Genetic engineering of the yeast Saccharomyces cerevisiae to ferment cellobiose

Van Rooyen, Ronel, 1976-

03 1900

Dissertation (PhD)--Stellenbosch University, 2007. / PCT patent registered: https://www.google.com/patents/WO2009034414A1?cl=en&dq=pct/ib2007/004098&hl=en&sa=X&ei=b7AxUsSZK4jB0gWi14HgCQ&ved=0CEkQ6AEwAg USA: https://www.google.com/patents/US20110129888?dq=pct/ib2007/004098&ei=b7AxUsSZK4jB0gWi14HgCQ&cl=en / USA patent registered: https://www.google.com/patents/US20110129888?dq=pct/ib2007/004098&ei=b7AxUsSZK4jB0gWi14HgCQ&cl=en / ENGLISH ABSTRACT: The conversion of cellulosic biomass into fuels and chemicals has the potential to positively impact the South African economy, but is reliant on the development of low-cost conversion technology. Perhaps the most important progress to be made is the development of “consolidated bioprocessing” (CBP). CBP refers to the conversion of pretreated biomass into desired product(s) in a single process step with either a single organism or consortium of organisms and without the addition of cellulase enzymes. Among the microbial hosts considered for CBP development, Saccharomyces cerevisiae has received significant interest from the biotechnology community as the yeast preferred for ethanol production. The major advantages of S. cerevisiae include high ethanol productivity and tolerance, as well as a well-developed gene expression system. Since S. cerevisiae is non-cellulolytic, the functional expression of at least three groups of enzymes, namely endoglucanases (EC 3.2.1.4); exoglucanases (EC 3.2.1.91) and β-glucosidases (EC 3.2.1.21) is a prerequisite for cellulose conversion via CBP. The endo- and exoglucanases act synergistically to efficiently degrade cellulose to soluble cellodextrins and cellobiose, whereas the β-glucosidases catalyze the conversion of the soluble cellulose hydrolysis products to glucose. This study focuses on the efficient utilization of cellobiose by recombinant S. cerevisiae strains that can either hydrolyse cellobiose extracellularly or transport and utilize cellobiose intracellularly. Since it is generally accepted that S. cerevisiae do not produce a dedicated cellobiose permease/transporter, the obvious strategy was to produce a secretable β-glucosidase that will catalyze the hydrolysis of cellobiose to glucose extracellularly. β-Glucosidase genes of various fungal origins were isolated and heterologously expressed in S. cerevisiae. The mature peptide sequence of the respective β-glucosidases were fused to the secretion signal of the Trichoderma reesei xyn2 gene and expressed constitutively from a multi-copy yeast expression vector under transcriptional control of the S. cerevisiae PGK1 promoter and terminator. The resulting recombinant enzymes were characterized with respect to pH and temperature optimum, as well as kinetic properties. The maximum specific growth rates (μmax) of the recombinant strains were compared during batch cultivation in high-performance bioreactors. S. cerevisiae secreting the recombinant Saccharomycopsis fibuligera BGL1 enzyme was identified as the best strain and grew at 0.23 h-1 on cellobiose (compared to 0.29 h-1 on glucose). More significantly, was the ability of this strain to anaerobically ferment cellobiose at 0.18 h-1 (compared to 0.25 h-1 on glucose). However, extracellular cellobiose hydrolysis has two major disadvantages, namely glucose’s inhibitory effect on the activity of cellulase enzymes as well as the increased risk of contamination associated with external glucose release. In an alternative approach, the secretion signal from the S. fibuligera β-glucosidase (BGL1) was removed and expressed constitutively from the above-mentioned multi-copy yeast expression vector. Consequently, the BGL1 enzyme