Global ETD Search

11	Conception et synthèse de nouveaux inhibiteurs de la kallicréine 7 / Design and synthesis of new inhibitors of kallikrein 7 Arama, Patomo Dominique 20 November 2015 (has links) Les kallikréines (KLKs) tissulaires humaines sont des protéases à sérine « (chymo)trypsine-like » impliquées dans divers processus physiologiques. Parmi les 15 isoformes connues dans la littérature, la kallikréine 7 (KLK7) est particulièrement impliquée dans les processus de desquamation. La dérégulation de cette enzyme est associée à diverses atteintes dermatologiques, telles que le psoriasis ou la maladie de Netherton. Il est également admis que cette enzyme participe à l'invasion tumorale et à la progression du cancer de la prostate, des ovaires et du pancréas. L'utilisation d'inhibiteurs de la KLK7 pourrait donc constituer une approche prometteuse pour le traitement de certaines atteintes dermatologiques, et pour lutter contre la dissémination métastatique.Depuis deux décennies, plusieurs inhibiteurs synthétiques de cette isoforme ont été développés. Toutefois, la plupart de ces molécules présentent une sélectivité insuffisante et sont dépourvues de propriétés physicochimiques adaptées à une utilisation in vivo. Ce travail de thèse est consacré à la synthèse d'inhibiteurs réversibles et sélectifs de la KLK7. A ce titre, deux séries de composés ont été explorées. La première est issue d'un criblage de molécules pyrido-imidazodiazépinones, qui a permis d'identifier un inhibiteur réversible et sélectif de la KLK7, le JMV4967 (IC50 = 57,0 µM). Ce composé se caractérise par la présence, en position 2 du cycle diazépinique, d'un noyau phényle substitué en ortho par un groupement méthyle. Sur la base de ces résultats, une étude de relations structure-activité (SAR), a été initiée. Les meilleures inhibitions ont été obtenues avec les analogues du JMV4967 possédant en position 2 du cycle diazépinique, un groupement 3,4,5-triméthoxyphényle ou 3,4-diméthoxyphényle. Cette étude a permis l'identification du composé JMV5046 (IC50 = 33,5 µM). Une étude biochimique du JMV5046, a mis en évidence son caractère réversible et compétitif vis-à-vis du substrat dans le site actif de la KLK7, comme le hit initial. La seconde série a été développée à partir d'une quinazoline substituée par un amino-benzimidazole, et une étude de RSA a également été menée. Finalement, une étude de réactivité chimique, a été également entreprise afin d'accéder à deux nouvelles séries de composés diazépiniques fusionnés avec l'imidazo[1,2-a]pyridine ou l'indole. Cette étude a montré que la 2-amino-imidazopyridine pouvait subir une alkylation en position 3 du cycle, dans le cadre de la réaction de nitro-Michael. Les produits d'addition de Michael ainsi formés peuvent ensuite conduire, après réduction du groupement nitro, aux dérivés diazépiniques correspondants. Par ailleurs, nous avons pu montrer que l'acylation du 2-amino-indole, en présence d'un donneur d'acyle de type ester activé d'acide aminé, conduisait aux dérivés N-acylés correspondants. Ces derniers ont été utilisés par la suite, pour la synthèse de dérivés indolodiazépiniques via la réaction de cyclisation de Pictet-Spengler. La synthèse de ces composés, l'étude de leur activité inhibitrice sur la KLK7 sont décrites. Les expériences de modélisation moléculaire par docking in silico, permettant de préciser les bases structurales de l'inhibition de la KLK7 par le JMV5046, sont également présentées. / Human tissular kallikreins (KLKs) are members of (chymo)trypsin-like serine proteases, involved in various physiological pathways. Among the 15 known isoforms in the literature, kallikrein 7 (KLK7) plays a significant role in physiological and pathophysiological processes of the skin, like psoriasis and the Netherton syndrome. Several studies report also its implication in multiple processes leading to invasive and metastatic tumor growth, especially in prostatic, ovarian and pancreatic cancers. Strategies focused on KLK7 inhibition are a promising alternative for the treatment of such dermatological diseases, and to avoid metastatic dissemination. In the last two decades, many synthetic inhibitors of this KLK isoform have been developed. However, most of these molecules exhibit low selectivity and unsuitable physicochemical properties for in vivo use. This thesis is devoted to the synthesis of selective and reversible inhibitors