Jamie R Konwerski et al. (2005) International Worm Meeting "A comparative approach to understanding P granule function in Caenorhabditis"

Jennifer A Schisa, Megan Senchuk, Jamie R Konwerski, David LaHaie, Emily Petty

[International Worm Meeting, 2005]

Proper germline formation is important for propagation of species. P granules, an organelle found only in the germline, may be important for germ cell identity and function in Caenorhabditis . Though the biochemical function of P granules is unknown, several lines of evidence suggest they may function in the regulation of germline mRNA. All proteins known to associate with P granules contain putative RNA-binding domains and several mRNAs are known which preferentially associate with P granules. In addition, P granules in immature germ cells of the adult are associated with nuclear pores; therefore, many of the newly transcribed RNAs in germ cells contact P granules as they are exported out of the nucleus. Thus, we and others hypothesize that P granules function to regulate the translation of maternal mRNAs. We are taking a comparative approach to better understand P granule function by determining whether selected P granule characteristics are conserved in C. briggsae and C. remanei. Preliminary data using TEM suggest that P granules are associated with clusters of nuclear pores in the immature germ cells of C. remanei. Thus it appears P granules in C. remanei interact with many of the newly transcribed RNAs as in C. elegans. Since this association appears to be conserved, it may be important to P granule function. We have also focused on understanding the significance of the association of RNA with P granules. In C. elegans, pos-1 RNA associates with P granules and is translationally regulated. In order to identify sequences that are important for pos-1 RNA to associate with P granules and/or be appropriately translationally regulated, we have cloned orthologs of pos-1 from C. briggsae and C. remanei. We have identified one novel amino acid domain that is highly conserved among the three species. We have also identified two regions in the 3 UTR that are highly conserved. In addition, we have shown that pos-1 RNA is expressed in the germline of C. briggsae and C. remanei and that regulation of pos-1 RNA translation is conserved. POS-1 is not expressed at high levels in C. briggsae until the 2-cell stage of embryogenesis. We conclude that pos-1 appears to be translationally regulated in C. briggsae as it is in C. elegans and speculate the conserved 3 UTR sequences may be involved. We plan to disrupt the conserved 3UTR sequences of pos-1 in C. elegans and determine any effects on the association of the RNA to P granules or proper translational regulation of the RNA.

Schein JE et al. (1997) International C. elegans Meeting "POSITIONING OF ESSENTIAL GENES IN THE lin-3 - let-60 INTERVAL"

Franz NW, Rose AM, Janke DL, Bilkhu N, Baillie DL, Schein JE

[International C. elegans Meeting, 1997]

The lin-3 - let-60 interval of the right arm of chromosome IV contains thirteen essential gene mutations and 22 overlapping sequenced cosmids. The Sanger Center has nearly finished sequencing the entire interval. Analysis of cosmid sequences shows over one hundred potential coding regions. Of the coding regions with proposed protein function, more than 50% have strong homology to human genes. Most notably, the putative genes include three phosphatases, four protein kinases, a kinesin, and a cluster of histones. C. elegans strains carrying sequenced cosmids (in extrachromosomal arrays) have been constructed (see abstract for D. Janke et al., this meeting) and will be used in rescue experiments involving the essential genes in this interval. lin-3 and let-60(ras), the two genes bracketing this interval, were previously placed on the physical map by others. One of the remaining eleven essential genes has been already positioned to a cosmid: let-70(ubc2) (in collaboration with Mei Zhen and Peter Candido). By the time of the meeting, we anticipate that several of the remaining mutations will have been positioned to cosmids. This work is being funded by a grant from the Medical Research Council to Ann Rose and David Baillie and by a grant from the Natural Sciences & Engineering Research Council to David Baillie.

Stewart HI et al. (1996) West Coast Worm Meeting "Rescue of New Essential Genes on LGIII(left), in the Nematode Caenorhabditis elegans."

