Molecular markers of the mitochondrial genomes of Isopoda and implications on the phylogeny of Peracarida (Crustacea: Malacostraca)

The mitochondrial genome features structural and organizational characters, also referred to as characters of ‘genome morphology’, in addition to primary sequence data. This thesis analyzes the state, evolution, and phylogenetic value of these characters in peracarid crustaceans, with the focus on Isopoda and putative isopod sister group taxa (Amphipoda, Cumacea). Therefore, eight complete or almost complete isopod mt genomes were sequenced, as well as an entire amphipod mt genome and about half of a cumacean mt genome. The comparison revealed several significant changes of character states of the mtDNA (mitochondrial gene order, nucleotide strand bias, tRNA secondary structure etc.). These characters were mapped on a molecular tree of isopods to trace the sequence of changes and to evaluate their phylogenetic significance. It is striking that gene arrangements differ in all examined mt genomes. However, several derived gene positions are shared among isopods, which even allow inferences on the gene order of the isopod ancestor (isopod ground pattern). There are also indications that the Cumacea share main rearrangements with isopods. This is not the case for the Amphipoda, which therefore do not qualify as the isopod sister group. Although there are also indices on rare homoplasious translocation events of tRNA genes in isopods, gene order changes can be overall evaluated as phylogenetically informative characters. This applies particularly to complex rearrangements comprising protein-coding and rRNA genes, which are unlikely to emerge by convergent evolution. The overall frequency of rearrangements appears to be higher in the examined species than usually assumed for mt genomes, but is still far from saturation. The diversity in gene order should be also valuable for inferring phylogenetic relationships of closer related isopod or peracarid species. In some cases it is even possible to infer the mechanism of a translocation event, e.g. inversion by intramolecular recombination or translocation by remolding of tRNA genes. Another rare and complex character, a bias in the nucleotide composition of DNA strands, is shared by the Asellota and most other crustaceans, but is reversed in the majority of Isopoda. This finding is contrary to the position of the Phreatoicidea being the sister group to all other isopods e.g. proposed by the sequence analysis

The complete mitochondrial genome of the common sea slater, Ligia oceanica (Crustacea, Isopoda) bears a novel gene order and unusual control region features

BACKGROUND: Sequence data and other characters from mitochondrial genomes (gene translocations, secondary structure of RNA molecules) are useful in phylogenetic studies among metazoan animals from population to phylum level. Moreover, the comparison of complete mitochondrial sequences gives valuable information about the evolution of small genomes, e.g. about different mechanisms of gene translocation, gene duplication and gene loss, or concerning nucleotide frequency biases. The Peracarida (gammarids, isopods, etc.) comprise about 21,000 species of crustaceans, living in many environments from deep sea floor to arid terrestrial habitats. Ligia oceanica is a terrestrial isopod living at rocky seashores of the european North Sea and Atlantic coastlines. RESULTS: The study reveals the first complete mitochondrial DNA sequence from a peracarid crustacean. The mitochondrial genome of Ligia oceanica is a circular double-stranded DNA molecule, with a size of 15,289 bp. It shows several changes in mitochondrial gene order compared to other crustacean species. An overview about mitochondrial gene order of all crustacean taxa yet sequenced is also presented. The largest non-coding part (the putative mitochondrial control region) of the mitochondrial genome of Ligia oceanica is unexpectedly not AT-rich compared to the remainder of the genome. It bears two repeat regions (4× 10 bp and 3× 64 bp), and a GC-rich hairpin-like secondary structure. Some of the transfer RNAs show secondary structures which derive from the usual cloverleaf pattern. While some tRNA genes are putative targets for RNA editing, trnR could not be localized at all. CONCLUSION: Gene order is not conserved among Peracarida, not even among isopods. The two isopod species Ligia oceanica and Idotea baltica show a similarly derived gene order, compared to the arthropod ground pattern and to the amphipod Parhyale hawaiiensis, suggesting that most of the translocation events were already present the last common ancestor of these isopods. Beyond that, the positions of three tRNA genes differ in the two isopod species. Strand bias in nucleotide frequency is reversed in both isopod species compared to other Malacostraca. This is probably due to a reversal of the replication origin, which is further supported by the fact that the hairpin structure typically found in the control region shows a reversed orientation in the isopod species, compared to other crustaceans

DOT1L promotes progenitor proliferation and primes neuronal layer identity in the developing cerebral cortex

