Formation of Giant and Ultramicroscopic Forms of Nostoc muscorum CALU 304 during Cocultivation with Rauwolfia Tissues

The study of heteromorphic Nostoc muscorum CALU 304 cells, whose formation was induced by 6- to 7-week cocultivation with the Rauwolfia callus tissues under unfavorable conditions, revealed the occurrence of giant cell forms (GCFs) with a volume which was 35–210 times greater than that of standard cyanobacterial cells. Some GCFs had an impaired structure of the murein layer of the cell wall, which resulted in a degree of impairment of the cell wall ranging from the mere loss of its rigidity to its profound degeneration with the retention of only small peptidoglycan fragments. An analysis of thin sections showed that all GCFs had enlarged nucleoids. The photosynthetic membranes of spheroplast-like GCFs formed vesicles with contents analogous to that of nucleoids (DNA strands and ribosomes). About 60% of the vesicles had a size exceeding 300 nm. With the degradation of GCFs, the vesicles appeared in the intercellular slimy matrix. It is suggested that the vesicles are analogous to elementary bodies, which are the minimal and likely primary reproductive elements of L-forms. The data obtained in this study indicate that such L-forms may be produced in the populations of the cyanobionts of natural and model syncyanoses. Along with the other known cyanobacterial forms induced by macrosymbionts, L-forms may represent specific adaptive cell forms generated in response to the action of plant symbionts.     

Ultrastructure of cyanobacterium <Emphasis Type="Italic">Nostoc</Emphasis> sp. f. <Emphasis Type="Italic">Blasia</Emphasis> cell forms in persisting populations

Cell clusters formed in persistent populations of Nostoc sp. f. Blasia, a cyanobacterium capable of cell differentiation, under prolonged storage in the dark at low temperatures were studied for the first time. Cell reorganization was observed, including changes in the ultrastructure of thylakoids, the cell wall peptidoglycan layer, and carboxysomes. Subcellular structures involved in intercellular communication within the clusters were revealed (structures similar to microplasmodesms and contact pores, secretory vesicles, etc.) Persistence of cyanobacterial populations was concluded to result from formation not only of specialized dormant cells (akinetes), but also L-forms, as well as from the modification changes of the clustered vegetative cells. A cluster containing the vegetative cells and L-like forms within a common intercellular matrix is considered a structural unit at the supracellular level, which is responsible for survival of cyanobacterial populations when mass akinete formation does not occur.     

Ultrastructure of L forms. IV. L forms of nonagglutinating vibrios]

A study was made of the ultrastructure of stable L-forms of Nag vibrios aged 24 hours. Cells of all types of the L-forms had cytoplasmic membranes, and a three-layered structure, which was found not everywhere. Externally of the cytoplasmic membrane, in some areas of the individual cells there were revealed a plastic layer of cell wall and a basal membrane. However, in difference to bacterial forms of the vibryos, rigidity of the cell wall was disturbed, and the links between the cell wall and the cytoplasmic membrane were indetectable. There were regularly revealed lamellar of myelin-like membranous structures in the cytoplasm, which did not occur in bacterial forms, and also lamellar mesosomes. The latter were found in the sites of cell division. Viability of small bodies as the minimal reproductive forms of the L-cultures is confirmed by the presence in them of a nucleoid and of the binary division.     

Ultrastructure of Brucella abortus L-forms induced by penicillin in a liquid and in a semisolid medium

Brucella abortus L-forms were induced by 5.0 or 10.0 mug of penicillin/ml in a broth medium containing 0.3 m sucrose, and in a semisolid medium containing 10% calf serum and 20.0, 40.0, or 60.0 mug of penicillin/ml. After 96 hr of incubation, L-forms of various sizes and shapes were observed. Basic structures of the L-forms were similar whether induced in liquid or semisolid medium. L-forms had two "unit" membranes, each consisting of two outer dense layers separated by a lucent layer. A few large, irregularly shaped organisms in penicillin-treated broth cultures had additional surface material and were referred to as "transitional" forms. In contrast with L-forms, the bacterial cells were fairly uniform in size and shape, were smaller, and had a more complex cell wall structure. Small bodies limited by a "unit" membrane were present within and around numerous L-forms from liquid and semisolid medium cultures. Other internal membranous structures were also seen in some L-forms. Most Brucella L-forms described in this paper reverted to bacteria in the absence of penicillin and were structurally characteristic of unstable L-forms.     

