Staphylococcal Cell Wall: Morphogenesis and Fatal Variations in the Presence of Penicillin

The primary goal of this review is to provide a compilation of the complex architectural features of staphylococcal cell walls and of some of their unusual morphogenetic traits including the utilization of murosomes and two different mechanisms of cell separation. Knowledge of these electron microscopic findings may serve as a prerequisite for a better understanding of the sophisticated events which lead to penicillin-induced death. For more than 50 years there have been controversial disputes about the mechanisms by which penicillin kills bacteria. Many hypotheses have tried to explain this fatal event biochemically and mainly via bacteriolysis. However, indications that penicillin-induced death of staphylococci results from overall biochemical defects or from a fatal attack of bacterial cell walls by bacteriolytic murein hydrolases were not been found. Rather, penicillin, claimed to trigger the activity of murein hydrolases, impaired autolytic wall enzymes of staphylococci. Electron microscopic investigations have meanwhile shown that penicillin-mediated induction of seemingly minute cross wall mistakes is the very reason for this killing. Such “morphogenetic death” taking place at predictable cross wall sites and at a predictable time is based on the initiation of normal cell separations in those staphylococci in which the completion of cross walls had been prevented by local penicillin-mediated impairment of the distribution of newly synthesized peptidoglycan; this death occurs because the high internal pressure of the protoplast abruptly kills such cells via ejection of some cytoplasm during attempted cell separation. An analogous fatal onset of cell partition is considered to take place without involvement of a detectable quantity of autolytic wall enzymes (“mechanical cell separation”). The most prominent feature of penicillin, the disintegration of bacterial cells via bacteriolysis, is shown to represent only a postmortem process resulting from shrinkage of dead cells and perturbation of the cytoplasmic membrane. Several schematic drawings have been included in this review to facilitate an understanding of the complex morphogenetic events.     

Penicillin-induced changes in the cell wall composition of Staphylococcus aureus before the onset of bacteriolysis

To analyze if chemical cell wall alterations contribute to penicillin-induced bacteriolysis, changes in the amount, stability, and chemical composition of staphylococcal cell walls were investigated. All analyses were performed before onset of bacteriolysis i.e. during the first 60 min following addition of different penicillin G doses. Only a slight reduction of the amount of cell wall material incorporated after penicillin addition at the optimal lytic concentration was observed as compared to control cells. However, the presence of higher penicillin G concentrations reduced the incorporation of wall material progressively without bacteriolysis. Losses of wall material during isolation of dodecylsulfate insoluble cell walls were monitored to assess the stability of the wall material following penicillin addition. Wall material grown at the lytic penicillin concentration was least stable but about 30% of the newly incorporated wall material withstood even the harsh conditions of mechanical breakage and dodecylsulfate treatment. Dodecylsulfate insoluble cell walls were used for chemical analyses. While peptidoglycan chain length was unaffected in the presence of penicillin, other wall parameters were considerably altered: peptide cross-linking was reduced in the wall material synthesized after addition of penicillin; reductions from approx. 85% in controls to about 60% were similar for lytic and also for very high penicillin concentrations leading to nonlytic death. O-acetylation was also reduced after treatment with penicillin; this effect paralleled the occurence of subsequent bacteriolysis at different drug concentrations. The results are not consistent with hypotheses explaining penicillin-induced lysis as a result of an overall weakened cell wall structure or an overall activation of autolytic wall enzymes but not conflicting with the model that ascribes penicillin-induced bacteriolysis as the result of a very restricted, local perforation of the peripheral cell wall (murosome-induced bacteriolysis).Abbreviations CL Cross-linking - DNFB 2,4-dinitro-1-fluorobenzole - MIC Minimal inhibitory concentration - OD Optical density at 578 nm - PEN Penicillin G     

A special morphogenetic wall defect and the subsequent activity of “murosomes” as the very reason for penicillin-induced bacteriolysis in staphylococci

