Regulation of fetal hemoglobin expression during hematopoietic stem cell development and its importance in bone metabolism and osteoporosis.

We have shown that an altered tissue redox environment in mice lacking either murine beta Hemoglobin major (HgbßmaKO) or minor (HgbßmiKO) regulates inflammation. The REDOX environment in marrow stem cell niches also control differentiation pathways. We investigated osteoclastogenesis (OC)/osteoblastogenesis (OB), in bone cultures derived from untreated or FSLE-treated WT, HgbßmaKO or HgbßmiKO mice. Marrow mesenchymal cells from 10d pre-cultures were incubated on an osteogenic matrix for 21d prior to analysis of inflammatory cytokine release into culture supernatants, and relative OC:OB using (TRAP:BSP, RANKL:OPG) mRNA expression ratios and TRAP or Von Kossa staining. Cells from WT and HgbßmaKO mice show decreased IL-1ß,TNFα and IL-6 production and enhanced osteoblastogenesis with altered mRNA expression ratios and increased bone nodules (Von Kossa staining) in vitro after in vivo stimulation of mRNA expression of fetal Hgb genes (Hgbε and Hgbßmi) by a fetal liver extract (FSLE). Marrow from HgbßmiKO showed enhanced cytokine release and preferential enhanced osteoclastogenesis relative to similar cells from WT or HgbßmaKO mice, with no increased osteoblastogenesis after mouse treatment with FSLE. Pre-treatment of WT or HgbßmaKO, but not HgbßmiKO mice, with other molecules (rapamycin; hydroxyurea) which increase expression of fetal Hgb genes also augmented osteoblastogenesis and decreased cytokine production in cells differentiating in vitro. Infusion of rabbit anti- Hgbε or anti- Hgbßmi, but not anti-Hgbα or anti- Hgbßma into WT mice from day 13 gestation for 3 weeks led to attenuated osteoblastogenesis in cultured cells. We conclude that increased fetal hemoglobin expression, or use of agents which improve fetal hemoglobin expression, increases osteoblast bone differentiation in association with decreased inflammatory cytokine release.

An altered REDOX environment, assisted by over-expression of fetal hemoglobins, protects from inflammatory colitis and reduces inflammatory cytokine expression.

C5BL/6 female mice receiving dextran sodium sulfate in their drinking water develop an acute inflammatory colitis within 7d, with weight loss, histopathologic signs of inflammation, and colonic expression of inflammatory cytokines. In previous studies we have reported that increased inflammatory cytokine expression in aged mice can be attenuated by oral gavage of a crude fetal extract containing glutathione (GSH), MPLA and fetal hemoglobin, or more specifically by injection of a combination of these purified reagents. We speculated that this combination led to an altered tissue redox environment in which the immune response developed, thus regulating inflammation. Accordingly, we used wild-type (WT) C57BL/6 mice, or mice lacking either murine beta Hemoglobin major (HgbßmaKO) or minor (HgbßmiKO) as recipients of DSS in their drinking water, and followed development of colitis both clinically and by inflammatory cytokine production, before/after oral treatment of mice with a crude fetal liver extract. Mice lacking an intact fetal hemoglobin chain (HgbßmiKO) developed severe colitis, with enhanced colonic expression of inflammatory cytokines, which could not be rescued by extract, unlike WT and HgbßmaKO animals. Moreover, disease in both WT and HgbßmaKO animals could also be attenuated by exposure to 5-hydroxymethyl furfural (5HMF), hydroxyurea or rapamycin. The former has been used as an alternative means of stabilizing the conformation of adult hemoglobin in a manner which mimicks the oxygen-affinity of fetal hemoglobin, while we show that both hydroxyurea and rapamycin augment expression of murine fetal hemoglobin chains. Our data suggests there may be a clinical value in exploring agents which alter local REDOX environments as an adjunctive treatment for colitis and attenuating inflammatory cytokine production.

Characterization of an interaction between fetal hemoglobin and lipid A of LPS resulting in augmented induction of cytokine production in vivo and in vitro.

