Novel System for Inducible Protein Degradation
From Kevin Griffith and Alan Grossmann at MIT come an exciting new collection of plasmids and strains that comprise a novel system for inducible protein degradation in Bacillus subtilis. With these tools, a user can rapidly deplete the concentration of a targeted protein and observe the phenotypic effects for the cell. For a more complete listing of the strains and plasmids in the collection and an introduction to their use, please see our product announcement. Our thanks to the Grossman lab for their generosity!
B. subtilis alternative sigma factor knockouts
The laboratories of John D. Helmann at Cornell University and Mohammed Marahiel at Philipps-Universität Marburg, Germany, have donated several strains that have greatly expanded the BGSC collection of B. subtilis mutants affected in alternative sigma factor genes. A list of these new strains can be found below. We thank these researchers for their generosity!
Gene | Product | Knockouts | Reference |
---|---|---|---|
sigL | σL | 1A914 | (6) |
sigM | σM | 1A906 | (4) |
sigV | σV | 1A907 | (2) |
sigW | σW | 1A905 | (1) |
sigX | σX | 1A901 | (5) |
sigY | σY | 1A909 | (3) |
sigZ | σZ | 1A902 | (2) |
ylaC | σYlaC | 1908 | (2) |
B. subtilis recombination and repair knockouts
Juan C. Alonso of the Campus Universidad Autonoma de Madrid has kindly supplied a collection of knockout mutants impaired in many of the genes implicated as being involved in DNA recombination and repair in Bacillus subtilis. These mutants should prove invaluable for those who wish to study the differences--sometimes subtle and sometimes dramatic--between Gram-positive and Gram-negative model systems in this area of cell function. We thank Dr. Alonso for his kindness.
- • 1A889 (= BG339) mfd::cat trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1 Cm; see Ayora, S. F., et al. (1996)
- • 1A890 (= BG775) recJ::six trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1 Cm; see Sanchez, H. D., et al. (2005)
- • 1A891 (= BG281) recN::cat trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1 recF15 Cm; see Alonso, J.C., et al. (1993)
- • 1A892 (= BG439) recO::cat trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1 Cm; see Fernández, S., et al. (1999)
- • 1A893 (= BG705) recQ::six trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1; see Sanchez, H. D., et al. (2005)
- • 1A894 (= BG425) recS::cat trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1 Cm; see Fernández, S., et al. (1998)
- • 1A895 (= BG633) recU::six trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1; see Sanchez, H. D., et al. (2005)
- • 1A896 (= BG703) ruvAB::six trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1; see Sanchez, H. D., et al. (2005)
- • 1A897 (= BG707) recG::six trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1; see Sanchez, H. D., et al. (2005)
- • 1A898 (= BG811) sbcC::cat trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1 Cm; Mascarenhas, J., et al. (2006)
- • 1A899 (= BG551) helD::erm trpC2 metB5 amyE sigB37 xre-1 attSPβ attICEBs1 Em; Alonso, J. C. (unpublished)
Skinless mutant of Bacillus subtilis 168
Tsutomu Sato of the Tokyo University of Agriculture and Technology has donated to the collection a Bacillus subtilis mutant cured of the prophage-like skin element. The BGSC code for this mutant is 1A884. In B. subtilis 168, the 48-kb skin element interrupts the coding sequence for the sporulation-specific sigma factor, σK, splitting it into two genes, spoIVCB and spoIIIC, that are reassembled during sporulation by the excision of skin in the mother cell chromosome. The skin element contains 57 reading frames, many of them similar in sequence to known temperate phage genes. Also included on skin is an operon involved in the extrusion of toxic arsenical compounds. The \\\\"skinless\\\\" mutant is therefore sensitive to sensitive to arsenate (1 mM) or arsenite (0.5 mM). It sporulates normally, indicating that skin is dispensable for spore formation. We are grateful to Dr. Sato for allowing us to maintain and distribute this interesting mutant.
