The Putative Coupling Protein TcpA Interacts with Other pCW3-Encoded Proteins To Form an Essential Part of the Conjugation Complex

Conjugative plasmids encode antibiotic resistance determinants or toxin genes in the anaerobic pathogen Clostridium perfringens. The paradigm conjugative plasmid in this bacterium is pCW3, a 47-kb tetracycline resistance plasmid that encodes the unique tcp transfer locus. The tcp locus consists of 11 genes, intP and tcpA-tcpJ, at least three of which, tcpA, tcpF, and tcpH, are essential for the conjugative transfer of pCW3. In this study we examined protein-protein interactions involving TcpA, the putative coupling protein. Use of a bacterial two-hybrid system identified interactions between TcpA and TcpC, TcpG, and TcpH. This analysis also demonstrated TcpA, TcpC, and TcpG self-interactions, which were confirmed by chemical cross-linking studies. Examination of a series of deletion and site-directed derivatives of TcpA identified the domains and motifs required for these interactions. Based on these results, we have constructed a model for this unique conjugative transfer apparatus.Conjugation systems are important contributors to the dissemination of antibiotic resistance determinants and virulence factors. Extensive analysis of conjugative plasmids from gram-negative bacteria has led to the elucidation of a general mechanism of conjugative transfer (10, 22). In this process, the transferred DNA is processed by components of a relaxosome complex. Specifically, the DNA is nicked at the origin of transfer (oriT) by a relaxase, which remains covalently coupled to the transferred DNA strand. The single-stranded DNA complex then interacts with the coupling protein, a DNA-dependent ATPase that provides the energy to actively pump the DNA through the mating pair formation (Mpf) complex into the recipient cell (36). The coupling protein interacts with both DNA processing proteins and components of the Mpf complex (1, 4, 12, 35, 38). These interactions have been demonstrated using bacterial and yeast two-hybrid approaches as well as gel filtration, pull-down, and coimmunoprecipitation studies.The mechanism of conjugative transfer has yet to be precisely determined for conjugative plasmids from gram-positive bacteria although bioinformatics analysis has identified similar gene arrangements and conservation of gene sequences within the transfer regions encoded on conjugative plasmids identified from strains of streptococcal, staphylococcal, enterococcal, and lactococcal origin (15). It was proposed that gram-positive and gram-negative conjugation systems utilize a similar transfer mechanism (15).In the anaerobic pathogen Clostridium perfringens conjugative plasmids have been shown to encode antibiotic resistance genes or extracellular toxins (3, 8, 9, 18). Although the contribution of conjugation to disease dissemination has not been systematically evaluated, it has been proposed that transfer of the C. perfringens enterotoxin plasmid pCPF4969 to normal flora isolates of C. perfringens may contribute to the severity of disease caused by non-food-borne isolates of C. perfringens (9).The prototype conjugative plasmid in C. perfringens is the 47-kb tetracycline resistance plasmid, pCW3. The complete sequence of pCW3 has been determined, and its unique replication protein and conjugation locus have been identified (8). Bioinformatics analysis of this C. perfringens tcp conjugation locus identified several proteins with limited similarity to proteins encoded within the transfer region of the conjugative transposon, Tn916 (8). The role of the tcp locus in the transfer of pCW3 has been confirmed by isolation of independent tcpA, tcpF, and tcpH mutants and subsequent complementation studies (8, 29). Since the region that encompasses the tcp locus is conserved in all conjugative plasmids from C. perfringens (2, 3, 8, 9, 18, 27) and since divergent tcpA homologues can complement a pCW3tcpA mutant (29), it appears that the conjugative transfer of both antibiotic resistance and toxin plasmids from this bacterium utilizes a common but poorly understood mechanism. Note that the C. perfringens tcp conjugation locus is different from the transfer regions of conjugative plasmids from other gram-positive bacteria.We have recently shown that the essential conjugation protein TcpH, a putative membrane-associated Mpf complex component, is localized to the poles of C. perfringens cells, as is another essential conjugation protein, TcpF (37). TcpH has also been shown to interact with itself and with the pCW3-encoded TcpC protein (37). In this study we have focused on the essential conjugation protein TcpA. Since TcpA encodes an FtsK/SpoIIIE domain found in DNA translocases (8), it is proposed that TcpA is involved in the movement of DNA during conjugative transfer, fulfilling a role equivalent to that of coupling proteins in other conjugation systems. Like such proteins, TcpA encodes two N-terminal transmembrane domains (TMDs) and a C-terminal cytoplasmic region that contains three motifs predicted to be involved in ATP binding and hydrolysis (8). Our previous studies revealed that the conserved motifs, motif I (Walker A box), motif II (Walker B box), and motif III (RAAG box), are essential for the function of TcpA. The C-terminal 61 amino acids (aa), though not essential for TcpA function, were shown to be important for efficient transfer of pCW3, as were the putative TMDs (29).To further investigate pCW3 transfer and the role of TcpA in this process, we have used bacterial two-hybrid analysis to examine protein-protein interactions involving TcpA. Using this system, interactions were observed between TcpA and itself, TcpC, TcpG, and TcpH. In addition, TcpC and TcpG were also found to self-interact. By combining these data with other data generated in this laboratory (37), we have constructed a model for the conjugative transfer of pCW3.     

