X-ray crystallographic structure determination of the Met repressor from Escherichia coli and its functional implications

Rafferty, John Bernard

January 1990

No description available.

572.8

Gene transcription

Antidepressants and gene expression : in vitro studies in model cell systems

Richards, Jemma

January 2003

No description available.

615

Gene transcription

The structural conservation and evolution of vertebrate TFIIS genes

Spriggs, Keith A.

January 2000

No description available.

572.8

Transcription elongation

The FNR protein of Neisseria gonorrhoeae

Overton, Timothy William

January 2002

No description available.

579.33

Transcription activation

The transcriptional effects of the anti-oestrogen tamoxifen on the immature rat uterus

Waters, A. P.

January 1982

No description available.

572.8

Rat RNA transcription

Transcriptional regulation of the human NAD(P)H: quinone oxidoreductase gene during oxidative stress

Wang, Bo

January 1995

No description available.

572

Antioxidant; Transcription factor

A study of the processes that control the level of vitellogenin mRNA in Xenopus laevis

MacKenzie, Edward A.

January 1990

No description available.

572.8

Gene transcription control

Studies on the vRNA promoter of influenza A virus

Fodor, Ervin

January 1995

No description available.

579

Transcription; Replication

Transcriptional control of macrophage function in the pig and its relationship to infectious disease susceptibility

Fairbairn, Lynsey

January 2012

The biology of cells of the mononuclear phagocyte system has been studied extensively in the mouse. Studies of the pig as an experimental model have commonly been consigned to specialist animal science journals. This thesis considered some of the many ways that pigs may address the shortcomings of mice as models for the study of macrophage differentiation and activation in vitro, and the biology of sepsis and other pathologies in the living animal. Flow cytometry was used initially to phenotype cells from the porcine lung, peritoneal cavity, blood and bone marrow using the LPS receptor CD14 and the FC receptor CD16, markers frequently employed to differentiate human monocytes into subsets. The expression of SIRP-alpha (SWC3a, CD172a), which is present on all cells of myeloid origin, and the haemoglobin scavenger receptor, CD163 which has previously been used to study monocyte differentiation in the pig was also studied. The findings validated previous work where blood monocytes were divided into subsets on the expression of CD14 and CD163. Furthermore, like human and mouse, pig monocytes also exhibited variation in CD16 expression, having a subset which was CD14hiCD16lo and another which was CD14loCD16hi. A whole genome approach was then used to study the differences between the monocyte subsets in the pig, using monocytes sorted into two populations based on the expression of CD14 and CD163. The gene expression profiles obtained were then compared to publically available data from monocyte subsets in human and mouse. This thesis also investigated the expression of genes that are known to be differentially expressed between human and mouse. To do this gene expression in porcine bone marrow derived macrophages was analyzed across an LPS time course. Like human macrophages, pig macrophages did not induce nitric oxide nor any arginine metabolizing genes in response to LPS. Instead they responded with robust induction of indoleamine 2,3-dioxygenase (IDO) and other enzymes of the tryptophan metabolism pathway such as kynurenine hydroxylase, kynureninase and tryptophan-tRNA synthetase. The tryptophan metabolism pathway has been implicated in sepsis in man and the absence of this pathway in the mouse may be one of the reasons why an adequate rodent model of sepsis has not been developed. The IDO inhibitor 1-methyl-tryptophan (1-MT) has been used to treat mouse macrophages where it had a protective effect after LPS administration. Similar experiments on pig macrophages did not show the same protective effect and induction of key immune genes was increased after treatment with 1-MT suggesting IDO is involved in feedback control of the immune system. With the completion of the genome sequence and the characterisation of many key regulators and markers, the pig has emerged as a tractable model of human innate immunity and disease that should address the limited predictive value of rodents in preclinical studies. This project aimed to address the gap in our knowledge of the control of innate immunity in the pig and provided further evidence that the pig can function as an ideal model to study innate immunity.

macrophage ; transcription ; pig

The insulin promoter

Ferguson, Laura A.

January 2008

The aims of this thesis were to determine the relative contribution of Pdx-1, MafA and β2 to the human insulin promoter.  Additionally, characterisation of the conserved CRE element (CRE2) was undertaken to identify the factor(s) that bind CRE2 to mediate affects upon the transcription of insulin.  Finally, the ectopic expression of insulin was investigated using an engineered zinc finger protein (ZFP-INS) that ‘switched on’ the endogenous insulin gene in a non-β cell (HEK293). Consistent with previous findings, Pdx-1, MafA and β2 were shown to synergistically activate the rat insulin 1 promoter.  However due to subtle sequence divergence, similar synergistic interaction was not observed on the human promoter.  Synergistic interactions were re-established in a rat insulin 1-like mutated human insulin construct.  The CRE binding protein activating transcription factor-2 (ATF-2) was shown to bind and stimulate transcription via CRE2 while CRE binding protein-1 (CREB-1) inhibited insulin transcription independently of CRE1 or CRE2.  ZFP-INS was shown to induce the ectopic expression of insulin in HEK293 cells via the ILPR region, inducing modifications of histone proteins at the insulin promoter.  Collectively, the continued characterisation of the human insulin promoter may reveal unique regulatory mechanisms controlling the expression of insulin under normal and diabetic conditions.

612.6

Insulin : Transcription factors