Condensin I folds the Caenorhabditis elegans genome.

The structural maintenance of chromosome (SMC) complexes-cohesin and condensins-are crucial for chromosome separation and compaction during cell division. During the interphase, mammalian cohesins additionally fold the genome into loops and domains. Here we show that, in Caenorhabditis elegans, a species with holocentric chromosomes, condensin I is the primary, long-range loop extruder. The loss of condensin I and its X-specific variant, condensin IDC, leads to genome-wide decompaction, chromosome mixing and disappearance of X-specific topologically associating domains, while reinforcing fine-scale epigenomic compartments. In addition, condensin I/IDC inactivation led to the upregulation of X-linked genes and unveiled nuclear bodies grouping together binding sites for the X-targeting loading complex of condensin IDC. C. elegans condensin I/IDC thus uniquely organizes holocentric interphase chromosomes, akin to cohesin in mammals, as well as regulates X-chromosome gene expression.

Tissue-Specific Transcription Footprinting Using RNA PoI DamID (RAPID) in Caenorhabditis elegans.

Differential gene expression across cell types underlies development and cell physiology in multicellular organisms. Caenorhabditis elegans is a powerful, extensively used model to address these biological questions. A remaining bottleneck relates to the difficulty to obtain comprehensive tissue-specific gene transcription data, since available methods are still challenging to execute and/or require large worm populations. Here, we introduce the RNA Polymerase DamID (RAPID) approach, in which the Dam methyltransferase is fused to a ubiquitous RNA polymerase subunit to create transcriptional footprints via methyl marks on the DNA of transcribed genes. To validate the method, we determined the polymerase footprints in whole animals, in sorted embryonic blastomeres and in different tissues from intact young adults by driving tissue-specific Dam fusion expression. We obtained meaningful transcriptional footprints in line with RNA-sequencing (RNA-seq) studies in whole animals or specific tissues. To challenge the sensitivity of RAPID and demonstrate its utility to determine novel tissue-specific transcriptional profiles, we determined the transcriptional footprints of the pair of XXX neuroendocrine cells, representing 0.2% of the somatic cell content of the animals. We identified 3901 candidate genes with putatively active transcription in XXX cells, including the few previously known markers for these cells. Using transcriptional reporters for a subset of new hits, we confirmed that the majority of them were expressed in XXX cells and identified novel XXX-specific markers. Taken together, our work establishes RAPID as a valid method for the determination of RNA polymerase footprints in specific tissues of C. elegans without the need for cell sorting or RNA tagging.

OZF is a Claspin-interacting protein essential to maintain the replication fork progression rate under replication stress.

DNA replication is essential for cell proliferation and is one of the cell cycle stages where DNA is more vulnerable. Replication stress is a prominent property of tumor cells and an emerging target for cancer therapy. Although it is not directly involved in nucleotide incorporation, Claspin is a protein with relevant functions in DNA replication. It harbors a DNA-binding domain that interacts preferentially with branched or forked DNA molecules. It also acts as a platform for the interaction of proteins related to DNA damage checkpoint activation, DNA repair, DNA replication origin firing, and fork progression. In order to find new proteins potentially involved in the regulation of DNA replication, we performed a two-hybrid screen to discover new Claspin-binding proteins. This system allowed us to identify the zinc-finger protein OZF (ZNF146) as a new Claspin-interacting protein. OZF is also present at replication forks and co-immunoprecipitates not only with Claspin but also with other replisome components. Interestingly, OZF depletion does not affect DNA replication in a normal cell cycle, but its depletion induces a reduction in the fork progression rate under replication stress conditions. Our results suggest that OZF is a Claspin-binding protein with a specific function in fork progression under replication stress.

Single and dual drug selection for transgenes following bombardment of Caenorhabditis species.

The use of drugs and drug resistance genes is a powerful method to select for the presence of a transgene. Unlike methods that require the complementation of a genetic mutation, this system can be used on any genetic background. Drug selection does not require extensive manipulation or costly equipment, yet it is very rapid and can achieve extremely high efficiency, selecting a small number of transgenic worms from among millions of non-transgenic worms. Introducing integrated transgenes into Caenorhabditis elegans by microparticle bombardment represents just such a challenge. Here we describe in detail the protocol we have developed for dual-drug selection in liquid with puromycin and G418 which works well in a variety of Caenorhabditis species. We also show that single drug selection with only puromycin or only G418 is effective in C. elegans. The growing number of drug selection markers that have been adapted to C. elegans are an important addition to the genetic toolkit at our disposal.

