Analysis of the Role of Rhodobacter sphaeroides CrpO in Tolerance to NaCl

Retamal, Susana B.

12 November 2010

No description available.

Biology

Rhodobacter sphaeroides

osmoregulation

osmoadaptation

gene regulation

Hydrogen production by Rhodobacter sphaeroides and its analysis by metabolic flux balancing

Chongcharoentaweesuk, Pasika

January 2014

There is a global need for sustainable, renewable and clean energy sources. Microbial production of hydrogen from renewable carbon sources, biorefinery compounds such as succinic acid or from food and drinks industry waste meets all these criteria. Although it has been studied for several decades, there is still no large scale bio-hydrogen production because the rate and yield of hydrogen production are not high enough to render the process economical. The dependency of biological hydrogen production of incipient light energy is also an important factor affecting economics. In order to improve the prospects of biohydrogen as a renewable and sustainable energy alternative, the genetic and process engineering approaches should be helped and targeted by metabolic engineering tools such as metabolic flux balance analysis. The overall aim of this research was the development of computational metabolic flux balance analysis for the study of growth and hydrogen production in Rhodobacter sphaeroides. The research reported in this thesis had two approaches; experimental and computational. Batch culture experiments for growth and hydrogen production by Rhodobacter sphaeroides were performed with either malate or succinate as carbon source and with glutamate as the nitrogen source. Other conditions investigated included; i) aerobic and anaerobic growth, ii) light and dark fermentation for growth, and iii) continuous light and cycled light/dark conditions for hydrogen production. The best growth was obtained with succinate under anaerobic photoheterotrophic conditions with the maximum specific growth rate of 0.0467 h– 1, which was accompanied with the maximum specific hydrogen production rate of 1.249 mmol(gDW.h)– 1. The range of the photon flux used was 5.457 - 0.080 mmol(gDW.h)– 1. The metabolic flux balance model involved 218 reactions and 176 metabolites. As expected the optimised specific rates of growth and hydrogen production were higher than those of the experimental values. The best prediction was for hydrogen production on succinate with computed specific hydrogen production rates in the range of 2.314 - 1.322 mmol(gDW.h)– 1. Sensitivity analyses indicated that the specific growth rate was affected by the nitrogen source uptake rate under aerobic dark condition whereas the flux of protein formation had the largest effect on the specific growth rate under anaerobic light condition.

665.8

Regulation of the expression and positioning of chemotaxis and motor proteins in Rhodobacter sphaeroides

Wilkinson, David Arthur

January 2010

Bacteria achieve directed motion through their environments by integrating propulsion with chemical detection in the process of chemotaxis. Central to this process are the macromolecular protein structures of the flagellar motor and the chemoreceptor arrays, which are responsible for motility and chemical sensing, respectively. These protein complexes localise to different discrete subcellular positions in different bacterial species, and their correct subcellular localisation is often essential to their function. In the monotrichous α‐proteobacterium Rhodobacter sphaeroides, the flagellum is subpolar and two distinct sets of chemotaxis proteins localise to discrete polar and cytoplasmic positions within the cell. In this study, the development of software for the analysis of fluorescent microscopy images allowed cellular morphologies and the localisation and distribution of the chemoreceptor arrays of R.sphaeroides to be characterised in detail, showing that protein partitioning at cell division results in an asymmetric separation of both cytoplasmic and membrane‐bound protein components between daughter cells. The design of a fluorescence‐based assay for the analysis of gene expression assisted in demonstrating that expression of both the chemotaxis and motor genes of R.sphaeroides is regulated by the sigma factor, FliA, and its inhibitor, FlgM. FliA was then used to achieve varying expression of the chemotaxis genes, and the concentration dependence of array clustering was explored in microscopy images, revealing important differences between cluster formation in R.sphaeroides and other species. Additionally, FliA was identified as a regulator of flagellar number in R.sphaeroides, controlling a negative feedback‐loop in the hierarchy of flagellar assembly that represses flagellar formation upon secretion of FlgM. The complex regulatory pathway controlling R.sphaeroides flagellar assembly is the first identified system where completion of a single flagellum directly inhibits the production of a second, a mechanism that may be important to many monotrichous bacterial species.