聚合酶链反应-单链构型多态性检测细胞壁缺陷型淋病奈瑟菌cppB基因变异

目的：检测与分析淋病奈瑟菌L型的cppB基因,探讨细胞壁缺陷对淋病奈瑟菌cppB基因的影响。方法：用青霉素诱导淋病奈瑟菌成为L型并获得稳定L型纯培养物,用cppB基因特异性引物以聚合酶链反应(PCR)检测稳定L型纯培养物的cppB基因和进行单链构型多态性(SSCP)分析。结果：淋病奈瑟菌的细菌型及其L型都具有cppB基因扩增产物,但PCR—SSCP分析可见异常泳动DNA带型(细菌型有2条带、L型有3条带)。结论：细胞壁缺陷淋病奈瑟菌仍然具有cppB基因,但其碱基序列可以发生改变。     

Primary Lysosomes of the Ciliate Pseudomicrothorax dubius: Cytochemical Identification and Role in Phagocytosis*

SYNOPSIS. Filamentous cyanobacteria are ingested through the cytopharynx of the ciliate Pseudomicrothorax dubius. The cytopharynx is a complex of microtubules and microfilaments located in a highly vesiculated cytoplasm, the phagoplasm. Two types of membrane-bounded phagoplasmic vesicles can be distinguished by their differences in size, fine structure, and acid phosphatase (AcPase) content. One type has a homogeneous, electron-dense interior which is AcPase-positive. These vesicles are present in fed cells and in unfed cells devoid of food vacuoles, and thus appear to be primary lysosomes. During phagocytosis, exocytosis within the cytopharynx of the primary lysosomes results in the elaboration of a food vacuole. The vacuole grows by incorporation of lysosomal membrane; lysosomal hydrolases are liberated into the vacuole. Within less than 1 second of AcPase's entry into the food vacuole, it is detectable within the cyanobacterial cytoplasm, and within 5 seconds, destruction of the cyanobacterial filament is observed. It is hypothesized that the rapidity of hydrolase penetration of the cyanobacterial cell wall is the result of the action of molecules analogous to the “killing agents” of neutrophil leukocytes, which rapidly render bacterial envelopes permeable. AcPase, and presumably other hydrolases, are present in the cyanobacterial filament when filament destruction occurs; they thus appear implicated in this process. Hydrolases may activate an autodestruction mechanism in the cyanobacterium. Firm adherence of the food vacuole membrane to the cyanobacterial filament is demonstrated, and its role in phagocytosis is discussed.     

免疫酶技术鉴定 El Tor 型霍乱弧菌稳定 L 型

细菌稳定 L 型的形态、培养特性以及生化反应常与原菌不同,其菌落在盐水中不能乳化,故不能通过玻片凝集测定其抗原。对于这种一时不能回复为原菌的 L 型很难进行鉴定。本文采用免疫酶技术对由鳝鱼和鲫鱼胆汁诱导的 El Tor 型霍乱弧菌稳定 L 型进行了鉴定。实验证明 L 型的细胞壁可有不同程度的缺失,稳定 L 型仍可能有少量“O”抗原存在。PAP 法比较敏感,即使少量抗原亦可以检出。     

Ultrastructure of LLR-mutants of E. coli K12]

The author studied the ultrastructure of two spherical E. coli K12 mutants (llr) obtained under the effect of N-nitroso-N-methylurea. Seven morphological types of cells differing from one another by shape, size and cytoarchitectonics were distinguished. Superficial structures of the majority of the cells were represented by the membranes of the cell wall and the cytoplasmic membrane of common structure. Some of the cells had only one membrane coat and a high electron optic density of the cytoplasm. Transitional forms of cells were also encountered. The ultrastructure of each morphological type in the population of the llr-mutants was described in detail. The capacity of the mutants to vacuolization, to the intra- and extracellular budding, and also the ability to form multiple membrane structures resembled analogous structures of stable L-forms of the Gram-negative microbes. The problems of morphological differentiation of the L-forms and of the llr-mutants, and also problems connected with the formation of the multiple membrane structures and small elemental bodies in the cells of the llr-mutants are discussed.     