was functionally produced within the intracellular space of the recombinant S. cerevisiae strain. A strategy employing continuous selection pressure was used to adapt the native S. cerevisiae disaccharide transport system(s) for cellobiose uptake and subsequent intracellular utilization. RNA Bio-Dot results revealed the induction of the native α-glucoside (AGT1) and maltose (MAL) transporters in the adapted strain, capable of transporting and utilizing cellobiose intracellularly. Aerobic batch cultivation of the strain resulted in a μmax of 0.17 h-1 and 0.30 h-1 when grown in cellobiose- and cellobiose/maltose-medium, respectively. The addition of maltose significantly improved the uptake of cellobiose, suggesting that cellobiose transport (via the combined action of the maltose permease and α-glucosidase transporter) is the rate-limiting step when the adapted strain is grown on cellobiose as sole carbon source. In agreement with the increased μmax value, the substrate consumption rate also improved significantly from 0.25 g.g DW-1.h-1 when grown on cellobiose to 0.37 g.g DW-1.h-1 upon addition of maltose to the medium. The adapted strain also displayed several interesting phenotypical characteristics, for example, flocculation, pseudohyphal growth and biofilm-formation. These features resemble some of the properties associated with the highly efficient cellulase enzyme systems of cellulosome-producing anaerobes. Recombinant S. cerevisiae strains that can either hydrolyse cellobiose extracellularly or transport and utilize cellobiose intracellularly. Both recombinant strains are of particular interest when the final goal of industrial-scale ethanol production from cellulosic waste is considered. However, the latter strain’s ability to efficiently remove cellobiose from the extracellular space together with its flocculating, pseudohyphae- and biofilm-forming properties can be an additional advantage when the recombinant S. cerevisiae strain is considered as a potential host for future CBP technology. / AFRIKAANSE OPSOMMING: Die omskakeling van sellulose-bevattende biomassa na brandstof en chemikalieë beskik oor die potensiaal om die Suid-Afrikaanse ekonomie positief te beïnvloed, indien bekostigbare tegnologie ontwikkel word. Die merkwaardigste vordering tot dusvêr kon in die ontwikkeling van “gekonsolideerde bioprosessering” (CBP) wees. CBP verwys na die eenstap-omskakeling van voorafbehandelde biomassa na gewenste produkte met behulp van ‘n enkele organisme of ‘n konsortium van organismes sonder die byvoeging van sellulase ensieme. Onder die mikrobiese gashere wat oorweeg word vir CBP-ontwikkeling, het Saccharomyces cerevisiae as die voorkeur gis vir etanolproduksie troot belangstelling by die biotegnologie-gemeenskap ontlok. Die voordele van S. cerevisiae sluit in hoë etanol-produktiwiteit en toleransie, tesame met ‘n goed ontwikkelde geen-uitdrukkingsisteem. Aangesien S. cerevisiae nie sellulose kan benut nie, is die funksionele uitdrukking van ten minste drie groepe ensieme, naamlik endoglukanases (EC 3.2.1.4); eksoglukanases (EC 3.2.1.91) en β-glukosidases (EC 3.2.1.21), ‘n voorvereiste vir die omskakeling van sellulose via CBP. Die sinergistiese werking van endo- en eksoglukanases word benodig vir die effektiewe afbraak van sellulose tot oplosbare sello-oligosakkariede en sellobiose, waarna β-glukosidases die finale omskakeling van die oplosbare sellulose-afbraak produkte na glukose kataliseer. Hierdie studie fokus op die effektiewe benutting van sellobiose m.b.v. rekombinante S. cerevisiae-rasse met die vermoeë om sellobiose ekstrasellulêr af te breek of dit op te neem en intrasellulêr te benut. Aangesien dit algemeen aanvaar word dat S. cerevisiae nie ‘n toegewyde sellobiosepermease/ transporter