Niu, Y. et al. (2011) International Worm Meeting "Characterization of the aminophospholipid translocase TAT-1 and phosphatidylserine asymmetry in plasma membrane."

Niu, Y., Xue, D., Xia, N., Yuan, Q.

[International Worm Meeting, 2011]

Phosphatidylserine (PS) is asymmetrically distributed in several biological membranes and is normally restricted to the cytoplasmic leaflet of plasma membrane. Loss of PS asymmetry occurs in both normal and pathological conditions. For example, PS is externalized at the early stage of apoptosis and serves as an "eat-me" signal to trigger phagocytosis of the apoptotic cell. Disruption of PS asymmetry may contribute to various human diseases, including stroke and cardiovascular disorders. How PS asymmetry in biological membranes is established and maintained is poorly understood. We have examined the potential roles of C. elegans aminophospholipid translocases (named TAT proteins) in maintaining phospholipid asymmetry. In C. elegans animals deficient in tat-1, PS is ectopically exposed on the surface of all cells, indicating that tat-1 plays a critical role in preventing appearance of PS in the outer leaflet of plasma membrane. Moreover, ectopic PS exposure on the surface of normal cells results in random removal of living cells through a mechanism dependent on PSR-1, a PS-recognizing phagocyte receptor, and CED-1, which recognizes and engulfs apoptotic cells partly through a PS-binding bridging molecule TTR-52 (Darland-Ransom et al., Science 2008; Wang et al., Nature Cell Biology 2010). How the TAT-1 activity is regulated is unclear. Recently, a C. elegans Cdc50 homologue, CHAT-1, was identified and shown to act as a TAT-1 chaperone to regulate membrane PS asymmetry (Chen et al., PLoS Genetics 2010). To understand how TAT-1 is regulated and its roles in animal development, we raised several monoclonal antibodies against the TAT-1 protein. These antibodies detect two protein bands of approximately 130 kDa in N2 worm lysate, which are absent in lysates from tat-1(tm1034) and tat-1(tm3117) mutant animals. We also carried out co-immunoprecipitation (co-IP) experiments in C. elegans and identified several potential TAT-1-interacting proteins, one of which turns out to be CHAT-1. Immunostaining experiments are underway to examine the expression pattern and cellular localization of the endogenous TAT-1 protein. These experiments will help reveal how the activity of TAT-1 is regulated and how TAT-1 is involved in maintaining PS asymmetry on plasma membrane.

Perreault J et al. (2007) Mol Biol Evol "Ro-associated Y RNAs in metazoans: evolution and diversification."

Perreault J, Perreault JP, Boire G

[Mol Biol Evol, 2007]

The Y genes encode small non-coding RNAs whose functions remain elusive, whose numbers vary between species, and whose major property is to be bound by the Ro60 protein (or its ortholog in other species). To better understand the evolution of the Y gene family, we performed a homology search in 27 different genomes along with a structural search using Y RNA specific motifs. These searches confirmed that Y RNAs are well conserved in the animal kingdom and resulted in the detection of several new Y RNA genes, including the first Y RNAs in insects and a second Y RNA detected in Caenorhabditis elegans. Unexpectedly, Y5 genes were retrieved almost as frequently as Y1 and Y3 genes, and, consequently are not the result of a relatively recent apparition as is generally believed. Investigation of the organization of the Y genes demonstrated that the synteny was conserved among species. Interestingly, it revealed the presence of six putative "fossil" Y genes, all of which were Y4 and Y5 related. Sequence analysis led to inference of the ancestral sequences for all Y RNAs. In addition, the evolution of existing Y RNAs was deduced for many families, orders and classes. Moreover, a consensus sequence and secondary structure for each Y species was determined. Further evolutionary insight was obtained from the analysis of several thousand Y retropseudogenes among various species. Taken together, these results confirm the rich and diversified evolution history of Y RNAs.

Yamaguchi M et al. (2016) Biochim Biophys Acta "NF-Y in invertebrates."

