Development of a Compatible Taper Function and Stand-Level Merchantable Volume Model for Chinese Fir Plantations

Chinese fir (Cunninghamia lanceolata [Lamb.] Hook) is one of the most important plantation tree species in China with good timber quality and fast growth. It covers an area of 8.54 million hectare, which corresponds to 21% of the total plantation area and 32% of total plantation volume in China. With the increasing market demand, an accurate estimation and prediction of merchantable volume at tree- and stand-level is becoming important for plantation owners. Although there are many studies on the total tree volume estimation from allometric models, these allometric models cannot predict tree- and stand-level merchantable volume at any merchantable height, and the stand-level merchantable volume model was not seen yet in Chinese fir plantations. This study aimed to develop (1) a compatible taper function for tree-level merchantable volume estimation, and (2) a stand-level merchantable volume model for Chinese fir plantations. This “taper function system” consisted in a taper function, a merchantable volume equation and a total tree volume equation. 46 Chinese fir trees were felled to develop the taper function in Shitai County, Anhui province, China. A second-order continuous autoregressive error structure corrected the inherent serial autocorrelation of different observations in one tree. The taper function and volume equations were fitted simultaneously after autocorrelation correction. The compatible taper function fitted well to our data and had very good performances in diameter and total tree volume prediction. The stand-level merchantable volume equation based on the ratio approach was developed using basal area, dominant height, quadratic mean diameter and top diameter (ranging from 0 to 30 cm) as independent variables. At last, a total stand-level volume table using stand basal area and dominant height as variables was proposed for local forest managers to simplify the stand volume estimation.     

Comparative study on the gametophyte morphology and development of three paramo species of Jamesonia (Pteridaceae,Polypodiopsida)

The sexual phase of three species of Jamesonia (J. imbricata, J. rotundifolia and J. scammaniae) has been studied, from spore germination to gametangia formation, with special attention to the morphological development of prothalli. This is the first work to deal with gametophytes of species in this genus. All three species have trilete, tetrahedrical spores that germinate following the Vittaria type. The developmental pattern of J. imbricata and J. rotundifolia is intermediate between the Adiantum and Ceratopteris types, as the initial mitotic activity is assumed by an obconical apical cell, substituted later by a lateral meristem. In J. scammaniae, no apical cell or lateral meristem is formed, so the prothalli remain ameristic throughout the developmental process. Adult gametophytes are naked and variable in shape, in the same species ranging from typical cordate prothalli to irregularly lobed forms. Gametangia of normal shape and size was observed in both J. imbricata and J. rotundifolia, but not in J. scammaniae. Apogamy could be expected to occur in the genus, a phenomenon to be examined in the future. Comparisons are made with known species of related genera and results are discussed from an ecological perspective in the paramo environment.     

Monthly stem increment in relation to climatic variables during 7 years in an East African rainforest

Monthly stem increment of 766 trees was assessed for 7 years in Kakamega Forest, Kenya and related to monthly climatic variables. Mean stem increment of all tree individuals correlated negatively with maximum temperature but not with mean and minimum temperatures. For the precipitation variables sum of precipitation and number of rainy days we found positive correlations. Stem increment of the trees in the early-, mid-, and late-successional groups correlated positively with the number of rainy days. For late-successional trees increment correlated negatively with mean and maximum temperature and positively with all other precipitation variables. For mid-successional trees we found a negative correlation with mean temperature. In addition, the stem increment of most species related positively to precipitation variables and negatively to mean and maximum temperature. In view of the expected increasing temperatures and fewer but heavier rain events, our results suggest that climate change will lead to a reduction in stem increment. The results appertaining to the successional groups imply that early and mid-successional species are better equipped to perform well under the expected future climatic conditions than the late-successional species. This could reduce the role of this East African forest as a carbon store. As the responses to climatic variables were highly group- and species-specific it is likely that climate change will result in a species composition shift, presumably in favour of drought-resistant and heat-tolerating species.     

Molecular characterization of InJR06, a class 1 integron located in a conjugative plasmid of Salmonella enterica ser. Typhimurium.

The presence of class 1, 2, and 3 integrons was investigated in four pediatric isolates of Salmonella enterica ser. Typhimurium (S. Typhimurium). A class 1 integron was detected in one S. Typhimurium strain, the only one that also showed resistance to various aminoglycoside antibiotics. This integron, called InJR06, and the aminoglycoside resistance determinants were located in pS06, a large (> or = 55 kb) conjugative plasmid. A single mobile cassette (encoding the aminoglycoside adenylyltransferase ANT(3')-Ia) was detected in the variable region of InJR06, while the architecture of the attI1 and attC sites was conserved.     

