Efficient genetic method for establishing Drosophila cell lines unlocks the potential to create lines of specific genotypes

Analysis of cells in culture has made substantial contributions to biological research. The versatility and scale of in vitro manipulation and new applications such as high-throughput gene silencing screens ensure the continued importance of cell-culture studies. In comparison to mammalian systems, Drosophila cell culture is underdeveloped, primarily because there is no general genetic method for deriving new cell lines. Here we found expression of the conserved oncogene Ras(V12) (a constitutively activated form of Ras) profoundly influences the development of primary cultures derived from embryos. The cultures become confluent in about three weeks and can be passaged with great success. The lines have undergone more than 90 population doublings and therefore constitute continuous cell lines. Most lines are composed of spindle-shaped cells of mesodermal type. We tested the use of the method for deriving Drosophila cell lines of a specific genotype by establishing cultures from embryos in which the warts (wts) tumor suppressor gene was targeted. We successfully created several cell lines and found that these differ from controls because they are primarily polyploid. This phenotype likely reflects the known role for the mammalian wts counterparts in the tetraploidy checkpoint. We conclude that expression of Ras(V12) is a powerful genetic mechanism to promote proliferation in Drosophila primary culture cells and serves as an efficient means to generate continuous cell lines of a given genotype.     

Learning, working memory, and intelligence revisited

Based on early findings showing low correlations between intelligence test scores and learning on laboratory tasks, psychologists typically have dismissed the role of learning in intelligence and emphasized the role of working memory instead. In 2006, however, B.A. Williams developed a verbal learning task inspired by three-term reinforcement contingencies and reported unexpectedly high correlations between this task and Raven's Advanced Progressive Matrices (RAPM) scores [Williams, B.A., Pearlberg, S.L., 2006. Learning of three-term contingencies correlates with Raven scores, but not with measures of cognitive processing. Intelligence 34, 177-191]. The present study replicated this finding: Performance on the three-term learning task explained almost 25% of the variance in RAPM scores. Adding complex verbal working memory span, measured using the operation span task, did not improve prediction. Notably, this was not due to a lack of correlation between complex working memory span and RAPM scores. Rather, it occurred because most of the variance captured by the complex working memory span was already accounted for by the three-term learning task. Taken together with the findings of Williams and Pearlberg, the present results make a strong case for the role of learning in performance on intelligence tests.     

Polymorphic microsatellite loci in Plantago lanceolata

The genus Plantago is particularly interesting for evolutionary studies because of its wide range of mating systems. We have developed primers for five highly polymorphic microsatellite loci isolated from P. lanceolata. All five loci amplified and were polymorphic in the two populations examined, Lowsteads Beach in the United Kingdom and Duke in the United States. These new markers will allow a comparison of population structure between the outcrossing species P. lanceolata, and the highly selfing species P. major.     

Fluoxetine potentiates the effects of corticotropin-releasing factor on locomotor activity and serotonergic systems in the roughskin newt, Taricha granulosa

The anxiety- and stress-related neuropeptide corticotropin-releasing factor (CRF) elicits behavioral changes in vertebrates including increases in behavioral arousal and locomotor activity. Intracerebroventricular injections of CRF in an amphibian, the roughskin newt (Taricha granulosa), induces rapid increases in locomotor activity in both intact and hypophysectomized animals. We hypothesized that this CRF-induced increase in locomotor activity involves a central effect of CRF on serotonergic neurons, based on known stimulatory actions of serotonin (5-hydroxytryptamine, 5-HT) on spinal motor neurons and the central pattern generator for locomotor activity in vertebrates. In Experiment 1, we found that neither intracerebroventricular injections of low doses of CRF (25 ng) nor the selective serotonin reuptake inhibitor fluoxetine (10, 100 ng), by themselves, altered locomotor activity. In contrast, newts treated concurrently with CRF and fluoxetine responded with marked increases in locomotor activity. In Experiment 2, we found that increases in locomotor activity following co-administration of CRF (25 ng) and fluoxetine (100 ng) were associated with decreased 5-HT concentrations in a number of forebrain structures involved in regulation of emotional behavior and emotional states, including the ventral striatum, amygdala pars lateralis, and dorsal hypothalamus, measured 37 min after treatment. These results are consistent with the hypothesis that CRF stimulates locomotor activity through activation of serotonergic systems.     