produseer nie, was die mees voor-die-hand-liggende strategie die produksie van ‘n β-glukosidase wat uitgeskei word om sodoende die ekstrasellulêre hidroliese van sellobiose na glukose te kataliseer. β-Glukosidase gene is vanaf verskeie fungi geïsoleer en daaropvolgend in S. cerevisiae uitgedruk. Die geprosesseerde peptiedvolgorde van die onderskeie β-glukosidases is met die sekresiesein van die Trichoderma reesei xyn2-geen verenig en konstitutief vanaf ‘n multikopie-gisuitdrukkingsvektor onder transkripsionele beheer van die S. cerevisiae PGK1 promotor en termineerder uitgedruk. Die gevolglike rekombinante ensieme is op grond van hul pH en temperatuur optima, asook kinetiese eienskappe, gekarakteriseer. Die maksimum spesifieke groeitempos (μmax) van die rekombinante rasse is gedurende aankweking in hoë-verrigting bioreaktors vergelyk. Die S. cerevisiae ras wat die rekombinante Saccharomycopsis fibuligera BGL1 ensiem uitskei, was as the beste ras geïdentifiseer en kon teen 0.23 h-1 op sellobiose (vergeleke met 0.29 h-1 op glukose) groei. Meer noemenswaardig is the ras se vermoë om sellobiose anaërobies teen 0.18 h-1 (vergeleke met 0.25 h-1 op glukose) te fermenteer. Ekstrasellulêre sellobiose-hidroliese het twee groot nadele, naamlik glukose se onderdrukkende effek op die aktiwiteit van sellulase ensieme, asook die verhoogde risiko van kontaminasie wat gepaard gaan met die glukose wat ekstern vrygestel word. ’n Alternatiewe benadering waarin die sekresiesein van die S. fibuligera β-glucosidase (BGL1) verwyder en konstitutief uitgedruk is vanaf die bogenoemde multi-kopie gisuitrukkingsvektor, is gevolg. Die funksionele BGL1 ensiem is gevolglik binne-in die intrasellulêre ruimte van die rekombinante S. cerevisiae ras geproduseer. Kontinûe selektiewe druk is gebruik om die oorspronklike S. cerevisiae disakkaried-transportsisteme vir sellobiose-opname and daaropvolgende intrasellulêre benutting aan te pas. RNA Bio-Dot resultate het gewys dat die oorspronklike α-glukosied (AGT1) en maltose (MAL) transporters in die aangepaste ras, wat in staat is om sellobiose op te neem en intrasellulêr te benut, geïnduseer is. Aërobiese kweking van die geselekteerde ras het gedui dat die ras teen 0.17 h-1 en 0.30 h-1 groei in onderskeidelik sellobiose en sellobiose/maltose-medium. Die byvoeging van maltose het die opname van sellobiose betekenisvol verbeter, waarna aangeneem is dat sellobiose transport (via die gekombineerde werking van die maltose permease en α-glukosidase transporter) die beperkende stap gedurende groei van die geselekteerde ras op sellobiose as enigste koolstofbron is. In ooreenstemming hiermee, het die substraatbenuttingstempo ook betekenisvol toegeneem van 0.25 g.g DW-1.h-1, gedurende groei op sellobiose, tot 0.37 g.g DW-1.h-1 wanneer maltose by die medium gevoeg word. Die geselekteerde ras het ook verskeie interessante fenotipiese kenmerke getoon, byvoorbeeld flokkulasie, pseudohife- en biofilm-vorming. Hierdie eienskappe kom ooreen met sommige van die kenmerke wat met die hoogs effektiewe sellulase ensiem-sisteme van sellulosomeproduserende anaerobe geassosieer word. Hierdie studie beskryf die suksesvolle konstruksie van ‘n rekombinante S. cerevisiae ras met die vermoë om sellobiose ekstrasellulêr af te breek of om dit op te neem en intrasellulêr te benut. Beide rekombinante rasse is van wesenlike belang indien die einddoel van industriële-skaal etanolproduksie vanaf selluloseafval oorweeg word. Die laasgenoemde ras se vermoë om sellobiose effektief uit die ekstrasellulêre ruimte te verwyder tesame met die flokkulasie, pseudohife- en biofilm-vormings eienskappe kan ‘n addisionele voordeel inhou, indien die rekombinante S. cerevisiae ras as ‘n potensiële gasheer vir toekomstige CBP-tegnologie oorweeg word.

