Effect of forests structure and small-scale environmental conditions on the community of epigeic arthropods (Carabidae, Araneae)

Ziesche, Tim

12 April 2016

Forests are more than a stand of trees in the landscape. They represent a complex, functional system of interacting and often interdependent biological, physical and chemical components (Kimmins 1997). In the past, complex interactions were increasingly recognized over time as food webs, abiotic processes and biotic feedbacks since then defined as the forest ecosystem. Trees grow in a world of multitrophic interactions (van der Putten et al. 2001). One component of this functional system is represented in several aspects by spiders and insects, as they contribute considerably to the biodiversity and ecosystem functioning in forest habitats (Watt et al. 1997). There is knowledge on the community composition of several forests of different stand type or tree species composition referring to soil dwelling arthropods. Moreover, studies often highlight the orientation of single arthropod species on abiotic factors or the composition of species assemblages in case studies; these represent ecologically well described groups that can be used as indicators of habitat quality (Pearce and Venier 2006; Cardoso et al. 2004). Evidence on the scale of interactions between the species and their environment are rare. This applies particularly to examples based on fine spatial and temporal scales.:Zusammenfassung 1 Summary 4 Chapter 1 General Introduction 7-19 1.1 Arthropods as a permanent component of forest ecosystems 7 1.2 Spiders and carabids in forest ecosystems 10 1.3 Are spiders and carabids in ecosystems dispensable? – functional diversity in natural antagonists 13 1.4 Objectives 20 Chapter 2 Influence of environmental parameters on small-scale distribution of soil-dwelling spiders in forests: what makes the difference, tree species or microhabitat? 23 2.1 Abstract 23 2.2 Introduction 24 2.3 Methods and materials 25 2.4 Results 32 2.5 Discussion 45 2.6 Conclusions 51 Chapter 3 Microhabitat heterogeneity in temperate forests: is distance to stems affecting ground-dwelling spider communities? 61 3.1 Abstract 61 3.2 Introduction 62 3.3 Materials and Methods 63 3.4 Results 68 3.5 Discussion 77 Chapter 4 The impacts of seasonality, forest type and succession on the community structure of temperate-forest ground beetles. 88 4.1 Abstract 88 4.2 Introduction 90 4.3 Methods and materials 92 4.4 Results 98 4.5 Discussion 113 4.6 Conclusions 120 Chapter 5 Is the age of forest habitats affecting the reproductive rate of generalist predatory ground beetle species? 129 5.1 Abstract 129 5.2 Introduction 131 5.3 Methods and materials 133 5.4 Results 138 5.5 Discussion 150 5.6 Conclusions 153 Chapter 6 General Discussion 161 6.1 Management effect 169 6.2 Future prospect 170 Liste der Veröffentlichtungen 173-174 Danksagung

info:eu-repo/classification/ddc/630

ddc:630

Permeability of fluorescently labelled proteins in silk-based skin equivalent

Chumpitaz Chavez, Gabriel

January 2021

Development of methods for studying drug delivery systems is of great significance for the improvement of topical formulations. Active compounds for topical drug delivery are often formulated into gels and creams, that can be applied onto skin surfaces. It is important to know the extent of the permeability of the active compounds, in order to determine the medical effect. This study examines the possibilities of using an animal-free skin equivalent for penetration and permeation experiments, i.e. a silk scaffold integrated with viable human dermaland epidermal cells. Mammalian cell culturing together with silkconstruct formation, constituted the upstream bioprocess and acquisition of the skin equivalents. Permeability of fluorescently labelled Bovine Serum Albumin and Sodium Fluorescein salt was assessed, using a Franz- cell setup incorporated with the skin equivalents. Furthermore, fluorescence analysis and SDS-PAGE was performed on the collected samples, along with cryosectioning and image analysis of the skin equivalents. The results indicate variations in tissue integrity, leading to both high and low permeability. Fluorescence intensity can be correlated with the amount of sample liquid passing through. The model is still under development, hence more research is needed to draw a conclusion regarding the cellular composition of the skin equivalents, and how it influences permeability. / NextBioForm

skin equivalent

recombinant spider silk

fibroblasts

keratinocytes

permeability

Franz cells

fluorescence

bovine serum albumin

sodium fluorescein salt

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Multitrophic impacts of an emerging invasive plant

Roberson, Elizabeth J.