Electroporation Facilitates Introduction of Reporter Transgenes and Virions into Schistosome Eggs

Background

The schistosome egg represents an attractive developmental stage at which to target transgenes because of the high ratio of germ to somatic cells, because the transgene might be propagated and amplified by infecting snails with the miracidia hatched from treated eggs, and because eggs can be readily obtained from experimentally infected rodents.

Methods/Findings

We investigated the utility of square wave electroporation to deliver transgenes and other macromolecules including fluorescent (Cy3) short interference (si) RNA molecules, messenger RNAs, and virions into eggs of Schistosoma mansoni. First, eggs were incubated in Cy3-labeled siRNA with and without square wave electroporation. Cy3-signals were detected by fluorescence microscopy in eggs and miracidia hatched from treated eggs. Second, electroporation was employed to introduce mRNA encoding firefly luciferase into eggs. Luciferase activity was detected three hours later, whereas luciferase was not evident in eggs soaked in the mRNA. Third, schistosome eggs were exposed to Moloney murine leukemia virus virions (MLV) pseudotyped with vesicular stomatitis virus glycoprotein (VSVG). Proviral transgenes were detected by PCR in genomic DNA from miracidia hatched from virion-exposed eggs, indicating the presence of transgenes in larval schistosomes that had been either soaked or electroporated. However, quantitative PCR (qPCR) analysis determined that electroporation of virions resulted in 2–3 times as many copies of provirus in these schistosomes compared to soaking alone. In addition, relative qPCR indicated a copy number for the proviral luciferase transgene of ∼20 copies for 100 copies of a representative single copy endogenous gene (encoding cathepsin D).

Conclusions

Square wave electroporation facilitates introduction of transgenes into the schistosome egg. Electroporation was more effective for the transduction of eggs with pseudotyped MLV than simply soaking the eggs in virions. These findings underscore the potential of targeting the schistosome egg for germ line transgenesis.     