Yoshida H, Ly LL, Yamaguchi M, Ali MS, Yoshioka Y

[Biochim Biophys Acta, 2016]

BothDrosophila melanogaster and Caenorhabditis elegans (C. elegans) are useful model organisms to study in vivo roles of NF-Y during development. Drosophila NF-Y (dNF-Y) consists of three subunits dNF-YA, dNF-YB and dNF-YC. In some tissues, dNF-YC-related protein Mes4 may replace dNF-YC in dNF-Y complex. Studies with eye imaginal disc-specific dNF-Y-knockdown flies revealed that dNF-Y positively regulates the sevenless gene encoding a receptor tyrosine kinase, a component of the ERK pathway and negatively regulates the Sensless gene encoding a transcription factor to ensure proper development of R7 photoreceptor cells together with proper R7 axon targeting. dNF-Y also controls the Drosophila Bcl-2 (debcl) to regulate apoptosis. In thorax development, dNF-Y is necessary for both proper Drosophila JNK (basket) expression and JNK signaling activity that is responsible for thorax development. Drosophila p53 gene was also identified as one of the dNF-Y target genes in this system. C. elegans contains two forms of NF-YA subunit, CeNF-YA1 and CeNF-YA2. C. elegans NF-Y (CeNF-Y) therefore consists of CeNF-YB, CeNF-YC and either CeNF-YA1 or CeNF-YA2. CeNF-Y negatively regulates expression of the Hox gene egl-5 (ortholog of Drosophila Abdominal-B) that is involved in tail patterning. CeNF-Y also negatively regulates expression of the tbx-2 gene that is essential for development of the pharyngeal muscles, specification of neural cell fate and adaptation in olfactory neurons. Negative regulation of the expression of egl-5 and tbx-2 by CeNF-Y provides new insight into the physiological meaning of negative regulation of gene expression by NF-Y during development. In addition, studies on NF-Y in platyhelminths are also summarized.

Burns RG (1996) Trends in Cell Biology "Reply: Defining the gamma-, delta- and epsilon-tubulins."

Burns RG

[Trends in Cell Biology, 1996]

Keeling and Logsdon propose that the y-like sequences from Caenorhabditis elegans and Saccharomyces cerevisiae are bona fide y-tubulins that have undergone rapid evolutionary divergence. Indeed, genetic and localization studies with the yeast epsilon-tubulin (encoded by the TUB4 gene) reveal striking similarities to the bona fide y-tubulins, whereas there is no apparent human analogue to the C. elegans delta-tubulin among the 60 available human y-tubulin expressed-sequence tags. (ESTs).

Gardiner TJ et al. (2009) RNA "A conserved motif of vertebrate Y RNAs essential for chromosomal DNA replication."

Langley AR, Gardiner TJ, Krude T, Christov CP

[RNA, 2009]

Noncoding Y RNAs are required for the reconstitution of chromosomal DNA replication in late G1 phase template nuclei in a human cell-free system. Y RNA genes are present in all vertebrates and in some isolated nonvertebrates, but the conservation of Y RNA function and key determinants for its function are unknown. Here, we identify a determinant of Y RNA function in DNA replication, which is conserved throughout vertebrate evolution. Vertebrate Y RNAs are able to reconstitute chromosomal DNA replication in the human cell-free DNA replication system, but nonvertebrate Y RNAs are not. A conserved nucleotide sequence motif in the double-stranded stem of vertebrate Y RNAs correlates with Y RNA function. A functional screen of human Y1 RNA mutants identified this conserved motif as an essential determinant for reconstituting DNA replication in vitro. Double-stranded RNA oligonucleotides comprising this RNA motif are sufficient to reconstitute DNA replication, but corresponding DNA or random sequence RNA oligonucleotides are not. In intact cells, wild-type hY1 or the conserved RNA duplex can rescue an inhibition of DNA replication after RNA interference against hY3 RNA. Therefore, we have identified a new RNA motif that is conserved in vertebrate Y RNA evolution, and essential and sufficient for Y RNA function in human chromosomal DNA replication.