Cortical development is controlled by transcriptional programs, which are orchestrated by transcription factors. Yet, stable inheritance of spatiooral activity of factors influencing cell fate and localization in different layers is only partly understood. Here we find that deletion of Dot1l in the murine telencephalon leads to cortical layering defects, indicating DOT1L activity and chromatin methylation at H3K79 impact on the cell cycle, and influence transcriptional programs conferring upper layer identity in early progenitors. Specifically, DOT1L prevents premature differentiation by increasing expression of genes that regulate asymmetric cell division (Vangl2, Cenpj). Loss of DOT1L results in reduced numbers of progenitors expressing genes including SoxB1 gene family members. Loss of DOT1L also leads to altered cortical distribution of deep layer neurons that express either TBR1, CTIP2 or SOX5, and less activation of transcriptional programs that are characteristic for upper layer neurons (Satb2, Pou3f3, Cux2, SoxC family members). Data from three different mouse models suggest that DOT1L balances transcriptional programs necessary for proper neuronal composition and distribution in the six cortical layers. Furthermore, because loss of DOT1L in the pre-neurogenic phase of development impairs specifically generation of SATB2-expressing upper layer neurons, our data suggest that DOT1L primes upper layer identity in cortical progenitors.Fil: Franz, Henriette. Universität Freiburg Im Breisgau; AlemaniaFil: Villarreal, Alejandro. Universität Freiburg Im Breisgau; Alemania. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Houssay. Instituto de Biología Celular y Neurociencia "Prof. Eduardo de Robertis". Universidad de Buenos Aires. Facultad de Medicina. Instituto de Biología Celular y Neurociencia; ArgentinaFil: Heidrich, Stefanie. Universität Freiburg Im Breisgau; AlemaniaFil: Videm, Pavankumar. Universität Freiburg Im Breisgau; AlemaniaFil: Kilpert, Fabian. Max Planck Institute Of Immunobiology And Epigenetics; AlemaniaFil: Mestres, Ivan. Technical University Dresden; AlemaniaFil: Calegari, Federico. Technical University Dresden; AlemaniaFil: Backofen, Rolf. Universidad de Copenhagen; Dinamarca. Universität Freiburg Im Breisgau; AlemaniaFil: Manke, Thomas. Max Planck Institute Of Immunobiology And Epigenetics; AlemaniaFil: Vogel, Tanja. Universität Freiburg Im Breisgau; Alemani

EOMES and IL-10 regulate antitumor activity of T regulatory type 1 CD4 + T cells in chronic lymphocytic leukemia

The transcription factor eomesodermin (EOMES) promotes interleukin (IL)-10 expression in CD4(+) T cells, which has been linked to immunosuppressive and cytotoxic activities. We detected cytotoxic, programmed cell death protein-1 (PD-1) and EOMES co-expressing CD4(+) T cells in lymph nodes (LNs) of patients with chronic lymphocytic leukemia (CLL) or diffuse large B-cell lymphoma. Transcriptome and flow cytometry analyses revealed that EOMES does not only drive IL-10 expression, but rather controls a unique transcriptional signature in CD4(+) T cells, that is enriched in genes typical for T regulatory type 1 (T(R)1) cells. The T(R)1 cell identity of these CD4(+) T cells was supported by their expression of interferon gamma and IL-10, as well as inhibitory receptors including PD-1. T(R)1 cells with cytotoxic capacity accumulate also in Eµ-TCL1 mice that develop CLL-like disease. Whereas wild-type CD4(+) T cells control TCL1 leukemia development after adoptive transfer in leukopenic Rag2(−/)(−) mice, EOMES-deficient CD4(+) T cells failed to do so. We further show that T(R)1 cell-mediated control of TCL1 leukemia requires IL-10 receptor (IL-10R) signaling, as Il10rb-deficient CD4(+) T cells showed impaired antileukemia activity. Altogether, our data demonstrate that EOMES is indispensable for the development of IL-10-expressing, cytotoxic T(R)1 cells, which accumulate in LNs of CLL patients and control TCL1 leukemia in mice in an IL-10R-dependent manner

Pathophysiological subtypes of Alzheimer's disease based on cerebrospinal fluid proteomics.

Alzheimer's disease is biologically heterogeneous, and detailed understanding of the processes involved in patients is critical for development of treatments. CSF contains hundreds of proteins, with concentrations reflecting ongoing (patho)physiological processes. This provides the opportunity to study many biological processes at the same time in patients. We studied whether Alzheimer's disease biological subtypes can be detected in CSF proteomics using the dual clustering technique non-negative matrix factorization. In two independent cohorts (EMIF-AD MBD and ADNI) we found that 705 (77% of 911 tested) proteins differed between Alzheimer's disease (defined as having abnormal amyloid, n = 425) and controls (defined as having normal CSF amyloid and tau and normal cognition, n = 127). Using these proteins for data-driven clustering, we identified three robust pathophysiological Alzheimer's disease subtypes within each cohort showing (i) hyperplasticity and increased BACE1 levels; (ii) innate immune activation; and (iii) blood-brain barrier dysfunction with low BACE1 levels. In both cohorts, the majority of individuals were labelled as having subtype 1 (80, 36% in EMIF-AD MBD; 117, 59% in ADNI), 71 (32%) in EMIF-AD MBD and 41 (21%) in ADNI were labelled as subtype 2, and 72 (32%) in EMIF-AD MBD and 39 (20%) individuals in ADNI were labelled as subtype 3. Genetic analyses showed that all subtypes had an excess of genetic risk for Alzheimer's disease (all P > 0.01). Additional pathological comparisons that were available for a subset in ADNI suggested that subtypes showed similar severity of Alzheimer's disease pathology, and did not differ in the frequencies of co-pathologies, providing further support that found subtypes truly reflect Alzheimer's disease heterogeneity. Compared to controls, all non-demented Alzheimer's disease individuals had increased risk of showing clinical progression (all P < 0.01). Compared to subtype 1, subtype 2 showed faster clinical progression after correcting for age, sex, level of education and tau levels (hazard ratio = 2.5; 95% confidence interval = 1.2, 5.1; P = 0.01), and subtype 3 at trend level (hazard ratio = 2.1; 95% confidence interval = 1.0, 4.4; P = 0.06). Together, these results demonstrate the value of CSF proteomics in studying the biological heterogeneity in Alzheimer's disease patients, and suggest that subtypes may require tailored therapy

