TY  - JOUR
A1  - Winck, Flavia Vischi
A1  - Kwasniewski, Miroslaw
A1  - Wienkoop, Stefanie
A1  - Müller-Röber, Bernd
T1  - An optimized method for the isolation of nuclei from chlamydomas Reinhardtii (Chlorophyceae)
JF  - Journal of phycology
N2  - The cell nucleus harbors a large number of proteins involved in transcription, RNA processing, chromatin remodeling, nuclear signaling, and ribosome assembly. The nuclear genome of the model alga Chlamydomonas reinhardtii P. A. Dang. was recently sequenced, and many genes encoding nuclear proteins, including transcription factors and transcription regulators, have been identified through computational discovery tools. However, elucidating the specific biological roles of nuclear proteins will require support from biochemical and proteomics data. Cellular preparations with enriched nuclei are important to assist in such analyses. Here, we describe a simple protocol for the isolation of nuclei from Chlamydomonas, based on a commercially available kit. The modifications done in the original protocol mainly include alterations of the differential centrifugation parameters and detergent-based cell lysis. The nuclei-enriched fractions obtained with the optimized protocol show low contamination with mitochondrial and plastid proteins. The protocol can be concluded within only 3 h, and the proteins extracted can be used for gel-based and non-gel-based proteomic approaches.
KW  - 2D gel electrophoresis
KW  - algae
KW  - Chlamydomonas
KW  - nuclear proteins
KW  - nucleus
KW  - proteomics
Y1  - 2011
U6  - https://doi.org/10.1111/j.1529-8817.2011.00967.x
SN  - 0022-3646
VL  - 47
IS  - 2
SP  - 333
EP  - 340
PB  - Wiley-Blackwell
CY  - Malden
ER  - 
TY  - JOUR
A1  - Wagner, Nicole D.
A1  - Hillebrand, Helmut
A1  - Wacker, Alexander
A1  - Frost, Paul C.
T1  - Nutritional indicators and their uses in ecology
JF  - Ecology letters
N2  - The nutrition of animal consumers is an important regulator of ecological processes due to its effects on their physiology, life-history and behaviour. Understanding the ecological effects of poor nutrition depends on correctly diagnosing the nature and strength of nutritional limitation. Despite the need to assess nutritional limitation, current approaches to delineating nutritional constraints can be non-specific and imprecise. Here, we consider the need and potential to develop new complementary approaches to the study of nutritional constraints on animal consumers by studying and using a suite of established and emerging biochemical and molecular responses. These nutritional indicators include gene expression, transcript regulators, protein profiling and activity, and gross biochemical and elemental composition. The potential applications of nutritional indicators to ecological studies are highlighted to demonstrate the value that this approach would have to future studies in community and ecosystem ecology.
KW  - Ecological stoichiometry
KW  - lipid profiling
KW  - metabolism
KW  - nutrient-stress
KW  - nutrition
KW  - proteomics
KW  - transcriptomics
Y1  - 2013
U6  - https://doi.org/10.1111/ele.12067
SN  - 1461-023X
VL  - 16
IS  - 4
SP  - 535
EP  - 544
PB  - Wiley-Blackwell
CY  - Hoboken
ER  - 
TY  - GEN
A1  - Witzel, Katja
A1  - Neugart, Susanne
A1  - Ruppel, Silke
A1  - Schreiner, Monika
A1  - Wiesner, Melanie
A1  - Baldermann, Susanne
T1  - Recent progress in the use of ‘omics technologies in brassicaceous vegetables
T2  - Frontiers in plant science
N2  - Continuing advances in 'omics methodologies and instrumentation is enhancing the understanding of how plants cope with the dynamic nature of their growing environment. 'Omics platforms have been only recently extended to cover horticultural crop species. Many of the most widely cultivated vegetable crops belong to the genus Brassica: these include plants grown for their root (turnip, rutabaga/swede), their swollen stem base (kohlrabi), their leaves (cabbage, kale, pak choi) and their inflorescence (cauliflower, broccoli). Characterization at the genome, transcript, protein and metabolite levels has illustrated the complexity of the cellular response to a whole series of environmental stresses, including nutrient deficiency, pathogen attack, heavy metal toxicity, cold acclimation, and excessive and sub optimal irradiation. This review covers recent applications of omics technologies to the brassicaceous vegetables, and discusses future scenarios in achieving improvements in crop end-use quality.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 429 