A previously described extract of sheep fetal liver was reported to reverse many of the cytokine changes associated with aging in mice, including an augmented spleen cell ConA-stimulated production of IL-4 and decreased production of IL-2. Similar effects were not seen with adult liver preparations. These changes were observed in various strains of mice, including BALB/c, DBA/2 and C57BL/6, using mice with ages ranging from 8 to 110 weeks. Preliminary characterization of this crude extract showed evidence for the presence of Hb gamma chain, as well as of lipid A of LPS. We show below that purified preparations of sheep fetal Hb, but not adult Hb, in concert with suboptimally stimulating doses of LPS (lipid A), cooperate in the regulation of production of a number of cytokines, including TNFalpha and IL-6, in vitro. Furthermore, isolated fresh spleen or peritoneal cells from animals treated in vivo with the same combination of Hb and LPS, showed an augmented capacity to produce these cytokines on further culture in vitro. Evidence was also obtained for a further interaction between CLP, LPS and fetal Hb itself in this augmented cytokine production. These data suggest that some of the functional activities in the fetal liver extract reported earlier can be explained in terms of a novel immunomodulatory role of a mixture of LPS (lipid A) and fetal Hb.

Tertiary structure of Staphylococcus aureus cell wall murein.

The recently described scaffold model of murein architecture depicts the gram-negative bacterial cell wall as a gel-like matrix composed of cross-linked glycan strands oriented perpendicularly to the plasma membrane while peptide bridges adopt a parallel orientation (B. A. Dmitriev, F. V. Toukach, K. J. Schaper, O. Holst, E. T. Rietschel, and S. Ehlers, J. Bacteriol. 185:3458-3468, 2003). Based on the scaffold model, we now present computer simulation studies on the peptidoglycan arrangement of the gram-positive organism Staphylococcus aureus, which show that the orientation of peptide bridges is critical for the highly cross-linked murein architecture of this microorganism. According to the proposed refined model, staphylococcal murein is composed of glycan and oligopeptide chains, both running in a plane that is perpendicular to the plasma membrane, with oligopeptide chains adopting a zigzag conformation and zippering adjacent glycan strands along their lengths. In contrast to previous models of murein in gram-positive bacteria, this model reflects the high degree of cross-linking that is the hallmark of the staphylococcal cell wall and is compatible with distinguishing features of S. aureus cytokinesis such as the triple consecutive alteration of the division plane orientation and the strictly centripetal mode of septum closure.

The biology of endotoxin.

Endotoxin (lipopolysaccharide, LPS) is the major component of the outer leaflet of Gram-negative bacteria and has profound immunostimulatory and inflammatory capacity. The septic shock syndrome caused by endotoxin still has an unacceptably high mortality rate and, owing to increasing numbers of resistant strains, remains an ongoing threat throughout the world. However, the past years have provided new insights especially into the receptors of the innate immune system that are involved into the recognition of LPS and the initial signal transduction pathways that are engaged after the primary recognition on the cell surface. The knowledge about the molecular basis for the responses to endotoxin may eventually lead to the development of new drugs to fight the fatal effects of bacterial infections.

Bacterial lipopolysaccharides and innate immunity.

Bacterial lipopolysaccharides (LPS) are the major outer surface membrane components present in almost all Gram-negative bacteria and act as extremely strong stimulators of innate or natural immunity in diverse eukaryotic species ranging from insects to humans. LPS consist of a poly- or oligosaccharide region that is anchored in the outer bacterial membrane by a specific carbohydrate lipid moiety termed lipid A. The lipid A component is the primary immunostimulatory centre of LPS. With respect to immunoactivation in mammalian systems, the classical group of strongly agonistic (highly endotoxic) forms of LPS has been shown to be comprised of a rather similar set of lipid A types. In addition, several natural or derivatised lipid A structures have been identified that display comparatively low or even no immunostimulation for a given mammalian species. Some members of the latter more heterogeneous group are capable of antagonizing the effects of strongly stimulatory LPS/lipid A forms. Agonistic forms of LPS or lipid A trigger numerous physiological immunostimulatory effects in mammalian organisms, but--in higher doses--can also lead to pathological reactions such as the induction of septic shock. Cells of the myeloid lineage have been shown to be the primary cellular sensors for LPS in the mammalian immune system. During the past decade, enormous progress has been obtained in the elucidation of the central LPS/lipid A recognition and signaling system in mammalian phagocytes. According to the current model, the specific cellular recognition of agonistic LPS/lipid A is initialized by the combined extracellular actions of LPS binding protein (LBP), the membrane-bound or soluble forms of CD14 and the newly identified Toll-like receptor 4 (TLR4)*MD-2 complex, leading to the rapid activation of an intracellular signaling network that is highly homologous to the signaling systems of IL-1 and IL-18. The elucidation of structure-activity correlations in LPS and lipid A has not only contributed to a molecular understanding of both immunostimulatory and toxic septic processes, but has also re-animated the development of new pharmacological and immunostimulatory strategies for the prevention and therapy of infectious and malignant diseases.