Dickkopf-1 Overexpression in vitro Nominates Candidate Blood Biomarkers Relating to Alzheimer's Disease Pathology

Previous studies suggest that Dickkopf-1 (DKK1), an inhibitor of Wnt signaling, plays a role in amyloid-induced toxicity and hence Alzheimer's disease (AD). However, the effect of DKK1 expression on protein expression, and whether such proteins are altered in disease, is unknown. We aim to test whether DKK1 induced protein signature obtained in vitro were associated with markers of AD pathology as used in the amyloid/tau/neurodegeneration (ATN) framework as well as with clinical outcomes. We first overexpressed DKK1 in HEK293A cells and quantified 1,128 proteins in cell lysates using aptamer capture arrays (SomaScan) to obtain a protein signature induced by DKK1. We then used the same assay to measure the DKK1-signature proteins in human plasma in two large cohorts, EMIF (n = 785) and ANM (n = 677). We identified a 100-protein signature induced by DKK1 in vitro. Subsets of proteins, along with age and apolipoprotein E ɛ 4 genotype distinguished amyloid pathology (A + T-N-, A+T+N-, A+T-N+, and A+T+N+) from no AD pathology (A-T-N-) with an area under the curve of 0.72, 0.81, 0.88, and 0.85, respectively. Furthermore, we found that some signature proteins (e.g., Complement C3 and albumin) were associated with cognitive score and AD diagnosis in both cohorts. Our results add further evidence for a role of DKK regulation of Wnt signaling in AD and suggest that DKK1 induced signature proteins obtained in vitro could reflect theATNframework as well as predict disease severity and progression in vivo

Alignancer

Alignancer is a tool for alignment enhancing. It is performing additional alignments on masked sections of hmmalign (HMMER 3.0) multiple alignments. ClustalW (default) or Muscle is being utilized to automatically align all sections which were not covered by a profile HMM and therefore were not aligned. In using additional aligners to complement hmmalign, compulsory loss of information may be avoided keeping the entire alignment for subsequent analyses, e.g. the calculation of phylogenetic trees

Phylogenetic assignment of amplicon pyrosequences

Placement of environmental sequences upon a reference phylogeny has been the "gold standard" method for taxonomic assignment of Sanger sequences. More recently, pyrosequencing technology has largely replaced Sanger methods in environmental DNA sequencing studies. Phylogenetic placement methods, as practiced earlier, became impractical with the data set sizes produced by pyrosequencing. Accordingly, variations of a workflow consisting of sequence clustering and taxonomic assignment based on k-mer statistics or pairwise alignment found widespread application. There are still reasons why read-by-read phylogenetic placement is expected to be superior to these methods though. In order to make this practicable for a large 16S rDNA V1 pyrosequencing data set consisting of about 2 million reads, we developed a software pipeline for the alignment and phylogenetic placement of large numbers of marker sequences. I will introduce this tool and illustrate it with results of our analyses of temporal patterns of SAR11 ecotype distributions at the Bermuda Atlantic Time Series site

Multiple rearrangements in mitochondrial genomes of Isopoda and phylogenetic implications

In this study, we analyse the evolutionary dynamics and phylogenetic implications of gene order rear- rangements in five newly sequenced mitochondrial (mt) genomes and four published mt genomes of isopod crustaceans. The sequence coverage is nearly complete for four of the five newly sequenced spe- cies, with only the control region and some tRNA genes missing, while in Janira maculosa only two thirds of the genome could be determined. Mitochondrial gene order in isopods seems to be more plastic than that in other crustacean lineages, making all nine known mt gene orders different. Especially the asellote Janira is characterized by many autapomorphies. The following inferred ancestral isopod mt gene order exists slightly modified in modern isopods: nad1, tnrL1, rrnS, control region, trnS1, cob, trnT, nad5, trnF. We consider the inferred gene translocation events leading to gene rearrangements as valuable charac- ters in phylogenetic analyses. In this first study covering major isopod lineages, potential apomorphies were identified, e.g., a shared relative position of trnR in Valvifera. We also report one of the first findings of homoplasy in mitochondrial gene order, namely a shared relative position of trnV in unrelated isopod lineages. In addition to increased taxon sampling secondary structure, modification in tRNAs and GC-skew inversion may be potentially fruitful subjects for future mt genome studies in a phylogenetic context