Population Variability of the FimH Type 1 Fimbrial Adhesin in Klebsiella pneumoniae

FimH is an adhesive subunit of type 1 fimbriae expressed by different enterobacterial species. The enteric bacterium Klebsiella pneumoniae is an environmental organism that is also a frequent cause of sepsis, urinary tract infection (UTI), and liver abscess. Type 1 fimbriae have been shown to be critical for the ability of K. pneumoniae to cause UTI in a murine model. We show here that the K. pneumoniae fimH gene is found in 90% of strains from various environmental and clinical sources. The fimH alleles exhibit relatively low nucleotide and structural diversity but are prone to frequent horizontal-transfer events between different bacterial clones. Addition of the fimH locus to multiple-locus sequence typing significantly improved the resolution of the clonal structure of pathogenic strains, including the K1 encapsulated liver isolates. In addition, the K. pneumoniae FimH protein is targeted by adaptive point mutations, though not to the same extent as FimH from uropathogenic Escherichia coli or TonB from the same K. pneumoniae strains. Such adaptive mutations include a single amino acid deletion from the signal peptide that might affect the length of the fimbrial rod by affecting FimH translocation into the periplasm. Another FimH mutation (S62A) occurred in the course of endemic circulation of a nosocomial uropathogenic clone of K. pneumoniae. This mutation is identical to one found in a highly virulent uropathogenic strain of E. coli, suggesting that the FimH mutations are pathoadaptive in nature. Considering the abundance of type 1 fimbriae in Enterobacteriaceae, our present finding that fimH genes are subject to adaptive microevolution substantiates the importance of type 1 fimbria-mediated adhesion in K. pneumoniae.Klebsiella pneumoniae is recognized as an important opportunistic pathogen that frequently causes urinary tract infections (UTI), septicemia, or pneumonia, particularly in immunocompromised individuals (25). K. pneumoniae is responsible for up to 10% of all nosocomial bacterial infections (12, 35). In recent years, a high incidence of community-acquired K. pneumoniae pyogenic liver abscess with a high mortality rate has been reported, especially from Taiwan, but also from other Asian countries, Europe, and North America (6, 8, 19, 27, 44). Furthermore, 15% to 30% of K. pneumoniae isolates are resistant to broad-spectrum cephalosporins via plasmid-encoded extended-spectrum β-lactamases (5).In contrast to many other bacterial pathogens, K. pneumoniae is ubiquitous in nature. Its nonclinical habitats include environmental locations, such as vegetation, soil, and surface waters, as well as transient commensal colonization of mucosal surfaces in humans and other animals (1). Several studies have reported K. pneumoniae isolates of environmental origin to be nearly identical to clinical isolates with respect to several phenotypic properties (16, 22, 23, 25, 30). It has been suggested that environmental isolates of K. pneumoniae may be as virulent as clinical isolates (24, 39).Several virulence factors have been identified in K. pneumoniae (25, 38). The prominent polysaccharide capsule expressed by most isolates, together with the lipopolysaccharide layer, protects the bacteria against phagocytosis and the bactericidal activity of serum. Fimbrial adhesins expressed by the bacteria are protein structures able to recognize molecular receptors and to facilitate adherence to specific tissue surfaces in the host. K. pneumoniae produces two major fimbrial adhesion organelles, type 1 and type 3 fimbriae (9). Type 1 fimbriae have mannose-sensitive hemagglutinins, while type 3 fimbriae have mannose-resistant hemagglutinins (21).Type 1 fimbriae are the most common adhesive organelle in Enterobacteriaceae and have been most extensively studied in Escherichia coli. The type 1 fimbrial structures of K. pneumoniae are homologous to those of E. coli with regard to genetic composition and regulation (37). Type 1 fimbriae and the adhesive subunit FimH, in particular, play an important role in UTI caused by both K. pneumoniae and E. coli (3, 15, 17, 30, 37). Analysis of E. coli fimH variation at the population level has revealed that the FimH adhesin in urinary E. coli isolates accumulates amino acid replacements that increase its tropism toward the uroepithelium and various components of basement membranes (14, 26, 31, 33, 46). Most of the replacements increase the monomannose binding capability of FimH under low shear by altering allosteric catch bond properties of the protein (40). The natural FimH mutants were shown to provide an advantage in colonization of the urinary tract in a mouse model (32) and correlate with the overall extraintestinal virulence of E. coli (11). Thus, FimH mutations are pathoadaptive in nature. No such population-wide analysis has been performed for K. pneumoniae fimH.Population genetic analysis involves comparison of the nucleotide and structural variability of the locus of interest across multiple bacterial strains of different clonalities and geographic origins. The clonal structure of the strains can be determined by multiple-locus sequence typing (MLST), in which 400- to 500-bp sequences of multiple genetically unlinked loci are determined in order to define the phylogenetic relationship of the strains and the extent of interclonal gene recombination (horizontal gene transfer). MLST has been used to reveal the epidemiological relationship of ceftazidime- and ciprofloxacin-resistant K. pneumoniae isolates of nosocomial origin (4). In addition, the analysis of gene variability enables the determination of the type of selection processes acting on loci of interest, with possible identification of mutational changes of functional significance that could enhance the organism''s ability to cause disease, i.e., that could be of a pathoadaptive nature.In this study, the population dynamics of the K. pneumoniae FimH adhesin were determined by analysis of fimH allelic diversity in strains of environmental and various clinical origins in the context of K. pneumoniae clonal structure based on the allelic diversity of three loci—tonB, mdh and fumC—commonly used for MLST.     

