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Department of Biological and Medical Sciences
Faculty of Health and Life Sciences
Background. Aberrant glycosylation is a hallmark of cancer cells and plays an important role in oncogenesis and cancer progression including metastasis. This study aimed to assess alteration in cellular glycosylation, detected by lectin Helix pomatia agglutinin (HPA) binding, in adrenal cancers and to determine whether such altered glycosylation has prognostic significance. Methods. HPA binding lectin histochemistry was performed on archival paraffin wax‐embedded specimens of adrenocortical cancers excised from patients attending two tertiary referral centres. Benign tumours were used as controls. Demographic, histological and survival data were collected and compared between patients with HPA‐positive and HPA‐negative tumours. Results. Thirty‐two patients were treated for adrenal cancer between 2000 and 2016; their median age was 49 (range 23–79) years. Fifteen patients had functioning tumours (14 adrenal Cushing's tumours and 1 Conn's tumour). Mean(s.d.) tumour size was 127·71(49·70) mm. None of 10 control tumours expressed HPA‐binding glycoproteins. Invasion was associated with HPA‐binding glycoproteins (P = 0·018). Local recurrence or metastatic disease did not significantly differ between HPA‐positive and HPA‐negative adrenocortical cancers. Overall survival was significantly longer in patients with HPA‐negative tumours (median survival not reached versus 22 months in patients with HPA‐positive tumours; P = 0·002). Conclusion. Altered cellular glycosylation detected by lectin HPA is associated with poor survival in patients with adrenocortical cancer.
Ovarian cancer is the deadliest gynaecological cancer. A major contributor to the poor survival rate is the development of chemoresistance to platinum-based therapies such as cisplatin and carboplatin. Here we aimed to test the role of miRNAs in the acquisition of drug resistance in ovarian cancer.
We used microarrays to measure miRNA levels in the ovarian cancer cell line A2780 and its cisplatin-resistant derivative CP70. The role of miRNAs and the mRNA targets were tested using transfected miRNA mimics and siRNAs, respectively. Potential in vivo significance was investigated by analysing RNA levels in cohorts of ovarian cancer patients.
We identified several miRNAs that are increased in cisplatin-resistant cells. We show that most of these do not directly contribute to cisplatin resistance. Interestingly, miR-21-3p, the passenger strand of the known oncomiR, directed increased resistance to cisplatin in a range of ovarian cell lines. This effect was specific to the star strand, as miR-21-5p had the opposite effect and actually increased sensitivity of A2780 cells to cisplatin. We identify NAV3 as a potential target of miR-21-3p and show that knockdown of NAV3 increases resistance. Exosomes released by CP70 cells were also capable of increasing resistance in A2780 cells, although this was independent of miR-21-3p. Finally, we use publically available transcriptomic data to demonstrate that miR-21-3p is raised, while NAV3 is reduced, in ovarian tumours that are resistant to platinum treatment.
Our data suggest that miR-21-3p can induce cisplatin resistance in ovarian tumours, potentially by targeting the NAV3 gene.
Ovarian cancers have a high mortality rate; this is in part due to resistance to the platinum-based compounds used in chemotherapy. In this paper, we assess the role of microRNA-31 in the development of chemoresistance to cisplatin. We used previous data from microarray experiments to identify potential microRNAs (miRNAs) involved in chemoresistance. The functional significance of these microRNAs was tested using miRNA mimics. We used RNA-seq to identify pathways and genes de-regulated in the resistant cell line and then determined their role using RNAi. Analysis of publically available datasets reveals the potential clinical significance. Our data show that miR-31 is increased, whilst potassium channel calcium activated large conductance subfamily M alpha, member 1 (KCNMA1), a subunit of calcium-regulated big potassium (BK) channels, is reduced in resistant ovarian cells. Over-expression of miR-31 increased resistance, as did knockdown of KCNMA1 or inhibition of BK channels. This suggests that these genes directly modulate cisplatin response. Our data also suggest that miR-31 represses KCNMA1 expression. Comparing the levels of miR-31 and KCNMA1 to cisplatin resistance in the NCI60 panel or chemoresistance in cohorts of ovarian cancer tumours reveals correlations that support a role for these genes in vitro and in vivo. Here we show that miR-31 and KCNMA1 are involved in mediating cisplatin resistance in ovarian cancer. Our data gives a new insight into the potential mechanisms to therapeutically target in cisplatin resistance common to ovarian cancer.