Desert isolates of B. subtilis complex strains
A collaboration from groups at University of Maryland School of Medicine (J. Ravel and W. F. Fricke), Harvard Medical School (R. Kolter and A. Earl), and Harvard University (R. Losick) is currently aiming to sequence six environmental isolates belonging to the \\"Bacillus subtilis group\\" of related species:
- • Bacillus subtilis subsp. spizizenii TU-B-10T (BGSC 2A11T), isolated from the Sahara Desert near Nefta, Tunisia;
- • Bacillus subtilis subsp. spizizenii DV1-B-1 (= BGSC 2A12), isolated from Death Valley National Monument, California;
- • Bacillus subtilis AUSI98 (=BGSC 3A26), isolated from a soil sample collected near Salzburg, Austria;
- • Bacillus subtilis subsp. subtilis RO-NN-1(=BGSC 3A27), isolated from the Mojave Desert near Rosamond, California;
- • Bacillus vallismortis DV1-F-3 (=BGSC 28A4), isolated from a sand dune with mesquite tree in Death Valley National Monument, California;
- • Bacillus mojavensis RO-H-1 (=BGSC 28A5), isolated from the Mojave Desert near Rosamond, California
We thank Ashlee Earl of Harvard Medical School for donating these strains to the BGSC collection, and we look forward to the availability of their genome sequences.
B. subtilis knockouts in cold-schock helicases
From the laboratory of Prof. M. A. Marahiel at Philipps Universität Marburg come three Bacillus subtilis mutants containing knockouts in cshA and cshB. These genes encode two cold-shock helicase-like proteins. Single knockouts of cshA (strain CB30, BGSC 1A881) and cshB (strain CB40, BGSC 1A882) grow normally at 15°C under laboratory conditions, but a double knockout is lethal. A cshA knockout with a cshA-gfp fusion is also available (CB50, BGSC 1A883). The mutants are described in the paper cited below. We thank Prof. Marahiel for the gift of these strains!
Biofilm-forming marine isolate of B. licheniformis
From Reindert Nijland of Newcastle University comes Bacillus licheniformis strain EI-34-6. This marine isolate forms a thick, red biofilm and produces bacitracin when grown at a medium-membrane interface in media containing glycerol and FeCl3. To learn more about this strain, you may read the paper describing its isolation. The strain is available from the BGSC as 5A37. We thank Dr. Nijland for this interesting new isolate!
Integration vector for lacZ transcriptional fusion
From Thomas Wiegert at the Universität Bayreuth comes a novel vector, pLacZ, designed to facilitate the construction of lacZ transcriptional fusions and their subsequent integration into the Bacillus subtilis amyE locus. Like other integration vectors, pLacZ can replicate in E. coli but not in B. subtilis. It contains the 5\\' and 3\\' ends from the amyE gene; sandwiched between them is a kanamycin/neomycin resistance marker, used for selection, and the complete lacZ coding sequence with convenient upstream sites for inserting EcoRI and BamHI and compatible fragments. An E. coli host containing pLacZ is available form the BGSC as strain ECE201; purified plasmid DNA is available as ECE201P. A genetic and physical map of the plasmid is available here. The sequence of the plasmid is available here. The construction and use of pLacZ is described in:
Our thanks to Dr. Wiegert for his generous donation!
Screening for synthetic lethal or sick mutations
From Dennis Claessen at the Jeff Errington lab at Newcastle University comes pLOSS* , a novel vector designed to screen for synthetic lethal or sick mutations in Bacillus subtilis and other gram-positive bacteria. Synthetic lethal mutations are those that individually are viable but in combination are lethal. These types of mutations can provide powerful insights into coordinated gene functions in cellular processes. For more information about pLOSS*, see our description here. Plasmid pLOSS* is available either as purified DNA (ECE200P) or in and E. coli host (ECE200). We thank Dr. Claessen for making this exciting new tool available through the BGSC!
The first generation general purpose shuttle vectors pMK3 and pMK4 are not new, but they are a tried and true tool for cloning in a wide variety of gram-positive bacteria, including species from the genera Bacillus, Listeria, and Staphylococcus. Recently, the BGSC determined the DNA sequence for these two plasmids. For details, see our description here.
Marine isolate, Bacillus sp. NRRL B-14911
We are now pleased to offer Bacillus sp. NRRL B-14911, a marine bacterial strain isolated from ocean water at 10 m depth in the Gulf of Mexico. 16S rRNA sequence comparisons suggest that it is either a member of or closely related to Bacillus firmus (Siefert J. L., et al. 2000. Curr. Microbiol. 41:84-88; view paper in PubMed). A gapped genome sequence is available at AAOX01000000. NRRL B-14911 forms pink-pigmented colonies on LB, TBAB, or a variety of standard complete media. It can grow between 20°-40°C with optimal growth at 28°C. It is moderately halo-tolerant, capable of growth in in 0-5% (w/v) NaCl. This strain has been accessioned into the BGSC collection as 29A3.
