Tag: cell wall

Correlation between plant cell wall stiffening and root extension arrest phenotype in combined abiotic stress of Fe and Al

The plasticity and growth of plant cell walls (CWs) is still not sufficiently understood on its molecular level. *

Atomic Force Microscopy (AFM) has been shown to be a powerful tool to measure the stiffness of plant tissues. *

In the article “Correlation between plant cell wall stiffening and root extension arrest phenotype in the combined abiotic stress of Fe and Al” Harinderbir Kaur, Jean-Marie Teulon, Christian Godon, Thierry Desnos, Shu-wen W. Chen and Jean-Luc Pellequer describe the use of atomic force microscopy (AFM) to observe elastic responses of the root transition zone of 4-day-old Arabidopsis thaliana wild-type and almt1-mutant seedlings grown under Fe or Al stresses. *

In order to evaluate the relationship between root extension and root cell wall elasticity, the authors used Atomic Force Microscopy to perform vertical indentations on surfaces of living plant roots. *

NanoWorld Pyrex-Nitride silicon-nitride PNP-TR AFM probes with triangular AFM cantilevers were used for the nanoindentation experiments with atomic force microscopy. (PNP-TR AFM cantilever beam 2 (CB2) with a typical force constant of 0.08 N/m and a typical resonant frequency of 17 kHz, typical AFM tip radius 10 nm, macroscopic half cone angles 35°). *

Force-distance (F-D) curves were measured using the Atomic Force Microscope and the PNP-TR AFM tips. *

Because of the heterogeneity of seedling CW surfaces, Harinderbir Kaur et al. used the recently developed trimechanics-3PCS framework for interpreting force-distance curves. The trimechanics-3PCS framework allows the extraction of both stiffness and elasticity along the depth of indentation and permits the investigation of the variation of stiffness with varied depth for biomaterials of heterogeneous elasticity responding to an external force. *

A glass slide with a glued seedling (see Figure 1 cited below) was positioned under the AFM cantilever with the help of an AFM optical camera. Due to the large motorized sample stage of the AFM, the glass slide was adjusted in such a way that the AFM cantilever could be positioned perpendicularly at the longitudinal middle of the glued root. The target working area, the transition zone, was 500 µm away from the root apex, almost twice the length of PNP-TR AFM cantilever. *

As shown in the article the presence of single metal species Fe2+ or Al3+ at 10 μM exerts no noticeable effect on the root growth compared with the control conditions. On the contrary, a mix of both the metal ions produced a strong root-extension arrest concomitant with significant increase of CW stiffness. *

Raising the concentration of either Fe2+or Al3+ to 20 μM, no root-extension arrest was observed; nevertheless, an increase in root stiffness occurred. In the presence of both the metal ions at 10 μM, root-extension arrest was not observed in the almt1 mutant, which substantially abolishes the ability to exude malate. The authors’ results indicate that the combination of Fe2+and Al3+ with exuded malate is crucial for both CW stiffening and root-extension arrest. *

It is shown that the elasticity of plant CW is sensitive and can be used to assess abiotic stresses on plant growth and stiffening. *

However, stiffness increase induced by single Fe2+ or Al3+ is not sufficient for arresting root growth in the described experimental conditions and unexpectedly, the stiffening and the phenotype of seedling roots such as REA are not directly correlated. *

Figure 1 from Harinderbir Kaur et al. 2024 “Correlation between plant cell wall stiffening and root extension arrest phenotype in the combined abiotic stress of Fe and Al”:Principle of nanomechanical measurement of seedling roots with atomic force microscopy. A seedling root (R) is deposited on a microscope slide using silicon glue (N, for Nusil). A fastening band of silicon is seen near the tip of the root (T). The thickness of the fastening band must be thin enough to avoid hindering the AFM support (S), but thick enough to withstand the bending of the root tip. The root is placed under the AFM cantilever (C) as observed by the AFM optical camera. The triangular shaped cantilever (200 µm long) was placed 500 µm away from the root tip in the transition zone where nanoindentation measurements proceeded (as shown). The seedling root and the AFM cantilever are placed within a liquid environment (growth solution, see Supplementary file of the cited article). AFM, atomic force microscopy. NanoWorld Pyrex-Nitride silicon-nitride PNP-TR AFM probes with triangular AFM cantilevers were used for the nanoindentation experiments with atomic force microscopy.
Figure 1 from Harinderbir Kaur et al. 2024 “Correlation between plant cell wall stiffening and root extension arrest phenotype in the combined abiotic stress of Fe and Al”:
Principle of nanomechanical measurement of seedling roots with atomic force microscopy.
A seedling root (R) is deposited on a microscope slide using silicon glue (N, for Nusil). A fastening band of silicon is seen near the tip of the root (T). The thickness of the fastening band must be thin enough to avoid hindering the AFM support (S), but thick enough to withstand the bending of the root tip. The root is placed under the AFM cantilever (C) as observed by the AFM optical camera. The triangular shaped cantilever (200 µm long) was placed 500 µm away from the root tip in the transition zone where nanoindentation measurements proceeded (as shown). The seedling root and the AFM cantilever are placed within a liquid environment (growth solution, see Supplementary file of the cited article). AFM, atomic force microscopy.

