Evolution of Reproductive Organs in Land Plants

LEAFY gene is the positive regulator of the MADS-box genes in flower primordia. The number of MADS-box genes presumably increased by gene duplications before the divergence of ferns and seed plants. Most MADS-box genes in ferns are expressed similarly in both vegetative and reproductive organs, while in gymnosperms, some MADS-box genes are specifically expressed in reproductive organs. This suggests that (1) the increase in the number of MADS-box genes and (2) the subsequent recruitment of some MADS-box genes as homeotic selector genes were important for the evolution of complex reproductive organs. The phylogenetic tree including both angiosperm and gymnosperm MADS-box genes indicates the loss of the A-function genes in the gymnosperm lineage, which is presumably related to the absence of perianths in extant gymnosperms. Comparison of expression patterns of orthologous MADS-box genes in angiosperms, Gnetales, and conifers supports the sister relationship of Gnetales and conifers over that of Gnetales and angiosperms predicted by phylogenetic trees based on amino acid and nucleotide sequences. Received 30 July 1999/ Accepted in revised form 9 September 1999     

Biological implications of the occurrence of 32 members of the XTH (xyloglucan endotransglucosylase/hydrolase) family of proteins in the bryophyte Physcomitrella patens

This comprehensive overview of the xyloglucan endotransglucosylase/hydrolase (XTH) family of genes and proteins in bryophytes, based on research using genomic resources that are newly available for the moss Physcomitrella patens, provides new insights into plant evolution. In angiosperms, the XTH genes are found in large multi‐gene families, probably reflecting the diverse roles of individual XTHs in various cell types. As there are fewer cell types in P. patens than in angiosperms such as Arabidopsis and rice, it is tempting to deduce that there are fewer XTH family genes in bryophytes. However, the present study unexpectedly identified as many as 32 genes that potentially encode XTH family proteins in the genome of P. patens, constituting a fairly large multi‐gene family that is comparable in size with those of Arabidopsis and rice. In situ localization of xyloglucan endotransglucosylase activity in this moss indicates that some P. patens XTH proteins exhibit biochemical functions similar to those found in angiosperms, and that their expression profiles are tissue‐dependent. However, comparison of structural features of families of XTH genes between P. patens and angiosperms demonstrated the existence of several bryophyte‐specific XTH genes with distinct structural and functional features that are not found in angiosperms. These bryophyte‐specific XTH genes might have evolved to meet morphological and functional needs specific to the bryophyte. These findings raise interesting questions about the biological implications of the XTH family of proteins in non‐seed plants.     

Early effects of HIV on CD4 lymphocytes in vivo

Low circulating CD4 cell numbers and CD4 cell dysfunction are distinguishing features of HIV-mediated disease. The current study delineates the in vivo effects of HIV on distinct functional subsets of CD4 cells in homosexually active men who have been infected with HIV for different lengths of time, and examines the capacity of lymphocytes from these men to proliferate in vitro in response to soluble antigen. Although peripherial blood mononuclear cells from most acquired immune deficiency syndrome (AIDS) patients did not proliferate in response to either tetanus toxoid or Candida albicans, cells from most HIV seropositive men without AIDS, many of whom had been infected for more than 18 mo, responded normally to both. Non-responsiveness in HIV-infected men without AIDS was a late event and was associated with longer duration of infection, lower CD4 cell numbers, and subsequent development of AIDS. A defect in this response was observed in only one of 19 HIV seropositive men whose CD4 levels were greater than 300/mm3, but in eight of 10 with levels less than 300/mm3. The defect could not be attributed to a selective depletion of defined CD4 subpopulations that respond to soluble antigen. Dual-color immunofluorescent flow cytometry indicated that 4B4+, 2H4-, and HB-11- CD4 cells were not lost at a faster rate than other CD4 subsets.     