Intracellular vesicles as reproduction elements in cell wall-deficient L-form bacteria

Cell wall-deficient bacteria, or L-forms, represent an extreme example of bacterial plasticity. Stable L-forms can multiply and propagate indefinitely in the absence of a cell wall. Data presented here are consistent with the model that intracellular vesicles in Listeria monocytogenes L-form cells represent the actual viable reproductive elements. First, small intracellular vesicles are formed along the mother cell cytoplasmic membrane, originating from local phospholipid accumulation. During growth, daughter vesicles incorporate a small volume of the cellular cytoplasm, and accumulate within volume-expanding mother cells. Confocal Raman microspectroscopy demonstrated the presence of nucleic acids and proteins in all intracellular vesicles, but only a fraction of which reveals metabolic activity. Following collapse of the mother cell and release of the daughter vesicles, they can establish their own membrane potential required for respiratory and metabolic processes. Premature depolarization of the surrounding membrane promotes activation of daughter cell metabolism prior to release. Based on genome resequencing of L-forms and comparison to the parental strain, we found no evidence for predisposing mutations that might be required for L-form transition. Further investigations revealed that propagation by intracellular budding not only occurs in Listeria species, but also in L-form cells generated from different Enterococcus species. From a more general viewpoint, this type of multiplication mechanism seems reminiscent of the physicochemical self-reproducing properties of abiotic lipid vesicles used to study the primordial reproduction pathways of putative prokaryotic precursor cells.     

Induction, growth and antibiotic production of Streptomyces viridifaciens L-form bacteria

AIMS: To induce, cultivate and investigate the characteristics of L-form bacteria derived from the filamentous actinomycete Streptomyces viridifaciens. METHODS AND RESULTS: L-forms were induced in a liquid medium supplemented with lysozyme and penicillin. A stable culture which no longer required inducing agents but could still revert, was obtained by the twelfth subculture. The specific growth rate of stable L-forms was faster (0.751) than unstable L-forms (0.361). After the exponential growth phase, the cell diameter continued to increase, as did the percentage of vacuoles. Morphologically, the L-forms appeared as spherical bodies with no signs of differentiation and were sensitive to osmotic stress, indicating removal of the cell wall. The L-forms produced secondary metabolites although much lower levels of antibiotic were assayed in the L-forms compared with the cell walled forms. CONCLUSION: Stable L-form bacteria were induced from S. viridifaciens and their growth characterized. The L-forms produced secondary metabolites. SIGNIFICANCE AND IMPACT OF THE STUDY: Stable Streptomyces L-forms were induced and have potential as biocontrol agents.     

Ultrastructure of the cell surface of heteromorphic Nostoc muscorum CALU 304 cocultured with Rauwolfia tissue]

The ultrastructure of the heteromorphic cells (HMCs) of the cyanobacterium Nostoc muscorum CALU 304 grown in pure culture, monoculture, and a mixed culture with the Rauwolfia callus tissue was studied. The comparative analysis of the cell surface of HMCs, the frequency of the generation of cell forms with defective cell walls (DCWFs), including protoplasts and spheroplasts, and the peculiarities of the cell surface ultrastructure under different growth conditions showed that, in the early terms of mixed incubation, the callus tissue acts to preserve the existing cyanobacterial DCWFs, but begins to promote their formation in the later incubation terms. DCWFs exhibited an integrity of their protoplasm and were metabolically active. It is suggested that structural alterations in the rigid layer of the cell wall may be due to the activation of the murolytic enzymes of cyanobacteria and the profound rearrangement of their peptidoglycan metabolism caused by the Rauwolfia metabolites diffused through the medium. These metabolites may also interfere with the functioning of the universal cell division protein of bacteria, FtsZ. In general, the Rauwolfia callus tissue promoted the unbalanced growth of the cyanobacterium N. muscorum CALU 304 and favored its viability in the mixed culture. The long-term incubation of the Rauwolfia tissue with the N. muscorum CALU 304 cells led to their transformation to L-forms.     

