遗传学实验技术

Identification of point mutations has been facilitated by a number of techniques, including transfection assays, oligonucleotide hybridization, electrophoretic migration of heteroduplexes, RNase mismatch analysis, direct sequencing, and DNA-polymerase catalyz ...

The advantages of direct sequencing of polymerase chain reaction (PCR) products over conventional sequencing of cloned, single-stranded DNA are manifold. Speed is perhaps the greatest asset. Time-consuming creation and screening of libraries, fragment purification, subclo ...

Loss of heterozygosity (LOH) is being detected with increasing frequency in a wide variety of human tumors (1-10). Frequent LOH at a given chromosomal locus implies the existence of a tumor suppressor gene that is important in the pathogenesis of the particular cancer under study. LOH is believed ...

It is a risky task to attempt to predict the direction that DNA barcoding and its applications may take in the future. In a very short time, the endeavor of DNA barcoding has gone from being a tool to facilitate taxonomy in difficult to identify species, to an ambitious, global initiative that seeks to tackle s ...

Long-term forest dynamics plots, such as those maintained and coordinated by the Center for Tropical Forest Science and Smithsonian Institution Global Earth Observatories (CTFS/SIGEO), are a rich source of biological data that describe the demographics, ecology, and evolution of p ...

The FISH-BOL campaign was initiated in 2005, and currently has barcoded for the cytochrome c oxidase subunit I (COI) gene about 8,000 of the 31,000 fish species currently recognised. This includes the great majority of the world’s most important commercial species. Results thus far show that abo ...

Ecologists and conservation biologists are increasingly focusing on quantifying the phylogenetic component of biodiversity in order to inform basic and applied research. A major obstacle of this approach in tropical ecosystems has been the difficulty of generating high-quali ...

The assembly of sequence data obtained from DNA barcodes into phylogenies or NJ trees has proven highly useful in estimating relatedness among species as well as providing a framework in which hypotheses regarding the evolution of traits or species distributions may be investigated. In t ...

DNA barcodes have great potential for species identification and taxonomic discovery in tropical forests. This use of DNA barcodes requires a reference DNA library of known taxa with which to match DNA from unidentified specimens. At an even more basic level, it presupposes that the species in ...

Procedures and protocols common to many DNA barcoding projects are summarized. Planning for any project should emphasize front-end procedures, especially the “genetic lockdown” of collected materials for downstream genetic procedures. Steps further into the DNA barcoding pr ...

DNA barcoding refers to the technique of sequencing a short fragment of the mitochondrial cytochrome c oxidase subunit I (COI) gene, the “DNA barcode,” from a taxonomically unknown specimen and performing comparisons with a reference library of barcodes of known species origin to establi ...

Invertebrates comprise approximately 34 phyla, while vertebrates represent one subphylum and insects a (very large) class. Thus, the clades excepting vertebrates and insects encompass almost all of animal diversity. Consequently, the barcoding challenge in invertebrates is t ...

Only a few major research programs are currently targeting COI barcoding of amphibians and reptiles (including chelonians and crocodiles), two major groups of tetrapods. Amphibian and reptile species are typically old, strongly divergent, and contain deep conspecific lineages w ...

This chapter is an overview of the techniques for DNA barcoding of fishes from field collection to DNA sequence analysis. Recommendations for modifications of field protocols and best tissue sampling practices are made. A variety of DNA extraction protocols is provided, including high- ...

As of February 2011, COI DNA barcode sequences (a 648-bp segment of the 5′ end of the mitochondrial gene cytochrome c oxidase I, the standard DNA barcode for animals) have been collected from over 23,000 avian specimens representing 3,800 species, more than one-third of the world’s avifauna. Here, we de ...

This chapter describes methods currently used for DNA barcoding of fungi, including some comments on the barcoding of aged herbarium material. The collecting procedures are focussed on macro-fungi. The laboratory methods are for medium-throughput DNA barcoding, targeted at the 96- ...

In the field of molecular biology, laboratory information management systems (LIMSs) have been created to track workflows through a process pipeline. For the purposes of DNA barcoding, this workflow involves tracking tissues through extraction, PCR, cycle sequencing, and consens ...

Information capture pertaining to the “what?”, “where?”, and “when?” of biodiversity data is critical to maintain data integrity, interoperability, and utility. Moreover, DNA barcoding and other biodiversity studies must adhere to agreed upon data standards in order to effectively co ...

The effectiveness of DNA barcoding as a routine practice in biodiversity research is strongly dependent on the quality of the source material, DNA extraction method, and selection of adequate primers in combination with optimized polymerase chain reaction (PCR) conditions. For the is ...

This chapter outlines the current practices used in our laboratory for routine DNA barcode analyses of the three major marine macroalgal groups, viz., brown (Phaeophyceae), red (Rhodophyta), and green (Chlorophyta) algae, as well as for the microscopic diatoms (Bacillariophyta). We st ...