Cooperative regulation of AJM-1 controls junctional integrity in Caenorhabditis elegans epithelia.

The function of epithelial cell sheets depends on the integrity of specialized cell-cell junctions that connect neighbouring cells. We have characterized the novel coiled-coil protein AJM-1, which localizes to an apical junctional domain of Caenorhabditis elegans epithelia basal to the HMR-HMP (cadherin-catenin) complex. In the absence of AJM-1, the integrity of this domain is compromised. Proper AJM-1 localization requires LET-413 and DLG-1, homologues of the Drosophila tumour suppressors Scribble and Discs large, respectively. DLG-1 physically interacts with AJM-1 and is required for its normal apical distribution, and LET-413 mediates the rapid accumulation of both DLG-1 and AJM-1 in the apical domain. In the absence of both dlg-1 and let-413 function AJM-1 is almost completely lost from apical junctions in embryos, whereas HMP-1 (alpha-catenin) localization is only mildly affected. We conclude that LET-413 and DLG-1 cooperatively control AJM-1 localization and that AJM-1 controls the integrity of a distinct apical junctional domain in C. elegans.

Cloning and characterization of cDNAs encoding putative glutamate transporters from Caenorhabditis elegans and Onchocerca volvulus.

We report the identification and partial characterization of cDNAs encoding for putative glutamate transporters from the free-living nematode Caenorhabditis elegans and the filarial parasite Onchocerca volvulus. Glutamate transporters can be used as reliable markers for identifying cells and neurons that synaptically release glutamate and aspartate. An amplified PCR fragment containing a highly conserved amino acid heptamer found in all vertebrate glutamate transporters was used to screen a C. elegans cDNA library. Two full-length cDNA sequences from C. elegans were deduced from the isolated cDNA clones and RT-PCR products with the splice leader. The two C. elegans cDNA sequences differ by only 97 nucleotides at the 5' end. The C. elegans glutamate transporter gene glt-1 spans at least 2.9 kb of chromosomal DNA and possesses nine exons and eight introns. Primers directed to the CeGlt cDNA were used with O. volvulus first-strand cDNA to amplify and isolate the O. volvulus cDNA homolog. The C. elegans and O. volvulus glutamate transporters are 98% identical over 492 amino acids to each other and 52 to 58% identical to the mammalian glutamate transporters. Antibodies generated against partial coding regions of the C. elegans glutamate transporter recognized a protein of approximately 66 kDa in C. elegans and O. volvulus protein extracts.

Widespread occurrence of the Tc1 transposon family: Tc1-like transposons from teleost fish.

We characterized five transposable elements from fish: one from zebrafish (Brachydanio rerio), one from rainbow trout (Salmo gairdneri), and three from Atlantic salmon (Salmo salar). All are closely similar in structure to the Tc1 transposon of the nematode Caenorhabditis elegans. A comparison of 17 Tc1-like transposons from species representing three phyla (nematodes, arthropods, and chordates) showed that these elements make up a highly conserved transposon family. Most are close to 1.7 kb in length, have inverted terminal repeats, have conserved terminal nucleotides, and each contains a single gene encoding similar polypeptides. The phylogenetic relationships of the transposons were reconstructed from the amino acid sequences of the conceptual proteins and from DNA sequences. The elements are highly diverged and have evidently inhibited the genomes of these diverse species for a long time. To account for the data, it is not necessary to invoke recent horizontal transmission.

Extrachromosomal circular copies of the transposon Tc1.

The 1.6 kb Tc1 transposable element of Caenorhabditis elegans undergoes excision and transposition in the germline. In somatic tissue it is excised at high frequency. Extrachromosomal linear and circular copies of Tc1 have been identified that are likely to be products of somatic and germline excision. In the present study, we have determined the sequences of the sites of circularization in circular extrachromosomal Tc1 molecules. DNA molecules containing these sites were cloned after PCR amplification with primers directed outward from within Tc1. Sequences were obtained with two complete Tc1 ends and one or more intervening copies of the TA dinucleotide, with one complete end and one deleted end, and with two deleted ends. The 24 clones had different structures, indicating the pool of molecules serving as PCR templates was heterogeneous. The predominant circular junction had one or more nucleotides deleted from at least one transposon end. Such a molecule without two complete ends might not be expected to serve as a transposition intermediate. Hence, some extrachromosomal circular Tc1 molecules may result from a deadend excision pathway.

Maturation of aldose reductase expression in the neonatal rat inner medulla.

