End-joining inhibition at telomeres requires the translocase and polySUMO-dependent ubiquitin ligase Uls1.

In eukaryotes, permanent inhibition of the non-homologous end joining (NHEJ) repair pathway at telomeres ensures that chromosome ends do not fuse. In budding yeast, binding of Rap1 to telomere repeats establishes NHEJ inhibition. Here, we show that the Uls1 protein is required for the maintenance of NHEJ inhibition at telomeres. Uls1 protein is a non-essential Swi2/Snf2-related translocase and a Small Ubiquitin-related Modifier (SUMO)-Targeted Ubiquitin Ligase (STUbL) with unknown targets. Loss of Uls1 results in telomere-telomere fusions. Uls1 requirement is alleviated by the absence of poly-SUMO chains and by rap1 alleles lacking SUMOylation sites. Furthermore, Uls1 limits the accumulation of Rap1 poly-SUMO conjugates. We propose that one of Uls1 functions is to clear non-functional poly-SUMOylated Rap1 molecules from telomeres to ensure the continuous efficiency of NHEJ inhibition. Since Uls1 is the only known STUbL with a translocase activity, it can be the general molecular sweeper for the clearance of poly-SUMOylated proteins on DNA in eukaryotes.

Tetrahymena Pot2 is a developmentally regulated paralog of Pot1 that localizes to chromosome breakage sites but not to telomeres.

Tetrahymena telomeres are protected by a protein complex composed of Pot1, Tpt1, Pat1, and Pat2. Pot1 binds the 3' overhang and serves multiple roles in telomere maintenance. Here we describe Pot2, a paralog of Pot1 which has evolved a novel function during Tetrahymena sexual reproduction. Pot2 is unnecessary for telomere maintenance during vegetative growth, as the telomere structure is unaffected by POT2 macronuclear gene disruption. Pot2 is expressed only in mated cells, where it accumulates in developing macronuclei around the time of two chromosome processing events: internal eliminated sequence (IES) excision and chromosome breakage. Chromatin immunoprecipitation (ChIP) demonstrated Pot2 localization to regions of chromosome breakage but not to telomeres or IESs. Pot2 association with chromosome breakage sites (CBSs) occurs slightly before chromosome breakage. Pot2 did not bind CBSs or telomeric DNA in vitro, suggesting that it is recruited to CBSs by another factor. The telomere proteins Pot1, Pat1, and Tpt1 and the IES binding factor Pdd1 fail to colocalize with Pot2. Thus, Pot2 is the first protein found to associate specifically with CBSs. The selective association of Pot2 versus Pdd1 with CBSs or IESs indicates a mechanistic difference between the chromosome processing events at these two sites. Moreover, ChIP revealed that histone marks characteristic of IES processing, H3K9me3 and H3K27me3, are absent from CBSs. Thus, the mechanisms of chromosome breakage and IES excision must be fundamentally different. Our results lead to a model where Pot2 directs chromosome breakage by recruiting telomerase and/or the endonuclease responsible for DNA cleavage to CBSs.

The orientation of the C-terminal domain of the Saccharomyces cerevisiae Rap1 protein is determined by its binding to DNA.

Rap1 is an essential DNA-binding factor from the yeast Saccharomyces cerevisiae involved in transcription and telomere maintenance. Its binding to DNA targets Rap1 at particular loci, and may optimize its ability to form functional macromolecular assemblies. It is a modular protein, rich in large potentially unfolded regions, and comprising BRCT, Myb and RCT well-structured domains. Here, we present the architectures of Rap1 and a Rap1/DNA complex, built through a step-by-step integration of small angle X-ray scattering, X-ray crystallography and nuclear magnetic resonance data. Our results reveal Rap1 structural adjustment upon DNA binding that involves a specific orientation of the C-terminal (RCT) domain with regard to the DNA binding domain (DBD). Crystal structure of DBD in complex with a long DNA identifies an essential wrapping loop, which constrains the orientation of the RCT and affects Rap1 affinity to DNA. Based on our structural information, we propose a model for Rap1 assembly at telomere.