571.29

Functional studies on a novel cytochrome c from Rhodobacter sphaeroides

Li, Bor-Ran

January 2009

SHP (Sphaeroides Heme Protein) is a monoheme cytochrome c of unknown function. In general, ligands cannot bind to ferric SHP, but some diatomic molecules, such as O2 or NO, can bind to ferrous SHP. The gene encoding SHP and genes encoding a diheme cytochrome c (DHC) and a b-type cytochrome (Cyt-b) are found in the same chromosome region in different species. In the case of Shewanella oneidensis MR-1, mRNA levels for SHP, DHC, and Cyt-b are up-regulated by nearly 10-fold when grown under anaerobic conditions using nitrate as the electron acceptor. Thus it is possible that the physiological role of SHP may be in nitrate metabolism. However, nitrate is too big to be a candidate substrate for SHP, and some nitrification steps need more than one electron transfer (SHP is a monoheme cytochrome). Therefore, we will focus on the nitrite reductase, nitric oxide reductase and nitric oxide dioxygenase activities of SHP. In this thesis it is shown that SHP can catalyse the reaction between oxygen and nitric oxide to give a nitrate ion as the final product. Thus a possible aerobic function for SHP as a nitric oxide dioxygenase is proposed. Aerobically, SHP is proposed to be a nitric oxide dioxygenase which utilizes the same mechanism as other NO dioxygenases, flavohemoglobin (HMP) and neuroglobin (Ngb). This mechanism is proposed to proceed via an oxy-ferrous complex (SHP2+-O2) which reacts with nitric oxide. A mechanism for the catalytic reaction with ferrous-NO complex is described. SHP2+-NO can be quickly converted back to ferrous SHP by reacting with superoxide liberated by SHP2+-O2 or from another source. In addition it is also found that Shewanella MR-1 wild type reveals a higher NO tolerance than the SHP knockout strain in aerobic conditions. The catalytic mechanism of NO dioxygenase is oxygen-dependent, but the SHP mRNA up-regulation in Shewanella oneidensis MR-1 grown with nitrate under anaerobic conditions indicates that SHP may also perform some anaerobic function and may possibly be involved in nitrate metabolism. This work found that SHP reveals anaerobic nitrite reductase activity. However, the catalytic efficiency of SHP is considerably lower than other nitrite reductases. This infers that although SHP can reduce nitrite in vitro, it is unlikely to function as a nitrite reductase in vivo. Ferrous SHP binds NO with a Kd of less than 1 μM, and does not auto-oxidise. Therefore, under anaerobic conditions SHP2+-NO must be processed by some other mechanism. In addition, biochemical results reveal that the SHP/DHC complex has NO reductase activity under anaerobic conditions. Unfortunately, this function was not proved in vivo. SHP was initially isolated from Rhodobacter sphaeroides and its structure was reported in 2000. Based upon this structure, SHP is clearly a class I cytochrome c with one axial histidine ligand to the heme iron. Unusually, however, it has an asparagine residue as the other axial heme ligand, and as such is unique among cytochromes c. For this reason it may be assumed that the asparagine plays a special role. This study reveals several potential reasons why SHP utilises asparagine as a heme ligand. Firstly, in the ferric form, asparagine 88 binds to the heme iron to prevent small molecules binding. Secondly, in the ferrous form it moves to allow oxygen to bind and form the oxy-ferrous complex, using hydrogen bonding for stability. Thirdly, using asparagine as a heme ligand creates a suitable redox potential for reduction by DHC, thus allowing NO dioxygenation.

572.6

Design of a BioBrick^TM Compatible Gene Expression System for <i>Rhodobacter sphaeroides</i>