28 August 2018

No description available.

Biology

Conservation

Ecology

Entomology

Environmental Science

Plant Biology

invasive plants

invasion

enemy release

novel weapons

community dynamics

arthropod

spider

white-tailed deer

Identification of changes in biomarkers relevant for breast cancer biology occurring in a novel 3D-Biosilk model

Ståhl, Emmy

January 2021

Bröstcancer är den vanligaste formen av cancer som drabbar kvinnor. Det är en heterogen och komplex sjukdom som består av flera undergrupper, var och en med distinkt morfologi och kliniska implikationer [1]. För att modellera och studera cellbiologi, vävnadsmorfologi, molekylära mekanismer och läkemedels effekter används cellkulturer [2]. Idag är tvådimensionella (2D) modeller fortfarande den mest använda metoden för att odla celler in vitro [3]. En nackdel med 2D-modeller är att mikromiljön i dessa modeller inte imiterar in vivo strukturen av tumörer och vävnader, då de saknar tre dimensionella (3D) cell-cell och cellextracellulär matrix (ECM) interaktioner [2]. På grund av nackdelarna med 2D-modeller, har 3D-modeller blivit mer intressanta som alternativ för att lösa behovet av en pålitlig preklinisk modell för läkemedelstestning och för studier av cancerbiologi. För att utveckla ett redskap som är relevant för cancerforskning etablerar professor My Hedhammars laboratorium en 3D-modell av bröstcancer. I en sådan ny modell används Biosilk som byggnadsställning för att odla odödliga cellinjer som är representativa för de tre huvudklasserna av bröstcancer (i.e. MCF-7 (luminal-lik), SKBR-3 (HER2-överuttryckt) och MDAMB- 231 (trippel-negativ)). Eftersom transkriptions signaturer kan användas för att klassificera och studera bröstcancer är det viktigt att undersöka om och hur tillväxt i 3D-Biosilk kan påverka genuttrycksprofiler. Hypotesen som testades i denna studie var om cellkulturer i 3DBiosilk kan ha signifikanta skillnader i uttryck av biomarkörer, relevanta för bröstcancerbiologi, vid jämförelse av samma cellinje kultiverad i 2D. För att testa detta utvärderades kvalitén och reproducerbarheten av 3D-Biosilk konstruktionen med hjälp av olika kvalitetstester. Strukturen granskades med brightfield mikroskopi, arean av konstruktionen mättes med ImageJ, infärgning med phalloidin bekräftade cellnärvaro och cellvidhäftning till modellen. Alamar blue utfördes för att bedöma den cellulära metaboliska aktiviteten i modellen. Förändringarna av målgenernas genuttryck undersöktes med kvantitativ omvänd transkription PCR (RT-qPCR) och detta påvisade en statistiskt signifikant skillnad i genuttrycket beroende på om cellerna odlats i 2D- eller 3D-Biosilk modeller. I cellinje MDA-MB-231 hittades tre gener, i cellinje SKBR-3 hittades två gener och i cellinje MCF-7 hittades fyra gener. Genuttrycket för en av dessa gener i cellinje MCF-7, som var kultiverad i 3D-Biosilk, var nedreglerad (i.e. ZO-1). Detta kunde valideras på proteinnivå med immunofluorescens. Sammanfattningsvis, celler odlade i 3D-Biosilk visar på en mer aggressiv fenotyp. / Breast cancer is the most common cancer among women. It is a heterogenous and complex disease composed of several subtypes, each with distinct morphological and clinical implications [1]. To model and study cell biology, tissue morphology, molecular mechanisms and drug actions, cell cultures are canonically used [2]. Today two-dimensional (2D) models are still widely the preferred method for culturing cells in vitro [3]. A drawback with 2D models is that the microenvironment in these models does not mimic the in vivo structure of tumors and tissues, lacking three-dimensional (3D) cell-cell and cell-extracellular matrix (ECM) interactions [2]. Due to the disadvantages of 2D models, 3D cultures have become an increasingly interesting alternative to solve the need for a reliable preclinical model for drug testing and the study of cancer biology. To develop a relevant tool for cancer research, the laboratory of professor My Hedhammar is currently establishing a 3D model of breast cancer. In such novel model, Biosilk is used as scaffold to grow immortalized cell lines representative of the three major classes of breast cancer (i.e. MCF-7 (luminal-like), SKBR-3 (HER2-overexpression) and MDA-MB-231 (triplenegative)). Since transcriptional signatures can be used to classify and study breast cancers, it is important to investigate if and how growth in 3D-Biosilk can impact gene expression profiles. The hypothesis tested in this study was that cells cultured in 3D-Biosilk have differences in expression of biomarkers relevant to breast cancer biology, when compared to the same cell lines cultured in 2D. To examine this, 3D-Biosilk models were created and evaluated to ensure their quality and reproducibility, for instance, the scaffold structure was monitored by brightfield microscopy, the construct’s area was measured with ImageJ, staining with phalloidin confirmed the presence of cells as well as their attachment to the construct, and Alamar blue was used to assess the cellular metabolic activity. Differences in gene expression of target genes were investigated using reverse transcription quantitative PCR (RTqPCR), which revealed statistically significant changes depending on whether the cells were cultivated in 2D or a 3D-Biosilk model. For cell line MDA-MB-231 three genes were found, for SKBR-3 two genes were found and for MCF-7 four genes were found. The expression of one gene which was found downregulated in MCF-7 cultured in 3D-Biosilk (i.e. ZO-1) was validated at protein level by immunofluorescence. In conclusion, cultivating cells in 3D-Biosilk indicates a more aggressive phenotype.