A Dibasic Amino Acid Pair Conserved in the Activation Loop Directs Plasma Membrane Localization and Is Necessary for Activity of Plant Type I/II Phosphatidylinositol Phosphate Kinase

Phosphatidylinositol phosphate kinase (PIPK) is an enzyme involved in the regulation of cellular levels of phosphoinositides involved in various physiological processes, such as cytoskeletal organization, ion channel activation, and vesicle trafficking. In animals, research has focused on the modes of activation and function of PIPKs, providing an understanding of the importance of plasma membrane localization. However, it still remains unclear how this issue is regulated in plant PIPKs. Here, we demonstrate that the carboxyl-terminal catalytic domain, which contains the activation loop, is sufficient for plasma membrane localization of PpPIPK1, a type I/II B PIPK from the moss Physcomitrella patens. The importance of the carboxyl-terminal catalytic domain for plasma membrane localization was confirmed with Arabidopsis (Arabidopsis thaliana) AtPIP5K1. Our findings, in which substitution of a conserved dibasic amino acid pair in the activation loop of PpPIPK1 completely prevented plasma membrane targeting and abolished enzymatic activity, demonstrate its critical role in these processes. Placing our results in the context of studies of eukaryotic PIPKs led us to conclude that the function of the dibasic amino acid pair in the activation loop in type I/II PIPKs is plant specific.Phosphoinositides (PIs) are minor lipids found in membrane fractions but implicated in a wide variety of physiological regulations in eukaryotes (Di Paolo and De Camilli, 2006; Zonia and Munnik, 2006). Phosphatidylinositol-4,5-bisphosphate [PtdIns(4,5)P₂] is a major PI in animal plasma membranes, affecting the localization and activity of various kinds of proteins carrying phosphatidylinositol-binding domains, which in turn affect the regulation of cytoskeletal organization, vesicle trafficking, cell proliferation, and cell growth during development and stress responses (Doughman et al., 2003; Downes et al., 2005; Di Paolo and De Camilli, 2006; Zonia and Munnik, 2006; Heck et al., 2007). In addition, PtdIns(4,5)P₂ is also a well-known substrate of phospholipase C, producing second messengers such as diacylglycerol, phosphatidic acid (PA), and inositol-1,4,5-trisphosphate, which are involved in the activation of intracellular signal transduction pathways (Zonia and Munnik, 2006). Transient accumulation of PtdIns(4,5)P₂ has also been observed under various kinds of environmental stress (Pical et al., 1999; DeWald et al., 2001), suggesting an important role of this lipid in the regulation of stress signal transduction pathways also in plants. These findings indicate that PtdIns(4,5)P₂ is multifunctional and involved in a variety of cellular processes. Therefore, elucidation of the mechanisms controlling the cellular levels of PtdIns(4,5)P₂ is important in understanding the significance of PI signaling in eukaryotes.PtdIns(4,5)P₂ is synthesized by phosphatidylinositol phosphate kinases (PIPKs; Anderson et al., 1999; Doughman et al., 2003; Heck et al., 2007). Physiological roles of several plant PIPKs have been reported. In Arabidopsis (Arabidopsis thaliana), AtPIP5K3 is an essential regulator of tip growth of root hairs (Kusano et al., 2008; Stenzel et al., 2008), while AtPIPK4 and AtPIPK5 are essential for pollen germination and pollen tube elongation (Ischebeck et al., 2008; Sousa et al., 2008). In addition, AtPIP5K9 was shown to interact with the cytosolic invertase CINV1 to regulate sugar-mediated root cell elongation negatively (Lou et al., 2007). Rice (Oryza sativa) OsPIPK1 is proposed to be involved in shoot growth and floral initiation through the regulation of floral induction genes (Ma et al., 2004). In animals, membrane-associated type I PIPK mainly phosphorylates the D-5 hydroxyl group of PtdIns4P to produce PtdIns(4,5)P₂ but also produces PtdIns(3,4)P₂ and PtdIns(3,5)P₂ from PtdIns3P with 5- and 4-kinase activity (Anderson et al., 1999; Heck et al., 2007), whereas type II PIPK prefers the D-4 position of PtdIns5P, producing PtdIns(4,5)P₂ in the nucleus and at the endoplasmic reticulum (Clarke et al., 2007). Thus, in animals, type I and II PIPKs are involved in the generation of PtdIns(4,5)P₂ via different pathways. Molecular biological analysis of plant PIPKs was initiated with AtPIP5K1 from Arabidopsis (Mikami et al., 1998), which phosphorylates PtdIns3P, PtdIns4P, and PtdIns(4,5)P₂ to produce PtdIns(3,4)P₂, PtdIns(4,5)P₂, and PtdIns (3,4,5)P₃, respectively, with D-4- and D-5-kinase activity (Elge et al., 2001; Westergren et al., 2001; Im et al., 2007). Similar enzymatic activity was also reported for other PIPKs from Arabidopsis (Ischebeck et al., 2008; Kusano et al., 2008; Stenzel et al., 2008). In addition, a PIPK from the moss Physcomitrella patens (designated as PpPIPK1) preferred PtdIns4P, PtdIns3P, and PtdIns(3,4)P₂ as substrates, but not PtdIns5P, producing PtdIns(4,5)P₂, PtdIns(3,4)P₂, and PtdIns(3,4,5)P₃, respectively (Saavedra