Lectins are naturally occurring carbohydrate-binding molecules. A very wide range of purified lectins are commercially available which exhibit a diversity of carbohydrate-binding preferences. They can be used in the laboratory to detect carbohydrate structures on, or in, cells and tissues in much the same way that purified antibodies can be employed to detect cell- or tissue-bound antigens using immunocytochemistry. As lectins can distinguish subtle alterations in cellular glycosylation, they are helpful in exploring the glycosylation changes that attend both transformation to malignancy and tumour progression. In this chapter, methodologies are given for appropriate preparation of many types of cell and tissue preparations, including cells cultured on coverslips (which can be used for live-cell imaging), cell smears, and frozen (cryostat) and fixed, paraffin wax-embedded tissue sections. Heat- and enzyme-based carbohydrate retrieval methods are covered. Basic detection methods, which can be readily adapted to the researcher's needs, are given for direct (labelled lectin), simple indirect (labelled secondary antibody directed against the lectin), and avidin-biotin (biotinylated lectin) and avidin-biotin complex. The use of both the enzyme label, horseradish peroxidase, and fluorescent labels is considered.
Immunocytochemistry, the identification of cell- or tissue-bound antigens in situ, by means of a specific antibody-antigen reaction, tagged microscopically by a visible label, has a remarkably wide range of applications. The basic techniques are straightforward and can be adapted to explore the localisation of virtually any molecule of interest to the researcher in samples of normal and/or malignant cells. Heterogeneity can be mapped and loss or gain of immunoreactivity with tumour progression can be visualised. In this chapter, methodologies are given for appropriate preparation of cells and tissues, including cells cultured on coverslips (which can be used for live cell imaging), cell smears, frozen (cryostat) and fixed, paraffin wax-embedded tissue sections. Heat- and enzyme-based antigen retrieval methods are covered. Basic detection methods, which can be readily adapted, are given for direct (labelled primary antibody), simple indirect (labelled secondary antibody), avidin-biotin (biotinylated primary antibody), avidin-biotin complex (ABC), peroxidase-anti-peroxidase or alkaline phosphatase-anti-alkaline phosphatase (PAP or APAAP), and polymer- based methods. The use of enzyme labels including horseradish peroxidase and alkaline phosphatase, and fluorescent labels, are considered.
Binding of the lectin Helix pomatia agglutinin (HPA) has been shown to be associated with poor prognosis in many human cancers, but not in thyroid cancer. The aims of the present study were to assess alteration in cellular glycosylation, detected by HPA binding, in thyroid tumors; to determine if such altered glycosylation carries any prognostic significance; and to analyze qualitative and quantitative differences of HPA-binding glycoproteins in various thyroid tumors. Methods Lectin histochemistry was performed on 110 archival paraffin wax embedded specimens of various thyroid tumors excised between the years 1983-1993. Demographic data, histological data, and time to death were recorded, and multivariate Cox regression analysis was performed to determine a prognostic model for patient survival based on the data. Helix pomatia agglutinin binding glycoproteins were isolated from 128 fresh specimens of various thyroid tissues by affinity chromatography, analyzed by SDS-PAGE and western blotting. Results There was a marked qualitative difference in the profile of HPA-binding glycoproteins, with the malignant thyroid tumors showing a heterogeneous profile of numerous HPA binding glycoprotein bands. Lectin histochemistry showed significant positive HPA binding in malignant thyroid tumors (p = 0.0009). Kaplan-Meir survival analysis revealed that among patients who died of their disease those with HPA-positive tumors had a significantly shorter survival (p = 0.009). Conclusions This is the first study showing that HPA binding glycoproteins are synthesized by thyroid tumors. Thyroid cancers show a broader profile of HPA binding glycoproteins compared to benign thyroid tumors, and positive HPA binding is significantly associated with shorter survival and poorer prognosis in thyroid cancers.