The actual reason for the penicillin-induced bacteriolysis of staphylococci was shown to be the punching of one or a few minute holes into the peripheral cell wall at predictable sites. These perforations were the result of the lytic activity of novel, extraplasmatic vesicular structures, located exclusively within the bacterial wall material, which we have named murosomes.In untreated staphylococci the punching of holes into the peripheral wall is a normal process which follows cross wall completion and represents the first visible step of cell separation. Under penicillin, however, analogous holes are punched by the murosomes at sites of presumptive cell separation even if no sufficient cross wall material had been assembled before at this site (but had rather been deposited at other sites). Consequently, because of the internal pressure of the protoplast, lytic death is the inevitable result of this perforation of the protective peripheral wall.Hence, the real mechanism of penicillin-induced bacteriolysis in staphylococci is considered to be mainly the result of a special morphogenetic wall defect: bacteriolysis is taking place regularly when a cell separation process is no longer preceeded by sufficient cross wall assembly at the correct place. However, hypotheses which are based purely on some variations of overall biochemical processes like total wall enzyme activities or total wall synthesis are not regarded to be sufficient to explain this type of lytic death.Dedicated to Prof. Dr. Gerhart Drews on the occasion of his 60th birthday     

Fan-shaped ejections of regularly arranged murosomes involved in penicillin-induced death of staphylococci.

Electron microscopic research into the murosomes of staphylococci has shown that the number of murosomes involved in penicillin-induced death varies depending on the experimental conditions employed. With 0.1 micrograms of penicillin G per ml, only 1 of a total of about 20 murosomes, the "killing murosome," completely perforated the pressure-stabilized peripheral cell wall during a three-step process. This strictly localized event was mainly attributed to a mechanical effect being comparable to the process of aneurysm formation. Wall perforation was also considered to mark the very moment of penicillin-induced death ("nonlytic killing event"), while bacteriolysis started only postmortem. By varying the osmolarity of the growth medium, the number of murosomes involved in penicillin-induced killing increased considerably, which resulted in the ejection of a fan-shaped row of murosomes at the second division plane. These data are compatible with the finding that, in untreated or chloramphenicol-treated staphylococci, the activation of the murosomes resulted in (i) the formation of regularly arranged "blebs" on the cell surface, containing traces of disintegrated wall material, and (ii) the subsequent liberation of the murosomes lying underneath, leaving behind their former sites in the peripheral wall as a row of regularly arranged "pores" in every division plane. The number, distribution, and positioning of these blebs corresponded with those of the pores and the original murosomes. The significance of wall autolysins liberated from the first division plane for penicillin-induced wall perforation at the second division plane is discussed.     

Neither an enhancement of autolytic wall degradation nor an inhibition of the incorporation of cell wall material are pre-requisites for penicillin-induced bacteriolysis in staphylococci

In contrast to what has been postulated, penicillin G at its optimal lytic concentration of 0.1 g per ml did not lead to a detectable activation of autolytic wall processes in staphylococci in terms of the release of uniformly labelled wall fragments from cells pretreated with the drug for 1 h. Rather a considerable inhibition of this release was observed. A similarly profound inhibition of the release of peptidoglycan fragments occurred when staphylococci pretreated for 1 h with 0.1 g penicillin per ml acted as a source of crude autolysins on peptidoglycan isolated from labelled normal cells of the same strain. This clearly demonstrated that the overall inhibition of autolytic wall processes caused by penicillin was mainly due to a decreased total autolysin action rather than to an altered wall structure. Furthermore, no substantial penicillin-induced inhibition of the incorporation of ¹⁴C-N-acetylglucosamine into the staphylococcal wall could be observed before bacteriolysis started, i. e., approximately during the first 80 min of penicillin action. These results are not consistent with any of the models hitherto proposed for the action of penicillin.Dedicated to Prof. Dr. Gerhart Drews on the occasion of his 60th birthday     

The cell cycle of<Emphasis Type="Italic">Chlamydomonas reinhardtii</Emphasis>: the role of the commitment point

Chlamydomonas reinhardtii cells can double their size several times during the light period before they enter the division phase. To explain the role of the commitment point (defined as the moment in the cell cycle after which cells can complete the cell cycle independently of light) and the moment of initiation of cell division we investigated whether the timing of commitment to cell division and cell division itself are dependent upon cell size or if they are under control of a timer mechanism that measures a period of constant duration. The time point at which cells attain commitment to cell division was dependent on the growth rate and coincided with the moment at which cells have approximately doubled in size. The timing of cell division was temperature-dependent and took place after a period of constant duration from the onset of the light period, irrespective of the light intensity and timing of the commitment point. We concluded that at the commitment point all the prerequisites are checked, which is required for progression through the cell cycle; the commitment point is not the moment at which cell division is initiated but it functions as a checkpoint, which ensures that cells have passed the minimum cell size required for the cell division.     