3D-Biosilk

breast cancer

3D cell culture

recombinant spider silk

ZO-1

3D-Biosilk

bröstcancer

3D cellkultur

rekombinant spindeltråd

ZO-1

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

The state of network research / Tillståndet för nätverksforskning

Zhu, Haoyu

January 2020

In the past decades, networking researchers experienced great changes. Being familiar with the development of networking researches is the first step for most scholars to start their work. The targeted areas, useful documents, and active institutions are helpful to set up the new research. This project is focused on developing an assistant tool based on public accessed papers and information on the Internet that allows researchers to view most cited papers in networking conferences and journals. NLP tools are implemented over crawled full-text in order to classify the papers and extract the keywords. Papers are located based on authors to show the most active countries around the world that are working in this area. References are analyzed to view the most cited topics and detailed paper information. We draw some interesting conclusions from our system, showing that some topics attract more attention in the past decades. / Under de senaste decennierna upplevde nätverksundersökningar stora förändringar. Att känna till utvecklingen av nätverksundersökningar är det första steget för de flesta forskare att starta sitt arbete. De riktade områdena, användbara dokument och aktiva institutioner är användbara för att skapa den nya forskningen. Projektet fokuserade på att utveckla ett assistentverktyg baserat på offentliga åtkomstpapper och information via internet. Som gör det möjligt för forskare att se de mest citerade artiklarna i nätverkskonferenser och tidskrifter. NLP- verktyg implementeras över genomsökt fulltext för att klassificera papperet och extrahera nyckelorden. Artiklar är baserade på författare för att visa de mest aktiva länderna runt om i världen som arbetar inom detta område. Hänvisningar analyseras för att se det mest citerade ämnet och detaljerad pappersinformation. Vi drar några intressanta slutsatser från vårt system och visar att något ämne inte lockar till sig mer under de senaste decennierna.

Natural Language Processing

Network Spider

Network

Topic Modelling

State of Research.

Naturlig Språkbearbetning

Nätverksspindel

Nätverk

Ämnesmodellering

Forskningstillstånd.

Computer and Information Sciences

Data- och informationsvetenskap

From Nano to Micro to Macro: Importance of Structure and Architecture in Spider Silk Adhesives

Sahni, Vasav

24 July 2012

No description available.

Biology

Biomechanics

Biophysics

Materials Science

Mechanics

Polymers

Spider Silk

Adhesion

Glycoproteins

Viscoelastic Solid

Elasticity

Pyriform Silk

Capture Silk

Prey Capture

Beads on a string

Development of a codon-optimized Latrodectus hesperus MaSp1 synthetic gene for bacterial protein expression using a seamless cloning strategy