Pyridopyrimidine based cannabinoid-1 receptor inverse agonists: Synthesis and biological evaluation

The synthesis, SAR and binding affinities are described for cannabinoid-1 receptor (CB1R) specific inverse agonists based on pyridopyrimidine and heterotricyclic scaffolds. Food intake and pharmacokinetic evaluation of several of these compounds indicate that they are effective orally active modulators of CB1R.     

Micro-drive Array for Chronic in vivo Recording: Drive Fabrication

Chronic recording of large populations of neurons is a valuable technique for studying the function of neuronal circuits in awake behaving rats. Lightweight recording devices carrying a high density array of tetrodes allow for the simultaneous monitoring of the activity of tens to hundreds of individual neurons. Here we describe a protocol for the fabrication of a micro-drive array with twenty one independently movable micro-drives. This device has been used successfully to record from hippocampal and cortical neurons in our lab. We show how to prepare a custom designed, 3-D printed plastic base that will hold the micro-drives. We demonstrate how to construct the individual micro-drives and how to assemble the complete micro-drive array. Further preparation of the drive array for surgical implantation, such as the fabrication of tetrodes, loading of tetrodes into the drive array and gold-plating, is covered in a subsequent video article.Open in a separate windowClick here to view.^{(88M, flv)}     

Self-Enhanced Accumulation of FtsN at Division Sites and Roles for Other Proteins with a SPOR Domain (DamX,DedD, and RlpA) in Escherichia coli Cell Constriction