Huo, Junling

01 May 2011

The concept of introducing engineering principles of abstraction and standardization into synthetic biology has received increasing attention in the past several years and continues to be in the forefront of synthetic biology. One direction being pursued by synthetic biologists is creation of modular biological parts (BioBrickTM) that can be readily synthesized and mixed together in different combinations. However, most standard BioBrickTM parts in the Registry were designed for E. coli, although synthesis of specific BioBrickTM parts for other bacteria, such as for yeast and cyanobacteria, have begun. Besides, at the present time, there are only three chassis, which include E. coli, Bacillus subtilis, and a cell-free chassis, available in the Registry. Thus, the choices of BioBrickTM chassis are very limited. In addition, most BioBrickTM parts in the Registry have not been characterized. In the present study, the BioBrickTM concept was extended to the photosynthetic bacteria, Rhodobacter sphaeroides. In order to do that, a BioBrickTM compatible gene expression system was designed to convert R. sphaeroides to potential solar powered bio-factories or bio-refineries. This gene expression system was composed of BioBrickTM promoters, Ribosome Binding Sites (RBSs), and terminators in a BioBrickTM compatible cloning vector and its function has been validated through the expression of fluorescent proteins. In addition, a bioluminescence-based BioBrickTM characterization method was developed in this study. This method was based on a cloning vector that includes two adjacent operons, with each expressing a different luciferase reporter gene. The measured optical signals from the two expressed bioluminescent reporters were then used to predict the performance of promoters, RBSs, and terminators. Based on this bioluminescence-based BioBrickTM characterization method, two BioBrickTM characterizations kits, one for E. coli and one for R. sphaeroides, were developed. BioBrickTM parts that include seven promoters, six RBSs, and six terminators were characterized using the E. coli characterization kit. R. sphaeroides BioBrickTM parts were characterized when R. sphaeroides containing the BioBrickTM measurement constructs were cultured by both anaerobic photosynthesis and by aerobic respiration respectively. The experimental results showed that the activities of these R. sphaeroides BioBrickTM parts were very similar for the cells growing under two different conditions.

design

BioBrickTM

compatible gene expression system

Rhodobacter spaeroides

Biology

Scale Up Of Panel Photobioreactors For Hydrogen Production By Pns Bacteria

Avcioglu, Sevler Gokce

01 September 2010

Production of hydrogen from biomass through the use of dark and photofermentative bacteria will be applicable in the future and a promising route. The aim of this study is to develop and to scale-up solar panel photobioreactors for the biological hydrogen production by photosynthetic purple non sulfur (PNS) bacteria on artificial substrates and on real dark fermentation effluent of molasses. The parameters studied are light intensity, temperature, feed stock, feed rate, pH, cell density, light and dark cycle and carbon to nitrogen ratio on hydrogen production. Continuous hydrogen production has been achieved on artificial medium and dark fermentor effluent of molasses containing acetate and lactate by Rhodobacter capsulatus wild type and (hup-) mutant strains in panel photobioreactors in indoor and outdoor conditions by fed batch operation. Laboratory (from 4 to 8 liters) and large scale (20 L) panel photobioreactors by using various designs and construction materials were developed. In this photobioreactors continuous hydrogen production was achieved by feeding. Na2CO3 can be used as buffer to keep the pH stable during long term operation on molasses dark fermentor effluent. The adjustment of the feedstock by dilution and buffer addition were found to be essential for the long term stability of pH, biomass and H2 production for both in indoor and outdoor applications.

TA Bioengineering 164

Das Photoreaktionszentrum aus Rhodobacter sphaeroides als Modellmembranprotein zur Reinigung, Rekonstitution in Liposomen aus ungewöhnlichen Phospholipiden, Charakterisierung und heterologen Expression

Peters, Heinz.

January 2001

Stuttgart, Univ., Diss., 2001.

Studies on 3-Hydroxypropionate Metabolism in <i>Rhodobacter sphaeroides</i>

Carlson, Steven Joseph

January 2018

No description available.

Microbiology

Rhodobacter

sphaeroides

3-hydroxypropionate

3HP

metabolism

ethylmalonyl-CoA pathway

Optimization production conditions of photosynthetic purple bacteria biomass at pilot scale to remove sulphide from aquaculture pond

Do, Thi Lien, Do, Thi To Uyen, Le, Thi Nhi Cong, Hoang, Phuong Ha, Cung, Thi Ngoc Mai

