Early manifestations of Anderson Fabry disease

This thesis examines some early renal and neurological manifestations in Anderson Fabry disease (AFD). First, estimating glomerular filtration rate in AFD using serum creatinine (Cr) based equations was assessed in 106 AFD patients. The Modification in diet in renal disease (MDRD) and the Chronic kidney disease epidemiology collaboration (CKD-EPI) equations had the least bias and were the best methods of estimating glomerular filtration rates in AFD patients with chronic kidney disease (CKD) stage 1 to 3. The monitoring of renal involvement in AFD use methods which assess glomerular function predominantly though there is evidence of renal tubular damage and atrophy on renal biopsy. We investigated possible urine markers of renal tubular dysfunction in AFD and 2 other proteins detectable in urine which have been shown to be markers of renal scarring and inflammation. Urine β-hexosaminidase (β-hex) and Monocyte chemoattractant protein-1 (MCP-1) were elevated in AFD patients compared with control demonstrating evidence of renal tubular involvement and possible renal inflammation. Finally we investigated cardiac autonomic function, cardiac neuroendocrine function, sweat function and symptoms related to neuropathic and autonomic function in an AFD cohort. There was little evidence of sweat dysfunction, cardiac autonomic or cardiac neuroendocrine dysfunction, though there is significant evidence of neuropathic pain and autonomic symptoms

Multi centre study from Malaysia on student preparedness for clinical learning- Perspectives of lecturers and students from medicine, pharmacy and allied health sciences

Objectives: To determine the characteristics important in health profession students’ preparedness for clinical learning from the perspectives of lecturers and studentsMethods: A descriptive cross sectional study was conducted at International Medical University, Perdana University and Monash University in Malaysia. All lecturers involved in preparing students for clinical learning in medicine, dentistry, nursing, pharmacy, nutrition and dietetics, chiropractic and Chinese medicine and immediate preclinical students were invited. We explored views regarding student preparedness on knowledge and understanding, willingness to learn, professionalism, communication and interaction, personal attributes and interpersonal skills rated on a 7 point Likert scale in a questionnaire with 62 items.Results: A total of 187 lecturers and 317 students participated. Fifty percent of lecturers had 5-9year of experience. Neither the lecturers nor the students had differentiated or identified specific characteristics as more important over the others but rated all 62 items as important (score >5) for training. The mean score of the 6 themes for lecturers and students respectively were for knowledge and understanding (5.44,5.09), willingness (5.95,5.51), professionalism (5.89,5.49), communication and interaction (5.54,5.34), personal attributes (5.54,5.35) and interpersonal skills (5.54,5.38). Interesting suggestions such as promotion of inter-professional learning among student from different disciplines, case discussions as a team with other professional categories, self reflection for lecturers regarding their attitudes towards students and teaching methods had been stated by students.Conclusions: Both lecturers and students deem that the knowledge and understanding is not the most important characteristic that makes a student better prepared for clinical learning.

A Distinct Urinary Biomarker Pattern Characteristic of Female Fabry Patients That Mirrors Response to Enzyme Replacement Therapy

Female patients affected by Fabry disease, an X-linked lysosomal storage disorder, exhibit a wide spectrum of symptoms, which renders diagnosis, and treatment decisions challenging. No diagnostic test, other than sequencing of the alpha-galactosidase A gene, is available and no biomarker has been proven useful to screen for the disease, predict disease course and monitor response to enzyme replacement therapy. Here, we used urine proteomic analysis based on capillary electrophoresis coupled to mass spectrometry and identified a biomarker profile in adult female Fabry patients. Urine samples were taken from 35 treatment-naive female Fabry patients and were compared to 89 age-matched healthy controls. We found a diagnostic biomarker pattern that exhibited 88.2% sensitivity and 97.8% specificity when tested in an independent validation cohort consisting of 17 treatment-naive Fabry patients and 45 controls. The model remained highly specific when applied to additional control patients with a variety of other renal, metabolic and cardiovascular diseases. Several of the 64 identified diagnostic biomarkers showed correlations with measures of disease severity. Notably, most biomarkers responded to enzyme replacement therapy, and 8 of 11 treated patients scored negative for Fabry disease in the diagnostic model. In conclusion, we defined a urinary biomarker model that seems to be of diagnostic use for Fabry disease in female patients and may be used to monitor response to enzyme replacement therapy