et al., 2009). These findings indicate that the substrate specificity of plant PIPKs is essentially the same as that of type I PIPKs. However, AtPIP5K1 has yet to be classified as either type I or type II based on sequence comparisons of the catalytic domain (CD; Mikami et al., 1998). This was confirmed by a genome-wide analysis of PIPK genes in Arabidopsis in which all 11 PIPKs were classified as type I/II based on sequence comparisons of the CDs, which were further subdivided into subtypes A and B (Mueller-Roeber and Pical, 2002). Therefore, it is suggested that typical type I and II PIPKs are absent in plants, although further confirmation is needed.The conserved PIPK CD contains a short highly conserved region near its C-terminal end, designated the activation loop, which acts as the substrate-binding site and is responsible for the differences in substrate specificity and subcellular localization between animal type I and type II PIPKs (Kunz et al., 2000, 2002). Substrate specificities of animal type I and type II PIPKs, for example, are determined by a respective Glu and Ala at the corresponding positions in the activation loop. Moreover, it has been established that substitution of Glu to Ala results in a swap of substrate specificity and subcellular localization between the two types (Kunz et al., 2000, 2002). In contrast to animal PIPKs, a substitution in the activation loop of PpPIPK1 from Glu to Ala resulted in a nearly complete loss of type I/II activity; however, such a mutation did not fully convert the substrate specificity, although an enhancement of type II versus type I activity was observed (Saavedra et al., 2009). Since the corresponding amino acid residue is Glu in all plant PIPKs so far reported, it is suggested that there also is a plant-specific mode of substrate specificity regulation in plant type I/II PIPKs. However, enzymatic activity appears to be modified in similar ways between plant type I/II and animal type I PIPKs; that is, phosphorylation- and PA-dependent activation of PIPKs has been observed in both animals and plants (Moritz et al., 1992; Jenkins et al., 1994; Pical et al., 1999; Westergren et al., 2001; Perera et al., 2005; Saavedra et al., 2009).The regulation of plasma membrane localization of mammalian type I PIPKs remains confusing. In addition to the involvement of a Glu residue as mentioned above, the substitution of two Lys residues in the activation loop to Asn residues changes the subcellular localization from the plasma membrane to the cytosol (Kunz et al., 2000, 2002). However, Arioka et al. (2004) also showed that the plasma membrane localization of type I PIPKs is regulated by another basic amino acid pair localized downstream of the activation loop in the CD, which is not found in type II PIPKs. Interestingly, the mechanism behind plasma membrane localization of plant PIPKs seems to differ significantly from the animal one. The obvious structural feature of plant PIPKs is the presence of a repetition of membrane occupation and recognition nexus (MORN) motifs at the N-terminal half, which is conserved across the B subfamily of plant type I/II PIPKs (Mueller-Roeber and Pical, 2002). The MORN motif was first identified in mammalian junctophilin, an endoplasmic reticulum-membrane-bound component of the junctional complex between the plasma membrane and the endoplasmic reticulum (Takeshima et al., 2000). Since MORN motifs are not found in PIPKs from nonplant organisms, a plant-specific mode of PIPK activation is speculated. Indeed, a regulatory role of the MORN domain was reported in the enzymatic activation of AtPIP5K1 (Im et al., 2007) and in root hair formation, but not in enzymatic activation, of AtPIP5K3 (Stenzel et al., 2008). Moreover, the MORN domain may play a role in the plasma membrane localization of OsPIPK1 from rice and AtPIP5K1 and AtPIP5K3 from Arabidopsis (Ma et al., 2006; Im et al., 2007; Kusano et al., 2008). However, stable transformation of tobacco (Nicotiana tabacum) cells to express an AtPIP5K1 MORN domain-GFP fusion did not allow visualization of the plasma membrane localization of this protein (Im et al., 2007). Thus, it is not clear if the MORN domain functions as a plasma membrane-targeting module.Given the sequence conservation of the CD among eukaryotic PIPKs (Saavedra et al., 2009), we hypothesize that the CD is responsible for the plasma membrane localization of plant PIPKs. Thus, to gain further insight into the mechanisms regulating this issue, we dissected PpPIPK1 to determine the molecular determinants of plasma membrane localization. Here, we show that the MORN domain is not involved in the plasma membrane localization of PpPIPK1 and AtPIP5K1 in P. patens protoplasts and onion (Allium cepa) epidermal cells. We further demonstrate that two basic amino acids, but not Glu, conserved in the activation loop of the CD are required for plasma membrane localization. These findings demonstrate that the activation mode of type I/II PIPKs is plant specific and differs from that of the membrane-localized animal type I PIPKs.     