Submicroscopic structure of the streptococcal L forms isolated from a living body]

The authors studied in the L-forms of streptococcus induced in the living organism. Submicroscopic structure of the L-forms under study was analogous to the L-forms of the museum streptococcus strain and to the L-forms of some other bacteria. As revealed on the ultra-thin sections of the protoplast-like cells the intracytoplasmic membrane structures were located close to the cytoplasmic membrane and also passed through the whole cell in the form of a band. The latter was in contact with the nucleotide. The elemental bodies were found in the vesicular and the protoplastic cells, and also in the space between the cells; sometimes they formed groups surrounded by a membrane.     

Nuclear and cell division in Bacillus subtilis: cell development from spore germination.

The changes in the morphology of the nucleoids and the mesosomes in Bacillus subtilis cells during synchronous outgrowth after spore germination were followed in large-scale three-dimensional cell reconstructions. Shortly after outgrowth of the cell begins in Spizizen medium with glucose, the mesosome becomes an elongated structure in close contact with a rounded nucleoid. When nuclear replication reaches full activity, the mesosome develops into a single, complicated versatile system, with tubules that traverse the cytoplasm and have elaborations in and near the nucleoplasm. Later the system may retract to form large rounded mesosomes; the tubules and strings of vesicles within these mesosomes probably have been collected from the cytoplasm. Shortly after the first cell division, both sister cells have two nucleoids, but with longer generation times induced by growth in media containing acetate instead of glucose; these sister cells have only one nucleoid each. In acetate-grown cells rounded nucleoids that have no contact with a mesosome may represent nucleoids in a temporary stage of rest. On the other hand, the nucleoids of cells growing in glucose-containing medium are always penetrated by mesosomal material, superficially or deeply. Since the mesosome appears capable of traversing the nuclear fibrils, and even reaching the last strands connecting the dividing nucleoids, it is suggested that this organelle may play a vital role in the Bacillus division cycle.     

细胞壁缺陷细菌生物氧化特性的观察

The L-forms were induced from Staphylococcus aureus,Escherichia coli and Bacdtos cereus by β-lactam anhbiohcs and then observahons on the proPenies of oxygen requlrement sugar fermentahon and sensihve tO cyanide of the Lforms were done. The resultS were shown that the Lforms derived from the obligate aerobe or the faCultative anaerobe did not ferment sugars and were highly oxygendePendent and more sensihve tD cyedde than their Parent bacteria The metabolic achvihes which were same as the Parent bacteria of …     

Surface Ultrastructure of the Heteromorphic Cells of Nostoc muscorumCALU 304 in a Mixed Culture with the RauwolfiaCallus Tissue

The ultrastructure of the heteromorphic cells (HMCs) of the cyanobacterium Nostoc muscorumCALU 304 grown in pure culture, monoculture, and a mixed culture with the Rauwolfiacallus tissue was studied. The comparative analysis of the cell surface of HMCs, the frequency of the generation of cell forms with defective cell walls (DCWFs), including protoplasts and spheroplasts, and the peculiarities of their ultrastructure under different growth conditions showed that, in the early terms of mixed incubation, the callus tissue acts to preserve the existing cyanobacterial DCWFs, but begins to promote their formation in the later incubation terms. DCWFs exhibited an integrity of their protoplasm and were metabolically active. It is suggested that structural alterations in the rigid layer of the cell wall may be due to the activation of the murolytic enzymes of cyanobacteria and the profound rearrangement of their peptidoglycan metabolism caused by the Rauwolfiametabolites diffused through the medium. These metabolites may also interfere with the functioning of the universal cell division protein of bacteria, FtsZ. In general, the Rauwolfiacallus tissue promoted the unbalanced growth of the cyanobacterium N. muscorumCALU 304 and favored its viability in the mixed culture. The long-term mixed cultivation substantially augmented the probability of the formation of L-forms of N. muscorumCALU 304.     

Bacterial L-forms on tap: an improved methodology to generate Bacillus subtilis L-forms heralds a new era of research

Bacterial L-forms are cell wall-less forms of bacteria that usually grow with a conventional cell wall. Despite being important for research, L-forms are difficult to generate reproducibly and research in this area is challenging. Domínguez-Cuevas et al. (2011) report a method to rapidly, quantitatively and reproducibly generate populations of L-forms in Bacillus subtilis. Importantly, the methodology may be applicable to other bacteria heralding a new era of L-form research. Moreover, the genetic requirements of this method provide insights into how Lipid II synthesis and autolysin expression/activity are normally balanced and the central role of the WalRK two-component system in this process.     