KW  - genomics
KW  - transcriptomics
KW  - metabolomics
KW  - proteomics
KW  - crop
KW  - microbiomics
Y1  - 2018
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-406479
ER  - 
TY  - JOUR
A1  - Witzel, Katja
A1  - Neugart, Susanne
A1  - Ruppel, Silke
A1  - Schreiner, Monika
A1  - Wiesner, Melanie
A1  - Baldermann, Susanne
T1  - Recent progress in the use of 'omics technologies in brassicaceous vegetables
JF  - Frontiers in plant science
N2  - Continuing advances in 'omics methodologies and instrumentation is enhancing the understanding of how plants cope with the dynamic nature of their growing environment. 'Omics platforms have been only recently extended to cover horticultural crop species. Many of the most widely cultivated vegetable crops belong to the genus Brassica: these include plants grown for their root (turnip, rutabaga/swede), their swollen stem base (kohlrabi), their leaves (cabbage, kale, pak choi) and their inflorescence (cauliflower, broccoli). Characterization at the genome, transcript, protein and metabolite levels has illustrated the complexity of the cellular response to a whole series of environmental stresses, including nutrient deficiency, pathogen attack, heavy metal toxicity, cold acclimation, and excessive and sub optimal irradiation. This review covers recent applications of omics technologies to the brassicaceous vegetables, and discusses future scenarios in achieving improvements in crop end-use quality.
KW  - genomics
KW  - transcriptomics
KW  - metabolomics
KW  - proteomics
KW  - crop
KW  - microbiomics
Y1  - 2015
U6  - https://doi.org/10.3389/fpls.2015.00244
SN  - 1664-462X
VL  - 6
PB  - Frontiers Research Foundation
CY  - Lausanne
ER  - 
TY  - JOUR
A1  - Christopher Ashwood, Wout Bittremieux
A1  - Bittremieux, Wout
A1  - Deutsch, Eric W.
A1  - Doncheva, Nadezhda T.
A1  - Dorfer, Viktoria
A1  - Gabriels, Ralf
A1  - Gorshkov, Vladimir
A1  - Gupta, Surya
A1  - Jones, Andrew R.
A1  - Käll, Lukas
A1  - Kopczynski, Dominik
A1  - Lane, Lydie
A1  - Lautenbacher, Ludwig
A1  - Legeay, Marc
A1  - Locard-Paulet, Marie
A1  - Mesuere, Bart
A1  - Sachsenberg, Timo
A1  - Salz, Renee
A1  - Samaras, Patroklos
A1  - Schiebenhoefer, Henning
A1  - Schmidt, Tobias
A1  - Schwämmle, Veit
A1  - Soggiu, Alessio
A1  - Uszkoreit, Julian
A1  - Van Den Bossche, Tim
A1  - Van Puyvelde, Bart
A1  - Van Strien, Joeri
A1  - Verschaffelt, Pieter
A1  - Webel, Henry
A1  - Willems, Sander
A1  - Perez-Riverolab, Yasset
A1  - Netz, Eugen
A1  - Pfeuffer, Julianus
T1  - Proceedings of the EuBIC-MS 2020 Developers’ Meeting
JF  - EuPA Open Proteomics
N2  - The 2020 European Bioinformatics Community for Mass Spectrometry (EuBIC-MS) Developers’ meeting was held from January 13th to January 17th 2020 in Nyborg, Denmark. Among the participants were scientists as well as developers working in the field of computational mass spectrometry (MS) and proteomics. The 4-day program was split between introductory keynote lectures and parallel hackathon sessions. During the latter, the participants developed bioinformatics tools and resources addressing outstanding needs in the community. The hackathons allowed less experienced participants to learn from more advanced computational MS experts, and to actively contribute to highly relevant research projects. We successfully produced several new tools that will be useful to the proteomics community by improving data analysis as well as facilitating future research. All keynote recordings are available on https://doi.org/10.5281/zenodo.3890181.
