Cyclic Nucleotide Gated Channels and Ca2+-Mediated Signal Transduction During Plant Innate Immune Response to Pathogens

Transitory perturbations in the level of cytosolic Ca²⁺ are well known to be involved in numerous cell signaling pathways in both plant and animal systems. However, not much is known at present about the molecular identity of plant plasma membrane Ca²⁺ conducting ion channels or their specific roles in signal transduction cascades. A recent study employing genetic approaches as well as patch clamp electrophysiological analysis of channel currents has provided the first such direct evidence linking a specific gene product with inward Ca²⁺ currents across the plant cell membrane. This work identified Ca²⁺ permeation through (Arabidopsis) cyclic nucleotide gated channel isoform 2 (CNGC2) as contributing to the plant innate immunity signaling cascade initiated upon perception of a pathogen. Here, we expand on the implications of CNGC2 mediated cytosolic Ca²⁺ elevations associated with plant cell response to pathogen recognition, and propose some additional steps that may be involved in the innate immunity signal cascade.Key Words: calcium, CNGC, hypersensitive response, nitric oxide, plant innate immunity, plant ion channel, reactive oxygen species     

Gonadotropin-releasing hormone in third ventricular cerebrospinal fluid of the heifer during the estrous cycle

The release profile of GnRH in cerebrospinal fluid (CSF) and its correlation with LH in peripheral blood of ovary-intact heifers during the estrous cycle were investigated. A silicon catheter was placed into the third ventricle of six heifers using ultrasonography. During the mid-luteal phase, the heifers were injected with prostaglandin F(2alpha) to induce luteolysis. Surges of CSF GnRH (66.7 h after prostaglandin F(2alpha) administration) and peripheral LH (66.3 h) occurred simultaneously and were coincident with the onset of estrus (67.0 h). Duration of elevated GnRH concentration considerably overlapped with the estrous phase in each of the heifers. Mean pulse frequencies of both GnRH and LH were significantly higher during the proestrous and early luteal phases than during the mid-luteal phase, while mean concentration and pulse amplitude of both GnRH and LH were not different between these three phases. Of all the GnRH pulses identified, more than 80% were accompanied by an LH pulse during the proestrous and early luteal phases. However, the proportion of GnRH pulses that were coincident with an LH pulse during the mid-luteal phase decreased to 60%. The results clearly demonstrate that a dynamic (pulse) and longer-term (surge) changes of GnRH release into CSF are physiologically expressed during the estrous cycle in heifers, and the pattern of pulsatile GnRH secretion in heifers depends upon their estrous cycle.     

Molecular cloning and characterization of a cDNA for a novel ethylene receptor, NT-ERS1, of tobacco (Nicotiana tabacum L.)

The cDNA encoding a novel member (NT-ERS1) of ethylene receptor family of tobacco (Nicotiana tabacum L.) was obtained by a combination of RT-PCR and 5'-/3'-RACE cloning. The cDNA was 2,092 nucleotides long and had an open reading frame of 1,911 bp encoding 637 amino acids. The deduced polypeptide lacked a response regulator domain, indicating that the ethylene receptor belongs to an ERS-group. The amino acid sequence was similar to respective members of the tobacco ethylene receptor family: 67.8% to NT-ETR1, 39.1% to NTHK1 and 31.1% to NTHK2. Comparison of amino acid sequence suggested that NT-ERS1 is the counterpart of Nr in the ethylene receptor family of tomato, which belongs to Solanaceae as does tobacco. Northern blot analysis showed that mRNA of NT-ERS1 was present in leaf, shoot and root tissues, and accumulated in leaves treated with exogenous ethylene. A mutated NT-ERS1 cDNA transgene, obtained by introducing one nucleotide substitution into NT-ETR1 cDNA, conferred ethylene insensitivity in tobacco plants, indicating that the translation product of the cDNA actually functioned in the plants.     

Indispensability of transmembrane domains of Golgi UDP-galactose transporter as revealed by analysis of genetic defects in UDP-galactose transporter-deficient murine had-1 mutant cell lines and construction of deletion mutants

UDP-galactose transporter is a membrane protein localized in the Golgi apparatus. It translocates UDP-galactose from the cytosol into the Golgi lumen, thus providing galactosyltransferases with their substrate. We characterized murine UDP-galactose transporter through molecular cloning for the following purposes: (i) to elucidate the molecular bases underlying the genetic defects of murine Had-1 mutants, which are deficient in UDP-galactose transporting activity, and (ii) to obtain information that would help us in planning rational approaches to identify functionally essential regions, based on comparison of primary structures between human and murine UDP-galactose transporters. We identified five nonsense mutations, one missense Gly178Asp mutation, and two aberrant splicing mutations. Although glycine178 is highly conserved among nucleotide-sugar transporters, a Gly178Ala variant was functional. The species-differences between human and murine UDP-galactose transporters were largely confined to the N- and C-terminal regions of the transporters. Substantial deletions in the N- and C-terminal regions did not lead to loss of UDP-galactose transporting activity, indicating that these cytosolic regions are dispensable for the transporting activity. The transporter was fused with green-fluorescent protein at the C-terminal cytosolic tail without impairing the functions of either protein. Our results demonstrate the importance of the transmembrane core region of the UDP-galactose transporter protein.     

Subunit Interacting Surfaces of Human Hemoglobin in Solution: Localization of the α–β Subunit Interacting Surfaces on the α-Chain by a Comprehensive Synthetic Strategy

By using synthetic overlapping peptides encompassing the entire -chain of adult human hemoglobin (HbA), we have mapped on the -chain the regions responsible for its binding to the -chain in solution. These binding surfaces were, in general, in good agreement with those expected from the crystal structure (peptides 81–95, 101–115, 111–125, and 131–141). However, we observed some significant differences in the levels of binding found here in solution and those expected from the crystal structure. Peptide 31–45, which in the crystal had the highest number of contact residues of all the -chain peptides, did not bind the -chain in solution. Similarly, peptide 91–105, with seven contact residues in the crystal, showed low binding with the -chain in solution. On the other hand, peptides 41–55 and 121–135 possessed much higher binding activity in solution than would be expected from their contribution to subunit association in the crystal. In fact, peptide 121–135 had the highest binding activity of the -chain peptides. These studies and our previous findings, which localized on the -chain the regions that bind to the -chain in solution, have shown that the regions of subunit association in solution are close to, but not identical with, those in the crystal. The approach should be quite useful for mapping subunit association in oligomeric proteins and could even be applied to proteins that are isolated only in traces or whose three-dimensional structure is not yet known.