While the cultivated soybean, Glycine max (L.) Merr., is more recalcitrant to pod dehiscence (shattering-resistant) than wild soybean, Glycine soja Sieb. & Zucc., there is also significant genetic variation in shattering resistance among cultivated soybean cultivars. To reveal the genetic basis and develop DNA markers for pod dehiscence, several research groups have conducted quantitative trait locus (QTL) analysis using segregated populations derived from crosses between G. max accessions or between a G. max and G. soja accession. In the populations of G. max, a major QTL was repeatedly identified near SSR marker Sat_366 on linkage group J (chromosome 16). Minor QTLs were also detected in several studies, although less commonality was found for the magnitudes of effect and location. In G. max × G. soja populations, only QTLs with a relatively small effect were detected. The major QTL found in G. max was further fine-mapped, leading to the development of specific markers for the shattering resistance allele at this locus. The markers were used in a breeding program, resulting in the production of near-isogenic lines with shattering resistance and genetic backgrounds of Japanese elite cultivars. The markers and lines developed will hopefully contribute to the rapid production of a variety of shattering-resistant soybean cultivars.
In potatoes, tuber secondary growth, especially sprouting, deforms the tubers and severely lowers their commercial value. Tuber sprouting is induced by signal substances, such as gibberellin (GA), which are transported to the tuber from the plant body. The molecular mechanism underlying GA-induced sprouting remains ambiguous. Here, we tried to recreate tuber secondary growth using in vitro stemmed microtubers (MTs) (with the nodal stem attached) and MT halves (with the nodal stem entirely removed). Our experiments showed that GA alone could initiate the sprouting of stemmed microtubers; however, GA failed to initiate MT halves unless 6-benzyladenine, a synthetic cytokinin CK, was co-applied. Here, we analyzed the transcriptional profiles of sprouting buds using these in vitro MTs. RNA-seq analysis revealed a downregulation of cytokinin-activated signaling but an upregulation of the "Zeatin biosynthesis" pathway, as shown by increased expression of CYP735A, CISZOG, and UGT85A1 in sprouting buds; additionally, the upregulation of genes, such as IAA15, IAA22, and SAUR50, associated with auxin-activated signaling and one abscisic acid (ABA) negative regulator, PLY4, plays a vital role during sprouting growth. Our findings indicate that the role of the nodal stem is synonymous with CK in sprouting growth, suggesting that CK signaling and homeostasis are critical to supporting GA-induced sprouting. To effectively control tuber sprouting, more effort is required to be devoted to these critical genes.
Mussels (Mytilus sp.) from Sanriku Bay, NE Honshu, Japan were examined using morphological characters and electrophoretically detectable enzyme polymorphisms. Using both sets of criteria, the mussels were identified as M. galloprovincialis, the mediterranean mussel. This confirms an earlier opinion, which was based on morphological criteria alone, that the mediterranean mussel occurs on the mainland coast of Japan. Investigation of some early Japanese literature suggests that mussels did not occur in this area earlier this century, and M. galloprovincialis may have been introduced to the region of Kobe, around 1930–1935. The present-day distribution of M. edulis and M. galloprovincialis in the Japanese archipelago may be explained by sea-surface temperatures in the region.
Journal Article Reorientation of Cortical Microtubules in the Sub-Apical Region during Tuberization in Single-Node Stem Segments of Potato in Culture Get access Kaien Fujino, Kaien Fujino Department of Botany, Faculty of Agriculture, Hokkaido UniversitySapporo, 060 Japan Search for other works by this author on: Oxford Academic Google Scholar Yasunori Koda, Yasunori Koda Department of Botany, Faculty of Agriculture, Hokkaido UniversitySapporo, 060 Japan Search for other works by this author on: Oxford Academic Google Scholar Yoshio Kikuta Yoshio Kikuta Department of Botany, Faculty of Agriculture, Hokkaido UniversitySapporo, 060 Japan Search for other works by this author on: Oxford Academic Google Scholar Plant and Cell Physiology, Volume 36, Issue 5, July 1995, Pages 891–895, https://doi.org/10.1093/oxfordjournals.pcp.a078835 Published: 01 July 1995 Article history Received: 02 July 1994 Accepted: 19 May 1995 Published: 01 July 1995
