A stochastic model of mutant growth due to mutation in tumors,based on stem cell considerations

A stochastic model of the evolution of mutant subpopulations from stem cells in a human tumor system is derived. From the model, the growth of mutants (both stem cell mutants and overall mutants) due to mutation of tumor stem cells during growth is explored in detail. This allows one to relate the mutant stem cell and overall tumor mutant cell population sizes. The relation of these average sizes is derived for large tumor size and confirms the result of the model due to MacKillop et al. [4], which is based on three tumor cell subpopulations: stem, transitional, and end cells. Furthermore, the results of the stem cell statistics obtained are the same as those obtained from the filtered Poisson process approach [2].     

Time-Restricted Feeding Prevents Obesity and Metabolic Syndrome in Mice Lacking a Circadian Clock

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Destabilization of Yeast Micro- and Minisatellite DNA Sequences by Mutations Affecting a Nuclease Involved in Okazaki Fragment Processing (rad27) and DNA Polymerase δ (pol3-t)

We examined the effects of mutations in the Saccharomyces cerevisiae RAD27 (encoding a nuclease involved in the processing of Okazaki fragments) and POL3 (encoding DNA polymerase δ) genes on the stability of a minisatellite sequence (20-bp repeats) and microsatellites (1- to 8-bp repeat units). Both the rad27 and pol3-t mutations destabilized both classes of repeats, although the types of tract alterations observed in the two mutant strains were different. The tract alterations observed in rad27 strains were primarily additions, and those observed in pol3-t strains were primarily deletions. Measurements of the rates of repetitive tract alterations in strains with both rad27 and pol3-t indicated that the stimulation of microsatellite instability by rad27 was reduced by the effects of the pol3-t mutation. We also found that rad27 and pol3-01 (an allele carrying a mutation in the “proofreading” exonuclease domain of DNA polymerase δ) mutations were synthetically lethal.All eukaryotic genomes thus far examined contain many simple repetitive DNA sequences, tracts of DNA with one or a small number of bases repeated multiple times (48). These repetitive regions can be classified as microsatellites (small repeat units in tandem arrays 10 to 60 bp in length) and minisatellites (larger repeat units in tandem arrays several hundred base pairs to several kilobase pairs in length). In this paper, arrays with repeat units 14 bp or less will be considered microsatellites and arrays with longer repeat units will be considered minisatellites.Previous studies show that simple repetitive sequences are unstable relative to “normal” DNA sequences, frequently undergoing additions or deletions of repeat units, in Escherichia coli (24), Saccharomyces cerevisiae (12), and mammals (59). This mutability has two important consequences. First, it results in polymorphic loci that are useful in genetic mapping and forensic studies (15, 59). Second, although these repetitive tracts are usually located outside of coding sequences, alterations in the lengths of microsatellites or minisatellites located within coding sequences can produce frameshift mutations or novel protein variants (20, 22, 26).From studies of the effects of various mutations on microsatellite stability in yeast and E. coli (40) and the analysis of mutational changes caused by DNA polymerase in vitro (21), it is likely that most alterations reflect DNA polymerase slippage events (47). These events involve the transient dissociation of the primer and template strands during the replication of a microsatellite (Fig. ​(Fig.1).1). If the strands reassociate to yield an unpaired repeat on the primer strand, the net result is an addition of repeats (following a second round of DNA replication). Unpaired repeats on the template strand would result in a deletion by the same mechanism. Open in a separate windowFIG. 1“Classical” model for the generation of microsatellite alterations by DNA polymerase slippage. Two single strands of a replicating DNA molecule are shown, with each repeat unit indicated by a rectangle. Arrows indicate the 3′ ends of the strand, and the top and bottom strands represent the elongating primer strand and the template strand, respectively. Step 1, the primer and template strand dissociate; step 2, the primer and template strands reassociate in a misaligned configuration, resulting in an unpaired repeat on either the template strand (left side) or primer strand (right side); step 3, DNA synthesis is completed. If the unpaired repeats are not excised by the DNA mismatch repair system, after the next round of DNA synthesis one DNA molecule will be shortened by one repeat (left side) or lengthened by one repeat (right side).A number of mutations have been shown to elevate microsatellite instability. In E. coli (24, 46), yeast (44, 45), and mammalian cells (27), mutations in genes affecting DNA mismatch repair dramatically elevate the instability of a dinucleotide microsatellite. The most likely explanation of this result is that the DNA mismatches (unpaired repeats) resulting from DNA polymerase slippage events are efficiently removed from the newly synthesized strand by the DNA mismatch repair system. Thus, in the absence of mismatch repair, tract instability is elevated. From genetic studies, it has been found that mismatch repair in yeast efficiently corrects DNA mismatches involving 1- to 14-base loops (the size of the repeat units in microsatellites) but fails to correct mismatches involving loops larger than 16 bases (the size of the repeat units in minisatellites) (3, 41, 53). An inefficient mechanism, not involving the classical DNA mismatch repair system, is capable of correcting large DNA loops formed during meiotic recombination (19).In addition to mutations affecting DNA mismatch repair, some mutations affecting DNA replication in yeast destabilize microsatellites. Yeast strains bearing a null mutation in the RAD27 (RTH1) gene have high levels of instability of the dinucleotide poly(GT) and the trinucleotide CAG, specifically elevating single-repeat insertions (18, 39). RAD27 encodes the homolog of the mammalian FEN-1 protein, a 5′-to-3′ exonuclease (10, 11, 33). This nuclease activity is required for removing the terminal ribonucleotide residue from the 5′ end of the Okazaki fragment (9, 14, 35, 54, 55, 57); this step is necessary for the two adjoining fragments to be ligated together. FEN-1 appears to be active as either an exonuclease in the presence of a single-stranded gap upstream of the 5′ terminus or an endonuclease on a 5′ flap structure (13, 34). Since yeast strains that contain a null mutation in RAD27 grow poorly but are viable (38, 43), it is likely that less efficient nuclease activities that are also capable of 5′ Okazaki fragment processing are present in yeast. In addition to destabilizing dinucleotide microsatellites, rad27 strains have high levels of spontaneous mitotic recombination, elevated rates of forward mutation, and increased sensitivity to the alkylating agent methyl methanesulfonate (MMS) (18, 38, 43). In contrast to the mutations normally seen in mismatch repair mutants, i.e., point mutations or small frameshifts, the types of mutations observed in the absence of Rad27p are duplications of sequences flanked by short direct repeats (4 to 7 bp in length) (49). These duplications were not affected by the DNA mismatch repair system.The same class of sequences that are duplicated in the rad27 strains show an elevated rate (up to 1,000-fold) of deletion in strains containing a temperature-sensitive allele (pol3-t) of the yeast gene encoding DNA polymerase δ (52, 53). This mutant (initially named tex1) was isolated in a strain that exhibited an increased excision rate of a bacterial transposon with long terminal repeats inserted within a yeast gene (7). The pol3-t allele, which encodes a mutation (Gly₆₄₁ to Ala₆₄₁) (51) located near the putative nucleotide binding and active-site domains of the enzyme (58), is thought to diminish the rate of lagging-strand synthesis resulting in long stretches of single-stranded DNA on the lagging-strand template (8). This single-stranded DNA may have the potential to form intrastrand base-paired structures, creating interactions between short direct repeats. These interactions would result in an increased frequency of deletions caused by DNA polymerase slippage.Since rad27 and pol3-t mutations elevate the rates of duplications and deletions associated with short separated repeats in nonrepetitive DNA sequences, Kunkel et al. (22) suggested that these mutations could also destabilize minisatellites. In this paper, we examine the effects of rad27 and pol3-t mutations on the stability of simple repeats in which the repeat unit length varies between 1 and 20 bp. Our results show that both mutations destabilize both microsatellites and minisatellites, but that the mechanisms involved in the destabilization are different for the two mutations.     