Newborns are less able to concentrate urine than adults are. With development of the concentrating system and a hypertonic medullary interstitium, there is a need to generate intracellular osmolytes such as sorbitol, which is produced in a reaction catalyzed by the enzyme aldose reductase. We sought to discriminate between two possible mechanisms of aldose reductase induction during development: (a) a response to an osmotic stimulus generated by the concentrating mechanism; or (b) part of the genetic program for development of the kidney. We measured the change in aldose reductase mRNA and activity in terminal inner medullary collecting ducts (IMCDs) microdissected from Sprague-Dawley rats during the first month of life. Aldose reductase mRNA was assayed by Northern analysis of total RNA from inner medulla and by detection of the reverse transcription-polymerase chain reaction (RT-PCR) product obtained from single IMCDs using aldose reductase-specific primers. Aldose reductase activity was measured in IMCDs taken from the same rats using a fluorescent microassay. Newborn rat IMCDs had minimal aldose reductase mRNA or activity, however mRNA was readily detected in IMCDs from rats older than 3 d of age, with peak expression occurring at 1-3 wk of age before decreasing to adult levels. In contrast, the mRNA level for a housekeeping metabolic enzyme, malate dehydrogenase, did not change during maturation. Aldose reductase enzyme activity was readily detectable by 6 d of age, peaked at 20 d, then decreased to adult levels. Urine osmolality remained < 600 mosmol/kg until 16 d, then increased to > 1,100 mosmol/kg after 20 d. Thus, aldose reductase mRNA and activity increased before urinary osmolality reached 870 mosmol/kg. Because urine osmolality may not be indicative of inner medullary osmolality and because mother's milk may provide excessive free water to the pups under 3 wk of age, half of the animals in several litters were separated from their mothers for 1 d and inner medullary osmolality, in addition to urine osmolality, was measured by vapor pressure osmometry, while aldose reductase mRNA was assessed densitometrically in IMCDs after RT-PCR. Although fluid restriction resulted in a near doubling of urine osmolality and a tendency towards increased aldose reductase mRNA, there was no consistently significant increase in aldose reductase mRNA or inner medullary osmolality during the first 13 d of life compared to the suckling animals. On the other hand, 2-3-wk-old rats showed significant increases in aldose reductase mRNA, accompanied by increases in inner medullary osmolality, after fluid restriction. Thus, the dissociation between the increases in aldose reductase expression and inner medullary hyperosmolality indicates that the maturational induction of the aldose reductase gene is not a consequence of osmotic stimulation, but rather, part of the developmental program of the kidney.

Detection of Intraspecific Diversity of Heterodera glycines Using Isozyme Phenotypes.

Twelve populations of Heterodera glycines from the United States (8), China (2), Japan (1), and Colombia (1) were surveyed for phenotypic intraspecific variability in 42 enzyme systems. Activity of 20 enzymes was detected following isoelectric focusing in polyacrylamide gels of extracts from mass homogenates and single females. Five enzymes, aspartate aminotransferase, phosphoglucose isomerase, alpha- and beta-esterases, and hexokinase were the most useful for detecting intraspecific variability. Phenotypic variability between single females was best demonstrated with alpha- and beta-esterases and acid phosphatase enzyme systems. These results suggest that isoelectric focusing in conjunction with sensitive enzyme systems can be used to detect phenotypic variation between individual nematodes from the same population. The unusual phenotypic variability detected in the H. glycines population from Virginia indicates that the genetic diversity of this population is complex.

Comparisons of Mitochondrial DNA from the Sibling Species Heterodera glycines and H. schachtii.

Restriction fragment patterns of mitochondrial DNA from sibling species of cyst nematodes Heterodera glycines and H. schachtii were examined. Fourteen restriction endonucleases recognizing four, five, and six base-pair sequences yielded a total of 90 scorable fragments of which 10% were shared by both species. Mitochondrial genome sizes for H. glycines and H. schachtii were estimated to be 22.5-23.5 kb and 23.0 kb, respectively. A single wild type mitochondrial genome was identified in all populations of H. glycines examined, although other mitochondrial genomes were present in some populations. The H. schachtii genome exhibited 57 scorable fragments, compared with 33 identified in the H. glycines wild type genome. The estimated nucleotide sequence divergence between the two species was p = 0.145. This estimate suggests these species diverged from a common ancestor 7.3-14.8 million years ago.

Studies on the Host Range, Biology, and Pathogenicity of Punctodera punctata Infecting Turfgrasses.

Punctodera punctata completed its life cycle on Poa annua (annual bluegrass), P. pratensis (Merion Kentucky bluegrass), Lolium perenne (perennial ryegrass), and Festuca rubra rubra (spreading fescue). Minimum time for completion of a life cycle from second-stage juvenile to mature brown cyst was 40 days at 22-28 C. Inoculation by single juveniles indicated that reproduction was most likely by amphimixis. Infestation levels of 50 or 500 juveniles/250 cm(3) soil did not affect top dry weight, root dry weight, or total dry weight of Poa annua.