A novel, “hidden” penicillin-induced death of staphylococci at high drug concentration,occurring earlier than murosome-mediated killing processes

In log-phase cells of staphylococci, cultivated under high, non-lytic concentrations of penicillin G, there occurred a novel killing process hitherto hidden behind seemingly bacteriostatic effects. Two events are essential for the apprearance of this hidden death: (i) the failure of the dividing cell to deposit enough fibrillar cross-wall material to be welded together, and (ii) a premature ripping up of incomplete cross walls along their splitting system. Hidden death started as early as 10–15 min after drug addition, already during the first division cycle. It was the consequence of a loss of cytoplasmic constituents which erupted through peripheral slit-like openings in the incomplete cross walls. The loss resulted either in more or less empty cells or in cell shrinkage. These destructions could be prevented by raising the external osmotic pressure. In contrast, the conventional non-hidden death occurred only much later and exclusively during the second division cycle and mainly in those dividing cells, whose nascent cross walls of the first division plane had been welded together. These welding processes at nascent cross walls, resulting in tough connecting bridges between presumptive individual cells, were considered as a morphogenetic tool which protects the cells, so that they can resist the otherwise fatal penicillin-induced damages for at least an additional generation time (morphogenetic resistance system). Such welded cells, in the virtual absence of underlying cross-wall material, lost cytoplasm and were killed via ejection through pore-like wall openings or via explosions in the second division plane and after liberation of their murosomes, as it was the case in the presence of low, lytic concentrations of penicillin. Bacteriolysis did not cause any of the hitherto known penicillin-induced killing processes.Dedicated to Prof. Dr. Georg Henneberg on the occasion of his 85th birthday     

SYNCHRONOUS CULTURE OF CHLORELLA: I. KINETIC ANALYSIS OF THE LIFE CYCLE OF CHLORELLA ELLIPSOIDEA AS AFFECTED BY CHANGES OF TEMPERATURE AND LIGHT INTENSITY

1. Using the technique of synchronous culture, investigationsweremade of the effects of temperature and light-intensityon cellularlife cycle of Chlorella ellipsoidea. Some improvementsin theculture technique for obtaining a good synchrony of algalgrowthwere described.
2. By following the changes of averagecell volume and cell numberoccurring during culturing, therates of the following processesof life cycle were determined:(i) "growth" (or the increasein cell mass) occurring from thestage of smaller cells (D_a)to the stage of ripened cell (L₃),(ii) "ripening" (or processofformation of "nuclear substances"as estimated from the averagenumber of daughter cells formedfrom single mother cell), and(iii) " maturing and division" which leads to the full maturationof mother cells (L-cells)and their division into separate daughtercells (D-cells).
3. "Growth"and "ripening" were found to be dependent in light,"maturingand division" light-independent. The time requiredfor "growth"and "ripening" (C) is dependent on temperaturebut independentof light intensity, the onset of "maturing anddivision" occurringat the same time (D) of culturing undervaried light intensities.The average cell volume at this stage(L₃),however, was foundto be markedly modified by light intensity;larger with highertemperatures (see Fig. 4).
4. Changes in incubation temperature(under the condition of saturatinglight intensities) were foundto affect the life cycle in thefollowing way: (i) The timeof onset of "maturing and division"(D), varies markedly withculturing temperature; earlier athigher temperatures, (ii)The average cell volume at this stagealso depends on temperature; smaller at higher temperatures.
5. The average number of daughtercells (n) emerging from singlemother cells, was found to beuninfluenced by culturing temperature;(4.0–4.1 underthe conditions of the present study). Itwas found that thedivision number n is remarkably varied bychanging the lightintensity in the "growth" and "ripening"phases; 2.0 at 1 kilolux,3.7 at 5 kilolux, 4.2 at saturatinglight intensities (10 and25 kilolux). This finding was explainedby assuming a light-dependentformation of "nuclear substances"during the "growth" and "ripening"phases, the quantity of thesubstances in the cell at L₃ stagedeterminig the division number.
6. The experimental data wereanalyzed reaction kinetically, therate constants and othercharacteristics of the reactions constitutingthe processesof life cycle were determined, and values forthe apparent activationenergy for each reaction were computed.The reactions were discussedwith special reference to theirrelationship with photosyntheticprocess was discussed.