of KLK7. Two series of compounds have been explored. The first one, derived from a screening of pyrido-imidazodiazepinones compounds, which led to the discovery of a reversible and selective inhibitor of KLK7, JMV4967 (IC50 = 57.0 µM). This compound is characterized by the presence of an ortho methyl substituted phenyl group, at position 2 of the diazepine ring. Based on these results, a structure-activity relationships (SAR) study was initiated. The best inhibitions were obtained with JMV4967analogs bearing a 3,4,5- trimethoxyphenyl group or 3,4- dimethoxyphenyl group, at position 2 of the diazepine ring. This study led to the discovery of one compound, JMV5046 (IC50 = 33.5 µM). A biochemical study of JMV5046, highlighted its reversible and competitive behavior against the substrate in the KLK7 active site, as previously observed for the initial hit. The second series was developed from an amino-benzimidazole substituted quinazoline, and a SAR study was also carried out. A chemical reactivity study was also initiated to access two new series of imidazo[1,2-a]pyridine-fused or indole-fused diazepine compounds. This study showed that 2-amino-imidazopyridine could undergo alkylation at position 3 of the ring, in the nitro-Michael reaction context. The obtained Michael adducts could then give, after reduction of the nitro group, the corresponding diazepine derivatives. We also showed that, in the presence of an acyl donor (as an activated amino acid ester), 2-amino-indole was N-acylated, unlike the 2-amino-imidazopyridine which leads to an exclusive C-acylation in the same conditions. The N-acylated derivatives were then used for the indolodiazepines synthesis, using Pictet-Spengler cyclization reaction.The synthesis of these compounds and their inhibiting activity against KLK7 are described. Molecular modeling experiments by in silico docking, to determine the structural requirements for KLK7 inhibition by JMV5046, are also presented. Inhibiteurs d'enzyme Kallikréines Imidazopyridine Pyrido-Imidazo[1.3]diazépinones Diazépines Enzyme inhibitors Kallikreins Imidazopyridine Pyrido-Imidazo[1.3]diazepinones Diazepines 616
12	Planejamento e síntese de peptideomiméticos como candidatos a inibidores de calicreínas teciduais humanas 5 e 7 Azevedo, Pedro Henrique Rodrigues de Alencar 12 March 2018 (has links) Submitted by Biblioteca da Faculdade de Farmácia (bff@ndc.uff.br) on 2018-03-12T17:36:57Z No. of bitstreams: 1 PEDRO HENRIQUE RODRIGUES DE ALENCAR AZEVEDO.pdf: 15048741 bytes, checksum: a121d29e5dc4898c7b8e4a85def01e12 (MD5) / Made available in DSpace on 2018-03-12T17:36:57Z (GMT). No. of bitstreams: 1 PEDRO HENRIQUE RODRIGUES DE ALENCAR AZEVEDO.pdf: 15048741 bytes, checksum: a121d29e5dc4898c7b8e4a85def01e12 (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / As calicreínas teciduais humanas (KLKs) compreendem uma família de 15 enzimas serina proteases (KLKs 1-15) amplamente encontradas nos tecidos humanos. Em diversas patologias como a dermatite atópica, psoríase, síndrome de Netherton, câncer de ovário, mama e testículos, as KLKs encontram-se em concentrações elevadas. Por exemplo, as KLKs 5 e 7 estão mais abundantemente expressadas na pele, na qual estão envolvidas com o processo de descamação da mesma, e também presentes em alguns tipos de carcinomas. Dessa forma, as KLKs 5 e 7 são consideradas importantes alvos terapêuticos para o tratamento de doenças onde elas encontram-se superexpressadas, enfatizando a existência de somente um fármaco comercialmente disponível como inibidor de KLK. Nesse contexto, o trabalho descreve a síntese de 3 séries de compostos peptideomiméticos, incorporando o cerne estatina e diferentes resíduos de aminoácidos, planejados como candidatos a inibidores das enzimas serina proteases do KLKs 5 e 7. Os compostos finais foram obtidos utilizando uma rota sintética eficiente tendo como reação-chave a formação da ligação peptídica entre o cerne estatina e cloridratos de aminoésteres, previamente sintetizados. Os compostos sintetizados foram identificados por técnicas de Ressonância Magnética Nuclear, Infravermelho e Espectrometria de massas de alta resolução e os produtos finais serão avaliados em testes in vitro de inibição das enzimas KLKs / Human tissue kallikreins (KLKs) comprise a family of 15 serine protease enzymes (KLKs 1-15) widely found in human tissues. In several pathologies such as atopic