Introduction: Circulating cell-derived microparticles (MPs) have been implicated in several disease processes and elevated levels are found in many pathological conditions. The detection and accurate measurement of MPs, although attracting widespread interest, is hampered by a lack of standardisation. The aim of this study was to establish a reliable flow cytometric assay to measure distinct subtypes of MPs in disease and to identify any significant causes of variability in MP quantification. Materials and Methods: Circulating MPs within plasma were identified by their phenotype (platelet, endothelial, leukocyte and annexin-V positivity (AnnV+). The influence of key variables (i.e. time between venepuncture and centrifugation, washing steps, the number of centrifugation steps, freezing/long-term storage and temperature of thawing) on MP measurement were investigated. Results: Increasing time between venepuncture and centrifugation leads to increased MP levels. Washing samples results in decreased AnnV+MPs (P=0.002) and platelet-derived MPs (PMPs) (P=0.002). Double centrifugation of MPs prior to freezing decreases numbers of AnnV+MPs (P=0.0004) and PMPs (P=0.0004). A single freeze thaw cycle of samples led to an increase in AnnV+MPs (P=0.0020) and PMPs (P=0.0039). Long-term storage of MP samples at -80° resulted in decreased MP levels. Conclusions: This study found that minor protocol changes significantly affected MP levels. This is one of the first studies attempting to standardise a method for obtaining and measuring circulating MPs. Standardisation will be essential for successful development of MP technologies, allowing direct comparison of results between studies and leading to a greater understanding of MPs in disease.
Metastasis, the process by which cancer cells leave the primary tumour, disseminate and form secondary tumours at anatomically distant sites, is a serious clinical problem as it is disseminated disease, which is often impossible to eradicate successfully, that causes the death of most cancer patients. Metastasis results from a complex molecular cascade comprising many steps, all of which are interconnected through a series of adhesive interactions and invasive processes as well as responses to chemotactic stimuli. In spite of its clinical significance, it remains incompletely understood. This review provides an overview of some of the molecular interactions that are critical to metastasis. It summarises the principle molecular players in the major steps of the metastatic cascade. These are: (1) tumour angiogenesis, (2) disaggregation of tumour cells from the primary tumour mass, mediated by cadherins and catenins, (3) invasion of, and migration through, the basement membrane (BM) and extracellular matrix (ECM) surrounding the tumour epithelium, and subsequent invasion of the BM of the endothelium of local blood vessels. This is mediated through integrins and proteases, including urokinase form of plasminogen activator (uPA), matrix metalloproteinases (MMPs) and cathepsins, (4) intravasation of the tumour cells into the blood vessels prior to hematogeneous dissemination to distant sites, (5) adhesion of the circulating tumour cells to the endothelial cell lining at the capillary bed of the target organ site. This occurs through adhesive interactions between cancer cells and endothelial cells involving selectins, integrins and members of the immunoglobulin superfamily (IgSF), (6) invasion of the tumour cells through the endothelial cell, layer and surrounding BM (extravasation) and target organ tissue and (7) the development of secondary tumour foci at the target organ site.
