Zarkower D et al. (1994) Worm Breeder's Gazette "mab-3 YAC Rescue"

De Bono M, Hodgkin JA, Zarkower D

[Worm Breeder's Gazette, 1994]

mab-3 YAC rescue David Zarkower, Mario de Bono, and Jonathan Hodgkin MRC Laboratory of Molecular Biology, Cambridge, England

Eberhardt AG et al. (2008) Vet Parasitol "The Strongyloides (Nematoda) of sheep and the predominant Strongyloides of cattle form at least two different, genetically isolated populations."

Mayer WE, Eberhardt AG, Streit A, Bonfoh B

[Vet Parasitol, 2008]

Strongyloides sp. (Nematoda) are very wide spread small intestinal parasites of vertebrates that can form a facultative free-living generation. Most authors considered all Strongyloides of farm ruminants to belong to the same species, namely Strongyloides papillosus (Wedl, 1856). Here we show that, at least in southern Germany, the predominant Strongyloides found in cattle and the Strongyloides found in sheep belong to separate, genetically isolated populations. While we did find mixed infections in cattle, one form clearly dominated. This variety, in turn, was never found in sheep, indicating that the two forms have different host preferences. We also present molecular tools for distinguishing the two varieties, and an analysis of their phylogenetic relationship with the human parasite Strongyloides stercoralis and the major laboratory model species Strongyloides ratti. Based on our findings we propose that Strongyloides from sheep and the predominant Strongyloides from cattle should be considered separate species as it had already been proposed by [Brumpt, E., 1921. Recherches sur le determinisme des sexes et de l''evolution des Anguillules parasites (Strongyloides). Comptes rendu hebdomadaires des seances et memoires de la Societe de Biologie et de ses filiales 85, 149-152], but was largely ignored by later authors. For nomenclature, we follow [Brumpt, E., 1921. Recherches sur le determinisme des sexes et de l''evolution des Anguillules parasites (Strongyloides). Comptes rendu hebdomadaires des seances et memoires de la Societe de Biologie et de ses filiales 85, 149-152] and use the name S. papillosus for the Strongyloides of sheep and the name Strongyloides vituli for the predominant Strongyloides of cattle.

Ma B (2015) J Am Soc Mass Spectrom "Novor: real-time peptide de novo sequencing software."

Ma B

[J Am Soc Mass Spectrom, 2015]

De novo sequencing software has been widely used in proteomics to sequence new peptides from tandem mass spectrometry data. This study presents a new software tool, Novor, to greatly improve both the speed and accuracy of today's peptide de novo sequencing analyses. To improve the accuracy, Novor's scoring functions are based on two large decision trees built from a peptide spectral library with more than 300,000 spectra with machine learning. Important knowledge about peptide fragmentation is extracted automatically from the library and incorporated into the scoring functions. The decision tree model also enables efficient score calculation and contributes to the speed improvement. To further improve the speed, a two-stage algorithmic approach, namely dynamic programming and refinement, is used. The software program was also carefully optimized. On the testing datasets, Novor sequenced 7%-37% more correct residues than the state-of-the-art de novo sequencing tool, PEAKS, while being an order of magnitude faster. Novor can de novo sequence more than 300 MS/MS spectra per second on a laptop computer. The speed surpasses the acquisition speed of today's mass spectrometer and, therefore, opens a new possibility to de novo sequence in real time while the spectrometer is acquiring the spectral data. Graphical Abstract .

Jagan Srinivasan et al. (2003) International Worm Meeting "Pristionchus genomics: An integrated physical and genetic map of Pristionchus pacificus"

Jagan Srinivasan, Martin van der Meulen, Waltraud Sinz, Taco Jesse, Kim Jansen, Michiel de Both, Ralf Sommer

[International Worm Meeting, 2003]