Stewart HI, Franz NW, Barbazuk BW, Baillie DL, Ha TT

[West Coast Worm Meeting, 1996]

We utilized trangenic strains containing cosmids, sequenced by the sequencing consortium, to rescue the lethal phenotype of several essential genes (See presentation by Diana Janke et al, this session). The rescued genes are positioned on LGIII(left) balanced by the duplication sDp3(see poster; Stewart et al, this session). A set of overlapping deficiencies was utilized to define areas within which to focus our rescue attempts). PCR analysis was utilized to further define the end points of these deficiencies, facilitating our analysis ( see poster ; Norm Franz et al, this session). We concentrated our analysis on areas to the right of dpy-17, in the interval between dpy-17 to dpy-19. Lethals mapping to sDf125 that were not rescued by sDp8 are presented in a poster by Nigel O'Niel et al, this session. We have rescued several essential genes. Our rescues will facilitate the functional analysis of these new genes. These rescues have also helped us to align and correlate the physical and genetic maps. Our estimates are that there will be more than two essential genes per cosmid. A total of 202 recessive lethal mutations have been generated, using EMS as a mutagen. We intend to make molecular assignments of all of these elements, through our cosmid rescue experiments. As we have estimated that there is only a 28% saturation of the area for essential genes, we will be generating more recessive lethal genes, to facilitate this analysis. This work has been funded by grants from the National Institute of Health (N.I.H.), U. S.A. to Ann Rose; D. Riddle and David Baillie and Canadian Genome and Advanced Technologies (C.G.A.T.), Canada to Ann Rose and David Baillie.

O'Neil NJ et al. (1996) West Coast Worm Meeting "SYSTEMATIC HIGH RESOLUTION MAPPING OF ESSENTIAL GENES IN THE sDf125 REGION BY TRANSGENIC RESCUE."

Kuervers LM, Baillie DL, Vatcher GP, O'Neil NJ

[West Coast Worm Meeting, 1996]

We have demonstrated that transgenic rescue is an effective method for high resolution mapping of essential genes. Our lab is constructing a map of essential genes on LGIII left. We have divided the left end of the central cluster into manageable regions which are defined by overlapping deficiencies and duplications. These regions are determined physically by PCR testing the deficiencies to determine endpoints (see N.Franz et al. abstract, this meeting). Into these regions, we have mapped a set of EMS induced lethals and maternal effect lethals. (see abstracts by H. Stewart et al. and G. Vatcher and D. Baillie, this meeting). One such region is defined by sDf125 and sDp8. This region spans 340 000 base pairs and is completely covered by nine cosmids. Within this region there are 75 putative genes predicted by Genefinder. We have used a sytematic approach to rescue essential genes within the sDf125 region with transgenic cosmids from the library created by J. Schein, D. Janke and The Ha as part of a CGAT grant to Ann Rose and David Baillie (see abstracts by J.Schein et al. and D. Janke et al., this meeting) To date this method has proven very successful. At least 8 genes have been completely rescued in this region by this approach. These transgenic rescues map these genes to 40 kB (one cosmid) resolution as opposed to the 340 kB resolution of the deficiency and duplication data. This is almost a ten-fold increase in resolution and reduces the number of ORFs which may be responsible for the gene function. The next step will be the subcloning of cosmids with which we have rescued essential genes. This will directly corellate the lethal or maternal effect lethal phenotype to the appropriate ORF. We have already begun the subcloning of cosmid C05D11 (see G.Vatcher and D.Baillie abstract, this meeting). This project is funded by a CGAT grant to Ann Rose and David Baillie.

O'Neil NJ et al. (1997) International C. elegans Meeting "ANALYSIS OF THE sDf127 REGION BY TRANSGENIC RESCUE."

O'Neil NJ, Vatcher GP, Kuervers LM, Baillie DL

[International C. elegans Meeting, 1997]

