Evolutionary concepts in biobanking - the BC BioLibrary.

BACKGROUND: Medical research to improve health care faces a major problem in the relatively limited availability of adequately annotated and collected biospecimens. This limitation is creating a growing gap between the pace of scientific advances and successful exploitation of this knowledge. Biobanks are an important conduit for transfer of biospecimens (tissues, blood, body fluids) and related health data to research. They have evolved outside of the historical source of tissue biospecimens, clinical pathology archives. Research biobanks have developed advanced standards, protocols, databases, and mechanisms to interface with researchers seeking biospecimens. However, biobanks are often limited in their capacity and ability to ensure quality in the face of increasing demand. Our strategy to enhance both capacity and quality in research biobanking is to create a new framework that repatriates the activity of biospecimen accrual for biobanks to clinical pathology. METHODS: The British Columbia (BC) BioLibrary is a framework to maximize the accrual of high-quality, annotated biospecimens into biobanks. The BC BioLibrary design primarily encompasses: 1) specialized biospecimen collection units embedded within clinical pathology and linked to a biospecimen distribution system that serves biobanks; 2) a systematic process to connect potential donors with biobanks, and to connect biobanks with consented biospecimens; and 3) interdisciplinary governance and oversight informed by public opinion. RESULTS: The BC BioLibrary has been embraced by biobanking leaders and translational researchers throughout BC, across multiple health authorities, institutions, and disciplines. An initial pilot network of three Biospecimen Collection Units has been successfully established. In addition, two public deliberation events have been held to obtain input from the public on the BioLibrary and on issues including consent, collection of biospecimens and governance. CONCLUSION: The BC BioLibrary framework addresses common issues for clinical pathology, biobanking, and translational research across multiple institutions and clinical and research domains. We anticipate that our framework will lead to enhanced biospecimen accrual capacity and quality, reduced competition between biobanks, and a transparent process for donors that enhances public trust in biobanking.

An isothermal method for whole genome amplification of fresh and degraded DNA for comparative genomic hybridization, genotyping and mutation detection.

Molecular genotyping has important biomedical and forensic applications. However, limiting amounts of human biological material often yield genomic DNA (gDNA) in insufficient quantity and of poor quality for a reliable analysis. This motivated the development of an efficient whole genome amplification method with quantitatively unbiased representation usable on fresh and degraded gDNA. Amplification of fresh frozen, formalin-fixed paraffin-embedded (FFPE) and DNase-degraded DNA using degenerate oligonucleotide-primed PCR or primer extension amplification using a short primer sequence bioinformatically optimized for coverage of the human genome was compared with amplification using current primers by chromosome-based and BAC-array comparative genomic hybridization (CGH), genotyping at short tandem repeats (STRs) and single base mutation detection. Compared with current primers, genome amplification using the bioinformatically optimized primer was significantly less biased on CGH in self-self hybridizations, and replicated tumour genome copy number aberrations, even from FFPE tissue. STR genotyping could be performed on degraded gDNA amplified using our technique but failed with multiple displacement amplification. Of the 18 different single base mutations 16 (89.5%) were correctly identified by sequencing gDNA amplified from clinical samples using our technique. This simple and efficient isothermal method should be helpful for genetic research and clinical and forensic applications.

Primer design for Whole Genome Amplification using genetic algorithms.

Whole Genome Amplification (WGA) is an important process to increase limiting amounts of genomic DNA prior to genomic analyses. Current amplification methods based on primer extension or strand displacement principles employ primers of partially or totally random sequence. In this paper, we present a method using Genetic Algorithms to optimize a single primer design to be used in a primer extension reaction to achieve unbiased WGA. Computational simulation and prediction of a suitable primer proposed two candidates NYP6-1 (ATCTCA) and NYP6-2 (TGAGAT). NYP6-1 amplified to a maximum length of 2537 base pairs (bp), had genome coverage of approximately 45.62%, with an average of 493 and variance of 163 amplicons per 1 megabasepairs (Mb). NYP6-2 amplified to a maximum length of 2926 bp and covered 54.35% of the genome with an average of 579 and a variance of 191 amplicons per Mb. In contrast, the original primer used in Degenerate Oligonucleotide-Primed PCR (DOP-PCR) had coverage of 20.93%, an average of 74 and variance of 188 amplicons per Mb when extended up to a length of 2000 bp. Successful WGA of miniscule amounts of genomic DNA requires the amplification method used to resolve issues on efficiency, accurate representation of the whole genome and ability to degraded DNA. The sequence NYP6-2 discovered using our method can be confidently used in a primer extension based protocol to perform quantitatively unbiased WGA.

An isothermal primer extension method for whole genome amplification of fresh and degraded DNA: applications in comparative genomic hybridization, genotyping and mutation screening.

We describe a protocol that uses a bioinformatically optimized primer in an isothermal whole genome amplification (WGA) reaction. Overnight incubation at 37 degrees C efficiently generates several hundred- to several thousand-fold increases in input DNA. The amplified product retains reasonably faithful quantitative representation of unamplified whole genomic DNA (gDNA). We provide protocols for applying this isothermal primer extension WGA protocol in three different techniques of genomic analysis: comparative genomic hybridization (CGH), genotyping at simple tandem repeat (STR) loci and screening for single base mutations in a common monogenic disorder, beta-thalassemia. gDNA extracted from formalin-fixed paraffin-embedded (FFPE) tissues can also be amplified with this protocol.

Compression of functional space in HLA-A sequence diversity.

The major histocompatibility complex (MHC) is highly polymorphic and more than 1500 human MHC alleles are known to date. These alleles do not bind to a given peptide with identical affinity. Although MHC alleles are functionally related, it is difficult to quantify the functional variation between them. Three-dimensional structures of known MHC-peptide (MHCp) complexes suggest that specific peptide residues bind selectively to functional pockets in the binding groove. From a set of known MHCp structures we identified 21 critical polymorphic functional residue positions (CPFRP) that significantly reduced functional pocket variability to just 189 among 212 HLA-A alleles. Interestingly 101 HLA-A alleles clustered into 29 clusters such that the six functional pockets formed by the CPFRPs are identical within the cluster.