Thyroid cancers are the most common endocrine malignancy. Radiation exposure, family history of thyroid cancer and some inherited conditions are the most important predisposing factors for the development of thyroid cancer. Three mitogenic signalling pathways have been described in the thyroid cell, which are influenced by various stimulatory and inhibitory hormones, growth factors and neurotransmitters. Various proto-oncogenes and oncogenes like ras, braf, trk, met and RET also play a role in the signal transduction systems. Two theories have been described in thyroid cancer pathogenesis, the foetal cell carcinogenesis theory and the more common, multistep carcinogenesis theory. The multistep carcinogenesis theory is now the accepted model in many human cancers, including thyroid cancer. The early events of tumour formation are the consequence of activation of either various growth factors or the proto-oncogenes like ras, met or ret. This results in the formation of differentiated thyroid cancers like the papillary, follicular or Hurthle cell cancers. The later stages of tumour formation involve further activation of proto-oncogenes and loss or inactivation of tumour suppressor genes like p53. Based on this theory, follicular carcinomas are generated from follicular adenomas and papillary carcinomas from precursor cells generated from thyrocytes. Anaplastic carcinoma may develop from papillary or follicular carcinoma by dedifferentiation. In this review article, we highlight the molecular pathogenesis of thyroid tumours.
More than half of human proteins are glycosylated by a bewildering array of complex and heterogeneous N- and O-linked glycans. They function in myriad biological processes, including cell adhesion and signalling and influence the physical characteristics, stability, function, activity and immunogenicity of soluble glycoproteins. A single protein may be glycosylated differently to yield heterogenous glycoforms. Glycosylation analysis is of increasing interest in biomedical and biological research, the pharmaceutical and healthcare industry and biotechnology. This is because it is increasingly apparent that glycosylation changes in diseases, such as cancer, making it a promising target for development of clinically useful biomarkers and therapeutics. Furthermore, as the non-human cells employed in expression systems glycosylate their proteins very differently to human cells, and as glycosylation changes unpredictably under changing environmental conditions, glycans analysis for quality control, optimum efficacy and safety of recombinant glycoproteins destined for human therapeutic use is paramount. The complexities of carbohydrate chemistry make analysis challenging and while there are a variety of robust methodologies available for glycan analysis, there is currently a pressing need for the development of new, streamlined, high throughput approaches accessible to non-specialist laboratories.
Whilst there are many common features in the glycosylation pathways of all eukaryotic cells, the cells of different species often glycosylate their proteins very differently. This is of particular interest when the cells of non-human species, such as bacteria, plants, yeast or non-human mammalian cells, are used to express glycoproteins for potential human therapeutic use, as these proteins may be glycosylated with glycans very different to those typical of human cells. In this presentation the similarities and differences between human cell glycoprotein glycosylation and the glycosylation of other types of cells will be discussed briefly and some interesting – and biologically important – features of glycosylation highlighted. Some of the advances and challenges in biotechnology and engineering glycosylation pathways in non-human cells types will be described.
Aberrant glycosylation is an established characteristic of cancer cells, and appears to have a functional role in metastasis – the process by which cancer cells spread around the body. The lectin from Helix pomatia, the Roman snail (Helix pomatia agglutinin, HPA) recognises cancer-associated aberrant glycans terminating in the monosaccharide α-N-acetylgalactosamine (GalNAc). The presence of these glycans, detected by HPA binding, is associated with metastasis and consequent poor survival. We are investigating the putative functional role of these glycans in cancer cell adhesion to, and migration through, the endothelium (lining blood vessels) during metastasis. Eight breast cell lines, characterised for synthesis of GalNAc-glycans of interest, have been employed in investigations; HMT 3522, is derived from normal breast, and stably synthesises negligible levels of GalNAc-glycans, and the other cell lines; BT474, MDA MB 435, MDA MB 468, ZR751, MCF7, T47D and DU4475, are derived from breast cancer and stably synthesise increasingly greater amounts of GalNAc-glycans, consistent with their increasing metastatic ability.
A rocking adhesion assay was used to investigate the adhesion of the breast cell lines to an endothelial cell monolayer derived from human brain microvasculature, a site physiologically relevant to breast cancer metastasis. The effect of masking the GalNAc-glycans with HPA was investigated. The results from these assays provide novel evidence that GalNAc-glycans have a functional role in cancer cell adhesion to endothelial cells. It was also found that the HPA binding profiles of the breast cell lines appear to correlate with their abilities to adhere to endothelial cells via GalNAc-glycans.