dermatitis, psoriasis, Netherton syndrome, ovarian, breast and testis cancer, KLKs are in high concentrations. For example, KLKs 5 and 7 are more abundantly expressed in the skin, in which they are involved in the desquamation process, and also present in some types of carcinomas. Thus, KLKs 5 and 7 are considered important therapeutic targets for the treatment of diseases where they are over expressed, emphasizing the existence of only one commercially available drug as a KLK inhibitor. In this context, the work describes the synthesis of three series of peptideomimetic compounds incorporating the statin core and different amino acid residues, designed as candidates for inhibitors of the serine protease enzymes of KLKs 5 and 7. The final compounds were obtained using an efficient synthetic route based on the reaction of formation of the peptide bond between the statin core and previously synthesized amino acid hydrochlorides. The synthesized compounds were identified by Nuclear Magnetic Resonance, Infrared and High Resolution Mass Spectrometry techniques and the final products will be evaluated in in vitro inhibition assays of the KLKs enzymes Serina protease peptideomiméticos calicreínas teciduais estatina Serina proteases Calicreínas teciduais Peptidomiméticos Serine protease peptidomimetics tissue kallikreins statin
13	Functional analyses of polymorphisms in the promoters of the KLK3 and KLK4 genes in prostate cancer Lai, John January 2006 (has links) This PhD aimed to elucidate the mechanisms by which polymorphisms may alter androgen-induced transactivation of androgen receptor (AR) target genes which may be important in prostate cancer aetiology. The second aspect of this PhD focused on identifying and characterising functional polymorphisms that may have utility as predictive risk indicators for prostate cancer and which may aid in earlier therapeutic intervention and better disease management. Analyses were carried out on the kallikrein-related peptidase 3 (KLK3), also known as the prostate specific antigen (PSA), gene and the kallikrein-related peptidase 4 (KLK4) gene. The PSA and KLK4 genes are part of the serine protease family that have trypsin or chymotrypsin like activity and are thought to play a role in the development of hormone-dependent cancers in tissues such as those in the prostate, breast, endometrium and ovaries. In the prostate, PSA is regulated by androgens and three androgen response elements (AREs) have been described in the promoter and upstream enhancer region. The PSA ARE I harbours a polymorphism at -158 bp from the transcription initiation site (TIS) that results in a G to A transition (G-158A). This PhD investigated the functional significance of the PSA G-158A polymorphism which has been reported to be associated with prostate cancer risk. Electromobility shift assays (EMSAs) investigating the interaction of ARE I variants with the AR DNA binding domain (AR-DBD) demonstrated that the A allele had a two-fold increased binding affinity for the AR-DBD when compared with the G allele. This was confirmed with endogenous AR in limited proteolysis-EMSA experiments. The limited proteolysis-EMSA experiments also demonstrated differential sensitivities of PSA ARE I alleles to trypsin digestion, which suggests that the G-158A polymorphism has an allosteric effect on the AR that alters AR/ARE I complex stability. Furthermore, Chromatin Immunoprecipitation (ChIP) assays suggest that the A allele more readily recruited the AR in vivo when compared with the G allele and is consistent with the in vitro binding data. Luciferase reporter assays carried out in both LNCaP and 22Rv1 prostate cancer cells, and using the natural (dihydrotestosterone; DHT) ligand demonstrated that the A allele was more responsive to androgens in LNCaP cells. Hence, this study has elucidated the potential mechanisms by which the G-158A polymorphism may differentially regulate PSA expression (of which up-regulation of PSA is thought to be important in prostate cancer development and progression). KLK4 has similar tissue-restricted expression as PSA and is up-regulated by steroid hormones in many endocrine cells including those in the prostate. A putative ARE (KLK4-pARE) located at -1,005 to -1019 relative to the more predominantly used transcription initiation site, TIS3, was initially found in supershift assays using AR antibodies to interact with