pMAP65: overexpression of LacI repressor
From Marie-Agnès Petit of the INRA in Jouy en Josas, France, comes a useful plasmid for tightening up regulation of Pspac promoter fusions in Bacillus subtilis and related organisms. Plasmid pMAP65 (Petit, M. A., et al. 1998. Mol. Microbiol. 29:261–273) is a LacI-overproduction plasmid based on the pUB110 replicon. Many of the most useful expression systems for gram-positive organisms are based on the Pspac system, composed of a hybrid SPO1/lac promoter and a constitutively expressed lacI repressor gene. This system, first developed by Yansura and Henner (1984. Proc. Natl. Acad. Sci. USA 81:439-443), allows for IPTG-inducible expression of gene fusions. It is still an expression system of choice in functional genomics projects. One limitation of Pspac, however, is that it is somewhat leaky; a significant basal level of expression still exists in the absence of IPTG, making the identification of essential genes, for example, somewhat problematic. Plasmid pMAP65 solves this problem by overexpressing the LacI repressor, virtually shutting down the expression of Pspac fusions in trans. Examples from the literature in which pMAP65 was used for this very purpose are listed below. We thank Dr. Petit for donating this useful tool.
Bacillus subtilis knockouts in yjbI and ypmQ
Dr. Michiko Nakano of the OGI School of Science and Engineering at Oregon Health and Science University has kindly deposited two additional knockout mutants, constructed in a JH642 background. The knockouts affect yjbI, which encodes a truncated hemoglobin, and ypmQ, which functions in delivering copper to cytochrome oxidase. We thank Dr. Nakano for these interesting new mutants.
BGSC Code | Original | Genotype | Comments |
---|---|---|---|
1A864 | ORB4185 | yjbI::spc trpC2 pheA1 | The yjbI gene is reported to encode a truncated hemoglobin with high oxygen affinity, moderate carbon monoxide affinity, and peroxidase-like activity; see Choudhary ML, et al (2005) Prot Express Purif 41:363; Giangiacomo L, et al (2005) J Biol Chem 280:9192 |
1A865 | ORB6556 | ypmQ::erm trpC2 pheA1 | The ypmQ gene encodes a homolog to the yeast Sco1 protein, which functions in delivering copper to cytochrome oxidase; deletion of ypmQ in B. subtilis reportedly depresses the expression of cytochrome c oxidase. See Mattatall NR, et al (2000) J Biol Chem 275:28802; Andruzzi L, et al (2005) J Am Chem Soc |127:16548 |
Three B. subtilis chemotaxis gene knockouts
Dr. George Ordal of the University of Illinois at Urbana-Champaign has donated three additional chemotaxis mutants, with knockouts in cheC, chedD, or both. The mutants are described in Rosario MML, et al. (1995) Biochemistry 34:3823 and Kirby JR, et al. (1997) Mol Microbiol 24:869. We thank Dr. Ordal for these strains.
BGSC Code | Original | Genotype | Comments |
---|---|---|---|
1A861 | OI2934 | cheD1::cat | Insertion of cat gene into the SstI site of the cheD gene; impaired chemotaxis to some amino acids and sugars; tumbly phenotype |
1A862 | OI3135 | cheCΔ | In-frame deletion of all but 50 codons of the cheC gene; impaired chemotaxis; highly methylated MCPs |
1A863 | OI3305 | cheCΔ cheD1::cat | Double knock-out of cheC and cheD |
B. subtilis gene knockouts in yxaL, ywhK, yerB
Also from Dr. Petit come three novel gene knockouts in a Bacillus subtilis 168 trpC2 background, all described in Noirot-Gros, M.-F., et al. 2002. Mol. Genet. Genom. 267:391-400. We once again extend our thanks for these strains
BGSC Code | Original | Genotype | Comments |
---|---|---|---|
1A858 | MAS 648 | trpC2 yxaL1 | The xyaL1 allele is an insertion of the spectinomycin resistance plasmid, pMAP132, into the chromosomal xyaLlocus. Resistant to spectinomycin 60 µg/ml |
1A859 | MAS 649 | trpC2 ywhK1 | The xyaL1 allele is an insertion of the erythromycin resistance plasmid, pMAP127, into the chromosomal ywhK locus. Resistant to erythromycin 0.5 µg/ml |
1A860 | MAS 650 | trpC2 yerB1 | The xyaL1 allele is an insertion of a chloramphenicol resistance cassette into the chromosomal yerB locus. Resistant to chloramphenicol 5 µg/ml* |
Pat Vary Bacillus megaterium mutant collection
Dr. Patricia S. Vary of Northern Illinois has donated 81 auxotrophic, antibiotic-resistant, and temperature-sensitive germination mutants of Bacillus megaterium QM B1551 from the James C. Vary collection. Strain QM B1551 (available from the BGSC as 7A16) has been carefully studied as a bacterial genetic system by several labs during the past three decades. The large dimensions of the B. megaterium cell have made it an attractive organism for studies in development and subcellular localization of expressed proteins. QM B1551 is now the subject of a whole-genome sequencing project that is nearing completion www.bios.niu.edu/b_megaterium. The availability of genome sequence data and a collection of genetically well-characterized legacy strains should make B. megaterium an exciting topic for future research.