Lipid composition of Staphylococcus aureus and its derived L-forms.

Two strains of Staphylococcus aureus (Newman and Tazaki) and their derived L-forms were cultured in serum-containing broth and the differences in their lipid compositions were analyzed. Cardiolipin accounted for more than 50% of the total phospholipid phosphorus in L-forms, but for less than 25% in parent bacteria. The cardiolipin content of L-forms was very high through all growth phases, although it increased gradually as growth proceeded. Significant amounts of cholesterol and its esters were present in parent strains and L-forms, all of which incorporated serum cholesterol into the cell membrane. On the other hand, they could be detected in the L-forms but not in the parent strains when they were cultured in serum-free broth. To examine the ability of L-forms to synthesize cholesterol, the cholesterol content of L-forms cultured in serum-free broth was compared with that of the medium. The results indicated that staphylococcal L-forms could synthesize cholesterol and its esters. These differences in lipid composition suggested that modification of membrane lipids may occur as an adaptational change in response to the disappearance of the cell wall.     

Studies on the compaction of isolated nucleoids from Escherichia coli

The genomic DNA of Escherichia coli is contained in one or two compact bodies known as nucleoids. Isolation of typically shaped nucleoids requires control of DNA expansion, accomplished here by a modification of the polylysine-spermidine procedure. The ability to control expansion of in vitro nucleoids has application in nucleoid purification and in preparation of samples for high-resolution imaging, and may allow an increased resolution in gene localization studies. Polylysine of relatively low average molecular weight (approximately 3 kDa) is used to produce lysates containing nucleoids that are several-fold expanded relative to the sizes of in vivo nucleoids. These expanded forms can be converted to compact forms similar in dimensions to the cellular nucleoids by either a further addition of polylysine or by incubation of diluted lysates at 37 degrees C. The incubation at 37 degrees C is accompanied by autolytic degradation of most ribosomal RNA. Hyperchromism and circular dichroism spectra indicate that polylysine-DNA complexes are modified during the incubation. Compact forms of the nucleoid can be progressively reexpanded by exposure to salt solutions. Nucleoid compaction was similar in lysates made from rapidly or slowly growing cells or from cells that had been briefly treated with chloramphenicol to reduce linkages between DNA and cell envelope.     

铜绿假单胞菌及L型诱导巨噬细胞凋亡的实验研究

目的研究铜绿假单胞菌（PA）及L型诱导巨噬细胞凋亡的能力,比较二者的差异。方法用生物素断端标记（TUNEL）法检测PA及L型感染巨噬细胞2、4、8、12、16和20h后各时间段的细胞凋亡率,Giemsa染色观察细胞凋亡情况,硝酸还原酶法检测培养液中一氧化氮（NO）的浓度变化。结果 PA及L型能诱导巨噬细胞发生凋亡,与对照组比较差异有统计学意义（P〈0.05）;L型诱导细胞的凋亡率弱于原菌（P〈0.05）;PA及L型感染组培养液NO浓度较对照组明显升高（P〈0.05）。结论 PA及L型可诱导巨噬细胞发生凋亡,L型较其原型诱导细胞凋亡的能力弱,NO可能在巨噬细胞凋亡中发挥一定作用。PA及L型可通过诱导巨噬细胞凋亡,发挥致病作用。     

Cellular ultrastructure of the meningococcus when incubated in a continuous culture of human FL-line amnion

Some details of the ultrastructure of several meningococcal strains having had contacts with cells in continuous human amnion cell culture FL for 6 hours to 2 days have been defined with greater precision by means of electron microscopy. The study has shown that the contact of meningococci with the tissue culture is accompanied by the appearance of meningococcal forms with the defective cell wall, similar to L-forms: spheroplast, protoplast, gigantic cells and microcells, as well as budding variants. The meningococcal variants with the defective cell wall, appearing in the cell culture, and the forms occurring (in different proportions) in "ripe" meningococcal populations developing in the culture media for a long time and isolated from a human body have been found to have no essential differences in their fine structure. These data indicate that any external influences (meningococci are highly sensitive to such influences) produce sufficiently rapid changes, similar to L-transformation, in the fine structure of these microorganisms.