Atrial arrhythmogenicity in aged Scn5a+/∆KPQ mice modeling long QT type 3 syndrome and its relationship to Na+ channel expression and cardiac conduction

Recent studies have reported that human mutations in Nav1.5 predispose to early age onset atrial arrhythmia. The present experiments accordingly assess atrial arrhythmogenicity in aging Scn5a+/∆KPQ mice modeling long QT3 syndrome in relationship to cardiac Na+ channel, Nav1.5, expression. Atrial electrophysiological properties in isolated Langendorff-perfused hearts from 3- and 12-month-old wild type (WT), and Scn5a+/∆KPQ mice were assessed using programmed electrical stimulation and their Nav1.5 expression assessed by Western blot. Cardiac conduction properties were assessed electrocardiographically in intact anesthetized animals. Monophasic action potential recordings demonstrated increased atrial arrhythmogenicity specifically in aged Scn5a+/ΔKPQ hearts. These showed greater action potential duration/refractory period ratios but lower atrial Nav1.5 expression levels than aged WT mice. Atrial Nav1.5 levels were higher in young Scn5a+/ΔKPQ than young WT. These levels increased with age in WT but not Scn5a+/ΔKPQ. Both young and aged Scn5a+/ΔKPQ mice showed lower heart rates and longer PR intervals than their WT counterparts. Young Scn5a+/ΔKPQ mice showed longer QT and QTc intervals than young WT. Aged Scn5a+/ΔKPQ showed longer QRS durations than aged WT. PR intervals were prolonged and QT intervals were shortened in young relative to aged WT. In contrast, ECG parameters were similar between young and aged Scn5a+/ΔKPQ. Aged murine Scn5a+/ΔKPQ hearts thus exhibit an increased atrial arrhythmogenicity. The differing Nav1.5 expression and electrocardiographic indicators of slowed cardiac conduction between Scn5a+/ΔKPQ and WT, which show further variations associated with aging, may contribute toward atrial arrhythmia in aged Scn5a+/ΔKPQ hearts

Quantum biology: an update and perspective

This is the final version. Available from MDPI via the DOI in this record. Data Availability Statement: Not applicable.Understanding the rules of life is one of the most important scientific endeavours and has revolutionised both biology and biotechnology. Remarkable advances in observation tech-niques allow us to investigate a broad range of complex and dynamic biological processes in which living systems could exploit quantum behaviour to enhance and regulate biological functions. Recent evidence suggests that these non-trivial quantum mechanical effects may play a crucial role in maintaining the non-equilibrium state of biomolecular systems. Quantum biology is the study of such quantum aspects of living systems. In this review, we summarise the latest progress in quantum biology, including the areas of enzyme-catalysed reactions, photosynthesis, spin-dependent reactions, DNA, fluorescent proteins, and ion channels. Many of these results are expected to be fundamental building blocks towards understanding the rules of life.Leverhulme Trus

Linkage to chromosome 2q32.2-q33.3 in familial serrated neoplasia (Jass syndrome)

Causative genetic variants have to date been identified for only a small proportion of familial colorectal cancer (CRC). While conditions such as Familial Adenomatous Polyposis and Lynch syndrome have well defined genetic causes, the search for variants underlying the remainder of familial CRC is plagued by genetic heterogeneity. The recent identification of families with a heritable predisposition to malignancies arising through the serrated pathway (familial serrated neoplasia or Jass syndrome) provides an opportunity to study a subset of familial CRC in which heterogeneity may be greatly reduced. A genome-wide linkage screen was performed on a large family displaying a dominantly-inherited predisposition to serrated neoplasia genotyped using the Affymetrix GeneChip Human Mapping 10 K SNP Array. Parametric and nonparametric analyses were performed and resulting regions of interest, as well as previously reported CRC susceptibility loci at 3q22, 7q31 and 9q22, were followed up by finemapping in 10 serrated neoplasia families. Genome-wide linkage analysis revealed regions of interest at 2p25.2-p25.1, 2q24.3-q37.1 and 8p21.2-q12.1. Finemapping linkage and haplotype analyses identified 2q32.2-q33.3 as the region most likely to harbour linkage, with heterogeneity logarithm of the odds (HLOD) 2.09 and nonparametric linkage (NPL) score 2.36 (P = 0.004). Five primary candidate genes (CFLAR, CASP10, CASP8, FZD7 and BMPR2) were sequenced and no segregating variants identified. There was no evidence of linkage to previously reported loci on chromosomes 3, 7 and 9

Cardiac sodium channel complexes and arrhythmia: structural and functional roles of the β1 and β3 subunits.