The interaction of human peripheral blood eosinophils with bacterial lipopolysaccharide is CD14 dependent.

Bacterial lipopolysaccharide (LPS, endotoxin) is a ubiquitous component of dust and air pollution and is suspected to contribute after inhalation to an activation of eosinophils in bronchial tissues of asthmatic patients, provoking inflammatory and allergic processes. We were therefore interested in the interaction of eosinophil granulocytes with LPS and have examined the activation of and uptake to human peripheral blood eosinophils by LPS. Eosinophils were stimulated by LPS and the endotoxic component lipid A and the release of tumor necrosis factor alpha (TNF-alpha) and of the eosinophil-specific granule protein eosinophil cationic protein (ECP) was estimated. The results show induction of TNF-alpha and ECP-release by LPS and lipid A in a dose-dependent manner. Anti-CD14 monoclonal antibody (moAb) (clone MEM-18) and the synthetic lipid A partial structure 406 blocked the release of TNF-alpha and ECP by LPS-stimulated eosinophils. Studies with radioactively labeled LPS showed dose-dependent uptake of (3)H-LPS to eosinophils. The (3)H-LPS uptake was found to be specific because preincubation with unlabeled LPS, compound 406 and also anti-CD14 antibodies inhibited uptake of (3)H-LPS to eosinophil granulocytes. By flow cytometry using anti-CD14 moAb and by reverse transcriptase-polymerase chain reaction (RT-PCR) technique, CD14 expression was detectable. Furthermore, messenger RNA (mRNA) expression of Toll-like receptors (TLR) 2 and TLR 4 was detected, indicating the presence of these CD14 coreceptors. The results indicate that eosinophils can take up LPS and can be stimulated by LPS in a CD14-dependent manner. Hence, in addition to allergens, eosinophils interact with endotoxin, a process that possibly exacerbates ongoing inflammatory and allergic processes.

Molecular mechanics of the mycobacterial cell wall: from horizontal layers to vertical scaffolds.

Current models depicting the structural organization of the mycobacterial cell wall assume peptidoglycan and galactan strands to run in parallel to the cytoplasmic membrane forming several horizontal layers beneath perpendicularly oriented mycolic acids. Following a thorough re-evaluation of the currently available chemical, biochemical and electron microscopical data, we propose a fundamentally distinct principle of the physical organization and biosynthesis of the mycobacterial cell wall skeleton. According to this new concept, the solid and elastic matrix that makes the mycobacterial cell wall a formidably impermeable barrier is the direct consequence of cross-linked glycan strands which all run in a direction perpendicular to the cytoplasmic membrane.

The 5'-proximal hairpin loop of lbi RNA is a key structural element in repression of D-galactan II biosynthesis in Klebsiella pneumoniae serotype O1.

The lbi (lipopolysaccharide biosynthesis interfering) RNA of phage Acm1, an untranslated RNA transcript of 97 nucleotides, previously shown to affect O-polysaccharide biosynthesis in various Escherichia coli strains, was found to downregulate the synthesis of the D-galactan II component of the O-specific polysaccharide in Klebsiella pneumoniae serotype O1. Enzymatic and Pb2+ probing experiments revealed that lbi RNA consists of two consecutive stem-loop structures, the 5'-proximal hairpin loop of 15 nucleotides being particularly accessible to single strand-specific probes. Based on the assumption that the 5'-proximal hairpin loop may be involved in an antisense interaction with cellular target RNAs, we randomly mutagenized one or two of its central nucleotides. Expression of mutated lbi RNA variants in K. pneumoniae serotype O1 relieved at least partly the repression of D-galactan II formation. In addition, a truncated version of lbi RNA lacking the 3'-proximal hairpin loop was almost as efficient as the wild-type RNA in downregulating D-galactan II synthesis. The results obtained indicate that the 5'-proximal hairpin loop of lbi RNA functions as a key structural element in the mechanism leading to the inhibition of D-galactan II biosynthesis in K. pneumoniae serotype O1.

Biological activities of lipopolysaccharides are determined by the shape of their lipid A portion.