(Received November 7, 1959; )     

Regulation of Cell Division in Escherichia coli: Characterization of Temperature-Sensitive Division Mutants

A temperature-sensitive division mutant of Escherichia coli was isolated by using differential filtration to select for filaments at 42 C and normal cells at 30 C. Cells shifted from 30 to 42 C stop dividing almost immediately, suggesting the temperature-sensitive element is required for cell division late in the cell cycle. Cells returned to 30 from 42 C divide abruptly, suggesting accumulation of division potential at 42 C. Inhibitors of protein, deoxyribonucleic acid, and ribonucleic acid synthesis do not block division during the recovery period at 30 C. Cycloserine does not stop cell division, vancomycin shows some effect on cell division, whereas penicillin completely stops cell division during this period. The addition of high concentrations of NaCl to filaments at 42 C results in a burst of cell division. The final cell number is equivalent to the control which is grown at 30 C if sufficient salt is added (11 g/liter, final concentration). After the original burst, cell division ceases at the nonpermissive temperature even at increased osmolality. Chloramphenicol, puromycin, vancomycin, and penicillin prevent division during the recovery in the presence of NaCl. Kinetic data indicate division potential decays to a reversible inactive intermediate which rapidly decays to an irreversible inactive form. Conversion of division potential to the inactive form is correlated with a 100- to 1,000-fold derepression of the synthesis of division potential. The mutation appears to involve a stage in cross-wall synthesis which is required during the terminal stages of division.     

Anisomorphic cell division by African trypanosomes

In the bloodstream of a mammalian host, African trypanosomes are pleomorphic; the shorter, non-proliferative, stumpy forms arise from longer, proliferative, slender forms with differentiation occurring via a range of morphological intermediates. In order to investigate how the onset of morphological change is co-ordinated with exit from the cell cycle we first characterized slender form cell division. Outgrowth of the new flagellum was found to occur at a linear rate, so by using outgrowth of the new flagellum as a temporal marker of the cell cycle we were able determine the order in which single copy organelles (nucleus, kinetoplast and mitochondrion) were segregated. We also found that flagellar length was an effective marker of the slender to stumpy differentiation and were, therefore, able to study both cell division and differentiation. When these differentiating cells were compared to cells undergoing proliferative cell division, they were found to be anisomorphic – showing discernible differences not only in the length of their new flagella but also in the shape and size of the cells and their nuclei.     

Flow cytometric studies of the host-regulated cell cycle in algae symbiotic with green paramecium

Summary. Paramecium bursaria (green paramecium) possesses endosymbiotically growing chlorella-like green algae. An aposymbiotic cell line of P. bursaria (MBw-1) was prepared from the green MB-1 strain with the herbicide paraquat. The SA-2 clone of symbiotic algae was employed to reinfect MBw-1 cells and thus a regreened cell line (MBr-1) was obtained. The regreened paramecia were used to study the impact of the hosts growth status on the life cycle of the symbiotic algae. Firstly, the relationship between the timing of algal propagation and the host cell division was investigated by counting the algal cells in single host cells during and after the host cell division and also in the stationary phase. Secondly, the changes in the endogenous chlorophyll level, DNA content, and cell size in the symbiotic algae were monitored by flow cytometry and fluorescence microscopy. The number of algae was shown to be doubled prior to or during the host cell division and the algal population in the two daughter cells is maintained at constant level until the host cell cycle reenters the cytokinesis, suggesting that algal propagation and cell cycle are dependent on the hosts cell cycle. During the hosts stationary growth, unicellular algal vegetatives with low chlorophyll content were dominant. In contrast, complexes of algal cells called sporangia (containing 1–4 autospores) were present in the logarithmically growing hosts, indicating that algal cell division leading to the formation of sporangia with multiple autospores is active in the dividing paramecia.Correspondence and reprints: Graduate School of Environmental Engineering, University of Kitakyushu, 1-1 Hibikino, Wakamatsu-ku, 808-0135 Kitakyushu, Japan.     

