Analysis and Molecular Characterization of an Unusual Copper Inducible Homeostasis Mechanism in Pseudomonas putida KT2440

Quaranta, Davide

January 2009

The purpose of this research was to identify and characterize novel molecular mechanisms in copper homeostasis. Pseudomonas putida KT2440 is a soil bacterium studied for its potential use in bioremediation of soils contaminated with aromatic organic contaminants. The cinAQ operon was analyzed. cinAQ is transcribed in presence of copper. The product of cinA is a periplasmic azurin-like protein with a methionine and histidine rich region, characterized by a high redox potential (456 ±4 mV). CinQ was shown to be a pyridine nucleotide-dependent nitrile oxidoreductase that catalyzes the reduction of preQ₀ to preQ₁, the first committed step in the biosynthetic pathway leading to the production of the unusual nucleotide queuosine. Gene disruption of cinQ in Pseudomonas putida KT2440 and in Pseudomonas aeruginosa PAO1 did not result in a significant increase in copper sensitivity on disk assays. Furthermore, a P. putida KT2440 cinA mutant also did not present a greater sensitivity to copper on disk assays while cinA mutants in Pseudomonas aeruginosa PAO1 presented increased toxicity to copper compared to the wild-type. CinA is by sequence similarity proposed to be an electron shuttle, and was shown to be upregulated in the presence of copper. Increasing CinA levels in the periplasm after copper stress may represent a mechanism used to regenerate the multicopper oxidase CopA (involved in Cu(I) to Cu(II) oxidation). Alternatively, CinA could act as an electron shuttle that takes part in an alternative electron transport chain once redox active copper is available, or it could represent a periplasmic copper chaperon. CinQ is involved in the biosynthesis of the rare hyper-modified nucleotide queuosine, found in the wobble position of several tRNAs, and required to avoid the readthrough of the stop codon UAG. Transcription of cinAQ was shown to be under the control of the two component system CinR-CinS. CinS is a histidine kinase, with a sensor domain located in the periplasm. CinR is the cognate response regulator that activates transcription of genes upon phosphorylation from CinS. The CinR-CinS two component system was shown to be responsive to 0.5 LM copper. CinS displayed very high metal specificity and elicited a response only in the presence of copper and silver, but not other metals. Modeling of the CinS protein structure, performed using Swiss Model and using the periplasmic sensor DcuS from Escherichia coli as a template, identified a potential copper binding site, containing H37 and H147. Sequence alignment of copper sensing histidine kinases further identified other conserved residues in the periplasmic domain. Site-Directed Mutagenesis was used to generate CinS mutants that were tested for their ability to activate the cinAQ promoter in presence of Cu. When challenged with copper CinS mutant H37R and H147R had an almost 10 fold reduction in copper sensitivity compared to the wild-type, indicating a possible role in Cu coordination. Other CinS mutants responded similarly to the wild-type in the presence of 10 μM of Cu.

azurin

copper homeostasis

copper sensing

Pseudomonas

queuosine

two component system

Biochemical and structural characterization of CpxP and CpxA, key components of an envelope stress response in Escherichia coli

Thede, Gina L.

Unknown Date

No description available.

periplasm

envelope stress

Gram-negative bacteria

two-component system

Understanding the Regulatory Mechanism of BfmR in Acinetobacter baumannii ATCC 19606T

Mack, Lydia Eileen

28 June 2019

No description available.

Microbiology

Acinetobacter

baumannii

two component system

BfmR

regulation

microbiology

A C. albicans two component pathway regulates the CDR4 and SSU1 transport genes involved in quorum sensing and response to bacterial signaling molecules.

Stuffle, Derek A, Kruppa, Michael D, Dr.