Tetrahymena POT1a regulates telomere length and prevents activation of a cell cycle checkpoint.

The POT1/TEBP telomere proteins are a group of single-stranded DNA (ssDNA)-binding proteins that have long been assumed to protect the G overhang on the telomeric 3' strand. We have found that the Tetrahymena thermophila genome contains two POT1 gene homologs, POT1a and POT1b. The POT1a gene is essential, but POT1b is not. We have generated a conditional POT1a cell line and shown that POT1a depletion results in a monster cell phenotype and growth arrest. However, G-overhang structure is essentially unchanged, indicating that POT1a is not required for overhang protection. In contrast, POT1a is required for telomere length regulation. After POT1a depletion, most telomeres elongate by 400 to 500 bp, but some increase by up to 10 kb. This elongation occurs in the absence of further cell division. The growth arrest caused by POT1a depletion can be reversed by reexpression of POT1a or addition of caffeine. Thus, POT1a is required to prevent a cell cycle checkpoint that is most likely mediated by ATM or ATR (ATM and ATR are protein kinases of the PI-3 protein kinase-like family). Our findings indicate that the essential function of POT1a is to prevent a catastrophic DNA damage response. This response may be activated when nontelomeric ssDNA-binding proteins bind and protect the G overhang.

New KCNQ1 mutations leading to haploinsufficiency in a general population; Defective trafficking of a KvLQT1 mutant.

OBJECTIVE: KCNQ1 mutations lead to the long QT syndrome (LQTS), characterized by a prolonged QT interval, syncopes and sudden death. However, some mutations are associated with non-penetrant phenotype (no symptoms, QTc normal or borderline). The objective of this study was to determine whether KCNQ1 variants are associated with borderline QTc prolongation in a general population and to evaluate the frequency of carriers. METHODS: We selected 2008 unrelated and untreated healthy individuals from a non-patient population. The KCNQ1 gene was screened by denaturing high-performance liquid chromatography (dHPLC) in 50 men and 50 women presenting the longest QTc intervals (403 to 443 ms). RESULTS: We identified a nonsense mutation, Y148X, and an in-frame deletion of the serine residue 276 (DeltaS276), in S2 and S5 transmembrane domains, respectively. DeltaS276 KvLQT1 channels expressed in COS-7 cells failed to conduct any K+ current in the homozygous state. Besides, a slight reduction in channel activity was observed when coexpressed with WT KvLQT1 and IsK. Confocal microscopy performed on transfected COS-7 cells revealed that DeltaS276 KvLQT1 was retained in the endoplasmic reticulum, whereas WT KvLQT1 was localized in the cell membrane. The two mutation carriers presented borderline QTc interval prolongation at slow heart rate but a 24-h ECG recording revealed a marked QTc prolongation at higher heart rate for the Y148X carrier. CONCLUSIONS: In this population, two subjects with borderline QTc prolongations (438 and 443 ms) were carriers of KCNQ1 mutations leading to haploinsufficiency and are potentially at risk of developing drug-induced arrhythmia. The study provides the first demonstration of a defective cell surface localization of a KvLQT1 mutant missing one amino acid in a transmembrane domain.

Proposed function of the accumulation of plasma membrane-type Ca2+-ATPase mRNA in resting cysts of the ciliate Sterkiella histriomuscorum.