System for Protein Expression, Surface Attachment
Dr. Wolfgang Schumann has donated two plasmids, pNDH09 and pNDH10, and a Bacillus subtilis host, NDH03, designed for the inducible expression of foreign proteins and their subsequent attachment to the host cell surface. Plasmid pNDH10 carries a xylose-inducible cassette and a sortase-mediated cell anchoring motif. B. subtilis NDH03 expresses sortase A, making it a suitable host for plasmids based on pNDH10. The sortase gene can also be integrated into the chromosome of other B. subtilis strains to create hosts by means of the integration vector pNDH09. For more details, see Nguyen HD, Schumann W (2006) J Biotechnol 122:473 and our for pNDH10. BGSC strains 1A857, ECE196, and ECE197 are B. subtilis NDH03, E. coli DH5α(pNDH09), and DH5α(pNDH10), respectively. We thank Dr. Schumann for this useful set of gene expression tools!
Mutants affected in calcium caronate precipitation
From Brunella Perito at the Università degli Studi de Firenze, Italy, comes a recent set of strains constructed to analyze the process of calcium carbonate precipitation in Bacillus subtilis. These strains are described in Barabesi, C., A. Galizzi, G. Mastromei, M. Rossi, E. Tamburini, and B. Perito. 2007. Bacillus subtilis Gene Cluster Involved in Calcium Carbonate Biomineralization. J. Bacteriol. 189:228-235. They represent knockout insertions in five genes within the lcfA operon. Four of the five knockouts are deficient in precipitation on B4 medium (0.4% yeast extract, 0.5% dextrose, 0.25% calcium acetate, 1.5% agar). We thank Dr. Perito for donating these strains to the BGSC!
BGSC No. | Original | Genotype | Insertion sites (Subtilist) |
---|---|---|---|
1A852 | FBC1 | trpC2 lcfA::pJM103 Cm | 2918385-2918577 |
1A853 | FBC2 | trpC2 ysiA::pJM103 Cm | 2917259-2917411 |
1A854 | FBC3 | trpC2 ysiB::pJM103 Cm | 2916546-2916791 |
1A855 | FBC4 | trpC2 etfB::pJM103 Cm | 2915644-2915865 |
1A856 | FBC5 | trpC2 etfA::pJM103 Cm | 2914849-2915047 |
Bacillus subtilis yshD knockout mutant
Allesandra Albertini, also from the Pavia Bacillus subtilis group, has kindly donated a knockout mutant in the mutS2 paralog yshD. Strain 1A845 (originally PB5266) is described in Rossolillo, P. and A. M. Albertini. 2001. Mol. Gen. Genet. 264:809-818.
Bacillus subtilis mutants affected in motility
Also from the Galizzi laboratory come two other mutants affected in motility. Strain 1A842 (originally PB5250) has a knockout in the flagellin hag locus. Strain 1A850 (originally PB5249) has a hypermotility phenotype due to a mutation in the ifm locus. Both mutants are described in Senesi, S., et al. 2004. J. Bacteriol. 186:1158-1164.
Bt israelensis expressing sphaericus binary toxins
Dr. Brian Federici at the University of California, Riverside, has donated a recombinant strain that produces the mosquitocidal Bacillus sphaericus binary toxin in the B. thuringiensis subsp. israelensis plasmid-cured host 4Q7. With transcription of the toxin genes driven by the cyt1A promoters and protected by the STAB-SD sequence, the toxin proteins themselves accumulate as large crystals in sporulating cells. We have deposited this strain, 4Q7(pPHSP-1), under the accession 4Q11 in our collection. We thank Dr. Federici for making the strain available to us!