04 April 2018

Polymicrobial communities of bacterial and fungal species are present on the skin and mucosal surfaces of the body. Invasive infections caused by Candida species are commonly seen in immunocompromised individuals (HIV, transplants, cancer) and ranks as the third leading cause of infection in hospitalized patients. C. albicans is a polymorphic opportunistic fungus that infects critically ill patients and has the ability to change its morphology from yeast to hyphal form.The morphogenesis of C. albicans is a major aspect of its virulence and is regulated by quorum sensing (QS) molecules they produce, as well as the presence of neighboring microbes.In this study, we examined two transporter mutants, cdr4 and ssu1, for their ability to form biofilms in the presence of cyclic-di-GMP and 3-oxo-12-homoserine lactone. To quantify biomass, wild type and mutant cells were grown overnight at 30˚C in YPD. The cells were washed, counted and diluted to a desired density of 106 cells/ml in medium 199, pH7.5. Cells were added to 96-well plates pre-incubated with 5% fetal bovine serum at densities of 105, 104, and 103 cells/well and allowed to adhere at 37˚C for one hour. The wells were then covered with fresh M199 media containing the QS molecule and monitored for 48 hours at 37˚C. After this time, the media and planktonic cells were removed. The biofilms were fixed with methanol, dried, then stained with 0.05% crystal violet. Bulk biomass was assessed by spectrophotometry. We did observe a difference in biofilm density when incubated in the presence of cyclic-diGMP. We noted that for the wild type and ssu1 strain their biofilms biomass increased by as much as 10% at 104 and 103 cell densities when compared with the control. While the cdr4 strain had a slight reduction in biofilm density when cyclic-diGMP was present. This result also indicates a potentially positive role in which cyclic-diGMP can help C. albicans develop denser biofilms, potentially in the presence of bacteria like P. aeruginsa, which secrete cyclic di-GMP, but kill hyphal forms of C. albicans. Additionally, it has been shown that C. albicans mutants lacking the hybrid histidine kinase, Chk1p, are refractory to the effects of farnesol, a QS molecule that inhibits morphogenesis.Given that mutations in CDR4 and SSU1 impact the QS response in C. albicans, we investigated whether these genes were regulated through two-component signaling by Chk1. To assess CDR4 and SSU1 expression, wild type and mutant strains were grown overnight in YPD media at 30˚C. Cells were then harvested and RNA was obtained by acid phenol extraction. Using RT-PCR, we determined both CDR4 and SSU1 expression is reduced or highly repressed in the chk1, ypd1, and skn7 null strains. These results suggest the two genes are downstream targets in a pathway regulated by Chk1p. The finding that QS proceeds through a two-component pathway can be exploited in antifungal drug development. Given that two-component signaling is absent in mammalian cells, development of novel compounds that interfere with this pathway may be a useful alternative for treating patients with candidiasis.

Candida albicans

quorum sensing

biofilms

two-component signaling

Pathogenic Microbiology

Evidences for Protein-Protein Interactions Between PstB and PhoU in the Phosphate Signaling Complex of Escherichia coli

Johns, Kristine Dawn

15 March 2013

The PstSCAB2 complex serves the dual function of being a phosphate transporter as well as the primary sensor of phosphate for the Pho regulon. PhoU is an integral protein required for the signal from PstSCAB2 to be transmitted to PhoR. Our hypothesis is that conformational changes of PstSCAB2 during the phosphate transport process are the mechanism by which information about environmental phosphate levels are transduced to the cell. Additionally, we propose that direct protein-protein interactions between PhoU and the alternating conformations of PstSCAB2 mediate PhoU interactions with PhoR. By means of genetic and biochemical approaches, we have found substantial evidence supporting both these hypotheses.

Pho regulon

two-component

ABC transporter

PstB

PhoU

Microbiology

Characterization of the PilS-PilR two component regulatory system of Pseudomonas aeruginosa

