Genes & Genetic Systems 98 巻, 1 号

Rice SUMOs and unification of their names

Posttranslational modifications (PTMs) to proteins are regulatory mechanisms that play a critical role in regulating growth and development. The SUMO system is a rapid and dynamic PTM system employed by eukaryotic cells. Plant SUMOs are involved in many physiological processes, such as stress responses, regulation of flowering time and defense reactions to pathogen attack. In Arabidopsis thaliana and rice (Oryza sativa), eight and seven SUMO genes, respectively, were predicted by sequence analysis. Phylogenetic tree analysis of these SUMOs shows that they are divided into two groups. One consists of SUMOs that contain no SUMO acceptor site and are involved in monoSUMOylation of their target proteins. Rice OsSUMO1 and OsSUMO2 are in this group, and are structurally similar to each other and to Arabidopsis AtSUMO1. The other group is composed of SUMOs in which an acceptor site (ΨKXE/D) occurs inside the SUMO molecule, suggesting their involvement in polySUMOylation. Several studies on the rice SUMOs have been performed independently and reported. Individual names of rice SUMOs are confusing, because a unified nomenclature has not been proposed. This review clarifies the attribution of seven rice SUMOs and unifies the individual SUMO names.

On the origin of the genetic code

Mechanisms underlying how the genetic code was generated by Darwinian selection have remained elusive since the code was cracked in 1965. Here, I propose a hypothesis on the emergence of the genetic code and predict that its emergence was driven by sequential distinct selective pressures. According to the hypothesis, aminoacyl-RNAs for Glu, Asp, Lys, Tyr, His, Arg, Cys and Ser were first selected as cartridge-type subunits of three-subunit ribozymes. Aminoacyl-RNA subunits acting as cofactors were accommodated by the proto P-site of the large subunit of ribozymes. Importantly, I predict that there was no direct relationship between amino acids and codon and anticodon pairs. Duplication of the proto P-site could have created the proto A-site, enabling multi-subunit ribozymes to simultaneously interact with two-cartridge-type aminoacyl-RNA subunits. Random insertion of two cartridges would have instantly abolished enzymatic activity of multi-subunit ribozymes. On the other hand, if two tandemly aligned pairs of codons and anticodons specify two cartridges, dozens of different active pockets in multi-subunit ribozymes would have rapidly emerged, leading to the rise of extant organisms’ metabolic pathways. The strong driving force of Darwinian selection described here could have created the primary genetic code for catalytic amino acids. Evolution of the protein translation system and events leading to the expansion of the genetic code until the time it was “frozen” are presented in detail.

Differential expression profile of miRNAs between stable and vulnerable plaques of carotid artery stenosis patients

Plaque vulnerability is associated with the degree of carotid artery stenosis (CS) and the risk of stroke. MicroRNAs (miRNAs) exert critical functions in disease progression, although only a few miRNAs have been well identified in CS. Therefore, this study aimed to investigate the differential expression profile of miRNAs and their potential functions in plaques of CS patients. Three CS patients with stable plaques and three patients with vulnerable plaques who underwent carotid endarterectomy were enrolled in this study. Differentially expressed miRNAs (DEmiRNAs) between patients with stable and vulnerable plaques were determined using small RNA sequencing. Target genes of DEmiRNAs were predicted and submitted to functional analyses. Validation of dysregulated DEmiRNAs was determined using quantitative real-time polymerase chain reaction (qRT-PCR). After sequencing, 76 DEmiRNAs were identified in vulnerable plaques, including 53 upregulated miRNAs and 23 downregulated miRNAs. Next, 23,495 target genes of the identified DEmiRNAs were predicted and functionally analyzed. This indicated that the target genes of the identified DEmiRNAs were mainly enriched in protein phosphorylation, transcription, nitrogen compound metabolism, endocytosis and autophagy, and related to signaling pathways of Hippo, MAPK, insulin, TGF-β, FoxO, AMPK and p53. Furthermore, qRT-PCR results for six miRNAs showed that five (83%) of them (hsa-miR-511-5p, hsa-miR-150-5p, hsa-miR-378a-5p, hsa-miR-365b-5p and hsa-miR-6511b-5p) were consistent with the sequencing results. Differential expression profiles and potential function of miRNAs associated with plaque stability in CS patients are identified for the first time, which should help to understand the regulatory mechanism of plaque stability in CS.

Genetic structure and population history of a peat swamp forest tree species, Shorea albida (Dipterocarpaceae), in Brunei Darussalam

Southeast Asia supports high biodiversity, in a mosaic of forest types formed by the expansion and contraction of habitats through past climate changes. Among the region’s forest types, the geographical distribution of peat swamp forests has fluctuated intensely over the past 120,000 years. Most peat swamp forests in Southeast Asia are found in coastal regions and formed within the last 7,000 years after a decline in sea level. However, some peat swamps were initiated earlier on substrates of slightly higher elevation, and these peat swamps might have been refugia for peat swamp species in the last glacial period and the high sea level period. We assessed genetic diversity, genetic structure and divergence time of current genetic groups for Shorea albida in Brunei, an endemic tree species of Bornean peat swamp forests, using 18 microsatellite markers. Genetic diversity was not lower than has been found in other Shorea species, possibly because of the high density of S. albida in Brunei. Although overall genetic divergence between populations was low, two populations (Ingei and Labi Road 3) were distinct from the other populations. Analysis using DIYABC estimated that three genetic groups (Ingei, Labi Road 3 and others) diverged simultaneously from their ancestral population, whose effective size was very small, about 7,500 years ago, corresponding to a recent sea level peak in the Belait-Baram river basin. In that high sea level period, some higher-elevation lands remained, and peat formation had already started in this region. We propose that the current genetic structure of S. albida in Brunei was formed from small refugial populations that survived the period of higher sea level in these higher-elevation areas. Because of their relatively high genetic diversity, Brunei’s S. albida populations should become an important genetic resource for the recovery of genetically healthy populations in other parts of northwest Borneo.

The role of conserved amino acid residues of Sae3 in Mei5–Sae3 complex for Dmc1 assembly in meiotic recombination

Meiotic recombination between homologous chromosomes is promoted by the collaborative action of two RecA homologs, Rad51 and meiosis-specific Dmc1. The filament assembly of Dmc1 is promoted by meiosis-specific Mei5–Sae3 in budding yeast. Mei5–Sae3 shows sequence similarity to fission yeast Sfr1–Swi5, which stimulates DNA strand exchanges by Rad51 as well as Dmc1. Sae3 and Swi5 share a conserved motif with the amino acid sequence YNEI/LK/RD. In this study, we analyzed the role of the YNEL residues in the Sae3 sequence in meiotic recombination and found that these residues are critical for Sae3 function in Dmc1 assembly. L59 substitution in the Sae3 protein disrupts complex formation with Mei5, while Y56 and N57 substitutions do not. These observations reveal the differential contribution of conserved YNEL residues to Sae3 activities in meiotic recombination.