Whole-genome resequencing reveals the pleistocene temporal dynamics of Branchiostoma belcheri and Branchiostoma floridae populations

Amphioxus adenosine-to-inosine tRNA-editing enzyme that can perform C-to-U and A-to-I deamination of DNA

Adenosine-to-inosine tRNA-editing enzyme has been identified for more than two decades, but the study on its DNA editing activity is rather scarce. We show that amphioxus (Branchiostoma japonicum) ADAT2 (BjADAT2) contains the active site 'HxE-PCxxC' and the key residues for target-base-binding, and amphioxus ADAT3 (BjADAT3) harbors both the N-terminal positively charged region and the C-terminal pseudo-catalytic domain important for recognition of substrates. The sequencing of BjADAT2-transformed Escherichia coli genome suggests that BjADAT2 has the potential to target E. coli DNA and can deaminate at TCG and GAA sites in the E. coli genome. Biochemical analyses further demonstrate that BjADAT2, in complex with BjADAT3, can perform A-to-I editing of tRNA and convert C-to-U and A-to-I deamination of DNA. We also show that BjADAT2 preferentially deaminates adenosines and cytidines in the loop of DNA hairpin structures of substrates, and BjADAT3 also affects the type of DNA substrate targeted by BjADAT2. Finally, we find that C89, N113, C148 and Y156 play critical roles in the DNA editing activity of BjADAT2. Collectively, our study indicates that BjADAT2/3 is the sole naturally occurring deaminase with both tRNA and DNA editing capacity identified so far in Metazoa.

High Genetic Connectivity Inferred from Whole-Genome Resequencing Provides Insight into the Phylogeographic Pattern of Larimichthys polyactis

Compared with terrestrial biota, marine fishes usually present lower genetic differentiation among different geographical populations because of high-level gene flow and lack of physical barriers. Understanding the genetic structure of marine fishes is essential for dividing management unit and making reasonable protection measures. The small yellow croaker (Larimichthys polyactis) belongs to the family Sciaenidae, which is an economic fish and widely distributed in the Western Pacific. To delineate genetic diversity and phylogeographic pattern, whole-genome resequencing was used to evaluate genetic connectivity, genetic diversity, and spatial pattern of L. polyactis for the first time. We obtained 6,645,711 high-quality single nucleotide polymorphisms (SNPs) markers from 40 L. polyactis individuals. The phylogenetic analysis, STRUCTURE, principal component analysis, and F_st results all indicated that no genetic structure consistent with the distribution pattern was found. This result revealed high genetic connectivity of L. polyactis in different sampling sites. High genetic diversity was also detected, indicating that there was sufficient evolutionary potential to maintain its effective population size. Besides, a similar result of high genetic connectivity and genetic diversity was also detected by mitochondria DNA marker. Our study demonstrated the persistence of high levels of genetic connectivity and a lack of population structure across L. polyactis in different sea areas. This study aimed to analyze the division of population structure and the reason for the decline and not exhaustion of L. polyactis resource on a genetic level.

Deep whole-genome resequencing sheds light on the distribution and effect of amphioxus SNPs

BACKGROUND

Amphioxus is a model organism for vertebrate evolutionary research. The significant contrast between morphological phenotypic similarity and high-level genetic polymorphism among amphioxus populations has aroused scientists' attention. Here we resequenced 21 amphioxus genomes to over 100X depth and mapped them to a haploid reference.

RESULTS

More than 11.5 million common SNPs were detected in the amphioxus population, which mainly affect genes enriched in ion transport, signal transduction and cell adhesion, while protein structure analysis via AlphaFold2 revealed that these SNPs fail to bring effective structural variants.

CONCLUSIONS

Our work provides explanation for "amphioxus polymorphism paradox" in a micro view, and generates an enhanced genomic dataset for amphioxus research.

A chromosome-level genome of the mud crab (Scylla paramamosain estampador) provides insights into the evolution of chemical and light perception in this crustacean

Mud crabs, found throughout the Indo-Pacific region, are coastal species that are important fisheries resources in many tropical and subtropical Asian countries. Here, we present a chromosome-level genome assembly of a mud crab (Scylla paramamosain). The genome is 1.55 Gb (contig N50 191 kb) in length and encodes 17,821 proteins. The heterozygosity of the assembled genome was estimated to be 0.47%. Effective population size analysis suggested that an initial large population size of this species was maintained until 200 thousand years ago. The contraction of cuticle protein and opsin genes compared with Litopenaeus vannamei is assumed to be correlated with shell hardness and light perception ability, respectively. Furthermore, the analysis of three chemoreceptor gene families, the odorant receptor (OR), gustatory receptor (GR) and ionotropic receptor (IR) families, suggested that the mud crab has no OR genes and shows a contraction of GR genes and expansion of IR genes. The numbers of the three gene families were similar to those in three other decapods but different from those in two nondecapods and insects. In addition, IRs were more diversified in decapods than in nondecapod crustaceans, and most of the expanded IRs in the mud crab genome were clustered with the antennal IR clades. These findings suggested that IRs might exhibit more diverse functions in decapods than in nondecapods, which may compensate for the smaller number of GR genes. Decoding the S. paramamosain genome not only provides insight into the genetic changes underpinning ecological traits but also provides valuable information for improving the breeding and aquaculture of this species.