endogenous AR. However, subsequent EMSA analysis using purified AR-DBD suggest that KLK4-pARE may be interacting with the AR indirectly. To investigate this hypothesis, a tandem construct of KLK4-pARE was cloned into the pGL3-Promoter vector for hormone-induced reporter assays. However, reporter assays did not demonstrate any responsiveness of KLK4-pARE to androgens, estradiol or progestins. Consequently, Real-Time PCR was carried out to reassess the hormonal regulation of KLK4 at the mRNA level. Consistent with the literature, data from this study suggests that KLK4 may be up-regulated by androgens, progestins and estradiol in a cyclical manner. Hormone-induced luciferase reporter assays were then carried out on seven promoter constructs that span 2.8 kb of the KLK4 promoter from TIS3. However, none of the seven promoter constructs demonstrated any significant responsiveness to androgens, estradiol or progestins. This study suggests that hormone response elements (HREs) that may drive the hormonal regulation of KLK4 in prostate cancer may be located further upstream from the promoter region investigated in this PhD, or alternatively, may lie 3' of TIS3. The characterisation of KLK4 promoter polymorphisms and their flanking sequences were also carried out in parallel to the functional work with the intent to assess the functional significance of any polymorphisms that may be located within HREs. In total 19 polymorphisms were identified from the public databases and from direct sequencing within 2.8 kb of the KLK4 promoter from TIS3. However, the functional and clinical significance of these 19 polymorphisms were not further pursued given the negative findings from the functional work. The PSA AR enhancer region was also assessed for potential polymorphisms that may be associated with prostate cancer risk. A total of 12 polymorphisms were identified in the PSA enhancer of which two (A-4643G and T-5412C) have been reported to alter functionality of the enhancer region and thus, prioritised for further analysis. Association analysis for prostate cancer risk was then carried out on these PSA enhancer polymorphisms as none of the KLK4 promoter polymorphisms were found in functional HREs. No significant association for either the A-4643G or T-5412C polymorphism with prostate cancer risk was found at the P = 0.05 level. However, under an age-adjusted dominant model a 1.22- (95% CI = 1.16-1.26) and 1.23-fold (95% CI = 1.17-1.29) increased risk for prostate cancer was found for the A-4643G or T-5412C polymorphisms, respectively. Both polymorphisms were also assessed for association with tumour grade and stage and PSA levels. Genotypes were significantly different for the A-4643G and T-5412C polymorphisms with tumour stage and PSA levels, respectively. However, these results are likely to be biased by the case population which consist primarily of men who presented with incidental (pT1) and organ-confined (pT2) tumours. To summarise, the A-4643G and T-5412C polymorphisms are unlikely to be associated with prostate cancer risk, PSA levels or stage/grade of disease. However, further analyses in a larger cohort is warranted given that these polymorphisms alter androgen responsiveness of the PSA enhancer and that elevated PSA levels are indicative of men with prostate cancer. To summarise, this PhD has elucidated the functional significance of the PSA G-158A polymorphism in prostate cancer and which may be important in prostate cancer patho-physiology. This PhD has also furthered the understanding of the hormonal regulation of KLK4 in prostate cancer cells. Finally, this PhD has carried out a pilot study on two functional PSA enhancer polymorphisms (A-4643G and T-5412C) with prostate cancer risk. prostate cancer single nucleotide polymorphism (SNP) kallikreins (KLKs) kallikrein 4 (KLK4) prostate specific antigen (PSA) androgens hormones androgen receptor (AR) androgen response element (ARE) electromobility shift assay (EMSA) luciferase reporter assay