The prognosis for the majority of patients suffering from a solid neoplasm remains bleak, due to the fact that most cancers have already formed metastases at distant sites. Any progress in cancer therapy will, therefore, depend on the understanding of the metastatic cascade and therapies derived from this understanding. The development of clinically relevant models of metastases, using lectin-defined human cancer cell lines and severe combined immunodeficient (SCID) mice, is described. In conjunction with modern imaging techniques, these models will help to elucidate the molecular mechanisms governing the metastatic spread of tumours.
Six human breast cancer cell lines were injected subcutaneously into scid mice and their in vivo growth behaviour and HPA binding pattern were analysed. Furthermore, the role of HPA binding glycoconjugates concerning the adhesion to endothelial cells in vitro was investigated.
Four of the tested cell lines engrafted in the scid mouse model but they showed considerable variations concerning their growth behaviour, their metastatic potential and their HPA binding pattern. HPA inhibited adhesive interactions between cell lines derived from metatstatic sources and tumour necrosis factor (TNF)α stimulated endothelial cells.
The transplantation of HPA defined breast cancer cell lines into scid mice is a useful animal model for the research of breast cancer and its metastasis. The HPA binding glycoconjugates appear to be associated with adhesive interactions between metastasising tumour cells and endothelial cells.
One of the commonest and least well understood posttranslational modifications of proteins is their glycosylation. Human glycoproteins are glycosylated with a bewilderingly heterogeneous array of complex N- and O-linked glycans, which are the product of the coordinated activity of enzymes resident in the endoplasmic reticulum and Golgi apparatus of the cell. Glycosylation of proteins is highly regulated and changes during differentiation, development, under different physiological—and cell culture—conditions and in disease. The glycosylation of recombinant proteins, especially those destined for potential administration to human subjects, is of critical importance. Glycosylation profoundly affects biological activity, function, clearance from circulation, and crucially, antigenicity. The cells of nonhuman species do not glycosylate their proteins in the same way as human cells do. In many cases, the differences are profound. Overall, the species most distant to humans in evolutionary terms, such as bacteria, yeasts, fungi, insects and plants—the species used most commonly in expression systems—have glycosylation repertoires least like our own. This review gives a brief overview of human N- and O-linked protein glycosylation, summarizes what is known of the glycosylation potential of the cells of nonhuman species, and presents the implications for the biotechnology industry.
Helix pomatia lectin (HPA) binding is a marker of metastatic competence in several human cancers. The altered cellular glycosylation detected by HPA is of clinical interest and functional significance, but research has been hampered by uncertainty over appropriate and accessible histochemical methods. Most studies have employed a complex multi-layered detection system localising binding of unconjugated HPA by layering with a polyclonal antibody to HPA, a biotinylated secondary antibody against the first antibody and streptavidin peroxidase. This detection system is sensitive and yields accurate prognostic information, but is lengthy and requires antibodies against HPA that are not widely available. A simpler technique, that uses peroxidase-labelled HPA is inappropriate as the carbohydrate-combining characteristics of the lectin are altered, and the prognostic significance of lectin binding is lost. Therefore a valid alternative, simple and accessible technique is required. In the present study, we compare the results of labelling of HPA binding using the complex multi-layered detection system with a simple avidin-biotin method. In a series of 101 breast cancers, both methods gave comparable results. Therefore, the avidin-biotin method appears to be appropriate for studies on HPA binding to detect altered glycoforms in cancer. It is hoped that its adoption may encourage research into this clinically significant alteration in cellular glycosylation.