Determinants in CaV1 Channels That Regulate the Ca2+ Sensitivity of Bound Calmodulin

Calmodulin binds to IQ motifs in the α₁ subunit of Ca_V1.1 and Ca_V1.2, but the affinities of calmodulin for the motif and for Ca²⁺ are higher when bound to Ca_V1.2 IQ. The Ca_V1.1 IQ and Ca_V1.2 IQ sequences differ by four amino acids. We determined the structure of calmodulin bound to Ca_V1.1 IQ and compared it with that of calmodulin bound to Ca_V1.2 IQ. Four methionines in Ca²⁺-calmodulin form a hydrophobic binding pocket for the peptide, but only one of the four nonconserved amino acids (His-1532 of Ca_V1.1 and Tyr-1675 of Ca_V1.2) contacts this calmodulin pocket. However, Tyr-1675 in Ca_V1.2 contributes only modestly to the higher affinity of this peptide for calmodulin; the other three amino acids in Ca_V1.2 contribute significantly to the difference in the Ca²⁺ affinity of the bound calmodulin despite having no direct contact with calmodulin. Those residues appear to allow an interaction with calmodulin with one lobe Ca²⁺-bound and one lobe Ca²⁺-free. Our data also provide evidence for lobe-lobe interactions in calmodulin bound to Ca_V1.2.The complexity of eukaryotic Ca²⁺ signaling arises from the ability of cells to respond differently to Ca²⁺ signals that vary in amplitude, duration, and location. A variety of mechanisms decode these signals to drive the appropriate physiological responses. The Ca²⁺ sensor for many of these physiological responses is the Ca²⁺-binding protein calmodulin (CaM).² The primary sequence of CaM is tightly conserved in all eukaryotes, yet it binds and regulates a broad set of target proteins in response to Ca²⁺ binding. CaM has two domains that bind Ca²⁺ as follows: an amino-terminal domain (N-lobe) and a carboxyl-terminal domain (C-lobe) joined via a flexible α-helix. Each lobe of CaM binds two Ca²⁺ ions, and binding within each lobe is highly cooperative. The two lobes of CaM, however, have distinct Ca²⁺ binding properties; the C-lobe has higher Ca²⁺ affinity because of a slower rate of dissociation, whereas the N-lobe has weaker Ca²⁺ affinity and faster kinetics (1). CaM can also bind to some target proteins in both the presence and absence of Ca²⁺, and the preassociation of CaM in low Ca²⁺ modulates the apparent Ca²⁺ affinity of both the amino-terminal and carboxyl-terminal lobes. Differences in the Ca²⁺ binding properties of the lobes and in the interaction sites of the amino- and carboxyl-terminal lobes enable CaM to decode local versus global Ca²⁺ signals (2).Even though CaM is highly conserved, CaM target (or recognition) sites are quite heterogeneous. The ability of CaM to bind to very different targets is at least partially due to its flexibility, which allows it to assume different conformations when bound to different targets. CaM also binds to various targets in distinct Ca²⁺ saturation states as follows: Ca²⁺-free (3), Ca²⁺ bound to only one of the two lobes, or fully Ca²⁺-bound (4–7). In addition, CaM may bind with both lobes bound to a target (5, 6) or with only a single lobe engaged (8). If a target site can bind multiple conformers of CaM, CaM may undergo several transitions that depend on Ca²⁺ concentration, thereby tuning the functional response. Identification of stable intermediate states of CaM bound to individual targets will help to elucidate the steps involved in this fine-tuned control.Both Ca_V1.1 and Ca_V1.2 belong to the L-type family of voltage-dependent Ca²⁺ channels, which bind apoCaM and Ca²⁺-CaM at carboxyl-terminal recognition sites in their α₁ subunits (9–14). Ca²⁺ binding to CaM, bound to Ca_V1.2 produces Ca²⁺-dependent facilitation (CDF) (14). Whether Ca_V1.1 undergoes CDF is not known. However, both Ca_V1.2 and Ca_V1.1 undergo Ca²⁺- and CaM-dependent inactivation (CDI) (14, 15). Ca_V1.1 CDI is slower and more sensitive to buffering by 1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid than Ca_V1.2 CDI (15). Ca²⁺ buffers are thought to influence CDI and/or CDF in voltage-dependent Ca²⁺ channels by competing with CaM for Ca²⁺ (16).The conformation of the carboxyl terminus of the α₁ subunit is critical for channel function and has been proposed to regulate the gating machinery of the channel (17, 18). Several interactions of this region include intramolecular contacts with the pore inactivation machinery and intermolecular contacts with CaM kinase II and ryanodine receptors (17, 19–22). Ca²⁺ regulation of Ca_V1.2 may involve several motifs within this highly conserved region, including an EF hand motif and three contiguous CaM-binding sequences (10, 12). ApoCaM and Ca²⁺-CaM-binding sites appear to overlap at the site designated as the “IQ motif” (9, 12, 13), which are critical for channel function at the molecular and cellular level (14, 23).Differences in the rate at which 1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid affects CDI of Ca_V1.1 and Ca_V1.2 could reflect differences in their interactions with CaM. In this study we describe the differences in CaM interactions with the IQ motifs of the Ca_V1.1 and the Ca_V1.2 channels in terms of crystal structure, CaM affinity, and Ca²⁺ binding to CaM. We find the structures of Ca²⁺-CaM-IQ complexes are similar except for a single amino acid change in the peptide that contributes to its affinity for CaM. We also find that the other three amino acids that differ in Ca_V1.2 and Ca_V1.1 contribute to the ability of Ca_V1.2 to bind a partially Ca²⁺-saturated form of CaM.     