Bt kurstaki mutant producing only Cry1Ab crystals
From Dr. Arthur I. Aronson comes a Bacillus thuringiensis subsp. kurstaki plasmid cured mutant that produces only Cry1Ab crystals. The mutant was isolated during the classic plasmid-curing studies that demonstrated the plasmid location of cry genes in this organism (Gonzalez 1981). Strain HD1-1-9 is missing only its 165-kb megaplasmid, but as a result has retained only cry1Ab from its complement of crystal toxin genes. As demonstrated in the Aronson lab, Cry1Ab production in this strain is temperature sensitive, requiring temperatures below 30°C (Minich 1984). We thank Dr. Aronson for providing this mutant.
Mutants of Bacillus amyloliquefaciens FZB42
Dr. Rainer Borriss of Humboldt University in Berlin has deposited in the BGSC collection three additional mutants of Bacillus amyloliquefaciens FZB42. The wild type isolate stimulates plant growth and suppresses pathogens in the rhizosphere. The mutants show a reduction in plant growth promotion activity due to reduced production of the hormone indole-3-acetic acid, a biochemical process that requires tryptophan as a substrate. Here are the three new strains, with their BGSC accession numbers:
BGSC No. | Original | Genotype |
---|---|---|
10A10 | E101 | ΔtrpAB::EmR |
10A11 | E102 | ΔtrpED::CmR |
10A12 | E103 | ΔysnE::EmR |
New Gram-Positive-E. coli expression vectors
Expression of foreign proteins in Bacillus subtilis and other gram-positives has been a technically challenging problem, due in part to the inherent instability of the rolling-circle replicating plasmids on which most shuttle vectors are based. From the Wolfgang Schumann lab come three new expression vectors, pHCMC02 (weakly constitutive), pHCMC04 (xylose inducible), and pHCMC05 (IPTG inducible). We thank Dr. Schumann for donating this set of vectors and anticipate that they will prove very useful to the Bacillus genetics community.
New Gram-Positive-E. coli expression vectors featuring high structural stability
B. amyloliquefaciens FZB42
Dr. Rainer Borriss of Humboldt University in Berlin has deposited in the BGSC collection four strains of Bacillus amyloliquefaciens. Strain FZB42 is a rhizosphere colonizing strain that stimulates plant growth and suppresses plant pathogenic organisms (Idriss EE, et al. (2002) Microbiology 148:2097). Like many B. subtilis isolates, it displays natural competence for transformation during stationary phase. A survey of the genome revealed sx large gene clusters encoding nonribosomal peptide synthetases (NRPS) and polyketide synthases (PKS). The Borriss lab constructed knockout mutants in two of these clusters, fen and bmy, encoding fengycin and bacillomycin D. Single mutants retained most of their ability to kill a fungal plant pathogen, but double mutants were severely impaired in this activity. Here are the strains, with their BGSC accession numbers:
BGSC No. | Original | Genotype |
---|---|---|
10A6 | FZB42 | wild type isolate |
10A7 | AK1 | ΔbmyA::EmR |
10A8 | AK2 | Δfen::CmR |
10A9 | AK3 | ΔbmyA::EmR Δfen::CmR |
Bacillus subtilis knockouts in des, cysK
From the lab of Diego de Mendoza at the IDCM in Rosario, Argentina come two knockout mutants in Bacillus subtilis. The first, MAΔK (our accession 1A834) has its cysK gene disrupted by a kanamycin cassette. It grows at a reduced rate on sulfate and requires the addition of yeast extract and casamino acids on cysteine as a sulfur source. The second, LC5 (our 1A835) has a similar cassette disrupting its des locus. This mutant is unable to perform the Δ5 desaturation on its fatty acids in response to cold shock. We thank Drs. Cecilia Mansilla, Larisa Cybulski, and Diego de Mendoza for these mutant strains.
Set of 14 B. subtilis knockouts
Dr. Jeff Errington has graciously deposited a set of 14 new mutants generated in his lab as part of the Bacillus subtilis genome consortium. Each mutant has a pMUTIN plasmid insertion into the target gene, placing expression of that gene under the control of the IPTG-inducible Spac promoter. With this strategy, essential genes can be distinguished from non-essential by the requirement of IPTG for growth and viability. For a description of this phase of the genome project, see Kobayashi K, et al. (2003) PNAS 100:4678. We thank Dr. Errington for his generosity and invite other members of the genome consortium to similarly deposit new mutants in the BGSC collection.