*Harinderbir Kaur, Jean‐Marie Teulon, Christian Godon, Thierry Desnos, Shu‐wen W. Chen and Jean‐Luc Pellequer
Correlation between plant cell wall stiffening and root extension arrest phenotype in the combined abiotic stress of Fe and Al
Plant, Cell & Environment 2024; 47:574–584
DOI: https://doi.org/10.1111/pce.14744

The article “Correlation between plant cell wall stiffening and root extension arrest phenotype in the combined abiotic stress of Fe and Al” by Harinderbir Kaur, Jean‐Marie Teulon, Christian Godon, Thierry Desnos, Shu‐wen W. Chen and Jean‐Luc Pellequer is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third-party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit https://creativecommons.org/licenses/by/4.0/.

Penicillin-Binding Protein 1 (PBP1) of Staphylococcus aureus Has Multiple Essential Functions in Cell Division

Bacterial cell division is a complex process requiring the coordination of multiple components to allow the appropriate spatial and temporal control of septum formation and cell scission. *

Peptidoglycan (PG) is the major structural component of the septum, and recent studies by Katarzyna Wacnik et al., in the human pathogen Staphylococcus aureus have revealed a complex, multistage PG architecture that develops during septation. *

Penicillin-binding proteins (PBPs) are essential for the final steps of PG biosynthesis; their transpeptidase activity links the peptide side chains of nascent glycan strands. PBP1 is required for cell division in S. aureus. *

In the article “Penicillin-Binding Protein 1 (PBP1) of Staphylococcus aureus Has Multiple Essential Functions in Cell Division” Katarzyna Wacnik, Vincenzo A. Rao, Xinyue Chen, Lucia Lafage, Manuel Pazos, Simon Booth, Waldemar Vollmer, Jamie K. Hobbs, Richard J. Lewis and Simon J. Foster demonstrate that it has multiple essential functions associated with its enzymatic activity and as a regulator of division. *

Loss of PBP1, or just its C-terminal PASTA domains, results in cessation of division at the point of septal plate formation. The PASTA domains can bind PG and thereby potentially coordinate the cell division process. The transpeptidase activity of PBP1 is also essential, but its loss leads to a strikingly different phenotype of thickened and aberrant septa, which is phenocopied by the morphological effects of adding the PBP1-specific β-lactam, meropenem. Together, these results lead to a model for septal PG synthesis where PBP1 enzyme activity is required for the characteristic architecture of the septum and PBP1 protein molecules enable the formation of the septal plate. *

Bacterial cell wall peptidoglycan is essential, and its synthesis is the target of clinically important antibiotics such as β-lactams. β-lactams target penicillin-binding proteins (PBPs) that assemble new peptidoglycan from its building blocks. *

The human pathogen Staphylococcus aureus only has two essential PBPs that can carry out all the functions necessary for growth and division. *

In the absence of the confounding antibiotic resistance-associated PBP PBP2A, the PBP1 transpeptidase activity is required for cell division, and in the article “Penicillin-Binding Protein 1 (PBP1) of Staphylococcus aureus Has Multiple Essential Functions in Cell Division”, Katarzyna Wacnik et al. state that they have found that it has several essential functions, both as an enzyme and as a coordinator by binding to cell division proteins and to its peptidoglycan product, via its PASTA domains. *

This has led to a new model for cell division with PBP1 responsible for the synthesis of the characteristic architectural features of the septum. *

NanoWorld Ultra-Short Cantilevers for High-Speed AFM of the USC-F0.3-k0.3 AFM probe type (nominal spring constant of 0.3 N/m and resonant frequency (in liquid) of ~150 kHz (300 kHz in air) were used for the Atomic Force Microscopy imaging.