Calcium Elevation in Mitochondria Is the Main Ca2+ Requirement for Mitochondrial Permeability Transition Pore (mPTP) Opening

We have investigated in detail the role of intra-organelle Ca²⁺ content during induction of apoptosis by the oxidant menadione while changing and monitoring the Ca²⁺ load of endoplasmic reticulum (ER), mitochondria, and acidic organelles. Menadione causes production of reactive oxygen species, induction of oxidative stress, and subsequently apoptosis. In both pancreatic acinar and pancreatic tumor AR42J cells, menadione was found to induce repetitive cytosolic Ca²⁺ responses because of the release of Ca²⁺ from both ER and acidic stores. Ca²⁺ responses to menadione were accompanied by elevation of Ca²⁺ in mitochondria, mitochondrial depolarization, and mitochondrial permeability transition pore (mPTP) opening. Emptying of both the ER and acidic Ca²⁺ stores did not necessarily prevent menadione-induced apoptosis. High mitochondrial Ca²⁺ at the time of menadione application was the major factor determining cell fate. However, if mitochondria were prevented from loading with Ca²⁺ with 10 μm RU360, then caspase-9 activation did not occur irrespective of the content of other Ca²⁺ stores. These results were confirmed by ratiometric measurements of intramitochondrial Ca²⁺ with pericam. We conclude that elevated Ca²⁺ in mitochondria is the crucial factor in determining whether cells undergo oxidative stress-induced apoptosis.Apoptosis, a mechanism of programmed cell death, usually occurs through intrinsic or extrinsic apoptotic pathways. The caspases involved in apoptosis can be split into two groups, the initiator caspases such as caspase-9 and effector caspases such as caspase-3. Effector caspases are activated by initiator caspases and mediate many of the morphological cellular changes associated with apoptosis (1).Calcium is an important signaling ion involved in the regulation of many physiological as well as pathological cellular responses (2). In the pancreas, we have shown that Ca²⁺ signals elicit enzyme secretion (3), apoptosis (4–6), and pathological intracellular activation of digestive enzymes (7). As such, there must be mechanisms in place by which the cell can differentiate between apoptotic and non-apoptotic Ca²⁺ signals.The spatiotemporal pattern of calcium signaling is crucial for the specificity of cellular responses. For example, repetitive cytosolic calcium spikes confined to the apical region of the pancreatic acinar cell are elicited by physiological stimulation with acetylcholine (ACh) or cholecystokinin (CCK) and result in physiological secretion of zymogen granules (8, 9). However, a sustained global increase in free cytosolic Ca²⁺ induced by supramaximal stimulation with CCK, which resembles prolonged hyperstimulation of pancreatic acinar cells in the pathophysiology of acute pancreatitis, can lead to premature activation of digestive enzymes and vacuole formation within the cell (10–12). Alternatively, global repetitive calcium spikes induced in the pancreatic acinar cell in response to oxidant stress can lead to induction of the mitochondrial permeability transition pore (mPTP)⁴ and apoptosis (4, 5, 13).To understand the role of calcium in apoptosis, several investigators have examined the influence of intracellular stores on the molding of calcium signals that lead to cell death (14–16). It has been