Histone modification and signalling cascade of the dormancy‐associated MADS‐box gene,PpMADS13‐1, in Japanese pear (Pyrus pyrifolia) during endodormancy

Dormancy‐associated MADS‐box (DAM) genes play an important role in endodormancy phase transition. We investigated histone modification in the DAM homolog (PpMADS13‐1) from Japanese pear, via chromatin immunoprecipitation–quantitative PCR, to understand the mechanism behind the reduced expression of the PpMADS13‐1 gene towards endodormancy release. Our results indicated that the reduction in the active histone mark by trimethylation of the histone H3 tail at lysine 4 contributed to the reduction of PpMADS13‐1 expression towards endodormancy release. In contrast, the inactive histone mark by trimethylation of the histone H3 tail at lysine 27 in PpMADS13‐1 locus was quite low, and these levels were more similar to a negative control [normal mouse immunoglobulin G (IgG)] than to a positive control (AGAMOUS) in endodormancy phase transition. The loss of histone variant H2A.Z also coincided with the down‐regulation of PpMADS13‐1. Subsequently, we investigated the PpMADS13‐1 signalling cascade and found that PpCBF2, a pear C‐repeated binding factor, regulated PpMADS13‐1 expression via interaction of PpCBF2 with the 5′‐upstream region of PpMADS13‐1 by transient reporter assay. Furthermore, transient reporter assay confirmed no interaction between the PpMADS13‐1 protein and the pear FLOWERING LOCUS T genes. Taken together, our results enhance understanding of the molecular mechanisms underlying endodormancy phase transition in Japanese pear.     

EFFECTS OF GLUCOSE ON THE PROCESS OF CHLOROPLAST DEVELOPMENT IN CHLORELLA PROTOTHECOIDES

By growing Chlorella protothecoides in a medium rich in glucoseand poor in nitrogen source (urea), the entirely chlorophyll-lesscells showing no discernible plastid structure and containingonly little RNA and protein were obtained. These cells, whichwere called "glucosebleached" cells, turned green after a certainlag period, when they were incubated, in the light, in a mediumcontaining the nitrogen source and basal mineral nutrients butwithout glucose. As has been shown in previous studies, thisgreening process involves two consecutive steps : a light-independentphase, in which RNA plays an essential role, and a light-requiringphase, in which the chlorophyll formation and full organizationof chloroplast take place accompanied by the formation of acertain species of protein ("alkali-stable" protein). The wholeprocess of greening was found to be profoundly suppressed byaddition of glucose, the degree of suppression being determinedby the relative concentrations of glucose and the nitrogen source.The primary act of glucose was manifest in the repression ofsyntheses of RNA, and of the species of protein mentioned above,which participate in, or causally related to, the first andsecond phases, respectively, in the greening process. ¹ This paper was read at the Symposium on Extranuclear Self-reproducingSystems held by the Botanical Society of Japan in October, 1964     

Sensory Responses of Reinnervated Muscle Spindles

EXTENSIVE morphological, histochemical and electrophysiological studies have been made on skeletal muscles at varying stages of motor reinnervation. But in spite of the physiological significance of muscle receptors in controlling skeletal muscle activity, there have been no detailed studies of their reinnervation. We have therefore investigated the functional and structural characteristics of muscle spindles associated with their sensory reinnervation.     

Progesterone facilitates Implantation of Xenogenic Cultured Cells in Hamster Uterus

ATTEMPTS to explain the phenomenon of nidation on the basis of maternal immunological tolerance have recently made progress^1–4 through pre-sensitization of the mother by the tissue of the father-to-be, followed by studies of the antigenicity of fertilized ova and evaluation of the mother's antibody production. Other workers have stressed the importance of chorionic cells in nidation, based on the occurrence of intraabdominal pregnancy not involving the uterus. Chambon⁵ and Cochrane and Meyer⁶ recognized the influence of oestrogen and progesterone on uterine tissue during nidation and Psychoyos⁷ emphasized the importance of gonadal hormones in the preparation of endometrium for implantation based on delayed nidation. The role of progesterone in the formation of the decidual reaction as a prerequisite to nidation has been clearly established.     

Evidence for a Viral Macronuclear Endosymbiont in Paramecium caudatum

ABSTRACT. Some strains of P. caudatum contain macronuclear inclusion bodies that are morphologically distinct from bacteria. They vary in number as well as in size in each macronucleus. The inclusion bodies are basically divided into peripheral and inner areas. The peripheral area consists of fibrillar proteins of 22–24 nm in thickness, which are specifically stained with fast green in 45% acetic acid. On the other hand, chromatin-like granules are within the inner area of large inclusion bodies. The granules within the inner area changed their distribution depending upon the physiological state of their host cells. Transplantation experiments and crossbreeding analyses revealed that genetic factors responsible for the multiplication of the inclusion bodies can 'infect' other macronuclei (or cells) via the cytoplasm. These results suggest that the inclusion bodies are a non-bacterial macronuclear endosymbiont, possibly produced by a virus or a virus-like element.