Kilmury, Sara LN

11 1900

Two-component regulatory systems are an important means for most prokaryotes to adapt quickly to changes in their environment. Canonical systems are composed of a sensor kinase, which detects signals that trigger autophosphorylation, and a response regulator, which imparts changes within the cell, usually through transcriptional regulation. The opportunistic pathogen, Pseudomonas aeruginosa, expresses a plethora of two-component systems including the PilS-PilR sensor-regulator pair, which directs transcription of the major component of the type IV pilus (T4P) system, pilA, in response to an unknown signal. T4P are surface appendages that are required for full virulence, as they perform several important functions including twitching motility, cell surface attachment, surface sensing, and biofilm formation. While loss of pili is known to decrease virulence, the effect of surplus surface pili on pathogenicity was unknown. In other T4P-expressing bacteria, PilR regulates the expression of non-T4P related genes, but its regulon in P. aeruginosa was undefined. Here, we identify PilA as an intramembrane signal for PilS, regulating its own expression. When PilS-PilR function is altered through the use of activating point mutations, which induce hyperpiliation, pathogenicity in C. elegans was significantly impaired compared to both wild type and non-piliated strains of P. aeruginosa. This phenotype could be recapitulated using other hyperpiliation-inducing mutations, providing evidence that over production of surface pili likely prevents productive engagement of contact-dependent virulence factors. Last, transcriptomic analyses revealed that expression of over 50 genes – including several involved in flagellar biosynthesis and function – is modulated by PilSR, suggesting coordinate regulation of motility in P. aeruginosa. Together, this work provides new information on the control of pilA transcription and suggests novel roles for surface pili and the PilSR two component system in virulence and swimming motility, respectively. The knowledge gained from this work could be applied to the development of a PilS or PilR based anti-virulence therapeutic. / Thesis / Doctor of Philosophy (PhD) / Pseudomonas aeruginosa is a Gram negative bacterium and a common cause of hospital acquired infections. The World Health Organization recently ranked P. aeruginosa as one of the top “priority pathogens” for which new treatments are desperately needed, in part due to its intrinsic resistance to many antibiotics. Among the key features that contribute to the infectivity of P. aeruginosa are its Type IV pili (T4P), which are flexible, retractile surface appendages involved in cell surface attachment, movement across solid surfaces and other important functions. Production of the major pilin protein, PilA, which forms most of the pilus, is tightly controlled by the two-component regulatory system, PilS-PilR, where PilS is a sensor and PilR is a regulator that directly controls pilin expression. The aim of this work was to identify the signal(s) detected by the sensor, as well as additional genes or systems under PilSR control. We showed that the pilin protein interacts directly with the sensor to control its own expression, and that dysregulation of the PilS-PilR two-component system impairs both pathogenicity and other forms of motility. Together, the data presented here provide insight into how PilS-PilR control expression of systems required for virulence of P. aeruginosa and highlight the potential of these proteins as possible therapeutic targets.

Pseudomonas aeruginosa

Type IV pili

Two-component System

Adaptation au froid de la bactérie pathogène Bacillus cereus : étude de mécanismes impliqués et exploitation de la diversité génétique / Cold Adaptation of the pathogen Bacillus cereus : mechanisms involved and genetic diversity

Diomande, Sara Esther

02 December 2014

Bacillus cereus sensu stricto (ss) est un pathogène alimentaire majeur représentant la 2e cause de toxiinfectionalimentaire en France en 2012. Cette espèce fait partie du groupe Bacillus cereus sensu lato (sl)constitué d’espèces ubiquitaires génétiquement très proches et incluant d’autres pathogènes comme B.anthracis, B. thuringensis et B. cytotoxicus. Les souches de B. cereus sl sont d’autre part réparties en septgroupes phylogénétiques présentant des gammes de température de croissance variées et caractérisés partrois thermotypes principaux: thermotolérants, mésophiles, psychrotolérants. L’adaptation au froid dessouches B. cereus ss est un mécanisme clé car il conditionne sa capacité à se développer dans les alimentsréfrigéré pour atteindre des doses qui peuvent être dangereuse pour les consommateurs. Le but de cetteétude a été d’étudier les mécanismes moléculaires impliqués dans l’adaptation au froid de la diversité desouches représentant B. cereus sl.Nous avons mis en évidence que les gènes codant pour le système à deux composants CasK/R sontsurexprimés à basse température. CasK/R s’est révélé être un système générique d’adaptation de B. cereussl au froid, car son rôle a été mis en évidence lors de l’étude de quatre souches de thermotypes différents etleurs mutants isogéniques ΔcasK/R respectifs. Une étude transcriptomique réalisée sur une souche ATCC14579 et son mutant ΔcasK/R a révélé que seize des gènes différentiellement exprimés en début de phaseexponentielle et en phase stationnaire, à basse température, codent pour des protéines impliquées dans lemétabolisme des acides gras. Nous avons mis en évidence le rôle de CasK /R dans la modification de lacomposition en acides gras membranaires via une augmentation de la proportion en acides gras insaturéslors de la croissance de B. cereus au froid. Par ailleurs, le gène codant pour la désaturase DesA,principalement responsable des insaturations des acides gras à basse température est régulée positivementpar CasK/R au froid.Nous avons également démontré que les gènes casK/R sont organisés en opéron avec un gène codant pourun régulateur RpiR-like. De manière originale, cet opéron est négativement régulé par CasK/R à bassetempérature en phase stationnaire. Le promoteur individuel du rpiR est réprimé à basse température maisaussi à température optimale de croissance, ce qui suggère un rôle de CasK/R, même à températureoptimale / Bacillus cereus sensu stricto (ss) is a major foodborne pathogen representing the second cause of foodpoisoning in France in 2012. This species belongs to Bacillus cereus sensu lato (sl) consisting of ubiquitousspecies genetically close-related and including other pathogens such as B. anthracis, B. thuringiensis and B.cytotoxicus. The strains of B. cereus sl are divided into seven phylogenetic groups with various growthtemperature ranges and characterized by three main thermotypes: thermotolerant, mesophilic,psychrotolerant. The B. cereus ss cold adaptation is a key mechanism because it determines B. cereusability to grow in refrigerated foods and achieve doses that can be dangerous to consumers. The aim of thisstudy was to study the molecular mechanisms involved in the cold adaptation of strains representing B.cereus sl diversity.We demonstrated that the genes encoding the two component system CasK/R are overexpressed at lowtemperature. CasK/R was found to be a generic mechanism for B. cereus sl cold adaptation as its role washighlighted in the study of four strains with different thermotypes and their respective isogenic mutantsΔcasK/R. A transcriptomic study on a B. cereus ATCC 14579 strain and its ΔcasK/R mutant strain revealedthat sixteen of the genes differentially expressed in both early log phase and stationary phase at lowtemperature encode proteins involved in the fatty acids metabolism. We showed the role of CasK/R in themodification of the membrane fatty acid composition via an increase of the proportion of unsaturated fattyacids during growth of B. cereus at low temperature. Furthermore, the gene encoding the desaturase DesA,mainly responsible of the fatty acids unsaturation at a low temperature is upregulated by CasK/R at lowtemperature.We also demonstrated that casK/R genes were organized in operon with a gene encoding a RpiR-likeregulator. Interstingly,, this operon is negatively regulated by CasK/R at low temperature in the stationaryphase. The individual rpiR promoter is repressed by CasK/R at low temperature but also optimal growthtemperature, suggesting also a role for CasK/R at optimal temperature