Erickson DL et al. (2006) J Bacteriol "Serotype differences and lack of biofilm formation characterize Yersinia pseudotuberculosis infection of the Xenopsylla cheopis flea vector of Yersinia pestis."

Hinnebusch BJ, Erickson DL, Wren BW, Jarrett CO

[J Bacteriol, 2006]

Yersinia pestis, the agent of plague, is usually transmitted by fleas. To produce a transmissible infection, Y. pestis colonizes the flea midgut and forms a biofilm in the proventricular valve, which blocks normal blood feeding. The enteropathogen Yersinia pseudotuberculosis, from which Y. pestis recently evolved, is not transmitted by fleas. However, both Y. pestis and Y. pseudotuberculosis form biofilms that adhere to the external mouthparts and block feeding of Caenorhabditis elegans nematodes, which has been proposed as a model of Y. pestis-flea interactions. We compared the ability of Y. pestis and Y. pseudotuberculosis to infect the rat flea Xenopsylla cheopis and to produce biofilms in the flea and in vitro. Five of 18 Y. pseudotuberculosis strains, encompassing seven serotypes, including all three serotype O3 strains tested, were unable to stably colonize the flea midgut. The other strains persisted in the flea midgut for 4 weeks but did not increase in numbers, and none of the 18 strains colonized the proventriculus or produced a biofilm in the flea. Y. pseudotuberculosis strains also varied greatly in their ability to produce biofilms in vitro, but there was no correlation between biofilm phenotype in vitro or on the surface of C. elegans and the ability to colonize or block fleas. Our results support a model in which a genetic change in the Y. pseudotuberculosis progenitor of Y. pestis extended its pre-existing ex vivo biofilm-forming ability to the flea gut environment, thus enabling proventricular blockage and efficient flea-borne transmission.

Sato, Manami et al. (2015) International Worm Meeting "Expression pattern of C. elegans Y RNA homologs."

Ushida, Chisato, Kihara, Shinya, Sato, Manami

[International Worm Meeting, 2015]

Y RNA is a small structured ncRNA of about 100 nt in length. This RNA binds to Ro60 protein, which is a target of autoimmune disease antibody in patients with systemic lupus erythematosus and Sjogren's syndrome. Several lines of evidence suggest that the role of Y RNA and Ro60 function in the quality control of structured ncRNAs in cells under stress conditions. It is also indicated that vertebrate Y RNAs function in the initiation of DNA replication without Ro60. However, the molecular mechanisms of these functions and the contribution of Ro60/Y RNP to the autoimmune disease are still unclear. C. elegans genome encodes one Ro60 homolog (ROP-1) and 19 Y RNA homologs (1 CeY RNA and 18 sbRNAs). Other animals also have several Y RNA homologs, but C. elegans is the first example which has more than 5 Y RNA homologs encoded in the genome. Here we show the expression pattern and the cellular localization of these Y RNA homologs in C. elegans examined by the RNA fluorescent in situ hybridization (RNA-FISH). The signals of 14 homologs were detected in the intestinal cytoplasm. The signals of two other homologs were detected in the germ cytoplasm. The remaining three could not be detected, probably because they present in too low abundance to be detected by RNA-FISH. All 19 Y RNA homologs have the structural elements required for the binding of ROP-1. In other organisms, Ro60 binding stabilizes Y RNAs in cells. To know whether C. elegans Y RNA homologs also stabilized by the presence of ROP-1, we examined RNA-FISH of the Y RNA homologs against a mutant strain MQ470, which has a transposon insertion in the middle of the ROP-1 gene and lacks ROP-1 proteins in the cell. As expected, all Y RNAs examined so far decreased extensively. These were confirmed by northern hybridization. The results suggest that several C. elegans Y RNA homologs are expressed in a tissue-specific manner and most Y RNA homologs are stabilized by ROP-1 binding as well as those in other organisms.