Comparison of air-lift and stirred tank reactors for itaconic acid production by Aspergillus terreus

In a 2-l stirred tank reactor (STR), maximum production rate ofitaconic acid was 0.48g/l.h , for an agitation rate of 400 rpm andan aeration rate of 0.5 vvm. In an air-lift reactor (ALR) themaximum production rate was 0.64 g/l.h at an O supply rate of0.41 l O /l. min. Power input per unit volume which gave themaximum production rates for STR and ALR were 1180 and 542 W/m 3,respectively. If O -enriched air was used in place of air for ALR,the corre-sponding power input per unit volume was decreased to 34W/m 3 . ALR requires less power input per unit volume in comparisonwith that of STR whether therefore air or O -enriched air is used.ALR would be a suitable bioreactor for a large production of itaconicacid.     

Characterization of the <Emphasis Type="Italic">Selaginella remotifolia</Emphasis> MADS-box gene

Recent progress in plant molecular genetics has revealed that floral organ development is regulated by several homeotic selector genes, most of which belong to the MADS-box gene family. Here we report on SrMADS1, a MIKC^c-type MADS-box gene from Selaginella, a spikemoss belonging to the lycophytes. SrMADS1 phylogenetically forms a monophyletic clade with genes of the LAMB2 group, which are MIKC^c genes of the clubmoss Lycopodium, and is expressed in whole sporophytic tissues except roots and rhizophores. Our results and the previous report on Lycopodium MIKC^c genes suggest that the ancestral MIKC^c gene of primitive dichotomous plants in the early Devonian was involved in the development of basic sporophytic tissues such as shoot, stem, and sporangium. Electronic Publication     

Kinesins Are Indispensable for Interdigitation of Phragmoplast Microtubules in the Moss Physcomitrella patens

Microtubules form arrays with parallel and antiparallel bundles and function in various cellular processes, including subcellular transport and cell division. The antiparallel bundles in phragmoplasts, plant-unique microtubule arrays, are mostly unexplored and potentially offer new cellular insights. Here, we report that the Physcomitrella patens kinesins KINID1a and KINID1b (for kinesin for interdigitated microtubules 1a and 1b), which are specific to land plants and orthologous to Arabidopsis thaliana PAKRP2, are novel factors indispensable for the generation of interdigitated antiparallel microtubules in the phragmoplasts of the moss P. patens. KINID1a and KINID1b are predominantly localized to the putative interdigitated parts of antiparallel microtubules. This interdigitation disappeared in double-deletion mutants of both genes, indicating that both KINID1a and 1b are indispensable for interdigitation of the antiparallel microtubule array. Furthermore, cell plates formed by these phragmoplasts did not reach the plasma membrane in ∼20% of the mutant cells examined. We observed that in the double-deletion mutant lines, chloroplasts remained between the plasma membrane and the expanding margins of the cell plate, while chloroplasts were absent from the margins of the cell plates in the wild type. This suggests that the kinesins, the antiparallel microtubule bundles with interdigitation, or both are necessary for proper progression of cell wall expansion.     

Development of a highly selective fluorescence probe for alkaline phosphatase

We have developed the first highly selective fluorescence probe for alkaline phosphatase (ALP), TG-mPhos. This probe shows selectivity for ALP over protein tyrosine phosphatase and protein serine/threonine phosphatase. Our previously developed TG-Phos, which has a phenolic phosphate linkage in place of the alcoholic phosphate linkage of TG-mPhos, lacks this selectivity. TG-mPhos should enable precise fluorescence imaging of ALP activity in biological applications.