Mendoza, J. Alexander Hoang

01 January 2015

Spider silk has outstanding mechanical properties, displaying high tensile strength and extensibility. The unique combination of strength and great extensibility make it one of the toughest materials in the world. Of the seven different spider silks, dragline silk, the lifeline silk of the spider, represents one of the most renowned fiber types that has extraordinary properties. As a result, many labs across the globe are racing to manufacture synthetic dragline silk fibers. With the production of synthetic dragline silk fibers, there are unlimited commercial applications. In this study, we developed several codon-optimized MaSp1 minifibroin constructs for recombinant protein expression in bacteria. These recombinant MaSp1 minifibroin constructs were engineered to contain the N-terminal domain (NTD), different copies of internal block repeats (ranging from 2 to 64 copies of 35 amino acid blocks), and the C-terminal domain (CTD). The NTD and CTDs were derived from the natural cDNA sequences of black widow spiders, while the internal block repeats were generated from synthetic DNA fragments that were codon-optimized for expression in Escherichia coli . Different numbers of internal block repeats were created using a specialized seamless cloning strategy. By applying this seamless cloning strategy, we successfully multimerized MaSp1 block repeats that approach the natural fibroin size. Moreover, through the construction of a customized NTD-CTD spidroin construct, multimerized block repeats from any fibroin can be rapidly inserted to facilitate minifibroin protein expression in bacteria. Overall, this strategy as well as the created vectors, should help advance the silk community in the production of synthetic silk fibers that have properties that more closely resemble natural fibers.

Molecular biology

Entomology

Cellular biology

Biochemistry

Textile Research

Pure sciences

Biological sciences

Applied sciences

Latrodectus hesperus

Major ampullate

Masp1

Spider silk

Biology

Silky Soft Bioelectronics

Menke, Maria Ann

17 November 2022

No description available.

Biomedical Engineering

Health Care

Materials Science

on-skin electrodes

non-invasive health monitoring

soft bioelectronics

epidermal electronics

spider silk

liquid metal networks

impedance

breathability

skin adhesion

Self-Assembly and Structure Formation of Spider Silk Based Proteins in (Ultra)thin Films