Of the known essential division proteins in Escherichia coli, FtsN is the last to join the septal ring organelle. FtsN is a bitopic membrane protein with a small cytoplasmic portion and a large periplasmic one. The latter is thought to form an α-helical juxtamembrane region, an unstructured linker, and a C-terminal, globular, murein-binding SPOR domain. We found that the essential function of FtsN is accomplished by a surprisingly small essential domain (^EFtsN) of at most 35 residues that is centered about helix H2 in the periplasm. ^EFtsN contributed little, if any, to the accumulation of FtsN at constriction sites. However, the isolated SPOR domain (^SFtsN) localized sharply to these sites, while SPOR-less FtsN derivatives localized poorly. Interestingly, localization of ^SFtsN depended on the ability of cells to constrict and, thus, on the activity of ^EFtsN. This and other results suggest that, compatible with a triggering function, FtsN joins the division apparatus in a self-enhancing fashion at the time of constriction initiation and that its SPOR domain specifically recognizes some form of septal murein that is only transiently available during the constriction process. SPOR domains are widely distributed in bacteria. The isolated SPOR domains of three additional E. coli proteins of unknown function, DamX, DedD, and RlpA, as well as that of Bacillus subtilis CwlC, also accumulated sharply at constriction sites in E. coli, suggesting that septal targeting is a common property of SPORs. Further analyses showed that DamX and, especially, DedD are genuine division proteins that contribute significantly to the cell constriction process.Bacterial cytokinesis is mediated by a ring-shaped apparatus. Assembly of this septal ring (SR; also called the divisome or septasome) begins at the future site of fission, well before cell constriction initiates, and it remains associated with the leading edge of the invaginating cell envelope until fission is completed. The mature ring in Escherichia coli is made up of at least 10 essential division proteins (FtsA, -B, -I, -K, -L, -N, -Q, -W, and -Z and ZipA), which are each needed to prevent a lethal filamentation phenotype. The first known step in assembly of the division apparatus is polymerization of FtsZ just underneath the cytoplasmic membrane. These polymers are joined by FtsA and ZipA via direct interactions with FtsZ, resulting in an intermediate ring structure (the Z ring), onto which the remaining components assemble in a specific order to form a constriction-competent complex.In addition to the essential SR proteins, a growing number of nonessential proteins that associate with the organelle are being identified. Some of the latter are likely to serve redundant functions, while some may be required only under particular conditions (for reviews on the topic, see references 15, 19, and 25).FtsN belongs to the essential SR proteins and is thought to be the last of this class to join the organelle before the onset of cell constriction (1, 9, 11, 57, 59). It is a type II bitopic transmembrane species of 319 residues with a small cytoplasmic domain (residues 1 to 30), a single transmembrane domain (residues 31 to 54), and a large periplasmic domain (residues 55 to 319) (12) (Fig. ​(Fig.1).1). The periplasmic domain comprises three short regions with an α-helical character that are centered around residues 62 to 67 (H1), 80 to 93 (H2), and 117 to 123 (H3), an unstructured glutamine-rich linker (residues 124 to 242), and a C-terminal globular SPOR domain (residues 243 to 319) that has an affinity for peptidoglycan (55, 60) (Fig. ​(Fig.11).Open in a separate windowFIG. 1.E. coli ftsN locus, FtsN domains, and properties of genetic constructs. Shown are the EZTnKan-2 insertion site in ftsN^slm117 strains and the deletion-replacement in ftsN<>aph (ΔftsN) strains. Numbers refer to the site of insertion (black triangle) or to the base pairs that were replaced with an aph cassette (doubleheaded arrow), counting from the start of ftsN. The domain structure of FtsN is illustrated below the ftsN gene. Indicated are the transmembrane domain (TM; light gray), helices H1, H2, and H3 (black) in the periplasmic juxtamembrane region, and the C-terminal SPOR domain (^SFtsN; dark gray). The small periplasmic peptide that is sufficient for FtsN′s essential function in cell division (^EFtsN [see text]) is indicated with the doubleheaded arrow below the domain structure diagram. Also shown are inserts present on plasmids that produce fusions of various portions of FtsN to GFP or ^TTGFP under the control of the P_lac regulatory region. ^TTGFP-fusions contain the TorA signal peptide (hatched box) that is cleaved upon export to the periplasm via the twin arginine transport (Tat) system. Columns indicate the FtsN residues present in each fusion, whether the fusion could (+) or could not (−) compensate for the absence of native FtsN, and whether it accumulated at constriction sites sharply (+++) or poorly (−−+) or appeared evenly distibuted along the periphery of the cell (−−−).As with most SR proteins, it is unclear what the essential role of FtsN is. The ftsN gene was first identified as a multicopy suppressor of a Ts allele in essential division gene ftsA (11). Elevated levels of FtsN were subsequently found to also suppress some Ts alleles in ftsI, ftsK, and ftsQ (11, 18), and even to allow the propagation of cells with a complete lack of FtsK (22, 26) or of FtsEX (48). Depletion of FtsN allows assembly of all the other known essential components into nonconstricting SRs, but the number of ring structures per unit of cell length in FtsN⁻ filaments is two- to threefold lower than in wild-type (WT) cells (9). Bacterial two-hybrid studies suggest that FtsN interacts with several other SR proteins, including FtsA, FtsI (penicillin-binding protein 3 [PBP3]), FtsQ, FtsW, and MtgA (10, 16, 17, 38). Moreover, it was recently shown that the requirement for FtsN itself can be bypassed in cells producing certain mutant forms of FtsA, which are thought to stabilize the SR to a greater degree than native FtsA (5). These observations are all compatible with a general role of FtsN in stabilizing the ring structure. In addition, it was recently found that FtsN interacts directly with PBP1B, one of the major bifunctional murein synthases in E. coli, and that it can stimulate both its transglycosylase and transpeptidase activities in vitro (46). Thus, in addition to stabilizing the SR, FtsN may have a more specific role in modulating septal murein synthesis. Lastly, based on the fact that FtsN is the last known essential protein to join the SR, it is attractive to speculate the protein plays a role in triggering the constriction phase (10, 25). To what degree any of these proposed functions contribute to the essentiality of FtsN remains unclear.What does seem clear is that the essential activity of FtsN takes place in the periplasm and that residues 139 to 319 are dispensable for its essential function (12, 55). In addition, as residues 1 to 45 are also dispensable for targeting of FtsN to division sites, some portion of the periplasmic domain must also be sufficient to direct the protein to the division apparatus (1).In a genetic screen for synthetic lethality with min (slm) (6, 7), we isolated a mutant strain carrying a transposon insertion in codon 119 of ftsN. The viability of cells containing this severely truncated ftsN^slm117 allele prompted us to better define the functional domains of FtsN, and we did so by studying the properties of fusions between various portions of FtsN to green fluorescent protein (GFP). To sublocalize a subset of these, we took advantage of the ability of the twin arginine transport system (Tat) to export functional and fluorescent GFP fusions into the periplasm, such that their periplasmic localization could be determined in live cells by fluorescence microscopy (6, 8, 50, 54).We show that the essential function of FtsN can be performed by a surprisingly small periplasmic peptide of at most 35 residues that is centered around helix H2 but that this essential domain (^EFtsN) itself is unlikely to contribute much, if anything, to the accumulation of FtsN at constriction sites. On the other hand, the nonessential periplasmic SPOR domain (^SFtsN) localized sharply to these sites by itself, while SPOR-less FtsN derivatives localized poorly, at best. Notably, septal localization of ^SFtsN depended on coproduction of ^EFtsN, in cis or in trans, unless cells were provided with the FtsA^E124A protein (5) to allow constriction to ensue in the complete absence of ^EFtsN. Localization of ^SFtsN also depended on the activity of FtsI (PBP3) and the presence of at least one of the periplasmic murein amidases, AmiA, -B, or -C. The results suggest that FtsN joins the division apparatus in a self-enhancing fashion at the time of constriction initiation, which is compatible with a role of the protein in triggering the constriction phase of the division process. In addition, the results, taken together with earlier biochemical work (44, 46, 55), suggest that ^SFtsN is recruited to some form of septal murein that accumulates only transiently at sites of active constriction.In addition to FtsN, E. coli produces three proteins of unknown function that also bear a C-terminal SPOR domain (PF05036; Pfam 23) (20). Two of these, DamX and DedD, are inner membrane proteins with the same topology as FtsN, while the third, RlpA, is an outer membrane lipoprotein (43, 47, 53). We found that all three also accumulate at septal rings and that each of their SPOR domains act as autonomous septal targeting determinants. Moreover, phenotypes of the mutants indicate that both DamX and DedD contribute to the cell constriction process, leading to classification of these proteins as new nonessential division proteins.A SPOR domain is predicted to be present in at least 1,650 (putative) proteins from over 500 bacterial species (PF05036; Pfam 23) (20), raising the question as to how far SPOR properties have been conserved. We find that the SPOR domain of CwlC, a Bacillus subtilis murein amidase that is active during late stages of sporulation (39, 44), also accumulates sharply at division sites in E. coli.Our results predict that many other bacterial SPOR domain proteins specifically recognize the same or closely related target molecule(s) that accumulates transiently at sites of cell constriction. This is supported by a very recent study showing that SPOR domain proteins from Burkholderia thailandensis, Caulobacter crescentus, and Myxococcus xanthus accumulate at cell constriction sites as well (45).     