Predicting phenotypic variation in yeast from individual genome sequences.

A central challenge in genetics is to predict phenotypic variation from individual genome sequences. Here we construct and evaluate phenotypic predictions for 19 strains of Saccharomyces cerevisiae. We use conservation-based methods to predict the impact of protein-coding variation within genes on protein function. We then rank strains using a prediction score that measures the total sum of function-altering changes in different sets of genes reported to influence over 100 phenotypes in genome-wide loss-of-function screens. We evaluate our predictions by comparing them with the observed growth rate and efficiency of 15 strains tested across 20 conditions in quantitative experiments. The median predictive performance, as measured by ROC AUC, was 0.76, and predictions were more accurate when the genes reported to influence a trait were highly connected in a functional gene network.

Rapid selection of transgenic C. elegans using antibiotic resistance.

Caenorhabditis elegans is an important model organism in biology, but until now no antibiotic selection markers have been successfully demonstrated for this species. We have developed a selection system using puromycin that allows the rapid and easy isolation of large populations of transgenic worms. This approach is sufficiently powerful to select single-copy transgenes, does not require any particular genetic background and also works in C. briggsae.

Intrinsic protein disorder and interaction promiscuity are widely associated with dosage sensitivity.

Why are genes harmful when they are overexpressed? By testing possible causes of overexpression phenotypes in yeast, we identify intrinsic protein disorder as an important determinant of dosage sensitivity. Disordered regions are prone to make promiscuous molecular interactions when their concentration is increased, and we demonstrate that this is the likely cause of pathology when genes are overexpressed. We validate our findings in two animals, Drosophila melanogaster and Caenorhabditis elegans. In mice and humans the same properties are strongly associated with dosage-sensitive oncogenes, such that mass-action-driven molecular interactions may be a frequent cause of cancer. Dosage-sensitive genes are tightly regulated at the transcriptional, RNA, and protein levels, which may serve to prevent harmful increases in protein concentration under physiological conditions. Mass-action-driven interaction promiscuity is a single theoretical framework that can be used to understand, predict, and possibly treat the effects of increased gene expression in evolution and disease.

Analysis of the human E2 ubiquitin conjugating enzyme protein interaction network.

In eukaryotic cells the stability and function of many proteins are regulated by the addition of ubiquitin or ubiquitin-like peptides. This process is dependent upon the sequential action of an E1-activating enzyme, an E2-conjugating enzyme, and an E3 ligase. Different combinations of these proteins confer substrate specificity and the form of protein modification. However, combinatorial preferences within ubiquitination networks remain unclear. In this study, yeast two-hybrid (Y2H) screens were combined with true homology modeling methods to generate a high-density map of human E2/E3-RING interactions. These data include 535 experimentally defined novel E2/E3-RING interactions and >1300 E2/E3-RING pairs with more favorable predicted free-energy values than the canonical UBE2L3-CBL complex. The significance of Y2H predictions was assessed by both mutagenesis and functional assays. Significantly, 74/80 (>92%) of Y2H predicted complexes were disrupted by point mutations that inhibit verified E2/E3-RING interactions, and a approximately 93% correlation was observed between Y2H data and the functional activity of E2/E3-RING complexes in vitro. Analysis of the high-density human E2/E3-RING network reveals complex combinatorial interactions and a strong potential for functional redundancy, especially within E2 families that have undergone evolutionary expansion. Finally, a one-step extended human E2/E3-RING network, containing 2644 proteins and 5087 edges, was assembled to provide a resource for future functional investigations.

Widespread conservation of genetic redundancy during a billion years of eukaryotic evolution.

Genetic redundancy means that two genes can perform the same function. Using a comprehensive phylogenetic analysis, we show here in both Saccharomyces cerevisiae and Caenorhabditis elegans that genetic redundancy is not just a transient consequence of gene duplication, but is often an evolutionary stable state. In multiple examples, genes have retained redundant functions since the divergence of the animal, plant and fungi kingdoms over a billion years ago. The stable conservation of genetic redundancy contrasts with the more rapid evolution of genetic interactions between unrelated genes and can be explained by theoretical models including a 'piggyback' mechanism in which overlapping redundant functions are co-selected with nonredundant ones.

A simple principle concerning the robustness of protein complex activity to changes in gene expression.