B. cereus

Système à deux composants

Froid

Adaptation

Acides gras

B. cereus

Two component systems

Cold

Fatty acids

Two component systems

579.3

Re-engineering bacterial two-component signalling systems

Blades, Gareth

January 2014

Bacteria use Two Component Systems (TCS) to sense and respond to changes in their external environment. TCS are used to navigate to nutrients or away from toxins (chemotaxis) and to adapt to changes in osmolarity (osomosensing). TCS are composed of a histidine protein kinase (HPK) which trans-autophosphorylates in response to environmental change, transferring the phosphoryl group to a cognate response regulator (RR). Phosphorylated RRs modulate an output response such as protein-protein interaction for chemotaxis, and transcription for osmosensing. RRs are composed of a conserved amino terminal REC domain, and where present a variable effector domain. CheY, the chemotaxis RR, contains only a REC domain, whilst OmpR, the osmosensing RR, also contains a DNA binding effector domain. Recently, TCS have been used in synthetic biology applications due to their modularity and conserved signalling mechanism. This thesis aimed to investigate whether it was possible to design a synthetic TCS composed of fused chemotaxis and osmosensing components. Synthetic RRs were designed, fusing the highly conserved REC domains of CheY and OmpR upstream of the OmpR effector domain. REC domains were fused across the α₄-β₅-α₅ region, a region which transmits REC domain phosphorylation into effector domain activation. Synthetic RRs were designed to undergo phosphotransfer to their fused REC domains from the chemotaxis HPK, CheA, activate the attached OmpR effector domain and bind promoter DNA. Four chimeric RRs were created, although only three were structurally viable; F2, F3 and F4. Each fusion bound CheA, and F3 and F4 bound CheA with a significantly higher affinity than CheY. The chimeric RRs could all be phosphorylated byCheA-P; F4 and F3 were phosphorylated to wild-type levels. DNA binding affinitywas investigated with fluorescence anisotropy, hosphorylated and unphosphorylated F3 could not bind promoter DNA. F2 bound promoter DNA regardless of phosphorylation state. These data indicate that phosphorylation of the F2 REC domain does not lead to activation of the effector domain. F2 is likely to be constitutively active suggesting a previously unknown role for OmpR α₅ as a mediator of effector domain activation. Furthermore, using a simple fusion approach to design RRs is not a viable method to create a synthetic TCS with a controllable output.

