Herstellung rekombinanter Clostridien-Sporen zur Therapie nekrotisierender Tumore

Box, Gunnar,

January 2006

Ulm, Univ. Diss., 2006.

Clostridium acetobutylicum. Spore.

Structure, chemical nature and development of the bacterial endospore as related to heat resistance

Cohen, Jill Marcella (Southworth),

January 1966

Thesis (M.S.)--University of Wisconsin--Madison, 1966. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Bacteria, Spore-forming. Heat

Relationship of heat activation and the mechanism of germination of bacterial spores

Vary, James Corydon.

January 1964

Thesis (M.S.)--University of Wisconsin--Madison, 1964. / eContent provider-neutral record in process. Description based on print version record. Bibliography: l. 66-70.

Bacteria, Spore-forming.

Characterization of proteins involved in Bacillus subtilis spore formation and germination

Barat, Bidisha

22 May 2020

Members of the Bacillus genus, when faced with unfavorable environmental conditions such as depletion of nutrients, undergo an asymmetric division process ultimately leading to the formation of an endospore. In some instances, the spore serves as the infectious agent of an associated disease; such is the case with the spore of Bacillus anthracis and the disease anthrax. Spores are resistant to a variety of unfavorable environmental conditions including traditional decontamination techniques. Spore resistance is due to the formation of specialized structures that contribute to spore dormancy through several mechanisms, including maintenance of the dehydrated state of the spore core. Spore germination is a rapid process resulting in the irrevocable transformation of the non-metabolizing dehydrated spore into a vegetative outgrowing bacterium. The exact mechanism by which individual proteins function in the germination pathway remains unknown. In this study, we have focused on the roles of putative ion transporters and other germination-active proteins in affecting spore formation and germination. Metal ions can activate enzymes during the sporulation process and/or be factors in spore resistance properties. In B. subtilis, six proteins within the spore membrane proteome (ChaA, YcnL,YflS, YloB, YugS, ZnuA) are similar to components of known cation transport systems. These proteins may play roles in the accumulation of ions during sporulation and/or the release of ions during germination. Multiple mutants altered in the putative ion transporter genes were generated, and the effects of these mutations were analyzed. All strains containing a yloB deletion showed a decrease in heat resistant cfu/ml, and >40% of the spores appeared phase dark during microscopy, indicating the formation of unstable spores. Studies were conducted to quantify the amounts of individual ions in phase-bright spores using atomic emission spectroscopy and to analyze the rate at which ions are released from germinating spores. The transport of Ca2+ from mother cell to forespore during sporulation seems to be affected in the yloB deletion mutant. This Ca2+ deficit apparently renders the spores unstable, heat sensitive, and partially germination defective, suggesting that a high-affinity transporter for Ca2+ is nonfunctional. To better understand the underlying mechanisms of germination, a high-throughput genetic screening method called transposon sequencing was used. This analysis identified genes that had not been previously implicated in germination. To investigate their functions, a number of functional assays of all the Ger mutant strains were performed that indicated a delay in stage I of germination. The mutant strains showed significant reduction in germination efficiency with L-valine: about 50% of the population failed to initiate germination suggesting a defect in the GerA-mediated response. The expression of gerA was studied using a lacZ transcriptional fusion followed by quantitative western blot analyses to determine abundance of GerA in mutant strains. The mutants were classified based upon normal or decreased gerA transcription and normal or reduced GerA protein. Further work involves understanding the functions of the identified genes and their correlation to the GerA receptor. Insight into ion transporters of spore-forming bacteria and understanding the germination apparatus may lead to promising new applications, detection methods, or therapeutics for spores, and may allow the development of better spore decontamination procedures. / Doctor of Philosophy / Bacillus subtilis is an ubiquitous bacterium that is capable of forming endospores when faced with unfavorable environmental conditions. Spores are highly resistant to heat, radiation, lack of nutrients, desiccation and oxygen deprivation. They lack metabolism, which effectively keeps them in a state of suspended animation until germinated. They may remain stable and viable in this state for extremely long periods of time. Several important pathogenic bacteria are spore formers. This leads to difficulty in their environmental eradication and the treatment of patients. Germination allows spores to resume metabolism and reestablish a vegetative state. Certain key molecules activate the germination process. Each species of spore-forming bacteria has a specific set of these molecules called germinants that will enable the spore to exit its dormant state. The work presented focuses on the understanding of the germination apparatus of Bacillus subtilis, which may provide a model to understand the germination of other spore formers and help to improve methods of decontamination.

Bacillus subtilis

spore

germination

Investigations of microbial physiology and cell structure using laser diffractometry

Ulanowski, Z.

January 1988

No description available.

579

Fungal/microbial spore study

Characterisation of a factor required for specific gene expression during Dictyostelium development

Gibson, Fernando

January 1988

No description available.

572

Spore coat protein synthesis

Scanning Electron Microscopic Studies on the Spores of Dryopteridoideae from Taiwan

Chen, Nien-chun

22 August 2007

The spores of Dryopterioideae from Taiwan were studied with scanning electron microscope. Eight genera and 45 species were observed. The spores were monolete and ellipsoidal to somewhat global. The spore macro-ornamentations were mostly rugate, tuberculate, cristate and reticulate, few are echinate. Surface micro-ornamentations observed were granulate, echinulate, fenestrate, sharp columellate, scale, and rugate. Based on observed spore ornamentation similarities and differences, the following points toward current different classification systems can be made: The echinulated spore ornamentation found in Tectaria and Dryopsis were quite different from others being studied and this result supported that Dryopterioid ferns are different from Tectarioid ferns. Lastreopsis have similar spore ornamentation with genera in Dryoterideae, but not Tectarioid ferns. The result agreed with molecular data but not traditional classification. Few species of Dryopteris had their distinct spore ornamentations and may be better classified into a subgenus in Dryopteris. One group of Polystichum had spore ornamentation quite different from other groups and this group may be classified into a subgenus of Polystichum. The spore ornamentations support that Cyrtomium be included in Polystichum.

Dryopteridoideae

classification

spore ornamentation

SEM

The production, rapid enumeration and immobilization of the spores of Paecilomyces varioti and other fungi

Abdullah, M. M.

January 1986

No description available.

611

Fungal spore production study

The Microsporidian Polar Tube and Spore Wall

Weiss, Louis M., Delbac, Frédéric, Hayman, J. Russell, Pan, Guoqing, Dang, Xiaoqun, Zhou, Zeyang

20 October 2014

All of the members of the microsporidia possess a unique, highly specialized invasion mechanism that involves the polar tube and spore wall. This chapter reviews the data on the organization, structure, and function of this invasion organelle. The application of immunological and molecular techniques and recent genome sequencing data has resulted in the identification of multiple polar tube and spore wall proteins (SWPs). The interactions of these identified proteins in the formation and function of the polar tube and spore wall remain to be determined. Inside the spore, the polar tube is filled with material and is often termed the polar filament; however, this chapter uses the term polar tube to refer to this structure when it is within the spore as well as when it forms a hollow tube after germination and is found outside the spore. The chapter presents details on the spore activation and discharge.

microsporidian polar tube

polar tube discharge

polar tube protein (PTP)

spore activation

spore wall

spore wall proteins (SWPs)

Biomedical Sciences

Application of miniaturized identification systems to the taxonomy of bacillus and relatives

Forsyth, Gillian

January 2001

No description available.

579

Phenotypic; Spore formers; Forming rods