Lipopolysaccharide (LPS) represents a major virulence factor of Gram-negative bacteria ('endotoxin') that can cause septic shock in mammals including man. The lipid anchor of LPS to the outer membrane, lipid A, has a peculiar chemical structure, harbours the 'endotoxic principle' of LPS and is responsible for the expression of pathophysiological effects. Chemically modified lipid A can be endotoxically inactive, but may express strong antagonistic activity against LPS, a property that can be utilized in antisepsis treatment. We show here that these different biological activities are directly correlated with the molecular shape of lipid A. Only (hexaacyl) lipid A with a conical/concave shape, the cross-section of the hydrophobic region being larger than that of the hydrophilic region, exhibited strong interleukin-6 (IL-6)-inducing capacity. Most strikingly, a correlation between a cylindrical molecular shape of lipid A and antagonistic activity was established: IL-6 induction by enterobacterial LPS was inhibited by cylindrically shaped lipid A except for compounds with reduced headgroup charge. The antagonistic action is interpreted by assuming that lipid A molecules intercalate into the cytoplasmic membrane of mononuclear cells, and subsequently blocking of the putative signaling protein by the lipid A with cylindrical shape.

Binding of lipopolysaccharide (LPS) to CHO cells does not correlate with LPS-induced NF-kappaB activation.

Activation of myeloid cells by lipopolysaccharide (LPS) is a key event in the development of gram-negative sepsis. One crucial step within this process is the binding of LPS to CD14. CD14 is a glycosylphosphatidylinositol (GPI)-anchored membrane protein requiring at least one additional membrane-spanning molecule for signal transduction. It is not clear whether the function of CD14 is to merely catalyze LPS binding, followed by the interaction of LPS with the signal transducer, or whether CD14 has a more specific function and may be a part of the signaling complex. To address this question we generated Chinese hamster ovary (CHO) cells expressing a human GPI-anchored form of LPS-binding protein (mLBP) to substitute for CD14 as LPS acceptor molecule. By comparison of CHO / mLBP with CHO / vector and CHO / CD14 cells we found that expression of GPI-linked LBP results in an enhanced binding of LPS but not in an increase in cell activation as determined by translocation of NF-kappaB. Furthermore, excess of recombinant soluble LBP resulted also in increased LPS binding without affecting NF-kappaB translocation. These data show that LPS binding alone is not sufficient to induce signaling. We conclude that CD14 is more than a catalyst for LPS binding: it seems to be directly involved in LPS signaling and thus appears to be an essential part of the signaling complex.

NOS2-derived nitric oxide regulates the size, quantity and quality of granuloma formation in Mycobacterium avium-infected mice without affecting bacterial loads.

Granuloma formation in response to mycobacterial infections is associated with increased expression of inducible nitric oxide synthase (NOS2) within granuloma macrophages and increased levels of nitrate/nitrite in the sera of infected mice. Continuous treatment with 5 mm or 10 mm l-N6-(1-imino-ethyl)-lysine (L-NIL), a selective NOS2-inhibitor, in acidified drinking water for up to 7 weeks consistently reduced infection-induced nitrate/nitrite to background levels in mycobacteria-infected BALB/c mice. Oral treatment with 5 mm L-NIL initiated at the time of infection significantly exacerbated growth of Mycobacterium tuberculosis, but had no effect on Mycobacterium avium colony-forming unit development in the liver, spleen and lungs of intravenously infected mice. In order to examine the role of nitric oxide in mycobacteria-induced granulomatous inflammation in the absence of any effect on the bacterial load, M. avium-infected mice were treated with 5 mm L-NIL from day 1 through 38 and the development of granulomatous lesions in the liver was assessed by histology, immunohistology and reverse-transcription-polymerase chain reaction (RT-PCR). Computer- and video-assisted morphometry performed at 4 and 7 weeks post-infection showed that treatment with L-NIL led to markedly increased number, cellularity and size of granulomatous lesions in infected mice regardless of the virulence of the M. avium isolate used for infection. Immunohistology of the liver revealed that in mice treated with L-NIL, the numbers of CD3+ T cells, CD21/35+ B cells, CD11b+ macrophages and RB6-8C5+ granulocytes associated with granulomatous lesions was increased. RT-PCR of the liver showed that in L-NIL-treated mice infected with M. avium, mRNA levels of tumour necrosis factor, interleukin-12p40, interferon-gamma, interleukin-10 and interferon-gamma-inducible protein-10 (IP-10) were up-regulated, while mRNA levels of interleukin-4, monocyte chemotactic protein-1 (MCP-1) and MCP-5 were similar to those in untreated control infected mice. When M. avium-infected mice were treated with 5 mm L-NIL between the 5th and 12th weeks of infection, similar changes in granuloma number and size were found in the absence of any effect on the bacterial load. These findings demonstrate that nitric oxide regulates the number, size and cellular composition of M. avium-induced granulomas independently of antibacterial effects by modulating the cytokine profile within infected tissues.