KW  - computational mass spectrometry
KW  - proteomics
KW  - bioinformatics
KW  - spectrum clustering
KW  - phosphoproteomics
KW  - XIC extraction
KW  - proteomics graph networks
KW  - predicted spectra
Y1  - 2020
U6  - https://doi.org/10.1016/j.euprot.2020.11.001
SN  - 2212-9685
VL  - 24
SP  - 1
EP  - 6
PB  - Elsevier
CY  - Amsterdam
ER  - 
TY  - JOUR
A1  - Kraus, Sara Milena
A1  - Mathew-Stephen, Mariet
A1  - Schapranow, Matthieu-Patrick
T1  - Eatomics
BT  - Shiny exploration of quantitative proteomics data
JF  - Journal of proteome research
N2  - Quantitative proteomics data are becoming increasingly more available, and as a consequence are being analyzed and interpreted by a larger group of users. However, many of these users have less programming experience. Furthermore, experimental designs and setups are getting more complicated, especially when tissue biopsies are analyzed. Luckily, the proteomics community has already established some best practices on how to conduct quality control, differential abundance analysis and enrichment analysis. However, an easy-to-use application that wraps together all steps for the exploration and flexible analysis of quantitative proteomics data is not yet available. For Eatomics, we utilize the R Shiny framework to implement carefully chosen parts of established analysis workflows to (i) make them accessible in a user-friendly way, (ii) add a multitude of interactive exploration possibilities, and (iii) develop a unique experimental design setup module, which interactively translates a given research hypothesis into a differential abundance and enrichment analysis formula. In this, we aim to fulfill the needs of a growing group of inexperienced quantitative proteomics data analysts. Eatomics may be tested with demo data directly online via https://we.analyzegenomes.com/now/eatomics/or with the user's own data by installation from the Github repository at https://github.com/Millchmaedchen/Eatomics.
KW  - R Shiny
KW  - application
KW  - label-free
KW  - proteomics
KW  - analysis
KW  - differential
KW  - abundance
KW  - experimental design
Y1  - 2021
U6  - https://doi.org/10.1021/acs.jproteome.0c00398
SN  - 1535-3893
SN  - 1535-3907
VL  - 20
IS  - 1
SP  - 1070
EP  - 1078
PB  - American Chemical Society
CY  - Washington
ER  - 
TY  - JOUR
A1  - Omolaoye, Temidayo S.
A1  - Omolaoye, Victor Adelakun
A1  - Kandasamy, Richard K.
A1  - Hachim, Mahmood Yaseen
A1  - Du Plessis, Stefan S.
T1  - Omics and male infertility
BT  - highlighting the application of transcriptomic data
JF  - Life : open access journal
N2  - Male infertility is a multifaceted disorder affecting approximately 50% of male partners in infertile couples. 
Over the years, male infertility has been diagnosed mainly through semen analysis, hormone evaluations, medical records and physical examinations, which of course are fundamental, but yet inefficient, because 30% of male infertility cases remain idiopathic. This dilemmatic status of the unknown needs to be addressed with more sophisticated and result-driven technologies and/or techniques. 
Genetic alterations have been linked with male infertility, thereby unveiling the practicality of investigating this disorder from the "omics" perspective. 
Omics aims at analyzing the structure and functions of a whole constituent of a given biological function at different levels, including the molecular gene level (genomics), transcript level (transcriptomics), protein level (proteomics) and metabolites level (metabolomics). In the current study, an overview of the four branches of omics and their roles in male infertility are briefly discussed; the potential usefulness of assessing transcriptomic data to understand this pathology is also elucidated. 
After assessing the publicly obtainable transcriptomic data for datasets on male infertility, a total of 1385 datasets were retrieved, of which 10 datasets met the inclusion criteria and were used for further analysis. 
These datasets were classified into groups according to the disease or cause of male infertility. 
The groups include non-obstructive azoospermia (NOA), obstructive azoospermia (OA), non-obstructive and obstructive azoospermia (NOA and OA), spermatogenic dysfunction, sperm dysfunction, and Y chromosome microdeletion. 
Findings revealed that 8 genes (LDHC, PDHA2, TNP1, TNP2, ODF1, ODF2, SPINK2, PCDHB3) were commonly differentially expressed between all disease groups. 