Supplemental Material from Katarzyna Wacnik et al 2022 “Penicillin-Binding Protein 1 (PBP1) of Staphylococcus aureus Has Multiple Essential Functions in Cell Division” FIG S5: Gallery of AFM images of S. aureus Δpbp1, pbp1ΔPASTA, and pbp1*. (A) Diagram of the section through of the cell with progressing septum (top) and AFM topographic images (bottom) of unfinished (i) and closed (ii) septa, parallel to the plane of the image, in SH1000 WT. Sacculi (images to the left, scale bars = 500 nm, data scales [z]: 200 [top] and 250 nm [bottom]) and higher-magnification scans (images to the right, scale bars = 50 nm, data scales [z]: 80 [top] and 40 nm [bottom]) of the boxed areas from the images to the left. (B) AFM topographic images of unfinished septa, parallel to the plane of the image, in Δpbp1 (from left to right, scale bars = 500, 50, and 50 nm; data scales [z] 500, 120, and 150 nm), pbp1ΔPASTA (from left to right, scale bars = 500, 50, and 50 nm; data scales [z] 693, 80, and 100 nm), and pbp1* (from left to right, scale bars = 500, 50, and 50 nm; data scales [z] 500, 80, and 25 nm) grown in the absence of inducer for 2 h. Images to the left are sacculi, while images in the center (1) and to the right (2) are higher-magnification scans of the boxed areas of the images on the left. (C) AFM topographic images (right) of the external nascent ring architecture in SH1000 WT (wt; from top to bottom, scale bars = 500 and 50 nm; data scales [z], 100 and 20 nm) and mutants Δpbp1 (top to bottom, scale bars = 500 and 50 nm; data scales [z], 400 and 60 nm) and pbp1ΔPASTA (from top to bottom, scale bars = 500 and 50 nm; data scales [z], 350 and 100 nm) grown in the absence of inducer for 2 h. The top images are the external surface of sacculi, while the bottom images are higher-magnification scans of the boxed areas of the top images. The arrows indicate piecrusts of the next division plane, which dissects the previous division septum. Arrowheads indicate abnormal features, holes, in the PG ring architecture. On the left is an interpretive diagram of a section through the cell wall (i) and the corresponding external surface (ii) as viewed by AFM. The mature cell wall of a newly separated daughter cell is shown in blue, which has both internally and externally mesh-structured PG. The newly exposed septum has an external ring-structured PG (green) and a mesh-like cytoplasmic facing PG (yellow). Data are representative of two independent experiments. NanoWorld Ultra-Short Cantilevers for High-Speed Atomic Force Microscopy of the USC-F0.3-k0.3 AFM probe type were used.
Supplemental Material from Katarzyna Wacnik et al 2022 “Penicillin-Binding Protein 1 (PBP1) of Staphylococcus aureus Has Multiple Essential Functions in Cell Division” FIG S5: Gallery of AFM images of S. aureus Δpbp1, pbp1ΔPASTA, and pbp1*. (A) Diagram of the section through of the cell with progressing septum (top) and AFM topographic images (bottom) of unfinished (i) and closed (ii) septa, parallel to the plane of the image, in SH1000 WT. Sacculi (images to the left, scale bars = 500 nm, data scales [z]: 200 [top] and 250 nm [bottom]) and higher-magnification scans (images to the right, scale bars = 50 nm, data scales [z]: 80 [top] and 40 nm [bottom]) of the boxed areas from the images to the left. (B) AFM topographic images of unfinished septa, parallel to the plane of the image, in Δpbp1 (from left to right, scale bars = 500, 50, and 50 nm; data scales [z] 500, 120, and 150 nm), pbp1ΔPASTA (from left to right, scale bars = 500, 50, and 50 nm; data scales [z] 693, 80, and 100 nm), and pbp1* (from left to right, scale bars = 500, 50, and 50 nm; data scales [z] 500, 80, and 25 nm) grown in the absence of inducer for 2 h. Images to the left are sacculi, while images in the center (1) and to the right (2) are higher-magnification scans of the boxed areas of the images on the left. (C) AFM topographic images (right) of the external nascent ring architecture in SH1000 WT (wt; from top to bottom, scale bars = 500 and 50 nm; data scales [z], 100 and 20 nm) and mutants Δpbp1 (top to bottom, scale bars = 500 and 50 nm; data scales [z], 400 and 60 nm) and pbp1ΔPASTA (from top to bottom, scale bars = 500 and 50 nm; data scales [z], 350 and 100 nm) grown in the absence of inducer for 2 h. The top images are the external surface of sacculi, while the bottom images are higher-magnification scans of the boxed areas of the top images. The arrows indicate piecrusts of the next division plane, which dissects the previous division septum. Arrowheads indicate abnormal features, holes, in the PG ring architecture. On the left is an interpretive diagram of a section through the cell wall (i) and the corresponding external surface (ii) as viewed by AFM. The mature cell wall of a newly separated daughter cell is shown in blue, which has both internally and externally mesh-structured PG. The newly exposed septum has an external ring-structured PG (green) and a mesh-like cytoplasmic facing PG (yellow). Data are representative of two independent experiments.
*Katarzyna Wacnik, Vincenzo A. Rao, Xinyue Chen, Lucia Lafage, Manuel Pazos, Simon Booth, Waldemar Vollmer, Jamie K. Hobbs, Richard J. Lewis and Simon J. Foster
Penicillin-Binding Protein 1 (PBP1) of Staphylococcus aureus Has Multiple Essential Functions in Cell Division
American Society for Microbiology Journals, (2022) mBio, Vol. 13, No. 4
DOI: https://doi.org/10.1128/mbio.00669-22

The article “Penicillin-Binding Protein 1 (PBP1) of Staphylococcus aureus Has Multiple Essential Functions in Cell Division” by Katarzyna Wacnik, Vincenzo A. Rao, Xinyue Chen, Lucia Lafage, Manuel Pazos, Simon Booth, Waldemar Vollmer, Jamie K. Hobbs, Richard J. Lewis and Simon J. Foster is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third-party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit https://creativecommons.org/licenses/by/4.0/.