Flg22‐triggered oxylipin production in Pyropia haitanensis

This study provides evidence that flg22, the most conserved 22‐amino acid peptide in the N‐terminal part of bacterial flagellin can trigger the defense responses of Pyropia haitanensis (Bangiales, Rhodophyta). The defense responses are a chain of events including release of H₂O₂ and free unsaturated fatty acids C20:4, consumption of C18:3, and the chemical or enzymatic oxidation of both C20 and C18 polyunsaturated fatty acids. Oxidized C20 and C18 fatty acids lead to the production of corresponding hydroperoxy and hydroxylated derivatives, such as 9‐hydroperoxy octadecadienoic acid, 8‐hydroperoxy eicosapentaenoic acid, and 8‐hydroxyl eicosapentaenoic acid, which could be further oxidatively metabolized to yield saturated aldehydes and ketone. Changes of three typical hormones jasmonate, methyl jasmonate, and salicylic acid were observed. Contrary to the increase of jasmonate and methyl jasmonate, salicylic acid was decreased. The expression of key enzymes of oxylipin pathway PhLOX and PhLOX2 were upregulated. However, some defense and antioxidant related genes including PhHsp 70, Phsod , and PhRboh were downregulated markedly at the early stage of flg22 challenge. Overall, our results imply that red algae have evolved a similar defense response and may share the conservative‐recognizing receptor for flg22 as in higher plants.     

坛紫菜叶状体的无菌化培养及其应用

对坛紫菜叶状体的无菌处理方法进行了优化,并利用紫菜外生菌对无菌处理后的紫菜叶片进行了人工感染。经0.7%KI和0.1%(w/v)氨苄青霉素对紫菜叶片进行预处理后,利用氨苄青霉素、硫酸链霉素、新霉素、庆大霉素及卡那霉素等5种抗生素及其不同组合对紫菜叶片进行处理,筛选出最佳抗生素组合、浓度和培养条件。结果表明:氨苄青霉素(终浓度300μg/mL)、卡那霉素(终浓度100μg/mL)与庆大霉素(终浓度100μg/mL)3种抗生素组合对坛紫菜叶状体进行无菌处理18 h,对紫菜细胞的毒害较小,并且3种抗生素合用对89.5%紫菜外生细菌的抑菌率达80%以上;外生菌感染结果研究表明:用105/mL真菌孢子液和细菌菌液回染紫菜,培养22 d后,实验组紫菜生长状况较对照组好,对照组紫菜出现褪色。用108/mL真菌孢子液分别回染健康紫菜、穿刺紫菜(用灭菌刀片在紫菜表面划1～2 mm的伤口),分别在18℃、28℃和35℃条件下培养。实验结果表明28℃和35℃高温和穿刺均会影响无菌紫菜健康生长,且加菌紫菜在高温和穿刺条件下,则会出现明显病斑,而18℃培养的加菌紫菜则生长良好。     

A temporal and spatial study of genetic structure in four species of bladed Bangiales (Rhodophyta) from the southeastern Pacific coast of Chile

The coastline is a heterogeneous and highly dynamic environment influenced by abiotic and biotic variables affecting the temporal stability of genetic diversity and structure of marine organisms. The aim of this study was to determine how much the genetic structure of four species of marine Bangiales vary in time and space. Partial sequences of the cytochrome oxidase I (COI) gene obtained from two Pyropia (Py. sp. CHJ and Py. orbicularis) and two Porphyra (P. mumfordii and P. sp. FIH) species were used to compare the effect of the 40° S/41° S biogeographic break (spatial-regional scale) and the one of the Valdivia River discharges (spatial-local scale) and determine their temporal stability. Four seasonal samplings were taken during 1 year at five sites, one site located in Melinka (Magallanes province) and four sites along the coast of Valdivia (Intermediate area), on both sides of the river mouth. Results showed a strong genetic spatial structure at regional scale (ΦST > 0.4) in Py. sp. CHJ, Py. orbicularis, and P. mumfordii, congruent with the 41° S/42° S biogeographic break. A potential barrier to gene flow, related to the Valdivia River discharge, was detected only in P. mumfordii. In P. sp. FIH, spatial genetic structure was not detected at any scale. The genetic structure of all four species is stable throughout the year. The potential effect of main currents and river discharge in limiting the transport of Bangiales spores are discussed. We propose that both a restricted propagule dispersal and the formation potential for persistent banks of microscopic stages could lead to a temporally stable spatial partitioning of genetic variation in bladed Bangiales.     

IDENTIFICATION OF PORPHYRA HAITANENSIS (BANGIALES,RHODOPHYTA) MEIOSIS BY SIMPLE SEQUENCE REPEAT MARKERS1

The simple sequence repeat (SSR) marks were employed to identify the stage at which meiosis occurs in the life cycle of Porphyra haitanensis T. J. Chang et B. F. Zheng. More than 90% of F1 blades of heterozygous conchocelis produced by the cross between a red mutant (R, ♀) and the wildtype (W, ♂) were color sectored. Two parental colors (R and W) and two new colors (R′ and W′) appeared in linear sectors in the color‐sectored F1 blades. Two SSR primer pairs selected from a total of 52 primer pairs generated a specific paternal and maternal fragment, respectively. Co‐occurrence of these two bands was detected in heterozygous conchocelis and in the color‐sectored F1 blades with two to four sectors, such as R + W, R′ + W′, and R′ + R + W + W′. However, the single‐colored F1 blades exhibited only one band. In the sectors isolated from the color‐sectored F1 blades, R and R′ were the same, showing the maternal pattern, whereas W and W′ were the same, showing the paternal pattern. These data suggested that the two different bands from heterozygous conchocelis originated from the parents and segregated in the F1 blades, whereas the two new colors, R′ and W′, in the F1 blades were produced by the exchange and recombination of alleles of the parental colors during meiosis. These results indicated that meiosis of P. haitanensis occurs during the first two cell divisions of a germinating conchospore, and, therefore, the initial four cells constitute a linear genetic tetrad, leading to the formation of a color‐sectored blade.