14	Kallikrein Gene Regulation in Hormone-Dependent Cancer Cell Lines Myers, Stephen Anthony January 2003 (has links) Hormone-dependent cancers (HDCs), such as those of the prostate, ovary, breast and endometrium, share characteristics that indicate similar underlying mechanisms of carcinogenesis. Through steroid hormone signalling on "down-stream" target genes, the growth, development and progression of HDCs are regulated. One such family of target genes, highly expressed in HDCs and regulated by steroid hormones, are the tissue kallikreins (KLKs). The KLKs are a multigene family of serine proteases involved in physiological processes such as blood pressure regulation, inflammation, and tumour development and progression via the hydrolysis of specific substrates. Although the KLK gene family is clearly implicated in tumourigenesis, the precise roles played by these genes are largely unknown. Additionally, except for the androgen-responsive genes, KLK2 and KLK3, the mechanisms underlying their hormonal regulation in HDCs are yet to be identified. The initial focus of this thesis was to examine the regulation of the kallikreins, KLK1 and KLK4, by estradiol and progesterone in endometrial and breast cancer cell lines. From these studies, progesterone clearly regulated KLK4 expression in T47D cells and therefore, the focus of the remaining studies was to further examine this regulation at the transcriptional level. An overview of the results obtained is detailed below. Human K1 and hK4 protein levels were increased by 10 nmol/L estradiol benzoate, progesterone, or a combination of the two, over 48 hours in the endometrial cancer cell line, KLE. However, these same treatments resulted in no change in KLK1 gene or hK1 protein levels in the endometrial cancer cell lines, HEC1A or HEC1B (only hK1 analysed). Progesterone treatment (0-100 nmol/L) over 24 hours resulted in a clear increase in KLK4 mRNA at the 10 nmol/L dose in the breast cancer cell line, T47D. Additionally, treatment of T47D cells with 10 nmol/L progesterone over 0-48 hr, resulted in the rapid expression of the hK4 protein at 2 hr which was sustained for 24 hr. Further analysis of this latter progesterone regulation with the antiprogesterone, RU486, over 24 hours, resulted in an observable decrease in hK4 levels at 1 µmol/L RU486. Although the estrogen and progesterone regulation of the hK1 protein was not further analysed, the data obtained for hK4 regulation in T47D cell lines, supported the premise that this gene was progesterone-responsive. The rapid expression of hK4 protein by progesterone at two hours suggests that KLK4 transcription is directly coupled to progesterone regulation, perhaps through progesterone receptor (PR) binding to progesterone-responsive regions within the KLK4 promoter or far "up-stream" regions. Thus, the following further studies were performed. To test this hypothesis, the transcription initiation site (TIS) and 5' flanking regions of the KLK4 gene in T47D cells were interrogated. Primer extension and 5' RACE identified the TIS 78 bp 5' of the putative ATG site for translation as identified by Korkmaz et al. (2001). This KLK4 gene transcript consists of only four exons, and thus excludes the pre/pro signal peptide. Although a TATA-box is not present within -25 to -30 bp 5' of the identified TIS, a number of consensus binding motifs for Sp1 and estrogen receptor half-sites were identified. It is possible that the Sp1 sites are involved in the basal levels of transcription for this gene. Additionally, a putative progesterone response element (PRE) was identified in the far "up-stream" regions of the KLK4 gene. Basal levels of transcription were observed within the KLK4 proximal promoter region when coupled to a luciferase reporter gene and transfected into T47D cell lines. Additionally, the KLK4 proximal promoter region did not induce the luciferase reporter gene expression when progesterone was added to the system, however, estradiol was inhibitory for luciferase gene expression. This suggests that the proximal promoter region of the KLK4 gene could contain functional EREs but not PREs. In keeping with this hypothesis, some ER half-sites were identified, but PR sites were not obvious within this region. The identified PRE in the far "up-stream" region of the KLK4 gene assembled the progesterone receptor in vitro, and in vivo, as assessed by electromobility shift assays and chromatin immunoprecipitation assays (EMSAs and ChIPs), respectively. The binding of the PR to the KLK4 PRE was successfully competed out by a PR antibody and not by an androgen receptor antibody, and thus confirms the specificity of the KLK4 PRE-PR complex. Additionally, the PR was recruited and assembled onto and off the progesterone-responsive KLK4 region in a cyclic fashion. Thus, these