We study the evolution of cell fate specification using vulva development as a model system and compare the satellite organism P.pacificus with C.elegans. Using forward genetics, we isolated vulva defective mutants in P. pacificus, many of which result in phenotypes unknown from C.elegans. To facilitate the molecular characterization of these mutants, we have constructed an integrated physical and genetic map of P.pacificus. The genome of Pristionchus is approximately 100 MB in size. We constructed BAC libraries from two different enzymes (HindIII and EcoRI) containing a total of around 21,000 clones. The libraries were end sequenced (Genome Sequencing Center, MPI Tuebingen) and the sequence information generated was used to construct a polymorphism map of P.pacificus. In total, more than 200 SSCP markers on the genetic linkage map (Srinivasan et al, 2002). In addition, we generated AFLP markers from BAC clones and placed them on the genetic linkage map. To complement the genetic linkage map, we generated a physical map adopting an AFLP based fingerprinting approach. We selected 7747 BAC clones from the HindIII BAC library, including those BAC clones that were used to generate the SSCP markers. All the BAC clones were AFLP fingerprinted using the primer combination HindIII-MseI (+0/+0). Each fingerprint generated was digitized and scanned for peak strength and peak quality. After peak determination, the fingerprints were scanned for repetitive elements as they produce excessive number of bands. In order to optimize contig assembly, a screening window of 260-825 bp from the AFLP pattern was chosen for creating the physical map. The 7747 BAC clone fingerprints were assembled in FPC v6.2 with a tolerance of 2 and cutoff value of e-06 to generate 376 contigs, with an average of 21 clones per contig. Since our genetic SSCP markers were generated from BAC ends, we anchored these markers on the physical map based on their BAC IDs. Hence, once a mutant maps between 2 genetic markers, we assign a physical location for the mutant thereby facilitating positional cloning of mutations in P.pacificus. References: 1. Srinivasan. J et.al (2002) Genetics, 162,129-134.

De Stasio E et al. (1994) Worm Breeder's Gazette "Mutagenesis of C. elegans Using N-ethyl-N-nitrosourea."

De Stasio E, Stanislaus D, Lephoto C

[Worm Breeder's Gazette, 1994]

Mutagenesis of C. elegans using N-ethyl-N-nitrosourea Elizabeth De Stasio, Dinesh Stanislaus and Catherine Lephoto. Department of Biology, Lawrence University, Appleton, Wl 54911

(2021) Development "The people behind the papers - Clement Dubois, Shivam Gupta, Andrew Mugler and Marie-Anne Felix."

[Development, 2021]

Cell migration needs to be precisely regulated during development so that cells stop in the right position. A new paper in Development investigates the robustness of neuroblast migration in the <i>C. elegans</i> larva in the face of both genetic and environmental variation. To hear more about the story, we met the paper's four authors: Clement Dubois and Shivam Gupta, and their respective supervisors Andrew Mugler (currently Assistant Professor at the Department of Physics and Astronomy at the University of Pittsburgh, where his lab recently moved from Purdue University) and Marie-Anne Felix (Principal Investigator at Institut de Biologie de l'Ecole Normale Superieure in Paris and Research Director at CNRS).

Merry A et al. (2014) Biochem J "RAD-6: pyrimidine synthesis and radiation sensitivity in Caenorhabditis elegans."

Merry A, Hasler M, Kuwabara PE, Qiao M

[Biochem J, 2014]

The Caenorhabditis elegans rad-6 (radiation-sensitive-6) mutant was isolated over 25 years ago in a genetic screen that identified mutants with enhanced sensitivity to DNA damaging agents. In the present paper we describe the molecular identification of the rad-6 gene and reveal that it encodes the bifunctional UMP synthase protein, which carries catalytic activities for OPRTase (orotate phosphoribosyltransferase) and ODCase (orotate monophosphate decarboxylase), key enzymes in the de novo pathway of pyrimidine synthesis. Mutations in genes encoding de novo pathway enzymes cause varying degrees of lethality and pleiotropic phenotypes in many organisms, including humans. We have examined how the absence of rad-6 activity leads to both UV-C hypersensitivity and a decline in both metabolic rate and lifespan. We discuss how rad-6 mutants adapt to the loss of the de novo pathway through a dependency on pyrimidine salvage. We establish further that rad-6(mn160) mutants lack ODCase activity because they are resistant to the cytotoxic effects of 5-FOA (5-fluoroorotic acid). Our results have also led to the identification of a metabolic sensor affecting survival and metabolism, which is dependent on the maternal rad-6 genotype.

Sokolowski MB (2002) Nature "Neurobiology: social eating for stress."