BACKGROUND: The functions of a eukaryotic cell are largely performed by multi-subunit protein complexes that act as molecular machines or information processing modules in cellular networks. An important problem in systems biology is to understand how, in general, these molecular machines respond to perturbations. RESULTS: In yeast, genes that inhibit growth when their expression is reduced are strongly enriched amongst the subunits of multi-subunit protein complexes. This applies to both the core and peripheral subunits of protein complexes, and the subunits of each complex normally have the same loss-of-function phenotypes. In contrast, genes that inhibit growth when their expression is increased are not enriched amongst the core or peripheral subunits of protein complexes, and the behaviour of one subunit of a complex is not predictive for the other subunits with respect to over-expression phenotypes. CONCLUSION: We propose the principle that the overall activity of a protein complex is in general robust to an increase, but not to a decrease in the expression of its subunits. This means that whereas phenotypes resulting from a decrease in gene expression can be predicted because they cluster on networks of protein complexes, over-expression phenotypes cannot be predicted in this way. We discuss the implications of these findings for understanding how cells are regulated, how they evolve, and how genetic perturbations connect to disease in humans.

Polo-like kinase-1 controls proteasome-dependent degradation of Claspin during checkpoint recovery.

DNA-damage checkpoints maintain genomic integrity by mediating a cell-cycle delay in response to genotoxic stress or stalled replication forks. In response to damage, the checkpoint kinase ATR phosphorylates and activates its effector kinase Chk1 in a process that critically depends on Claspin . However, it is not known how exactly this kinase cascade is silenced. Here we demonstrate that the abundance of Claspin is regulated through proteasomal degradation. In response to DNA damage, Claspin is transiently stabilized, and its expression depends on Chk1 kinase activity. In addition, we show that Claspin is degraded upon mitotic entry, a process that depends on the beta-TrCP-SCF ubiquitin ligase and Polo-like kinase-1 (Plk1). We demonstrate that Claspin interacts with both beta-TrCP and Plk1 and that inactivation of these components or the beta-TrCP recognition motif in Claspin prevents its mitotic degradation. Interestingly, expression of a nondegradable Claspin mutant inhibits recovery from a DNA-damage-induced checkpoint arrest. Thus, we conclude that Claspin levels are tightly regulated, both during unperturbed cell cycles and after DNA damage. Moreover, our data demonstrate that the degradation of Claspin at the onset of mitosis is an essential step for the recovery of a cell from a DNA-damage-induced cell-cycle arrest.

Two-hybrid reporter vectors for gap repair cloning.

Yeast two-hybrid analysis is a valuable approach to the discovery and characterization of protein interactions. We have developed vectors that can indicate the presence of an insert when used in two-hybrid bait and prey construction by gap repair cloning. The strategy uses a recombination cloning site flanked by sequences encoding the GAL4 activation and binding domains. After gap repair cloning in standard hosts carrying an ADE2 reporter gene, disruption of GAL4 by an insert can be identified by the development of red colony color, while empty vector plasmids produce white colonies. Function in yeast two-hybrid applications was initially validated using known interacting proteins in pair-wise analyses, and subsequently, the bait vectors were used in library screens with the mouse Mad212 and human Mccd1 proteins, identifying a number of putative new interactions for these proteins. These vectors should facilitate high-throughput yeast two-hybrid screens in which large numbers of bait and prey constructs may be required.

Expression and motogenic activity of TFF2 in human breast cancer cells.

The expression of TFF2 in breast cancer cells and the effect of recombinant TFF2 on breast cancer cell migration were assessed. TFF2 expression was detected by PCR in estrogen receptor-negative and at lower levels in estrogen receptor-positive breast cancer cells. TFF2 expression was detected in nine out of 10 primary breast tumors but its expression was not related to that of the estrogen receptor. Focal expression was observed in normal and tumor cells by immunohistochemistry. TFF2 stimulated the migration of estrogen-responsive MCF-7 and non-responsive MDA-MB231 cells. We conclude that TFF2 is expressed in normal and malignant breast epithelial cells and that it stimulates the migration of breast cancer cells.

Analysis of a high-throughput yeast two-hybrid system and its use to predict the function of intracellular proteins encoded within the human MHC class III region.

