In order to find out whether long interspersed elements (LINEs) existed in macro-algae gehomes or not, we tested the LINE homologues in representative families (species): Gracilaria (G. eucheumoides Harv., G. tenuistipitata Chang et Xia, and G. textorii (Sur) De-Toni), Laminaria (L. longissima Miyabe and L. japonica Aresch.), and Ulva (U. lactuca L. and U. pertusa Kjellm.) during 2004 to 2005. Polymerase Chain Reaction (PCR) was carried out with degenerate oligonucleotide primers designed from LINEs of rice homologues and Cin4 of maize. Cloning and nucleotide sequencing of the PCR products revealed that 4 clones that derived from 3 species of Gracilaria have LINE homologues. The nucleotide sequences of the 4 LINE homologues diverged greatly, but the amino acid sequences deduced from them were relatively conserved. The endonuclease regions of the LINE homologues greatly diverged from that of other plants, but they had closer phylogenetic relationship to Zepp elements in Chlorella sp., which indicated that sequence divergence by vertical transmission has been a major influence on the evolution of algal LINEs.
The development of genetics has entered into new genetic markers application ysage which developed one after the other from Mendelian morphological marker, cytogenetics marker, allozyme marker to DNA markers in algal research.Based on morphological features such as the colours and seed sizes of pea, Mendel discovered the famous genetic laws. The cytogenetics markers included chromosome morphology, number and structure, which can be used for gene localization. Allozymes are allelic variants of proteins produced by a single gene locus, and are of interest as markers because of the existing polymorphism. Since the 1970s, it has been used widespread for population genetics and other fields in biology. Since the last decade of the 20th century, various DNA marker techniques have been invented, such as RFLP, RAPD, AFLP, SSR and SNP. With DNA markers, it is conveniently and easily to observe and exploit genetic variation in the entire genome. However, the application of molecular markers is still in its primary level. Here the principles and characters of kinds of molecular markers were reviewed including their applications in algae research, respectively.
With a "two-way pseudo-testcross" mapping strategy, we applied the amplified fragment length polymorphism (AFLP) markers to construct two moderate density genetic linkage maps for Laminaria. The linkage maps were generated from the 60 progenies of the F1 cross family (Laminaria iongissima Aresch. × L. Japonica Miyabe) with twenty pairs of primer combinations. Of the 333 polymorphic loci scored in 60 progenies, 173 segregated in a 1:1 ratio, corresponding to DNA polymorphisms heterozygous in a single parent, and the other 58 loci existing in both parents followed a 3:1 Mendelian segregation ratio. Among the loci with 1:1 segregating ratios, 79 loci were ordered in 14 linkage groups (648.6 cM) of the paternal map, and 72 loci were ordered in 14 linkage groups (601.9 cM) of the maternal map. The average density of loci was approximately 1 per 8 cM. To Investigate the homologies between two parental maps, we used 58 loci segregated 3:1 for further analysis, and deduced one homologous linkage group. The linkage data developed in these maps will be useful for detecting loci-controlling commercially important traits for Laminaria.