The expression of the aberrant N-acetylgalactosamine (GalNAc) glycoconjugates, detected by binding of the lectin from Helix pomatia (HPA) is reported to be associated with metastatic competence and poor prognosis in a range of human adenocarcinomas, but the functional significance of the glycoconjugates in metastatic mechanisms is unknown. We have employed seven cell lines derived from normal breast epithelium, primary breast cancer and breast cancer metastases which stably express varying levels of HPA-binding glycoconjugates consistent with their derivation and phenotype. These cell lines have been thoroughly characterised and express identical profiles of HPA-binding glycoconjugates as tumour cells derived from clinical samples. Their ability to adhere to, and invade through, basement membrane components was investigated in a matrigel assay system, and the functional role of the aberrant GalNAc glycans assessed by competitive inhibition experiments using HPA. The behaviour of the cell lines in these assay systems was entirely consistent with their derivation and phenotype, but there was no evidence that the glycoconjugates of interest were functionally involved in adhesion or invasion mechanisms. Research in our laboratory is ongoing to seek a functional role for the HPA-binding glycoconjugates in other aspects of the metastatic cascade.
Predicting long-term outcome after breast-cancer diagnosis remains problematic, particularly for patients with clinically small, axillary lymph node- negative tumours. Evidence suggests that the lectin Helix pomatia agglutinin (HPA) identifies oligosaccharides associated with poor-prognosis cancer. Our aim was to identify oligosaccharides that bind HPA in aggressive breast cancers. Breast-cancer cell lines (MCF-7, BT-549 and BT-20) and a cell line from human milk (HBL-100), which showed a range of HPA-binding intensities, were used to extract HPA-binding glycoproteins. Oligosaccharides were released using anhydrous hydrazine and separated on a range of HPLC matrices. We investigated whether HPA-binding oligosaccharides from cell lines were present in human breast-cancer tissues, using 69 breast-cancer specimens from patients with between 5 and 10 years' follow-up. A monosialylated oligosaccharide was over-expressed in the cell line that bound HPA strongly. Further analysis by normal-phase HPLC showed that the 2-aminobenzamide-conjugated oligosaccharide had a hydrodynamic volume of 4.58 glucose units (HPAgly1). Increased expression of HPAgly1 was associated with HPA staining of breast-cancer specimens (Student's t-test p = 0.025). Analysis of oligosaccharide levels and disease-free survival after treatment for breast cancer indicated a shorter disease-free interval for patients with elevated levels of HPAgly1. This is the first time that histochemical lectin staining has been correlated with biochemical mapping of oligosaccharides. Using this approach, we have identified a monosialylated HPA lectin-binding oligosaccharide present in breast-cancer cells grown in vitro which is elevated in breast-cancer specimens that bind the lectin.
Over-expression of N-acetylgalactosamine glycoproteins as detected by binding of the lectin from Helix pomatia (HPA), is associated with metastatic competence and poor patient prognosis in a range of human adenocarcinomas. These glycoproteins remain poorly characterised, and their functional role has yet to be elucidated. This study describes characterisation of a range of human breast/breast cancer cell lines for the expression of the N-acetylgalactosaminylated glycoproteins of interest, and their comparison with normal breast epithelium and a range of clinical breast carcinoma samples. Confocal and light microscopy studies revealed cytochemical HPA-binding patterns consistent with a fundamental disruption in normal glycobiosynthetic pathways attending increasing metastatic potential. We report the most complete comparative analysis of HPA-binding ligands from cultured breast cells, clinical breast carcinoma samples and normal breast epithelium to date. Lectin blotting identified 11 major HPA-binding glycoprotein bands common to both clinical tumour samples and breast cell lines and 6 of these bands were also expressed by samples of normal breast epithelium, albeit at much lower levels. Moreover, very marked quantitative but not qualitative differences in levels of expression consistent with metastatic capability were noted.