High-throughput (HTP) protein-interaction assays, such as the yeast two-hybrid (Y2H) system, are enormously useful in predicting the functions of novel gene-products. HTP-Y2H screens typically do not include all of the reconfirmation and specificity tests used in small-scale studies, but the effects of omitting these steps have not been assessed. We performed HTP-Y2H screens that included all standard controls, using the predicted intracellular proteins expressed from the human MHC class III region, a region of the genome associated with many autoimmune diseases. The 91 novel interactions identified provide insight into the potential functions of many MHC genes, including C6orf47, LSM2, NELF-E (RDBP), DOM3Z, STK19, PBX2, RNF5, UAP56 (BAT1), ATP6G2, LST1/f, BAT2, Scythe (BAT3), CSNK2B, BAT5, and CLIC1. Surprisingly, our results predict that 1/3 of the proteins may have a role in mRNA processing, which suggests clustering of functionally related genes within the human genome. Most importantly, our analysis shows that omitting standard controls in HTP-Y2H screens could significantly compromise data quality.

A novel gene encoding a coiled-coil mitochondrial protein located at the telomeric end of the human MHC Class III region.

The human Major Histocompatibility Complex (MHC) Class III region, which lies in between the MHC Class I and Class II regions on chromosome 6p21.3, contains approximately 60 genes with diverse functions. Using bioinformatics analyses, we identified a novel open reading frame (ORF) in this region, telomeric of BAT1, which we called Mitochondrial Coiled-Coil Domain 1 (MCCD1). The expression of the predicted ORF in a number of human tissues was confirmed by RT-PCR analysis. An orthologue of the MCCD1 gene was identified in the swine MHC in an analogous position, adjacent to pig BAT1. The overall sequence identity between the human and pig MCCD1 proteins is only 65.9%, but their C-terminal domains are highly conserved, showing 92% identity over 53 residues. The MCCD1 gene encodes a short polypeptide (119 amino acids) which contains a putative coiled-coil domain at its highly conserved C terminus and a predicted mitochondrial localisation signal at its N terminus. Transient expression in mammalian cells of MCCD1 fused at its C terminus to either EGFP or the T7-epitope tag showed that this protein is indeed targeted to mitochondria. Finally, we characterised the polymorphism in this gene using denaturing high-performance liquid chromatography (DHPLC) analysis and found that the MCCD1 gene is highly polymorphic containing an average of 1 single nucleotide polymorphism (SNP) every 99 bp. Interestingly, MCCD1 contains four SNPs within the coding region, three of which cause nonsynonymous and nonconservative changes in the amino acid sequence.

A distinct bipartite motif is required for the localization of inhibitory kappaB-like (IkappaBL) protein to nuclear speckles.

The inhibitory kappaB (IkappaB)-like (IkappaBL) gene is located within the Class III region of the MHC on human chromosome 6. Previous analysis of the predicted amino acid sequence of the human IkappaBL protein revealed three putative functional domains; 2-3 ankyrin repeat sequences, which are similar to the second and third ankyrin repeats of the nuclear factor kappaB (NF-kappaB) protein; three PEST sequence motifs (a sequence that is rich in proline, serine, aspartic acid and threonine residues), which are also found in other IkappaB family members; and a C-terminal leucine zipper-like motif. In the present study we have identified a novel bipartite motif, which is required for nuclear localization of the IkappaBL protein. Analyses of IkappaBL-specific transcripts revealed the existence of a widely expressed spliced variant form of IkappaBL (IkappaBLsv1), which lacks the amino acid sequence GELEDEWQEVMGRFE (where single-letter amino-acid notation has been used). Interestingly, translation of IkappaBL mRNA in vivo was found to initiate predominantly from the second available methionine, thereby resulting in the disruption of the predicted N-terminal PEST sequence. Also, transient expression of T7 epitope-tagged IkappaBL and IkappaBLsv1 proteins in mammalian cells showed that both proteins were targeted to the nucleus, where they accumulate in nuclear speckles. To define the protein domains required for nuclear import and subnuclear localization, a complementary set of deletion mutants and enhanced green fluorescent protein-IkappaBL domain fusions were expressed in mammalian cells. Data from these experiments show that a combination of the ankyrin-repeat region and an adjacent arginine-rich sequence are necessary and sufficient for both nuclear import and speckle localization.

The jury is out on "guilt by association" trials.

The availability of comprehensive protein-protein interaction maps will significantly enhance medical research and aid the functional characterisation of novel genes. To date, the largest scale studies of protein-protein interactions have used the yeast two hybrid method. In this review we take a closer look at the different approaches used in these studies and discuss some key considerations that should be taken into account when designing high throughput interaction mapping projects.