Zhou D et al. (2011) Protein Cell "Formation and regulation of Yersinia biofilms."

Yang R, Zhou D

[Protein Cell, 2011]

Flea-borne transmission is a recent evolutionary adaptation that distinguishes the deadly Yersinia pestis from its progenitor Y. Pseudotuberculosis, a mild pathogen transmitted via the food-borne route. Y. Pestis synthesizes biofilms in the flea gut, which is important for fleaborne transmission. Yersinia biofilms are bacterial colonies surrounded by extracellular matrix primarily containing a homopolymer of N-acetyl-D-glucosamine that are synthesized by a set of specific enzymes. Yersinia biofilm production is tightly regulated at both transcriptional and post-transcriptional levels. All the known structural genes responsible for biofilm production are harbored in both Y. Pseudotuberculosis and Y. Pestis, but Y. Pestis has evolved changes in the regulation of biofilm development, thereby acquiring efficient arthropod-borne transmission.

Georgieva S et al. (2001) Mol Cell Biol "The novel transcription factor e(y)2 interacts with TAF(II)40 and potentiates transcription activation on chromatin templates."

Soldatov A, Georgieva S, Eickhoff H, Tora L, Becker P, Dilworth FJ, Georgiev P, Nabirochkina E

[Mol Cell Biol, 2001]

Weak hypomorph mutations in the enhancer of yellow genes, e(y)1 and e(y)2, of Drosophila melanogaster were discovered during the search for genes involved in the organization of interaction between enhancers and promoters. Previously, the e(y)1 gene was cloned and found to encode TAF(II)40 protein. Here we cloned the e(y)2 gene and demonstrated that it encoded a new ubiquitous evolutionarily conserved transcription factor. The e(y)2 gene is located at 10C3 (36.67) region and is expressed at all stages of Drosophila development. It encodes a 101-amino-acid protein, e(y)2. Vertebrates, insects, protozoa, and plants have proteins which demonstrate a high degree of homology to e(y)2. The e(y)2 protein is localized exclusively to the nuclei and is associated with numerous sites along the entire length of the salivary gland polytene chromosomes. Both genetic and biochemical experiments demonstrate an interaction between e(y)2 and TAF(II)40, while immunoprecipitation studies demonstrate that the major complex, including both proteins, appears to be distinct from TFIID. Furthermore, we provide genetic evidence suggesting that the carboxy terminus of dTAF(II)40 is important for mediating this interaction. Finally, using an in vitro transcription system, we demonstrate that recombinant e(y)2 is able to enhance transactivation by GAL4-VP16 on chromatin but not on naked DNA templates, suggesting that this novel protein is involved in the regulation of transcription.

Styer KL et al. (2005) EMBO Rep "Yersinia pestis kills Caenorhabditis elegans by a biofilm-independent process that involves novel virulence factors."

Plano GV, Aballay A, Frothingham R, Bartra SS, Hopkins GW, Styer KL

[EMBO Rep, 2005]

It is known that Yersinia pestis kills Caenorhabditis elegans by a biofilm-dependent mechanism that is similar to the mechanism used by the pathogen to block food intake in the flea vector. Using Y. pestis KIM 5, which lacks the genes that are required for biofilm formation, we show that Y. pestis can kill C. elegans by a biofilm-independent mechanism that correlates with the accumulation of the pathogen in the intestine. We used this novel Y. pestis-C. elegans pathogenesis system to show that previously known and unknown virulence-related genes are required for full virulence in C. elegans. Six Y. pestis mutants with insertions in genes that are not related to virulence before were isolated using C. elegans. One of the six mutants carried an insertion in a novel virulence gene and showed significantly reduced virulence in a mouse model of Y. pestis pathogenesis. Our results indicate that the Y. pestis-C. elegans pathogenesis system that is described here can be used to identify and study previously uncharacterized Y. pestis gene products required for virulence in mammalian systems.