The Historical Demography and Genetic Variation of the Endangered Cycas multipinnata (Cycadaceae) in the Red River Region,Examined by Chloroplast DNA Sequences and Microsatellite Markers

Cycas multipinnata C.J. Chen & S.Y. Yang is a cycad endemic to the Red River drainage region that occurs under evergreen forest on steep limestone slopes in Southwest China and northern Vietnam. It is listed as endangered due to habitat loss and over-collecting for the ornamental plant trade, and only several populations remain. In this study, we assess the genetic variation, population structure, and phylogeography of C. multipinnata populations to help develop strategies for the conservation of the species. 60 individuals from six populations were used for chloroplast DNA (cpDNA) sequencing and 100 individuals from five populations were genotyped using 17 nuclear microsatellites. High genetic differentiation among populations was detected, suggesting that pollen or seed dispersal was restricted within populations. Two main genetic clusters were observed in both the cpDNA and microsatellite loci, corresponding to Yunnan China and northern Vietnam. These clusters indicated low levels of gene flow between the regions since their divergence in the late Pleistocene, which was inferred from both Bayesian and coalescent analysis. In addition, the result of a Bayesian skyline plot based on cpDNA portrayed a long history of constant population size followed by a decline in the last 50,000 years of C. multipinnata that was perhaps affected by the Quaternary glaciations, a finding that was also supported by the Garza-Williamson index calculated from the microsatellite data. The genetic consequences produced by climatic oscillations and anthropogenic disturbances are considered key pressures on C. multipinnata. To establish a conservation management plan, each population of C. multipinnata should be recognized as a Management Unit (MU). In situ and ex situ actions, such as controlling overexploitation and creating a germplasm bank with high genetic diversity, should be urgently implemented to preserve this species.     