well established in a range of cell types that the endoplasmic reticulum (ER) is the major intracellular calcium store required for induction of apoptosis. Pinton et al. (17) have shown that decreasing ER Ca²⁺ concentration with tBuBHQ increased HeLa cell survival in response to oxidant stress induced by ceramide. Scorrano and Korsmeyer (18) also observed that double knock-out Bax and Bak (pro-apoptotic proteins) mouse fibroblasts displayed a reduced resting concentration of ER Ca²⁺ compared with wild type and were resistant to induction of apoptosis by various stimulants, including ceramide. These important studies strongly suggest that the concentration of Ca²⁺ in the ER is a critical determinant of cellular susceptibility to apoptotic stimuli in the cell types studied.A key event in early apoptosis is permeabilization of the mitochondrial membrane. The mPTP is a pore whose molecular composition is still debated (19). Activation of an open pore state can result in swelling of the mitochondrial matrix and release of the apoptogenic proteins from the intermembrane space (20).One important activator of the mPTP is Ca²⁺ (20–22), a function which implicates Ca²⁺ in the initiation of apoptosis (23, 24). Once Ca²⁺ is released from the ER into the cytoplasm, mitochondria take up part of the released Ca²⁺ to prevent propagation of large calcium waves (25–27). This influx is followed by calcium efflux from the mitochondria back into the cytosol (28, 29). An increase in mitochondrial Ca²⁺ concentration in response to physiological stimuli induces increased activity of the mitochondrial respiratory chain and the synthesis of ATP to meet with increasing energy demands on the cell. When mitochondria are exposed to a pathological overload of calcium, opening of the mPTP is triggered, leading to mitochondrial dysfunction and eventually cell death. The mechanism through which calcium can trigger mPTP opening is still unclear and may involve cyclophilin D (30) and voltage-dependent anion channel (31). The mitochondria are endowed with selective and efficient calcium uptake (a calcium-selective uniporter) and release mechanisms (Ca²⁺/Na exchanger, Ca²⁺/H⁺ exchanger, and mPTP) (16, 29, 32, 33).Oxidant stress is a well known inducer of apoptosis in several cell types (34) and is thought to play an important role in the pathogenesis of acute pancreatitis (35). We have used the quinone compound menadione to induce oxidative stress in the pancreatic acinar cell. Menadione is metabolized by flavoprotein reductase to semiquinone and then is oxidized back to quinone, resulting in generation of superoxide anion radicals, hydrogen peroxide, and other reactive oxygen species (ROS) (36). In vivo, menadione causes depolarization and swelling of the mitochondria (37). In pancreatic acinar cells, treatment with menadione not only produces an increase in ROS, but has also been found to evoke cytosolic Ca²⁺ responses, mPTP opening, activation of caspases and apoptotic cell death (4, 5). When cells were pretreated with the calcium chelator BAPTA-AM, menadione was unable to induce apoptosis, indicating that oxidant stress-induced apoptosis in the pancreatic acinar cell is highly calcium-dependent. Here we show that in pancreatic acinar cells, oxidative stress-induced apoptosis is strongly dependent on the Ca²⁺ concentration within mitochondria at the time of ROS production.     