Cellulose -- Biodegradation

Cellulose -- Biotechnology

Cellulase

Theses -- Microbiology

Dissertations -- Microbiology

An investigation into genetic improvement in reproductive efficiency in beef cattle through the unravelling of composite reproductive traits

Rust, Tina

03 1900

Dissertation (PhD(Agric))--University of Stellenbosch, 2007. / ENGLISH ABSTRACT: This study is a search for a quantifiable measure which estimates the genetic merit of female animals’ breeding efficiency. For practical reasons, such a measure must be both simple and inexpensive to record, irrespective of the herd management strategy. A literature investigation was undertaken to summarize breeding objectives for reproduction efficiency and to review different ways of expressing genetic reproduction efficiency. Traits to assess these in terms of the breeding objective, merits and requirements in terms of data collection are discussed. During the lifetime of a cow events occur which influence her fertility. A distinction is made between component traits and aggregate traits: a component trait points to one event, while aggregate traits are composites of more than one event. Although all the traits discussed seem relevant for breeding value estimation, the practical application depends on the herd management system in use. Age at first calving and days to calving are component traits that are easily and inexpensively measurable. Heritability estimates for the age at first calving were moderate. The heritability estimated for days to calving was 0.09. Calving rate comes close to the overall breeding objective. The estimated heritability of calving rate is low (0.04), resulting in slow genetic improvement. Calving success was defined and investigated even though some constraints exist. A sire model proved that genetic variation exists for calving success on the underlying scale. The corresponding heritability estimate was 0.27. Three categorical traits were defined. For stayability a sire variance of 0.41 was estimated with a heritabitity on the underlying scale of 0.27. The sire variances and heritabilities estimated for retention and calf tempo were high. Of the three traits, calf tempo is the one that reflects the true fertility of the bull’s female progeny. Calf tempo was redefined as net breeding merit, a trait describing the retention of male animals and the reproductive performance of their female offspring. The obtained sire variances show that the trait is heritable and can be improved by selection. Net breeding merit gives an indication of the ‘success’ of sires in a given population. A heritability estimate of 0.20 was estimated on a data set comprising offspring of bulls older than nine years, but when offspring of all sires were included, heritability estimates of 0.08 and 0.11 for the Afrikaner and Bonsmara, respectively, were found. Adjusting for young females was investigated by using the best linear unbiased estimate (BLUE) deviations to derive adjustment factors for herd level in order to predict performance for net breeding merit. Variation in the BLUE deviations occurred between all age class groups for the Afrikaner, whereas for the Bonsmara the variation between the BLUE deviations for the 3 year olds seems greater than the variation in the other age groups. It is suggested that the standardized curve for herd performance level derived from the BLUE deviations be used to adjust the phenotypic values of younger animals. This way the comparison between older and younger animals should be more valid. In conclusion, reproductive traits are heritable and genetic improvement can be achieved through selection. Any economical viable beef enterprise should include at least one trait in their selection criteria that will improve the reproductive efficiency. / AFRIKAANSE OPSOMMING: Hierdie studie is ‘n ondersoek na ‘n kwantifiseerbare maatstaf wat die genetiese meriete van vroulike diere se teeldoeltreffendheid beraam. Om praktiese redes moet so ‘n beraming sowel eenvoudig as goedkoop wees om te bepaal, onafhanklik van die kudde bestuurstrategie. ‘n Literatuurstudie is onderneem om die teeldoeleindes vir reproduktiewe doeltreffendheid op te som, sowel as om die verskillende wyses van genetiese reproduksiedoeltreffendheid beskrywing onder oë te neem. Verskeie eienskappe om hierdie beskrywings in terme van teeldoeleindes, meriete en dataversamelings-vereistes te raam, word bespreek. Gedurende ‘n koei se leeftyd kom gebeurtenisse voor wat haar vrugbaarheid beïnvloed. Daar word onderskei tussen komponenteienskappe en aggregaateienskappe: ‘n komponenteienskap verwys na een gebeurtenis, terwyl aggregaateienskappe na samestellings van meer as een gebeurtenis verwys. Hoewel al die eienskappe wat bespreek word relevant voorkom, sal die praktiese toepassing afhang van die kuddebestuurstelsel in gebruik. Ouderdom by eerste kalwing en dae tot kalwing is komponenteienskappe wat maklik en goedkoop bepaal kan word. Oorerflikheidsramings vir die ouderdom van eerste kalwing was matig. Die oorerflikheidsraming vir dae tot kalwing was 0.09. Kalffrekwensie is baie na aan die oorkoepelende teeldoelwit. Die geraamde oorerflikheid vir kalffrekwensie is laag (0.04), wat stadige genetiese verbetering tot gevolg het. Kalfsukses is gedefinieer en ondersoek, hoewel enkele beperkings bestaan het. ‘n Vaar-model het aangetoon dat genetiese variasie ten opsigte van kalfsukses op die onderliggende skaal bestaan. Die ooreenkomstige oorerflikheidsraming was 0.27. Drie kategoriese eienskappe is gedefinieer. Vir blyvermoë in die kudde is ‘n vaar-variansie van 0.41 geraam, met ‘n oorerflikheid van 0.27 op die onderliggende skaal. Die vaar-variansies en oorerflikhede wat vir retensie en kalftempo bereken is, was hoog. Van die drie eienskappe is kalftempo die een wat die ware vrugbaarheid van die bul se vroulike nageslag reflekteer. Kalftempo is herdefinieer as netto teelmeriete, ‘n eienskap wat die retensie van manlike diere en die reproduktiewe prestasie van hulle vroulike nasate beskryf. Die verkreë vaar-variasies wys dat die eienskap oorerflik is en verbeter kan word met seleksie. Netto teelmeriete gee ‘n aanduiding van die “sukses” van ‘n vaar in ‘n gegewe populasie. ‘n Oorerflikheidsraming van 0.30 is verkry op ‘n datastel bestaande uit die nageslag van bulle ouer as nege jaar, maar as die nageslag van alle vaars ingesluit is, was die oorerflikheidsraming onderskeidelik 0.08 en 0.11 vir die Afrikaner en Bonsmara. Aanpassing vir jong vroulike diere is ondersoek deur gebruik te maak van die beste lineêre onpartydige beramings (BLUE) om korreksiefaktore vir die kuddevlak te verkry, ten einde die prestasie ten opsigte van netto teelmeriete te voorspel. Variasies in die BLUE afwykings het voorgekom tussen alle ouderdomsgroepe vir die Afrikaner, terwyl vir die Bonsmara die variasie tussen BLUE afwykings vir die 3-jaar oud diere groter was as vir die ander ouderdomsgroepe. Dit word voorgestel dat die gestandardiseerde kurwe vir kuddeprestasievlak wat afgelei word van BLUE afwykings gebruik word om die fenotipiesewaardes van jonger diere aan te pas. Op hierdie wyse behoort die vergelyking tussen ouer en jonger diere meer geldig te wees. Ten slotte, reproduktiewe eienskappe is oorerfbaar en genetiese vordering is moontlik deur seleksie. Enige ekonomies lewensvatbare vleisbees-onderneming behoort ten minste een eienskap wat die reproduktiewe doeltreffendhied sal verbeter, in te sluit in seleksie kriteria.