Radiosensitivity of Mammalian Cells: I. Timing and Dose-Dependence of Radiation-Induced Division Delay

The time of onset and duration of division delay induced by exposure to 250-kvp x-irradiation have been measured in several mammalian cell lines grown in suspension culture. Unique times of action (i.e. interval from irradiation to cessation of division) late in G₂ are characteristic for HeLa, L-5178Y, and Chinese hamster cells, and the time of action is independent of dose over the range 25-800 rads. The duration of delay was directly proportional to dose; all irradiated cells divided at least once and maintained their relative positions in the life cycle for periods exceeding one generation time. Neither random nor synchronous cultures exposed at varying times in the life cycle exhibited differences in radiation sensitivity measured either by onset or duration of the delay period. The time of action was experimentally indistinguishable from the point marking completion of protein synthesis essential for division, leading to speculation that division delay involves a translation defect.     

Influence of penicillin and nalidixic acid on growth and cell division of Escherichia coli K-12

Ultrastructure of E. coli K-12 cells and the synthesis of DNA in bacteria treated with low concentration of nalidixic acid and penicillin was investigated. In E. coli both drugs caused inhibition of cell division in period D of the life cycle although nalidixic acid inhibits division at an earlier stage of septum formation. The ability of cells to form filaments in the presence of nalidixic acid depends on their age, i.e. time at which cells are taken from synchronous culture.     

Centriole inheritance

Early cell biologists perceived centrosomes to be permanent cellular structures. Centrosomes were observed to reproduce once each cycle and to orchestrate assembly a transient mitotic apparatus that segregated chromosomes and a centrosome to each daughter at the completion of cell division. Centrosomes are composed of a pair of centrioles buried in a complex pericentriolar matrix. The bulk of microtubules in cells lie with one end buried in the pericentriolar matrix and the other extending outward into the cytoplasm. Centrioles recruit and organize pericentriolar material. As a result, centrioles dominate microtubule organization and spindle assembly in cells born with centrosomes. Centrioles duplicate in concert with chromosomes during the cell cycle. At the onset of mitosis, sibling centrosomes separate and establish a bipolar spindle that partitions a set of chromosomes and a centrosome to each daughter cell at the completion of mitosis and cell division. Centriole inheritance has historically been ascribed to a template mechanism in which the parental centriole contributed to, if not directed, assembly of a single new centriole once each cell cycle. It is now clear that neither centrioles nor centrosomes are essential to cell proliferation. This review examines the recent literature on inheritance of centrioles in animal cells.Key words: centrosome, centriol, spindle, mitosis, microtubule, cell cycle, checkpoints     

Teilungsverhalten der Chromatophoren in bezug auf die Mitose während des Lebenszyklus vonDiatoma hiemale var.mesodon

The vegetative life cycle ofDiatoma hiemale var.mesodon (Ehr.)Grun. living in a spring has been studied under natural conditions. In the beginning the cells have a constant number of 8 chromatophores which are divided into 16 during cell growth. Chloroplast division is finished before nuclear division starts. The young daughter cells have again 8 chromatophores. In the course of cell division a plastic remodelling of the chromatophores and a simplifying of their shape occurs. Besides single cells also populations have been studied to follow the temporal progress of chromatophore division, mitosis and cell growth. The results are evaluated by indices and demonstrated by a diagram. The maximum of chromatophore divisions preceds the maximum of mitoses by several hours, while the cell growth is in correlation with the chromatophore division. Minima of the other parameters were found before mitosis is starting and after it is finished. Our results are discussed with regard to the semiautonomy of the plastids. From the morphological point of view this concept is supported by the mode of division and by the anticipation of the chromatophore division. The number of chromatophores at the beginning (8) and at the end (16) of the life cycle is constant. The life cycle is classified into stages of cell growth, chromatophore division, stagnation, mitosis and differentiation of the daughter cells.     

