKOR was obtained with freshly prepared intact microsomes from insect cells expressing HPC4-tagged full-length VKOR. In these experiments an HPC4 tag at the N terminus was protected from proteinase K digestion, whereas an HPC4 tag at the C terminus was susceptible. Altogether, our results suggest that VKOR is a type III membrane protein with three transmembrane domains, which agrees well with the prediction by the topology prediction program TMHMM.     

1. BIRD-LIFE AT THE ORANGE RIVER MOUTH

Kalejta, B. 1993. Diets of shorebirds at the Berg River estuary, South Africa: spatial and temporal variation. Ostrich 64: 123–133.

The diets of three common migrant waders; Curlew Sandpiper Calidris ferruginea. Grey Plover Pluvialis-squatarola and Greenshank Tringa nebularia and three resident species, Blacksmith Vanellus armatus, Kittlitz's Charadrius pecuarius and Whitefronted Plovers C. marginatus, were studied at the Berg River estuary, South Africa from December 1987 to April 1989. Direct observations of feeding were combined with analyses of stomach contents, pellets and droppings. Nereid worms, Ceratonereis erythraeensis and C. keiskama, were the principal food of all species studied except Greenshanks, which fed mostly on crabs, Hymenosoma orbiculare. Despite considerable overlap in the diets of all bird species, there were differences in the size classes of nereids taken by different bird species. Visually-foraging plovers (Charadriidae) were highly selective, feeding on the largest nereids regardless of their abundance. Tactile foragers, represented by Curlew Sandpipers, were non-selective, and consumed different size-classes of worms in proportion to their abundance in the substratum. Seasonal variations in the diet of waders are linked to seasonal changes in the availability of prey species.     

A hetero-dimer model for concerted action of vitamin K carboxylase and vitamin K reductase in vitamin K cycle

Vitamin K carboxylase (VKC) is believed to convert vitamin K, in the vitamin K cycle, to an alkoxide-epoxide form which then reacts with CO₂ and glutamate to generate γ-carboxyglutamic acid (Gla). Subsequently, vitamin K epoxide reductase (VKOR) is thought to convert the alkoxide-epoxide to a hydroquinone form. By recycling vitamin K, the two integral-membrane proteins, VKC and VKOR, maintain vitamin K levels and sustain the blood coagulation cascade. Unfortunately, NMR or X-ray crystal structures of the two proteins have not been characterized. Thus, our understanding of the vitamin K cycle is only partial at the molecular level. In this study, based on prior biochemical experiments on VKC and VKOR, we propose a hetero-dimeric form of VKC and VKOR that may explain the efficient oxidation and reduction of vitamin K during the vitamin K cycle.