Beef cattle -- Genetic engineering

Beef cattle -- Reproduction

Theses -- Animal sciences

Dissertations -- Animal sciences

Ecology and genetic stability of Tn5 mutants of bean rhizobia in Sonoran desert soils.

Pillai, Suresh Divakaran.

January 1989

Five transposon Tn5 mutants of bean rhizobia (Rhizobium leguminosarum b.v. phaseoli) and the wild type strain were used in ecological studies to evaluate the efficacy of transposon Tn5 as a phenotypic marker in rhizobia for ecological studies in two Sonoran desert soils. All mutants possessed chromosomal insertions of the transposable element. Survival of each mutant strain was compared to that of the wild type strain under non stress, moisture stress and temperature stress conditions in Pima silty clay loam and Brazil to sandy loam. The genetic stability of Tn5 in terms of transposition of the element within the chromosome and the Tn5 coded antibiotic resistant phenotype was determined in cells recovered throughout the survival period. Under non stress conditions, the viable Tn5 mutant population decreased in size. Two mutants showed significantly (p < 0.01) lower populations than the wild type at the end of 30 days in the silty clay loam. In the sandy loam, four of the five mutant populations were significantly lower than the wild type. Tn5 was genetically stable in both soils. Under moisture stress conditions, the decline of the Tn5 mutant and wild type populations corresponded to a decline in soil moisture content. The finer textured soil afforded more protection to the cells than the coarse textured soil. There were no indications of Tn5 instability under moisture stress. In both soils under temperature stress, sizes of all populations declined rapidly and after 12 days, the mutant cells when screened using the Tn5 coded markers were significantly less in numbers than the wild type indicating a loss of Tn5 coded antibiotic resistance phenotype. There were no significant differences in numbers between wild type and mutant cells when screened using only the intrinsic markers. DNA:DNA hybridizations confirmed that the lack of Tn5 coded antibiotic resistance phenotype was probably not due to a deletion or transposition of the element. Under non stress conditions Tn5 is a useful ecological marker, but each Tn5 mutant has to be evaluated independently under specific environmental conditions to determine the efficacy of Tn5 as an ecological marker.

Rhizobium.

Microbial genetic engineering.

Soil microbiology -- Arizona.

Plasmids.

Insertion elements, DNA.