Likewise, 56 genes were common between NOA versus NOA and OA (ADAD1, BANF2, BCL2L14, C12orf50, C20orf173, C22orf23, C6orf99, C9orf131, C9orf24, CABS1, CAPZA3, CCDC187, CCDC54, CDKN3, CEP170, CFAP206, CRISP2, CT83, CXorf65, FAM209A, FAM71F1, FAM81B, GALNTL5, GTSF1, H1FNT, HEMGN, HMGB4, KIF2B, LDHC, LOC441601, LYZL2, ODF1, ODF2, PCDHB3, PDHA2, PGK2, PIH1D2, PLCZ1, PROCA1, RIMBP3, ROPN1L, SHCBP1L, SMCP, SPATA16, SPATA19, SPINK2, TEX33, TKTL2, TMCO2, TMCO5A, TNP1, TNP2, TSPAN16, TSSK1B, TTLL2, UBQLN3). 
These genes, particularly the above-mentioned 8 genes, are involved in diverse biological processes such as germ cell development, spermatid development, spermatid differentiation, regulation of proteolysis, spermatogenesis and metabolic processes. 
Owing to the stage-specific expression of these genes, any mal-expression can ultimately lead to male infertility. 
Therefore, currently available data on all branches of omics relating to male fertility can be used to identify biomarkers for diagnosing male infertility, which can potentially help in unravelling some idiopathic cases.
KW  - male infertility
KW  - omics
KW  - genomics
KW  - transcriptomics
KW  - proteomics
KW  - metabolomics
Y1  - 2022
U6  - https://doi.org/10.3390/life12020280
SN  - 2075-1729
VL  - 12
IS  - 2
PB  - MDPI
CY  - Basel
ER  - 
TY  - THES
A1  - Schlossarek, Dennis
T1  - Identification of dynamic protein-metabolite complexes in saccharomyces cerevisiae using co-fractionation mass spectrometry
T1  - Identifikation von dynamischen Protein-Metabolit Komplexes in Saccharomyces cerevisiae unter Nutzung der Co-Fraktionierungs Massenspektrometrie
N2  - Cells are built from a variety of macromolecules and metabolites. Both, the proteome and the metabolome are highly dynamic and responsive to environmental cues and developmental processes. But it is not their bare numbers, but their interactions that enable life. The protein-protein (PPI) and protein-metabolite interactions (PMI) facilitate and regulate all aspects of cell biology, from metabolism to mitosis. Therefore, the study of PPIs and PMIs and their dynamics in a cell-wide context is of great scientific interest. In this dissertation, I aim to chart a map of the dynamic PPIs and PMIs across metabolic and cellular transitions. As a model system, I study the shift from the fermentative to the respiratory growth, known as the diauxic shift, in the budding yeast Saccharomyces cerevisiae. To do so, I am applying a co-fractionation mass spectrometry (CF-MS) based method, dubbed protein metabolite interactions using size separation (PROMIS). PROMIS, as well as comparable methods, will be discussed in detail in chapter 1. 
Since PROMIS was developed originally for Arabidopsis thaliana, in chapter 2, I will describe the adaptation of PROMIS to S. cerevisiae. Here, the obtained results demonstrated a wealth of protein-metabolite interactions, and experimentally validated 225 previously predicted PMIs. Applying orthogonal, targeted approaches to validate the interactions of a proteogenic dipeptide, Ser-Leu, five novel protein-interactors were found. One of those proteins, phosphoglycerate kinase, is inhibited by Ser-Leu, placing the dipeptide at the regulation of glycolysis.
In chapter 3, I am presenting PROMISed, a novel web-tool designed for the analysis of PROMIS- and other CF-MS-datasets. Starting with raw fractionation profiles, PROMISed enables data pre-processing, profile deconvolution, scores differences in fractionation profiles between experimental conditions, and ultimately charts interaction networks. PROMISed comes with a user-friendly graphic interface, and thus enables the routine analysis of CF-MS data by non-computational biologists.
Finally, in chapter 4, I applied PROMIS in combination with the isothermal shift assay to the diauxic shift in S. cerevisiae to study changes in the PPI and PMI landscape across this metabolic transition. I found a major rewiring of protein-protein-metabolite complexes, exemplified by the disassembly of the proteasome in the respiratory phase, the loss of interaction of an enzyme involved in amino acid biosynthesis and its cofactor, as well as phase and structure specific interactions between dipeptides and enzymes of central carbon metabolism.