Binding of the lectin from Helix pomatia (HPA), which recognises N-acetylgalactosamine and N-acetylglucosamine glycans, is a predictor of metastasis and poor prognosis in a number of human adenocarcinomas, including breast cancer. The glycoproteins to which it binds in these tumours have been only partially characterised, and the mechanisms underlying their biosynthesis remain unknown. In this study, 111 primary breast cancers were assessed for binding of HPA and labelling characteristics were compared directly with those of Dolichos biflorus agglutinin and soybean agglutinin, both of which also recognise N-acetylgalactosamine, Griffonia simplicifolia agglutinin II, which recognises N-acetylglucosamine, and Limax flavus agglutinin, Sambucus nigra agglutinin and Maackia amurensis lectin I, all of which recognise sialic acids. Results indicate that the HPA-binding partners expressed by cancer cells are predominantly N-acetylgalactosamine glycans, but some recognition of N-acetylglucosamine species is also likely. There was no evidence to support the hypothesis that overexpression of these moieties results from failure in sialylation. Alternative mechanisms, for example alterations in levels of activity of appropriate glycosyl transferases or disruption in transport and processing mechanisms leading to failure of normal chain extension of glycans may be responsible, and these are areas that warrant further investigation.
The lectin from Helix pomatia, the Roman snail (HPA), recognises terminal alpha N-acetylgalactosamine residues. A large number of lectin histochemical studies have demonstrated that expression of HPA-binding glycoproteins by cancer cells to be a marker of metastatic competence and poor prognosis in a range of common human adenocarcinomas, including those of breast, stomach, ovary, oesophagus, colorectum, thyroid and prostate. Around 80% of metastases arising from primary breast cancer are predictably HPA positive, but, intriguingly, around 20% do not express HPA binding glycoproteins reflecting the complexity of metastatic mechanisms and the further disruptions in cellular glycosylation that attend tumour progression. HPA binding is not an independent prognostic factor, but is strongly associated with the presence of metastases in local lymph nodes. It does appear to be independent of other clinical features of prognostic importance such as tumour size, histological grade, S-phase fraction, ploidy, and there is little convincing evidence of any association with oncogene expression or hormone receptor positivity. The precise nature of the metastasis-associated HPA binding partner(s) is a question of some interest, but thus far remains unclear. HPA will recognise, for example, the Tn epitope and blood group A antigen, but its prognostic significance appears to be through recognition of a much broader and heterogeneous array of N-galactosaminylated glycoproteins. Their synthesis appears to be mediated through alteration in expression or activity of one or more of the enzymes of glycosylation. The most likely putative roles of HPA-binding ligands in the metastatic cascade may be enhancement of invasive capacity, or interaction with an as yet unidentified lectin-like receptor facilitating adhesion processes. The prognostic information provided by HPA lectin histochemistry may be used clinically to inform the physician and aid treatment decisions; far more interesting is the challenge of further understanding the precise nature of the HPA-binding ligands, and defining their role in the complex mechanisms of metastasis.
Aberrant glycosylation is an established characteristic of cancer cells, and appears to have a functional role in metastasis — the process by which cancer cells spread around the body. The lectin from Helix pomatia, the Romansnail, (H. pomatia agglutinin, HPA) recognises cancer-associated aberrant glycans terminating in the monosaccharide α-N-acetylgalactosamine (GalNAc). The presence of these GalNAc-glycans, detected by HPA binding, is associated with metastasis and consequent poor survival. We are investigating the putative functional role of these glycans in cancer cell adhesion to, and migration through, the endothelium (lining blood vessels) during metastasis. A study by our group investigated the adhesion of eight breast cell lines; one normal breast cell line, and seven breast cancer cell lines with increasingly greater amounts of GalNAc-glycans, consistent with their increasing metastatic ability, to an endothelial cell monolayer from human brain microvasculature, a site physiologically relevant to breast cancer metastasis. This study provided novel evidence that GalNAc-glycanson breast cancer cells have a functional role in breast cancer cell adhesion to endothelial cells. It was also found that the HPA binding profiles of the breast cell lines appear to correlate with their abilities to adhere to endothelial cells via GalNAc-glycans.
A study is also currently being carried out to aim to identify the receptors on the endothelial cells that bind to the GalNAc-glycans on the breast cancer cells.