We have demonstrated that transgenic rescue is an effective method for high resolution mapping of essential genes. Our lab is constructing a map of essential genes on LGIII left. We have divided the region between dpy-17 and unc-36 into manageable regions that are defined by overlapping deficiencies and duplications. These regions are determined physically by PCR testing the deficiencies to determine endpoints. Into these regions, we have mapped a set of EMS induced lethal and maternal effect lethal mutations (See abstract H.Stewart et al., this meeting). One such region is defined by sDf127 and sDp8. This region spans 340 000 base pairs and is completely covered by ten cosmids. Within this region there are 75 putative genes predicted by Genefinder. To date, we have mapped 14 essential genes into this region. We have used a sytematic approach to rescue these essential genes with cosmid transgenics from the library created as part of a CGAT grant to Ann Rose and David Baillie (See abstract by D. Janke et al., this meeting) To date this method has proven very successful. At least 8 genes have been completely rescued in this region utilizing this approach. These transgenic rescues map these genes to 40 kB (one cosmid) as opposed to the 340 kB resolution of the deficiency and duplication data. This is almost a ten-fold increase in resolution and reduces the number of coding sequences which may be responsible for the gene function. The next step will be to subclone the cosmids with which we have rescued essential gene mutations. This will directly corellate the lethal or maternal effect lethal phenotype to the appropriate coding sequence. We have already begun the subcloning of the cosmids C05D11 (see abstract by G.Vatcher et al., this meeting), C31H11 and C16A3. This project is funded by a grant from the Medical Research Council of Canada to Ann Rose and David Baillie.

David R. Bell et al. (2006) European Worm Meeting "The Function of Latrophilin in C. elegans"

S. van der Poel, P.N.R. Usherwood, D. Kendall, J. Davy, A. Ademola, I.R. Duce, D. de Pomerai, David R. Bell, I. R. Mellor

[European Worm Meeting, 2006]

David R. Bell, A. Ademola, J. Davy, S. van der Poel, D. Kendall, P.N.R. Usherwood, I.R. Duce, I. R. Mellor and D. de Pomerai. Black Widow spider venom (BWSV) contains latrotoxins that induce catastrophic neurotransmitter release in mammals, and is known to bind with high affinity to three neural proteins in mammals, including latrophilin. We have investigated C. elegans as a model system for studying the function of these proteins, and their role in regulating neurotransmitter release by latrotoxins.. We have shown that latrophilin is required for the lethality of BWSV in C. elegans by RNAi experiments. We now present data on the characterisation of null mutants of the C. elegans latrophilin, lat-1, illustrating the function of this gene in C. elegans, and show that lat-1 nulls are resistant to emodepside. The expression of latrophilin-GFP constructs is examined, and compared with the phenotypes seen in null mutants. Genetic interactions between endogenous signaling pathways and the lat-1 nulls have been examined by the construction of double mutant worms, revealing novel facets of lat-1 function.

Victor L. Jensen et al. (2006) European Worm Meeting "A Potential DAF-16 Target Involved in Longevity"

David L. Baillie, Victor L. Jensen, Donald L. Riddle

[European Worm Meeting, 2006]

Victor L. Jensen1, David L. Baillie2, and Donald L. Riddle3. Genes differing in steady-state RNA levels between N2 and daf-2 adults and N2 dauer larvae were identified using Serial Analysis of Gene Expression (SAGE) databases. One gene, a putative transcription factor, was isolated from a screen for genes involved in longevity. The outcrossed knockout allele was shown to have extended longevity, ~3% Him and ~2% Vab phenotypes. The 1 kb of genomic sequence 5? of the confirmed transcription start site contains several possible DAF-16 binding sites. By using a series of truncated promoter sequences to drive GFP expression, possible in vivo activity for these DAF-16 binding sites was observed. One consensus site DBE (DAF-16 Binding Element) may act to repress transcription. This is in agreement with the SAGE data which shows down regulation of this transcription factor in the daf-2 background. In daf-2 mutants DAF-16 is activated and is required for extended longevity. Transcriptional targets and the DNA binding motif for the transcription factor will be elucidated, and its role in longevity will be characterized.

James P McCarter et al. (2001) International C. elegans Meeting "Genes from Other"

Michael Dante, James P McCarter, John C Martin, Deana Pape, Brandi Chiapelli, Todd N Wylie, Robert H Waterston, Sandra W Clifton

[International C. elegans Meeting, 2001]