BGSC No. | Original | Locus No. | Name | Product | Essential?* |
---|---|---|---|---|---|
1A815 | BFS2809 | BG11373 | pgsA | phosphatidylglycerophosphate synthase | Yes |
1A816 | BFS2814 | BG11795 | ylyA | protein of unknown function | No |
1A817 | BFS2817 | BG11425 | yllB | conserved protein of unknown function | No |
1A818 | BFS2818 | BG10219 | ylxA | conserved protein of unknown function | No |
1A819 | BFS2820 | BG13389 | yloN | conserved protein of unknown function | No |
1A820 | BFS2822 | BG13391 | prkC | probable membrane-linked protein kinase | No |
1A821 | BFS2824 | BG13394 | yloS | conserved protein of unknown function | No |
1A822 | BFS2839 | BG11538 | smc | SMC protein (chromosome condensation, segregation) | Yes |
1A823 | BFS2845 | BG13136 | yjbG | probable oligoendopeptidase | No |
1A824 | BFS2847 | BG13139 | yjbJ | similar to lytic transglycosylase | No |
1A825 | BFS2851 | BG13143 | ppnK | inorganic polyphosphate/ATP-NAD kinase | Yes |
1A826 | BFS2862 | BG13376 | ylmG | conserved protein of unknown function | No |
1A827 | BFS2864 | BG13402 | ylqC | possible RNA binding protein | No |
1A828 | BFS2866 | BG13407 | ylqH | protein similar to flagellar biosynthetic protein | No |
*Mutant requires IPTG for growth on LB
CFP and YFP fusion vectors
Jan-Willem Veening of the University of Groningen has kindly donated a set of integration vectors that greatly facilitate the construction of fusions to either the Cyan or Yellow Fluorescent Proteins in Bacillus subtilis. The original CFP and YFP proteins were engineered for expression in eukaryotic organisms, not gram-positives. These improved variants contain several additional codons at the 5\\' end, allowing for much higher levels of expression in B. subtilis and potentially a host of other gram-positive bacteria. The large multiple cloning site should make construction of fusions a simple matter. We thank Dr. Veening and colleagues for their generosity. Look for a paper describing the plasmids to appear in an upcoming issue of Applied and Environmental Microbiology.
Integration vectors allow improved expression of Cyan and Yellow Fluorescent Proteins in Bacillus
14 novel Bacillus, Paenibacillus, Brevibacillus
From two sources--the ARS collection at the US Department of Agriculture and the T. Leighton laboratory at Children’s Hospital Oakland Research Institute--come a collection of 14 strains from underrepresented species in our collection. Included are nine type strains. We appreciate the kindness of Alex Rooney at the ARS and Katie Wheeler at CHORI in helping us acquire these strains:
- 80A1T Aneurinibacillus aneurinilyticus NRRL NRS-1589T
- 81A1T Aneurinibacillus migulanus NRRL NRS-1137T
- 11A2T Bacillus atrophaeus NRRL NRS-213T
- 6A17 Bacillus cereus ATCC 13472
- 6A18 Bacillus cereus ATCC 15816
- 61A1T Bacillus coagulans ATCC 7050T
- 7A36T Bacillus megaterium ATCC 14581T
- 6A20 Bacillus mycoides ATCC 11986
- 6A19 Bacillus mycoides ATCC 31101
- 2A9T Bacillus subtilis subsp. spizizenii NRRL B-23049T
- 2A10 Bacillus subtilis subsp. spizizenii NRRL B-14472
- 34A1T Paenibacillus thiaminolyticus NRRL B-4156T
- 41A1T Brevibacillus borstelensis NRRL NRS-818T
- 42A1T Brevibacilus centrosporus NRRL NRS-664
New ectopic integration vectors
Rebecca Middleton of the University of California, Berkeley, has generously donated to the BGSC a set of novel integration vectors. The vectors integrate into the Bacillus subtilis chromosome “ectopically,” that is, at a locus targeted by homologous sequences within the vector itself, rather than by sequences within a cloned insert. Each vector contains an integration cassette consisting of the 5’ and 3’ ends of a non-essential chromosomal gene, interrupted by a selectable antibiotic resistance marker and a multiple cloning site. When the vectors are introduced into a host strain by transformation with selection for antibiotic resistance, a double-crossover event replaces the chromosomal locus with the plasmid-borne cassette, including any fragments that have been inserted into the cloning sites. The six plasmids within the collection allow the user to target any of three loci—gltA, pyrD, or sacA—with selection for either kanamycin or chloramphenicol resistance. The collection also includes six control strains in which the cassettes, without inserts, have been integrated into the chromosomal loci.