data strongly suggest that the PR represents one of the core components of a transcription complex for the KLK4 gene, and presumably also contributes to the expression of this gene. Moreover, these data suggest a functional coordination between the PR and the KLK4 progesterone-responsive region in T47D cells, and thus, provide a model system to further study these events in vivo. Kallikreins (KLKs) Kallikrein 1 and 4 genes (KLK1 KLK4) Human Kallikrein 1 and 4 protein (hK1 hK4) Hormonal Regulation Estrogen Progesterone Progesterone Receptor (PR) Promoter Transcription Initiation Site (TIS) Hormone Response Elements (HREs) Progesterone Response Elements (PREs) Reporter Gene Assays Electromobility Shift Assay (EMSA)
15	Localisation of kallikreins in the prostate and association with prostate cancer progression Bui, Loan Thuy January 2006 (has links) At present, prostate cancer is a significant public health issue throughout the world and is the second leading cause of cancer deaths in older men. The prostate specific antigen or PSA (which is encoded by the kallikrein 3/KLK3 gene) test is the current most valuable tool for the diagnosis and management of prostate cancer. However, it is insufficiently sensitive and specific for early diagnosis, for staging of prostate cancer or for discriminating between benign prostatic hyperplasia (BPH) and prostate cancer. Recent research has revealed another potential tumour marker, glandular kallikrein 2 (KLK2 gene/hK2 protein), which may be used alone or in conjunction with PSA to overcome some of the limitations of the PSA test. Twelve new kallikrein gene family members have been recently identified and, like hK2 and PSA, many of these genes have been suggested to be involved in carcinogenesis. In this study, the cellular localisation and level of expression of several of these newer kallikreins (KLK4, KLK5, KLK7, KLK8 and KLK11) was examined in prostate tissue, to provide an understanding of the association of their expression with prostatic diseases and their potential as additional biomarkers. Like PSA and hK2, the present observation indicated that each of these proteins, hK4, hK5, hK7, hK8 and hK11, was detected within the cytoplasm of the secretory cells of the prostate glands. For the first time, all of these newly-identified proteins were shown to be expressed in prostatic intraepithelial neoplasia (PIN) lesions, in comparison to normal glands and cancer lesions. In addition to cytoplasmic secretory cell expression, the localisation of hK4 to the basal cells and nuclei in prostatic lesions was intriguing. The intensity of hK4 staining in prostate tissue was strongest in comparison to the other newly-identified kallikrein proteins (hK5, hK7, hK8 and hK11). Therefore, KLK4/hK4 expression was characterised further to define this cellular localisation and examined in non-prostatic tissue and also in a larger number of prostate tissues in an attempt to determine its potential value as a biomarker for prostate disease. Three hK4 antipeptide polyclonal antibodies, derived against N-terminal, mid-region and C-terminal hK4 amino acid sequences, were used. The hK4 N-terminal antipeptide antibody was used to demonstrate the cellular localisation of hK4 in kidney, salivary glands, liver, testis, colon carcinoma, heart, endometrium and ovarian cancer, for the first time. The presence of hK4 in these non-prostate tissues was consistent with the previous reports using RT-PCR. The dual cytoplasmic and nuclear localisation of hK4 observed in the prostate above was also seen in these tissues. Although hK4 was found widely expressed in many human tissue types, indicating that it is not prostate specific in its expression, the highest expression level of hK4 was seen in the prostate. Therefore, detailed expression patterns and levels of KLK4 mRNA and hK4 protein in the normal prostate and prostatic diseases and histopathological lesions were investigated and reported for the first time in this study. Twelve benign prostatic hyperplasia (BPH), 19 adenocarcinoma (Gleason grade 2-5) and 34 bone metastases from prostate cancer were analysed. Using in situ hybridisation, the expression of KLK4 mRNA was detected in the cytoplasm of the secretory cells of both normal and diseased prostate tissue. KLK4 mRNA was also noted in both secretory and basal cells of PIN lesions, but the basal cells of normal glands were