Hofmaier, Mirjam

13 February 2024

Spider silk is one of the most fascinating materials found in nature. Besides its properties like biodegradability, low immunoreactivity, and biocompatibility, especially the mechanical properties outperforming today’s artificial high-tech materials like Kevlar® are of great interest in biomedicine or material science. Spider silk comprises highly repetitive amino acid sequence motives, whose structure is accepted to be responsible for the extraordinary properties of spider silk. Typically, hydrophilic sequence motives alternate with hydrophobic ones making spider silk proteins resemble block copolymers. Additionally, the simple amino acid sequence and the possibility to form fibrillar structures are common characteristics of spider silk proteins as well as intrinsically disordered proteins (IDP) or protein regions (IDR). Both are suspected of being involved in the development of certain neurodegenerative diseases like Alzheimer´s disease. These aspects open promising possibilities of the use of spider silk proteins in nanotechnology, but also as model systems for the fibrillization processes of IDPs and IDRs, which are still unresolved today. Currently, most of the research and application is focused on 1-dimensional spider silk protein fibrils and fibers or 0-dimensional spider silk particles. However, 2-dimensional spider silk protein films or porous 3-dimensional objects are highly relevant platforms with the potential for cell-supporting scaffolds, biodegradable electrolyte materials in transistors, or e.g., planar drug-eluting implant coatings. Generally, the effects of sequence-based and external influences on the self-assembly and folding of spider silk proteins have not yet been fully elucidated in all of these various dimensional spider silk materials, even concerning IDP and IDR models. Thus, basic research regarding assembly and folding processes is still needed, especially in films. Particularly, 2-dimensional films allow a broad spectrum of (surface) analytical techniques, from whose outcome general structure-property relations of spider silk materials across all material dimensions can be obtained. In this work, engineered spider silk proteins, which are based on the consensus sequence motives in the spider silk fibroin (spidroin) 3 and 4 of the European garden spider Araneus diadematus (eADF4(Cx), eADF3(AQ)x, eADF3(QAQ)x) as well as blends of two short peptides with the respective aa sequence of the hydrophobic (pep-c) and hydrophilic (pep-a) part of eADF4(Cx) proteins were used. Spider silk-related proteins and peptides were dissolved in 1,1,1,3,3,3-hexafluoroisopropanol or formic acid, processed as thin films, and post-treated with methanol vapor to induce β-sheet formation. Dichroic FTIR-spectroscopy was used, a powerful tool for studying protein secondary structure formation and orientation. Proteins reveal characteristic amide bands, which are highly sensitive to the conformation of the protein backbone. In the course of this work, a set of components for the line shape analysis (LSA) of the Amide I band was developed. Therby, each component was assigned to a typical secondary structure allowing a quantitative determination of the respective portions and their structural orientation. Quantitative secondary structure portions and their orientation could be determined on this basis. Furthermore, a comprehensive study of folding and self-assembly-influencing parameters like hydrophobic and hydrophilic sequences, molecular weight, the repeating sequence motive order, the film thickness, surface topography, and the surface chemistry in engineered spider silk protein and spider silk protein-based films was carried out. In general, methanol vapor post-treatment induced the formation of β-sheet structures in all films, causing phase separation and the formation of spherical and filamentous structures. The phase separation upon post-treatment was influenced by the covalent connectivity between hydrophobic and hydrophilic sequence parts as well as the repeating sequence motives. In thin films, the increased flexibility of shorter peptides enabled the formation of multipack filaments instead of spherical structures, which were formed by higher molecular weight proteins with several inter-connected repeating sequence motives. Stamping wrinkled structures using poly(dimethylsiloxane) substrates was possible. Filamentous structures were successfully assigned to β-sheet rich structures using infrared nanospectroscopy for the first time. Further, enhanced surface hydrophobicity led to the clustering of β-sheet filaments. The β-sheet content could be controlled by the amount of hydrophobic sequences in thin films. With a higher amount of hydrophobic sequences in the proteins or blends, the β-sheet content increased until a maximum β-sheet content of around 60% was reached. Additionally, β-sheet formation could be suppressed by increasing substrate hydrophobicity or by decreasing the number of repeating sequence motives by going from protein-like folding to peptide-like self-assembly. The backfolding of proteins with covalently linked repeating sequence motives further promoted the formation of more antiparallel β-sheets. Antiparallel β-sheet formation was also favored when the portion of the hydrophilic, amorphous phase was increased. Micrometer thick films did not reveal any preferred alignment of β-sheets, while a general out-of-plane orientation of β-sheets could be obtained in all thin protein, peptide, and blend films. Z-axial orientation in films was increased by using short pep-c and pep-a peptides, higher molecular weight proteins or the