New ectopic integration vectors for Bacillus subtilis
pBCJ164.3, with constitutive, high expression
Dr. Brian Jester of Trinity College, Dublin, Ireland has kindly donated a novel vector, pBCJ164.3, to our collection. The plasmid contains the 5\\' and 3\\' ends of the Bacillus subtilis rpsD gene, together with its promoter and transcription terminator. An NdeI site within this cassette allows for inserted fragments to be placed under the control of the strong rpsD promoter. Like other integration vectors, pBCJ164.3 replicates in E. coli but not in B. subtilis. When a recombinant plasmid is isolated from E. coli and transformed into a recombination-proficient B. subtilis host with selection for chloramphenicol resistance, a non-mutagenic Campbell-type insertion even should take place within the host chromosomal rpsD locus.
New integration vector for high level, constitutive expression of cloned inserts
Novel B. mycoides, B. firmus, B. lentus, B. brevis
Dr. Len Peruski from the Indiana University School of Medicine in Gary, Indiana, has donated several strains to fill holes in our collection, including four strains of Bacillus mycoides (BGSC Codes 6A11-6A14), two strains of Bacillus firmus (BGSC 29A1 and 29A2), and one strain each of Bacillus lentus (60A1), Brevibacillus brevis (26A6), and Bacillus circulans (16A4). For more information about any of these strains, enter the BGSC code or species name on our improved search page! Our thanks to Dr. Peruski for his generosity.
New shuttle vector for constructing GFP fusions
Anne K. Dunn, a student in the Jo Handlesman lab at the University of Wisconsin, has constructed pAD123 (see map and sequence), a new shuttle vector optimized for fluorescence-assisted cell sorting. This vector can be a powerful tool for isolating sets of promoters that all respond to certain environmental or physiological stimuli. These GFP fusions can also serve to localize proteins within cells. Request strain ECE165 for pAD123 or strain ECE166 for pAD43-25 (see map and sequence), a derivative carrying a constitutive B. cereus promoter.
Bacillus subtilis safA knockout mutant
Amanda J. Ozin, currently at the Max Planck Institute for Infection Biology in Berlin, has donated a safA (formerly yrbA) knockout mutant in B. subtilis. The gene product, SpoVID-associated factor (SafA), is required during the early stages of spore coat assembly. Mutants produce abnormal spores lacking several coat proteins. To obtain this mutant, request our strain 1S117.
Surfactin-producing strain of Bacillus subtilis
Peter Zuber of the OGI School of Science & Engineering has donated a surfactin-producing strain of Bacillus subtilis, ATCC 21332, our strain 3A22. Surfactin is a cyclic lipopeptide with a fascinating array of properties. At micromolar concentrations, it lowers the surface tension of water from 72 mN m-1 to 27 mN m-1, suggesting many possible \"environmentally friendly\" applications in industry. Anti-clotting, antibacterial, antitumoral, and hypocholesterolemic properties have all been described as well. For an interesting minireview, read Peypoux, F., J. M. Bonmatin and J. Wallach. 1999. Recent trends in the biochemistry of surfactin. Appl. Microbiol. Biotechnol. 51:553-563. The Zuber lab has extensively published research elucidating the molecular genetics and biochemistry of surfactin synthesis and its relation to developmental processes in B. subtilis.
Three novel Bacillus mojavensis strains
From Fred Cohan at Wesleyan University in Middletown, Connecticut come three strains belonging to Bacillus mojavensis, a species closely related to B. subtilis. Our strains 28A1, 28A2, and 28A3 were originally described as RO-H-1, RS-A-2, and RO-C-2, respectively, in Roberts, M. S., L. K. Nakamura, and F. M. Cohan. 1994. Bacillus mohavensis sp. nov., Distinguishable from Bacillus subtilis by Sexual Isolation, Divergence in DNA Sequence, and Differences in Fatty Acid Composition. Int. J. Syst. Bacteriol. 44:256-264. The Cohan lab has used these and other relatives of B. subtilis to investigate the relationship between DNA sequence divergence and sexual isolation in bacteria.
Three new Epitope-tagging vectors
Also from the Schumann laboratory come three vectors designed to tag a gene of interest with either the FLAG, cMyc, or HA epitopes, greatly simplifying the detection and purification of proteins in gram-positive organisms.
Three new Epitope-tagging vectors
Sixteen new Fluorescent Protein tagging vectors
The Bacillus Genetic Stock Center is pleased to offer 16 new vectors designed for constructing fluorescent protein fusions. Three of the vectors come from the laboratory of Wolfgang Schumann at the University of Bayreuth, Germany, while the remaining 13 come from Peter Lewis at the University of Newcastle, Australia.