Sokolowski MB

[Nature, 2002]

Behavioral ecologists have shown that many animals form social groups in conditions. Neurobiological evidence for this behaviour has now been discovered in the nematode worm, Caenorhabditis elegans. On pages 899 and 925 of this issue, de Bono et al. and Coates and de Bono present striking results on the genetic, molecular and neural mechanisms underlying nematode social feeding. These discoveries provide tantalizing insights into the effects of stress in social groupings.

Platzer K et al. (2018) Am J Hum Genet "De Novo Variants in MAPK8IP3 Cause Intellectual Disability with Variable Brain Anomalies."

Stegmann APA, Bonati MT, Panis B, Smith-Hicks C, Lemke JR, Pepler A, Wilson C, Iascone M, McWalter K, Brasington C, Allen W, Di Donato N, Platzer K, Ramos L, Edwards SL, Jamra R, Gamble CN, Mandel H, Stobe P, Mahida S, Marquardt T, Demmer LA, Miller KG, Falik-Zaccai T, Pinz H, Hellenbroich Y, Sticht H, Kok F, Cho MT, Stumpel CTRM, Shinde DN, Angione KM

[Am J Hum Genet, 2018]

Using exome sequencing, we have identified de novo variants in MAPK8IP3 in 13 unrelated individuals presenting with an overlapping phenotype of mild to severe intellectual disability. The de novo variants comprise six missense variants, three of which are recurrent, and three truncating variants. Brain anomalies such as perisylvian polymicrogyria, cerebral or cerebellar atrophy, and hypoplasia of the corpus callosum were consistent among individuals harboring recurrent de novo missense variants. MAPK8IP3 has been shown to be involved in the retrograde axonal-transport machinery, but many of its specific functions are yet to be elucidated. Using the CRISPR-Cas9 system to target six conserved amino acid positions in Caenorhabditis elegans, we found that two of the six investigated human alterations led to a significantly elevated density of axonal lysosomes, and five variants were associated with adverse locomotion. Reverse-engineering normalized the observed adverse effects back to wild-type levels. Combining genetic, phenotypic, and functional findings, as well as the significant enrichment of de novo variants in MAPK8IP3 within our total cohort of 27,232 individuals who underwent exome sequencing, we implicate de novo variants in MAPK8IP3 as a cause of a neurodevelopmental disorder with intellectual disability and variable brain anomalies.

Kajitani R et al. (2014) Genome Res "Efficient de novo assembly of highly heterozygous genomes from whole-genome shotgun short reads."

Harada M, Maruyama H, Toyoda A, Ogura Y, Noguchi H, Hayashi T, Kajitani R, Fujiyama A, Kohara Y, Nagayasu E, Okuno M, Yabana M, Toshimoto K, Itoh T

[Genome Res, 2014]

Although many de novo genome assembly projects have recently been conducted using high-throughput sequencers, assembling highly heterozygous diploid genomes is a substantial challenge due to the increased complexity of the de Bruijn graph structure predominantly used. To address the increasing demand for sequencing of nonmodel and/or wild-type samples, in most cases inbred lines or fosmid-based hierarchical sequencing methods are used to overcome such problems. However, these methods are costly and time consuming, forfeiting the advantages of massive parallel sequencing. Here, we describe a novel de novo assembler, Platanus, that can effectively manage high-throughput data from heterozygous samples. Platanus assembles DNA fragments (reads) into contigs by constructing de Bruijn graphs with automatically optimized k-mer sizes followed by the scaffolding of contigs based on paired-end information. The complicated graph structures that result from the heterozygosity are simplified during not only the contig assembly step but also the scaffolding step. We evaluated the assembly results on eukaryotic samples with various levels of heterozygosity. Compared with other assemblers, Platanus yields assembly results that have a larger scaffold NG50 length without any accompanying loss of accuracy in both simulated and real data. In addition, Platanus recorded the largest scaffold NG50 values for two of the three low-heterozygosity species used in the de novo assembly contest, Assemblathon 2. Platanus therefore provides a novel and efficient approach for the assembly of gigabase-sized highly heterozygous genomes and is an attractive alternative to the existing assemblers designed for genomes of lower heterozygosity.