572.8

In vitro and In vivo characterization of Amyloliquecidin, a novel two-component lantibiotic produced by Bacillus amyloliquefaciens

Van Staden, Anton Du Preez

04 1900

Thesis (PhD)--Stellenbosch University, 2015. / ENGLISH ABSTRACT: Antimicrobial resistance is one of the major problems faced by the medical industry today. The ability of bacteria to rapidly acquire resistance against antibiotics and the over prescription and inappropriate use of antibiotics further exacerbate this crisis. Few new antimicrobials are, however, making it through the drug discovery pipeline. The search and development of novel and effective antimicrobials is therefore of the utmost importance. Lantibiotics are ribosomally synthesized cationic antimicrobial peptides with extensive post-translational modifications. They are active against a wide range of Gram-positive bacteria, including antibiotic-resistant strains. They are characterized by the presence of lanthionine and methyllanthionine rings and have been suggested as alternatives or for use in conjunction with antibiotics against resistant pathogens. Staphylococcus aureus is the most common bacteria isolated from skin and soft tissue infections (SSTIs). Strains of S. aureus have emerged with resistance against antibiotics with the most common being methicillin-resistant S. aureus (MRSA). Several lantibiotics are active against MRSA in vivo and have even shown superior activity to traditional antibiotics. Lantibiotics therefore show much promise for the treatment of SSTIs caused by resistant- and non-resistant S. aureus. In this study the bacterially diverse soil of the Fynbos in the Western Cape was screened for novel antimicrobials. Two antimicrobial producing Bacillus strains were isolated, Bacillus clausii AD1 and Bacillus amyloliquefaciens AD2. Both of these strains produce lantibiotics with B. clausii AD1 producing a known lantibiotic, clausin. B. amyloliquefaciens AD2 produces a novel two-component lantibiotic which was designated amyloliquecidin. The lantibiotic operon of amyloliquecidin was sequenced and annotated. All the genes required for successful production of amyloliquecidin are present in the operon. Amyloliquecidin was characterized in vitro and along with clausin is active against clinical strains of S. aureus (including MRSA), Enterococcus spp., Listeria spp. and beta-haemolytic streptococci. Amyloliquecidin has remarkable stability at physiological pH compared to nisin and clausin. A comparative in vivo murine infection model was used to evaluate the effectiveness of amyloliquecidin, nisin, clausin and Bactroban (commercial S. aureus topical treatment) in treating wound infections caused by S. aureus. All the lantibiotics proved to be just as effective as the Bactroban treatment. Furthermore, the tested lantibiotics did not have a negative influence on the wound closure rates of infected and non-infected wounds. Bactroban had a negative effect on wound healing compared to the lantibiotics. To our knowledge amyloliquecidin is the third two-component lantibiotic isolated from Bacillus. This study represents the first to test the effectiveness of amyloliquecidin in vivo and is one of a handful to test lantibiotics as topical treatments. / AFRIKAANSE OPSOMMING: Antimikrobiese weerstandbiedende bakterieë is op die oomblik een van die grootste probleme in die mediese veld. Die antibiotika krisis word vererg deur die vermoë van bakterieë om vinnig weerstand op te bou teen antibiotika, asook die alledaagse misbruik van antibiotika. Daar is ook ʼn tekort in die hoeveelheid antibiotika wat na die finale fases van ontwikkeling gaan. Om die oorhand teen antibiotika-weerstandige bakterieë te kry is dit van uiterste belang dat meer effektiewe antibiotika ontdek word. Lantibiotika is kationiese antimikrobiese peptiede wat deur die ribosoom gesintetiseer word en bevat ʼn verskeidenheid van modifikasies wat na translasie ingebou word. Hulle word gekarakteriseer deur lanthionien en metiellanthionien ringe. Lantibiotika is aktief teen ʼn verskeidenheid Gram-positiewe bakterieë en kan in kombinasie met antibiotika, of as alternatief gebruik word. Staphylococcus aureus is die mees algemene bakterium wat geassosieer word met vel en sagte weefsel infeksies (VSWIs). Staphylococcus aureus met weerstand teen antibiotika is ook al geïsoleer, die mees algemene weerstandige ras is methisillien-weerstandige S. aureus (MWSA). Lantibiotika is wel aktief teen MWSA in vitro en in vivo, met van hulle wat tot beter aktiwiteit as die voorgeskrewe antibiotika het. Lantibiotika kan dus gebruik word as behandeling vir VSWIs wat veroorsaak word deur weerstandige S. aureus, asook teen nie-weerstandige rasse. In hierdie studie was die bakteriese diverse grond van die Fynbos in die Wes-kaap ondersoek vir bakterieë wat antimikrobiese middels produseer. Twee Bacillus rasse, Bacillus clausii AD1 en Bacillus amyloliquefaciens AD2, wat antimikrobiese middels produseer, is geïsoleer. Bacillus clausii AD1 produseer ʼn bekende lantibiotikum, naamlik clausin. Bacillus amyloliquefaciens AD2 produseer ʼn nuwe twee-komponent lantibiotikum, amyloliquecidin. Die lantibiotikum operon wat verantwoordelik is vir die produksie van amyloliquecidin is geïdentifiseer en geannoteer. Die operon bevat al die gene benodig vir die biosintese van amyloliquecidin. Amyloliquecidin is in vitro gekarakteriseer en het aktiwiteit teen ʼn verskeidenheid Gram-positiewe bakterieë. Amyloliquecidin en clausin is aktief teen S. aureus (insluitend MWSA), Enterococcus spp., Listeria spp. en beta-hemolitiese streptococci wat vanaf infeksies geïsoleer is. Amyloliquecidin is baie stabiel by filologiese pH en aansienlik meer stabiel as nisin en clausin. Die effektiwiteit van nisin, clausin en amyloliquecidin in die behandeling van muis vel infeksies veroorsaak deur S. aureus was vergelyk met die kommersiële behandeling Bactroban. Al drie lantibiotika het die verspreiding van S. aureus met die selfde effektiwiteit as Bactroban belemmer. Geen van die lantibiotika het ʼn negatiewe effek op wond genesing nie. Bactroban, inteendeel, belemmer wond genesing. So ver ons weet is amyloliquecidin die derde twee-komponent lantibiotikum wat uit Bacillus geïsoleer is. Die studie is ook die eerste om die effektiwiteit van amyloliquecidin in vivo te rapporteer, asook ook een van die min studies wat kyk na lantibiotika as behandeling vir topikale infeksies.