Inductive and Inhibitory Effects of Light on Cell Division in Chattonella antiqua

The cell division of a red tide flagellate, Chattonella antiqua,was synchronously induced under light and dark regimes of 10L14D(a light period, L, for 10 h followed by a dark period, D, for14 h), 12L12D and l4L10D. In all regimes cell number began toincrease ca. 14 h after the onset of L and almost doubled duringone LD cycle. When the light-off timing of the last L was changedor the whole L was shifted, cells that had been synchronizedunder 12L12D invariably began to divide ca. 14 h after the onsetof L. This shows that the timing of cell division was determinedby the time of the onset of L. When cells were continuously exposed to light after a cell division,the subsequent cell division was inhibited. This effect waslimited to cells that had been synchronized under short-dayconditions. Thus it can be concluded that light has both inductive and inhibitoryeffects on cell division in this alga, the latter effect dependingupon the previously given light and dark regimes. (Received December 21, 1984; Accepted February 28, 1985)     

Towards understanding the control of the division cycle in animal cells.

The author reviewed the historical process by which classical knowledge of cell division accumulated, to give rise to the molecular biology of the cell cycle, and discussed the perspective of this field of research. The study of the control of cell division began at the turn of the century. It was hypothesized that cell division was a physiological regulation necessary for growing cells to maintain a proper nucleocytoplasmic ratio to survive, which was later substantiated by the finding that amoeba cells could be prevented from dividing by repeated excision of the cytoplasm. However, the observation in Tetrahymena that heat-shocked cells grow exceedingly, but fail to divide, suggested that the cell required the accumulation of a labile "division protein" to initiate division. Mechanisms that control the cell cycle were studied in oocytes by nuclear transplantation and cytoplasmic transfer, and in cultured mammalian cells, protozoa, and Physarum plasmodia by cell fusion. These experiments demonstrated the existence of cytoplasmic factors that control the cell cycle. Maturation promoting factor (MPF) thus discovered in frog oocytes became known to be an ubiquitous cytoplasmic factor that causes the transition from interphase to metaphase in all organisms. The insight into the molecular control of cell growth and division was gained from yeast cell genetics. For biochemical analysis of the cell cycle control, the method to observe the cell cycle in vitro was developed using frog egg extracts. Thus, MPF was identified as a cdc2--cyclin protein complex. Its activity was found to depend on synthesis and phosphorylation of these proteins. However, recently it was found that there were cell cycle phenomena that were difficult to explain in these terms. Various other cellular factors, including nucleocytoplasmic ratio and microtubule assembly, were also found to control MPF, as well as the cell cycle. It remained open to future how these factors control MPF to alter the pattern of the cell cycle.     

Requirement of a cell division step for stalk formation in Caulobacter crescentus.

Penicillin G at low concentrations blocked cell division in Caulobacter crescentus without inhibiting cell growth. The long filamentous cells formed after two to three generations under these conditions had a stalk at one pole and usually one or more flagella at the opposite pole. The failure of the filaments to form a second stalk at the flagellated pole indicates that stalk formation was dependent upon completion of a step that was also required for cell division. Two observations support this conclusion. (i) Penicillin did not stop the normal development of synchronous swarmer cells into stalked initiation and stalk elongation. (ii) When the action of penicillin was reversed by the addition of penicillinase to cultures of filaments, stalks were not formed at the nonstalked pole until after cell division had occurred; thus the normal order of development events was maintained: cell division leads to stalk formation. These results are consistent with a model in which the organization of the developmental program for stalk formation occurs before cell division as a consequence of steps that branch from the cell division pathway.     

Photoperiodic Regulation of Cell Division and Chloroplast Replication in Heterosigma akashiwo

Cell division and chloroplast replication in Heterosigma akashiwo(Hada) Hada occurred as separate synchronous events during thecell cycle when cells were subjected to light-dark regimes.Under three different photoperiodic cycles of 10L/14D (10 hlight/14 h dark), 12L/12D or 16L/8D, cell division began athour 19–20 and finished at hour 23–26 after theonset of the light period, while chloroplast replication beganat hour 20–22 after the onset of the dark period. Almostall the cells divided only once in the 12L/12D cycle. The rateof increase in chloroplast number during one light-anddark cyclewas always equal to that in cell number in every photoperiodexamined. Light was essential for both cell division and chloroplast replication,but the minimum light period necessary for each event differed.When the light period was shorter than 6 h, no cell divisionoccurred; when it was shorter than 3 h, no chloroplast replicationoccurred. (Received February 26, 1987; Accepted June 17, 1987)