In chapter 5, I am summarizing the presented results, and discuss a strategy to unravel the potential patterns of dipeptide accumulation and binding specificities. Lastly, I recapitulate recently postulated guidelines for CF-MS experiments, and give an outlook of protein interaction studies in the near future.
N2  - Die Zelle besteht aus einer Vielzahl von großen und kleinen Molekülen, und sowohl das Proteom als auch das Metabolom passen sich dynamisch den vorherrschenden Umweltbedingungen oder zellulären Anforderungen an. Allerdings ist es nicht die bloße Menge an biologischen Molekülen, sondern deren Interaktionen miteinander, die das Leben erst ermöglichen. Protein-Protein (PPI) und Protein-Metabolit Interaktionen (PMI) vollbringen und regulieren alle Aspekte der Zelle, vom Stoffwechsel bis zur Mitose. Die Studie dieser Interaktionen ist daher von fundamentalem wissenschaftlichem Interesse. In dieser Dissertation strebe ich an, eine Karte der Protein-Protein und Protein-Metabolit Interaktionen zu zeichnen, die den Übergang vom fermentativen zum respiratioschen Stoffwechsel in der Hefe Saccharomyces cerevisiae umfasst. Zu diesem Zweck nutze ich PROMIS (egl. protein metabolite interactions using size separation), eine auf der co-Fraktionierungs Massensprektrometrie (CF-MS) aufbauende Methode. PROMIS, und ähnliche Methoden zur Untersuchung von Protein-Interkationen, werden ausgiebig in Kapitel 1 vorgestellt.
Da PROMIS ursprünglich für die Modellpflanze Arabadopsis thaliana entwickelt wurde, beschreibe ich in Kapitel 2 zunächst die erste Anwendung der Methode in S. cerevisiae. Die Ergebnisse stellen eine Fülle an Protein-Metabolit Interaktionen dar, und 225 zuvor prognostizierte Interaktionen wurden das erste Mal experimentell beschrieben. Mit Hilfe orthogonaler Methoden wurde außerdem eine inhibitorische Interaktion zwischen dem proteinogenen Dipeptid Ser-Leu und einem Enzym der Glykolyse gefunden.
In Kapitel 3 präsentiere ich PROMISed, eine neue Web-Anwendung zur Auswertung von Daten von PROMIS oder anderen CF-MS Experimente. PROMISed kann genutzt werden um in rohen Fraktionierungs-Profile lokale Maxima zu finden, aus denen ein Interaktions-Netzwerk basierend auf Korrelationen erstellt wird. Außerdem kann die Anwendung Unterschiede in den Profilen zwischen verschiedenen experimentellen Bedingungen bewerten. PROMISed umfasst eine benutzerfreundliche grafische Oberfläche und bedarf daher keiner Programmierkenntnisse zur Nutzung.
In Kapitel 4 benutze ich schließlich PROMIS und ItSA (engl. isothermal shift assay) um PPI und PMI während des Übergangs vom fermentativen zum respiratorischen Stoffwechsel in Hefe zu untersuchen. Hier beschreibe ich eine zellweite Umbildung der Protein-Metabolit-Komplexe, bespielhaft beschrieben anhand des Auseinanderfallens des Proteasoms im respiratorischen Stoffwechsel, des Verlustes der Interaktion zwischen einem Enzym des Aminosäure Stoffwechsels mit seinem Cofaktor und spezifischen Interaktionen zwischen Dipeptiden und Enzymen des zentralen Stoffwechsels.
In Kapitel 5 fasse ich die gefundenen Ergebnisse zusammen und stelle eine Strategie zur Untersuchung der Spezifität sowohl der Bildung als auch der Protein-Interaktionen von Dipeptiden vor. Zu aller letzt rekapituliere ich Richtlinien für CF-MS Experimente und gebe einen Ausblick auf die nahe Zukunft der Studien der Protein-Interkationen.
KW  - Protein
KW  - Metabolit
KW  - Interaktion
KW  - Interaktions Netzwerk
KW  - Stoffwechsel
KW  - Saccharomyces cerevisiae
KW  - protein
KW  - metabolite
KW  - interaction
KW  - interaction network
KW  - metabolism
KW  - saccharomyces cerevisiae
KW  - interactomics
KW  - proteomics
KW  - metabolomics
Y1  - 2023
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-582826
ER  -