In cardiac myocytes, the voltage-gated sodium channel NaV 1.5 opens in response to membrane depolarisation and initiates the action potential.  The NaV 1.5 channel is typically associated with regulatory β-subunits that modify gating and trafficking behaviour. These β-subunits contain a single extracellular immunoglobulin (Ig) domain, a single transmembrane alpha-helix and an intracellular region. Here we focus on the role of the β1 and β3-subunits in regulating NaV 1.5. We catalogue β1 and β3 domain specific mutations that have been associated with inherited cardiac arrhythmia, including Brugada Syndrome, long QT syndrome, atrial fibrillation and sudden death. We discuss how new structural insights into these proteins raises new questions about physiological function. Abstract figure legend Molecular organisation of NaV α- and β-subunits in healthy ventricular myocardium. The cardiac voltage-gated sodium channel, NaV 1.5, is typically found in multiple locations within ventricular myocytes together with β1 and/or β3, including at the lateral surface membrane, intercalated disc (ID) and caveolae. Other neuronal NaV α isoforms including NaV 1.1, NaV 1.3 and NaV 1.6 have been identified in the t-tubules along with both β1 and β3. In the specialised caveolar lipid membranes NaV 1.5 localises with Kir2.1, in addition to L-type Ca channels and other potassium channels (not shown). Further functional specialisations arise from unique trans, cell-cell, NaV 1.5 interactions facilitated by the β1-subunit adopting an alternative structural conformation in which the extracellular Ig domains extend across the intercalated discs (inset). The β3-subunit likely also facilitates stabilisation of NaV 1.5 macromolecular complexes in cis (on the same cell), however the relative organisation of the α- and β-subunits are less defined. Image created with BioRender.com (license: OO24F5AVYS). This article is protected by copyright. All rights reserved

Cardiac sodium channel complexes and arrhythmia: structural and functional roles of the β1 and β3 subunits.

In cardiac myocytes, the voltage-gated sodium channel NaV 1.5 opens in response to membrane depolarisation and initiates the action potential.  The NaV 1.5 channel is typically associated with regulatory β-subunits that modify gating and trafficking behaviour. These β-subunits contain a single extracellular immunoglobulin (Ig) domain, a single transmembrane alpha-helix and an intracellular region. Here we focus on the role of the β1 and β3-subunits in regulating NaV 1.5. We catalogue β1 and β3 domain specific mutations that have been associated with inherited cardiac arrhythmia, including Brugada Syndrome, long QT syndrome, atrial fibrillation and sudden death. We discuss how new structural insights into these proteins raises new questions about physiological function. Abstract figure legend Molecular organisation of NaV α- and β-subunits in healthy ventricular myocardium. The cardiac voltage-gated sodium channel, NaV 1.5, is typically found in multiple locations within ventricular myocytes together with β1 and/or β3, including at the lateral surface membrane, intercalated disc (ID) and caveolae. Other neuronal NaV α isoforms including NaV 1.1, NaV 1.3 and NaV 1.6 have been identified in the t-tubules along with both β1 and β3. In the specialised caveolar lipid membranes NaV 1.5 localises with Kir2.1, in addition to L-type Ca channels and other potassium channels (not shown). Further functional specialisations arise from unique trans, cell-cell, NaV 1.5 interactions facilitated by the β1-subunit adopting an alternative structural conformation in which the extracellular Ig domains extend across the intercalated discs (inset). The β3-subunit likely also facilitates stabilisation of NaV 1.5 macromolecular complexes in cis (on the same cell), however the relative organisation of the α- and β-subunits are less defined. Image created with BioRender.com (license: OO24F5AVYS). This article is protected by copyright. All rights reserved