To build upon knowledge gained from the genome of C. elegans , we have begun generating Expressed Sequence Tags (ESTs) from parasitic (and free-living) nematodes. This project will generate >225,000 5' ESTs from 14 species by 2003. Additionally, the Sanger Centre and Edinburgh Univ. will complete 80,000 ESTs from 7 species. Through these combined efforts, we anticipate the identification of >80,000 new nematode genes. At the GSC, approximately 35,000 ESTs have been generated to date including sequences from Ancylostoma caninum, Heterodera glycines, Meloidogyne incognita and javanica, Parastrongyloides trichosuri, Pristionchus pacificus, Strongyloides stercoralis and ratti, Trichinella spiralis, and Zeldia punctata . We will report on our progress in sequence analysis, including the creation of the NemaGene gene index for each species by EST clustering and consensus sequence generation, identification of common and rare transcripts, and identification of genes with orthologues in C. elegans and other nematodes. All sequences are publicly available at www.ncbi.nlm.nih.gov/dbEST. NemaGene sequences and project details are available at WWW.NEMATODE.NET. We would like to thank collaborators who have provided materials and ideas for this project including Prema Arasu, David Bird, Rick Davis, Warwick Grant, John Hawdon, Doug Jasmer, Andrew Kloek, Thomas Nutman, Charlie Opperman, Alan Scott, Ralf Sommer, and Mark Viney. This work is funded by NIH-AI-46593, NSF-0077503, and a Merck / Helen Hay Whitney Foundation fellowship.

O'Connell KF et al. (1997) International C. elegans Meeting "NEW MUTATIONS AFFECTING THE GENERATION OF ZYGOTIC POLARITY"

White JG, Badrinath AS, O'Connell KF, Maxwell KN

[International C. elegans Meeting, 1997]

Division of the C. elegans zygote is asymmetric, producing daughter cells that differ in size and developmental potential. To produce distinct daughter cell fates, the zygote must be polarized prior to division such that a different complement of cell fate determinants is inherited by each of the daughters. It is currently thought that the unfertilized egg possesses no inherent polarity and that polarity is established only after fertilization. A number of par genes have been described that are required for partitioning of developmental instructions during the early cleavages and it is thought that the products of these genes interact directly or indirectly with microfilament and microtubule systems to establish polarity and cleavage orientation. Here we describe two new mutations that affect zygotic polarity, both identified in screens for conditional mutations producing a sterile uncoordinated phenotype. oj29 embryos lack functional centrosomes and a number of indicators of embryonic polarity; membrane ruffling and pronuclear migration are aberrant and the posterior-directed cytoplasmic streaming seen in wild-type embryos is missing. stu-4(e2406) isolated by David Livingstone appears to affect the actin cytoskeleton; embryos are defective in polar body formation, pronuclear migration, pseudocleavage and cytokinesis. In addition the first mitotic spindle is often misaligned. We are currently analyzing these mutants for defects in other aspects of asymmetry such as the segregation of P granules. In addition we are screening a small bank of emb mutations, produced in the sterile unc screen, for similar phenotypes.

Gerami B et al. (1997) International C. elegans Meeting "MAPPING QUANTITATIVE TRAIT LOCI FOR CHEMOTAXIS: CORRESPONDENCE BETWEEN QTL AND odr CANDIDATE LOCI"

Phillips PC, Gerami B, Morphew JJ

[International C. elegans Meeting, 1997]

Understanding the genetics of complex traits is challenging because it can be difficult to separate out the effects of the numerous genes affecting the trait. C. elegans can serve as a useful model system for studying complex traits because of the wealth of genetic and functional information available. Chemotaxis provides an ideal trait for this type of study because it ecologically important to the nematodes, as well as likely to be influenced by many genes (a number of which are known). In collaboration with Thomas Johnson and David Shook [1] and Robert Shmookler Reis and Robert Ebert [2], who provided genotyped lines generated in a cross between N2 and BO, we have assayed the chemotaxic response of 180 recombinant inbred lines to benzaldehyde at two concentrations. These concentrations, 50 nl and 500 nl, respectively lead to an attraction or repulsion response. Separate analysis of the lines from the two labs yield different results. The SR lines show a QTL mapping to the fourth chromosome, whereas the TJ lines show several QTL, primarily on the X chromosome. The QTL on X map to the same locations as two mutants known to block the response to benzaldehyde, odr-1 and odr-5 [3]. We are in the process of evaluating these candidate loci as the actual QTL using backcrossing and complementation testing approaches. Our hope is to create a model system for studying a variety of quantitative genetic questions. [1] Genetics 142:801 (1996), [2] Genetics 135:1003 (1993), [3] Bargmann et al., Cell 74:515 (1993)