deposition of monolayered films instead of thin multilayered films. Also, increased hydrophilicity of the substrate promoted the alignment of β-sheets perpendicular to the substrate surface. The folding kinetics and final domain size were found to be directly correlated. The amount of hydrophobic phase, backfolding, and increased flexibility due to low chain lengths increased the folding kinetics and led to smaller domain sizes. Thus, competing effects of backfolding and flexibility of the protein/peptide backbone could be rationalized. The film integrity and water contact angle were directly related to the β-sheet content and the molecular weight. Beyond the classical protein conformation and orientation analysis, the possibilities and limits of orientation analysis using dichroic attenuated total reflection Fourier transform infrared (ATR-FTIR) spectroscopy were elaborated on the seemingly ideal oriented polymer model system of end-grafted poly(N,N-dimethylaminoethylmethacrylate) chains. Such a system featured a polymer brush regime in the swollen state with z-axial orientation expected similarly high as thin spider silk films after ptm. Moreover, dichroic ATR-FTIR spectroscopy is a promising analytical method for closing gaps in the defined assignment of brush regimes. In summary, general models of the structure formation and self-assembly of spider silk protein in films depending on the parameters mentioned above could be developed and set in relation to IDP/IDR self-assembly by using dichroic FTIR spectroscopy as the basic analysis method. The herein postulated models on the molecular level contribute to the understanding and development of future industrial applications of spider silk protein-based materials and the clarification of unresolved questions regarding IDP and IDR systems.:Abstract V Kurzfassung IX List of Publications XIII Publications in Trade Journals XIII Presentations and Posters XIII Contribution to Joint Publications XV List of Abbrevations XVII List of Symbols XIX List of Figures XXV List of Tables XXXIII 1 Introduction and Motivation 1 2 Theory 5 2.1 Proteins and Peptides 5 2.1.1 General Definition of Proteins and Peptides 5 2.1.2 Structure of Globular Proteins 7 2.1.3 Protein Folding 10 2.1.4 Intrinsically Disordered Proteins and Protein Regions 11 2.2 Block Copolymers 14 2.3 Spiders and Spider Silks 17 2.3.1 Classification of Spiders 17 2.3.2 The Natural Spider Silk Spinning Process 18 2.3.3 Structure of Spider Silk and Spider Silk Proteins 19 2.3.4 Structure-Property Relationships of Spider Silk 21 2.4 Infrared Spectroscopy 23 2.4.1 Basic Principles of Infrared Spectroscopy 23 2.4.2 Basic Equipment and IR-Technologies 27 2.4.3 Orientation Analysis using Dichroic FTIR Spectroscopy 32 2.4.4 Infrared Spectroscopy of Proteins and Peptides 38 2.4.5 Quantitative Analysis of TRANS- and ATR-FTIR Protein Spectra 43 2.5 Electronic Circular Dichroism 46 2.5.1 Basics Principles of Circular Dichroism 46 2.5.2 Circular Dichroism of Proteins and Polypeptides 48 2.5.3 Spectra Analysis 50 2.6 Atomic Force Microscopy 51 2.6.1 Setup of Atomic Force Microscopes 51 2.6.2 Basic Principles of Atomic Force Microscopy 52 2.6.3 AFM Operation Modes 55 3 Experimental Section 57 3.1 Materials 57 3.1.1 Chemicals 57 3.1.2 Substrates 57 3.1.3 Film Preparation 58 3.2 Analytical Methods 60 3.2.1 Dichroic FTIR Spectroscopy 60 3.2.2 Atomic Force Microscopy 64 3.2.3 Electronic Circular Dichroism 64 3.2.4 Spectroscopic Ellipsometry 64 3.2.5 Infrared Nanospectroscopy 65 3.2.6 Grazing Incident Small Angle X-Ray Scattering 66 4 Results 67 4.1 Self-Assembly of eADF4(C16) Films 67 4.1.1 Motivation 67 4.1.2 Dichroic FTIR Spectroscopy Characterization of ß-sheet Orientation in Spider Silk Films on Silicon Substrates 68 4.2 Influence of the Hydrophilic and Hydrophobic Blocks on Peptide Self-Assembly 90 4.2.1 Motivation 90 4.2.2 β-Sheet Structure Formation within Binary Blends of Two Spider Silk Related Peptides 90 4.2.3 Influence of the Hydrophilic and Hydrophobic Blocks on the Inner Morphology in Spider Silk Protein Based Blend Films 122 4.3 Influence of the Sequence Motive Repeating Number on Spider Silk Protein Folding 123 4.3.1 Motivation 123 4.3.2 Influence of Sequence Motive Repeating Number on Protein Folding in Spider Silk Protein Films 124 4.4 Influence of the Module Order on Spider Silk Protein Self-Assembly 152 4.4.1 Motivation 152 4.4.2 Secondary Structure upon Post-treatment 153 4.4.3 β-Sheet Orientation after Post-treatment 157 4.4.4 Morphology and Surface Properties 158 4.4.5 Conclusion 160 4.5 Surface Induced Changes of Spider Silk Protein Self-Assembly 161 4.5.1 Motivation 161 4.5.2 Variation of the Substrate Surface Chemistry and Topography 161 4.5.3 Influence of the Surface Topography on Protein Self-Assembly 162 4.5.4 Influence of the Surface Chemistry on Protein Self-Assembly 164 4.5.5 Conclusion 169 4.6 Chances and Limits of Dichroic ATR-FTIR Spectroscopy 170 4.6.1 Motivation 170 4.6.2 Novel Insights into Swelling and Orientation of End-Grafted PDMAEMA Chains by In-Situ ATR-FTIR Complementing In-Situ Ellipsometry 171 5 Conclusion and Outlook 197 6 References 203 7 Appendix 219 8 Danksagung 227 9 Eidesstattliche Versicherung 229

info:eu-repo/classification/ddc/530

ddc:530

Neoichnology of the Burrowing Spiders <i>Gorgyrella inermis</i> (Araneae: Mygalomorphae) and <i>Hogna lenta</i> (Araneae: Araneomorphae)

Hils, John M.

24 September 2014

No description available.

Paleontology

Paleoecology

Geology

Animals

Soil Sciences

Neoichnology

trace fossil

spider

Araneae

Mygalomorphae

Araneomorphae

Gorgyrella inermis

Hogna lenta

continental ichnology

Skolithos

Macanopsis

ichnology