Modular languages for systems and synthetic biology

Pedersen, Michael

January 2010

Systems biology is a rapidly growing field which seeks a refined quantitative understanding of organisms, particularly studying how molecular species such as metabolites, proteins and genes interact in cells to form the complex emerging behaviour exhibited by living systems. Synthetic biology is a related and emerging field which seeks to engineer new organisms for practical purposes. Both fields can benefit from formal languages for modelling, simulation and analysis. In systems biology there is however a trade-off in the landscape of existing formal languages: some are modular but may be difficult for some biologists to understand (e.g. process calculi) while others are more intuitive but monolithic (e.g. rule-based languages). The first major contribution of this thesis is to bridge this gap with a Language for Biochemical Systems (LBS). LBS is based on the modular Calculus of Biochemical Systems and adds e.g. parameterised modules with subtyping and a notion of nondeterminism for handling combinatorial explosion. LBS can also incorporate other rule-based languages such as Kappa, hence adding modularity to these. Modularity is important for a rational structuring of models but can also be exploited in analysis as is shown for the specific case of Petri net flows. On the synthetic biology side, none of the few existing dedicated languages allow for a high-level description of designs that can be automatically translated into DNA sequences for implementation in living cells. The second major contribution of this thesis is exactly such a language for Genetic Engineering of Cells (GEC). GEC exploits the recent advent of standard genetic parts (“biobricks”) and allows for the composition of such parts into genes in a modular and abstract manner using logical constraints. GEC programs can then be translated to DNA sequences using a constraint satisfaction engine based on a given database of genetic parts.

579

Improvement of abiotic stress tolerance and calcium-deficiency disorder resistance of tomato plants

Wu, Qingyu

January 1900

Doctor of Philosophy / Department of Horticulture, Forestry, and Recreation Resources / Sunghun Park / Plants are continuously exposed to numerous abiotic stresses, which adversely affect plant growth, development, and yield. Plants have developed different signaling pathways to cope with abiotic stresses, and some of the pathways converge to help plants tolerate simultaneous stresses. Here, we report ectopic expression of an Arabidopsis glutaredoxin AtGRXS17 that confers tolerance to multiple abiotic stresses in tomato plants. In yeast assays, AtGRXS17 co-localized with yeast ScGrx3 in the nucleus and suppressed the sensitivity of yeast grx3grx4 double mutants to oxidative stress and heat shock. In plants, GFP-AtGRXS17 fusion proteins initially localized in the cytoplasm but migrated to the nucleus during heat stress. Ectopic expression of AtGRXS17 in tomato plants minimized photo-oxidation of chlorophyll and reduced oxidative damage of cell membrane systems under heat stress. Furthermore, expression of the heat shock transcription factor (HSF) and heat shock protein (HSP) genes was up-regulated in AtGRXS17-expressing tomato plants during heat stress when compared to wild-type controls. Under cold, drought, and oxidative stress conditions, AtGRXS17-expressing tomato plants also displayed more vigorous growth and less physiological damage than those of the wild-type control plants. Quantitative real-time PCR (qRT-PCR) analysis indicated that expression of AtGRXS17 alters multiple stress defense signaling pathways, including the Abscisic Acid (ABA) and C-Repeat Binding Factors (CBF) pathways. The results revealed a conserved function for a glutaredoxin protein in abiotic stress adaptation, and manipulation of AtGRXS17 may be a useful approach to improve crop stress tolerance and understand plant signaling under abiotic stress conditions. Deregulated expression of an Arabidopsis H[superscript]+/Ca[superscript]2[superscript]+ antiporter (sCAX1) in agricultural crops increases total calcium (Ca[superscript]2[superscript]+) but may result in yield loses due to calcium-deficiency like symptoms. Here we demonstrate that co-expression of a maize calreticulin (CRT, a Ca[superscript]2[superscript]+ binding protein located at endoplasmic reticulum) in sCAX1-expressing plants mitigated these adverse effects while maintaining enhanced Ca[superscript]2[superscript]+ content. Co-expression of CRT and sCAX1 could alleviate the hypersensitivity to ion imbalance in tobacco plants. Furthermore, blossom-end rot (BER) in tomato may be linked to changes in CAX activity and enhanced CRT expression mitigated BER in sCAX1 expressing lines. These findings suggest that co-expressing Ca[superscript]2[superscript]+ transporters and binding protein at different intracellular compartments can alter the content and distribution of calcium within the plant matrix.

