Construction of a Full-Length transcriptome resource for the African sharptooth catfish (Clarias gariepinus), a prototypical air-breathing Fish, based on isoform sequencing (Iso-Seq).

The African sharptooth catfish (Clarias gariepinus) assumes significance in aquaculture, given its role as a farmed freshwater species with modified gill structures functioning as an air-breathing organ (ABO). To provide a scientific basis for further elucidating the air-breathing formation mechanism and deeply utilizing the genetic resources of Clarias gariepinus, we utilized the PacBio sequencing platform to acquire a comprehensive full-length transcriptome from five juvenile developmental stages and various adult tissues, including the ABO, gills, liver, skin, and muscle. We generated 25,766,688 high-quality reads, with an average length of 2,006 bp and an N50 of 2,241 bp. Following rigorous quality control, 34,890 (97.7 %) of the high-quality isoforms were mapped to the reference genome for gene and transcript annotation, yielding 387 novel isoforms and 14,614 new isoforms. Additionally, we identified 28,582 open reading frames, 48 SNPs, 5,464 variable splices, and 6,141 variable polyadenylation sites, along with 475 long non-coding RNAs. Many DEGs were involved with low oxygen GO terms and KEGG pathways, such as response to stimulus, biological regulation and catalytic activities. Furthermore, it was found that transcription factors such as zf-C2H2, Homeobox, bHLH, and MYB could underpin the African sharptooth catfish's developmental plasticity and its capacity to adapt its morphology and function to its environment. Through the comprehensive analysis of its genomic characteristics, it was found that the African sharptooth catfish has developed a series of unique respiratory adaptive mechanisms during the evolutionary process, These results not only advances the understanding of genetic adaptations to hypoxia in Clarias fish but also provides a valuable framework for future studies aimed at improving aquaculture practices,besides provide important references and inspirations for the evolution of aquatic organisms.

Phylogenetic inference of inter-population transmission rates for infectious diseases.

Estimating transmission rates is a challenging yet essential aspect of comprehending and controlling the spread of infectious diseases. Various methods exist for estimating transmission rates, each with distinct assumptions, data needs, and constraints. This study introduces a novel phylogenetic approach called transRate, which integrates genetic information with traditional epidemiological approaches to estimate inter-population transmission rates. The phylogenetic method is statistically consistent as the sample size (i.e. the number of pathogen genomes) approaches infinity under the multi-population susceptible-infected-recovered model. Simulation analyses indicate that transRate can accurately estimate the transmission rate with a sample size of 200 ~ 400 pathogen genomes. Using transRate, we analyzed 40,028 high-quality sequences of SARS-CoV-2 in human hosts during the early pandemic. Our analysis uncovered significant transmission between populations even before widespread travel restrictions were implemented. The development of transRate provides valuable insights for scientists and public health officials to enhance their understanding of the pandemic's progression and aiding in preparedness for future viral outbreaks. As public databases for genomic sequences continue to expand, transRate is increasingly vital for tracking and mitigating the spread of infectious diseases.

A developmental validation of the Quick TargSeq 1.0 integrated system for automated DNA genotyping in forensic science for reference samples.

Analysis of short tandem repeats (STRs) is a global standard method for human identification. Insertion/Deletion polymorphisms (DIPs) can be used for biogeographical ancestry inference. Current DNA typing involves a trained forensic worker operating several specialized instruments in a controlled laboratory environment, which takes 6-8 h. We developed the Quick TargSeq 1.0 integrated system (hereinafter abbreviated to Quick TargSeq) for automated generation of STR and DIP profiles from buccal swab samples and blood stains. The system fully integrates the processes of DNA extraction, polymerase chain reaction (PCR) amplification, and electrophoresis separation using microfluidic biochip technology. Internal validation studies were performed using RTyper 21 or DIP 38 chip cartridges with single-source reference samples according to the Scientific Working Group for DNA Analysis Methods guidelines. These results indicated that the Quick TargSeq system can process reference samples and generate STR or DIP profiles in approximately 2 h, and the profiles were concordant with those determined using traditional STR or DIP analysis methods. Thus, reproducible and concordant DNA profiles were obtained from reference samples. Throughout the study, no lane-to-lane or run-to-run contamination was observed. The Quick TargSeq system produced full profiles from buccal swabs with at least eight swipes, dried blood spot cards with two 2-mm disks, or 10 ng of purified DNA. Potential PCR inhibitors (i.e., coffee, smoking tobacco, and chewing tobacco) did not appear to affect the amplification reactions of the instrument. The overall success rate and concordance rate of 153 samples were 94.12% and 93.44%, respectively, which is comparable to other commercially available rapid DNA instruments. A blind test initiated by a DNA expert group showed that the system can correctly produce DNA profiles with 97.29% genotype concordance with standard bench-processing methods, and the profiles can be uploaded into the national DNA database. These results demonstrated that the Quick TargSeq system can rapidly generate reliable DNA profiles in an automated manner and has the potential for use in the field and forensic laboratories.