Skin infections

Two-component Lantibiotic

Fynbos -- Novel antimicrobials

UCTD

Homologous evolution in the post-collapse expansion of globular clusters

Apple, Rosemary K.

January 2010

We examine the evolution of globular star clusters, modelled as spherically symmetric stellar systems, using various techniques. Such clusters possess a central region of approximately uniform density which is referred to as the core. We concentrate our analysis on the evolution of the cluster after the core has undergone core collapse; a process where its radius decreases and its density increases. After this collapse, the system as a whole can expand in a self-similar fashion (homologous post-collapse evolution) which has long been thought to be due to gravitational interactions between different populations of single stars and binary stars in the core. We confirm this assumption by constructing a simple analytical model which combines much of the theoretical knowledge of previous research in the field. This model consists of two stellar populations, each defined by the mass of the individual stars, and a separate core. Our simple model is itself constructed from two simpler models – a twocomponent model without a core and a single mass model with a core – and takes into account the main gravitational interactions thought to drive the post-collapse evolution. To ensure that no important mechanisms have been neglected in our simple model, we will compare it with an N-body simulation. We compute our N-body models with NBODY6 (using a GPU version for large N). When we compare the N-body model with the simple model, we find qualitative agreement between them for most cases. Even though some mechanisms (e.g. escape of stars) are neglected in our simple model, we find that both models show homologous post-collapse evolution. We also review the homologous post-collapse Fokker-Planck model in the case of equal stellar masses derived by H´enon (1961) with the intention of extending this for the two-component case. We present our numerical solutions for H´enon’s model and find that our numerical solutions are in satisfactory agreement with the results shown in this paper. When we extend this work for a general two-component model (i.e. with no restriction on the number of heavier stars), we find that a homologous solution cannot be found with this approach. By contrast, we suggest that it would be possible to find a homologous two-component solution by extending the one-component solution published later by H´enon (1965), which differs from the earlier model by neglecting the external tidal field of the parent galaxy. Much of the work shown in this thesis would be relevant for such future study.

520