negative. Using the hK4 N-terminal and mid-region antipeptide antibodies, hK4 was predominantly localised in the cytoplasm of the secretory cells. The intensity of hK4 staining appeared lowest in normal and BPH, and increased in PIN lesions, high Gleason grade prostate cancer and bone metastases indicating the potential of hK4 as a histopathological marker for prostatic neoplasias. Further studies are required with a larger cohort to determine its utility as a clinical biomarker. Small foci of atypical cells, which were found within normal glands, were also intensely stained. Surprisingly, hK4 protein was found in the nucleus of the secretory cells (but not the basal cells) of high grade PIN and Gleason grade 3 prostate cancer. The detection of KLK4 mRNA and hK4 protein in PIN lesions and small foci of atypical cells suggests that up-regulation of KLK4 expression occurs early in the pathology of prostate carcinogenesis. The finding of basal cell expression is not typical for the kallikreins and it is not clear what role hK4 would play in this cell type. With the use of the hK4 C-terminal antipeptide antibody, the staining was mainly localised in the nuclei of the secretory cells of the prostate glands. Although the nuclear localisation was readily noted in more than 90% of epithelial cells of the prostate gland with the C-terminal antibody, no difference in staining intensity was observed among the histopathological lesions of the prostate. The prominent nuclear localisation with the C-terminal antipeptide antibody was also shown to be distributed throughout the nucleus by using confocal microscopy. Further, by using gold-labelled particles for electron microscopy, the intracellular localisation of these hK4 antipeptide antibodies was reported here for the first time. Similar to the immunohistochemical results, the cytoplasm was the major site of localisation with the N-terminal and mid-region antipeptide antibodies. To further characterise the involvement of KLK4/hK4 in human prostate cancer progression, the transgenic adenocarcinoma mouse prostate (TRAMP) model was used in this study. In this study, mouse KLK4 (also known as enamel matrix serine protease -1, EMSP-1) was shown to be expressed in the TRAMP prostate for the first time. Previous studies had only shown the developing tooth as a site of expression for EMSP-1. The level of EMSP-1 mRNA expression was increased in PIN and prostate cancer lesions of the TRAMP model, while negative or low levels of EMSP-1 mRNA were seen in normal glands or in control mouse prostate tissue. The normal mouse prostate did not stain with any the three hK4 antipeptide antibodies. hK4 N-terminal and mid-region antipeptide antibodies showed positive staining in the cytoplasm of the epithelial cells of PIN and cancer lesions of the mouse prostate. The C-terminal antipeptide antibody showed distinctively nuclear staining and was predominantly localised in the nuclei of the glandular cells of PIN and cancer lesions of the mouse prostate. The expression patterns of both the mRNA and protein level for mouse KLK4 strongly supported the observations of KLK4/hK4 expression in the human prostate and further support the utility of the TRAMP model. Overall, the findings in this thesis indicate a clear association of KLK4/hK4 expression with prostate cancer progression. In addition, several intriguing findings were made in terms of cellular localisation (basal as well as secretory cells; nuclear and cytoplasmic) and high expression in atypical glandular cells and PIN, perhaps indicating an early involvement in prostate disease progression and, additionally, utility as basal cell and PIN histological markers. These findings provide the basis for future studies to confirm the utility of hK4 as a biomarker for prostate cancer progression and identify functional roles in the different cellular compartments. Prostate cancer Prostate cancer progression Gleason grade Benign prostatic hyperplasia (BPH) Bone metastases from prostate cancer Kallikreins KLK4/hK4 (prostase KLK-L1 protein EMSP-1) Prostate specific antigen (PSA KLK3) Human glandular kallikrein (KLK2/hK2) KLK5/hK5 (KLK-L2 HSCTE) KLK7/hK7 (PRSS6 HSCCE) KLK8/hK8 (PRSS19 Neuropsin Ovasin) KLK11/hK11 (PRSS20 TLSP Hippostasin) Immunohistochemistry In situ hybridisation Secretory cells Basal cells Nuclear staining Cellular localisation

Page generated in 0.0581 seconds