16 January 2019

For the purpose of sulphide removal in aquaculture ponds, three strains (name: TH21, QN71, QN51) were isolated and selected with the highest sulphide removal activity from Thanh Hoa and Quang Ninh coastal zones. These strains have identified and tested in a number of aquaculture ponds in different areas with good water quality results. With the objective of purple non sulfur bacteria biomass production containing 3 selected strains for wide application and suitable price for farmers, in this study, we study on optimum conditions of mixed purple non sulfur bacteria biomass production at pilot scale. The results showed that the sources of substrates were soybean meal (1g/l) and acetate (0.5g/l). These substrates are low cost, easy to find, convenient in large culture. The mixture of photosynthetic bacteria can be cultured in glass tanks, under micro aerobic and natural lighting conditions that produce highly concentrated photosynthetic bacteria and lowest rest media. / Nhằm mục tiêu xử lý sulphide trong môi trường nuôi trồng thủy sản, chúng tôi đã phân lập và lựa chọn được ba chủng vi khuẩn tía quang hợp có khả năng loại bỏ sulphide cao nhất ký hiệu TH21, QN71, QN52 từ các vùng ven biển Thanh Hóa và Quảng Ninh. Các chủng này đã được định loại và thử nghiệm tại một số ao nuôi thủy sản ở các vùng khác nhau thu được kết quả tốt về chất lượng nước. Để tạo chế phẩm vi khuẩn tía quang hợp từ 3 chủng lựa chọn được ứng dụng rộng rãi và có giá thành phù hợp cho nông hộ, trong nghiên cứu này, chúng tôi nghiên cứu tối ưu hóa các điều kiện sản xuất sinh khối hỗn hợp 3 chủng vi khuẩn tía quang hợp ở quy mô pilot. Kết quả cho thấy đã tìm kiếm được nguồn cơ chất là bột đậu tương (1g/l) và acetate (0.5g/l) là những chất có giá thành thấp, dễ tìm kiếm, thuận tiện trong nhân nuôi ở quy mô lớn. Hỗn hợp vi khuẩn tía quang hợp có thể nuôi trong các bể kính, ở điều kiện vi hiếu khí, có ánh sáng chiếu tự nhiên có thể sản xuất được chế phẩm vi khuẩn tía quang hợp có mật độ cao, cơ chất còn lại sau sản xuất là ít nhất.

info:eu-repo/classification/ddc/363.7

ddc:363.7

Control of the unidirectional motor in Rhodobacter sphaeroides

Brown, Mostyn T.

January 2009

The control of the flagellar motor in Rhodobacter sphaeroides was investigated. Unlike most flagellar motors which are controlled by reversing the direction of rotation, the R. sphaeroides motor is controlled via a stop-start mechanism. Advanced optical microscopy was employed alongside genetic, biochemical, and behavioural techniques. High-resolution measurements of rotating beads on flagellar stubs revealed that the R. sphaeroides motor is similar to its E. coli counterpart, rotating counterclockwise at comparable torques/speeds (1,300 pNnm/rad at stall torque), and exhibiting transient step changes in speed. The mean stop duration, mean stop frequency (number of stops per s), and run bias (fraction of time spent rotating) of wild-type at steady-state were 0.66 ± 1.01 s, 0.31 ± 0.19 s-1, and 0.80 ± 0.20, respectively. Manipulating signal inputs to the motor genetically, or by exposing cells to chemotactic stimuli revealed that (i) without chemotactic stimulation the motor rotates continuously, (ii) phosphorylated CheYs are required to stop the motor, and (iii) the chemotaxis system cannot control the speed of rotation of the motor (termed chemokinesis) as previously reported. Complementation studies revealed that CheY3, CheY4, and CheY5 are functionally equivalent. The copy numbers per cell of important CheYs were found to vary greatly under the conditions tested (<1,000, ~3,000, ~60,000 for CheY3, CheY4, and CheY6 respectively). To determine how CheY-P binding causes the motor to stop, external force (viscous flow or optical tweezers) was applied to chemotactically stopped motors. CheY-P binding might either cause the torque-generating units to disengage from the rotor, analogous to a clutch, or trigger the rotor to jam, analogous to a brake. The rotor resisted re-orientation during a chemotactic stop implying that the motor was held in a locked state. The value of torque resisting forward motion (keeping it locked) was estimated to be 2-3 x stall torque (2,500-4,000 pNnm/rad). Furthermore beads attached to flagellar stubs stop at fixed angles for several seconds, showing no large-scale Brownian motion. Step analysis revealed that these stop events occur at 27-28 discrete angles around the motor, which most likely reflect the periodicity of the rotor (i.e. copies of FliG). This represents the first experimental resolution of steps in the rotation of a wild-type bacterial flagellar motor with a full complement of torque-generating units.

579