From an mRNA differential-display analysis of the encystment-excystment cycle of the ciliate Sterkiella histriomuscorum, we have isolated an expressed sequence tag encoding a plasma membrane-type Ca2+-ATPase (PMCA). PMCAs are located either in the plasma membranes or in the membranes of intracellular organelles, and their function is to pump calcium either out of the cell or into the intracellular calcium stores, respectively. The S. histriomuscorum macronuclear PMCA gene (ShPMCA) and its corresponding cDNA were cloned; it is the first member of the Ca2+-ATPase family identified in Sterkiella. The predicted protein of 1,065 amino acids exhibits 37% identity with PMCAs of diverse organisms. A phylogenetic analysis showed its relatedness to homologs of two alveolates: the ciliate Paramecium tetraurelia and the apicomplexan Toxoplasma gondii. Overexpression of the protein ShPMCA failed to rescue the wild-type phenotype of three Ca2+-ATPase-defective mutant strains of Saccharomyces cerevisiae; this failure contrasts with the reported ability of the PMCAs of parasites to complement defects in yeast. ShPMCA mRNA is markedly accumulated during encystment and in resting cysts, suggesting a function during excystment. To address the possibility of a signaling role for calcium at excystment, the capacity of calcium to induce excystment was examined.

Gene structure of the ciliate Sterkiella histriomuscorum based on a combined analysis of DNA and cDNA sequences from 21 macronuclear chromosomes.

Macronuclear deoxyribonucleic acid (DNA) in hypotrichous ciliates consists of a set of linear molecules ranging in size from 0.5 to several tens of kilobases and typically carrying a single gene. Each minichromosome is present at a ploidy of >or=1,000 per macronucleus. These molecules are known as gene-sized molecules. Multigene molecules are also present, but are still poorly described. In analyzing the encystment-excystment cycle of Sterkiella histriomuscorum, we have characterized a set of 21 macronuclear molecules both at the DNA and complementary DNA (cDNA) levels. On a total of 23 validated coding sequences, we mapped the 5' and 3' untranslated regions for a subset of 10 and 18 transcripts, respectively. A combination of DNA and cDNA data allows us to precisely determine several structural features of macronuclear chromosomes, such as the organization of multigene molecules, an intron content higher than expected, and a conserved sequence surrounding the initiation transcription site. It also reveals one coding sequence containing a transcribed 10-bp element that displays the characteristic features of internal eliminated sequences (IES). Its presence in a fraction of the minichromosomes carrying this gene raises the possibility of an incomplete IES excision process during the development of the S. histriomuscorum macronucleus.

Heteroplasmy and evidence for recombination in the mitochondrial control region of the flatfish Platichthys flesus.

The general assumption that mitochondrial DNA (mtDNA) does not undergo recombination has been challenged recently in invertebrates. Here we present the first direct evidence for recombination in the mtDNA of a vertebrate, the flounder Platichthys flesus. The control region in the mtDNA of this flatfish is characterized by the presence of a variable number of tandem repeats and a high level of heteroplasmy. Two types of repeats were recognized, differing by two C-T point mutations. Most individuals carry a pure "C" or a pure "T" array, but one individual showed a compound "CT" array. Such a compound array is evidence for recombination in the mtDNA control region from the flounder.

A homologue of CROC-1 in a ciliated protist (Sterkiella histriomuscorum) testifies to the ancient origin of the ubiquitin-conjugating enzyme variant family.

Resting cysts of Sterkiella histriomuscorum (Ciliophora, Oxytrichidae) have been shown to contain messenger RNA, one of which codes for a protein significantly similar to CROC-1. CROC-1 is a human regulatory protein capable of transactivating the promoter of c-fos and belongs to a newly characterized family of ubiquitin-conjugating enzyme (E2) variants (UEV). We have determined the corresponding macronuclear gene sequence, which is the first protistan UEV sequence available. The phylogenetic analysis indicates the deep separation and solid clustering of all the UEV sequences within the E2 tree showing the ancient origin of these regulatory genes and their high structural conservation during evolution. Furthermore, overexpression of the ciliate UEV is able to rescue the Saccharomyces cerevisiae mms2 null mutant from killing by DNA damaging agents, implying that the UEV family proteins are functionally conserved. In S. histriomuscorum, expression of UEV is correlated with the growth of the cells as transcripts are present in excysting and vegetative cells but are rapidly down-regulated during starvation. These data support the high conservation of the UEV family in eukaryotes, and a regulatory role of the gene is discussed in relation to known functions of UEVs. This analysis may promote the search for homologues of other regulatory genes (metazoan regulators of differentiation) in ciliates.