Fatty acids, alcohol and fatty acid ethyl esters: Toxic Ca signal generation and pancreatitis

Pancreatitis, a potentially fatal disease in which the pancreas digests itself as well as its surroundings, is a well recognized complication of hyperlipidemia. Fatty acids have toxic effects on pancreatic acinar cells and these are mediated by large sustained elevations of the cytosolic Ca²⁺ concentration. An important component of the effect of fatty acids is due to inhibition of mitochondrial function and subsequent ATP depletion, which reduces the operation of Ca²⁺-activated ATPases in both the endoplasmic reticulum and the plasma membrane. One of the main causes of pancreatitis is alcohol abuse. Whereas the effects of even high alcohol concentrations on isolated pancreatic acinar cells are variable and often small, fatty acid ethyl esters – synthesized by combination of alcohol and fatty acids – consistently evoke major Ca²⁺ release from intracellular stores, subsequently opening Ca²⁺ entry channels in the plasma membrane. The crucial trigger for pancreatic autodigestion is intracellular trypsin activation. Although there is still uncertainty about the exact molecular mechanism by which this Ca²⁺-dependent process occurs, progress has been made in identifying a subcellular compartment – namely acid post-exocytotic endocytic vacuoles – in which this activation takes place.     

Proton nuclear magnetic resonance spectroscopy based investigation on propylene glycol toxicosis in a Holstein cow

Background  

It is unknown which metabolites are responsible for propylene glycol (PG)-induced toxicosis, and a better understanding of the underlying mechanisms explaining incidences of abnormal behaviour of dairy cows fed PG is therefore needed.     