Methods for simultaneous measurement of apoptosis and cell surface phenotype of epithelial cells in effusions by flow cytometry

We describe here a protocol for the detection of epithelial cells in effusions combined with quantification of apoptosis by flow cytometry (FCM). The procedure described consists of the following stages: culturing and induction of apoptosis by staurosporine in control ovarian carcinoma cell lines (SKOV-3 and OVCAR-8); preparation of effusion specimens and cell lines for staining; staining of cancer cells in effusions and cell lines for cell surface markers (Ber-EP4, EpCAM and CD45) and intracellular/nuclear markers of apoptosis (cleaved caspase-3 and caspase-8, and incorporated deoxyuridine triphosphates); and FCM analysis of stained cell lines and effusions. This protocol identifies a specific cell population in cytologically heterogeneous clinical specimens and applies two methods to measure different aspects of apoptosis in the cell population of interest. The cleaved caspase and deoxyuridine triphosphate incorporation FCM assays are run in parallel and require (including sample preparation, staining, instrument adjustment and data acquisition) 8 h. The culturing of cell lines requires 2-3 days and induction of apoptosis requires 16 h.     

Inducible ablation of melanopsin-expressing retinal ganglion cells reveals their central role in non-image forming visual responses

Rod/cone photoreceptors of the outer retina and the melanopsin-expressing retinal ganglion cells (mRGCs) of the inner retina mediate non-image forming visual responses including entrainment of the circadian clock to the ambient light, the pupillary light reflex (PLR), and light modulation of activity. Targeted deletion of the melanopsin gene attenuates these adaptive responses with no apparent change in the development and morphology of the mRGCs. Comprehensive identification of mRGCs and knowledge of their specific roles in image-forming and non-image forming photoresponses are currently lacking. We used a Cre-dependent GFP expression strategy in mice to genetically label the mRGCs. This revealed that only a subset of mRGCs express enough immunocytochemically detectable levels of melanopsin. We also used a Cre-inducible diphtheria toxin receptor (iDTR) expression approach to express the DTR in mRGCs. mRGCs develop normally, but can be acutely ablated upon diphtheria toxin administration. The mRGC-ablated mice exhibited normal outer retinal function. However, they completely lacked non-image forming visual responses such as circadian photoentrainment, light modulation of activity, and PLR. These results point to the mRGCs as the site of functional integration of the rod/cone and melanopsin phototransduction pathways and as the primary anatomical site for the divergence of image-forming and non-image forming photoresponses in mammals.     

New species of Ophiopogon,Peliosanthes and Tupistra (Asparagaceae s.l.) in the flora of Vietnam

Five new species named Peliosanthes aperta, P. elegans, P. kenhillii, Tupistra densiflora and T. patula are described and illustrated. These species are very local in distribution and endemic to northern or southern Vietnam. Two other species, Ophiopogon ogisui and Peliosanthes griffithii, are recorded as new to the flora of Vietnam. A key to the species of Tupistra occurring in Indochina and its neighboring regions is also provided.     

Friedolanostane, friedocycloartane and benzophenone constituents of the bark and leaves of Garcinia benthami

Friedolanostanes, (22Z,24E)-3β-acetoxy-9α-hydroxy-17,14-friedolanosta-14,22,24-trien-26-oic acid, (22Z,24E)-3β,9α-dihydroxy-17,14-friedolanosta-14,22,24-trien-26-oic acid, (22Z,24E)-9α-hydroxy-3-oxo-17,14-friedolanosta-14,22,24-trien-26-oic acid, a friedocycloartane, (22Z,24E)-3α-hydroxy-17,13-friedocycloarta-12,22,24-trien-26-oic acid, and a benzophenone, benthaphenone, together with known compounds (22Z,24E)-3α,9α-dihydroxy-17,13-friedolanosta-12,22,24-trien-26-oic acid, methyl (24E)-3α,23-dihydroxy-17,14-friedolanosta-8,14,24-trien-26-oate, glutinol, lupeol, and stigmasterol, were isolated from leaves and bark of Garcinia benthami. Their structures were elucidated using spectroscopic techniques, mainly 1-D and 2-D NMR spectroscopy, and chemical correlations.     

Existence of at least three distinct Alu subfamilies

Summary Computer-assisted sequence analysis of human Alu family members reveals that Alu repeats belong to one of at least three subfamilies. The insertion of human Alu repeats can be represented by three episodic bursts, each of which was founded by a distinct master sequence.