GRX

Genetic engineering

ROS

Abiotic stress

Biology, Plant Physiology (0817)

Horticulture (0471)

The chitinolytic enzyme system of the compost-dwelling thermophilic fungus Thermomyces lanuginosus

Zhang, Meng

January 2014

Submitted in complete fulfillment for the Degree of Master of Technology (Biotechnology), Durban University of Technology, Durban, South Africa, 2014. / Chitin, a highly insoluble 1,4- -linked polymer of N-acetyl- -D-glucosamine, is the second-most abundant bio-polysaccharide in nature after cellulose. Most chitinolytic fungi are known to produce more than one kind of chitinase. The recent sequencing of the Thermomyces lanuginosus SSBP genome by our group has revealed four putative family 18 chitinases. In this study, three novel chitinase genes (chitl, chit2 and chit3) and the previously reported chit4 gene were cloned from Thermomyces lanuginosus SSBP and their gene structures were analysed. chit3, encoding a 36.6 kDa protein, and chit4, encoding a 44.1 kDa protein, were successfully expressed in Pichia pastoris. The recombinant Chit3 and Chit4 enzymes exhibited optimum activity at pH 4.0 and 5.0 and at 40oC and 50°C, respectively. Chit3 was stable at 40oC and retained 71% of its activity at 50°C after 60 min, while Chit4 was stable at 50°C and retained 56% of its activity at 60°C after 30 min. Both enzymes produced chitobiose as the major product using colloidal chitin, chitooligosaccharides and shrimp shell powder as substrates. Of the fungal strains tested, Chit3 displayed antifungal activity against Penicillium sp. and Aspergillus sp. This is the first report on the multi-chitinolytic system of T. lanuginosus and enzyme characterization has shown the potential of the enzymes to be used in degradation of the under-utilized bio-resource chitin. / PDF Full-text unavailable. Please refer to hard copy for Full-text / M

Biotechnology

Chitin--Genetics

Chitin--Biotechnology

Genomes

Thermophilic fungi--Genetic engineering

Enzymes--Industrial applications

Parental responsibility, autonomy and genetic enchancement.

Annegarn, Eric

11 June 2014

This report analyses the responsibilities and harms that are imposed upon parents when genetic enhancement is made institutionally available and shows that there is a counter-intuitive impact upon parental autonomy. The institutional availability of genetic enhancement may be a good thing and may increase autonomy. My thesis is that harm is caused to parents because of the negative implications that arise from the institutional availability of genetic enhancement: their autonomy may be diminished irrespective of their reasons for rejecting genetic enhancement.

Parenting.

Responsibility.

Biological Computation: the development of a genomic analysis pipeline to identify cellular genes modulated by the transcription / splicing factor srsf1

Unknown Date

SRSF1 is a widely expressed mammalian protein with multiple functions in the regulation of gene expression through processes including transcription, mRNA splicing, and translation. Although much is known of SRSF1 role in alternative splicing of specific genes little is known about its functions as a transcription factor and its global effect on cellular gene expression. We utilized a RNA sequencing (RNA-¬‐Seq) approach to determine the impact of SRSF1 in on cellular gene expression and analyzed both the short term (12 hours) and long term (48 hours) effects of SRSF1 expression in a human cell line. Furthermore, we analyzed and compared the effect of the expression of a naturally occurring deletion mutant of SRSF1 (RRM12) to the full-¬‐length protein. Our analysis reveals that shortly after SRSF1 is over-¬‐expressed the transcription of several histone coding genes is down-¬‐regulated, allowing for a more relaxed chromatin state and efficient transcription by RNA Polymerase II. This effect is reversed at 48 hours. At the same time key genes for the immune pathways are activated, more notably Tumor Necrosis Factor-¬‐Alpha (TNF-¬‐α), suggesting a role for SRSF1 in T cell functions. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2017. / FAU Electronic Theses and Dissertations Collection

Gene expression.

Computational biology.

Markov processes.

Bioinformatics.

Genetic engineering.

Molecular biology.

Impact of a Genetically Engineered Probiotic Therapy and IGF-1 Genomics in the PAHenu2 Mouse Model of PKU