Gene mapping in the wild with SNPs: guidelines and future directions

One of the biggest challenges facing evolutionary biologists is to identify and understand loci that explain fitness variation in natural populations. This review describes how genetic (linkage) mapping with single nucleotide polymorphism (SNP) markers can lead to great progress in this area. Strategies for SNP discovery and SNP genotyping are described and an overview of how to model SNP genotype information in mapping studies is presented. Finally, the opportunity afforded by new generation sequencing and typing technologies to map fitness genes by genome-wide association studies is discussed.     

Determination of prednisolone in human adipose tissue incubation medium using LC-MS/MS to support the measurement of 11beta-hydroxysteroid dehydrogenase activity

A method for the determination of prednisolone in human adipose tissue incubation medium has been developed, validated and used to support studies designed to measure the activity of 11beta-hydroxysteroid dehydrogenase in human adipose tissue. After incubation, samples (80 microL) were extracted using Oasis HLB microElute SPE plates and the resulting extracts were analyzed using reversed-phase chromatography coupled to an Applied Biosystems Sciex PE API-4000 mass spectrometer with a TurboIonSpray interface (400 degrees C). The method was validated over the calibration range of 0.5-100 ng/mL. Intraday precision and accuracy were 6.1% R.S.D. or less and within 6.3%, respectively. Interday precision and accuracy were 4.2% R.S.D. or less and within 3.6%, respectively. Extraction recovery of prednisolone was greater than 84% over the range of low to high quality control sample concentrations. The validated assay was used to support studies designed to estimate ex vivo 11beta-hydroxysteroid dehydrogenase type 1 (11beta-HSD1) enzyme activity in human adipose tissue.