Sixteen new Fluorescent Protein tagging vectors
Bacillus subtilis sulfur utilization knockouts
Jan van der Ploeg at the University of Zurich has kindly donated four Bacillus subtilis mutants with knockouts in one or more sulfur utilization genes: ssuA, ssuC, ssuD, cysI, or cysJ.
New Bacillus subtilis sulfur source utilization gene knockout mutants
pDG148-Stu, Gram-Positive - E. coli Shuttle Vector
From F. Denizot at the INRS in Marseille, France, comes pDG148-Stu a shuttle vector, capable of replicating in E. coli from the pBR322 origin and in Bacillus from the pUB110 origin. It allows inducible expression of foreign inserts cloned into its unique StuI site. Oriented, ligation-independent cloning of PCR fragments is possible using the proper primers and a prepared template. Erratum - The original Adobe Acrobat file describing pDG148-Stu was in error. Instead of treating StuI-linearized vector with T4 polymerase in the presence of dATP, one must use dTTP. The file above has been corrected.
RecA-independent Integration Vector
New from the Patrick Piggot lab at Temple University School of Medicine: a Bacillus subtilis integration vector that inserts into the dif site at about 166° on the chromosome. Integration takes place via the host system for resolving chromosome dimers and does not require the action of the standard recombination pathways. Even recA mutants can be transformed with this vector!
RecA-independent Integration Vector for Bacillus subtilis
High titer PBS1 transducing lysate
A high titer PBS1 transducing lysate is now available, a gift from Brooke Murphy of the Tina Henkin lab here at the Ohio State University. The BGSC accession number for PBS1 is 1P1. Please note that this phage is heat labile and requires a motile strain of Bacillus subtilis as a host.
Antibiotic Switching Vectors
Vasant K. Chary from the Patrick Piggot lab at Temple University School of Medicine has kindly donated a pair of novel antibiotic-cassette switching vectors, pVK71 and pVK73, for use in Bacillus subtilis and other Gram-positive organisms.
Bacillus subtilis autolysin-deficient mutants
The Bacillus Genetic Stock Center is pleased to offer an isogenic set of Bacillus subtilis mutants deficient in the major autolysins. Philippe Margot, from the Dimitri Karamata group at the Institut de Génétique et de Biologie Microbiennes in Lausanne, Switzerland, kindly donated the collection.
Bacillus subtilis autolysin-deficient mutants
Strains with Insecticidal, Nematicidal activity
From the laboratory of Samuel Singer, who retired in 1997 from Western Illinois University, comes a collection of environmental bacterial isolates demonstrating activity against a variety of invertebrate species.
Novel Strains Showing Insecticidal, Nematicidal, and Molluscicidal Activity
Integrative expression vectors for B. subtilis
From the laboratory of Wolfgang Schumann at the University of Bayreuth come two new expression vectors capable of integrating into the Bacillus subtilis chromosome at the lacA locus. Each allows for regulated expression of cloned inserts.
Bacillus subtilis Integration Vectors with Inducible Expression of Cloned Inserts
pMUTIN4, Vector Useful for Gram-Positive Genomics
pMUTIN4 should allow the researcher to produce knockout or conditional expression mutations in any unknown coding sequence.
A Vector Useful for Gram-Positive Genomics
Bacillus subtilis mutants affected in PrpC, PrkC
From the laboratory of Chet Price at UC Davis comes an important set of mutants altered with the regulation of late stationary phase events. PrpC is a member of the PPM family of serine/threonine protein phosphatases; it removes phosphates from PrkC, a serine/threonine kinase. The pair is believed to regulate the activity of Elongation factor G (EF-G) during stationary phase. In prpC knockouts, such as PB702 (=BGSC 1A961), stationary phase cultures grow to a much greater density in rich, non-sporulation media. In contrast, stationary phase cultures of prkC knockouts, such as PB705 (=BGSC 1A962), grow to a significantly lower density. In double mutants, such as PB722 (=BGSC 1A964), prkC is epistatic to prpC (1). We thank Tatiana Gaidenko and Chet Price for donating this set of strains to the BGSC.
BGSC | Strain | Genotype |
---|---|---|
1A961 | PB2 | trpC2 |
1A962 | PB702 | prpCΔ1 trpC2 |
1A963 | PB705 | prkCΔ1 trpC2 |
1A964 | PB722 | prpC-prkCΔ1 trpC2 |
pNW33N, Cloning Vector for Bacillus Thermophiles
Neil Welker has donated plasmid pNW33N, a fifth generation vector that stably replicates in Bacillus subtilis, Geobacillus stearothermophilus and Escherichia coli
Cloning Vector for Thermophilic Bacillus Strains