Fatal granuloma necrosis without exacerbated mycobacterial growth in tumor necrosis factor receptor p55 gene-deficient mice intravenously infected with Mycobacterium avium.

The pathogenesis of mycobacterial infections is associated with the formation of granulomas in which both antibacterial protection and tissue damage take place concomitantly. We used murine Mycobacterium avium infection to compare the development of granulomatous lesions in intravenously infected tumor necrosis factor receptor p55 (TNFRp55) gene-deficient (p55(-/-)) mice to the development of granulomatous lesions in M. avium-infected syngeneic C57BL/6 (p55(+/+)) mice. Up to 5 weeks after infection with either the highly virulent M. avium strain TMC724 or the intermediately virulent M. avium strain SE01, bacterial counts in the liver, spleen, and lung of p55(-/-) mice were identical to or lower than those in infected p55(+/+) mice. However, the formation of mononuclear cell foci in the liver was delayed by approximately 2 to 3 weeks in p55(-/-) mice compared to the results obtained for infected p55(+/+) mice. Despite comparable bacterial loads, granulomas in p55(-/-) mice underwent progressive necrosis, causing damage to the surrounding liver tissue. The appearance of necrotizing granulomas was associated with the death of all infected p55(-/-) mice, regardless of the virulence of the M. avium strain used for infection. Granulomatous lesions in the liver contained three times as many CD3(+) cells in p55(-/-) mice yet appeared more diffuse than in p55(+/+) mice. Semiquantitative reverse transcription-PCR studies revealed that prior to mouse death, interleukin-12 (IL-12) and gamma interferon mRNA levels were up regulated in the livers of infected p55(-/-) mice, while mRNA levels for tumor necrosis factor, the inducible isoform of nitric-oxide synthase (iNOS), and IL-10 were similar to those found in infected p55(+/+) mice. In response to persistent mycobacterial infection, the absence of TNFRp55 causes the disregulation of T-cell-macrophage interactions and results in fatal granuloma necrosis even when adequate antibacterial functions are maintained.

The internalization time course of a given lipopolysaccharide chemotype does not correspond to its activation kinetics in monocytes.

The prerequisites for the initiation of pathophysiological effects of endotoxin (lipopolysaccharide [LPS]) include binding to and possibly internalization by target cells. Monocytes/macrophages are prominent target cells which are activated by LPS to release various pro- and anti-inflammatory mediators. The aim of the present study was to establish a new method to determine the binding and internalization rate of different LPS chemotypes by human monocytes and to correlate these phenomena with biological activity. It was found that membrane-bound LPS disappears within hours from the surface being internalized into the cell. Further, a correlation between the kinetics of internalization and the length of the sugar chain as well as an inverse correlation between the time course of internalization and LPS hydrophobicity was revealed. Comparison of the internalization kinetics of different LPS chemotypes with kinetics of tumor necrosis factor alpha release and kinetics of oxidative burst did not reveal any correlation of these parameters. These findings suggest that cellular internalization of and activation by LPS are mechanisms which are independently regulated.

Elucidation of the structure of an alanine-lacking core tetrasaccharide trisphosphate from the lipopolysaccharide of Pseudomonas aeruginosa mutant H4.

