Kouchi H, Hata S
Department of Applied Physiology, National Institute of Agrobiological Resources, Ibaraki, Japan.
Mol Gen Genet. 1993 Apr;238(1-2):106-19. doi: 10.1007/BF00279537.
We took advantage of a subtractive hybridization procedure to isolate a set of cDNA clones of nodule-specific genes (nodulin genes) from developing soybean root nodules. Single-stranded 32P-labelled cDNA synthesized from nodule poly(A)+ RNA was hybridized with a large excess of uninfected root poly(A)+ RNA. Unhybridized cDNA was selected and used to screen nodule cDNA libraries. By this procedure we isolated several novel nodulin cDNA clones together with most of the nodulin cDNAs previously described. Four novel nodulin genes, which were expressed long before the onset of nitrogen fixation, were further characterized. GmN#36 and GmN#93 transcripts appeared in the roots less than 3 days after sowing and inoculation with Bradyrhizobium, but GmN#36 transcripts were also detected at very low levels in the stems of uninfected plants. Transcripts of GmN#315 and GmN#70 first appeared at 6-7 days, just before nodule emergence. Amino acid sequences of the predicted products of GmN#36, GmN#93 and GmN#70 exhibited no significant homology to proteins identified so far. The GmN#315 encoded protein has a limited but significant homology to some plant cyanins, suggesting that it is a metal-binding glycoprotein. In situ hybridization studies revealed that GmN#36 transcripts first appeared in the pericycle cells of the root stele near the infected site. During nodule emergence they were found in a few cell layers surrounding the vascular strands connecting the nodule meristem with the root stele, and in mature nodules they were present specifically in the pericycle cells in vascular bundles. These observations led us to hypothesize that GmN#36 gene products play a role in the transport and/or degradation of photosynthate. On the other hand, GmN#93 transcripts first appeared in the primary nodule meristem just below the root epidermis. In mature nodules they were only present in the infected cells.
我们利用消减杂交技术从发育中的大豆根瘤中分离出一组根瘤特异性基因(根瘤素基因)的cDNA克隆。由根瘤多聚腺苷酸加尾RNA(poly(A)+ RNA)合成的单链32P标记的cDNA与大量未感染根的多聚腺苷酸加尾RNA杂交。未杂交的cDNA被筛选出来用于筛选根瘤cDNA文库。通过这个方法,我们分离出了几个新的根瘤素cDNA克隆以及之前描述的大多数根瘤素cDNA。对四个在固氮开始前很久就表达的新根瘤素基因进行了进一步的表征。GmN#36和GmN#93转录本在播种和接种慢生根瘤菌后不到3天就在根中出现,但在未感染植株的茎中也能检测到极低水平的GmN#36转录本。GmN#315和GmN#70的转录本在第6 - 7天首次出现,就在根瘤出现之前。GmN#36、GmN#93和GmN#70预测产物的氨基酸序列与目前已鉴定的蛋白质没有显著同源性。GmN#315编码的蛋白质与一些植物花青素具有有限但显著的同源性,表明它是一种金属结合糖蛋白。原位杂交研究表明,GmN#36转录本首先出现在感染部位附近根中柱的中柱鞘细胞中。在根瘤出现期间,它们出现在连接根瘤分生组织和根中柱的维管束周围的几层细胞中,在成熟根瘤中,它们特异性地存在于维管束的中柱鞘细胞中。这些观察结果使我们推测GmN#36基因产物在光合产物的运输和/或降解中起作用。另一方面,GmN#93转录本首先出现在根表皮下方的初级根瘤分生组织中。在成熟根瘤中,它们只存在于被感染的细胞中。