Durrer, Katherine Elaine

12 1900

Absence of functional phenylalanine hydroxylase results in phenylketonuria (PKU). Viable treatments remain few, expensive and secondary conditions such as osteopenia occur in most PKU patients. Objective 1: Given the recently described roles of gut microbes to aid host digestion, an orally administered genetically engineered probiotic as the delivery vehicle for enzyme replacement therapy was created. The engineered probiotic, pHENOMMenal, produced phenylalanine ammonia lyase with significant production of trans-cinnamate (phenylalanine cleavage product) in vitro and resulted in a reduction of 515 μM in blood phenylalanine when fed to PKU animals for 14 days (from 2307µM ± 264µM to 1792µM ± 261µM, n = 6, P < 0.05). The control probiotic produced no change in blood phenylalanine. Thus, pHENOMMenal treatment in PKU mice demonstrated engineered microbes could compensate for a metabolic deficiency of the host. Objective 2: Evaluate the PAHenu2 mouse model of PKU for a genetic discrepancy causing ocular enlargement and delayed development observed only after the PAHenu2 mutation was crossed to the C57BL/6J mouse. When compared to healthy littermates, ELISA indicated a consistent but insignificant decrease in plasma IGF-1 and an increase in ocular IGF-1 in PKU animals. SNP screening demonstrated a differential inheritance of IGF-1 alleles in healthy and PKU animals based on PAH allele inheritance. Ocular and developmental phenotypes in the PAHenu2 colony match those described in previous IGF-1 studies. Understanding the IGF-1 inheritance discrepancy will enable better osteopenia research using PAHenu2 mice and allow breeding of a healthier mouse colony for continued research. Collectively the results from this work describe a new therapeutic approach for treatment of PKU as well as a better understanding of the PAHenu2 mouse model to study this disease.

PKU

metabolism

probiotic

IGF-1

Probiotics.

Phenylketonuria -- Treatment.

Genetic engineering.

Somatomedin.

Genetic engineering tools for transforming the nucleus and chloroplast of microalgae

Herrera Rodriguez, Leopoldo

January 2017

Biotechnology of microalgae is a fast-growing field and several species have become targets for transgenic manipulation. Microalgae provide low-cost and scalable production platforms for manufacturing recombinant proteins and other high value products. However, the exploitation of microalgae as expression systems is restricted by the low yield of recombinant proteins and the limited availability of tools for the genetic manipulation of commercially important species. This thesis explores transgene instability and gene autoregulation as causes for low recombinant protein accumulation in the chloroplast of Chlamydomonas reinhardtii and describes the isolation of a mutant phytoene desaturase (PDS) gene which confers resistance to the herbicide norflurazon for future use as a selection marker for the marine microalga Dunaliella tertiolecta. Recombination between short dispersed DNA repeats (SDR) found in the chloroplast genome of C. reinhardtii was identified as a cause of transgene instability. The genes coding for β-glucuronidase (GUS) and peridinin-chlorophyll binding protein (PCP) were inserted in the chloroplast genome next to the atpB 3' UTR by homologous recombination. Recombination of a 30bp SDR located within the 3' UTR of atpB was identified as the cause of transgene excision in the transplastomic lines. Such transgene instability was tackled by replacing the 3' UTR of atpB with the rbcL 3' UTR from D. tertiolecta. Using this 3'UTR sequence from a different species produced a photosynthetic strain and prevented excision of the transgene by SDR recombination in all transfomants. Very low levels of recombinant GUS and PCP accumulated in chloroplast transformants when using the psbD 5' regulatory region to drive their expression. To address low levels of accumulation caused by regulatory pathways that inhibit transgene expression, I have engineered the chloroplast genome of a non-photosynthetic atpB mutant of C. reinhardtii by replacing the endogenous psbD promoter and 5'UTR with the promoter and 5'UTR of psbA. The engineered strain was subsequently transformed with the wildtype atpB and two different reporter genes driven by the psbD regulatory regions: gusA and kat, which code for GUS and the fluorescent protein Katushka respectively. Analysis of the transformants showed that accumulation of recombinant proteins in our engineered strain was 10 to 20 fold higher than in the nonengineered cells. Most of the selectable markers used in plants and algae are inefficient in Dunaliella, which is naturally resistant to many of the antibiotics used for the selection of transformants. Norflurazon inhibits PDS, an essential enzyme for carotenoid biosynthesis. Using forward genetics I have isolated, sequenced and characterised mutant PDS alleles conferring norflurazon resistance in D. tertiolecta. Independent mutations in pds, leading to substitutions R265C, S472L, S472F and L502F, all result in high resistance to norflurazon but differ in sensitivity to other bleaching herbicides. By mapping the four amino acid substitutions on 3D models of D. tertiolecta PDS I determined that R265C, S472L, S472F and L502F, cluster together in proximity to a Rossman-like domain and to aminoacids F128 and V469, previously reported to confer norflurazon resistance. This suggests that the mode of action of norflurazon is by competition with flavin adenine dinucleotide (FAD) for its binding site. A unique aspect of the R265C substitution is its negative cross-resistance to diflufenican and beflutamid which could be advantageous for its use as a positive/negative selection marker for transformation.

660