Structural Homology between the C-Terminal Domain of the PapC Usher and Its Plug

P pili are extracellular appendages responsible for the targeting of uropathogenic Escherichia coli to the kidney. They are assembled by the chaperone-usher (CU) pathway of pilus biogenesis involving two proteins, the periplasmic chaperone PapD and the outer membrane assembly platform, PapC. Many aspects of the structural biology of the Pap CU pathway have been elucidated, except for the C-terminal domain of the PapC usher, the structure of which is unknown. In this report, we identify a stable and folded fragment of the C-terminal region of the PapC usher and determine its structure using both X-ray crystallography and nuclear magnetic resonance (NMR) spectroscopy. These structures reveal a β-sandwich fold very similar to that of the plug domain, a domain of PapC obstructing its translocation domain. This structural similarity suggests similar functions in usher-mediated pilus biogenesis, playing out at different stages of the process. This structure paves the way for further functional analysis targeting surfaces common to both the plug and the C-terminal domain of PapC.Adhesive surface organelles termed pili mediate the adhesion of bacteria to host cells. Pili assembled by the chaperone-usher (CU) pathway form one of five major classes of nonflagellar surface appendages in Gram-negative bacteria, with the P pilus system from uropathogenic Escherichia coli being one of the two best-characterized CU systems. These pili are multisubunit structures consisting of two distinct subassemblies, a rigid rod with a diameter of 6.8 nm and a distal flexible tip fibrillum with a diameter of 2 nm (18, 21). In P pili the helical rod is comprised of more than 1,000 copies of the PapA subunits arranged in a right-handed helical cylinder with 3.3 subunits per turn (3, 8, 14), and the tip fibrillum is comprised of 5 to 10 copies of the PapE subunits (21). Two “adaptor” subunits, PapK and PapF, connect the PapE tip fibrillum to the PapA rod and the PapE tip fibrillum to the distal PapG adhesin (16, 21). The proximal end of the pilus is terminated by the PapH subunit (2, 50). The PapG adhesin mediates the bacterial colonization of the kidney (25, 40) by binding to the globoseries of glycolipids present in the human kidney (25, 40) (Fig. ​(Fig.1A),1A), an event that is critical in pyelonephritis.Open in a separate windowFIG. 1.(A) Schematic diagram of a P pilus assembled in the usher translocation platform. Subunits are represented by oval shapes, and N-terminal extensions are represented by short rectangular shapes. The usher homodimer is represented in the outer membrane (OM). In the usher protomer through which the nascent pilus passes, two positions of the plug are indicated by P where the plug is positioned to the side of the transmembrane barrel''s lumen and P′ where the plug has swung into the periplasmic space. (B) Domain organization of the PapC usher based on amino acid sequence. The C-terminal domain sequences are indicated in marine blue. The constructs used in this study are schematically represented underneath; all converge to a fragment containing residues 722 to 809, termed the “PapC CTD.” Ntd, N-terminal domain. (C) Identification of a discrete folding unit at the C terminus of PapC. Shown is an SDS-PAGE gel stained with Coomassie blue of the eluted PapC C-terminal fragments obtained with a construct comprising residues 641 to 809 after the first purification step. PS, prestained protein standards; Inj, loaded sample; FT, flowthrough.The assembly of pili is a coordinated process requiring two proteins: a chaperone and an outer membrane assembly platform, the usher. Pilus subunits are translocated into the periplasm via the general secretory machinery (38, 47). The binding of the PapD chaperone to the nascently translocated subunits facilitates their folding on the chaperone template. The chaperone remains bound to the folded subunits capping their interactive surfaces, thus preventing nonproductive interactions in the periplasm (7). Chaperone-subunit complexes are then targeted to the usher (PapC), where subunits polymerize in an ordered fashion and translocate across the outer membrane through the usher pore (47, 52). Subunit folding and stabilization occur when the chaperone and subunit form a complex through a mechanism termed donor strand complementation (DSC) (9, 41). In this mechanism the C-terminally truncated Ig-like fold of the pilus subunits, which contains only six of the seven β-strands that constitute the canonical Ig fold, is complemented by the donation of a β-strand from the chaperone (9, 41). Chaperone-subunit complexes are then targeted to the outer membrane usher, where the chaperone is released and subunits are noncovalently joined to preceding subunits in the nascent pilus fiber. This polymerization process is made possible by the presence of a disordered N-terminal extension sequence (NTES) in each subunit (except the adhesin) (41), which during pilus assembly displaces the strand donated by the chaperone, thereby substituting for the missing secondary structure in the previously assembled subunit. This mechanism is called donor-strand exchange (DSE) (9, 41, 42, 55). It is believed that this structural reorganization provides the driving force for pilus biogenesis, since no ATP hydrolysis or other type of external energy source is required (17, 56).DSE occurs at the outer membrane usher, which acts as a catalyst for polymerization (34). Biophysical and cryo-electron microscopy (EM) studies of the FimD usher (a close homolog of PapC) have shown that the usher is a twinned pore in both detergent and lipid bilayers (23, 46). Only one pore is used for secretion, but two pores are required for subunit recruitment (39). For PapC, both monomers and dimers have been described (15, 39). The usher has four functional domains (Fig. ​(Fig.1B):1B): a translocation domain forming a β-barrel with 24 transmembrane β-strands (15, 39), a plug domain in the middle of the translocation domain, and two periplasmic domains, one at each of the N- and C-terminal ends of the usher polypeptide (35, 48). The plug domain has a β-sandwich fold and completely occludes the pore in the inactive usher. Its function, besides gating the channel, seems to be further associated with pilus biogenesis since the deletion of the plug domain abolishes pilus formation in vitro and in vivo (15, 26, 54). The N-terminal domain selectively binds chaperone-subunit complexes (12, 33). The structure of the N-terminal domain of FimD bound to chaperone-subunit complexes indicated that the first 24 residues of FimD are involved in the recognition of chaperone-subunit complexes; the deletion of this region was shown previously to abolish pilus biogenesis (12, 32, 33).The role of the usher C-terminal domain (CTD) is not well understood. The binding of the chaperone-adhesin complex to the usher C terminus was previously demonstrated in vitro (46), while protease susceptibility in FimD shows that, following targeting to the usher N terminus, the chaperone-adhesin complex forms stable interactions with the FimD C terminus, inducing a conformational change in FimD that may be fundamental in the activation step of pilus biogenesis (29, 30, 43). The structure of the C-terminal domain is unknown and is the only part of the CU pilus biogenesis pathway not yet represented in structural terms. Here we provide evidence for the presence of a discrete folding unit in the PapC CTD and report its structure determined by nuclear magnetic resonance (NMR) spectroscopy and X-ray crystallography.