Lipopolysaccharide (LPS) of Pseudomonas aeruginosa rough mutant H4 was isolated by hot water/phenol extraction followed by a modified phenol/chloroform/petroleum ether procedure. Upon SDS/PAGE, the LPS showed a strong major band corresponding to the expected rough-type LPS. Additional faint high molecular-mass bands revealed that the O-chain was present, indicating that the H4 mutant is genetically unstable. Mild acid hydrolysis of the LPS removed lipid A and released a phosphorylated core oligosaccharide that was purified by gel-permeation chromatography and high-performance anion-exchange liquid chromatography. The oligosaccharide contained two residues of L-glycero-D-manno-heptose (Hep) and one residue each of 3-deoxy-D-manno-oct-2-ulosonic acid (Kdo) and GalNAc. Upon matrix-assisted laser desorption/ionization mass spectroscopy in the negative ion mode, the main fraction expressed a peak for the molecular ion [M-H]- at m/z 1106.41, which was compatible with a carbamoylated, trisphosphorylated tetrasaccharide. The structure was further investigated using one- and two-dimensional homonuclear and heteronuclear correlated NMR spectroscopy at pD 3 and, after borohydride reduction, at pD 9. The NMR data of the two phosphorylated tetrasaccharides recorded at different pD allowed determination of the positions of the three phosphate (P) groups and the carbamoyl group (Cm) thus establishing the following structure of the core oligosaccharide: [equation: see text] Two unusual structural features in the core oligosaccharide of P. aeruginosa were identified for the first time, i.e. the replacement of an amide-linked alanyl group in GalN with an acetyl group and the phosphorylation at position 6 of HepII.

Reduced bacterial dissemination and liver injury in CD14-deficient mice following a chronic abscess-forming peritonitis induced by Bacteroides fragilis.

The CD14 myelomonocytic differentiation antigen plays a major role in acute Gram-negative infections with Escherichia coli; however, its role in chronic infections has not yet been analyzed. To address this question, we studied the role of CD14 in a chronic abscess-forming peritonitis, induced by Bacteroides fragilis. B. fragilis (3x10(8) CFU/ml) were resuspended in a liquid nutrient agar and injected into the peritoneal cavity of CD14-deficient (CD 14-/-) and normal C57BL/6J (CD 14+/+) mice, respectively. After 3 days there was a severe phlegmonous intra-abdominal inflammation in both groups. After 7 days an abscess-forming peritonitis developed and by 14 days the infectious foci were compartimentalized. These observations were indistinguishable between CD14-/- and CD14+/+ mice. Although no differences were seen in abscess formation, CD14-/- mice were able to clear B. fragilis more efficiently from the blood than CD14+/+ mice. After 3, 7, and 14 days blood cultures were B. fragilis positive in 11% (1/9), 20% (2/10), and 0% (0/9) in CD14-/-compared with 90% (9/10), 78% (7/9), and 20% (2/10) in CD14+/+ mice, respectively (P<0.05). Furthermore, although the infection resulted in hepatocellular necrosis and severe hepatitis in both groups, at day 14 the liver cell damage was more severe in CD14+/+ than in CD14-/- mice (P<0.05). These results show that the chronic abscess formation induced by B. fragilis capsular polysaccharides is CD14 independent; however, bacterial clearance and/or dissemination and liver cell damage are at least partially influenced by CD14-dependent mechanisms.

Layered murein revisited: a fundamentally new concept of bacterial cell wall structure, biogenesis and function.

The classical concept of the architecture of microbial murein assumes cross-linked glycan chains to be arranged in horizontal layers outside of the plasma membrane. It necessitates elaborate hypotheses to explain processes such as the biosynthesis, growth and division of the bacterial cell wall and provides no explanation for transenvelope macromolecular transport. Moreover, this model is difficult to reconcile with a number of basic chemical and electron microscopical data. According to a fundamentally distinct concept which is presented here, glycan strands in the microbial wall run perpendicular to the plasma membrane, each strand being cross-linked by peptide bridges with four other strands. This arrangement allows the formation of a structured matrix pierced with ordered ionophoric channels potentially harboring either lipoprotein or teichoic (lipoteichoic) acid molecules in Gram-negative and Gram-positive bacteria, respectively. New wall structures are synthesized in toto emerging from the cytoplasmic membrane as a condensed gel-like network below the old wall without being covalently attached to it, expanding due to inherent elasticity as the old wall is lyzed. This model reflects published genetic and biochemical data and offers a simple explanation for peptidoglycan biogenesis. As the biosynthesis is terminated by enzymic cleavage of all glycan strands, murein is irreversibly released from the membrane. The murein detachment prepares the membrane for de novo assembly of both the new wall synthesis machinery and the multicomponent factory for protein, DNA and phospholipid transfer. Being assembled in parallel, both new murein and the traffic complexes grow from the membrane together. This concept eliminates the necessity for the traffic complexes to penetrate intact murein. In the process of simultaneous assembly, the expanding murein functions as a lifting platform driven by the force of turgor pressure, transporting macromolecules through the perisplasmic space.