Characterization of 24 microsatellite loci in delta smelt, Hypomesus transpacificus, and their cross-species amplification in two other smelt species of the Osmeridae family

We characterized 24 polymorphic tetranucleotide microsatellite loci for delta smelt (Hypomesus transpacificus) endemic to the San Francisco Bay Estuary, CA, USA. Screening of samples (n = 30) yielded two to 26 alleles per locus with observed levels of heterozygosity ranging from 0.17 to 1.0. Only one locus deviated from Hardy–Weinberg equilibrium, suggesting these individuals originate from a single panmictic population. Linkage disequilibrium was found in two pairs of loci after excluding the locus out of Hardy–Weinberg equilibrium. Twenty‐two primer pairs cross‐amplified in wakasagi smelt (Hypomesus nipponensis), and 15 primer pairs cross‐amplified in longfin smelt (Spirinchus thaleichthys).     

A comparative Raman and CARS imaging study of colon tissue

An experimental evaluation of the information content of two complimentary techniques, linear Raman and coherent anti‐Stokes Raman scattering (CARS) microscopy, is presented. CARS is a nonlinear variant of Raman spectroscopy that enables rapid acquisition of images within seconds in combination with laser scanning microscopes. CARS images were recorded from thin colon tissue sections at 2850, 1660, 1450 and 1000 cm^–1 and compared with Raman images. Raman images were obtained from univariate and multivariate (k‐means clustering) methods, whereas all CARS images represent univariate results. Variances within tissue sections could be visualized in chemical maps of CARS and Raman images. However, identification of tissue types and characterization of variances between different tissue sections were only possible by analysis of cluster mean spectra, obtained from k‐means cluster analysis. This first comparison establishes the foundation for further development of the CARS technology to assess tissue. (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Amelioration of muscular dystrophy by transgenic expression of Niemann-Pick C1

Duchenne muscular dystrophy (DMD) and other types of muscular dystrophies are caused by the loss or alteration of different members of the dystrophin protein complex. Understanding the molecular mechanisms by which dystrophin-associated protein abnormalities contribute to the onset of muscular dystrophy may identify new therapeutic approaches to these human disorders. By examining gene expression alterations in mouse skeletal muscle lacking α-dystrobrevin (Dtna^−/−), we identified a highly significant reduction of the cholesterol trafficking protein, Niemann-Pick C1 (NPC1). Mutations in NPC1 cause a progressive neurodegenerative, lysosomal storage disorder. Transgenic expression of NPC1 in skeletal muscle ameliorates muscular dystrophy in the Dtna^−/− mouse (which has a relatively mild dystrophic phenotype) and in the mdx mouse, a model for DMD. These results identify a new compensatory gene for muscular dystrophy and reveal a potential new therapeutic target for DMD.     

Functional Brain Networks Develop from a “Local to Distributed” Organization

The mature human brain is organized into a collection of specialized functional networks that flexibly interact to support various cognitive functions. Studies of development often attempt to identify the organizing principles that guide the maturation of these functional networks. In this report, we combine resting state functional connectivity MRI (rs-fcMRI), graph analysis, community detection, and spring-embedding visualization techniques to analyze four separate networks defined in earlier studies. As we have previously reported, we find, across development, a trend toward ‘segregation’ (a general decrease in correlation strength) between regions close in anatomical space and ‘integration’ (an increased correlation strength) between selected regions distant in space. The generalization of these earlier trends across multiple networks suggests that this is a general developmental principle for changes in functional connectivity that would extend to large-scale graph theoretic analyses of large-scale brain networks. Communities in children are predominantly arranged by anatomical proximity, while communities in adults predominantly reflect functional relationships, as defined from adult fMRI studies. In sum, over development, the organization of multiple functional networks shifts from a local anatomical emphasis in children to a more “distributed” architecture in young adults. We argue that this “local to distributed” developmental characterization has important implications for understanding the development of neural systems underlying cognition. Further, graph metrics (e.g., clustering coefficients and average path lengths) are similar in child and adult graphs, with both showing “small-world”-like properties, while community detection by modularity optimization reveals stable communities within the graphs that are clearly different between young children and young adults. These observations suggest that early school age children and adults both have relatively efficient systems that may solve similar information processing problems in divergent ways.